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TypeScript/lib/typescriptServices.js

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/*! *****************************************************************************
Copyright (c) Microsoft Corporation. All rights reserved.
Licensed under the Apache License, Version 2.0 (the "License"); you may not use
this file except in compliance with the License. You may obtain a copy of the
License at http://www.apache.org/licenses/LICENSE-2.0
THIS CODE IS PROVIDED ON AN *AS IS* BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
KIND, EITHER EXPRESS OR IMPLIED, INCLUDING WITHOUT LIMITATION ANY IMPLIED
WARRANTIES OR CONDITIONS OF TITLE, FITNESS FOR A PARTICULAR PURPOSE,
MERCHANTABLITY OR NON-INFRINGEMENT.
See the Apache Version 2.0 License for specific language governing permissions
and limitations under the License.
***************************************************************************** */
var __extends = (this && this.__extends) || function (d, b) {
for (var p in b) if (b.hasOwnProperty(p)) d[p] = b[p];
function __() { this.constructor = d; }
d.prototype = b === null ? Object.create(b) : (__.prototype = b.prototype, new __());
};
var ts;
(function (ts) {
// token > SyntaxKind.Identifer => token is a keyword
// Also, If you add a new SyntaxKind be sure to keep the `Markers` section at the bottom in sync
var SyntaxKind;
(function (SyntaxKind) {
SyntaxKind[SyntaxKind["Unknown"] = 0] = "Unknown";
SyntaxKind[SyntaxKind["EndOfFileToken"] = 1] = "EndOfFileToken";
SyntaxKind[SyntaxKind["SingleLineCommentTrivia"] = 2] = "SingleLineCommentTrivia";
SyntaxKind[SyntaxKind["MultiLineCommentTrivia"] = 3] = "MultiLineCommentTrivia";
SyntaxKind[SyntaxKind["NewLineTrivia"] = 4] = "NewLineTrivia";
SyntaxKind[SyntaxKind["WhitespaceTrivia"] = 5] = "WhitespaceTrivia";
// We detect and preserve #! on the first line
SyntaxKind[SyntaxKind["ShebangTrivia"] = 6] = "ShebangTrivia";
// We detect and provide better error recovery when we encounter a git merge marker. This
// allows us to edit files with git-conflict markers in them in a much more pleasant manner.
SyntaxKind[SyntaxKind["ConflictMarkerTrivia"] = 7] = "ConflictMarkerTrivia";
// Literals
SyntaxKind[SyntaxKind["NumericLiteral"] = 8] = "NumericLiteral";
SyntaxKind[SyntaxKind["StringLiteral"] = 9] = "StringLiteral";
SyntaxKind[SyntaxKind["JsxText"] = 10] = "JsxText";
SyntaxKind[SyntaxKind["RegularExpressionLiteral"] = 11] = "RegularExpressionLiteral";
SyntaxKind[SyntaxKind["NoSubstitutionTemplateLiteral"] = 12] = "NoSubstitutionTemplateLiteral";
// Pseudo-literals
SyntaxKind[SyntaxKind["TemplateHead"] = 13] = "TemplateHead";
SyntaxKind[SyntaxKind["TemplateMiddle"] = 14] = "TemplateMiddle";
SyntaxKind[SyntaxKind["TemplateTail"] = 15] = "TemplateTail";
// Punctuation
SyntaxKind[SyntaxKind["OpenBraceToken"] = 16] = "OpenBraceToken";
SyntaxKind[SyntaxKind["CloseBraceToken"] = 17] = "CloseBraceToken";
SyntaxKind[SyntaxKind["OpenParenToken"] = 18] = "OpenParenToken";
SyntaxKind[SyntaxKind["CloseParenToken"] = 19] = "CloseParenToken";
SyntaxKind[SyntaxKind["OpenBracketToken"] = 20] = "OpenBracketToken";
SyntaxKind[SyntaxKind["CloseBracketToken"] = 21] = "CloseBracketToken";
SyntaxKind[SyntaxKind["DotToken"] = 22] = "DotToken";
SyntaxKind[SyntaxKind["DotDotDotToken"] = 23] = "DotDotDotToken";
SyntaxKind[SyntaxKind["SemicolonToken"] = 24] = "SemicolonToken";
SyntaxKind[SyntaxKind["CommaToken"] = 25] = "CommaToken";
SyntaxKind[SyntaxKind["LessThanToken"] = 26] = "LessThanToken";
SyntaxKind[SyntaxKind["LessThanSlashToken"] = 27] = "LessThanSlashToken";
SyntaxKind[SyntaxKind["GreaterThanToken"] = 28] = "GreaterThanToken";
SyntaxKind[SyntaxKind["LessThanEqualsToken"] = 29] = "LessThanEqualsToken";
SyntaxKind[SyntaxKind["GreaterThanEqualsToken"] = 30] = "GreaterThanEqualsToken";
SyntaxKind[SyntaxKind["EqualsEqualsToken"] = 31] = "EqualsEqualsToken";
SyntaxKind[SyntaxKind["ExclamationEqualsToken"] = 32] = "ExclamationEqualsToken";
SyntaxKind[SyntaxKind["EqualsEqualsEqualsToken"] = 33] = "EqualsEqualsEqualsToken";
SyntaxKind[SyntaxKind["ExclamationEqualsEqualsToken"] = 34] = "ExclamationEqualsEqualsToken";
SyntaxKind[SyntaxKind["EqualsGreaterThanToken"] = 35] = "EqualsGreaterThanToken";
SyntaxKind[SyntaxKind["PlusToken"] = 36] = "PlusToken";
SyntaxKind[SyntaxKind["MinusToken"] = 37] = "MinusToken";
SyntaxKind[SyntaxKind["AsteriskToken"] = 38] = "AsteriskToken";
SyntaxKind[SyntaxKind["AsteriskAsteriskToken"] = 39] = "AsteriskAsteriskToken";
SyntaxKind[SyntaxKind["SlashToken"] = 40] = "SlashToken";
SyntaxKind[SyntaxKind["PercentToken"] = 41] = "PercentToken";
SyntaxKind[SyntaxKind["PlusPlusToken"] = 42] = "PlusPlusToken";
SyntaxKind[SyntaxKind["MinusMinusToken"] = 43] = "MinusMinusToken";
SyntaxKind[SyntaxKind["LessThanLessThanToken"] = 44] = "LessThanLessThanToken";
SyntaxKind[SyntaxKind["GreaterThanGreaterThanToken"] = 45] = "GreaterThanGreaterThanToken";
SyntaxKind[SyntaxKind["GreaterThanGreaterThanGreaterThanToken"] = 46] = "GreaterThanGreaterThanGreaterThanToken";
SyntaxKind[SyntaxKind["AmpersandToken"] = 47] = "AmpersandToken";
SyntaxKind[SyntaxKind["BarToken"] = 48] = "BarToken";
SyntaxKind[SyntaxKind["CaretToken"] = 49] = "CaretToken";
SyntaxKind[SyntaxKind["ExclamationToken"] = 50] = "ExclamationToken";
SyntaxKind[SyntaxKind["TildeToken"] = 51] = "TildeToken";
SyntaxKind[SyntaxKind["AmpersandAmpersandToken"] = 52] = "AmpersandAmpersandToken";
SyntaxKind[SyntaxKind["BarBarToken"] = 53] = "BarBarToken";
SyntaxKind[SyntaxKind["QuestionToken"] = 54] = "QuestionToken";
SyntaxKind[SyntaxKind["ColonToken"] = 55] = "ColonToken";
SyntaxKind[SyntaxKind["AtToken"] = 56] = "AtToken";
// Assignments
SyntaxKind[SyntaxKind["EqualsToken"] = 57] = "EqualsToken";
SyntaxKind[SyntaxKind["PlusEqualsToken"] = 58] = "PlusEqualsToken";
SyntaxKind[SyntaxKind["MinusEqualsToken"] = 59] = "MinusEqualsToken";
SyntaxKind[SyntaxKind["AsteriskEqualsToken"] = 60] = "AsteriskEqualsToken";
SyntaxKind[SyntaxKind["AsteriskAsteriskEqualsToken"] = 61] = "AsteriskAsteriskEqualsToken";
SyntaxKind[SyntaxKind["SlashEqualsToken"] = 62] = "SlashEqualsToken";
SyntaxKind[SyntaxKind["PercentEqualsToken"] = 63] = "PercentEqualsToken";
SyntaxKind[SyntaxKind["LessThanLessThanEqualsToken"] = 64] = "LessThanLessThanEqualsToken";
SyntaxKind[SyntaxKind["GreaterThanGreaterThanEqualsToken"] = 65] = "GreaterThanGreaterThanEqualsToken";
SyntaxKind[SyntaxKind["GreaterThanGreaterThanGreaterThanEqualsToken"] = 66] = "GreaterThanGreaterThanGreaterThanEqualsToken";
SyntaxKind[SyntaxKind["AmpersandEqualsToken"] = 67] = "AmpersandEqualsToken";
SyntaxKind[SyntaxKind["BarEqualsToken"] = 68] = "BarEqualsToken";
SyntaxKind[SyntaxKind["CaretEqualsToken"] = 69] = "CaretEqualsToken";
// Identifiers
SyntaxKind[SyntaxKind["Identifier"] = 70] = "Identifier";
// Reserved words
SyntaxKind[SyntaxKind["BreakKeyword"] = 71] = "BreakKeyword";
SyntaxKind[SyntaxKind["CaseKeyword"] = 72] = "CaseKeyword";
SyntaxKind[SyntaxKind["CatchKeyword"] = 73] = "CatchKeyword";
SyntaxKind[SyntaxKind["ClassKeyword"] = 74] = "ClassKeyword";
SyntaxKind[SyntaxKind["ConstKeyword"] = 75] = "ConstKeyword";
SyntaxKind[SyntaxKind["ContinueKeyword"] = 76] = "ContinueKeyword";
SyntaxKind[SyntaxKind["DebuggerKeyword"] = 77] = "DebuggerKeyword";
SyntaxKind[SyntaxKind["DefaultKeyword"] = 78] = "DefaultKeyword";
SyntaxKind[SyntaxKind["DeleteKeyword"] = 79] = "DeleteKeyword";
SyntaxKind[SyntaxKind["DoKeyword"] = 80] = "DoKeyword";
SyntaxKind[SyntaxKind["ElseKeyword"] = 81] = "ElseKeyword";
SyntaxKind[SyntaxKind["EnumKeyword"] = 82] = "EnumKeyword";
SyntaxKind[SyntaxKind["ExportKeyword"] = 83] = "ExportKeyword";
SyntaxKind[SyntaxKind["ExtendsKeyword"] = 84] = "ExtendsKeyword";
SyntaxKind[SyntaxKind["FalseKeyword"] = 85] = "FalseKeyword";
SyntaxKind[SyntaxKind["FinallyKeyword"] = 86] = "FinallyKeyword";
SyntaxKind[SyntaxKind["ForKeyword"] = 87] = "ForKeyword";
SyntaxKind[SyntaxKind["FunctionKeyword"] = 88] = "FunctionKeyword";
SyntaxKind[SyntaxKind["IfKeyword"] = 89] = "IfKeyword";
SyntaxKind[SyntaxKind["ImportKeyword"] = 90] = "ImportKeyword";
SyntaxKind[SyntaxKind["InKeyword"] = 91] = "InKeyword";
SyntaxKind[SyntaxKind["InstanceOfKeyword"] = 92] = "InstanceOfKeyword";
SyntaxKind[SyntaxKind["NewKeyword"] = 93] = "NewKeyword";
SyntaxKind[SyntaxKind["NullKeyword"] = 94] = "NullKeyword";
SyntaxKind[SyntaxKind["ReturnKeyword"] = 95] = "ReturnKeyword";
SyntaxKind[SyntaxKind["SuperKeyword"] = 96] = "SuperKeyword";
SyntaxKind[SyntaxKind["SwitchKeyword"] = 97] = "SwitchKeyword";
SyntaxKind[SyntaxKind["ThisKeyword"] = 98] = "ThisKeyword";
SyntaxKind[SyntaxKind["ThrowKeyword"] = 99] = "ThrowKeyword";
SyntaxKind[SyntaxKind["TrueKeyword"] = 100] = "TrueKeyword";
SyntaxKind[SyntaxKind["TryKeyword"] = 101] = "TryKeyword";
SyntaxKind[SyntaxKind["TypeOfKeyword"] = 102] = "TypeOfKeyword";
SyntaxKind[SyntaxKind["VarKeyword"] = 103] = "VarKeyword";
SyntaxKind[SyntaxKind["VoidKeyword"] = 104] = "VoidKeyword";
SyntaxKind[SyntaxKind["WhileKeyword"] = 105] = "WhileKeyword";
SyntaxKind[SyntaxKind["WithKeyword"] = 106] = "WithKeyword";
// Strict mode reserved words
SyntaxKind[SyntaxKind["ImplementsKeyword"] = 107] = "ImplementsKeyword";
SyntaxKind[SyntaxKind["InterfaceKeyword"] = 108] = "InterfaceKeyword";
SyntaxKind[SyntaxKind["LetKeyword"] = 109] = "LetKeyword";
SyntaxKind[SyntaxKind["PackageKeyword"] = 110] = "PackageKeyword";
SyntaxKind[SyntaxKind["PrivateKeyword"] = 111] = "PrivateKeyword";
SyntaxKind[SyntaxKind["ProtectedKeyword"] = 112] = "ProtectedKeyword";
SyntaxKind[SyntaxKind["PublicKeyword"] = 113] = "PublicKeyword";
SyntaxKind[SyntaxKind["StaticKeyword"] = 114] = "StaticKeyword";
SyntaxKind[SyntaxKind["YieldKeyword"] = 115] = "YieldKeyword";
// Contextual keywords
SyntaxKind[SyntaxKind["AbstractKeyword"] = 116] = "AbstractKeyword";
SyntaxKind[SyntaxKind["AsKeyword"] = 117] = "AsKeyword";
SyntaxKind[SyntaxKind["AnyKeyword"] = 118] = "AnyKeyword";
SyntaxKind[SyntaxKind["AsyncKeyword"] = 119] = "AsyncKeyword";
SyntaxKind[SyntaxKind["AwaitKeyword"] = 120] = "AwaitKeyword";
SyntaxKind[SyntaxKind["BooleanKeyword"] = 121] = "BooleanKeyword";
SyntaxKind[SyntaxKind["ConstructorKeyword"] = 122] = "ConstructorKeyword";
SyntaxKind[SyntaxKind["DeclareKeyword"] = 123] = "DeclareKeyword";
SyntaxKind[SyntaxKind["GetKeyword"] = 124] = "GetKeyword";
SyntaxKind[SyntaxKind["IsKeyword"] = 125] = "IsKeyword";
SyntaxKind[SyntaxKind["KeyOfKeyword"] = 126] = "KeyOfKeyword";
SyntaxKind[SyntaxKind["ModuleKeyword"] = 127] = "ModuleKeyword";
SyntaxKind[SyntaxKind["NamespaceKeyword"] = 128] = "NamespaceKeyword";
SyntaxKind[SyntaxKind["NeverKeyword"] = 129] = "NeverKeyword";
SyntaxKind[SyntaxKind["ReadonlyKeyword"] = 130] = "ReadonlyKeyword";
SyntaxKind[SyntaxKind["RequireKeyword"] = 131] = "RequireKeyword";
SyntaxKind[SyntaxKind["NumberKeyword"] = 132] = "NumberKeyword";
SyntaxKind[SyntaxKind["SetKeyword"] = 133] = "SetKeyword";
SyntaxKind[SyntaxKind["StringKeyword"] = 134] = "StringKeyword";
SyntaxKind[SyntaxKind["SymbolKeyword"] = 135] = "SymbolKeyword";
SyntaxKind[SyntaxKind["TypeKeyword"] = 136] = "TypeKeyword";
SyntaxKind[SyntaxKind["UndefinedKeyword"] = 137] = "UndefinedKeyword";
SyntaxKind[SyntaxKind["FromKeyword"] = 138] = "FromKeyword";
SyntaxKind[SyntaxKind["GlobalKeyword"] = 139] = "GlobalKeyword";
SyntaxKind[SyntaxKind["OfKeyword"] = 140] = "OfKeyword";
// Parse tree nodes
// Names
SyntaxKind[SyntaxKind["QualifiedName"] = 141] = "QualifiedName";
SyntaxKind[SyntaxKind["ComputedPropertyName"] = 142] = "ComputedPropertyName";
// Signature elements
SyntaxKind[SyntaxKind["TypeParameter"] = 143] = "TypeParameter";
SyntaxKind[SyntaxKind["Parameter"] = 144] = "Parameter";
SyntaxKind[SyntaxKind["Decorator"] = 145] = "Decorator";
// TypeMember
SyntaxKind[SyntaxKind["PropertySignature"] = 146] = "PropertySignature";
SyntaxKind[SyntaxKind["PropertyDeclaration"] = 147] = "PropertyDeclaration";
SyntaxKind[SyntaxKind["MethodSignature"] = 148] = "MethodSignature";
SyntaxKind[SyntaxKind["MethodDeclaration"] = 149] = "MethodDeclaration";
SyntaxKind[SyntaxKind["Constructor"] = 150] = "Constructor";
SyntaxKind[SyntaxKind["GetAccessor"] = 151] = "GetAccessor";
SyntaxKind[SyntaxKind["SetAccessor"] = 152] = "SetAccessor";
SyntaxKind[SyntaxKind["CallSignature"] = 153] = "CallSignature";
SyntaxKind[SyntaxKind["ConstructSignature"] = 154] = "ConstructSignature";
SyntaxKind[SyntaxKind["IndexSignature"] = 155] = "IndexSignature";
// Type
SyntaxKind[SyntaxKind["TypePredicate"] = 156] = "TypePredicate";
SyntaxKind[SyntaxKind["TypeReference"] = 157] = "TypeReference";
SyntaxKind[SyntaxKind["FunctionType"] = 158] = "FunctionType";
SyntaxKind[SyntaxKind["ConstructorType"] = 159] = "ConstructorType";
SyntaxKind[SyntaxKind["TypeQuery"] = 160] = "TypeQuery";
SyntaxKind[SyntaxKind["TypeLiteral"] = 161] = "TypeLiteral";
SyntaxKind[SyntaxKind["ArrayType"] = 162] = "ArrayType";
SyntaxKind[SyntaxKind["TupleType"] = 163] = "TupleType";
SyntaxKind[SyntaxKind["UnionType"] = 164] = "UnionType";
SyntaxKind[SyntaxKind["IntersectionType"] = 165] = "IntersectionType";
SyntaxKind[SyntaxKind["ParenthesizedType"] = 166] = "ParenthesizedType";
SyntaxKind[SyntaxKind["ThisType"] = 167] = "ThisType";
SyntaxKind[SyntaxKind["TypeOperator"] = 168] = "TypeOperator";
SyntaxKind[SyntaxKind["IndexedAccessType"] = 169] = "IndexedAccessType";
SyntaxKind[SyntaxKind["MappedType"] = 170] = "MappedType";
SyntaxKind[SyntaxKind["LiteralType"] = 171] = "LiteralType";
// Binding patterns
SyntaxKind[SyntaxKind["ObjectBindingPattern"] = 172] = "ObjectBindingPattern";
SyntaxKind[SyntaxKind["ArrayBindingPattern"] = 173] = "ArrayBindingPattern";
SyntaxKind[SyntaxKind["BindingElement"] = 174] = "BindingElement";
// Expression
SyntaxKind[SyntaxKind["ArrayLiteralExpression"] = 175] = "ArrayLiteralExpression";
SyntaxKind[SyntaxKind["ObjectLiteralExpression"] = 176] = "ObjectLiteralExpression";
SyntaxKind[SyntaxKind["PropertyAccessExpression"] = 177] = "PropertyAccessExpression";
SyntaxKind[SyntaxKind["ElementAccessExpression"] = 178] = "ElementAccessExpression";
SyntaxKind[SyntaxKind["CallExpression"] = 179] = "CallExpression";
SyntaxKind[SyntaxKind["NewExpression"] = 180] = "NewExpression";
SyntaxKind[SyntaxKind["TaggedTemplateExpression"] = 181] = "TaggedTemplateExpression";
SyntaxKind[SyntaxKind["TypeAssertionExpression"] = 182] = "TypeAssertionExpression";
SyntaxKind[SyntaxKind["ParenthesizedExpression"] = 183] = "ParenthesizedExpression";
SyntaxKind[SyntaxKind["FunctionExpression"] = 184] = "FunctionExpression";
SyntaxKind[SyntaxKind["ArrowFunction"] = 185] = "ArrowFunction";
SyntaxKind[SyntaxKind["DeleteExpression"] = 186] = "DeleteExpression";
SyntaxKind[SyntaxKind["TypeOfExpression"] = 187] = "TypeOfExpression";
SyntaxKind[SyntaxKind["VoidExpression"] = 188] = "VoidExpression";
SyntaxKind[SyntaxKind["AwaitExpression"] = 189] = "AwaitExpression";
SyntaxKind[SyntaxKind["PrefixUnaryExpression"] = 190] = "PrefixUnaryExpression";
SyntaxKind[SyntaxKind["PostfixUnaryExpression"] = 191] = "PostfixUnaryExpression";
SyntaxKind[SyntaxKind["BinaryExpression"] = 192] = "BinaryExpression";
SyntaxKind[SyntaxKind["ConditionalExpression"] = 193] = "ConditionalExpression";
SyntaxKind[SyntaxKind["TemplateExpression"] = 194] = "TemplateExpression";
SyntaxKind[SyntaxKind["YieldExpression"] = 195] = "YieldExpression";
SyntaxKind[SyntaxKind["SpreadElement"] = 196] = "SpreadElement";
SyntaxKind[SyntaxKind["ClassExpression"] = 197] = "ClassExpression";
SyntaxKind[SyntaxKind["OmittedExpression"] = 198] = "OmittedExpression";
SyntaxKind[SyntaxKind["ExpressionWithTypeArguments"] = 199] = "ExpressionWithTypeArguments";
SyntaxKind[SyntaxKind["AsExpression"] = 200] = "AsExpression";
SyntaxKind[SyntaxKind["NonNullExpression"] = 201] = "NonNullExpression";
// Misc
SyntaxKind[SyntaxKind["TemplateSpan"] = 202] = "TemplateSpan";
SyntaxKind[SyntaxKind["SemicolonClassElement"] = 203] = "SemicolonClassElement";
// Element
SyntaxKind[SyntaxKind["Block"] = 204] = "Block";
SyntaxKind[SyntaxKind["VariableStatement"] = 205] = "VariableStatement";
SyntaxKind[SyntaxKind["EmptyStatement"] = 206] = "EmptyStatement";
SyntaxKind[SyntaxKind["ExpressionStatement"] = 207] = "ExpressionStatement";
SyntaxKind[SyntaxKind["IfStatement"] = 208] = "IfStatement";
SyntaxKind[SyntaxKind["DoStatement"] = 209] = "DoStatement";
SyntaxKind[SyntaxKind["WhileStatement"] = 210] = "WhileStatement";
SyntaxKind[SyntaxKind["ForStatement"] = 211] = "ForStatement";
SyntaxKind[SyntaxKind["ForInStatement"] = 212] = "ForInStatement";
SyntaxKind[SyntaxKind["ForOfStatement"] = 213] = "ForOfStatement";
SyntaxKind[SyntaxKind["ContinueStatement"] = 214] = "ContinueStatement";
SyntaxKind[SyntaxKind["BreakStatement"] = 215] = "BreakStatement";
SyntaxKind[SyntaxKind["ReturnStatement"] = 216] = "ReturnStatement";
SyntaxKind[SyntaxKind["WithStatement"] = 217] = "WithStatement";
SyntaxKind[SyntaxKind["SwitchStatement"] = 218] = "SwitchStatement";
SyntaxKind[SyntaxKind["LabeledStatement"] = 219] = "LabeledStatement";
SyntaxKind[SyntaxKind["ThrowStatement"] = 220] = "ThrowStatement";
SyntaxKind[SyntaxKind["TryStatement"] = 221] = "TryStatement";
SyntaxKind[SyntaxKind["DebuggerStatement"] = 222] = "DebuggerStatement";
SyntaxKind[SyntaxKind["VariableDeclaration"] = 223] = "VariableDeclaration";
SyntaxKind[SyntaxKind["VariableDeclarationList"] = 224] = "VariableDeclarationList";
SyntaxKind[SyntaxKind["FunctionDeclaration"] = 225] = "FunctionDeclaration";
SyntaxKind[SyntaxKind["ClassDeclaration"] = 226] = "ClassDeclaration";
SyntaxKind[SyntaxKind["InterfaceDeclaration"] = 227] = "InterfaceDeclaration";
SyntaxKind[SyntaxKind["TypeAliasDeclaration"] = 228] = "TypeAliasDeclaration";
SyntaxKind[SyntaxKind["EnumDeclaration"] = 229] = "EnumDeclaration";
SyntaxKind[SyntaxKind["ModuleDeclaration"] = 230] = "ModuleDeclaration";
SyntaxKind[SyntaxKind["ModuleBlock"] = 231] = "ModuleBlock";
SyntaxKind[SyntaxKind["CaseBlock"] = 232] = "CaseBlock";
SyntaxKind[SyntaxKind["NamespaceExportDeclaration"] = 233] = "NamespaceExportDeclaration";
SyntaxKind[SyntaxKind["ImportEqualsDeclaration"] = 234] = "ImportEqualsDeclaration";
SyntaxKind[SyntaxKind["ImportDeclaration"] = 235] = "ImportDeclaration";
SyntaxKind[SyntaxKind["ImportClause"] = 236] = "ImportClause";
SyntaxKind[SyntaxKind["NamespaceImport"] = 237] = "NamespaceImport";
SyntaxKind[SyntaxKind["NamedImports"] = 238] = "NamedImports";
SyntaxKind[SyntaxKind["ImportSpecifier"] = 239] = "ImportSpecifier";
SyntaxKind[SyntaxKind["ExportAssignment"] = 240] = "ExportAssignment";
SyntaxKind[SyntaxKind["ExportDeclaration"] = 241] = "ExportDeclaration";
SyntaxKind[SyntaxKind["NamedExports"] = 242] = "NamedExports";
SyntaxKind[SyntaxKind["ExportSpecifier"] = 243] = "ExportSpecifier";
SyntaxKind[SyntaxKind["MissingDeclaration"] = 244] = "MissingDeclaration";
// Module references
SyntaxKind[SyntaxKind["ExternalModuleReference"] = 245] = "ExternalModuleReference";
// JSX
SyntaxKind[SyntaxKind["JsxElement"] = 246] = "JsxElement";
SyntaxKind[SyntaxKind["JsxSelfClosingElement"] = 247] = "JsxSelfClosingElement";
SyntaxKind[SyntaxKind["JsxOpeningElement"] = 248] = "JsxOpeningElement";
SyntaxKind[SyntaxKind["JsxClosingElement"] = 249] = "JsxClosingElement";
SyntaxKind[SyntaxKind["JsxAttribute"] = 250] = "JsxAttribute";
SyntaxKind[SyntaxKind["JsxSpreadAttribute"] = 251] = "JsxSpreadAttribute";
SyntaxKind[SyntaxKind["JsxExpression"] = 252] = "JsxExpression";
// Clauses
SyntaxKind[SyntaxKind["CaseClause"] = 253] = "CaseClause";
SyntaxKind[SyntaxKind["DefaultClause"] = 254] = "DefaultClause";
SyntaxKind[SyntaxKind["HeritageClause"] = 255] = "HeritageClause";
SyntaxKind[SyntaxKind["CatchClause"] = 256] = "CatchClause";
// Property assignments
SyntaxKind[SyntaxKind["PropertyAssignment"] = 257] = "PropertyAssignment";
SyntaxKind[SyntaxKind["ShorthandPropertyAssignment"] = 258] = "ShorthandPropertyAssignment";
SyntaxKind[SyntaxKind["SpreadAssignment"] = 259] = "SpreadAssignment";
// Enum
SyntaxKind[SyntaxKind["EnumMember"] = 260] = "EnumMember";
// Top-level nodes
SyntaxKind[SyntaxKind["SourceFile"] = 261] = "SourceFile";
// JSDoc nodes
SyntaxKind[SyntaxKind["JSDocTypeExpression"] = 262] = "JSDocTypeExpression";
// The * type
SyntaxKind[SyntaxKind["JSDocAllType"] = 263] = "JSDocAllType";
// The ? type
SyntaxKind[SyntaxKind["JSDocUnknownType"] = 264] = "JSDocUnknownType";
SyntaxKind[SyntaxKind["JSDocArrayType"] = 265] = "JSDocArrayType";
SyntaxKind[SyntaxKind["JSDocUnionType"] = 266] = "JSDocUnionType";
SyntaxKind[SyntaxKind["JSDocTupleType"] = 267] = "JSDocTupleType";
SyntaxKind[SyntaxKind["JSDocNullableType"] = 268] = "JSDocNullableType";
SyntaxKind[SyntaxKind["JSDocNonNullableType"] = 269] = "JSDocNonNullableType";
SyntaxKind[SyntaxKind["JSDocRecordType"] = 270] = "JSDocRecordType";
SyntaxKind[SyntaxKind["JSDocRecordMember"] = 271] = "JSDocRecordMember";
SyntaxKind[SyntaxKind["JSDocTypeReference"] = 272] = "JSDocTypeReference";
SyntaxKind[SyntaxKind["JSDocOptionalType"] = 273] = "JSDocOptionalType";
SyntaxKind[SyntaxKind["JSDocFunctionType"] = 274] = "JSDocFunctionType";
SyntaxKind[SyntaxKind["JSDocVariadicType"] = 275] = "JSDocVariadicType";
SyntaxKind[SyntaxKind["JSDocConstructorType"] = 276] = "JSDocConstructorType";
SyntaxKind[SyntaxKind["JSDocThisType"] = 277] = "JSDocThisType";
SyntaxKind[SyntaxKind["JSDocComment"] = 278] = "JSDocComment";
SyntaxKind[SyntaxKind["JSDocTag"] = 279] = "JSDocTag";
SyntaxKind[SyntaxKind["JSDocParameterTag"] = 280] = "JSDocParameterTag";
SyntaxKind[SyntaxKind["JSDocReturnTag"] = 281] = "JSDocReturnTag";
SyntaxKind[SyntaxKind["JSDocTypeTag"] = 282] = "JSDocTypeTag";
SyntaxKind[SyntaxKind["JSDocTemplateTag"] = 283] = "JSDocTemplateTag";
SyntaxKind[SyntaxKind["JSDocTypedefTag"] = 284] = "JSDocTypedefTag";
SyntaxKind[SyntaxKind["JSDocPropertyTag"] = 285] = "JSDocPropertyTag";
SyntaxKind[SyntaxKind["JSDocTypeLiteral"] = 286] = "JSDocTypeLiteral";
SyntaxKind[SyntaxKind["JSDocLiteralType"] = 287] = "JSDocLiteralType";
SyntaxKind[SyntaxKind["JSDocNullKeyword"] = 288] = "JSDocNullKeyword";
SyntaxKind[SyntaxKind["JSDocUndefinedKeyword"] = 289] = "JSDocUndefinedKeyword";
SyntaxKind[SyntaxKind["JSDocNeverKeyword"] = 290] = "JSDocNeverKeyword";
// Synthesized list
SyntaxKind[SyntaxKind["SyntaxList"] = 291] = "SyntaxList";
// Transformation nodes
SyntaxKind[SyntaxKind["NotEmittedStatement"] = 292] = "NotEmittedStatement";
SyntaxKind[SyntaxKind["PartiallyEmittedExpression"] = 293] = "PartiallyEmittedExpression";
SyntaxKind[SyntaxKind["MergeDeclarationMarker"] = 294] = "MergeDeclarationMarker";
SyntaxKind[SyntaxKind["EndOfDeclarationMarker"] = 295] = "EndOfDeclarationMarker";
// Enum value count
SyntaxKind[SyntaxKind["Count"] = 296] = "Count";
// Markers
SyntaxKind[SyntaxKind["FirstAssignment"] = 57] = "FirstAssignment";
SyntaxKind[SyntaxKind["LastAssignment"] = 69] = "LastAssignment";
SyntaxKind[SyntaxKind["FirstCompoundAssignment"] = 58] = "FirstCompoundAssignment";
SyntaxKind[SyntaxKind["LastCompoundAssignment"] = 69] = "LastCompoundAssignment";
SyntaxKind[SyntaxKind["FirstReservedWord"] = 71] = "FirstReservedWord";
SyntaxKind[SyntaxKind["LastReservedWord"] = 106] = "LastReservedWord";
SyntaxKind[SyntaxKind["FirstKeyword"] = 71] = "FirstKeyword";
SyntaxKind[SyntaxKind["LastKeyword"] = 140] = "LastKeyword";
SyntaxKind[SyntaxKind["FirstFutureReservedWord"] = 107] = "FirstFutureReservedWord";
SyntaxKind[SyntaxKind["LastFutureReservedWord"] = 115] = "LastFutureReservedWord";
SyntaxKind[SyntaxKind["FirstTypeNode"] = 156] = "FirstTypeNode";
SyntaxKind[SyntaxKind["LastTypeNode"] = 171] = "LastTypeNode";
SyntaxKind[SyntaxKind["FirstPunctuation"] = 16] = "FirstPunctuation";
SyntaxKind[SyntaxKind["LastPunctuation"] = 69] = "LastPunctuation";
SyntaxKind[SyntaxKind["FirstToken"] = 0] = "FirstToken";
SyntaxKind[SyntaxKind["LastToken"] = 140] = "LastToken";
SyntaxKind[SyntaxKind["FirstTriviaToken"] = 2] = "FirstTriviaToken";
SyntaxKind[SyntaxKind["LastTriviaToken"] = 7] = "LastTriviaToken";
SyntaxKind[SyntaxKind["FirstLiteralToken"] = 8] = "FirstLiteralToken";
SyntaxKind[SyntaxKind["LastLiteralToken"] = 12] = "LastLiteralToken";
SyntaxKind[SyntaxKind["FirstTemplateToken"] = 12] = "FirstTemplateToken";
SyntaxKind[SyntaxKind["LastTemplateToken"] = 15] = "LastTemplateToken";
SyntaxKind[SyntaxKind["FirstBinaryOperator"] = 26] = "FirstBinaryOperator";
SyntaxKind[SyntaxKind["LastBinaryOperator"] = 69] = "LastBinaryOperator";
SyntaxKind[SyntaxKind["FirstNode"] = 141] = "FirstNode";
SyntaxKind[SyntaxKind["FirstJSDocNode"] = 262] = "FirstJSDocNode";
SyntaxKind[SyntaxKind["LastJSDocNode"] = 287] = "LastJSDocNode";
SyntaxKind[SyntaxKind["FirstJSDocTagNode"] = 278] = "FirstJSDocTagNode";
SyntaxKind[SyntaxKind["LastJSDocTagNode"] = 290] = "LastJSDocTagNode";
})(SyntaxKind = ts.SyntaxKind || (ts.SyntaxKind = {}));
var NodeFlags;
(function (NodeFlags) {
NodeFlags[NodeFlags["None"] = 0] = "None";
NodeFlags[NodeFlags["Let"] = 1] = "Let";
NodeFlags[NodeFlags["Const"] = 2] = "Const";
NodeFlags[NodeFlags["NestedNamespace"] = 4] = "NestedNamespace";
NodeFlags[NodeFlags["Synthesized"] = 8] = "Synthesized";
NodeFlags[NodeFlags["Namespace"] = 16] = "Namespace";
NodeFlags[NodeFlags["ExportContext"] = 32] = "ExportContext";
NodeFlags[NodeFlags["ContainsThis"] = 64] = "ContainsThis";
NodeFlags[NodeFlags["HasImplicitReturn"] = 128] = "HasImplicitReturn";
NodeFlags[NodeFlags["HasExplicitReturn"] = 256] = "HasExplicitReturn";
NodeFlags[NodeFlags["GlobalAugmentation"] = 512] = "GlobalAugmentation";
NodeFlags[NodeFlags["HasClassExtends"] = 1024] = "HasClassExtends";
NodeFlags[NodeFlags["HasDecorators"] = 2048] = "HasDecorators";
NodeFlags[NodeFlags["HasParamDecorators"] = 4096] = "HasParamDecorators";
NodeFlags[NodeFlags["HasAsyncFunctions"] = 8192] = "HasAsyncFunctions";
NodeFlags[NodeFlags["HasSpreadAttribute"] = 16384] = "HasSpreadAttribute";
NodeFlags[NodeFlags["HasRestAttribute"] = 32768] = "HasRestAttribute";
NodeFlags[NodeFlags["DisallowInContext"] = 65536] = "DisallowInContext";
NodeFlags[NodeFlags["YieldContext"] = 131072] = "YieldContext";
NodeFlags[NodeFlags["DecoratorContext"] = 262144] = "DecoratorContext";
NodeFlags[NodeFlags["AwaitContext"] = 524288] = "AwaitContext";
NodeFlags[NodeFlags["ThisNodeHasError"] = 1048576] = "ThisNodeHasError";
NodeFlags[NodeFlags["JavaScriptFile"] = 2097152] = "JavaScriptFile";
NodeFlags[NodeFlags["ThisNodeOrAnySubNodesHasError"] = 4194304] = "ThisNodeOrAnySubNodesHasError";
NodeFlags[NodeFlags["HasAggregatedChildData"] = 8388608] = "HasAggregatedChildData";
NodeFlags[NodeFlags["BlockScoped"] = 3] = "BlockScoped";
NodeFlags[NodeFlags["ReachabilityCheckFlags"] = 384] = "ReachabilityCheckFlags";
NodeFlags[NodeFlags["EmitHelperFlags"] = 64512] = "EmitHelperFlags";
NodeFlags[NodeFlags["ReachabilityAndEmitFlags"] = 64896] = "ReachabilityAndEmitFlags";
// Parsing context flags
NodeFlags[NodeFlags["ContextFlags"] = 3080192] = "ContextFlags";
// Exclude these flags when parsing a Type
NodeFlags[NodeFlags["TypeExcludesFlags"] = 655360] = "TypeExcludesFlags";
})(NodeFlags = ts.NodeFlags || (ts.NodeFlags = {}));
var ModifierFlags;
(function (ModifierFlags) {
ModifierFlags[ModifierFlags["None"] = 0] = "None";
ModifierFlags[ModifierFlags["Export"] = 1] = "Export";
ModifierFlags[ModifierFlags["Ambient"] = 2] = "Ambient";
ModifierFlags[ModifierFlags["Public"] = 4] = "Public";
ModifierFlags[ModifierFlags["Private"] = 8] = "Private";
ModifierFlags[ModifierFlags["Protected"] = 16] = "Protected";
ModifierFlags[ModifierFlags["Static"] = 32] = "Static";
ModifierFlags[ModifierFlags["Readonly"] = 64] = "Readonly";
ModifierFlags[ModifierFlags["Abstract"] = 128] = "Abstract";
ModifierFlags[ModifierFlags["Async"] = 256] = "Async";
ModifierFlags[ModifierFlags["Default"] = 512] = "Default";
ModifierFlags[ModifierFlags["Const"] = 2048] = "Const";
ModifierFlags[ModifierFlags["HasComputedFlags"] = 536870912] = "HasComputedFlags";
ModifierFlags[ModifierFlags["AccessibilityModifier"] = 28] = "AccessibilityModifier";
// Accessibility modifiers and 'readonly' can be attached to a parameter in a constructor to make it a property.
ModifierFlags[ModifierFlags["ParameterPropertyModifier"] = 92] = "ParameterPropertyModifier";
ModifierFlags[ModifierFlags["NonPublicAccessibilityModifier"] = 24] = "NonPublicAccessibilityModifier";
ModifierFlags[ModifierFlags["TypeScriptModifier"] = 2270] = "TypeScriptModifier";
ModifierFlags[ModifierFlags["ExportDefault"] = 513] = "ExportDefault";
})(ModifierFlags = ts.ModifierFlags || (ts.ModifierFlags = {}));
var JsxFlags;
(function (JsxFlags) {
JsxFlags[JsxFlags["None"] = 0] = "None";
/** An element from a named property of the JSX.IntrinsicElements interface */
JsxFlags[JsxFlags["IntrinsicNamedElement"] = 1] = "IntrinsicNamedElement";
/** An element inferred from the string index signature of the JSX.IntrinsicElements interface */
JsxFlags[JsxFlags["IntrinsicIndexedElement"] = 2] = "IntrinsicIndexedElement";
JsxFlags[JsxFlags["IntrinsicElement"] = 3] = "IntrinsicElement";
})(JsxFlags = ts.JsxFlags || (ts.JsxFlags = {}));
/* @internal */
var RelationComparisonResult;
(function (RelationComparisonResult) {
RelationComparisonResult[RelationComparisonResult["Succeeded"] = 1] = "Succeeded";
RelationComparisonResult[RelationComparisonResult["Failed"] = 2] = "Failed";
RelationComparisonResult[RelationComparisonResult["FailedAndReported"] = 3] = "FailedAndReported";
})(RelationComparisonResult = ts.RelationComparisonResult || (ts.RelationComparisonResult = {}));
/*@internal*/
var GeneratedIdentifierKind;
(function (GeneratedIdentifierKind) {
GeneratedIdentifierKind[GeneratedIdentifierKind["None"] = 0] = "None";
GeneratedIdentifierKind[GeneratedIdentifierKind["Auto"] = 1] = "Auto";
GeneratedIdentifierKind[GeneratedIdentifierKind["Loop"] = 2] = "Loop";
GeneratedIdentifierKind[GeneratedIdentifierKind["Unique"] = 3] = "Unique";
GeneratedIdentifierKind[GeneratedIdentifierKind["Node"] = 4] = "Node";
})(GeneratedIdentifierKind = ts.GeneratedIdentifierKind || (ts.GeneratedIdentifierKind = {}));
var FlowFlags;
(function (FlowFlags) {
FlowFlags[FlowFlags["Unreachable"] = 1] = "Unreachable";
FlowFlags[FlowFlags["Start"] = 2] = "Start";
FlowFlags[FlowFlags["BranchLabel"] = 4] = "BranchLabel";
FlowFlags[FlowFlags["LoopLabel"] = 8] = "LoopLabel";
FlowFlags[FlowFlags["Assignment"] = 16] = "Assignment";
FlowFlags[FlowFlags["TrueCondition"] = 32] = "TrueCondition";
FlowFlags[FlowFlags["FalseCondition"] = 64] = "FalseCondition";
FlowFlags[FlowFlags["SwitchClause"] = 128] = "SwitchClause";
FlowFlags[FlowFlags["ArrayMutation"] = 256] = "ArrayMutation";
FlowFlags[FlowFlags["Referenced"] = 512] = "Referenced";
FlowFlags[FlowFlags["Shared"] = 1024] = "Shared";
FlowFlags[FlowFlags["Label"] = 12] = "Label";
FlowFlags[FlowFlags["Condition"] = 96] = "Condition";
})(FlowFlags = ts.FlowFlags || (ts.FlowFlags = {}));
var OperationCanceledException = (function () {
function OperationCanceledException() {
}
return OperationCanceledException;
}());
ts.OperationCanceledException = OperationCanceledException;
/** Return code used by getEmitOutput function to indicate status of the function */
var ExitStatus;
(function (ExitStatus) {
// Compiler ran successfully. Either this was a simple do-nothing compilation (for example,
// when -version or -help was provided, or this was a normal compilation, no diagnostics
// were produced, and all outputs were generated successfully.
ExitStatus[ExitStatus["Success"] = 0] = "Success";
// Diagnostics were produced and because of them no code was generated.
ExitStatus[ExitStatus["DiagnosticsPresent_OutputsSkipped"] = 1] = "DiagnosticsPresent_OutputsSkipped";
// Diagnostics were produced and outputs were generated in spite of them.
ExitStatus[ExitStatus["DiagnosticsPresent_OutputsGenerated"] = 2] = "DiagnosticsPresent_OutputsGenerated";
})(ExitStatus = ts.ExitStatus || (ts.ExitStatus = {}));
var TypeFormatFlags;
(function (TypeFormatFlags) {
TypeFormatFlags[TypeFormatFlags["None"] = 0] = "None";
TypeFormatFlags[TypeFormatFlags["WriteArrayAsGenericType"] = 1] = "WriteArrayAsGenericType";
TypeFormatFlags[TypeFormatFlags["UseTypeOfFunction"] = 2] = "UseTypeOfFunction";
TypeFormatFlags[TypeFormatFlags["NoTruncation"] = 4] = "NoTruncation";
TypeFormatFlags[TypeFormatFlags["WriteArrowStyleSignature"] = 8] = "WriteArrowStyleSignature";
TypeFormatFlags[TypeFormatFlags["WriteOwnNameForAnyLike"] = 16] = "WriteOwnNameForAnyLike";
TypeFormatFlags[TypeFormatFlags["WriteTypeArgumentsOfSignature"] = 32] = "WriteTypeArgumentsOfSignature";
TypeFormatFlags[TypeFormatFlags["InElementType"] = 64] = "InElementType";
TypeFormatFlags[TypeFormatFlags["UseFullyQualifiedType"] = 128] = "UseFullyQualifiedType";
TypeFormatFlags[TypeFormatFlags["InFirstTypeArgument"] = 256] = "InFirstTypeArgument";
TypeFormatFlags[TypeFormatFlags["InTypeAlias"] = 512] = "InTypeAlias";
TypeFormatFlags[TypeFormatFlags["UseTypeAliasValue"] = 1024] = "UseTypeAliasValue";
})(TypeFormatFlags = ts.TypeFormatFlags || (ts.TypeFormatFlags = {}));
var SymbolFormatFlags;
(function (SymbolFormatFlags) {
SymbolFormatFlags[SymbolFormatFlags["None"] = 0] = "None";
// Write symbols's type argument if it is instantiated symbol
// eg. class C<T> { p: T } <-- Show p as C<T>.p here
// var a: C<number>;
// var p = a.p; <--- Here p is property of C<number> so show it as C<number>.p instead of just C.p
SymbolFormatFlags[SymbolFormatFlags["WriteTypeParametersOrArguments"] = 1] = "WriteTypeParametersOrArguments";
// Use only external alias information to get the symbol name in the given context
// eg. module m { export class c { } } import x = m.c;
// When this flag is specified m.c will be used to refer to the class instead of alias symbol x
SymbolFormatFlags[SymbolFormatFlags["UseOnlyExternalAliasing"] = 2] = "UseOnlyExternalAliasing";
})(SymbolFormatFlags = ts.SymbolFormatFlags || (ts.SymbolFormatFlags = {}));
/* @internal */
var SymbolAccessibility;
(function (SymbolAccessibility) {
SymbolAccessibility[SymbolAccessibility["Accessible"] = 0] = "Accessible";
SymbolAccessibility[SymbolAccessibility["NotAccessible"] = 1] = "NotAccessible";
SymbolAccessibility[SymbolAccessibility["CannotBeNamed"] = 2] = "CannotBeNamed";
})(SymbolAccessibility = ts.SymbolAccessibility || (ts.SymbolAccessibility = {}));
/* @internal */
var SyntheticSymbolKind;
(function (SyntheticSymbolKind) {
SyntheticSymbolKind[SyntheticSymbolKind["UnionOrIntersection"] = 0] = "UnionOrIntersection";
SyntheticSymbolKind[SyntheticSymbolKind["Spread"] = 1] = "Spread";
})(SyntheticSymbolKind = ts.SyntheticSymbolKind || (ts.SyntheticSymbolKind = {}));
var TypePredicateKind;
(function (TypePredicateKind) {
TypePredicateKind[TypePredicateKind["This"] = 0] = "This";
TypePredicateKind[TypePredicateKind["Identifier"] = 1] = "Identifier";
})(TypePredicateKind = ts.TypePredicateKind || (ts.TypePredicateKind = {}));
/** Indicates how to serialize the name for a TypeReferenceNode when emitting decorator
* metadata */
/* @internal */
var TypeReferenceSerializationKind;
(function (TypeReferenceSerializationKind) {
TypeReferenceSerializationKind[TypeReferenceSerializationKind["Unknown"] = 0] = "Unknown";
// should be emitted using a safe fallback.
TypeReferenceSerializationKind[TypeReferenceSerializationKind["TypeWithConstructSignatureAndValue"] = 1] = "TypeWithConstructSignatureAndValue";
// function that can be reached at runtime (e.g. a `class`
// declaration or a `var` declaration for the static side
// of a type, such as the global `Promise` type in lib.d.ts).
TypeReferenceSerializationKind[TypeReferenceSerializationKind["VoidNullableOrNeverType"] = 2] = "VoidNullableOrNeverType";
TypeReferenceSerializationKind[TypeReferenceSerializationKind["NumberLikeType"] = 3] = "NumberLikeType";
TypeReferenceSerializationKind[TypeReferenceSerializationKind["StringLikeType"] = 4] = "StringLikeType";
TypeReferenceSerializationKind[TypeReferenceSerializationKind["BooleanType"] = 5] = "BooleanType";
TypeReferenceSerializationKind[TypeReferenceSerializationKind["ArrayLikeType"] = 6] = "ArrayLikeType";
TypeReferenceSerializationKind[TypeReferenceSerializationKind["ESSymbolType"] = 7] = "ESSymbolType";
TypeReferenceSerializationKind[TypeReferenceSerializationKind["Promise"] = 8] = "Promise";
TypeReferenceSerializationKind[TypeReferenceSerializationKind["TypeWithCallSignature"] = 9] = "TypeWithCallSignature";
// with call signatures.
TypeReferenceSerializationKind[TypeReferenceSerializationKind["ObjectType"] = 10] = "ObjectType";
})(TypeReferenceSerializationKind = ts.TypeReferenceSerializationKind || (ts.TypeReferenceSerializationKind = {}));
var SymbolFlags;
(function (SymbolFlags) {
SymbolFlags[SymbolFlags["None"] = 0] = "None";
SymbolFlags[SymbolFlags["FunctionScopedVariable"] = 1] = "FunctionScopedVariable";
SymbolFlags[SymbolFlags["BlockScopedVariable"] = 2] = "BlockScopedVariable";
SymbolFlags[SymbolFlags["Property"] = 4] = "Property";
SymbolFlags[SymbolFlags["EnumMember"] = 8] = "EnumMember";
SymbolFlags[SymbolFlags["Function"] = 16] = "Function";
SymbolFlags[SymbolFlags["Class"] = 32] = "Class";
SymbolFlags[SymbolFlags["Interface"] = 64] = "Interface";
SymbolFlags[SymbolFlags["ConstEnum"] = 128] = "ConstEnum";
SymbolFlags[SymbolFlags["RegularEnum"] = 256] = "RegularEnum";
SymbolFlags[SymbolFlags["ValueModule"] = 512] = "ValueModule";
SymbolFlags[SymbolFlags["NamespaceModule"] = 1024] = "NamespaceModule";
SymbolFlags[SymbolFlags["TypeLiteral"] = 2048] = "TypeLiteral";
SymbolFlags[SymbolFlags["ObjectLiteral"] = 4096] = "ObjectLiteral";
SymbolFlags[SymbolFlags["Method"] = 8192] = "Method";
SymbolFlags[SymbolFlags["Constructor"] = 16384] = "Constructor";
SymbolFlags[SymbolFlags["GetAccessor"] = 32768] = "GetAccessor";
SymbolFlags[SymbolFlags["SetAccessor"] = 65536] = "SetAccessor";
SymbolFlags[SymbolFlags["Signature"] = 131072] = "Signature";
SymbolFlags[SymbolFlags["TypeParameter"] = 262144] = "TypeParameter";
SymbolFlags[SymbolFlags["TypeAlias"] = 524288] = "TypeAlias";
SymbolFlags[SymbolFlags["ExportValue"] = 1048576] = "ExportValue";
SymbolFlags[SymbolFlags["ExportType"] = 2097152] = "ExportType";
SymbolFlags[SymbolFlags["ExportNamespace"] = 4194304] = "ExportNamespace";
SymbolFlags[SymbolFlags["Alias"] = 8388608] = "Alias";
SymbolFlags[SymbolFlags["Instantiated"] = 16777216] = "Instantiated";
SymbolFlags[SymbolFlags["Merged"] = 33554432] = "Merged";
SymbolFlags[SymbolFlags["Transient"] = 67108864] = "Transient";
SymbolFlags[SymbolFlags["Prototype"] = 134217728] = "Prototype";
SymbolFlags[SymbolFlags["SyntheticProperty"] = 268435456] = "SyntheticProperty";
SymbolFlags[SymbolFlags["Optional"] = 536870912] = "Optional";
SymbolFlags[SymbolFlags["ExportStar"] = 1073741824] = "ExportStar";
SymbolFlags[SymbolFlags["Enum"] = 384] = "Enum";
SymbolFlags[SymbolFlags["Variable"] = 3] = "Variable";
SymbolFlags[SymbolFlags["Value"] = 107455] = "Value";
SymbolFlags[SymbolFlags["Type"] = 793064] = "Type";
SymbolFlags[SymbolFlags["Namespace"] = 1920] = "Namespace";
SymbolFlags[SymbolFlags["Module"] = 1536] = "Module";
SymbolFlags[SymbolFlags["Accessor"] = 98304] = "Accessor";
// Variables can be redeclared, but can not redeclare a block-scoped declaration with the
// same name, or any other value that is not a variable, e.g. ValueModule or Class
SymbolFlags[SymbolFlags["FunctionScopedVariableExcludes"] = 107454] = "FunctionScopedVariableExcludes";
// Block-scoped declarations are not allowed to be re-declared
// they can not merge with anything in the value space
SymbolFlags[SymbolFlags["BlockScopedVariableExcludes"] = 107455] = "BlockScopedVariableExcludes";
SymbolFlags[SymbolFlags["ParameterExcludes"] = 107455] = "ParameterExcludes";
SymbolFlags[SymbolFlags["PropertyExcludes"] = 0] = "PropertyExcludes";
SymbolFlags[SymbolFlags["EnumMemberExcludes"] = 900095] = "EnumMemberExcludes";
SymbolFlags[SymbolFlags["FunctionExcludes"] = 106927] = "FunctionExcludes";
SymbolFlags[SymbolFlags["ClassExcludes"] = 899519] = "ClassExcludes";
SymbolFlags[SymbolFlags["InterfaceExcludes"] = 792968] = "InterfaceExcludes";
SymbolFlags[SymbolFlags["RegularEnumExcludes"] = 899327] = "RegularEnumExcludes";
SymbolFlags[SymbolFlags["ConstEnumExcludes"] = 899967] = "ConstEnumExcludes";
SymbolFlags[SymbolFlags["ValueModuleExcludes"] = 106639] = "ValueModuleExcludes";
SymbolFlags[SymbolFlags["NamespaceModuleExcludes"] = 0] = "NamespaceModuleExcludes";
SymbolFlags[SymbolFlags["MethodExcludes"] = 99263] = "MethodExcludes";
SymbolFlags[SymbolFlags["GetAccessorExcludes"] = 41919] = "GetAccessorExcludes";
SymbolFlags[SymbolFlags["SetAccessorExcludes"] = 74687] = "SetAccessorExcludes";
SymbolFlags[SymbolFlags["TypeParameterExcludes"] = 530920] = "TypeParameterExcludes";
SymbolFlags[SymbolFlags["TypeAliasExcludes"] = 793064] = "TypeAliasExcludes";
SymbolFlags[SymbolFlags["AliasExcludes"] = 8388608] = "AliasExcludes";
SymbolFlags[SymbolFlags["ModuleMember"] = 8914931] = "ModuleMember";
SymbolFlags[SymbolFlags["ExportHasLocal"] = 944] = "ExportHasLocal";
SymbolFlags[SymbolFlags["HasExports"] = 1952] = "HasExports";
SymbolFlags[SymbolFlags["HasMembers"] = 6240] = "HasMembers";
SymbolFlags[SymbolFlags["BlockScoped"] = 418] = "BlockScoped";
SymbolFlags[SymbolFlags["PropertyOrAccessor"] = 98308] = "PropertyOrAccessor";
SymbolFlags[SymbolFlags["Export"] = 7340032] = "Export";
SymbolFlags[SymbolFlags["ClassMember"] = 106500] = "ClassMember";
/* @internal */
// The set of things we consider semantically classifiable. Used to speed up the LS during
// classification.
SymbolFlags[SymbolFlags["Classifiable"] = 788448] = "Classifiable";
})(SymbolFlags = ts.SymbolFlags || (ts.SymbolFlags = {}));
/* @internal */
var NodeCheckFlags;
(function (NodeCheckFlags) {
NodeCheckFlags[NodeCheckFlags["TypeChecked"] = 1] = "TypeChecked";
NodeCheckFlags[NodeCheckFlags["LexicalThis"] = 2] = "LexicalThis";
NodeCheckFlags[NodeCheckFlags["CaptureThis"] = 4] = "CaptureThis";
NodeCheckFlags[NodeCheckFlags["SuperInstance"] = 256] = "SuperInstance";
NodeCheckFlags[NodeCheckFlags["SuperStatic"] = 512] = "SuperStatic";
NodeCheckFlags[NodeCheckFlags["ContextChecked"] = 1024] = "ContextChecked";
NodeCheckFlags[NodeCheckFlags["AsyncMethodWithSuper"] = 2048] = "AsyncMethodWithSuper";
NodeCheckFlags[NodeCheckFlags["AsyncMethodWithSuperBinding"] = 4096] = "AsyncMethodWithSuperBinding";
NodeCheckFlags[NodeCheckFlags["CaptureArguments"] = 8192] = "CaptureArguments";
NodeCheckFlags[NodeCheckFlags["EnumValuesComputed"] = 16384] = "EnumValuesComputed";
NodeCheckFlags[NodeCheckFlags["LexicalModuleMergesWithClass"] = 32768] = "LexicalModuleMergesWithClass";
NodeCheckFlags[NodeCheckFlags["LoopWithCapturedBlockScopedBinding"] = 65536] = "LoopWithCapturedBlockScopedBinding";
NodeCheckFlags[NodeCheckFlags["CapturedBlockScopedBinding"] = 131072] = "CapturedBlockScopedBinding";
NodeCheckFlags[NodeCheckFlags["BlockScopedBindingInLoop"] = 262144] = "BlockScopedBindingInLoop";
NodeCheckFlags[NodeCheckFlags["ClassWithBodyScopedClassBinding"] = 524288] = "ClassWithBodyScopedClassBinding";
NodeCheckFlags[NodeCheckFlags["BodyScopedClassBinding"] = 1048576] = "BodyScopedClassBinding";
NodeCheckFlags[NodeCheckFlags["NeedsLoopOutParameter"] = 2097152] = "NeedsLoopOutParameter";
NodeCheckFlags[NodeCheckFlags["AssignmentsMarked"] = 4194304] = "AssignmentsMarked";
NodeCheckFlags[NodeCheckFlags["ClassWithConstructorReference"] = 8388608] = "ClassWithConstructorReference";
NodeCheckFlags[NodeCheckFlags["ConstructorReferenceInClass"] = 16777216] = "ConstructorReferenceInClass";
})(NodeCheckFlags = ts.NodeCheckFlags || (ts.NodeCheckFlags = {}));
var TypeFlags;
(function (TypeFlags) {
TypeFlags[TypeFlags["Any"] = 1] = "Any";
TypeFlags[TypeFlags["String"] = 2] = "String";
TypeFlags[TypeFlags["Number"] = 4] = "Number";
TypeFlags[TypeFlags["Boolean"] = 8] = "Boolean";
TypeFlags[TypeFlags["Enum"] = 16] = "Enum";
TypeFlags[TypeFlags["StringLiteral"] = 32] = "StringLiteral";
TypeFlags[TypeFlags["NumberLiteral"] = 64] = "NumberLiteral";
TypeFlags[TypeFlags["BooleanLiteral"] = 128] = "BooleanLiteral";
TypeFlags[TypeFlags["EnumLiteral"] = 256] = "EnumLiteral";
TypeFlags[TypeFlags["ESSymbol"] = 512] = "ESSymbol";
TypeFlags[TypeFlags["Void"] = 1024] = "Void";
TypeFlags[TypeFlags["Undefined"] = 2048] = "Undefined";
TypeFlags[TypeFlags["Null"] = 4096] = "Null";
TypeFlags[TypeFlags["Never"] = 8192] = "Never";
TypeFlags[TypeFlags["TypeParameter"] = 16384] = "TypeParameter";
TypeFlags[TypeFlags["Object"] = 32768] = "Object";
TypeFlags[TypeFlags["Union"] = 65536] = "Union";
TypeFlags[TypeFlags["Intersection"] = 131072] = "Intersection";
TypeFlags[TypeFlags["Index"] = 262144] = "Index";
TypeFlags[TypeFlags["IndexedAccess"] = 524288] = "IndexedAccess";
/* @internal */
TypeFlags[TypeFlags["FreshLiteral"] = 1048576] = "FreshLiteral";
/* @internal */
TypeFlags[TypeFlags["ContainsWideningType"] = 2097152] = "ContainsWideningType";
/* @internal */
TypeFlags[TypeFlags["ContainsObjectLiteral"] = 4194304] = "ContainsObjectLiteral";
/* @internal */
TypeFlags[TypeFlags["ContainsAnyFunctionType"] = 8388608] = "ContainsAnyFunctionType";
/* @internal */
TypeFlags[TypeFlags["Nullable"] = 6144] = "Nullable";
TypeFlags[TypeFlags["Literal"] = 480] = "Literal";
TypeFlags[TypeFlags["StringOrNumberLiteral"] = 96] = "StringOrNumberLiteral";
/* @internal */
TypeFlags[TypeFlags["DefinitelyFalsy"] = 7392] = "DefinitelyFalsy";
TypeFlags[TypeFlags["PossiblyFalsy"] = 7406] = "PossiblyFalsy";
/* @internal */
TypeFlags[TypeFlags["Intrinsic"] = 16015] = "Intrinsic";
/* @internal */
TypeFlags[TypeFlags["Primitive"] = 8190] = "Primitive";
TypeFlags[TypeFlags["StringLike"] = 34] = "StringLike";
TypeFlags[TypeFlags["NumberLike"] = 340] = "NumberLike";
TypeFlags[TypeFlags["BooleanLike"] = 136] = "BooleanLike";
TypeFlags[TypeFlags["EnumLike"] = 272] = "EnumLike";
TypeFlags[TypeFlags["UnionOrIntersection"] = 196608] = "UnionOrIntersection";
TypeFlags[TypeFlags["StructuredType"] = 229376] = "StructuredType";
TypeFlags[TypeFlags["StructuredOrTypeParameter"] = 507904] = "StructuredOrTypeParameter";
// 'Narrowable' types are types where narrowing actually narrows.
// This *should* be every type other than null, undefined, void, and never
TypeFlags[TypeFlags["Narrowable"] = 1033215] = "Narrowable";
TypeFlags[TypeFlags["NotUnionOrUnit"] = 33281] = "NotUnionOrUnit";
/* @internal */
TypeFlags[TypeFlags["RequiresWidening"] = 6291456] = "RequiresWidening";
/* @internal */
TypeFlags[TypeFlags["PropagatingFlags"] = 14680064] = "PropagatingFlags";
})(TypeFlags = ts.TypeFlags || (ts.TypeFlags = {}));
var ObjectFlags;
(function (ObjectFlags) {
ObjectFlags[ObjectFlags["Class"] = 1] = "Class";
ObjectFlags[ObjectFlags["Interface"] = 2] = "Interface";
ObjectFlags[ObjectFlags["Reference"] = 4] = "Reference";
ObjectFlags[ObjectFlags["Tuple"] = 8] = "Tuple";
ObjectFlags[ObjectFlags["Anonymous"] = 16] = "Anonymous";
ObjectFlags[ObjectFlags["Mapped"] = 32] = "Mapped";
ObjectFlags[ObjectFlags["Instantiated"] = 64] = "Instantiated";
ObjectFlags[ObjectFlags["ObjectLiteral"] = 128] = "ObjectLiteral";
ObjectFlags[ObjectFlags["EvolvingArray"] = 256] = "EvolvingArray";
ObjectFlags[ObjectFlags["ObjectLiteralPatternWithComputedProperties"] = 512] = "ObjectLiteralPatternWithComputedProperties";
ObjectFlags[ObjectFlags["ClassOrInterface"] = 3] = "ClassOrInterface";
})(ObjectFlags = ts.ObjectFlags || (ts.ObjectFlags = {}));
var SignatureKind;
(function (SignatureKind) {
SignatureKind[SignatureKind["Call"] = 0] = "Call";
SignatureKind[SignatureKind["Construct"] = 1] = "Construct";
})(SignatureKind = ts.SignatureKind || (ts.SignatureKind = {}));
var IndexKind;
(function (IndexKind) {
IndexKind[IndexKind["String"] = 0] = "String";
IndexKind[IndexKind["Number"] = 1] = "Number";
})(IndexKind = ts.IndexKind || (ts.IndexKind = {}));
/* @internal */
var SpecialPropertyAssignmentKind;
(function (SpecialPropertyAssignmentKind) {
SpecialPropertyAssignmentKind[SpecialPropertyAssignmentKind["None"] = 0] = "None";
/// exports.name = expr
SpecialPropertyAssignmentKind[SpecialPropertyAssignmentKind["ExportsProperty"] = 1] = "ExportsProperty";
/// module.exports = expr
SpecialPropertyAssignmentKind[SpecialPropertyAssignmentKind["ModuleExports"] = 2] = "ModuleExports";
/// className.prototype.name = expr
SpecialPropertyAssignmentKind[SpecialPropertyAssignmentKind["PrototypeProperty"] = 3] = "PrototypeProperty";
/// this.name = expr
SpecialPropertyAssignmentKind[SpecialPropertyAssignmentKind["ThisProperty"] = 4] = "ThisProperty";
})(SpecialPropertyAssignmentKind = ts.SpecialPropertyAssignmentKind || (ts.SpecialPropertyAssignmentKind = {}));
var DiagnosticCategory;
(function (DiagnosticCategory) {
DiagnosticCategory[DiagnosticCategory["Warning"] = 0] = "Warning";
DiagnosticCategory[DiagnosticCategory["Error"] = 1] = "Error";
DiagnosticCategory[DiagnosticCategory["Message"] = 2] = "Message";
})(DiagnosticCategory = ts.DiagnosticCategory || (ts.DiagnosticCategory = {}));
var ModuleResolutionKind;
(function (ModuleResolutionKind) {
ModuleResolutionKind[ModuleResolutionKind["Classic"] = 1] = "Classic";
ModuleResolutionKind[ModuleResolutionKind["NodeJs"] = 2] = "NodeJs";
})(ModuleResolutionKind = ts.ModuleResolutionKind || (ts.ModuleResolutionKind = {}));
var ModuleKind;
(function (ModuleKind) {
ModuleKind[ModuleKind["None"] = 0] = "None";
ModuleKind[ModuleKind["CommonJS"] = 1] = "CommonJS";
ModuleKind[ModuleKind["AMD"] = 2] = "AMD";
ModuleKind[ModuleKind["UMD"] = 3] = "UMD";
ModuleKind[ModuleKind["System"] = 4] = "System";
ModuleKind[ModuleKind["ES2015"] = 5] = "ES2015";
})(ModuleKind = ts.ModuleKind || (ts.ModuleKind = {}));
var JsxEmit;
(function (JsxEmit) {
JsxEmit[JsxEmit["None"] = 0] = "None";
JsxEmit[JsxEmit["Preserve"] = 1] = "Preserve";
JsxEmit[JsxEmit["React"] = 2] = "React";
})(JsxEmit = ts.JsxEmit || (ts.JsxEmit = {}));
var NewLineKind;
(function (NewLineKind) {
NewLineKind[NewLineKind["CarriageReturnLineFeed"] = 0] = "CarriageReturnLineFeed";
NewLineKind[NewLineKind["LineFeed"] = 1] = "LineFeed";
})(NewLineKind = ts.NewLineKind || (ts.NewLineKind = {}));
var ScriptKind;
(function (ScriptKind) {
ScriptKind[ScriptKind["Unknown"] = 0] = "Unknown";
ScriptKind[ScriptKind["JS"] = 1] = "JS";
ScriptKind[ScriptKind["JSX"] = 2] = "JSX";
ScriptKind[ScriptKind["TS"] = 3] = "TS";
ScriptKind[ScriptKind["TSX"] = 4] = "TSX";
})(ScriptKind = ts.ScriptKind || (ts.ScriptKind = {}));
var ScriptTarget;
(function (ScriptTarget) {
ScriptTarget[ScriptTarget["ES3"] = 0] = "ES3";
ScriptTarget[ScriptTarget["ES5"] = 1] = "ES5";
ScriptTarget[ScriptTarget["ES2015"] = 2] = "ES2015";
ScriptTarget[ScriptTarget["ES2016"] = 3] = "ES2016";
ScriptTarget[ScriptTarget["ES2017"] = 4] = "ES2017";
ScriptTarget[ScriptTarget["ESNext"] = 5] = "ESNext";
ScriptTarget[ScriptTarget["Latest"] = 5] = "Latest";
})(ScriptTarget = ts.ScriptTarget || (ts.ScriptTarget = {}));
var LanguageVariant;
(function (LanguageVariant) {
LanguageVariant[LanguageVariant["Standard"] = 0] = "Standard";
LanguageVariant[LanguageVariant["JSX"] = 1] = "JSX";
})(LanguageVariant = ts.LanguageVariant || (ts.LanguageVariant = {}));
/* @internal */
var DiagnosticStyle;
(function (DiagnosticStyle) {
DiagnosticStyle[DiagnosticStyle["Simple"] = 0] = "Simple";
DiagnosticStyle[DiagnosticStyle["Pretty"] = 1] = "Pretty";
})(DiagnosticStyle = ts.DiagnosticStyle || (ts.DiagnosticStyle = {}));
var WatchDirectoryFlags;
(function (WatchDirectoryFlags) {
WatchDirectoryFlags[WatchDirectoryFlags["None"] = 0] = "None";
WatchDirectoryFlags[WatchDirectoryFlags["Recursive"] = 1] = "Recursive";
})(WatchDirectoryFlags = ts.WatchDirectoryFlags || (ts.WatchDirectoryFlags = {}));
/* @internal */
var CharacterCodes;
(function (CharacterCodes) {
CharacterCodes[CharacterCodes["nullCharacter"] = 0] = "nullCharacter";
CharacterCodes[CharacterCodes["maxAsciiCharacter"] = 127] = "maxAsciiCharacter";
CharacterCodes[CharacterCodes["lineFeed"] = 10] = "lineFeed";
CharacterCodes[CharacterCodes["carriageReturn"] = 13] = "carriageReturn";
CharacterCodes[CharacterCodes["lineSeparator"] = 8232] = "lineSeparator";
CharacterCodes[CharacterCodes["paragraphSeparator"] = 8233] = "paragraphSeparator";
CharacterCodes[CharacterCodes["nextLine"] = 133] = "nextLine";
// Unicode 3.0 space characters
CharacterCodes[CharacterCodes["space"] = 32] = "space";
CharacterCodes[CharacterCodes["nonBreakingSpace"] = 160] = "nonBreakingSpace";
CharacterCodes[CharacterCodes["enQuad"] = 8192] = "enQuad";
CharacterCodes[CharacterCodes["emQuad"] = 8193] = "emQuad";
CharacterCodes[CharacterCodes["enSpace"] = 8194] = "enSpace";
CharacterCodes[CharacterCodes["emSpace"] = 8195] = "emSpace";
CharacterCodes[CharacterCodes["threePerEmSpace"] = 8196] = "threePerEmSpace";
CharacterCodes[CharacterCodes["fourPerEmSpace"] = 8197] = "fourPerEmSpace";
CharacterCodes[CharacterCodes["sixPerEmSpace"] = 8198] = "sixPerEmSpace";
CharacterCodes[CharacterCodes["figureSpace"] = 8199] = "figureSpace";
CharacterCodes[CharacterCodes["punctuationSpace"] = 8200] = "punctuationSpace";
CharacterCodes[CharacterCodes["thinSpace"] = 8201] = "thinSpace";
CharacterCodes[CharacterCodes["hairSpace"] = 8202] = "hairSpace";
CharacterCodes[CharacterCodes["zeroWidthSpace"] = 8203] = "zeroWidthSpace";
CharacterCodes[CharacterCodes["narrowNoBreakSpace"] = 8239] = "narrowNoBreakSpace";
CharacterCodes[CharacterCodes["ideographicSpace"] = 12288] = "ideographicSpace";
CharacterCodes[CharacterCodes["mathematicalSpace"] = 8287] = "mathematicalSpace";
CharacterCodes[CharacterCodes["ogham"] = 5760] = "ogham";
CharacterCodes[CharacterCodes["_"] = 95] = "_";
CharacterCodes[CharacterCodes["$"] = 36] = "$";
CharacterCodes[CharacterCodes["_0"] = 48] = "_0";
CharacterCodes[CharacterCodes["_1"] = 49] = "_1";
CharacterCodes[CharacterCodes["_2"] = 50] = "_2";
CharacterCodes[CharacterCodes["_3"] = 51] = "_3";
CharacterCodes[CharacterCodes["_4"] = 52] = "_4";
CharacterCodes[CharacterCodes["_5"] = 53] = "_5";
CharacterCodes[CharacterCodes["_6"] = 54] = "_6";
CharacterCodes[CharacterCodes["_7"] = 55] = "_7";
CharacterCodes[CharacterCodes["_8"] = 56] = "_8";
CharacterCodes[CharacterCodes["_9"] = 57] = "_9";
CharacterCodes[CharacterCodes["a"] = 97] = "a";
CharacterCodes[CharacterCodes["b"] = 98] = "b";
CharacterCodes[CharacterCodes["c"] = 99] = "c";
CharacterCodes[CharacterCodes["d"] = 100] = "d";
CharacterCodes[CharacterCodes["e"] = 101] = "e";
CharacterCodes[CharacterCodes["f"] = 102] = "f";
CharacterCodes[CharacterCodes["g"] = 103] = "g";
CharacterCodes[CharacterCodes["h"] = 104] = "h";
CharacterCodes[CharacterCodes["i"] = 105] = "i";
CharacterCodes[CharacterCodes["j"] = 106] = "j";
CharacterCodes[CharacterCodes["k"] = 107] = "k";
CharacterCodes[CharacterCodes["l"] = 108] = "l";
CharacterCodes[CharacterCodes["m"] = 109] = "m";
CharacterCodes[CharacterCodes["n"] = 110] = "n";
CharacterCodes[CharacterCodes["o"] = 111] = "o";
CharacterCodes[CharacterCodes["p"] = 112] = "p";
CharacterCodes[CharacterCodes["q"] = 113] = "q";
CharacterCodes[CharacterCodes["r"] = 114] = "r";
CharacterCodes[CharacterCodes["s"] = 115] = "s";
CharacterCodes[CharacterCodes["t"] = 116] = "t";
CharacterCodes[CharacterCodes["u"] = 117] = "u";
CharacterCodes[CharacterCodes["v"] = 118] = "v";
CharacterCodes[CharacterCodes["w"] = 119] = "w";
CharacterCodes[CharacterCodes["x"] = 120] = "x";
CharacterCodes[CharacterCodes["y"] = 121] = "y";
CharacterCodes[CharacterCodes["z"] = 122] = "z";
CharacterCodes[CharacterCodes["A"] = 65] = "A";
CharacterCodes[CharacterCodes["B"] = 66] = "B";
CharacterCodes[CharacterCodes["C"] = 67] = "C";
CharacterCodes[CharacterCodes["D"] = 68] = "D";
CharacterCodes[CharacterCodes["E"] = 69] = "E";
CharacterCodes[CharacterCodes["F"] = 70] = "F";
CharacterCodes[CharacterCodes["G"] = 71] = "G";
CharacterCodes[CharacterCodes["H"] = 72] = "H";
CharacterCodes[CharacterCodes["I"] = 73] = "I";
CharacterCodes[CharacterCodes["J"] = 74] = "J";
CharacterCodes[CharacterCodes["K"] = 75] = "K";
CharacterCodes[CharacterCodes["L"] = 76] = "L";
CharacterCodes[CharacterCodes["M"] = 77] = "M";
CharacterCodes[CharacterCodes["N"] = 78] = "N";
CharacterCodes[CharacterCodes["O"] = 79] = "O";
CharacterCodes[CharacterCodes["P"] = 80] = "P";
CharacterCodes[CharacterCodes["Q"] = 81] = "Q";
CharacterCodes[CharacterCodes["R"] = 82] = "R";
CharacterCodes[CharacterCodes["S"] = 83] = "S";
CharacterCodes[CharacterCodes["T"] = 84] = "T";
CharacterCodes[CharacterCodes["U"] = 85] = "U";
CharacterCodes[CharacterCodes["V"] = 86] = "V";
CharacterCodes[CharacterCodes["W"] = 87] = "W";
CharacterCodes[CharacterCodes["X"] = 88] = "X";
CharacterCodes[CharacterCodes["Y"] = 89] = "Y";
CharacterCodes[CharacterCodes["Z"] = 90] = "Z";
CharacterCodes[CharacterCodes["ampersand"] = 38] = "ampersand";
CharacterCodes[CharacterCodes["asterisk"] = 42] = "asterisk";
CharacterCodes[CharacterCodes["at"] = 64] = "at";
CharacterCodes[CharacterCodes["backslash"] = 92] = "backslash";
CharacterCodes[CharacterCodes["backtick"] = 96] = "backtick";
CharacterCodes[CharacterCodes["bar"] = 124] = "bar";
CharacterCodes[CharacterCodes["caret"] = 94] = "caret";
CharacterCodes[CharacterCodes["closeBrace"] = 125] = "closeBrace";
CharacterCodes[CharacterCodes["closeBracket"] = 93] = "closeBracket";
CharacterCodes[CharacterCodes["closeParen"] = 41] = "closeParen";
CharacterCodes[CharacterCodes["colon"] = 58] = "colon";
CharacterCodes[CharacterCodes["comma"] = 44] = "comma";
CharacterCodes[CharacterCodes["dot"] = 46] = "dot";
CharacterCodes[CharacterCodes["doubleQuote"] = 34] = "doubleQuote";
CharacterCodes[CharacterCodes["equals"] = 61] = "equals";
CharacterCodes[CharacterCodes["exclamation"] = 33] = "exclamation";
CharacterCodes[CharacterCodes["greaterThan"] = 62] = "greaterThan";
CharacterCodes[CharacterCodes["hash"] = 35] = "hash";
CharacterCodes[CharacterCodes["lessThan"] = 60] = "lessThan";
CharacterCodes[CharacterCodes["minus"] = 45] = "minus";
CharacterCodes[CharacterCodes["openBrace"] = 123] = "openBrace";
CharacterCodes[CharacterCodes["openBracket"] = 91] = "openBracket";
CharacterCodes[CharacterCodes["openParen"] = 40] = "openParen";
CharacterCodes[CharacterCodes["percent"] = 37] = "percent";
CharacterCodes[CharacterCodes["plus"] = 43] = "plus";
CharacterCodes[CharacterCodes["question"] = 63] = "question";
CharacterCodes[CharacterCodes["semicolon"] = 59] = "semicolon";
CharacterCodes[CharacterCodes["singleQuote"] = 39] = "singleQuote";
CharacterCodes[CharacterCodes["slash"] = 47] = "slash";
CharacterCodes[CharacterCodes["tilde"] = 126] = "tilde";
CharacterCodes[CharacterCodes["backspace"] = 8] = "backspace";
CharacterCodes[CharacterCodes["formFeed"] = 12] = "formFeed";
CharacterCodes[CharacterCodes["byteOrderMark"] = 65279] = "byteOrderMark";
CharacterCodes[CharacterCodes["tab"] = 9] = "tab";
CharacterCodes[CharacterCodes["verticalTab"] = 11] = "verticalTab";
})(CharacterCodes = ts.CharacterCodes || (ts.CharacterCodes = {}));
var Extension;
(function (Extension) {
Extension[Extension["Ts"] = 0] = "Ts";
Extension[Extension["Tsx"] = 1] = "Tsx";
Extension[Extension["Dts"] = 2] = "Dts";
Extension[Extension["Js"] = 3] = "Js";
Extension[Extension["Jsx"] = 4] = "Jsx";
Extension[Extension["LastTypeScriptExtension"] = 2] = "LastTypeScriptExtension";
})(Extension = ts.Extension || (ts.Extension = {}));
/* @internal */
var TransformFlags;
(function (TransformFlags) {
TransformFlags[TransformFlags["None"] = 0] = "None";
// Facts
// - Flags used to indicate that a node or subtree contains syntax that requires transformation.
TransformFlags[TransformFlags["TypeScript"] = 1] = "TypeScript";
TransformFlags[TransformFlags["ContainsTypeScript"] = 2] = "ContainsTypeScript";
TransformFlags[TransformFlags["Jsx"] = 4] = "Jsx";
TransformFlags[TransformFlags["ContainsJsx"] = 8] = "ContainsJsx";
TransformFlags[TransformFlags["ESNext"] = 16] = "ESNext";
TransformFlags[TransformFlags["ContainsESNext"] = 32] = "ContainsESNext";
TransformFlags[TransformFlags["ES2017"] = 64] = "ES2017";
TransformFlags[TransformFlags["ContainsES2017"] = 128] = "ContainsES2017";
TransformFlags[TransformFlags["ES2016"] = 256] = "ES2016";
TransformFlags[TransformFlags["ContainsES2016"] = 512] = "ContainsES2016";
TransformFlags[TransformFlags["ES2015"] = 1024] = "ES2015";
TransformFlags[TransformFlags["ContainsES2015"] = 2048] = "ContainsES2015";
TransformFlags[TransformFlags["Generator"] = 4096] = "Generator";
TransformFlags[TransformFlags["ContainsGenerator"] = 8192] = "ContainsGenerator";
TransformFlags[TransformFlags["DestructuringAssignment"] = 16384] = "DestructuringAssignment";
TransformFlags[TransformFlags["ContainsDestructuringAssignment"] = 32768] = "ContainsDestructuringAssignment";
// Markers
// - Flags used to indicate that a subtree contains a specific transformation.
TransformFlags[TransformFlags["ContainsDecorators"] = 65536] = "ContainsDecorators";
TransformFlags[TransformFlags["ContainsPropertyInitializer"] = 131072] = "ContainsPropertyInitializer";
TransformFlags[TransformFlags["ContainsLexicalThis"] = 262144] = "ContainsLexicalThis";
TransformFlags[TransformFlags["ContainsCapturedLexicalThis"] = 524288] = "ContainsCapturedLexicalThis";
TransformFlags[TransformFlags["ContainsLexicalThisInComputedPropertyName"] = 1048576] = "ContainsLexicalThisInComputedPropertyName";
TransformFlags[TransformFlags["ContainsDefaultValueAssignments"] = 2097152] = "ContainsDefaultValueAssignments";
TransformFlags[TransformFlags["ContainsParameterPropertyAssignments"] = 4194304] = "ContainsParameterPropertyAssignments";
TransformFlags[TransformFlags["ContainsSpreadExpression"] = 8388608] = "ContainsSpreadExpression";
TransformFlags[TransformFlags["ContainsComputedPropertyName"] = 16777216] = "ContainsComputedPropertyName";
TransformFlags[TransformFlags["ContainsBlockScopedBinding"] = 33554432] = "ContainsBlockScopedBinding";
TransformFlags[TransformFlags["ContainsBindingPattern"] = 67108864] = "ContainsBindingPattern";
TransformFlags[TransformFlags["ContainsYield"] = 134217728] = "ContainsYield";
TransformFlags[TransformFlags["ContainsHoistedDeclarationOrCompletion"] = 268435456] = "ContainsHoistedDeclarationOrCompletion";
TransformFlags[TransformFlags["HasComputedFlags"] = 536870912] = "HasComputedFlags";
// Assertions
// - Bitmasks that are used to assert facts about the syntax of a node and its subtree.
TransformFlags[TransformFlags["AssertTypeScript"] = 3] = "AssertTypeScript";
TransformFlags[TransformFlags["AssertJsx"] = 12] = "AssertJsx";
TransformFlags[TransformFlags["AssertESNext"] = 48] = "AssertESNext";
TransformFlags[TransformFlags["AssertES2017"] = 192] = "AssertES2017";
TransformFlags[TransformFlags["AssertES2016"] = 768] = "AssertES2016";
TransformFlags[TransformFlags["AssertES2015"] = 3072] = "AssertES2015";
TransformFlags[TransformFlags["AssertGenerator"] = 12288] = "AssertGenerator";
TransformFlags[TransformFlags["AssertDestructuringAssignment"] = 49152] = "AssertDestructuringAssignment";
// Scope Exclusions
// - Bitmasks that exclude flags from propagating out of a specific context
// into the subtree flags of their container.
TransformFlags[TransformFlags["NodeExcludes"] = 536892757] = "NodeExcludes";
TransformFlags[TransformFlags["ArrowFunctionExcludes"] = 979719509] = "ArrowFunctionExcludes";
TransformFlags[TransformFlags["FunctionExcludes"] = 980243797] = "FunctionExcludes";
TransformFlags[TransformFlags["ConstructorExcludes"] = 975983957] = "ConstructorExcludes";
TransformFlags[TransformFlags["MethodOrAccessorExcludes"] = 975983957] = "MethodOrAccessorExcludes";
TransformFlags[TransformFlags["ClassExcludes"] = 559895893] = "ClassExcludes";
TransformFlags[TransformFlags["ModuleExcludes"] = 839734613] = "ModuleExcludes";
TransformFlags[TransformFlags["TypeExcludes"] = -3] = "TypeExcludes";
TransformFlags[TransformFlags["ObjectLiteralExcludes"] = 554784085] = "ObjectLiteralExcludes";
TransformFlags[TransformFlags["ArrayLiteralOrCallOrNewExcludes"] = 545281365] = "ArrayLiteralOrCallOrNewExcludes";
TransformFlags[TransformFlags["VariableDeclarationListExcludes"] = 604001621] = "VariableDeclarationListExcludes";
TransformFlags[TransformFlags["ParameterExcludes"] = 604001621] = "ParameterExcludes";
// Masks
// - Additional bitmasks
TransformFlags[TransformFlags["TypeScriptClassSyntaxMask"] = 4390912] = "TypeScriptClassSyntaxMask";
TransformFlags[TransformFlags["ES2015FunctionSyntaxMask"] = 2621440] = "ES2015FunctionSyntaxMask";
})(TransformFlags = ts.TransformFlags || (ts.TransformFlags = {}));
/* @internal */
var EmitFlags;
(function (EmitFlags) {
EmitFlags[EmitFlags["EmitEmitHelpers"] = 1] = "EmitEmitHelpers";
EmitFlags[EmitFlags["EmitExportStar"] = 2] = "EmitExportStar";
EmitFlags[EmitFlags["EmitSuperHelper"] = 4] = "EmitSuperHelper";
EmitFlags[EmitFlags["EmitAdvancedSuperHelper"] = 8] = "EmitAdvancedSuperHelper";
EmitFlags[EmitFlags["UMDDefine"] = 16] = "UMDDefine";
EmitFlags[EmitFlags["SingleLine"] = 32] = "SingleLine";
EmitFlags[EmitFlags["AdviseOnEmitNode"] = 64] = "AdviseOnEmitNode";
EmitFlags[EmitFlags["NoSubstitution"] = 128] = "NoSubstitution";
EmitFlags[EmitFlags["CapturesThis"] = 256] = "CapturesThis";
EmitFlags[EmitFlags["NoLeadingSourceMap"] = 512] = "NoLeadingSourceMap";
EmitFlags[EmitFlags["NoTrailingSourceMap"] = 1024] = "NoTrailingSourceMap";
EmitFlags[EmitFlags["NoSourceMap"] = 1536] = "NoSourceMap";
EmitFlags[EmitFlags["NoNestedSourceMaps"] = 2048] = "NoNestedSourceMaps";
EmitFlags[EmitFlags["NoTokenLeadingSourceMaps"] = 4096] = "NoTokenLeadingSourceMaps";
EmitFlags[EmitFlags["NoTokenTrailingSourceMaps"] = 8192] = "NoTokenTrailingSourceMaps";
EmitFlags[EmitFlags["NoTokenSourceMaps"] = 12288] = "NoTokenSourceMaps";
EmitFlags[EmitFlags["NoLeadingComments"] = 16384] = "NoLeadingComments";
EmitFlags[EmitFlags["NoTrailingComments"] = 32768] = "NoTrailingComments";
EmitFlags[EmitFlags["NoComments"] = 49152] = "NoComments";
EmitFlags[EmitFlags["NoNestedComments"] = 65536] = "NoNestedComments";
EmitFlags[EmitFlags["ExportName"] = 131072] = "ExportName";
EmitFlags[EmitFlags["LocalName"] = 262144] = "LocalName";
EmitFlags[EmitFlags["Indented"] = 524288] = "Indented";
EmitFlags[EmitFlags["NoIndentation"] = 1048576] = "NoIndentation";
EmitFlags[EmitFlags["AsyncFunctionBody"] = 2097152] = "AsyncFunctionBody";
EmitFlags[EmitFlags["ReuseTempVariableScope"] = 4194304] = "ReuseTempVariableScope";
EmitFlags[EmitFlags["CustomPrologue"] = 8388608] = "CustomPrologue";
EmitFlags[EmitFlags["NoHoisting"] = 16777216] = "NoHoisting";
EmitFlags[EmitFlags["HasEndOfDeclarationMarker"] = 33554432] = "HasEndOfDeclarationMarker";
})(EmitFlags = ts.EmitFlags || (ts.EmitFlags = {}));
/* @internal */
var EmitContext;
(function (EmitContext) {
EmitContext[EmitContext["SourceFile"] = 0] = "SourceFile";
EmitContext[EmitContext["Expression"] = 1] = "Expression";
EmitContext[EmitContext["IdentifierName"] = 2] = "IdentifierName";
EmitContext[EmitContext["Unspecified"] = 3] = "Unspecified";
})(EmitContext = ts.EmitContext || (ts.EmitContext = {}));
})(ts || (ts = {}));
/*@internal*/
var ts;
(function (ts) {
/** Gets a timestamp with (at least) ms resolution */
ts.timestamp = typeof performance !== "undefined" && performance.now ? function () { return performance.now(); } : Date.now ? Date.now : function () { return +(new Date()); };
})(ts || (ts = {}));
/*@internal*/
/** Performance measurements for the compiler. */
(function (ts) {
var performance;
(function (performance) {
var profilerEvent = typeof onProfilerEvent === "function" && onProfilerEvent.profiler === true
? onProfilerEvent
: function (_markName) { };
var enabled = false;
var profilerStart = 0;
var counts;
var marks;
var measures;
/**
* Marks a performance event.
*
* @param markName The name of the mark.
*/
function mark(markName) {
if (enabled) {
marks[markName] = ts.timestamp();
counts[markName] = (counts[markName] || 0) + 1;
profilerEvent(markName);
}
}
performance.mark = mark;
/**
* Adds a performance measurement with the specified name.
*
* @param measureName The name of the performance measurement.
* @param startMarkName The name of the starting mark. If not supplied, the point at which the
* profiler was enabled is used.
* @param endMarkName The name of the ending mark. If not supplied, the current timestamp is
* used.
*/
function measure(measureName, startMarkName, endMarkName) {
if (enabled) {
var end = endMarkName && marks[endMarkName] || ts.timestamp();
var start = startMarkName && marks[startMarkName] || profilerStart;
measures[measureName] = (measures[measureName] || 0) + (end - start);
}
}
performance.measure = measure;
/**
* Gets the number of times a marker was encountered.
*
* @param markName The name of the mark.
*/
function getCount(markName) {
return counts && counts[markName] || 0;
}
performance.getCount = getCount;
/**
* Gets the total duration of all measurements with the supplied name.
*
* @param measureName The name of the measure whose durations should be accumulated.
*/
function getDuration(measureName) {
return measures && measures[measureName] || 0;
}
performance.getDuration = getDuration;
/**
* Iterate over each measure, performing some action
*
* @param cb The action to perform for each measure
*/
function forEachMeasure(cb) {
for (var key in measures) {
cb(key, measures[key]);
}
}
performance.forEachMeasure = forEachMeasure;
/** Enables (and resets) performance measurements for the compiler. */
function enable() {
counts = ts.createMap();
marks = ts.createMap();
measures = ts.createMap();
enabled = true;
profilerStart = ts.timestamp();
}
performance.enable = enable;
/** Disables performance measurements for the compiler. */
function disable() {
enabled = false;
}
performance.disable = disable;
})(performance = ts.performance || (ts.performance = {}));
})(ts || (ts = {}));
/// <reference path="types.ts"/>
/// <reference path="performance.ts" />
/* @internal */
var ts;
(function (ts) {
/**
* Ternary values are defined such that
* x & y is False if either x or y is False.
* x & y is Maybe if either x or y is Maybe, but neither x or y is False.
* x & y is True if both x and y are True.
* x | y is False if both x and y are False.
* x | y is Maybe if either x or y is Maybe, but neither x or y is True.
* x | y is True if either x or y is True.
*/
var Ternary;
(function (Ternary) {
Ternary[Ternary["False"] = 0] = "False";
Ternary[Ternary["Maybe"] = 1] = "Maybe";
Ternary[Ternary["True"] = -1] = "True";
})(Ternary = ts.Ternary || (ts.Ternary = {}));
var createObject = Object.create;
// More efficient to create a collator once and use its `compare` than to call `a.localeCompare(b)` many times.
ts.collator = typeof Intl === "object" && typeof Intl.Collator === "function" ? new Intl.Collator() : undefined;
function createMap(template) {
var map = createObject(null); // tslint:disable-line:no-null-keyword
// Using 'delete' on an object causes V8 to put the object in dictionary mode.
// This disables creation of hidden classes, which are expensive when an object is
// constantly changing shape.
map["__"] = undefined;
delete map["__"];
// Copies keys/values from template. Note that for..in will not throw if
// template is undefined, and instead will just exit the loop.
for (var key in template)
if (hasOwnProperty.call(template, key)) {
map[key] = template[key];
}
return map;
}
ts.createMap = createMap;
function createFileMap(keyMapper) {
var files = createMap();
return {
get: get,
set: set,
contains: contains,
remove: remove,
forEachValue: forEachValueInMap,
getKeys: getKeys,
clear: clear,
};
function forEachValueInMap(f) {
for (var key in files) {
f(key, files[key]);
}
}
function getKeys() {
var keys = [];
for (var key in files) {
keys.push(key);
}
return keys;
}
// path should already be well-formed so it does not need to be normalized
function get(path) {
return files[toKey(path)];
}
function set(path, value) {
files[toKey(path)] = value;
}
function contains(path) {
return toKey(path) in files;
}
function remove(path) {
var key = toKey(path);
delete files[key];
}
function clear() {
files = createMap();
}
function toKey(path) {
return keyMapper ? keyMapper(path) : path;
}
}
ts.createFileMap = createFileMap;
function toPath(fileName, basePath, getCanonicalFileName) {
var nonCanonicalizedPath = isRootedDiskPath(fileName)
? normalizePath(fileName)
: getNormalizedAbsolutePath(fileName, basePath);
return getCanonicalFileName(nonCanonicalizedPath);
}
ts.toPath = toPath;
var Comparison;
(function (Comparison) {
Comparison[Comparison["LessThan"] = -1] = "LessThan";
Comparison[Comparison["EqualTo"] = 0] = "EqualTo";
Comparison[Comparison["GreaterThan"] = 1] = "GreaterThan";
})(Comparison = ts.Comparison || (ts.Comparison = {}));
/**
* Iterates through 'array' by index and performs the callback on each element of array until the callback
* returns a truthy value, then returns that value.
* If no such value is found, the callback is applied to each element of array and undefined is returned.
*/
function forEach(array, callback) {
if (array) {
for (var i = 0, len = array.length; i < len; i++) {
var result = callback(array[i], i);
if (result) {
return result;
}
}
}
return undefined;
}
ts.forEach = forEach;
function zipWith(arrayA, arrayB, callback) {
Debug.assert(arrayA.length === arrayB.length);
for (var i = 0; i < arrayA.length; i++) {
callback(arrayA[i], arrayB[i], i);
}
}
ts.zipWith = zipWith;
/**
* Iterates through `array` by index and performs the callback on each element of array until the callback
* returns a falsey value, then returns false.
* If no such value is found, the callback is applied to each element of array and `true` is returned.
*/
function every(array, callback) {
if (array) {
for (var i = 0, len = array.length; i < len; i++) {
if (!callback(array[i], i)) {
return false;
}
}
}
return true;
}
ts.every = every;
/** Works like Array.prototype.find, returning `undefined` if no element satisfying the predicate is found. */
function find(array, predicate) {
for (var i = 0, len = array.length; i < len; i++) {
var value = array[i];
if (predicate(value, i)) {
return value;
}
}
return undefined;
}
ts.find = find;
/**
* Returns the first truthy result of `callback`, or else fails.
* This is like `forEach`, but never returns undefined.
*/
function findMap(array, callback) {
for (var i = 0, len = array.length; i < len; i++) {
var result = callback(array[i], i);
if (result) {
return result;
}
}
Debug.fail();
}
ts.findMap = findMap;
function contains(array, value) {
if (array) {
for (var _i = 0, array_1 = array; _i < array_1.length; _i++) {
var v = array_1[_i];
if (v === value) {
return true;
}
}
}
return false;
}
ts.contains = contains;
function indexOf(array, value) {
if (array) {
for (var i = 0, len = array.length; i < len; i++) {
if (array[i] === value) {
return i;
}
}
}
return -1;
}
ts.indexOf = indexOf;
function indexOfAnyCharCode(text, charCodes, start) {
for (var i = start || 0, len = text.length; i < len; i++) {
if (contains(charCodes, text.charCodeAt(i))) {
return i;
}
}
return -1;
}
ts.indexOfAnyCharCode = indexOfAnyCharCode;
function countWhere(array, predicate) {
var count = 0;
if (array) {
for (var i = 0; i < array.length; i++) {
var v = array[i];
if (predicate(v, i)) {
count++;
}
}
}
return count;
}
ts.countWhere = countWhere;
function filter(array, f) {
if (array) {
var len = array.length;
var i = 0;
while (i < len && f(array[i]))
i++;
if (i < len) {
var result = array.slice(0, i);
i++;
while (i < len) {
var item = array[i];
if (f(item)) {
result.push(item);
}
i++;
}
return result;
}
}
return array;
}
ts.filter = filter;
function removeWhere(array, f) {
var outIndex = 0;
for (var _i = 0, array_2 = array; _i < array_2.length; _i++) {
var item = array_2[_i];
if (!f(item)) {
array[outIndex] = item;
outIndex++;
}
}
if (outIndex !== array.length) {
array.length = outIndex;
return true;
}
return false;
}
ts.removeWhere = removeWhere;
function filterMutate(array, f) {
var outIndex = 0;
for (var _i = 0, array_3 = array; _i < array_3.length; _i++) {
var item = array_3[_i];
if (f(item)) {
array[outIndex] = item;
outIndex++;
}
}
array.length = outIndex;
}
ts.filterMutate = filterMutate;
function map(array, f) {
var result;
if (array) {
result = [];
for (var i = 0; i < array.length; i++) {
result.push(f(array[i], i));
}
}
return result;
}
ts.map = map;
// Maps from T to T and avoids allocation if all elements map to themselves
function sameMap(array, f) {
var result;
if (array) {
for (var i = 0; i < array.length; i++) {
if (result) {
result.push(f(array[i], i));
}
else {
var item = array[i];
var mapped = f(item, i);
if (item !== mapped) {
result = array.slice(0, i);
result.push(mapped);
}
}
}
}
return result || array;
}
ts.sameMap = sameMap;
/**
* Flattens an array containing a mix of array or non-array elements.
*
* @param array The array to flatten.
*/
function flatten(array) {
var result;
if (array) {
result = [];
for (var _i = 0, array_4 = array; _i < array_4.length; _i++) {
var v = array_4[_i];
if (v) {
if (isArray(v)) {
addRange(result, v);
}
else {
result.push(v);
}
}
}
}
return result;
}
ts.flatten = flatten;
/**
* Maps an array. If the mapped value is an array, it is spread into the result.
*
* @param array The array to map.
* @param mapfn The callback used to map the result into one or more values.
*/
function flatMap(array, mapfn) {
var result;
if (array) {
result = [];
for (var i = 0; i < array.length; i++) {
var v = mapfn(array[i], i);
if (v) {
if (isArray(v)) {
addRange(result, v);
}
else {
result.push(v);
}
}
}
}
return result;
}
ts.flatMap = flatMap;
/**
* Computes the first matching span of elements and returns a tuple of the first span
* and the remaining elements.
*/
function span(array, f) {
if (array) {
for (var i = 0; i < array.length; i++) {
if (!f(array[i], i)) {
return [array.slice(0, i), array.slice(i)];
}
}
return [array.slice(0), []];
}
return undefined;
}
ts.span = span;
/**
* Maps contiguous spans of values with the same key.
*
* @param array The array to map.
* @param keyfn A callback used to select the key for an element.
* @param mapfn A callback used to map a contiguous chunk of values to a single value.
*/
function spanMap(array, keyfn, mapfn) {
var result;
if (array) {
result = [];
var len = array.length;
var previousKey = void 0;
var key = void 0;
var start = 0;
var pos = 0;
while (start < len) {
while (pos < len) {
var value = array[pos];
key = keyfn(value, pos);
if (pos === 0) {
previousKey = key;
}
else if (key !== previousKey) {
break;
}
pos++;
}
if (start < pos) {
var v = mapfn(array.slice(start, pos), previousKey, start, pos);
if (v) {
result.push(v);
}
start = pos;
}
previousKey = key;
pos++;
}
}
return result;
}
ts.spanMap = spanMap;
function mapObject(object, f) {
var result;
if (object) {
result = {};
for (var _i = 0, _a = getOwnKeys(object); _i < _a.length; _i++) {
var v = _a[_i];
var _b = f(v, object[v]) || [undefined, undefined], key = _b[0], value = _b[1];
if (key !== undefined) {
result[key] = value;
}
}
}
return result;
}
ts.mapObject = mapObject;
function some(array, predicate) {
if (array) {
if (predicate) {
for (var _i = 0, array_5 = array; _i < array_5.length; _i++) {
var v = array_5[_i];
if (predicate(v)) {
return true;
}
}
}
else {
return array.length > 0;
}
}
return false;
}
ts.some = some;
function concatenate(array1, array2) {
if (!some(array2))
return array1;
if (!some(array1))
return array2;
return array1.concat(array2);
}
ts.concatenate = concatenate;
// TODO: fixme (N^2) - add optional comparer so collection can be sorted before deduplication.
function deduplicate(array, areEqual) {
var result;
if (array) {
result = [];
loop: for (var _i = 0, array_6 = array; _i < array_6.length; _i++) {
var item = array_6[_i];
for (var _a = 0, result_1 = result; _a < result_1.length; _a++) {
var res = result_1[_a];
if (areEqual ? areEqual(res, item) : res === item) {
continue loop;
}
}
result.push(item);
}
}
return result;
}
ts.deduplicate = deduplicate;
function arrayIsEqualTo(array1, array2, equaler) {
if (!array1 || !array2) {
return array1 === array2;
}
if (array1.length !== array2.length) {
return false;
}
for (var i = 0; i < array1.length; i++) {
var equals = equaler ? equaler(array1[i], array2[i]) : array1[i] === array2[i];
if (!equals) {
return false;
}
}
return true;
}
ts.arrayIsEqualTo = arrayIsEqualTo;
function changesAffectModuleResolution(oldOptions, newOptions) {
return !oldOptions ||
(oldOptions.module !== newOptions.module) ||
(oldOptions.moduleResolution !== newOptions.moduleResolution) ||
(oldOptions.noResolve !== newOptions.noResolve) ||
(oldOptions.target !== newOptions.target) ||
(oldOptions.noLib !== newOptions.noLib) ||
(oldOptions.jsx !== newOptions.jsx) ||
(oldOptions.allowJs !== newOptions.allowJs) ||
(oldOptions.rootDir !== newOptions.rootDir) ||
(oldOptions.configFilePath !== newOptions.configFilePath) ||
(oldOptions.baseUrl !== newOptions.baseUrl) ||
(oldOptions.maxNodeModuleJsDepth !== newOptions.maxNodeModuleJsDepth) ||
!arrayIsEqualTo(oldOptions.lib, newOptions.lib) ||
!arrayIsEqualTo(oldOptions.typeRoots, newOptions.typeRoots) ||
!arrayIsEqualTo(oldOptions.rootDirs, newOptions.rootDirs) ||
!equalOwnProperties(oldOptions.paths, newOptions.paths);
}
ts.changesAffectModuleResolution = changesAffectModuleResolution;
/**
* Compacts an array, removing any falsey elements.
*/
function compact(array) {
var result;
if (array) {
for (var i = 0; i < array.length; i++) {
var v = array[i];
if (result || !v) {
if (!result) {
result = array.slice(0, i);
}
if (v) {
result.push(v);
}
}
}
}
return result || array;
}
ts.compact = compact;
/**
* Gets the relative complement of `arrayA` with respect to `b`, returning the elements that
* are not present in `arrayA` but are present in `arrayB`. Assumes both arrays are sorted
* based on the provided comparer.
*/
function relativeComplement(arrayA, arrayB, comparer, offsetA, offsetB) {
if (comparer === void 0) { comparer = compareValues; }
if (offsetA === void 0) { offsetA = 0; }
if (offsetB === void 0) { offsetB = 0; }
if (!arrayB || !arrayA || arrayB.length === 0 || arrayA.length === 0)
return arrayB;
var result = [];
outer: for (; offsetB < arrayB.length; offsetB++) {
inner: for (; offsetA < arrayA.length; offsetA++) {
switch (comparer(arrayB[offsetB], arrayA[offsetA])) {
case -1 /* LessThan */: break inner;
case 0 /* EqualTo */: continue outer;
case 1 /* GreaterThan */: continue inner;
}
}
result.push(arrayB[offsetB]);
}
return result;
}
ts.relativeComplement = relativeComplement;
function sum(array, prop) {
var result = 0;
for (var _i = 0, array_7 = array; _i < array_7.length; _i++) {
var v = array_7[_i];
result += v[prop];
}
return result;
}
ts.sum = sum;
/**
* Appends a value to an array, returning the array.
*
* @param to The array to which `value` is to be appended. If `to` is `undefined`, a new array
* is created if `value` was appended.
* @param value The value to append to the array. If `value` is `undefined`, nothing is
* appended.
*/
function append(to, value) {
if (value === undefined)
return to;
if (to === undefined)
to = [];
to.push(value);
return to;
}
ts.append = append;
/**
* Appends a range of value to an array, returning the array.
*
* @param to The array to which `value` is to be appended. If `to` is `undefined`, a new array
* is created if `value` was appended.
* @param from The values to append to the array. If `from` is `undefined`, nothing is
* appended. If an element of `from` is `undefined`, that element is not appended.
*/
function addRange(to, from) {
if (from === undefined)
return to;
for (var _i = 0, from_1 = from; _i < from_1.length; _i++) {
var v = from_1[_i];
to = append(to, v);
}
return to;
}
ts.addRange = addRange;
function rangeEquals(array1, array2, pos, end) {
while (pos < end) {
if (array1[pos] !== array2[pos]) {
return false;
}
pos++;
}
return true;
}
ts.rangeEquals = rangeEquals;
/**
* Returns the first element of an array if non-empty, `undefined` otherwise.
*/
function firstOrUndefined(array) {
return array && array.length > 0
? array[0]
: undefined;
}
ts.firstOrUndefined = firstOrUndefined;
/**
* Returns the last element of an array if non-empty, `undefined` otherwise.
*/
function lastOrUndefined(array) {
return array && array.length > 0
? array[array.length - 1]
: undefined;
}
ts.lastOrUndefined = lastOrUndefined;
/**
* Returns the only element of an array if it contains only one element, `undefined` otherwise.
*/
function singleOrUndefined(array) {
return array && array.length === 1
? array[0]
: undefined;
}
ts.singleOrUndefined = singleOrUndefined;
/**
* Returns the only element of an array if it contains only one element; otheriwse, returns the
* array.
*/
function singleOrMany(array) {
return array && array.length === 1
? array[0]
: array;
}
ts.singleOrMany = singleOrMany;
function replaceElement(array, index, value) {
var result = array.slice(0);
result[index] = value;
return result;
}
ts.replaceElement = replaceElement;
/**
* Performs a binary search, finding the index at which 'value' occurs in 'array'.
* If no such index is found, returns the 2's-complement of first index at which
* number[index] exceeds number.
* @param array A sorted array whose first element must be no larger than number
* @param number The value to be searched for in the array.
*/
function binarySearch(array, value, comparer, offset) {
if (!array || array.length === 0) {
return -1;
}
var low = offset || 0;
var high = array.length - 1;
comparer = comparer !== undefined
? comparer
: function (v1, v2) { return (v1 < v2 ? -1 : (v1 > v2 ? 1 : 0)); };
while (low <= high) {
var middle = low + ((high - low) >> 1);
var midValue = array[middle];
if (comparer(midValue, value) === 0) {
return middle;
}
else if (comparer(midValue, value) > 0) {
high = middle - 1;
}
else {
low = middle + 1;
}
}
return ~low;
}
ts.binarySearch = binarySearch;
function reduceLeft(array, f, initial, start, count) {
if (array && array.length > 0) {
var size = array.length;
if (size > 0) {
var pos = start === undefined || start < 0 ? 0 : start;
var end = count === undefined || pos + count > size - 1 ? size - 1 : pos + count;
var result = void 0;
if (arguments.length <= 2) {
result = array[pos];
pos++;
}
else {
result = initial;
}
while (pos <= end) {
result = f(result, array[pos], pos);
pos++;
}
return result;
}
}
return initial;
}
ts.reduceLeft = reduceLeft;
function reduceRight(array, f, initial, start, count) {
if (array) {
var size = array.length;
if (size > 0) {
var pos = start === undefined || start > size - 1 ? size - 1 : start;
var end = count === undefined || pos - count < 0 ? 0 : pos - count;
var result = void 0;
if (arguments.length <= 2) {
result = array[pos];
pos--;
}
else {
result = initial;
}
while (pos >= end) {
result = f(result, array[pos], pos);
pos--;
}
return result;
}
}
return initial;
}
ts.reduceRight = reduceRight;
var hasOwnProperty = Object.prototype.hasOwnProperty;
/**
* Indicates whether a map-like contains an own property with the specified key.
*
* NOTE: This is intended for use only with MapLike<T> objects. For Map<T> objects, use
* the 'in' operator.
*
* @param map A map-like.
* @param key A property key.
*/
function hasProperty(map, key) {
return hasOwnProperty.call(map, key);
}
ts.hasProperty = hasProperty;
/**
* Gets the value of an owned property in a map-like.
*
* NOTE: This is intended for use only with MapLike<T> objects. For Map<T> objects, use
* an indexer.
*
* @param map A map-like.
* @param key A property key.
*/
function getProperty(map, key) {
return hasOwnProperty.call(map, key) ? map[key] : undefined;
}
ts.getProperty = getProperty;
/**
* Gets the owned, enumerable property keys of a map-like.
*
* NOTE: This is intended for use with MapLike<T> objects. For Map<T> objects, use
* Object.keys instead as it offers better performance.
*
* @param map A map-like.
*/
function getOwnKeys(map) {
var keys = [];
for (var key in map)
if (hasOwnProperty.call(map, key)) {
keys.push(key);
}
return keys;
}
ts.getOwnKeys = getOwnKeys;
/**
* Enumerates the properties of a Map<T>, invoking a callback and returning the first truthy result.
*
* @param map A map for which properties should be enumerated.
* @param callback A callback to invoke for each property.
*/
function forEachProperty(map, callback) {
var result;
for (var key in map) {
if (result = callback(map[key], key))
break;
}
return result;
}
ts.forEachProperty = forEachProperty;
/**
* Returns true if a Map<T> has some matching property.
*
* @param map A map whose properties should be tested.
* @param predicate An optional callback used to test each property.
*/
function someProperties(map, predicate) {
for (var key in map) {
if (!predicate || predicate(map[key], key))
return true;
}
return false;
}
ts.someProperties = someProperties;
/**
* Performs a shallow copy of the properties from a source Map<T> to a target MapLike<T>
*
* @param source A map from which properties should be copied.
* @param target A map to which properties should be copied.
*/
function copyProperties(source, target) {
for (var key in source) {
target[key] = source[key];
}
}
ts.copyProperties = copyProperties;
function assign(t) {
var args = [];
for (var _i = 1; _i < arguments.length; _i++) {
args[_i - 1] = arguments[_i];
}
for (var _a = 0, args_1 = args; _a < args_1.length; _a++) {
var arg = args_1[_a];
for (var _b = 0, _c = getOwnKeys(arg); _b < _c.length; _b++) {
var p = _c[_b];
t[p] = arg[p];
}
}
return t;
}
ts.assign = assign;
/**
* Reduce the properties of a map.
*
* NOTE: This is intended for use with Map<T> objects. For MapLike<T> objects, use
* reduceOwnProperties instead as it offers better runtime safety.
*
* @param map The map to reduce
* @param callback An aggregation function that is called for each entry in the map
* @param initial The initial value for the reduction.
*/
function reduceProperties(map, callback, initial) {
var result = initial;
for (var key in map) {
result = callback(result, map[key], String(key));
}
return result;
}
ts.reduceProperties = reduceProperties;
/**
* Reduce the properties defined on a map-like (but not from its prototype chain).
*
* NOTE: This is intended for use with MapLike<T> objects. For Map<T> objects, use
* reduceProperties instead as it offers better performance.
*
* @param map The map-like to reduce
* @param callback An aggregation function that is called for each entry in the map
* @param initial The initial value for the reduction.
*/
function reduceOwnProperties(map, callback, initial) {
var result = initial;
for (var key in map)
if (hasOwnProperty.call(map, key)) {
result = callback(result, map[key], String(key));
}
return result;
}
ts.reduceOwnProperties = reduceOwnProperties;
/**
* Performs a shallow equality comparison of the contents of two map-likes.
*
* @param left A map-like whose properties should be compared.
* @param right A map-like whose properties should be compared.
*/
function equalOwnProperties(left, right, equalityComparer) {
if (left === right)
return true;
if (!left || !right)
return false;
for (var key in left)
if (hasOwnProperty.call(left, key)) {
if (!hasOwnProperty.call(right, key) === undefined)
return false;
if (equalityComparer ? !equalityComparer(left[key], right[key]) : left[key] !== right[key])
return false;
}
for (var key in right)
if (hasOwnProperty.call(right, key)) {
if (!hasOwnProperty.call(left, key))
return false;
}
return true;
}
ts.equalOwnProperties = equalOwnProperties;
function arrayToMap(array, makeKey, makeValue) {
var result = createMap();
for (var _i = 0, array_8 = array; _i < array_8.length; _i++) {
var value = array_8[_i];
result[makeKey(value)] = makeValue ? makeValue(value) : value;
}
return result;
}
ts.arrayToMap = arrayToMap;
function isEmpty(map) {
for (var id in map) {
if (hasProperty(map, id)) {
return false;
}
}
return true;
}
ts.isEmpty = isEmpty;
function cloneMap(map) {
var clone = createMap();
copyProperties(map, clone);
return clone;
}
ts.cloneMap = cloneMap;
function clone(object) {
var result = {};
for (var id in object) {
if (hasOwnProperty.call(object, id)) {
result[id] = object[id];
}
}
return result;
}
ts.clone = clone;
function extend(first, second) {
var result = {};
for (var id in second)
if (hasOwnProperty.call(second, id)) {
result[id] = second[id];
}
for (var id in first)
if (hasOwnProperty.call(first, id)) {
result[id] = first[id];
}
return result;
}
ts.extend = extend;
/**
* Adds the value to an array of values associated with the key, and returns the array.
* Creates the array if it does not already exist.
*/
function multiMapAdd(map, key, value) {
var values = map[key];
if (values) {
values.push(value);
return values;
}
else {
return map[key] = [value];
}
}
ts.multiMapAdd = multiMapAdd;
/**
* Removes a value from an array of values associated with the key.
* Does not preserve the order of those values.
* Does nothing if `key` is not in `map`, or `value` is not in `map[key]`.
*/
function multiMapRemove(map, key, value) {
var values = map[key];
if (values) {
unorderedRemoveItem(values, value);
if (!values.length) {
delete map[key];
}
}
}
ts.multiMapRemove = multiMapRemove;
/**
* Tests whether a value is an array.
*/
function isArray(value) {
return Array.isArray ? Array.isArray(value) : value instanceof Array;
}
ts.isArray = isArray;
/** Does nothing. */
function noop() { }
ts.noop = noop;
/** Throws an error because a function is not implemented. */
function notImplemented() {
throw new Error("Not implemented");
}
ts.notImplemented = notImplemented;
function memoize(callback) {
var value;
return function () {
if (callback) {
value = callback();
callback = undefined;
}
return value;
};
}
ts.memoize = memoize;
function chain(a, b, c, d, e) {
if (e) {
var args_2 = [];
for (var i = 0; i < arguments.length; i++) {
args_2[i] = arguments[i];
}
return function (t) { return compose.apply(void 0, map(args_2, function (f) { return f(t); })); };
}
else if (d) {
return function (t) { return compose(a(t), b(t), c(t), d(t)); };
}
else if (c) {
return function (t) { return compose(a(t), b(t), c(t)); };
}
else if (b) {
return function (t) { return compose(a(t), b(t)); };
}
else if (a) {
return function (t) { return compose(a(t)); };
}
else {
return function (_) { return function (u) { return u; }; };
}
}
ts.chain = chain;
function compose(a, b, c, d, e) {
if (e) {
var args_3 = [];
for (var i = 0; i < arguments.length; i++) {
args_3[i] = arguments[i];
}
return function (t) { return reduceLeft(args_3, function (u, f) { return f(u); }, t); };
}
else if (d) {
return function (t) { return d(c(b(a(t)))); };
}
else if (c) {
return function (t) { return c(b(a(t))); };
}
else if (b) {
return function (t) { return b(a(t)); };
}
else if (a) {
return function (t) { return a(t); };
}
else {
return function (t) { return t; };
}
}
ts.compose = compose;
function formatStringFromArgs(text, args, baseIndex) {
baseIndex = baseIndex || 0;
return text.replace(/{(\d+)}/g, function (_match, index) { return args[+index + baseIndex]; });
}
ts.localizedDiagnosticMessages = undefined;
function getLocaleSpecificMessage(message) {
return ts.localizedDiagnosticMessages && ts.localizedDiagnosticMessages[message.key] || message.message;
}
ts.getLocaleSpecificMessage = getLocaleSpecificMessage;
function createFileDiagnostic(file, start, length, message) {
var end = start + length;
Debug.assert(start >= 0, "start must be non-negative, is " + start);
Debug.assert(length >= 0, "length must be non-negative, is " + length);
if (file) {
Debug.assert(start <= file.text.length, "start must be within the bounds of the file. " + start + " > " + file.text.length);
Debug.assert(end <= file.text.length, "end must be the bounds of the file. " + end + " > " + file.text.length);
}
var text = getLocaleSpecificMessage(message);
if (arguments.length > 4) {
text = formatStringFromArgs(text, arguments, 4);
}
return {
file: file,
start: start,
length: length,
messageText: text,
category: message.category,
code: message.code,
};
}
ts.createFileDiagnostic = createFileDiagnostic;
/* internal */
function formatMessage(_dummy, message) {
var text = getLocaleSpecificMessage(message);
if (arguments.length > 2) {
text = formatStringFromArgs(text, arguments, 2);
}
return text;
}
ts.formatMessage = formatMessage;
function createCompilerDiagnostic(message) {
var text = getLocaleSpecificMessage(message);
if (arguments.length > 1) {
text = formatStringFromArgs(text, arguments, 1);
}
return {
file: undefined,
start: undefined,
length: undefined,
messageText: text,
category: message.category,
code: message.code
};
}
ts.createCompilerDiagnostic = createCompilerDiagnostic;
function createCompilerDiagnosticFromMessageChain(chain) {
return {
file: undefined,
start: undefined,
length: undefined,
code: chain.code,
category: chain.category,
messageText: chain.next ? chain : chain.messageText
};
}
ts.createCompilerDiagnosticFromMessageChain = createCompilerDiagnosticFromMessageChain;
function chainDiagnosticMessages(details, message) {
var text = getLocaleSpecificMessage(message);
if (arguments.length > 2) {
text = formatStringFromArgs(text, arguments, 2);
}
return {
messageText: text,
category: message.category,
code: message.code,
next: details
};
}
ts.chainDiagnosticMessages = chainDiagnosticMessages;
function concatenateDiagnosticMessageChains(headChain, tailChain) {
var lastChain = headChain;
while (lastChain.next) {
lastChain = lastChain.next;
}
lastChain.next = tailChain;
return headChain;
}
ts.concatenateDiagnosticMessageChains = concatenateDiagnosticMessageChains;
function compareValues(a, b) {
if (a === b)
return 0 /* EqualTo */;
if (a === undefined)
return -1 /* LessThan */;
if (b === undefined)
return 1 /* GreaterThan */;
return a < b ? -1 /* LessThan */ : 1 /* GreaterThan */;
}
ts.compareValues = compareValues;
function compareStrings(a, b, ignoreCase) {
if (a === b)
return 0 /* EqualTo */;
if (a === undefined)
return -1 /* LessThan */;
if (b === undefined)
return 1 /* GreaterThan */;
if (ignoreCase) {
if (ts.collator && String.prototype.localeCompare) {
// accent means a ≠ b, a ≠ á, a = A
var result = a.localeCompare(b, /*locales*/ undefined, { usage: "sort", sensitivity: "accent" });
return result < 0 ? -1 /* LessThan */ : result > 0 ? 1 /* GreaterThan */ : 0 /* EqualTo */;
}
a = a.toUpperCase();
b = b.toUpperCase();
if (a === b)
return 0 /* EqualTo */;
}
return a < b ? -1 /* LessThan */ : 1 /* GreaterThan */;
}
ts.compareStrings = compareStrings;
function compareStringsCaseInsensitive(a, b) {
return compareStrings(a, b, /*ignoreCase*/ true);
}
ts.compareStringsCaseInsensitive = compareStringsCaseInsensitive;
function getDiagnosticFileName(diagnostic) {
return diagnostic.file ? diagnostic.file.fileName : undefined;
}
function compareDiagnostics(d1, d2) {
return compareValues(getDiagnosticFileName(d1), getDiagnosticFileName(d2)) ||
compareValues(d1.start, d2.start) ||
compareValues(d1.length, d2.length) ||
compareValues(d1.code, d2.code) ||
compareMessageText(d1.messageText, d2.messageText) ||
0 /* EqualTo */;
}
ts.compareDiagnostics = compareDiagnostics;
function compareMessageText(text1, text2) {
while (text1 && text2) {
// We still have both chains.
var string1 = typeof text1 === "string" ? text1 : text1.messageText;
var string2 = typeof text2 === "string" ? text2 : text2.messageText;
var res = compareValues(string1, string2);
if (res) {
return res;
}
text1 = typeof text1 === "string" ? undefined : text1.next;
text2 = typeof text2 === "string" ? undefined : text2.next;
}
if (!text1 && !text2) {
// if the chains are done, then these messages are the same.
return 0 /* EqualTo */;
}
// We still have one chain remaining. The shorter chain should come first.
return text1 ? 1 /* GreaterThan */ : -1 /* LessThan */;
}
function sortAndDeduplicateDiagnostics(diagnostics) {
return deduplicateSortedDiagnostics(diagnostics.sort(compareDiagnostics));
}
ts.sortAndDeduplicateDiagnostics = sortAndDeduplicateDiagnostics;
function deduplicateSortedDiagnostics(diagnostics) {
if (diagnostics.length < 2) {
return diagnostics;
}
var newDiagnostics = [diagnostics[0]];
var previousDiagnostic = diagnostics[0];
for (var i = 1; i < diagnostics.length; i++) {
var currentDiagnostic = diagnostics[i];
var isDupe = compareDiagnostics(currentDiagnostic, previousDiagnostic) === 0 /* EqualTo */;
if (!isDupe) {
newDiagnostics.push(currentDiagnostic);
previousDiagnostic = currentDiagnostic;
}
}
return newDiagnostics;
}
ts.deduplicateSortedDiagnostics = deduplicateSortedDiagnostics;
function normalizeSlashes(path) {
return path.replace(/\\/g, "/");
}
ts.normalizeSlashes = normalizeSlashes;
/**
* Returns length of path root (i.e. length of "/", "x:/", "//server/share/, file:///user/files")
*/
function getRootLength(path) {
if (path.charCodeAt(0) === 47 /* slash */) {
if (path.charCodeAt(1) !== 47 /* slash */)
return 1;
var p1 = path.indexOf("/", 2);
if (p1 < 0)
return 2;
var p2 = path.indexOf("/", p1 + 1);
if (p2 < 0)
return p1 + 1;
return p2 + 1;
}
if (path.charCodeAt(1) === 58 /* colon */) {
if (path.charCodeAt(2) === 47 /* slash */)
return 3;
return 2;
}
// Per RFC 1738 'file' URI schema has the shape file://<host>/<path>
// if <host> is omitted then it is assumed that host value is 'localhost',
// however slash after the omitted <host> is not removed.
// file:///folder1/file1 - this is a correct URI
// file://folder2/file2 - this is an incorrect URI
if (path.lastIndexOf("file:///", 0) === 0) {
return "file:///".length;
}
var idx = path.indexOf("://");
if (idx !== -1) {
return idx + "://".length;
}
return 0;
}
ts.getRootLength = getRootLength;
/**
* Internally, we represent paths as strings with '/' as the directory separator.
* When we make system calls (eg: LanguageServiceHost.getDirectory()),
* we expect the host to correctly handle paths in our specified format.
*/
ts.directorySeparator = "/";
var directorySeparatorCharCode = 47 /* slash */;
function getNormalizedParts(normalizedSlashedPath, rootLength) {
var parts = normalizedSlashedPath.substr(rootLength).split(ts.directorySeparator);
var normalized = [];
for (var _i = 0, parts_1 = parts; _i < parts_1.length; _i++) {
var part = parts_1[_i];
if (part !== ".") {
if (part === ".." && normalized.length > 0 && lastOrUndefined(normalized) !== "..") {
normalized.pop();
}
else {
// A part may be an empty string (which is 'falsy') if the path had consecutive slashes,
// e.g. "path//file.ts". Drop these before re-joining the parts.
if (part) {
normalized.push(part);
}
}
}
}
return normalized;
}
function normalizePath(path) {
path = normalizeSlashes(path);
var rootLength = getRootLength(path);
var root = path.substr(0, rootLength);
var normalized = getNormalizedParts(path, rootLength);
if (normalized.length) {
var joinedParts = root + normalized.join(ts.directorySeparator);
return pathEndsWithDirectorySeparator(path) ? joinedParts + ts.directorySeparator : joinedParts;
}
else {
return root;
}
}
ts.normalizePath = normalizePath;
/** A path ending with '/' refers to a directory only, never a file. */
function pathEndsWithDirectorySeparator(path) {
return path.charCodeAt(path.length - 1) === directorySeparatorCharCode;
}
ts.pathEndsWithDirectorySeparator = pathEndsWithDirectorySeparator;
function getDirectoryPath(path) {
return path.substr(0, Math.max(getRootLength(path), path.lastIndexOf(ts.directorySeparator)));
}
ts.getDirectoryPath = getDirectoryPath;
function isUrl(path) {
return path && !isRootedDiskPath(path) && path.indexOf("://") !== -1;
}
ts.isUrl = isUrl;
function isExternalModuleNameRelative(moduleName) {
// TypeScript 1.0 spec (April 2014): 11.2.1
// An external module name is "relative" if the first term is "." or "..".
return /^\.\.?($|[\\/])/.test(moduleName);
}
ts.isExternalModuleNameRelative = isExternalModuleNameRelative;
function getEmitScriptTarget(compilerOptions) {
return compilerOptions.target || 0 /* ES3 */;
}
ts.getEmitScriptTarget = getEmitScriptTarget;
function getEmitModuleKind(compilerOptions) {
return typeof compilerOptions.module === "number" ?
compilerOptions.module :
getEmitScriptTarget(compilerOptions) >= 2 /* ES2015 */ ? ts.ModuleKind.ES2015 : ts.ModuleKind.CommonJS;
}
ts.getEmitModuleKind = getEmitModuleKind;
/* @internal */
function hasZeroOrOneAsteriskCharacter(str) {
var seenAsterisk = false;
for (var i = 0; i < str.length; i++) {
if (str.charCodeAt(i) === 42 /* asterisk */) {
if (!seenAsterisk) {
seenAsterisk = true;
}
else {
// have already seen asterisk
return false;
}
}
}
return true;
}
ts.hasZeroOrOneAsteriskCharacter = hasZeroOrOneAsteriskCharacter;
function isRootedDiskPath(path) {
return getRootLength(path) !== 0;
}
ts.isRootedDiskPath = isRootedDiskPath;
function convertToRelativePath(absoluteOrRelativePath, basePath, getCanonicalFileName) {
return !isRootedDiskPath(absoluteOrRelativePath)
? absoluteOrRelativePath
: getRelativePathToDirectoryOrUrl(basePath, absoluteOrRelativePath, basePath, getCanonicalFileName, /*isAbsolutePathAnUrl*/ false);
}
ts.convertToRelativePath = convertToRelativePath;
function normalizedPathComponents(path, rootLength) {
var normalizedParts = getNormalizedParts(path, rootLength);
return [path.substr(0, rootLength)].concat(normalizedParts);
}
function getNormalizedPathComponents(path, currentDirectory) {
path = normalizeSlashes(path);
var rootLength = getRootLength(path);
if (rootLength === 0) {
// If the path is not rooted it is relative to current directory
path = combinePaths(normalizeSlashes(currentDirectory), path);
rootLength = getRootLength(path);
}
return normalizedPathComponents(path, rootLength);
}
ts.getNormalizedPathComponents = getNormalizedPathComponents;
function getNormalizedAbsolutePath(fileName, currentDirectory) {
return getNormalizedPathFromPathComponents(getNormalizedPathComponents(fileName, currentDirectory));
}
ts.getNormalizedAbsolutePath = getNormalizedAbsolutePath;
function getNormalizedPathFromPathComponents(pathComponents) {
if (pathComponents && pathComponents.length) {
return pathComponents[0] + pathComponents.slice(1).join(ts.directorySeparator);
}
}
ts.getNormalizedPathFromPathComponents = getNormalizedPathFromPathComponents;
function getNormalizedPathComponentsOfUrl(url) {
// Get root length of http://www.website.com/folder1/folder2/
// In this example the root is: http://www.website.com/
// normalized path components should be ["http://www.website.com/", "folder1", "folder2"]
var urlLength = url.length;
// Initial root length is http:// part
var rootLength = url.indexOf("://") + "://".length;
while (rootLength < urlLength) {
// Consume all immediate slashes in the protocol
// eg.initial rootlength is just file:// but it needs to consume another "/" in file:///
if (url.charCodeAt(rootLength) === 47 /* slash */) {
rootLength++;
}
else {
// non slash character means we continue proceeding to next component of root search
break;
}
}
// there are no parts after http:// just return current string as the pathComponent
if (rootLength === urlLength) {
return [url];
}
// Find the index of "/" after website.com so the root can be http://www.website.com/ (from existing http://)
var indexOfNextSlash = url.indexOf(ts.directorySeparator, rootLength);
if (indexOfNextSlash !== -1) {
// Found the "/" after the website.com so the root is length of http://www.website.com/
// and get components after the root normally like any other folder components
rootLength = indexOfNextSlash + 1;
return normalizedPathComponents(url, rootLength);
}
else {
// Can't find the host assume the rest of the string as component
// but make sure we append "/" to it as root is not joined using "/"
// eg. if url passed in was http://website.com we want to use root as [http://website.com/]
// so that other path manipulations will be correct and it can be merged with relative paths correctly
return [url + ts.directorySeparator];
}
}
function getNormalizedPathOrUrlComponents(pathOrUrl, currentDirectory) {
if (isUrl(pathOrUrl)) {
return getNormalizedPathComponentsOfUrl(pathOrUrl);
}
else {
return getNormalizedPathComponents(pathOrUrl, currentDirectory);
}
}
function getRelativePathToDirectoryOrUrl(directoryPathOrUrl, relativeOrAbsolutePath, currentDirectory, getCanonicalFileName, isAbsolutePathAnUrl) {
var pathComponents = getNormalizedPathOrUrlComponents(relativeOrAbsolutePath, currentDirectory);
var directoryComponents = getNormalizedPathOrUrlComponents(directoryPathOrUrl, currentDirectory);
if (directoryComponents.length > 1 && lastOrUndefined(directoryComponents) === "") {
// If the directory path given was of type test/cases/ then we really need components of directory to be only till its name
// that is ["test", "cases", ""] needs to be actually ["test", "cases"]
directoryComponents.length--;
}
// Find the component that differs
var joinStartIndex;
for (joinStartIndex = 0; joinStartIndex < pathComponents.length && joinStartIndex < directoryComponents.length; joinStartIndex++) {
if (getCanonicalFileName(directoryComponents[joinStartIndex]) !== getCanonicalFileName(pathComponents[joinStartIndex])) {
break;
}
}
// Get the relative path
if (joinStartIndex) {
var relativePath = "";
var relativePathComponents = pathComponents.slice(joinStartIndex, pathComponents.length);
for (; joinStartIndex < directoryComponents.length; joinStartIndex++) {
if (directoryComponents[joinStartIndex] !== "") {
relativePath = relativePath + ".." + ts.directorySeparator;
}
}
return relativePath + relativePathComponents.join(ts.directorySeparator);
}
// Cant find the relative path, get the absolute path
var absolutePath = getNormalizedPathFromPathComponents(pathComponents);
if (isAbsolutePathAnUrl && isRootedDiskPath(absolutePath)) {
absolutePath = "file:///" + absolutePath;
}
return absolutePath;
}
ts.getRelativePathToDirectoryOrUrl = getRelativePathToDirectoryOrUrl;
function getBaseFileName(path) {
if (path === undefined) {
return undefined;
}
var i = path.lastIndexOf(ts.directorySeparator);
return i < 0 ? path : path.substring(i + 1);
}
ts.getBaseFileName = getBaseFileName;
function combinePaths(path1, path2) {
if (!(path1 && path1.length))
return path2;
if (!(path2 && path2.length))
return path1;
if (getRootLength(path2) !== 0)
return path2;
if (path1.charAt(path1.length - 1) === ts.directorySeparator)
return path1 + path2;
return path1 + ts.directorySeparator + path2;
}
ts.combinePaths = combinePaths;
/**
* Removes a trailing directory separator from a path.
* @param path The path.
*/
function removeTrailingDirectorySeparator(path) {
if (path.charAt(path.length - 1) === ts.directorySeparator) {
return path.substr(0, path.length - 1);
}
return path;
}
ts.removeTrailingDirectorySeparator = removeTrailingDirectorySeparator;
/**
* Adds a trailing directory separator to a path, if it does not already have one.
* @param path The path.
*/
function ensureTrailingDirectorySeparator(path) {
if (path.charAt(path.length - 1) !== ts.directorySeparator) {
return path + ts.directorySeparator;
}
return path;
}
ts.ensureTrailingDirectorySeparator = ensureTrailingDirectorySeparator;
function comparePaths(a, b, currentDirectory, ignoreCase) {
if (a === b)
return 0 /* EqualTo */;
if (a === undefined)
return -1 /* LessThan */;
if (b === undefined)
return 1 /* GreaterThan */;
a = removeTrailingDirectorySeparator(a);
b = removeTrailingDirectorySeparator(b);
var aComponents = getNormalizedPathComponents(a, currentDirectory);
var bComponents = getNormalizedPathComponents(b, currentDirectory);
var sharedLength = Math.min(aComponents.length, bComponents.length);
for (var i = 0; i < sharedLength; i++) {
var result = compareStrings(aComponents[i], bComponents[i], ignoreCase);
if (result !== 0 /* EqualTo */) {
return result;
}
}
return compareValues(aComponents.length, bComponents.length);
}
ts.comparePaths = comparePaths;
function containsPath(parent, child, currentDirectory, ignoreCase) {
if (parent === undefined || child === undefined)
return false;
if (parent === child)
return true;
parent = removeTrailingDirectorySeparator(parent);
child = removeTrailingDirectorySeparator(child);
if (parent === child)
return true;
var parentComponents = getNormalizedPathComponents(parent, currentDirectory);
var childComponents = getNormalizedPathComponents(child, currentDirectory);
if (childComponents.length < parentComponents.length) {
return false;
}
for (var i = 0; i < parentComponents.length; i++) {
var result = compareStrings(parentComponents[i], childComponents[i], ignoreCase);
if (result !== 0 /* EqualTo */) {
return false;
}
}
return true;
}
ts.containsPath = containsPath;
/* @internal */
function startsWith(str, prefix) {
return str.lastIndexOf(prefix, 0) === 0;
}
ts.startsWith = startsWith;
/* @internal */
function endsWith(str, suffix) {
var expectedPos = str.length - suffix.length;
return expectedPos >= 0 && str.indexOf(suffix, expectedPos) === expectedPos;
}
ts.endsWith = endsWith;
function hasExtension(fileName) {
return getBaseFileName(fileName).indexOf(".") >= 0;
}
ts.hasExtension = hasExtension;
function fileExtensionIs(path, extension) {
return path.length > extension.length && endsWith(path, extension);
}
ts.fileExtensionIs = fileExtensionIs;
function fileExtensionIsAny(path, extensions) {
for (var _i = 0, extensions_1 = extensions; _i < extensions_1.length; _i++) {
var extension = extensions_1[_i];
if (fileExtensionIs(path, extension)) {
return true;
}
}
return false;
}
ts.fileExtensionIsAny = fileExtensionIsAny;
// Reserved characters, forces escaping of any non-word (or digit), non-whitespace character.
// It may be inefficient (we could just match (/[-[\]{}()*+?.,\\^$|#\s]/g), but this is future
// proof.
var reservedCharacterPattern = /[^\w\s\/]/g;
var wildcardCharCodes = [42 /* asterisk */, 63 /* question */];
/**
* Matches any single directory segment unless it is the last segment and a .min.js file
* Breakdown:
* [^./] # matches everything up to the first . character (excluding directory seperators)
* (\\.(?!min\\.js$))? # matches . characters but not if they are part of the .min.js file extension
*/
var singleAsteriskRegexFragmentFiles = "([^./]|(\\.(?!min\\.js$))?)*";
var singleAsteriskRegexFragmentOther = "[^/]*";
function getRegularExpressionForWildcard(specs, basePath, usage) {
if (specs === undefined || specs.length === 0) {
return undefined;
}
var replaceWildcardCharacter = usage === "files" ? replaceWildCardCharacterFiles : replaceWildCardCharacterOther;
var singleAsteriskRegexFragment = usage === "files" ? singleAsteriskRegexFragmentFiles : singleAsteriskRegexFragmentOther;
/**
* Regex for the ** wildcard. Matches any number of subdirectories. When used for including
* files or directories, does not match subdirectories that start with a . character
*/
var doubleAsteriskRegexFragment = usage === "exclude" ? "(/.+?)?" : "(/[^/.][^/]*)*?";
var pattern = "";
var hasWrittenSubpattern = false;
for (var _i = 0, specs_1 = specs; _i < specs_1.length; _i++) {
var spec = specs_1[_i];
if (!spec) {
continue;
}
var subPattern = getSubPatternFromSpec(spec, basePath, usage, singleAsteriskRegexFragment, doubleAsteriskRegexFragment, replaceWildcardCharacter);
if (subPattern === undefined) {
continue;
}
if (hasWrittenSubpattern) {
pattern += "|";
}
pattern += "(" + subPattern + ")";
hasWrittenSubpattern = true;
}
if (!pattern) {
return undefined;
}
// If excluding, match "foo/bar/baz...", but if including, only allow "foo".
var terminator = usage === "exclude" ? "($|/)" : "$";
return "^(" + pattern + ")" + terminator;
}
ts.getRegularExpressionForWildcard = getRegularExpressionForWildcard;
/**
* An "includes" path "foo" is implicitly a glob "foo/** /*" (without the space) if its last component has no extension,
* and does not contain any glob characters itself.
*/
function isImplicitGlob(lastPathComponent) {
return !/[.*?]/.test(lastPathComponent);
}
ts.isImplicitGlob = isImplicitGlob;
function getSubPatternFromSpec(spec, basePath, usage, singleAsteriskRegexFragment, doubleAsteriskRegexFragment, replaceWildcardCharacter) {
var subpattern = "";
var hasRecursiveDirectoryWildcard = false;
var hasWrittenComponent = false;
var components = getNormalizedPathComponents(spec, basePath);
var lastComponent = lastOrUndefined(components);
if (usage !== "exclude" && lastComponent === "**") {
return undefined;
}
// getNormalizedPathComponents includes the separator for the root component.
// We need to remove to create our regex correctly.
components[0] = removeTrailingDirectorySeparator(components[0]);
if (isImplicitGlob(lastComponent)) {
components.push("**", "*");
}
var optionalCount = 0;
for (var _i = 0, components_1 = components; _i < components_1.length; _i++) {
var component = components_1[_i];
if (component === "**") {
if (hasRecursiveDirectoryWildcard) {
return undefined;
}
subpattern += doubleAsteriskRegexFragment;
hasRecursiveDirectoryWildcard = true;
}
else {
if (usage === "directories") {
subpattern += "(";
optionalCount++;
}
if (hasWrittenComponent) {
subpattern += ts.directorySeparator;
}
if (usage !== "exclude") {
// The * and ? wildcards should not match directories or files that start with . if they
// appear first in a component. Dotted directories and files can be included explicitly
// like so: **/.*/.*
if (component.charCodeAt(0) === 42 /* asterisk */) {
subpattern += "([^./]" + singleAsteriskRegexFragment + ")?";
component = component.substr(1);
}
else if (component.charCodeAt(0) === 63 /* question */) {
subpattern += "[^./]";
component = component.substr(1);
}
}
subpattern += component.replace(reservedCharacterPattern, replaceWildcardCharacter);
}
hasWrittenComponent = true;
}
while (optionalCount > 0) {
subpattern += ")?";
optionalCount--;
}
return subpattern;
}
function replaceWildCardCharacterFiles(match) {
return replaceWildcardCharacter(match, singleAsteriskRegexFragmentFiles);
}
function replaceWildCardCharacterOther(match) {
return replaceWildcardCharacter(match, singleAsteriskRegexFragmentOther);
}
function replaceWildcardCharacter(match, singleAsteriskRegexFragment) {
return match === "*" ? singleAsteriskRegexFragment : match === "?" ? "[^/]" : "\\" + match;
}
function getFileMatcherPatterns(path, excludes, includes, useCaseSensitiveFileNames, currentDirectory) {
path = normalizePath(path);
currentDirectory = normalizePath(currentDirectory);
var absolutePath = combinePaths(currentDirectory, path);
return {
includeFilePattern: getRegularExpressionForWildcard(includes, absolutePath, "files"),
includeDirectoryPattern: getRegularExpressionForWildcard(includes, absolutePath, "directories"),
excludePattern: getRegularExpressionForWildcard(excludes, absolutePath, "exclude"),
basePaths: getBasePaths(path, includes, useCaseSensitiveFileNames)
};
}
ts.getFileMatcherPatterns = getFileMatcherPatterns;
function matchFiles(path, extensions, excludes, includes, useCaseSensitiveFileNames, currentDirectory, getFileSystemEntries) {
path = normalizePath(path);
currentDirectory = normalizePath(currentDirectory);
var patterns = getFileMatcherPatterns(path, excludes, includes, useCaseSensitiveFileNames, currentDirectory);
var regexFlag = useCaseSensitiveFileNames ? "" : "i";
var includeFileRegex = patterns.includeFilePattern && new RegExp(patterns.includeFilePattern, regexFlag);
var includeDirectoryRegex = patterns.includeDirectoryPattern && new RegExp(patterns.includeDirectoryPattern, regexFlag);
var excludeRegex = patterns.excludePattern && new RegExp(patterns.excludePattern, regexFlag);
var result = [];
for (var _i = 0, _a = patterns.basePaths; _i < _a.length; _i++) {
var basePath = _a[_i];
visitDirectory(basePath, combinePaths(currentDirectory, basePath));
}
return result;
function visitDirectory(path, absolutePath) {
var _a = getFileSystemEntries(path), files = _a.files, directories = _a.directories;
for (var _i = 0, files_1 = files; _i < files_1.length; _i++) {
var current = files_1[_i];
var name_1 = combinePaths(path, current);
var absoluteName = combinePaths(absolutePath, current);
if ((!extensions || fileExtensionIsAny(name_1, extensions)) &&
(!includeFileRegex || includeFileRegex.test(absoluteName)) &&
(!excludeRegex || !excludeRegex.test(absoluteName))) {
result.push(name_1);
}
}
for (var _b = 0, directories_1 = directories; _b < directories_1.length; _b++) {
var current = directories_1[_b];
var name_2 = combinePaths(path, current);
var absoluteName = combinePaths(absolutePath, current);
if ((!includeDirectoryRegex || includeDirectoryRegex.test(absoluteName)) &&
(!excludeRegex || !excludeRegex.test(absoluteName))) {
visitDirectory(name_2, absoluteName);
}
}
}
}
ts.matchFiles = matchFiles;
/**
* Computes the unique non-wildcard base paths amongst the provided include patterns.
*/
function getBasePaths(path, includes, useCaseSensitiveFileNames) {
// Storage for our results in the form of literal paths (e.g. the paths as written by the user).
var basePaths = [path];
if (includes) {
// Storage for literal base paths amongst the include patterns.
var includeBasePaths = [];
for (var _i = 0, includes_1 = includes; _i < includes_1.length; _i++) {
var include = includes_1[_i];
// We also need to check the relative paths by converting them to absolute and normalizing
// in case they escape the base path (e.g "..\somedirectory")
var absolute = isRootedDiskPath(include) ? include : normalizePath(combinePaths(path, include));
// Append the literal and canonical candidate base paths.
includeBasePaths.push(getIncludeBasePath(absolute));
}
// Sort the offsets array using either the literal or canonical path representations.
includeBasePaths.sort(useCaseSensitiveFileNames ? compareStrings : compareStringsCaseInsensitive);
var _loop_1 = function (includeBasePath) {
if (ts.every(basePaths, function (basePath) { return !containsPath(basePath, includeBasePath, path, !useCaseSensitiveFileNames); })) {
basePaths.push(includeBasePath);
}
};
// Iterate over each include base path and include unique base paths that are not a
// subpath of an existing base path
for (var _a = 0, includeBasePaths_1 = includeBasePaths; _a < includeBasePaths_1.length; _a++) {
var includeBasePath = includeBasePaths_1[_a];
_loop_1(includeBasePath);
}
}
return basePaths;
}
function getIncludeBasePath(absolute) {
var wildcardOffset = indexOfAnyCharCode(absolute, wildcardCharCodes);
if (wildcardOffset < 0) {
// No "*" or "?" in the path
return !hasExtension(absolute)
? absolute
: removeTrailingDirectorySeparator(getDirectoryPath(absolute));
}
return absolute.substring(0, absolute.lastIndexOf(ts.directorySeparator, wildcardOffset));
}
function ensureScriptKind(fileName, scriptKind) {
// Using scriptKind as a condition handles both:
// - 'scriptKind' is unspecified and thus it is `undefined`
// - 'scriptKind' is set and it is `Unknown` (0)
// If the 'scriptKind' is 'undefined' or 'Unknown' then we attempt
// to get the ScriptKind from the file name. If it cannot be resolved
// from the file name then the default 'TS' script kind is returned.
return (scriptKind || getScriptKindFromFileName(fileName)) || 3 /* TS */;
}
ts.ensureScriptKind = ensureScriptKind;
function getScriptKindFromFileName(fileName) {
var ext = fileName.substr(fileName.lastIndexOf("."));
switch (ext.toLowerCase()) {
case ".js":
return 1 /* JS */;
case ".jsx":
return 2 /* JSX */;
case ".ts":
return 3 /* TS */;
case ".tsx":
return 4 /* TSX */;
default:
return 0 /* Unknown */;
}
}
ts.getScriptKindFromFileName = getScriptKindFromFileName;
/**
* List of supported extensions in order of file resolution precedence.
*/
ts.supportedTypeScriptExtensions = [".ts", ".tsx", ".d.ts"];
/** Must have ".d.ts" first because if ".ts" goes first, that will be detected as the extension instead of ".d.ts". */
ts.supportedTypescriptExtensionsForExtractExtension = [".d.ts", ".ts", ".tsx"];
ts.supportedJavascriptExtensions = [".js", ".jsx"];
var allSupportedExtensions = ts.supportedTypeScriptExtensions.concat(ts.supportedJavascriptExtensions);
function getSupportedExtensions(options) {
return options && options.allowJs ? allSupportedExtensions : ts.supportedTypeScriptExtensions;
}
ts.getSupportedExtensions = getSupportedExtensions;
function hasJavaScriptFileExtension(fileName) {
return forEach(ts.supportedJavascriptExtensions, function (extension) { return fileExtensionIs(fileName, extension); });
}
ts.hasJavaScriptFileExtension = hasJavaScriptFileExtension;
function hasTypeScriptFileExtension(fileName) {
return forEach(ts.supportedTypeScriptExtensions, function (extension) { return fileExtensionIs(fileName, extension); });
}
ts.hasTypeScriptFileExtension = hasTypeScriptFileExtension;
function isSupportedSourceFileName(fileName, compilerOptions) {
if (!fileName) {
return false;
}
for (var _i = 0, _a = getSupportedExtensions(compilerOptions); _i < _a.length; _i++) {
var extension = _a[_i];
if (fileExtensionIs(fileName, extension)) {
return true;
}
}
return false;
}
ts.isSupportedSourceFileName = isSupportedSourceFileName;
/**
* Extension boundaries by priority. Lower numbers indicate higher priorities, and are
* aligned to the offset of the highest priority extension in the
* allSupportedExtensions array.
*/
var ExtensionPriority;
(function (ExtensionPriority) {
ExtensionPriority[ExtensionPriority["TypeScriptFiles"] = 0] = "TypeScriptFiles";
ExtensionPriority[ExtensionPriority["DeclarationAndJavaScriptFiles"] = 2] = "DeclarationAndJavaScriptFiles";
ExtensionPriority[ExtensionPriority["Limit"] = 5] = "Limit";
ExtensionPriority[ExtensionPriority["Highest"] = 0] = "Highest";
ExtensionPriority[ExtensionPriority["Lowest"] = 2] = "Lowest";
})(ExtensionPriority = ts.ExtensionPriority || (ts.ExtensionPriority = {}));
function getExtensionPriority(path, supportedExtensions) {
for (var i = supportedExtensions.length - 1; i >= 0; i--) {
if (fileExtensionIs(path, supportedExtensions[i])) {
return adjustExtensionPriority(i);
}
}
// If its not in the list of supported extensions, this is likely a
// TypeScript file with a non-ts extension
return 0 /* Highest */;
}
ts.getExtensionPriority = getExtensionPriority;
/**
* Adjusts an extension priority to be the highest priority within the same range.
*/
function adjustExtensionPriority(extensionPriority) {
if (extensionPriority < 2 /* DeclarationAndJavaScriptFiles */) {
return 0 /* TypeScriptFiles */;
}
else if (extensionPriority < 5 /* Limit */) {
return 2 /* DeclarationAndJavaScriptFiles */;
}
else {
return 5 /* Limit */;
}
}
ts.adjustExtensionPriority = adjustExtensionPriority;
/**
* Gets the next lowest extension priority for a given priority.
*/
function getNextLowestExtensionPriority(extensionPriority) {
if (extensionPriority < 2 /* DeclarationAndJavaScriptFiles */) {
return 2 /* DeclarationAndJavaScriptFiles */;
}
else {
return 5 /* Limit */;
}
}
ts.getNextLowestExtensionPriority = getNextLowestExtensionPriority;
var extensionsToRemove = [".d.ts", ".ts", ".js", ".tsx", ".jsx"];
function removeFileExtension(path) {
for (var _i = 0, extensionsToRemove_1 = extensionsToRemove; _i < extensionsToRemove_1.length; _i++) {
var ext = extensionsToRemove_1[_i];
var extensionless = tryRemoveExtension(path, ext);
if (extensionless !== undefined) {
return extensionless;
}
}
return path;
}
ts.removeFileExtension = removeFileExtension;
function tryRemoveExtension(path, extension) {
return fileExtensionIs(path, extension) ? removeExtension(path, extension) : undefined;
}
ts.tryRemoveExtension = tryRemoveExtension;
function removeExtension(path, extension) {
return path.substring(0, path.length - extension.length);
}
ts.removeExtension = removeExtension;
function changeExtension(path, newExtension) {
return (removeFileExtension(path) + newExtension);
}
ts.changeExtension = changeExtension;
function Symbol(flags, name) {
this.flags = flags;
this.name = name;
this.declarations = undefined;
}
function Type(_checker, flags) {
this.flags = flags;
}
function Signature() {
}
function Node(kind, pos, end) {
this.id = 0;
this.kind = kind;
this.pos = pos;
this.end = end;
this.flags = 0 /* None */;
this.modifierFlagsCache = 0 /* None */;
this.transformFlags = 0 /* None */;
this.parent = undefined;
this.original = undefined;
}
ts.objectAllocator = {
getNodeConstructor: function () { return Node; },
getTokenConstructor: function () { return Node; },
getIdentifierConstructor: function () { return Node; },
getSourceFileConstructor: function () { return Node; },
getSymbolConstructor: function () { return Symbol; },
getTypeConstructor: function () { return Type; },
getSignatureConstructor: function () { return Signature; }
};
var AssertionLevel;
(function (AssertionLevel) {
AssertionLevel[AssertionLevel["None"] = 0] = "None";
AssertionLevel[AssertionLevel["Normal"] = 1] = "Normal";
AssertionLevel[AssertionLevel["Aggressive"] = 2] = "Aggressive";
AssertionLevel[AssertionLevel["VeryAggressive"] = 3] = "VeryAggressive";
})(AssertionLevel = ts.AssertionLevel || (ts.AssertionLevel = {}));
var Debug;
(function (Debug) {
Debug.currentAssertionLevel = 0 /* None */;
function shouldAssert(level) {
return Debug.currentAssertionLevel >= level;
}
Debug.shouldAssert = shouldAssert;
function assert(expression, message, verboseDebugInfo) {
if (!expression) {
var verboseDebugString = "";
if (verboseDebugInfo) {
verboseDebugString = "\r\nVerbose Debug Information: " + verboseDebugInfo();
}
debugger;
throw new Error("Debug Failure. False expression: " + (message || "") + verboseDebugString);
}
}
Debug.assert = assert;
function fail(message) {
Debug.assert(/*expression*/ false, message);
}
Debug.fail = fail;
})(Debug = ts.Debug || (ts.Debug = {}));
/** Remove an item from an array, moving everything to its right one space left. */
function orderedRemoveItemAt(array, index) {
// This seems to be faster than either `array.splice(i, 1)` or `array.copyWithin(i, i+ 1)`.
for (var i = index; i < array.length - 1; i++) {
array[i] = array[i + 1];
}
array.pop();
}
ts.orderedRemoveItemAt = orderedRemoveItemAt;
function unorderedRemoveItemAt(array, index) {
// Fill in the "hole" left at `index`.
array[index] = array[array.length - 1];
array.pop();
}
ts.unorderedRemoveItemAt = unorderedRemoveItemAt;
/** Remove the *first* occurrence of `item` from the array. */
function unorderedRemoveItem(array, item) {
unorderedRemoveFirstItemWhere(array, function (element) { return element === item; });
}
ts.unorderedRemoveItem = unorderedRemoveItem;
/** Remove the *first* element satisfying `predicate`. */
function unorderedRemoveFirstItemWhere(array, predicate) {
for (var i = 0; i < array.length; i++) {
if (predicate(array[i])) {
unorderedRemoveItemAt(array, i);
break;
}
}
}
function createGetCanonicalFileName(useCaseSensitiveFileNames) {
return useCaseSensitiveFileNames
? (function (fileName) { return fileName; })
: (function (fileName) { return fileName.toLowerCase(); });
}
ts.createGetCanonicalFileName = createGetCanonicalFileName;
/**
* patternStrings contains both pattern strings (containing "*") and regular strings.
* Return an exact match if possible, or a pattern match, or undefined.
* (These are verified by verifyCompilerOptions to have 0 or 1 "*" characters.)
*/
/* @internal */
function matchPatternOrExact(patternStrings, candidate) {
var patterns = [];
for (var _i = 0, patternStrings_1 = patternStrings; _i < patternStrings_1.length; _i++) {
var patternString = patternStrings_1[_i];
var pattern = tryParsePattern(patternString);
if (pattern) {
patterns.push(pattern);
}
else if (patternString === candidate) {
// pattern was matched as is - no need to search further
return patternString;
}
}
return findBestPatternMatch(patterns, function (_) { return _; }, candidate);
}
ts.matchPatternOrExact = matchPatternOrExact;
/* @internal */
function patternText(_a) {
var prefix = _a.prefix, suffix = _a.suffix;
return prefix + "*" + suffix;
}
ts.patternText = patternText;
/**
* Given that candidate matches pattern, returns the text matching the '*'.
* E.g.: matchedText(tryParsePattern("foo*baz"), "foobarbaz") === "bar"
*/
/* @internal */
function matchedText(pattern, candidate) {
Debug.assert(isPatternMatch(pattern, candidate));
return candidate.substr(pattern.prefix.length, candidate.length - pattern.suffix.length);
}
ts.matchedText = matchedText;
/** Return the object corresponding to the best pattern to match `candidate`. */
/* @internal */
function findBestPatternMatch(values, getPattern, candidate) {
var matchedValue = undefined;
// use length of prefix as betterness criteria
var longestMatchPrefixLength = -1;
for (var _i = 0, values_1 = values; _i < values_1.length; _i++) {
var v = values_1[_i];
var pattern = getPattern(v);
if (isPatternMatch(pattern, candidate) && pattern.prefix.length > longestMatchPrefixLength) {
longestMatchPrefixLength = pattern.prefix.length;
matchedValue = v;
}
}
return matchedValue;
}
ts.findBestPatternMatch = findBestPatternMatch;
function isPatternMatch(_a, candidate) {
var prefix = _a.prefix, suffix = _a.suffix;
return candidate.length >= prefix.length + suffix.length &&
startsWith(candidate, prefix) &&
endsWith(candidate, suffix);
}
/* @internal */
function tryParsePattern(pattern) {
// This should be verified outside of here and a proper error thrown.
Debug.assert(hasZeroOrOneAsteriskCharacter(pattern));
var indexOfStar = pattern.indexOf("*");
return indexOfStar === -1 ? undefined : {
prefix: pattern.substr(0, indexOfStar),
suffix: pattern.substr(indexOfStar + 1)
};
}
ts.tryParsePattern = tryParsePattern;
function positionIsSynthesized(pos) {
// This is a fast way of testing the following conditions:
// pos === undefined || pos === null || isNaN(pos) || pos < 0;
return !(pos >= 0);
}
ts.positionIsSynthesized = positionIsSynthesized;
/** True if an extension is one of the supported TypeScript extensions. */
function extensionIsTypeScript(ext) {
return ext <= ts.Extension.LastTypeScriptExtension;
}
ts.extensionIsTypeScript = extensionIsTypeScript;
/**
* Gets the extension from a path.
* Path must have a valid extension.
*/
function extensionFromPath(path) {
var ext = tryGetExtensionFromPath(path);
if (ext !== undefined) {
return ext;
}
Debug.fail("File " + path + " has unknown extension.");
}
ts.extensionFromPath = extensionFromPath;
function tryGetExtensionFromPath(path) {
if (fileExtensionIs(path, ".d.ts")) {
return ts.Extension.Dts;
}
if (fileExtensionIs(path, ".ts")) {
return ts.Extension.Ts;
}
if (fileExtensionIs(path, ".tsx")) {
return ts.Extension.Tsx;
}
if (fileExtensionIs(path, ".js")) {
return ts.Extension.Js;
}
if (fileExtensionIs(path, ".jsx")) {
return ts.Extension.Jsx;
}
}
ts.tryGetExtensionFromPath = tryGetExtensionFromPath;
})(ts || (ts = {}));
/// <reference path="core.ts"/>
var ts;
(function (ts) {
ts.sys = (function () {
function getWScriptSystem() {
var fso = new ActiveXObject("Scripting.FileSystemObject");
var shell = new ActiveXObject("WScript.Shell");
var fileStream = new ActiveXObject("ADODB.Stream");
fileStream.Type = 2 /*text*/;
var binaryStream = new ActiveXObject("ADODB.Stream");
binaryStream.Type = 1 /*binary*/;
var args = [];
for (var i = 0; i < WScript.Arguments.length; i++) {
args[i] = WScript.Arguments.Item(i);
}
function readFile(fileName, encoding) {
if (!fso.FileExists(fileName)) {
return undefined;
}
fileStream.Open();
try {
if (encoding) {
fileStream.Charset = encoding;
fileStream.LoadFromFile(fileName);
}
else {
// Load file and read the first two bytes into a string with no interpretation
fileStream.Charset = "x-ansi";
fileStream.LoadFromFile(fileName);
var bom = fileStream.ReadText(2) || "";
// Position must be at 0 before encoding can be changed
fileStream.Position = 0;
// [0xFF,0xFE] and [0xFE,0xFF] mean utf-16 (little or big endian), otherwise default to utf-8
fileStream.Charset = bom.length >= 2 && (bom.charCodeAt(0) === 0xFF && bom.charCodeAt(1) === 0xFE || bom.charCodeAt(0) === 0xFE && bom.charCodeAt(1) === 0xFF) ? "unicode" : "utf-8";
}
// ReadText method always strips byte order mark from resulting string
return fileStream.ReadText();
}
catch (e) {
throw e;
}
finally {
fileStream.Close();
}
}
function writeFile(fileName, data, writeByteOrderMark) {
fileStream.Open();
binaryStream.Open();
try {
// Write characters in UTF-8 encoding
fileStream.Charset = "utf-8";
fileStream.WriteText(data);
// If we don't want the BOM, then skip it by setting the starting location to 3 (size of BOM).
// If not, start from position 0, as the BOM will be added automatically when charset==utf8.
if (writeByteOrderMark) {
fileStream.Position = 0;
}
else {
fileStream.Position = 3;
}
fileStream.CopyTo(binaryStream);
binaryStream.SaveToFile(fileName, 2 /*overwrite*/);
}
finally {
binaryStream.Close();
fileStream.Close();
}
}
function getNames(collection) {
var result = [];
for (var e = new Enumerator(collection); !e.atEnd(); e.moveNext()) {
result.push(e.item().Name);
}
return result.sort();
}
function getDirectories(path) {
var folder = fso.GetFolder(path);
return getNames(folder.subfolders);
}
function getAccessibleFileSystemEntries(path) {
try {
var folder = fso.GetFolder(path || ".");
var files = getNames(folder.files);
var directories = getNames(folder.subfolders);
return { files: files, directories: directories };
}
catch (e) {
return { files: [], directories: [] };
}
}
function readDirectory(path, extensions, excludes, includes) {
return ts.matchFiles(path, extensions, excludes, includes, /*useCaseSensitiveFileNames*/ false, shell.CurrentDirectory, getAccessibleFileSystemEntries);
}
var wscriptSystem = {
args: args,
newLine: "\r\n",
useCaseSensitiveFileNames: false,
write: function (s) {
WScript.StdOut.Write(s);
},
readFile: readFile,
writeFile: writeFile,
resolvePath: function (path) {
return fso.GetAbsolutePathName(path);
},
fileExists: function (path) {
return fso.FileExists(path);
},
directoryExists: function (path) {
return fso.FolderExists(path);
},
createDirectory: function (directoryName) {
if (!wscriptSystem.directoryExists(directoryName)) {
fso.CreateFolder(directoryName);
}
},
getExecutingFilePath: function () {
return WScript.ScriptFullName;
},
getCurrentDirectory: function () {
return shell.CurrentDirectory;
},
getDirectories: getDirectories,
getEnvironmentVariable: function (name) {
return new ActiveXObject("WScript.Shell").ExpandEnvironmentStrings("%" + name + "%");
},
readDirectory: readDirectory,
exit: function (exitCode) {
try {
WScript.Quit(exitCode);
}
catch (e) {
}
}
};
return wscriptSystem;
}
function getNodeSystem() {
var _fs = require("fs");
var _path = require("path");
var _os = require("os");
var _crypto = require("crypto");
var useNonPollingWatchers = process.env["TSC_NONPOLLING_WATCHER"];
function createWatchedFileSet() {
var dirWatchers = ts.createMap();
// One file can have multiple watchers
var fileWatcherCallbacks = ts.createMap();
return { addFile: addFile, removeFile: removeFile };
function reduceDirWatcherRefCountForFile(fileName) {
var dirName = ts.getDirectoryPath(fileName);
var watcher = dirWatchers[dirName];
if (watcher) {
watcher.referenceCount -= 1;
if (watcher.referenceCount <= 0) {
watcher.close();
delete dirWatchers[dirName];
}
}
}
function addDirWatcher(dirPath) {
var watcher = dirWatchers[dirPath];
if (watcher) {
watcher.referenceCount += 1;
return;
}
watcher = _fs.watch(dirPath, { persistent: true }, function (eventName, relativeFileName) { return fileEventHandler(eventName, relativeFileName, dirPath); });
watcher.referenceCount = 1;
dirWatchers[dirPath] = watcher;
return;
}
function addFileWatcherCallback(filePath, callback) {
ts.multiMapAdd(fileWatcherCallbacks, filePath, callback);
}
function addFile(fileName, callback) {
addFileWatcherCallback(fileName, callback);
addDirWatcher(ts.getDirectoryPath(fileName));
return { fileName: fileName, callback: callback };
}
function removeFile(watchedFile) {
removeFileWatcherCallback(watchedFile.fileName, watchedFile.callback);
reduceDirWatcherRefCountForFile(watchedFile.fileName);
}
function removeFileWatcherCallback(filePath, callback) {
ts.multiMapRemove(fileWatcherCallbacks, filePath, callback);
}
function fileEventHandler(eventName, relativeFileName, baseDirPath) {
// When files are deleted from disk, the triggered "rename" event would have a relativefileName of "undefined"
var fileName = typeof relativeFileName !== "string"
? undefined
: ts.getNormalizedAbsolutePath(relativeFileName, baseDirPath);
// Some applications save a working file via rename operations
if ((eventName === "change" || eventName === "rename") && fileWatcherCallbacks[fileName]) {
for (var _i = 0, _a = fileWatcherCallbacks[fileName]; _i < _a.length; _i++) {
var fileCallback = _a[_i];
fileCallback(fileName);
}
}
}
}
var watchedFileSet = createWatchedFileSet();
function isNode4OrLater() {
return parseInt(process.version.charAt(1)) >= 4;
}
function isFileSystemCaseSensitive() {
// win32\win64 are case insensitive platforms
if (platform === "win32" || platform === "win64") {
return false;
}
// convert current file name to upper case / lower case and check if file exists
// (guards against cases when name is already all uppercase or lowercase)
return !fileExists(__filename.toUpperCase()) || !fileExists(__filename.toLowerCase());
}
var platform = _os.platform();
var useCaseSensitiveFileNames = isFileSystemCaseSensitive();
function readFile(fileName, _encoding) {
if (!fileExists(fileName)) {
return undefined;
}
var buffer = _fs.readFileSync(fileName);
var len = buffer.length;
if (len >= 2 && buffer[0] === 0xFE && buffer[1] === 0xFF) {
// Big endian UTF-16 byte order mark detected. Since big endian is not supported by node.js,
// flip all byte pairs and treat as little endian.
len &= ~1;
for (var i = 0; i < len; i += 2) {
var temp = buffer[i];
buffer[i] = buffer[i + 1];
buffer[i + 1] = temp;
}
return buffer.toString("utf16le", 2);
}
if (len >= 2 && buffer[0] === 0xFF && buffer[1] === 0xFE) {
// Little endian UTF-16 byte order mark detected
return buffer.toString("utf16le", 2);
}
if (len >= 3 && buffer[0] === 0xEF && buffer[1] === 0xBB && buffer[2] === 0xBF) {
// UTF-8 byte order mark detected
return buffer.toString("utf8", 3);
}
// Default is UTF-8 with no byte order mark
return buffer.toString("utf8");
}
function writeFile(fileName, data, writeByteOrderMark) {
// If a BOM is required, emit one
if (writeByteOrderMark) {
data = "\uFEFF" + data;
}
var fd;
try {
fd = _fs.openSync(fileName, "w");
_fs.writeSync(fd, data, undefined, "utf8");
}
finally {
if (fd !== undefined) {
_fs.closeSync(fd);
}
}
}
function getAccessibleFileSystemEntries(path) {
try {
var entries = _fs.readdirSync(path || ".").sort();
var files = [];
var directories = [];
for (var _i = 0, entries_1 = entries; _i < entries_1.length; _i++) {
var entry = entries_1[_i];
// This is necessary because on some file system node fails to exclude
// "." and "..". See https://github.com/nodejs/node/issues/4002
if (entry === "." || entry === "..") {
continue;
}
var name_3 = ts.combinePaths(path, entry);
var stat = void 0;
try {
stat = _fs.statSync(name_3);
}
catch (e) {
continue;
}
if (stat.isFile()) {
files.push(entry);
}
else if (stat.isDirectory()) {
directories.push(entry);
}
}
return { files: files, directories: directories };
}
catch (e) {
return { files: [], directories: [] };
}
}
function readDirectory(path, extensions, excludes, includes) {
return ts.matchFiles(path, extensions, excludes, includes, useCaseSensitiveFileNames, process.cwd(), getAccessibleFileSystemEntries);
}
var FileSystemEntryKind;
(function (FileSystemEntryKind) {
FileSystemEntryKind[FileSystemEntryKind["File"] = 0] = "File";
FileSystemEntryKind[FileSystemEntryKind["Directory"] = 1] = "Directory";
})(FileSystemEntryKind || (FileSystemEntryKind = {}));
function fileSystemEntryExists(path, entryKind) {
try {
var stat = _fs.statSync(path);
switch (entryKind) {
case 0 /* File */: return stat.isFile();
case 1 /* Directory */: return stat.isDirectory();
}
}
catch (e) {
return false;
}
}
function fileExists(path) {
return fileSystemEntryExists(path, 0 /* File */);
}
function directoryExists(path) {
return fileSystemEntryExists(path, 1 /* Directory */);
}
function getDirectories(path) {
return ts.filter(_fs.readdirSync(path), function (dir) { return fileSystemEntryExists(ts.combinePaths(path, dir), 1 /* Directory */); });
}
var noOpFileWatcher = { close: ts.noop };
var nodeSystem = {
args: process.argv.slice(2),
newLine: _os.EOL,
useCaseSensitiveFileNames: useCaseSensitiveFileNames,
write: function (s) {
process.stdout.write(s);
},
readFile: readFile,
writeFile: writeFile,
watchFile: function (fileName, callback, pollingInterval) {
if (useNonPollingWatchers) {
var watchedFile_1 = watchedFileSet.addFile(fileName, callback);
return {
close: function () { return watchedFileSet.removeFile(watchedFile_1); }
};
}
else {
_fs.watchFile(fileName, { persistent: true, interval: pollingInterval || 250 }, fileChanged);
return {
close: function () { return _fs.unwatchFile(fileName, fileChanged); }
};
}
function fileChanged(curr, prev) {
if (+curr.mtime <= +prev.mtime) {
return;
}
callback(fileName);
}
},
watchDirectory: function (directoryName, callback, recursive) {
// Node 4.0 `fs.watch` function supports the "recursive" option on both OSX and Windows
// (ref: https://github.com/nodejs/node/pull/2649 and https://github.com/Microsoft/TypeScript/issues/4643)
var options;
if (!directoryExists(directoryName)) {
return noOpFileWatcher;
}
if (isNode4OrLater() && (process.platform === "win32" || process.platform === "darwin")) {
options = { persistent: true, recursive: !!recursive };
}
else {
options = { persistent: true };
}
return _fs.watch(directoryName, options, function (eventName, relativeFileName) {
// In watchDirectory we only care about adding and removing files (when event name is
// "rename"); changes made within files are handled by corresponding fileWatchers (when
// event name is "change")
if (eventName === "rename") {
// When deleting a file, the passed baseFileName is null
callback(!relativeFileName ? relativeFileName : ts.normalizePath(ts.combinePaths(directoryName, relativeFileName)));
}
;
});
},
resolvePath: function (path) {
return _path.resolve(path);
},
fileExists: fileExists,
directoryExists: directoryExists,
createDirectory: function (directoryName) {
if (!nodeSystem.directoryExists(directoryName)) {
_fs.mkdirSync(directoryName);
}
},
getExecutingFilePath: function () {
return __filename;
},
getCurrentDirectory: function () {
return process.cwd();
},
getDirectories: getDirectories,
getEnvironmentVariable: function (name) {
return process.env[name] || "";
},
readDirectory: readDirectory,
getModifiedTime: function (path) {
try {
return _fs.statSync(path).mtime;
}
catch (e) {
return undefined;
}
},
createHash: function (data) {
var hash = _crypto.createHash("md5");
hash.update(data);
return hash.digest("hex");
},
getMemoryUsage: function () {
if (global.gc) {
global.gc();
}
return process.memoryUsage().heapUsed;
},
getFileSize: function (path) {
try {
var stat = _fs.statSync(path);
if (stat.isFile()) {
return stat.size;
}
}
catch (e) { }
return 0;
},
exit: function (exitCode) {
process.exit(exitCode);
},
realpath: function (path) {
return _fs.realpathSync(path);
},
tryEnableSourceMapsForHost: function () {
try {
require("source-map-support").install();
}
catch (e) {
}
},
setTimeout: setTimeout,
clearTimeout: clearTimeout
};
return nodeSystem;
}
function getChakraSystem() {
var realpath = ChakraHost.realpath && (function (path) { return ChakraHost.realpath(path); });
return {
newLine: ChakraHost.newLine || "\r\n",
args: ChakraHost.args,
useCaseSensitiveFileNames: !!ChakraHost.useCaseSensitiveFileNames,
write: ChakraHost.echo,
readFile: function (path, _encoding) {
// encoding is automatically handled by the implementation in ChakraHost
return ChakraHost.readFile(path);
},
writeFile: function (path, data, writeByteOrderMark) {
// If a BOM is required, emit one
if (writeByteOrderMark) {
data = "\uFEFF" + data;
}
ChakraHost.writeFile(path, data);
},
resolvePath: ChakraHost.resolvePath,
fileExists: ChakraHost.fileExists,
directoryExists: ChakraHost.directoryExists,
createDirectory: ChakraHost.createDirectory,
getExecutingFilePath: function () { return ChakraHost.executingFile; },
getCurrentDirectory: function () { return ChakraHost.currentDirectory; },
getDirectories: ChakraHost.getDirectories,
getEnvironmentVariable: ChakraHost.getEnvironmentVariable || (function () { return ""; }),
readDirectory: function (path, extensions, excludes, includes) {
var pattern = ts.getFileMatcherPatterns(path, excludes, includes, !!ChakraHost.useCaseSensitiveFileNames, ChakraHost.currentDirectory);
return ChakraHost.readDirectory(path, extensions, pattern.basePaths, pattern.excludePattern, pattern.includeFilePattern, pattern.includeDirectoryPattern);
},
exit: ChakraHost.quit,
realpath: realpath
};
}
function recursiveCreateDirectory(directoryPath, sys) {
var basePath = ts.getDirectoryPath(directoryPath);
var shouldCreateParent = directoryPath !== basePath && !sys.directoryExists(basePath);
if (shouldCreateParent) {
recursiveCreateDirectory(basePath, sys);
}
if (shouldCreateParent || !sys.directoryExists(directoryPath)) {
sys.createDirectory(directoryPath);
}
}
var sys;
if (typeof ChakraHost !== "undefined") {
sys = getChakraSystem();
}
else if (typeof WScript !== "undefined" && typeof ActiveXObject === "function") {
sys = getWScriptSystem();
}
else if (typeof process !== "undefined" && process.nextTick && !process.browser && typeof require !== "undefined") {
// process and process.nextTick checks if current environment is node-like
// process.browser check excludes webpack and browserify
sys = getNodeSystem();
}
if (sys) {
// patch writefile to create folder before writing the file
var originalWriteFile_1 = sys.writeFile;
sys.writeFile = function (path, data, writeBom) {
var directoryPath = ts.getDirectoryPath(ts.normalizeSlashes(path));
if (directoryPath && !sys.directoryExists(directoryPath)) {
recursiveCreateDirectory(directoryPath, sys);
}
originalWriteFile_1.call(sys, path, data, writeBom);
};
}
return sys;
})();
if (ts.sys && ts.sys.getEnvironmentVariable) {
ts.Debug.currentAssertionLevel = /^development$/i.test(ts.sys.getEnvironmentVariable("NODE_ENV"))
? 1 /* Normal */
: 0 /* None */;
}
})(ts || (ts = {}));
// <auto-generated />
/// <reference path="types.ts" />
/* @internal */
var ts;
(function (ts) {
ts.Diagnostics = {
Unterminated_string_literal: { code: 1002, category: ts.DiagnosticCategory.Error, key: "Unterminated_string_literal_1002", message: "Unterminated string literal." },
Identifier_expected: { code: 1003, category: ts.DiagnosticCategory.Error, key: "Identifier_expected_1003", message: "Identifier expected." },
_0_expected: { code: 1005, category: ts.DiagnosticCategory.Error, key: "_0_expected_1005", message: "'{0}' expected." },
A_file_cannot_have_a_reference_to_itself: { code: 1006, category: ts.DiagnosticCategory.Error, key: "A_file_cannot_have_a_reference_to_itself_1006", message: "A file cannot have a reference to itself." },
Trailing_comma_not_allowed: { code: 1009, category: ts.DiagnosticCategory.Error, key: "Trailing_comma_not_allowed_1009", message: "Trailing comma not allowed." },
Asterisk_Slash_expected: { code: 1010, category: ts.DiagnosticCategory.Error, key: "Asterisk_Slash_expected_1010", message: "'*/' expected." },
Unexpected_token: { code: 1012, category: ts.DiagnosticCategory.Error, key: "Unexpected_token_1012", message: "Unexpected token." },
A_rest_parameter_must_be_last_in_a_parameter_list: { code: 1014, category: ts.DiagnosticCategory.Error, key: "A_rest_parameter_must_be_last_in_a_parameter_list_1014", message: "A rest parameter must be last in a parameter list." },
Parameter_cannot_have_question_mark_and_initializer: { code: 1015, category: ts.DiagnosticCategory.Error, key: "Parameter_cannot_have_question_mark_and_initializer_1015", message: "Parameter cannot have question mark and initializer." },
A_required_parameter_cannot_follow_an_optional_parameter: { code: 1016, category: ts.DiagnosticCategory.Error, key: "A_required_parameter_cannot_follow_an_optional_parameter_1016", message: "A required parameter cannot follow an optional parameter." },
An_index_signature_cannot_have_a_rest_parameter: { code: 1017, category: ts.DiagnosticCategory.Error, key: "An_index_signature_cannot_have_a_rest_parameter_1017", message: "An index signature cannot have a rest parameter." },
An_index_signature_parameter_cannot_have_an_accessibility_modifier: { code: 1018, category: ts.DiagnosticCategory.Error, key: "An_index_signature_parameter_cannot_have_an_accessibility_modifier_1018", message: "An index signature parameter cannot have an accessibility modifier." },
An_index_signature_parameter_cannot_have_a_question_mark: { code: 1019, category: ts.DiagnosticCategory.Error, key: "An_index_signature_parameter_cannot_have_a_question_mark_1019", message: "An index signature parameter cannot have a question mark." },
An_index_signature_parameter_cannot_have_an_initializer: { code: 1020, category: ts.DiagnosticCategory.Error, key: "An_index_signature_parameter_cannot_have_an_initializer_1020", message: "An index signature parameter cannot have an initializer." },
An_index_signature_must_have_a_type_annotation: { code: 1021, category: ts.DiagnosticCategory.Error, key: "An_index_signature_must_have_a_type_annotation_1021", message: "An index signature must have a type annotation." },
An_index_signature_parameter_must_have_a_type_annotation: { code: 1022, category: ts.DiagnosticCategory.Error, key: "An_index_signature_parameter_must_have_a_type_annotation_1022", message: "An index signature parameter must have a type annotation." },
An_index_signature_parameter_type_must_be_string_or_number: { code: 1023, category: ts.DiagnosticCategory.Error, key: "An_index_signature_parameter_type_must_be_string_or_number_1023", message: "An index signature parameter type must be 'string' or 'number'." },
readonly_modifier_can_only_appear_on_a_property_declaration_or_index_signature: { code: 1024, category: ts.DiagnosticCategory.Error, key: "readonly_modifier_can_only_appear_on_a_property_declaration_or_index_signature_1024", message: "'readonly' modifier can only appear on a property declaration or index signature." },
Accessibility_modifier_already_seen: { code: 1028, category: ts.DiagnosticCategory.Error, key: "Accessibility_modifier_already_seen_1028", message: "Accessibility modifier already seen." },
_0_modifier_must_precede_1_modifier: { code: 1029, category: ts.DiagnosticCategory.Error, key: "_0_modifier_must_precede_1_modifier_1029", message: "'{0}' modifier must precede '{1}' modifier." },
_0_modifier_already_seen: { code: 1030, category: ts.DiagnosticCategory.Error, key: "_0_modifier_already_seen_1030", message: "'{0}' modifier already seen." },
_0_modifier_cannot_appear_on_a_class_element: { code: 1031, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_appear_on_a_class_element_1031", message: "'{0}' modifier cannot appear on a class element." },
super_must_be_followed_by_an_argument_list_or_member_access: { code: 1034, category: ts.DiagnosticCategory.Error, key: "super_must_be_followed_by_an_argument_list_or_member_access_1034", message: "'super' must be followed by an argument list or member access." },
Only_ambient_modules_can_use_quoted_names: { code: 1035, category: ts.DiagnosticCategory.Error, key: "Only_ambient_modules_can_use_quoted_names_1035", message: "Only ambient modules can use quoted names." },
Statements_are_not_allowed_in_ambient_contexts: { code: 1036, category: ts.DiagnosticCategory.Error, key: "Statements_are_not_allowed_in_ambient_contexts_1036", message: "Statements are not allowed in ambient contexts." },
A_declare_modifier_cannot_be_used_in_an_already_ambient_context: { code: 1038, category: ts.DiagnosticCategory.Error, key: "A_declare_modifier_cannot_be_used_in_an_already_ambient_context_1038", message: "A 'declare' modifier cannot be used in an already ambient context." },
Initializers_are_not_allowed_in_ambient_contexts: { code: 1039, category: ts.DiagnosticCategory.Error, key: "Initializers_are_not_allowed_in_ambient_contexts_1039", message: "Initializers are not allowed in ambient contexts." },
_0_modifier_cannot_be_used_in_an_ambient_context: { code: 1040, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_be_used_in_an_ambient_context_1040", message: "'{0}' modifier cannot be used in an ambient context." },
_0_modifier_cannot_be_used_with_a_class_declaration: { code: 1041, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_be_used_with_a_class_declaration_1041", message: "'{0}' modifier cannot be used with a class declaration." },
_0_modifier_cannot_be_used_here: { code: 1042, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_be_used_here_1042", message: "'{0}' modifier cannot be used here." },
_0_modifier_cannot_appear_on_a_data_property: { code: 1043, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_appear_on_a_data_property_1043", message: "'{0}' modifier cannot appear on a data property." },
_0_modifier_cannot_appear_on_a_module_or_namespace_element: { code: 1044, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_appear_on_a_module_or_namespace_element_1044", message: "'{0}' modifier cannot appear on a module or namespace element." },
A_0_modifier_cannot_be_used_with_an_interface_declaration: { code: 1045, category: ts.DiagnosticCategory.Error, key: "A_0_modifier_cannot_be_used_with_an_interface_declaration_1045", message: "A '{0}' modifier cannot be used with an interface declaration." },
A_declare_modifier_is_required_for_a_top_level_declaration_in_a_d_ts_file: { code: 1046, category: ts.DiagnosticCategory.Error, key: "A_declare_modifier_is_required_for_a_top_level_declaration_in_a_d_ts_file_1046", message: "A 'declare' modifier is required for a top level declaration in a .d.ts file." },
A_rest_parameter_cannot_be_optional: { code: 1047, category: ts.DiagnosticCategory.Error, key: "A_rest_parameter_cannot_be_optional_1047", message: "A rest parameter cannot be optional." },
A_rest_parameter_cannot_have_an_initializer: { code: 1048, category: ts.DiagnosticCategory.Error, key: "A_rest_parameter_cannot_have_an_initializer_1048", message: "A rest parameter cannot have an initializer." },
A_set_accessor_must_have_exactly_one_parameter: { code: 1049, category: ts.DiagnosticCategory.Error, key: "A_set_accessor_must_have_exactly_one_parameter_1049", message: "A 'set' accessor must have exactly one parameter." },
A_set_accessor_cannot_have_an_optional_parameter: { code: 1051, category: ts.DiagnosticCategory.Error, key: "A_set_accessor_cannot_have_an_optional_parameter_1051", message: "A 'set' accessor cannot have an optional parameter." },
A_set_accessor_parameter_cannot_have_an_initializer: { code: 1052, category: ts.DiagnosticCategory.Error, key: "A_set_accessor_parameter_cannot_have_an_initializer_1052", message: "A 'set' accessor parameter cannot have an initializer." },
A_set_accessor_cannot_have_rest_parameter: { code: 1053, category: ts.DiagnosticCategory.Error, key: "A_set_accessor_cannot_have_rest_parameter_1053", message: "A 'set' accessor cannot have rest parameter." },
A_get_accessor_cannot_have_parameters: { code: 1054, category: ts.DiagnosticCategory.Error, key: "A_get_accessor_cannot_have_parameters_1054", message: "A 'get' accessor cannot have parameters." },
Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value: { code: 1055, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Prom_1055", message: "Type '{0}' is not a valid async function return type in ES5/ES3 because it does not refer to a Promise-compatible constructor value." },
Accessors_are_only_available_when_targeting_ECMAScript_5_and_higher: { code: 1056, category: ts.DiagnosticCategory.Error, key: "Accessors_are_only_available_when_targeting_ECMAScript_5_and_higher_1056", message: "Accessors are only available when targeting ECMAScript 5 and higher." },
An_async_function_or_method_must_have_a_valid_awaitable_return_type: { code: 1057, category: ts.DiagnosticCategory.Error, key: "An_async_function_or_method_must_have_a_valid_awaitable_return_type_1057", message: "An async function or method must have a valid awaitable return type." },
Operand_for_await_does_not_have_a_valid_callable_then_member: { code: 1058, category: ts.DiagnosticCategory.Error, key: "Operand_for_await_does_not_have_a_valid_callable_then_member_1058", message: "Operand for 'await' does not have a valid callable 'then' member." },
Return_expression_in_async_function_does_not_have_a_valid_callable_then_member: { code: 1059, category: ts.DiagnosticCategory.Error, key: "Return_expression_in_async_function_does_not_have_a_valid_callable_then_member_1059", message: "Return expression in async function does not have a valid callable 'then' member." },
Expression_body_for_async_arrow_function_does_not_have_a_valid_callable_then_member: { code: 1060, category: ts.DiagnosticCategory.Error, key: "Expression_body_for_async_arrow_function_does_not_have_a_valid_callable_then_member_1060", message: "Expression body for async arrow function does not have a valid callable 'then' member." },
Enum_member_must_have_initializer: { code: 1061, category: ts.DiagnosticCategory.Error, key: "Enum_member_must_have_initializer_1061", message: "Enum member must have initializer." },
_0_is_referenced_directly_or_indirectly_in_the_fulfillment_callback_of_its_own_then_method: { code: 1062, category: ts.DiagnosticCategory.Error, key: "_0_is_referenced_directly_or_indirectly_in_the_fulfillment_callback_of_its_own_then_method_1062", message: "{0} is referenced directly or indirectly in the fulfillment callback of its own 'then' method." },
An_export_assignment_cannot_be_used_in_a_namespace: { code: 1063, category: ts.DiagnosticCategory.Error, key: "An_export_assignment_cannot_be_used_in_a_namespace_1063", message: "An export assignment cannot be used in a namespace." },
The_return_type_of_an_async_function_or_method_must_be_the_global_Promise_T_type: { code: 1064, category: ts.DiagnosticCategory.Error, key: "The_return_type_of_an_async_function_or_method_must_be_the_global_Promise_T_type_1064", message: "The return type of an async function or method must be the global Promise<T> type." },
In_ambient_enum_declarations_member_initializer_must_be_constant_expression: { code: 1066, category: ts.DiagnosticCategory.Error, key: "In_ambient_enum_declarations_member_initializer_must_be_constant_expression_1066", message: "In ambient enum declarations member initializer must be constant expression." },
Unexpected_token_A_constructor_method_accessor_or_property_was_expected: { code: 1068, category: ts.DiagnosticCategory.Error, key: "Unexpected_token_A_constructor_method_accessor_or_property_was_expected_1068", message: "Unexpected token. A constructor, method, accessor, or property was expected." },
_0_modifier_cannot_appear_on_a_type_member: { code: 1070, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_appear_on_a_type_member_1070", message: "'{0}' modifier cannot appear on a type member." },
_0_modifier_cannot_appear_on_an_index_signature: { code: 1071, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_appear_on_an_index_signature_1071", message: "'{0}' modifier cannot appear on an index signature." },
A_0_modifier_cannot_be_used_with_an_import_declaration: { code: 1079, category: ts.DiagnosticCategory.Error, key: "A_0_modifier_cannot_be_used_with_an_import_declaration_1079", message: "A '{0}' modifier cannot be used with an import declaration." },
Invalid_reference_directive_syntax: { code: 1084, category: ts.DiagnosticCategory.Error, key: "Invalid_reference_directive_syntax_1084", message: "Invalid 'reference' directive syntax." },
Octal_literals_are_not_available_when_targeting_ECMAScript_5_and_higher: { code: 1085, category: ts.DiagnosticCategory.Error, key: "Octal_literals_are_not_available_when_targeting_ECMAScript_5_and_higher_1085", message: "Octal literals are not available when targeting ECMAScript 5 and higher." },
An_accessor_cannot_be_declared_in_an_ambient_context: { code: 1086, category: ts.DiagnosticCategory.Error, key: "An_accessor_cannot_be_declared_in_an_ambient_context_1086", message: "An accessor cannot be declared in an ambient context." },
_0_modifier_cannot_appear_on_a_constructor_declaration: { code: 1089, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_appear_on_a_constructor_declaration_1089", message: "'{0}' modifier cannot appear on a constructor declaration." },
_0_modifier_cannot_appear_on_a_parameter: { code: 1090, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_appear_on_a_parameter_1090", message: "'{0}' modifier cannot appear on a parameter." },
Only_a_single_variable_declaration_is_allowed_in_a_for_in_statement: { code: 1091, category: ts.DiagnosticCategory.Error, key: "Only_a_single_variable_declaration_is_allowed_in_a_for_in_statement_1091", message: "Only a single variable declaration is allowed in a 'for...in' statement." },
Type_parameters_cannot_appear_on_a_constructor_declaration: { code: 1092, category: ts.DiagnosticCategory.Error, key: "Type_parameters_cannot_appear_on_a_constructor_declaration_1092", message: "Type parameters cannot appear on a constructor declaration." },
Type_annotation_cannot_appear_on_a_constructor_declaration: { code: 1093, category: ts.DiagnosticCategory.Error, key: "Type_annotation_cannot_appear_on_a_constructor_declaration_1093", message: "Type annotation cannot appear on a constructor declaration." },
An_accessor_cannot_have_type_parameters: { code: 1094, category: ts.DiagnosticCategory.Error, key: "An_accessor_cannot_have_type_parameters_1094", message: "An accessor cannot have type parameters." },
A_set_accessor_cannot_have_a_return_type_annotation: { code: 1095, category: ts.DiagnosticCategory.Error, key: "A_set_accessor_cannot_have_a_return_type_annotation_1095", message: "A 'set' accessor cannot have a return type annotation." },
An_index_signature_must_have_exactly_one_parameter: { code: 1096, category: ts.DiagnosticCategory.Error, key: "An_index_signature_must_have_exactly_one_parameter_1096", message: "An index signature must have exactly one parameter." },
_0_list_cannot_be_empty: { code: 1097, category: ts.DiagnosticCategory.Error, key: "_0_list_cannot_be_empty_1097", message: "'{0}' list cannot be empty." },
Type_parameter_list_cannot_be_empty: { code: 1098, category: ts.DiagnosticCategory.Error, key: "Type_parameter_list_cannot_be_empty_1098", message: "Type parameter list cannot be empty." },
Type_argument_list_cannot_be_empty: { code: 1099, category: ts.DiagnosticCategory.Error, key: "Type_argument_list_cannot_be_empty_1099", message: "Type argument list cannot be empty." },
Invalid_use_of_0_in_strict_mode: { code: 1100, category: ts.DiagnosticCategory.Error, key: "Invalid_use_of_0_in_strict_mode_1100", message: "Invalid use of '{0}' in strict mode." },
with_statements_are_not_allowed_in_strict_mode: { code: 1101, category: ts.DiagnosticCategory.Error, key: "with_statements_are_not_allowed_in_strict_mode_1101", message: "'with' statements are not allowed in strict mode." },
delete_cannot_be_called_on_an_identifier_in_strict_mode: { code: 1102, category: ts.DiagnosticCategory.Error, key: "delete_cannot_be_called_on_an_identifier_in_strict_mode_1102", message: "'delete' cannot be called on an identifier in strict mode." },
A_continue_statement_can_only_be_used_within_an_enclosing_iteration_statement: { code: 1104, category: ts.DiagnosticCategory.Error, key: "A_continue_statement_can_only_be_used_within_an_enclosing_iteration_statement_1104", message: "A 'continue' statement can only be used within an enclosing iteration statement." },
A_break_statement_can_only_be_used_within_an_enclosing_iteration_or_switch_statement: { code: 1105, category: ts.DiagnosticCategory.Error, key: "A_break_statement_can_only_be_used_within_an_enclosing_iteration_or_switch_statement_1105", message: "A 'break' statement can only be used within an enclosing iteration or switch statement." },
Jump_target_cannot_cross_function_boundary: { code: 1107, category: ts.DiagnosticCategory.Error, key: "Jump_target_cannot_cross_function_boundary_1107", message: "Jump target cannot cross function boundary." },
A_return_statement_can_only_be_used_within_a_function_body: { code: 1108, category: ts.DiagnosticCategory.Error, key: "A_return_statement_can_only_be_used_within_a_function_body_1108", message: "A 'return' statement can only be used within a function body." },
Expression_expected: { code: 1109, category: ts.DiagnosticCategory.Error, key: "Expression_expected_1109", message: "Expression expected." },
Type_expected: { code: 1110, category: ts.DiagnosticCategory.Error, key: "Type_expected_1110", message: "Type expected." },
A_default_clause_cannot_appear_more_than_once_in_a_switch_statement: { code: 1113, category: ts.DiagnosticCategory.Error, key: "A_default_clause_cannot_appear_more_than_once_in_a_switch_statement_1113", message: "A 'default' clause cannot appear more than once in a 'switch' statement." },
Duplicate_label_0: { code: 1114, category: ts.DiagnosticCategory.Error, key: "Duplicate_label_0_1114", message: "Duplicate label '{0}'" },
A_continue_statement_can_only_jump_to_a_label_of_an_enclosing_iteration_statement: { code: 1115, category: ts.DiagnosticCategory.Error, key: "A_continue_statement_can_only_jump_to_a_label_of_an_enclosing_iteration_statement_1115", message: "A 'continue' statement can only jump to a label of an enclosing iteration statement." },
A_break_statement_can_only_jump_to_a_label_of_an_enclosing_statement: { code: 1116, category: ts.DiagnosticCategory.Error, key: "A_break_statement_can_only_jump_to_a_label_of_an_enclosing_statement_1116", message: "A 'break' statement can only jump to a label of an enclosing statement." },
An_object_literal_cannot_have_multiple_properties_with_the_same_name_in_strict_mode: { code: 1117, category: ts.DiagnosticCategory.Error, key: "An_object_literal_cannot_have_multiple_properties_with_the_same_name_in_strict_mode_1117", message: "An object literal cannot have multiple properties with the same name in strict mode." },
An_object_literal_cannot_have_multiple_get_Slashset_accessors_with_the_same_name: { code: 1118, category: ts.DiagnosticCategory.Error, key: "An_object_literal_cannot_have_multiple_get_Slashset_accessors_with_the_same_name_1118", message: "An object literal cannot have multiple get/set accessors with the same name." },
An_object_literal_cannot_have_property_and_accessor_with_the_same_name: { code: 1119, category: ts.DiagnosticCategory.Error, key: "An_object_literal_cannot_have_property_and_accessor_with_the_same_name_1119", message: "An object literal cannot have property and accessor with the same name." },
An_export_assignment_cannot_have_modifiers: { code: 1120, category: ts.DiagnosticCategory.Error, key: "An_export_assignment_cannot_have_modifiers_1120", message: "An export assignment cannot have modifiers." },
Octal_literals_are_not_allowed_in_strict_mode: { code: 1121, category: ts.DiagnosticCategory.Error, key: "Octal_literals_are_not_allowed_in_strict_mode_1121", message: "Octal literals are not allowed in strict mode." },
A_tuple_type_element_list_cannot_be_empty: { code: 1122, category: ts.DiagnosticCategory.Error, key: "A_tuple_type_element_list_cannot_be_empty_1122", message: "A tuple type element list cannot be empty." },
Variable_declaration_list_cannot_be_empty: { code: 1123, category: ts.DiagnosticCategory.Error, key: "Variable_declaration_list_cannot_be_empty_1123", message: "Variable declaration list cannot be empty." },
Digit_expected: { code: 1124, category: ts.DiagnosticCategory.Error, key: "Digit_expected_1124", message: "Digit expected." },
Hexadecimal_digit_expected: { code: 1125, category: ts.DiagnosticCategory.Error, key: "Hexadecimal_digit_expected_1125", message: "Hexadecimal digit expected." },
Unexpected_end_of_text: { code: 1126, category: ts.DiagnosticCategory.Error, key: "Unexpected_end_of_text_1126", message: "Unexpected end of text." },
Invalid_character: { code: 1127, category: ts.DiagnosticCategory.Error, key: "Invalid_character_1127", message: "Invalid character." },
Declaration_or_statement_expected: { code: 1128, category: ts.DiagnosticCategory.Error, key: "Declaration_or_statement_expected_1128", message: "Declaration or statement expected." },
Statement_expected: { code: 1129, category: ts.DiagnosticCategory.Error, key: "Statement_expected_1129", message: "Statement expected." },
case_or_default_expected: { code: 1130, category: ts.DiagnosticCategory.Error, key: "case_or_default_expected_1130", message: "'case' or 'default' expected." },
Property_or_signature_expected: { code: 1131, category: ts.DiagnosticCategory.Error, key: "Property_or_signature_expected_1131", message: "Property or signature expected." },
Enum_member_expected: { code: 1132, category: ts.DiagnosticCategory.Error, key: "Enum_member_expected_1132", message: "Enum member expected." },
Variable_declaration_expected: { code: 1134, category: ts.DiagnosticCategory.Error, key: "Variable_declaration_expected_1134", message: "Variable declaration expected." },
Argument_expression_expected: { code: 1135, category: ts.DiagnosticCategory.Error, key: "Argument_expression_expected_1135", message: "Argument expression expected." },
Property_assignment_expected: { code: 1136, category: ts.DiagnosticCategory.Error, key: "Property_assignment_expected_1136", message: "Property assignment expected." },
Expression_or_comma_expected: { code: 1137, category: ts.DiagnosticCategory.Error, key: "Expression_or_comma_expected_1137", message: "Expression or comma expected." },
Parameter_declaration_expected: { code: 1138, category: ts.DiagnosticCategory.Error, key: "Parameter_declaration_expected_1138", message: "Parameter declaration expected." },
Type_parameter_declaration_expected: { code: 1139, category: ts.DiagnosticCategory.Error, key: "Type_parameter_declaration_expected_1139", message: "Type parameter declaration expected." },
Type_argument_expected: { code: 1140, category: ts.DiagnosticCategory.Error, key: "Type_argument_expected_1140", message: "Type argument expected." },
String_literal_expected: { code: 1141, category: ts.DiagnosticCategory.Error, key: "String_literal_expected_1141", message: "String literal expected." },
Line_break_not_permitted_here: { code: 1142, category: ts.DiagnosticCategory.Error, key: "Line_break_not_permitted_here_1142", message: "Line break not permitted here." },
or_expected: { code: 1144, category: ts.DiagnosticCategory.Error, key: "or_expected_1144", message: "'{' or ';' expected." },
Declaration_expected: { code: 1146, category: ts.DiagnosticCategory.Error, key: "Declaration_expected_1146", message: "Declaration expected." },
Import_declarations_in_a_namespace_cannot_reference_a_module: { code: 1147, category: ts.DiagnosticCategory.Error, key: "Import_declarations_in_a_namespace_cannot_reference_a_module_1147", message: "Import declarations in a namespace cannot reference a module." },
Cannot_use_imports_exports_or_module_augmentations_when_module_is_none: { code: 1148, category: ts.DiagnosticCategory.Error, key: "Cannot_use_imports_exports_or_module_augmentations_when_module_is_none_1148", message: "Cannot use imports, exports, or module augmentations when '--module' is 'none'." },
File_name_0_differs_from_already_included_file_name_1_only_in_casing: { code: 1149, category: ts.DiagnosticCategory.Error, key: "File_name_0_differs_from_already_included_file_name_1_only_in_casing_1149", message: "File name '{0}' differs from already included file name '{1}' only in casing" },
new_T_cannot_be_used_to_create_an_array_Use_new_Array_T_instead: { code: 1150, category: ts.DiagnosticCategory.Error, key: "new_T_cannot_be_used_to_create_an_array_Use_new_Array_T_instead_1150", message: "'new T[]' cannot be used to create an array. Use 'new Array<T>()' instead." },
const_declarations_must_be_initialized: { code: 1155, category: ts.DiagnosticCategory.Error, key: "const_declarations_must_be_initialized_1155", message: "'const' declarations must be initialized" },
const_declarations_can_only_be_declared_inside_a_block: { code: 1156, category: ts.DiagnosticCategory.Error, key: "const_declarations_can_only_be_declared_inside_a_block_1156", message: "'const' declarations can only be declared inside a block." },
let_declarations_can_only_be_declared_inside_a_block: { code: 1157, category: ts.DiagnosticCategory.Error, key: "let_declarations_can_only_be_declared_inside_a_block_1157", message: "'let' declarations can only be declared inside a block." },
Unterminated_template_literal: { code: 1160, category: ts.DiagnosticCategory.Error, key: "Unterminated_template_literal_1160", message: "Unterminated template literal." },
Unterminated_regular_expression_literal: { code: 1161, category: ts.DiagnosticCategory.Error, key: "Unterminated_regular_expression_literal_1161", message: "Unterminated regular expression literal." },
An_object_member_cannot_be_declared_optional: { code: 1162, category: ts.DiagnosticCategory.Error, key: "An_object_member_cannot_be_declared_optional_1162", message: "An object member cannot be declared optional." },
A_yield_expression_is_only_allowed_in_a_generator_body: { code: 1163, category: ts.DiagnosticCategory.Error, key: "A_yield_expression_is_only_allowed_in_a_generator_body_1163", message: "A 'yield' expression is only allowed in a generator body." },
Computed_property_names_are_not_allowed_in_enums: { code: 1164, category: ts.DiagnosticCategory.Error, key: "Computed_property_names_are_not_allowed_in_enums_1164", message: "Computed property names are not allowed in enums." },
A_computed_property_name_in_an_ambient_context_must_directly_refer_to_a_built_in_symbol: { code: 1165, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_in_an_ambient_context_must_directly_refer_to_a_built_in_symbol_1165", message: "A computed property name in an ambient context must directly refer to a built-in symbol." },
A_computed_property_name_in_a_class_property_declaration_must_directly_refer_to_a_built_in_symbol: { code: 1166, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_in_a_class_property_declaration_must_directly_refer_to_a_built_in_symbol_1166", message: "A computed property name in a class property declaration must directly refer to a built-in symbol." },
A_computed_property_name_in_a_method_overload_must_directly_refer_to_a_built_in_symbol: { code: 1168, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_in_a_method_overload_must_directly_refer_to_a_built_in_symbol_1168", message: "A computed property name in a method overload must directly refer to a built-in symbol." },
A_computed_property_name_in_an_interface_must_directly_refer_to_a_built_in_symbol: { code: 1169, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_in_an_interface_must_directly_refer_to_a_built_in_symbol_1169", message: "A computed property name in an interface must directly refer to a built-in symbol." },
A_computed_property_name_in_a_type_literal_must_directly_refer_to_a_built_in_symbol: { code: 1170, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_in_a_type_literal_must_directly_refer_to_a_built_in_symbol_1170", message: "A computed property name in a type literal must directly refer to a built-in symbol." },
A_comma_expression_is_not_allowed_in_a_computed_property_name: { code: 1171, category: ts.DiagnosticCategory.Error, key: "A_comma_expression_is_not_allowed_in_a_computed_property_name_1171", message: "A comma expression is not allowed in a computed property name." },
extends_clause_already_seen: { code: 1172, category: ts.DiagnosticCategory.Error, key: "extends_clause_already_seen_1172", message: "'extends' clause already seen." },
extends_clause_must_precede_implements_clause: { code: 1173, category: ts.DiagnosticCategory.Error, key: "extends_clause_must_precede_implements_clause_1173", message: "'extends' clause must precede 'implements' clause." },
Classes_can_only_extend_a_single_class: { code: 1174, category: ts.DiagnosticCategory.Error, key: "Classes_can_only_extend_a_single_class_1174", message: "Classes can only extend a single class." },
implements_clause_already_seen: { code: 1175, category: ts.DiagnosticCategory.Error, key: "implements_clause_already_seen_1175", message: "'implements' clause already seen." },
Interface_declaration_cannot_have_implements_clause: { code: 1176, category: ts.DiagnosticCategory.Error, key: "Interface_declaration_cannot_have_implements_clause_1176", message: "Interface declaration cannot have 'implements' clause." },
Binary_digit_expected: { code: 1177, category: ts.DiagnosticCategory.Error, key: "Binary_digit_expected_1177", message: "Binary digit expected." },
Octal_digit_expected: { code: 1178, category: ts.DiagnosticCategory.Error, key: "Octal_digit_expected_1178", message: "Octal digit expected." },
Unexpected_token_expected: { code: 1179, category: ts.DiagnosticCategory.Error, key: "Unexpected_token_expected_1179", message: "Unexpected token. '{' expected." },
Property_destructuring_pattern_expected: { code: 1180, category: ts.DiagnosticCategory.Error, key: "Property_destructuring_pattern_expected_1180", message: "Property destructuring pattern expected." },
Array_element_destructuring_pattern_expected: { code: 1181, category: ts.DiagnosticCategory.Error, key: "Array_element_destructuring_pattern_expected_1181", message: "Array element destructuring pattern expected." },
A_destructuring_declaration_must_have_an_initializer: { code: 1182, category: ts.DiagnosticCategory.Error, key: "A_destructuring_declaration_must_have_an_initializer_1182", message: "A destructuring declaration must have an initializer." },
An_implementation_cannot_be_declared_in_ambient_contexts: { code: 1183, category: ts.DiagnosticCategory.Error, key: "An_implementation_cannot_be_declared_in_ambient_contexts_1183", message: "An implementation cannot be declared in ambient contexts." },
Modifiers_cannot_appear_here: { code: 1184, category: ts.DiagnosticCategory.Error, key: "Modifiers_cannot_appear_here_1184", message: "Modifiers cannot appear here." },
Merge_conflict_marker_encountered: { code: 1185, category: ts.DiagnosticCategory.Error, key: "Merge_conflict_marker_encountered_1185", message: "Merge conflict marker encountered." },
A_rest_element_cannot_have_an_initializer: { code: 1186, category: ts.DiagnosticCategory.Error, key: "A_rest_element_cannot_have_an_initializer_1186", message: "A rest element cannot have an initializer." },
A_parameter_property_may_not_be_declared_using_a_binding_pattern: { code: 1187, category: ts.DiagnosticCategory.Error, key: "A_parameter_property_may_not_be_declared_using_a_binding_pattern_1187", message: "A parameter property may not be declared using a binding pattern." },
Only_a_single_variable_declaration_is_allowed_in_a_for_of_statement: { code: 1188, category: ts.DiagnosticCategory.Error, key: "Only_a_single_variable_declaration_is_allowed_in_a_for_of_statement_1188", message: "Only a single variable declaration is allowed in a 'for...of' statement." },
The_variable_declaration_of_a_for_in_statement_cannot_have_an_initializer: { code: 1189, category: ts.DiagnosticCategory.Error, key: "The_variable_declaration_of_a_for_in_statement_cannot_have_an_initializer_1189", message: "The variable declaration of a 'for...in' statement cannot have an initializer." },
The_variable_declaration_of_a_for_of_statement_cannot_have_an_initializer: { code: 1190, category: ts.DiagnosticCategory.Error, key: "The_variable_declaration_of_a_for_of_statement_cannot_have_an_initializer_1190", message: "The variable declaration of a 'for...of' statement cannot have an initializer." },
An_import_declaration_cannot_have_modifiers: { code: 1191, category: ts.DiagnosticCategory.Error, key: "An_import_declaration_cannot_have_modifiers_1191", message: "An import declaration cannot have modifiers." },
Module_0_has_no_default_export: { code: 1192, category: ts.DiagnosticCategory.Error, key: "Module_0_has_no_default_export_1192", message: "Module '{0}' has no default export." },
An_export_declaration_cannot_have_modifiers: { code: 1193, category: ts.DiagnosticCategory.Error, key: "An_export_declaration_cannot_have_modifiers_1193", message: "An export declaration cannot have modifiers." },
Export_declarations_are_not_permitted_in_a_namespace: { code: 1194, category: ts.DiagnosticCategory.Error, key: "Export_declarations_are_not_permitted_in_a_namespace_1194", message: "Export declarations are not permitted in a namespace." },
Catch_clause_variable_cannot_have_a_type_annotation: { code: 1196, category: ts.DiagnosticCategory.Error, key: "Catch_clause_variable_cannot_have_a_type_annotation_1196", message: "Catch clause variable cannot have a type annotation." },
Catch_clause_variable_cannot_have_an_initializer: { code: 1197, category: ts.DiagnosticCategory.Error, key: "Catch_clause_variable_cannot_have_an_initializer_1197", message: "Catch clause variable cannot have an initializer." },
An_extended_Unicode_escape_value_must_be_between_0x0_and_0x10FFFF_inclusive: { code: 1198, category: ts.DiagnosticCategory.Error, key: "An_extended_Unicode_escape_value_must_be_between_0x0_and_0x10FFFF_inclusive_1198", message: "An extended Unicode escape value must be between 0x0 and 0x10FFFF inclusive." },
Unterminated_Unicode_escape_sequence: { code: 1199, category: ts.DiagnosticCategory.Error, key: "Unterminated_Unicode_escape_sequence_1199", message: "Unterminated Unicode escape sequence." },
Line_terminator_not_permitted_before_arrow: { code: 1200, category: ts.DiagnosticCategory.Error, key: "Line_terminator_not_permitted_before_arrow_1200", message: "Line terminator not permitted before arrow." },
Import_assignment_cannot_be_used_when_targeting_ECMAScript_2015_modules_Consider_using_import_Asterisk_as_ns_from_mod_import_a_from_mod_import_d_from_mod_or_another_module_format_instead: { code: 1202, category: ts.DiagnosticCategory.Error, key: "Import_assignment_cannot_be_used_when_targeting_ECMAScript_2015_modules_Consider_using_import_Asteri_1202", message: "Import assignment cannot be used when targeting ECMAScript 2015 modules. Consider using 'import * as ns from \"mod\"', 'import {a} from \"mod\"', 'import d from \"mod\"', or another module format instead." },
Export_assignment_cannot_be_used_when_targeting_ECMAScript_2015_modules_Consider_using_export_default_or_another_module_format_instead: { code: 1203, category: ts.DiagnosticCategory.Error, key: "Export_assignment_cannot_be_used_when_targeting_ECMAScript_2015_modules_Consider_using_export_defaul_1203", message: "Export assignment cannot be used when targeting ECMAScript 2015 modules. Consider using 'export default' or another module format instead." },
Decorators_are_not_valid_here: { code: 1206, category: ts.DiagnosticCategory.Error, key: "Decorators_are_not_valid_here_1206", message: "Decorators are not valid here." },
Decorators_cannot_be_applied_to_multiple_get_Slashset_accessors_of_the_same_name: { code: 1207, category: ts.DiagnosticCategory.Error, key: "Decorators_cannot_be_applied_to_multiple_get_Slashset_accessors_of_the_same_name_1207", message: "Decorators cannot be applied to multiple get/set accessors of the same name." },
Cannot_compile_namespaces_when_the_isolatedModules_flag_is_provided: { code: 1208, category: ts.DiagnosticCategory.Error, key: "Cannot_compile_namespaces_when_the_isolatedModules_flag_is_provided_1208", message: "Cannot compile namespaces when the '--isolatedModules' flag is provided." },
Ambient_const_enums_are_not_allowed_when_the_isolatedModules_flag_is_provided: { code: 1209, category: ts.DiagnosticCategory.Error, key: "Ambient_const_enums_are_not_allowed_when_the_isolatedModules_flag_is_provided_1209", message: "Ambient const enums are not allowed when the '--isolatedModules' flag is provided." },
Invalid_use_of_0_Class_definitions_are_automatically_in_strict_mode: { code: 1210, category: ts.DiagnosticCategory.Error, key: "Invalid_use_of_0_Class_definitions_are_automatically_in_strict_mode_1210", message: "Invalid use of '{0}'. Class definitions are automatically in strict mode." },
A_class_declaration_without_the_default_modifier_must_have_a_name: { code: 1211, category: ts.DiagnosticCategory.Error, key: "A_class_declaration_without_the_default_modifier_must_have_a_name_1211", message: "A class declaration without the 'default' modifier must have a name" },
Identifier_expected_0_is_a_reserved_word_in_strict_mode: { code: 1212, category: ts.DiagnosticCategory.Error, key: "Identifier_expected_0_is_a_reserved_word_in_strict_mode_1212", message: "Identifier expected. '{0}' is a reserved word in strict mode" },
Identifier_expected_0_is_a_reserved_word_in_strict_mode_Class_definitions_are_automatically_in_strict_mode: { code: 1213, category: ts.DiagnosticCategory.Error, key: "Identifier_expected_0_is_a_reserved_word_in_strict_mode_Class_definitions_are_automatically_in_stric_1213", message: "Identifier expected. '{0}' is a reserved word in strict mode. Class definitions are automatically in strict mode." },
Identifier_expected_0_is_a_reserved_word_in_strict_mode_Modules_are_automatically_in_strict_mode: { code: 1214, category: ts.DiagnosticCategory.Error, key: "Identifier_expected_0_is_a_reserved_word_in_strict_mode_Modules_are_automatically_in_strict_mode_1214", message: "Identifier expected. '{0}' is a reserved word in strict mode. Modules are automatically in strict mode." },
Invalid_use_of_0_Modules_are_automatically_in_strict_mode: { code: 1215, category: ts.DiagnosticCategory.Error, key: "Invalid_use_of_0_Modules_are_automatically_in_strict_mode_1215", message: "Invalid use of '{0}'. Modules are automatically in strict mode." },
Export_assignment_is_not_supported_when_module_flag_is_system: { code: 1218, category: ts.DiagnosticCategory.Error, key: "Export_assignment_is_not_supported_when_module_flag_is_system_1218", message: "Export assignment is not supported when '--module' flag is 'system'." },
Experimental_support_for_decorators_is_a_feature_that_is_subject_to_change_in_a_future_release_Set_the_experimentalDecorators_option_to_remove_this_warning: { code: 1219, category: ts.DiagnosticCategory.Error, key: "Experimental_support_for_decorators_is_a_feature_that_is_subject_to_change_in_a_future_release_Set_t_1219", message: "Experimental support for decorators is a feature that is subject to change in a future release. Set the 'experimentalDecorators' option to remove this warning." },
Generators_are_only_available_when_targeting_ECMAScript_2015_or_higher: { code: 1220, category: ts.DiagnosticCategory.Error, key: "Generators_are_only_available_when_targeting_ECMAScript_2015_or_higher_1220", message: "Generators are only available when targeting ECMAScript 2015 or higher." },
Generators_are_not_allowed_in_an_ambient_context: { code: 1221, category: ts.DiagnosticCategory.Error, key: "Generators_are_not_allowed_in_an_ambient_context_1221", message: "Generators are not allowed in an ambient context." },
An_overload_signature_cannot_be_declared_as_a_generator: { code: 1222, category: ts.DiagnosticCategory.Error, key: "An_overload_signature_cannot_be_declared_as_a_generator_1222", message: "An overload signature cannot be declared as a generator." },
_0_tag_already_specified: { code: 1223, category: ts.DiagnosticCategory.Error, key: "_0_tag_already_specified_1223", message: "'{0}' tag already specified." },
Signature_0_must_have_a_type_predicate: { code: 1224, category: ts.DiagnosticCategory.Error, key: "Signature_0_must_have_a_type_predicate_1224", message: "Signature '{0}' must have a type predicate." },
Cannot_find_parameter_0: { code: 1225, category: ts.DiagnosticCategory.Error, key: "Cannot_find_parameter_0_1225", message: "Cannot find parameter '{0}'." },
Type_predicate_0_is_not_assignable_to_1: { code: 1226, category: ts.DiagnosticCategory.Error, key: "Type_predicate_0_is_not_assignable_to_1_1226", message: "Type predicate '{0}' is not assignable to '{1}'." },
Parameter_0_is_not_in_the_same_position_as_parameter_1: { code: 1227, category: ts.DiagnosticCategory.Error, key: "Parameter_0_is_not_in_the_same_position_as_parameter_1_1227", message: "Parameter '{0}' is not in the same position as parameter '{1}'." },
A_type_predicate_is_only_allowed_in_return_type_position_for_functions_and_methods: { code: 1228, category: ts.DiagnosticCategory.Error, key: "A_type_predicate_is_only_allowed_in_return_type_position_for_functions_and_methods_1228", message: "A type predicate is only allowed in return type position for functions and methods." },
A_type_predicate_cannot_reference_a_rest_parameter: { code: 1229, category: ts.DiagnosticCategory.Error, key: "A_type_predicate_cannot_reference_a_rest_parameter_1229", message: "A type predicate cannot reference a rest parameter." },
A_type_predicate_cannot_reference_element_0_in_a_binding_pattern: { code: 1230, category: ts.DiagnosticCategory.Error, key: "A_type_predicate_cannot_reference_element_0_in_a_binding_pattern_1230", message: "A type predicate cannot reference element '{0}' in a binding pattern." },
An_export_assignment_can_only_be_used_in_a_module: { code: 1231, category: ts.DiagnosticCategory.Error, key: "An_export_assignment_can_only_be_used_in_a_module_1231", message: "An export assignment can only be used in a module." },
An_import_declaration_can_only_be_used_in_a_namespace_or_module: { code: 1232, category: ts.DiagnosticCategory.Error, key: "An_import_declaration_can_only_be_used_in_a_namespace_or_module_1232", message: "An import declaration can only be used in a namespace or module." },
An_export_declaration_can_only_be_used_in_a_module: { code: 1233, category: ts.DiagnosticCategory.Error, key: "An_export_declaration_can_only_be_used_in_a_module_1233", message: "An export declaration can only be used in a module." },
An_ambient_module_declaration_is_only_allowed_at_the_top_level_in_a_file: { code: 1234, category: ts.DiagnosticCategory.Error, key: "An_ambient_module_declaration_is_only_allowed_at_the_top_level_in_a_file_1234", message: "An ambient module declaration is only allowed at the top level in a file." },
A_namespace_declaration_is_only_allowed_in_a_namespace_or_module: { code: 1235, category: ts.DiagnosticCategory.Error, key: "A_namespace_declaration_is_only_allowed_in_a_namespace_or_module_1235", message: "A namespace declaration is only allowed in a namespace or module." },
The_return_type_of_a_property_decorator_function_must_be_either_void_or_any: { code: 1236, category: ts.DiagnosticCategory.Error, key: "The_return_type_of_a_property_decorator_function_must_be_either_void_or_any_1236", message: "The return type of a property decorator function must be either 'void' or 'any'." },
The_return_type_of_a_parameter_decorator_function_must_be_either_void_or_any: { code: 1237, category: ts.DiagnosticCategory.Error, key: "The_return_type_of_a_parameter_decorator_function_must_be_either_void_or_any_1237", message: "The return type of a parameter decorator function must be either 'void' or 'any'." },
Unable_to_resolve_signature_of_class_decorator_when_called_as_an_expression: { code: 1238, category: ts.DiagnosticCategory.Error, key: "Unable_to_resolve_signature_of_class_decorator_when_called_as_an_expression_1238", message: "Unable to resolve signature of class decorator when called as an expression." },
Unable_to_resolve_signature_of_parameter_decorator_when_called_as_an_expression: { code: 1239, category: ts.DiagnosticCategory.Error, key: "Unable_to_resolve_signature_of_parameter_decorator_when_called_as_an_expression_1239", message: "Unable to resolve signature of parameter decorator when called as an expression." },
Unable_to_resolve_signature_of_property_decorator_when_called_as_an_expression: { code: 1240, category: ts.DiagnosticCategory.Error, key: "Unable_to_resolve_signature_of_property_decorator_when_called_as_an_expression_1240", message: "Unable to resolve signature of property decorator when called as an expression." },
Unable_to_resolve_signature_of_method_decorator_when_called_as_an_expression: { code: 1241, category: ts.DiagnosticCategory.Error, key: "Unable_to_resolve_signature_of_method_decorator_when_called_as_an_expression_1241", message: "Unable to resolve signature of method decorator when called as an expression." },
abstract_modifier_can_only_appear_on_a_class_method_or_property_declaration: { code: 1242, category: ts.DiagnosticCategory.Error, key: "abstract_modifier_can_only_appear_on_a_class_method_or_property_declaration_1242", message: "'abstract' modifier can only appear on a class, method, or property declaration." },
_0_modifier_cannot_be_used_with_1_modifier: { code: 1243, category: ts.DiagnosticCategory.Error, key: "_0_modifier_cannot_be_used_with_1_modifier_1243", message: "'{0}' modifier cannot be used with '{1}' modifier." },
Abstract_methods_can_only_appear_within_an_abstract_class: { code: 1244, category: ts.DiagnosticCategory.Error, key: "Abstract_methods_can_only_appear_within_an_abstract_class_1244", message: "Abstract methods can only appear within an abstract class." },
Method_0_cannot_have_an_implementation_because_it_is_marked_abstract: { code: 1245, category: ts.DiagnosticCategory.Error, key: "Method_0_cannot_have_an_implementation_because_it_is_marked_abstract_1245", message: "Method '{0}' cannot have an implementation because it is marked abstract." },
An_interface_property_cannot_have_an_initializer: { code: 1246, category: ts.DiagnosticCategory.Error, key: "An_interface_property_cannot_have_an_initializer_1246", message: "An interface property cannot have an initializer." },
A_type_literal_property_cannot_have_an_initializer: { code: 1247, category: ts.DiagnosticCategory.Error, key: "A_type_literal_property_cannot_have_an_initializer_1247", message: "A type literal property cannot have an initializer." },
A_class_member_cannot_have_the_0_keyword: { code: 1248, category: ts.DiagnosticCategory.Error, key: "A_class_member_cannot_have_the_0_keyword_1248", message: "A class member cannot have the '{0}' keyword." },
A_decorator_can_only_decorate_a_method_implementation_not_an_overload: { code: 1249, category: ts.DiagnosticCategory.Error, key: "A_decorator_can_only_decorate_a_method_implementation_not_an_overload_1249", message: "A decorator can only decorate a method implementation, not an overload." },
Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5: { code: 1250, category: ts.DiagnosticCategory.Error, key: "Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5_1250", message: "Function declarations are not allowed inside blocks in strict mode when targeting 'ES3' or 'ES5'." },
Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5_Class_definitions_are_automatically_in_strict_mode: { code: 1251, category: ts.DiagnosticCategory.Error, key: "Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5_Class_d_1251", message: "Function declarations are not allowed inside blocks in strict mode when targeting 'ES3' or 'ES5'. Class definitions are automatically in strict mode." },
Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5_Modules_are_automatically_in_strict_mode: { code: 1252, category: ts.DiagnosticCategory.Error, key: "Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5_Modules_1252", message: "Function declarations are not allowed inside blocks in strict mode when targeting 'ES3' or 'ES5'. Modules are automatically in strict mode." },
_0_tag_cannot_be_used_independently_as_a_top_level_JSDoc_tag: { code: 1253, category: ts.DiagnosticCategory.Error, key: "_0_tag_cannot_be_used_independently_as_a_top_level_JSDoc_tag_1253", message: "'{0}' tag cannot be used independently as a top level JSDoc tag." },
A_const_initializer_in_an_ambient_context_must_be_a_string_or_numeric_literal: { code: 1254, category: ts.DiagnosticCategory.Error, key: "A_const_initializer_in_an_ambient_context_must_be_a_string_or_numeric_literal_1254", message: "A 'const' initializer in an ambient context must be a string or numeric literal." },
with_statements_are_not_allowed_in_an_async_function_block: { code: 1300, category: ts.DiagnosticCategory.Error, key: "with_statements_are_not_allowed_in_an_async_function_block_1300", message: "'with' statements are not allowed in an async function block." },
await_expression_is_only_allowed_within_an_async_function: { code: 1308, category: ts.DiagnosticCategory.Error, key: "await_expression_is_only_allowed_within_an_async_function_1308", message: "'await' expression is only allowed within an async function." },
can_only_be_used_in_an_object_literal_property_inside_a_destructuring_assignment: { code: 1312, category: ts.DiagnosticCategory.Error, key: "can_only_be_used_in_an_object_literal_property_inside_a_destructuring_assignment_1312", message: "'=' can only be used in an object literal property inside a destructuring assignment." },
The_body_of_an_if_statement_cannot_be_the_empty_statement: { code: 1313, category: ts.DiagnosticCategory.Error, key: "The_body_of_an_if_statement_cannot_be_the_empty_statement_1313", message: "The body of an 'if' statement cannot be the empty statement." },
Global_module_exports_may_only_appear_in_module_files: { code: 1314, category: ts.DiagnosticCategory.Error, key: "Global_module_exports_may_only_appear_in_module_files_1314", message: "Global module exports may only appear in module files." },
Global_module_exports_may_only_appear_in_declaration_files: { code: 1315, category: ts.DiagnosticCategory.Error, key: "Global_module_exports_may_only_appear_in_declaration_files_1315", message: "Global module exports may only appear in declaration files." },
Global_module_exports_may_only_appear_at_top_level: { code: 1316, category: ts.DiagnosticCategory.Error, key: "Global_module_exports_may_only_appear_at_top_level_1316", message: "Global module exports may only appear at top level." },
A_parameter_property_cannot_be_declared_using_a_rest_parameter: { code: 1317, category: ts.DiagnosticCategory.Error, key: "A_parameter_property_cannot_be_declared_using_a_rest_parameter_1317", message: "A parameter property cannot be declared using a rest parameter." },
Duplicate_identifier_0: { code: 2300, category: ts.DiagnosticCategory.Error, key: "Duplicate_identifier_0_2300", message: "Duplicate identifier '{0}'." },
Initializer_of_instance_member_variable_0_cannot_reference_identifier_1_declared_in_the_constructor: { code: 2301, category: ts.DiagnosticCategory.Error, key: "Initializer_of_instance_member_variable_0_cannot_reference_identifier_1_declared_in_the_constructor_2301", message: "Initializer of instance member variable '{0}' cannot reference identifier '{1}' declared in the constructor." },
Static_members_cannot_reference_class_type_parameters: { code: 2302, category: ts.DiagnosticCategory.Error, key: "Static_members_cannot_reference_class_type_parameters_2302", message: "Static members cannot reference class type parameters." },
Circular_definition_of_import_alias_0: { code: 2303, category: ts.DiagnosticCategory.Error, key: "Circular_definition_of_import_alias_0_2303", message: "Circular definition of import alias '{0}'." },
Cannot_find_name_0: { code: 2304, category: ts.DiagnosticCategory.Error, key: "Cannot_find_name_0_2304", message: "Cannot find name '{0}'." },
Module_0_has_no_exported_member_1: { code: 2305, category: ts.DiagnosticCategory.Error, key: "Module_0_has_no_exported_member_1_2305", message: "Module '{0}' has no exported member '{1}'." },
File_0_is_not_a_module: { code: 2306, category: ts.DiagnosticCategory.Error, key: "File_0_is_not_a_module_2306", message: "File '{0}' is not a module." },
Cannot_find_module_0: { code: 2307, category: ts.DiagnosticCategory.Error, key: "Cannot_find_module_0_2307", message: "Cannot find module '{0}'." },
Module_0_has_already_exported_a_member_named_1_Consider_explicitly_re_exporting_to_resolve_the_ambiguity: { code: 2308, category: ts.DiagnosticCategory.Error, key: "Module_0_has_already_exported_a_member_named_1_Consider_explicitly_re_exporting_to_resolve_the_ambig_2308", message: "Module {0} has already exported a member named '{1}'. Consider explicitly re-exporting to resolve the ambiguity." },
An_export_assignment_cannot_be_used_in_a_module_with_other_exported_elements: { code: 2309, category: ts.DiagnosticCategory.Error, key: "An_export_assignment_cannot_be_used_in_a_module_with_other_exported_elements_2309", message: "An export assignment cannot be used in a module with other exported elements." },
Type_0_recursively_references_itself_as_a_base_type: { code: 2310, category: ts.DiagnosticCategory.Error, key: "Type_0_recursively_references_itself_as_a_base_type_2310", message: "Type '{0}' recursively references itself as a base type." },
A_class_may_only_extend_another_class: { code: 2311, category: ts.DiagnosticCategory.Error, key: "A_class_may_only_extend_another_class_2311", message: "A class may only extend another class." },
An_interface_may_only_extend_a_class_or_another_interface: { code: 2312, category: ts.DiagnosticCategory.Error, key: "An_interface_may_only_extend_a_class_or_another_interface_2312", message: "An interface may only extend a class or another interface." },
Type_parameter_0_has_a_circular_constraint: { code: 2313, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_has_a_circular_constraint_2313", message: "Type parameter '{0}' has a circular constraint." },
Generic_type_0_requires_1_type_argument_s: { code: 2314, category: ts.DiagnosticCategory.Error, key: "Generic_type_0_requires_1_type_argument_s_2314", message: "Generic type '{0}' requires {1} type argument(s)." },
Type_0_is_not_generic: { code: 2315, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_generic_2315", message: "Type '{0}' is not generic." },
Global_type_0_must_be_a_class_or_interface_type: { code: 2316, category: ts.DiagnosticCategory.Error, key: "Global_type_0_must_be_a_class_or_interface_type_2316", message: "Global type '{0}' must be a class or interface type." },
Global_type_0_must_have_1_type_parameter_s: { code: 2317, category: ts.DiagnosticCategory.Error, key: "Global_type_0_must_have_1_type_parameter_s_2317", message: "Global type '{0}' must have {1} type parameter(s)." },
Cannot_find_global_type_0: { code: 2318, category: ts.DiagnosticCategory.Error, key: "Cannot_find_global_type_0_2318", message: "Cannot find global type '{0}'." },
Named_property_0_of_types_1_and_2_are_not_identical: { code: 2319, category: ts.DiagnosticCategory.Error, key: "Named_property_0_of_types_1_and_2_are_not_identical_2319", message: "Named property '{0}' of types '{1}' and '{2}' are not identical." },
Interface_0_cannot_simultaneously_extend_types_1_and_2: { code: 2320, category: ts.DiagnosticCategory.Error, key: "Interface_0_cannot_simultaneously_extend_types_1_and_2_2320", message: "Interface '{0}' cannot simultaneously extend types '{1}' and '{2}'." },
Excessive_stack_depth_comparing_types_0_and_1: { code: 2321, category: ts.DiagnosticCategory.Error, key: "Excessive_stack_depth_comparing_types_0_and_1_2321", message: "Excessive stack depth comparing types '{0}' and '{1}'." },
Type_0_is_not_assignable_to_type_1: { code: 2322, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_assignable_to_type_1_2322", message: "Type '{0}' is not assignable to type '{1}'." },
Cannot_redeclare_exported_variable_0: { code: 2323, category: ts.DiagnosticCategory.Error, key: "Cannot_redeclare_exported_variable_0_2323", message: "Cannot redeclare exported variable '{0}'." },
Property_0_is_missing_in_type_1: { code: 2324, category: ts.DiagnosticCategory.Error, key: "Property_0_is_missing_in_type_1_2324", message: "Property '{0}' is missing in type '{1}'." },
Property_0_is_private_in_type_1_but_not_in_type_2: { code: 2325, category: ts.DiagnosticCategory.Error, key: "Property_0_is_private_in_type_1_but_not_in_type_2_2325", message: "Property '{0}' is private in type '{1}' but not in type '{2}'." },
Types_of_property_0_are_incompatible: { code: 2326, category: ts.DiagnosticCategory.Error, key: "Types_of_property_0_are_incompatible_2326", message: "Types of property '{0}' are incompatible." },
Property_0_is_optional_in_type_1_but_required_in_type_2: { code: 2327, category: ts.DiagnosticCategory.Error, key: "Property_0_is_optional_in_type_1_but_required_in_type_2_2327", message: "Property '{0}' is optional in type '{1}' but required in type '{2}'." },
Types_of_parameters_0_and_1_are_incompatible: { code: 2328, category: ts.DiagnosticCategory.Error, key: "Types_of_parameters_0_and_1_are_incompatible_2328", message: "Types of parameters '{0}' and '{1}' are incompatible." },
Index_signature_is_missing_in_type_0: { code: 2329, category: ts.DiagnosticCategory.Error, key: "Index_signature_is_missing_in_type_0_2329", message: "Index signature is missing in type '{0}'." },
Index_signatures_are_incompatible: { code: 2330, category: ts.DiagnosticCategory.Error, key: "Index_signatures_are_incompatible_2330", message: "Index signatures are incompatible." },
this_cannot_be_referenced_in_a_module_or_namespace_body: { code: 2331, category: ts.DiagnosticCategory.Error, key: "this_cannot_be_referenced_in_a_module_or_namespace_body_2331", message: "'this' cannot be referenced in a module or namespace body." },
this_cannot_be_referenced_in_current_location: { code: 2332, category: ts.DiagnosticCategory.Error, key: "this_cannot_be_referenced_in_current_location_2332", message: "'this' cannot be referenced in current location." },
this_cannot_be_referenced_in_constructor_arguments: { code: 2333, category: ts.DiagnosticCategory.Error, key: "this_cannot_be_referenced_in_constructor_arguments_2333", message: "'this' cannot be referenced in constructor arguments." },
this_cannot_be_referenced_in_a_static_property_initializer: { code: 2334, category: ts.DiagnosticCategory.Error, key: "this_cannot_be_referenced_in_a_static_property_initializer_2334", message: "'this' cannot be referenced in a static property initializer." },
super_can_only_be_referenced_in_a_derived_class: { code: 2335, category: ts.DiagnosticCategory.Error, key: "super_can_only_be_referenced_in_a_derived_class_2335", message: "'super' can only be referenced in a derived class." },
super_cannot_be_referenced_in_constructor_arguments: { code: 2336, category: ts.DiagnosticCategory.Error, key: "super_cannot_be_referenced_in_constructor_arguments_2336", message: "'super' cannot be referenced in constructor arguments." },
Super_calls_are_not_permitted_outside_constructors_or_in_nested_functions_inside_constructors: { code: 2337, category: ts.DiagnosticCategory.Error, key: "Super_calls_are_not_permitted_outside_constructors_or_in_nested_functions_inside_constructors_2337", message: "Super calls are not permitted outside constructors or in nested functions inside constructors." },
super_property_access_is_permitted_only_in_a_constructor_member_function_or_member_accessor_of_a_derived_class: { code: 2338, category: ts.DiagnosticCategory.Error, key: "super_property_access_is_permitted_only_in_a_constructor_member_function_or_member_accessor_of_a_der_2338", message: "'super' property access is permitted only in a constructor, member function, or member accessor of a derived class." },
Property_0_does_not_exist_on_type_1: { code: 2339, category: ts.DiagnosticCategory.Error, key: "Property_0_does_not_exist_on_type_1_2339", message: "Property '{0}' does not exist on type '{1}'." },
Only_public_and_protected_methods_of_the_base_class_are_accessible_via_the_super_keyword: { code: 2340, category: ts.DiagnosticCategory.Error, key: "Only_public_and_protected_methods_of_the_base_class_are_accessible_via_the_super_keyword_2340", message: "Only public and protected methods of the base class are accessible via the 'super' keyword." },
Property_0_is_private_and_only_accessible_within_class_1: { code: 2341, category: ts.DiagnosticCategory.Error, key: "Property_0_is_private_and_only_accessible_within_class_1_2341", message: "Property '{0}' is private and only accessible within class '{1}'." },
An_index_expression_argument_must_be_of_type_string_number_symbol_or_any: { code: 2342, category: ts.DiagnosticCategory.Error, key: "An_index_expression_argument_must_be_of_type_string_number_symbol_or_any_2342", message: "An index expression argument must be of type 'string', 'number', 'symbol', or 'any'." },
Type_0_does_not_satisfy_the_constraint_1: { code: 2344, category: ts.DiagnosticCategory.Error, key: "Type_0_does_not_satisfy_the_constraint_1_2344", message: "Type '{0}' does not satisfy the constraint '{1}'." },
Argument_of_type_0_is_not_assignable_to_parameter_of_type_1: { code: 2345, category: ts.DiagnosticCategory.Error, key: "Argument_of_type_0_is_not_assignable_to_parameter_of_type_1_2345", message: "Argument of type '{0}' is not assignable to parameter of type '{1}'." },
Supplied_parameters_do_not_match_any_signature_of_call_target: { code: 2346, category: ts.DiagnosticCategory.Error, key: "Supplied_parameters_do_not_match_any_signature_of_call_target_2346", message: "Supplied parameters do not match any signature of call target." },
Untyped_function_calls_may_not_accept_type_arguments: { code: 2347, category: ts.DiagnosticCategory.Error, key: "Untyped_function_calls_may_not_accept_type_arguments_2347", message: "Untyped function calls may not accept type arguments." },
Value_of_type_0_is_not_callable_Did_you_mean_to_include_new: { code: 2348, category: ts.DiagnosticCategory.Error, key: "Value_of_type_0_is_not_callable_Did_you_mean_to_include_new_2348", message: "Value of type '{0}' is not callable. Did you mean to include 'new'?" },
Cannot_invoke_an_expression_whose_type_lacks_a_call_signature_Type_0_has_no_compatible_call_signatures: { code: 2349, category: ts.DiagnosticCategory.Error, key: "Cannot_invoke_an_expression_whose_type_lacks_a_call_signature_Type_0_has_no_compatible_call_signatur_2349", message: "Cannot invoke an expression whose type lacks a call signature. Type '{0}' has no compatible call signatures." },
Only_a_void_function_can_be_called_with_the_new_keyword: { code: 2350, category: ts.DiagnosticCategory.Error, key: "Only_a_void_function_can_be_called_with_the_new_keyword_2350", message: "Only a void function can be called with the 'new' keyword." },
Cannot_use_new_with_an_expression_whose_type_lacks_a_call_or_construct_signature: { code: 2351, category: ts.DiagnosticCategory.Error, key: "Cannot_use_new_with_an_expression_whose_type_lacks_a_call_or_construct_signature_2351", message: "Cannot use 'new' with an expression whose type lacks a call or construct signature." },
Type_0_cannot_be_converted_to_type_1: { code: 2352, category: ts.DiagnosticCategory.Error, key: "Type_0_cannot_be_converted_to_type_1_2352", message: "Type '{0}' cannot be converted to type '{1}'." },
Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1: { code: 2353, category: ts.DiagnosticCategory.Error, key: "Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1_2353", message: "Object literal may only specify known properties, and '{0}' does not exist in type '{1}'." },
A_function_whose_declared_type_is_neither_void_nor_any_must_return_a_value: { code: 2355, category: ts.DiagnosticCategory.Error, key: "A_function_whose_declared_type_is_neither_void_nor_any_must_return_a_value_2355", message: "A function whose declared type is neither 'void' nor 'any' must return a value." },
An_arithmetic_operand_must_be_of_type_any_number_or_an_enum_type: { code: 2356, category: ts.DiagnosticCategory.Error, key: "An_arithmetic_operand_must_be_of_type_any_number_or_an_enum_type_2356", message: "An arithmetic operand must be of type 'any', 'number' or an enum type." },
The_operand_of_an_increment_or_decrement_operator_must_be_a_variable_or_a_property_access: { code: 2357, category: ts.DiagnosticCategory.Error, key: "The_operand_of_an_increment_or_decrement_operator_must_be_a_variable_or_a_property_access_2357", message: "The operand of an increment or decrement operator must be a variable or a property access." },
The_left_hand_side_of_an_instanceof_expression_must_be_of_type_any_an_object_type_or_a_type_parameter: { code: 2358, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_an_instanceof_expression_must_be_of_type_any_an_object_type_or_a_type_paramete_2358", message: "The left-hand side of an 'instanceof' expression must be of type 'any', an object type or a type parameter." },
The_right_hand_side_of_an_instanceof_expression_must_be_of_type_any_or_of_a_type_assignable_to_the_Function_interface_type: { code: 2359, category: ts.DiagnosticCategory.Error, key: "The_right_hand_side_of_an_instanceof_expression_must_be_of_type_any_or_of_a_type_assignable_to_the_F_2359", message: "The right-hand side of an 'instanceof' expression must be of type 'any' or of a type assignable to the 'Function' interface type." },
The_left_hand_side_of_an_in_expression_must_be_of_type_any_string_number_or_symbol: { code: 2360, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_an_in_expression_must_be_of_type_any_string_number_or_symbol_2360", message: "The left-hand side of an 'in' expression must be of type 'any', 'string', 'number', or 'symbol'." },
The_right_hand_side_of_an_in_expression_must_be_of_type_any_an_object_type_or_a_type_parameter: { code: 2361, category: ts.DiagnosticCategory.Error, key: "The_right_hand_side_of_an_in_expression_must_be_of_type_any_an_object_type_or_a_type_parameter_2361", message: "The right-hand side of an 'in' expression must be of type 'any', an object type or a type parameter" },
The_left_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_or_an_enum_type: { code: 2362, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_or_an_enum_type_2362", message: "The left-hand side of an arithmetic operation must be of type 'any', 'number' or an enum type." },
The_right_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_or_an_enum_type: { code: 2363, category: ts.DiagnosticCategory.Error, key: "The_right_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_or_an_enum_type_2363", message: "The right-hand side of an arithmetic operation must be of type 'any', 'number' or an enum type." },
The_left_hand_side_of_an_assignment_expression_must_be_a_variable_or_a_property_access: { code: 2364, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_an_assignment_expression_must_be_a_variable_or_a_property_access_2364", message: "The left-hand side of an assignment expression must be a variable or a property access." },
Operator_0_cannot_be_applied_to_types_1_and_2: { code: 2365, category: ts.DiagnosticCategory.Error, key: "Operator_0_cannot_be_applied_to_types_1_and_2_2365", message: "Operator '{0}' cannot be applied to types '{1}' and '{2}'." },
Function_lacks_ending_return_statement_and_return_type_does_not_include_undefined: { code: 2366, category: ts.DiagnosticCategory.Error, key: "Function_lacks_ending_return_statement_and_return_type_does_not_include_undefined_2366", message: "Function lacks ending return statement and return type does not include 'undefined'." },
Type_parameter_name_cannot_be_0: { code: 2368, category: ts.DiagnosticCategory.Error, key: "Type_parameter_name_cannot_be_0_2368", message: "Type parameter name cannot be '{0}'" },
A_parameter_property_is_only_allowed_in_a_constructor_implementation: { code: 2369, category: ts.DiagnosticCategory.Error, key: "A_parameter_property_is_only_allowed_in_a_constructor_implementation_2369", message: "A parameter property is only allowed in a constructor implementation." },
A_rest_parameter_must_be_of_an_array_type: { code: 2370, category: ts.DiagnosticCategory.Error, key: "A_rest_parameter_must_be_of_an_array_type_2370", message: "A rest parameter must be of an array type." },
A_parameter_initializer_is_only_allowed_in_a_function_or_constructor_implementation: { code: 2371, category: ts.DiagnosticCategory.Error, key: "A_parameter_initializer_is_only_allowed_in_a_function_or_constructor_implementation_2371", message: "A parameter initializer is only allowed in a function or constructor implementation." },
Parameter_0_cannot_be_referenced_in_its_initializer: { code: 2372, category: ts.DiagnosticCategory.Error, key: "Parameter_0_cannot_be_referenced_in_its_initializer_2372", message: "Parameter '{0}' cannot be referenced in its initializer." },
Initializer_of_parameter_0_cannot_reference_identifier_1_declared_after_it: { code: 2373, category: ts.DiagnosticCategory.Error, key: "Initializer_of_parameter_0_cannot_reference_identifier_1_declared_after_it_2373", message: "Initializer of parameter '{0}' cannot reference identifier '{1}' declared after it." },
Duplicate_string_index_signature: { code: 2374, category: ts.DiagnosticCategory.Error, key: "Duplicate_string_index_signature_2374", message: "Duplicate string index signature." },
Duplicate_number_index_signature: { code: 2375, category: ts.DiagnosticCategory.Error, key: "Duplicate_number_index_signature_2375", message: "Duplicate number index signature." },
A_super_call_must_be_the_first_statement_in_the_constructor_when_a_class_contains_initialized_properties_or_has_parameter_properties: { code: 2376, category: ts.DiagnosticCategory.Error, key: "A_super_call_must_be_the_first_statement_in_the_constructor_when_a_class_contains_initialized_proper_2376", message: "A 'super' call must be the first statement in the constructor when a class contains initialized properties or has parameter properties." },
Constructors_for_derived_classes_must_contain_a_super_call: { code: 2377, category: ts.DiagnosticCategory.Error, key: "Constructors_for_derived_classes_must_contain_a_super_call_2377", message: "Constructors for derived classes must contain a 'super' call." },
A_get_accessor_must_return_a_value: { code: 2378, category: ts.DiagnosticCategory.Error, key: "A_get_accessor_must_return_a_value_2378", message: "A 'get' accessor must return a value." },
Getter_and_setter_accessors_do_not_agree_in_visibility: { code: 2379, category: ts.DiagnosticCategory.Error, key: "Getter_and_setter_accessors_do_not_agree_in_visibility_2379", message: "Getter and setter accessors do not agree in visibility." },
get_and_set_accessor_must_have_the_same_type: { code: 2380, category: ts.DiagnosticCategory.Error, key: "get_and_set_accessor_must_have_the_same_type_2380", message: "'get' and 'set' accessor must have the same type." },
A_signature_with_an_implementation_cannot_use_a_string_literal_type: { code: 2381, category: ts.DiagnosticCategory.Error, key: "A_signature_with_an_implementation_cannot_use_a_string_literal_type_2381", message: "A signature with an implementation cannot use a string literal type." },
Specialized_overload_signature_is_not_assignable_to_any_non_specialized_signature: { code: 2382, category: ts.DiagnosticCategory.Error, key: "Specialized_overload_signature_is_not_assignable_to_any_non_specialized_signature_2382", message: "Specialized overload signature is not assignable to any non-specialized signature." },
Overload_signatures_must_all_be_exported_or_non_exported: { code: 2383, category: ts.DiagnosticCategory.Error, key: "Overload_signatures_must_all_be_exported_or_non_exported_2383", message: "Overload signatures must all be exported or non-exported." },
Overload_signatures_must_all_be_ambient_or_non_ambient: { code: 2384, category: ts.DiagnosticCategory.Error, key: "Overload_signatures_must_all_be_ambient_or_non_ambient_2384", message: "Overload signatures must all be ambient or non-ambient." },
Overload_signatures_must_all_be_public_private_or_protected: { code: 2385, category: ts.DiagnosticCategory.Error, key: "Overload_signatures_must_all_be_public_private_or_protected_2385", message: "Overload signatures must all be public, private or protected." },
Overload_signatures_must_all_be_optional_or_required: { code: 2386, category: ts.DiagnosticCategory.Error, key: "Overload_signatures_must_all_be_optional_or_required_2386", message: "Overload signatures must all be optional or required." },
Function_overload_must_be_static: { code: 2387, category: ts.DiagnosticCategory.Error, key: "Function_overload_must_be_static_2387", message: "Function overload must be static." },
Function_overload_must_not_be_static: { code: 2388, category: ts.DiagnosticCategory.Error, key: "Function_overload_must_not_be_static_2388", message: "Function overload must not be static." },
Function_implementation_name_must_be_0: { code: 2389, category: ts.DiagnosticCategory.Error, key: "Function_implementation_name_must_be_0_2389", message: "Function implementation name must be '{0}'." },
Constructor_implementation_is_missing: { code: 2390, category: ts.DiagnosticCategory.Error, key: "Constructor_implementation_is_missing_2390", message: "Constructor implementation is missing." },
Function_implementation_is_missing_or_not_immediately_following_the_declaration: { code: 2391, category: ts.DiagnosticCategory.Error, key: "Function_implementation_is_missing_or_not_immediately_following_the_declaration_2391", message: "Function implementation is missing or not immediately following the declaration." },
Multiple_constructor_implementations_are_not_allowed: { code: 2392, category: ts.DiagnosticCategory.Error, key: "Multiple_constructor_implementations_are_not_allowed_2392", message: "Multiple constructor implementations are not allowed." },
Duplicate_function_implementation: { code: 2393, category: ts.DiagnosticCategory.Error, key: "Duplicate_function_implementation_2393", message: "Duplicate function implementation." },
Overload_signature_is_not_compatible_with_function_implementation: { code: 2394, category: ts.DiagnosticCategory.Error, key: "Overload_signature_is_not_compatible_with_function_implementation_2394", message: "Overload signature is not compatible with function implementation." },
Individual_declarations_in_merged_declaration_0_must_be_all_exported_or_all_local: { code: 2395, category: ts.DiagnosticCategory.Error, key: "Individual_declarations_in_merged_declaration_0_must_be_all_exported_or_all_local_2395", message: "Individual declarations in merged declaration '{0}' must be all exported or all local." },
Duplicate_identifier_arguments_Compiler_uses_arguments_to_initialize_rest_parameters: { code: 2396, category: ts.DiagnosticCategory.Error, key: "Duplicate_identifier_arguments_Compiler_uses_arguments_to_initialize_rest_parameters_2396", message: "Duplicate identifier 'arguments'. Compiler uses 'arguments' to initialize rest parameters." },
Declaration_name_conflicts_with_built_in_global_identifier_0: { code: 2397, category: ts.DiagnosticCategory.Error, key: "Declaration_name_conflicts_with_built_in_global_identifier_0_2397", message: "Declaration name conflicts with built-in global identifier '{0}'." },
Duplicate_identifier_this_Compiler_uses_variable_declaration_this_to_capture_this_reference: { code: 2399, category: ts.DiagnosticCategory.Error, key: "Duplicate_identifier_this_Compiler_uses_variable_declaration_this_to_capture_this_reference_2399", message: "Duplicate identifier '_this'. Compiler uses variable declaration '_this' to capture 'this' reference." },
Expression_resolves_to_variable_declaration_this_that_compiler_uses_to_capture_this_reference: { code: 2400, category: ts.DiagnosticCategory.Error, key: "Expression_resolves_to_variable_declaration_this_that_compiler_uses_to_capture_this_reference_2400", message: "Expression resolves to variable declaration '_this' that compiler uses to capture 'this' reference." },
Duplicate_identifier_super_Compiler_uses_super_to_capture_base_class_reference: { code: 2401, category: ts.DiagnosticCategory.Error, key: "Duplicate_identifier_super_Compiler_uses_super_to_capture_base_class_reference_2401", message: "Duplicate identifier '_super'. Compiler uses '_super' to capture base class reference." },
Expression_resolves_to_super_that_compiler_uses_to_capture_base_class_reference: { code: 2402, category: ts.DiagnosticCategory.Error, key: "Expression_resolves_to_super_that_compiler_uses_to_capture_base_class_reference_2402", message: "Expression resolves to '_super' that compiler uses to capture base class reference." },
Subsequent_variable_declarations_must_have_the_same_type_Variable_0_must_be_of_type_1_but_here_has_type_2: { code: 2403, category: ts.DiagnosticCategory.Error, key: "Subsequent_variable_declarations_must_have_the_same_type_Variable_0_must_be_of_type_1_but_here_has_t_2403", message: "Subsequent variable declarations must have the same type. Variable '{0}' must be of type '{1}', but here has type '{2}'." },
The_left_hand_side_of_a_for_in_statement_cannot_use_a_type_annotation: { code: 2404, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_a_for_in_statement_cannot_use_a_type_annotation_2404", message: "The left-hand side of a 'for...in' statement cannot use a type annotation." },
The_left_hand_side_of_a_for_in_statement_must_be_of_type_string_or_any: { code: 2405, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_a_for_in_statement_must_be_of_type_string_or_any_2405", message: "The left-hand side of a 'for...in' statement must be of type 'string' or 'any'." },
The_left_hand_side_of_a_for_in_statement_must_be_a_variable_or_a_property_access: { code: 2406, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_a_for_in_statement_must_be_a_variable_or_a_property_access_2406", message: "The left-hand side of a 'for...in' statement must be a variable or a property access." },
The_right_hand_side_of_a_for_in_statement_must_be_of_type_any_an_object_type_or_a_type_parameter: { code: 2407, category: ts.DiagnosticCategory.Error, key: "The_right_hand_side_of_a_for_in_statement_must_be_of_type_any_an_object_type_or_a_type_parameter_2407", message: "The right-hand side of a 'for...in' statement must be of type 'any', an object type or a type parameter." },
Setters_cannot_return_a_value: { code: 2408, category: ts.DiagnosticCategory.Error, key: "Setters_cannot_return_a_value_2408", message: "Setters cannot return a value." },
Return_type_of_constructor_signature_must_be_assignable_to_the_instance_type_of_the_class: { code: 2409, category: ts.DiagnosticCategory.Error, key: "Return_type_of_constructor_signature_must_be_assignable_to_the_instance_type_of_the_class_2409", message: "Return type of constructor signature must be assignable to the instance type of the class" },
The_with_statement_is_not_supported_All_symbols_in_a_with_block_will_have_type_any: { code: 2410, category: ts.DiagnosticCategory.Error, key: "The_with_statement_is_not_supported_All_symbols_in_a_with_block_will_have_type_any_2410", message: "The 'with' statement is not supported. All symbols in a 'with' block will have type 'any'." },
Property_0_of_type_1_is_not_assignable_to_string_index_type_2: { code: 2411, category: ts.DiagnosticCategory.Error, key: "Property_0_of_type_1_is_not_assignable_to_string_index_type_2_2411", message: "Property '{0}' of type '{1}' is not assignable to string index type '{2}'." },
Property_0_of_type_1_is_not_assignable_to_numeric_index_type_2: { code: 2412, category: ts.DiagnosticCategory.Error, key: "Property_0_of_type_1_is_not_assignable_to_numeric_index_type_2_2412", message: "Property '{0}' of type '{1}' is not assignable to numeric index type '{2}'." },
Numeric_index_type_0_is_not_assignable_to_string_index_type_1: { code: 2413, category: ts.DiagnosticCategory.Error, key: "Numeric_index_type_0_is_not_assignable_to_string_index_type_1_2413", message: "Numeric index type '{0}' is not assignable to string index type '{1}'." },
Class_name_cannot_be_0: { code: 2414, category: ts.DiagnosticCategory.Error, key: "Class_name_cannot_be_0_2414", message: "Class name cannot be '{0}'" },
Class_0_incorrectly_extends_base_class_1: { code: 2415, category: ts.DiagnosticCategory.Error, key: "Class_0_incorrectly_extends_base_class_1_2415", message: "Class '{0}' incorrectly extends base class '{1}'." },
Class_static_side_0_incorrectly_extends_base_class_static_side_1: { code: 2417, category: ts.DiagnosticCategory.Error, key: "Class_static_side_0_incorrectly_extends_base_class_static_side_1_2417", message: "Class static side '{0}' incorrectly extends base class static side '{1}'." },
Class_0_incorrectly_implements_interface_1: { code: 2420, category: ts.DiagnosticCategory.Error, key: "Class_0_incorrectly_implements_interface_1_2420", message: "Class '{0}' incorrectly implements interface '{1}'." },
A_class_may_only_implement_another_class_or_interface: { code: 2422, category: ts.DiagnosticCategory.Error, key: "A_class_may_only_implement_another_class_or_interface_2422", message: "A class may only implement another class or interface." },
Class_0_defines_instance_member_function_1_but_extended_class_2_defines_it_as_instance_member_accessor: { code: 2423, category: ts.DiagnosticCategory.Error, key: "Class_0_defines_instance_member_function_1_but_extended_class_2_defines_it_as_instance_member_access_2423", message: "Class '{0}' defines instance member function '{1}', but extended class '{2}' defines it as instance member accessor." },
Class_0_defines_instance_member_function_1_but_extended_class_2_defines_it_as_instance_member_property: { code: 2424, category: ts.DiagnosticCategory.Error, key: "Class_0_defines_instance_member_function_1_but_extended_class_2_defines_it_as_instance_member_proper_2424", message: "Class '{0}' defines instance member function '{1}', but extended class '{2}' defines it as instance member property." },
Class_0_defines_instance_member_property_1_but_extended_class_2_defines_it_as_instance_member_function: { code: 2425, category: ts.DiagnosticCategory.Error, key: "Class_0_defines_instance_member_property_1_but_extended_class_2_defines_it_as_instance_member_functi_2425", message: "Class '{0}' defines instance member property '{1}', but extended class '{2}' defines it as instance member function." },
Class_0_defines_instance_member_accessor_1_but_extended_class_2_defines_it_as_instance_member_function: { code: 2426, category: ts.DiagnosticCategory.Error, key: "Class_0_defines_instance_member_accessor_1_but_extended_class_2_defines_it_as_instance_member_functi_2426", message: "Class '{0}' defines instance member accessor '{1}', but extended class '{2}' defines it as instance member function." },
Interface_name_cannot_be_0: { code: 2427, category: ts.DiagnosticCategory.Error, key: "Interface_name_cannot_be_0_2427", message: "Interface name cannot be '{0}'" },
All_declarations_of_0_must_have_identical_type_parameters: { code: 2428, category: ts.DiagnosticCategory.Error, key: "All_declarations_of_0_must_have_identical_type_parameters_2428", message: "All declarations of '{0}' must have identical type parameters." },
Interface_0_incorrectly_extends_interface_1: { code: 2430, category: ts.DiagnosticCategory.Error, key: "Interface_0_incorrectly_extends_interface_1_2430", message: "Interface '{0}' incorrectly extends interface '{1}'." },
Enum_name_cannot_be_0: { code: 2431, category: ts.DiagnosticCategory.Error, key: "Enum_name_cannot_be_0_2431", message: "Enum name cannot be '{0}'" },
In_an_enum_with_multiple_declarations_only_one_declaration_can_omit_an_initializer_for_its_first_enum_element: { code: 2432, category: ts.DiagnosticCategory.Error, key: "In_an_enum_with_multiple_declarations_only_one_declaration_can_omit_an_initializer_for_its_first_enu_2432", message: "In an enum with multiple declarations, only one declaration can omit an initializer for its first enum element." },
A_namespace_declaration_cannot_be_in_a_different_file_from_a_class_or_function_with_which_it_is_merged: { code: 2433, category: ts.DiagnosticCategory.Error, key: "A_namespace_declaration_cannot_be_in_a_different_file_from_a_class_or_function_with_which_it_is_merg_2433", message: "A namespace declaration cannot be in a different file from a class or function with which it is merged" },
A_namespace_declaration_cannot_be_located_prior_to_a_class_or_function_with_which_it_is_merged: { code: 2434, category: ts.DiagnosticCategory.Error, key: "A_namespace_declaration_cannot_be_located_prior_to_a_class_or_function_with_which_it_is_merged_2434", message: "A namespace declaration cannot be located prior to a class or function with which it is merged" },
Ambient_modules_cannot_be_nested_in_other_modules_or_namespaces: { code: 2435, category: ts.DiagnosticCategory.Error, key: "Ambient_modules_cannot_be_nested_in_other_modules_or_namespaces_2435", message: "Ambient modules cannot be nested in other modules or namespaces." },
Ambient_module_declaration_cannot_specify_relative_module_name: { code: 2436, category: ts.DiagnosticCategory.Error, key: "Ambient_module_declaration_cannot_specify_relative_module_name_2436", message: "Ambient module declaration cannot specify relative module name." },
Module_0_is_hidden_by_a_local_declaration_with_the_same_name: { code: 2437, category: ts.DiagnosticCategory.Error, key: "Module_0_is_hidden_by_a_local_declaration_with_the_same_name_2437", message: "Module '{0}' is hidden by a local declaration with the same name" },
Import_name_cannot_be_0: { code: 2438, category: ts.DiagnosticCategory.Error, key: "Import_name_cannot_be_0_2438", message: "Import name cannot be '{0}'" },
Import_or_export_declaration_in_an_ambient_module_declaration_cannot_reference_module_through_relative_module_name: { code: 2439, category: ts.DiagnosticCategory.Error, key: "Import_or_export_declaration_in_an_ambient_module_declaration_cannot_reference_module_through_relati_2439", message: "Import or export declaration in an ambient module declaration cannot reference module through relative module name." },
Import_declaration_conflicts_with_local_declaration_of_0: { code: 2440, category: ts.DiagnosticCategory.Error, key: "Import_declaration_conflicts_with_local_declaration_of_0_2440", message: "Import declaration conflicts with local declaration of '{0}'" },
Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module: { code: 2441, category: ts.DiagnosticCategory.Error, key: "Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module_2441", message: "Duplicate identifier '{0}'. Compiler reserves name '{1}' in top level scope of a module." },
Types_have_separate_declarations_of_a_private_property_0: { code: 2442, category: ts.DiagnosticCategory.Error, key: "Types_have_separate_declarations_of_a_private_property_0_2442", message: "Types have separate declarations of a private property '{0}'." },
Property_0_is_protected_but_type_1_is_not_a_class_derived_from_2: { code: 2443, category: ts.DiagnosticCategory.Error, key: "Property_0_is_protected_but_type_1_is_not_a_class_derived_from_2_2443", message: "Property '{0}' is protected but type '{1}' is not a class derived from '{2}'." },
Property_0_is_protected_in_type_1_but_public_in_type_2: { code: 2444, category: ts.DiagnosticCategory.Error, key: "Property_0_is_protected_in_type_1_but_public_in_type_2_2444", message: "Property '{0}' is protected in type '{1}' but public in type '{2}'." },
Property_0_is_protected_and_only_accessible_within_class_1_and_its_subclasses: { code: 2445, category: ts.DiagnosticCategory.Error, key: "Property_0_is_protected_and_only_accessible_within_class_1_and_its_subclasses_2445", message: "Property '{0}' is protected and only accessible within class '{1}' and its subclasses." },
Property_0_is_protected_and_only_accessible_through_an_instance_of_class_1: { code: 2446, category: ts.DiagnosticCategory.Error, key: "Property_0_is_protected_and_only_accessible_through_an_instance_of_class_1_2446", message: "Property '{0}' is protected and only accessible through an instance of class '{1}'." },
The_0_operator_is_not_allowed_for_boolean_types_Consider_using_1_instead: { code: 2447, category: ts.DiagnosticCategory.Error, key: "The_0_operator_is_not_allowed_for_boolean_types_Consider_using_1_instead_2447", message: "The '{0}' operator is not allowed for boolean types. Consider using '{1}' instead." },
Block_scoped_variable_0_used_before_its_declaration: { code: 2448, category: ts.DiagnosticCategory.Error, key: "Block_scoped_variable_0_used_before_its_declaration_2448", message: "Block-scoped variable '{0}' used before its declaration." },
Cannot_redeclare_block_scoped_variable_0: { code: 2451, category: ts.DiagnosticCategory.Error, key: "Cannot_redeclare_block_scoped_variable_0_2451", message: "Cannot redeclare block-scoped variable '{0}'." },
An_enum_member_cannot_have_a_numeric_name: { code: 2452, category: ts.DiagnosticCategory.Error, key: "An_enum_member_cannot_have_a_numeric_name_2452", message: "An enum member cannot have a numeric name." },
The_type_argument_for_type_parameter_0_cannot_be_inferred_from_the_usage_Consider_specifying_the_type_arguments_explicitly: { code: 2453, category: ts.DiagnosticCategory.Error, key: "The_type_argument_for_type_parameter_0_cannot_be_inferred_from_the_usage_Consider_specifying_the_typ_2453", message: "The type argument for type parameter '{0}' cannot be inferred from the usage. Consider specifying the type arguments explicitly." },
Variable_0_is_used_before_being_assigned: { code: 2454, category: ts.DiagnosticCategory.Error, key: "Variable_0_is_used_before_being_assigned_2454", message: "Variable '{0}' is used before being assigned." },
Type_argument_candidate_1_is_not_a_valid_type_argument_because_it_is_not_a_supertype_of_candidate_0: { code: 2455, category: ts.DiagnosticCategory.Error, key: "Type_argument_candidate_1_is_not_a_valid_type_argument_because_it_is_not_a_supertype_of_candidate_0_2455", message: "Type argument candidate '{1}' is not a valid type argument because it is not a supertype of candidate '{0}'." },
Type_alias_0_circularly_references_itself: { code: 2456, category: ts.DiagnosticCategory.Error, key: "Type_alias_0_circularly_references_itself_2456", message: "Type alias '{0}' circularly references itself." },
Type_alias_name_cannot_be_0: { code: 2457, category: ts.DiagnosticCategory.Error, key: "Type_alias_name_cannot_be_0_2457", message: "Type alias name cannot be '{0}'" },
An_AMD_module_cannot_have_multiple_name_assignments: { code: 2458, category: ts.DiagnosticCategory.Error, key: "An_AMD_module_cannot_have_multiple_name_assignments_2458", message: "An AMD module cannot have multiple name assignments." },
Type_0_has_no_property_1_and_no_string_index_signature: { code: 2459, category: ts.DiagnosticCategory.Error, key: "Type_0_has_no_property_1_and_no_string_index_signature_2459", message: "Type '{0}' has no property '{1}' and no string index signature." },
Type_0_has_no_property_1: { code: 2460, category: ts.DiagnosticCategory.Error, key: "Type_0_has_no_property_1_2460", message: "Type '{0}' has no property '{1}'." },
Type_0_is_not_an_array_type: { code: 2461, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_an_array_type_2461", message: "Type '{0}' is not an array type." },
A_rest_element_must_be_last_in_a_destructuring_pattern: { code: 2462, category: ts.DiagnosticCategory.Error, key: "A_rest_element_must_be_last_in_a_destructuring_pattern_2462", message: "A rest element must be last in a destructuring pattern" },
A_binding_pattern_parameter_cannot_be_optional_in_an_implementation_signature: { code: 2463, category: ts.DiagnosticCategory.Error, key: "A_binding_pattern_parameter_cannot_be_optional_in_an_implementation_signature_2463", message: "A binding pattern parameter cannot be optional in an implementation signature." },
A_computed_property_name_must_be_of_type_string_number_symbol_or_any: { code: 2464, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_must_be_of_type_string_number_symbol_or_any_2464", message: "A computed property name must be of type 'string', 'number', 'symbol', or 'any'." },
this_cannot_be_referenced_in_a_computed_property_name: { code: 2465, category: ts.DiagnosticCategory.Error, key: "this_cannot_be_referenced_in_a_computed_property_name_2465", message: "'this' cannot be referenced in a computed property name." },
super_cannot_be_referenced_in_a_computed_property_name: { code: 2466, category: ts.DiagnosticCategory.Error, key: "super_cannot_be_referenced_in_a_computed_property_name_2466", message: "'super' cannot be referenced in a computed property name." },
A_computed_property_name_cannot_reference_a_type_parameter_from_its_containing_type: { code: 2467, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_cannot_reference_a_type_parameter_from_its_containing_type_2467", message: "A computed property name cannot reference a type parameter from its containing type." },
Cannot_find_global_value_0: { code: 2468, category: ts.DiagnosticCategory.Error, key: "Cannot_find_global_value_0_2468", message: "Cannot find global value '{0}'." },
The_0_operator_cannot_be_applied_to_type_symbol: { code: 2469, category: ts.DiagnosticCategory.Error, key: "The_0_operator_cannot_be_applied_to_type_symbol_2469", message: "The '{0}' operator cannot be applied to type 'symbol'." },
Symbol_reference_does_not_refer_to_the_global_Symbol_constructor_object: { code: 2470, category: ts.DiagnosticCategory.Error, key: "Symbol_reference_does_not_refer_to_the_global_Symbol_constructor_object_2470", message: "'Symbol' reference does not refer to the global Symbol constructor object." },
A_computed_property_name_of_the_form_0_must_be_of_type_symbol: { code: 2471, category: ts.DiagnosticCategory.Error, key: "A_computed_property_name_of_the_form_0_must_be_of_type_symbol_2471", message: "A computed property name of the form '{0}' must be of type 'symbol'." },
Spread_operator_in_new_expressions_is_only_available_when_targeting_ECMAScript_5_and_higher: { code: 2472, category: ts.DiagnosticCategory.Error, key: "Spread_operator_in_new_expressions_is_only_available_when_targeting_ECMAScript_5_and_higher_2472", message: "Spread operator in 'new' expressions is only available when targeting ECMAScript 5 and higher." },
Enum_declarations_must_all_be_const_or_non_const: { code: 2473, category: ts.DiagnosticCategory.Error, key: "Enum_declarations_must_all_be_const_or_non_const_2473", message: "Enum declarations must all be const or non-const." },
In_const_enum_declarations_member_initializer_must_be_constant_expression: { code: 2474, category: ts.DiagnosticCategory.Error, key: "In_const_enum_declarations_member_initializer_must_be_constant_expression_2474", message: "In 'const' enum declarations member initializer must be constant expression." },
const_enums_can_only_be_used_in_property_or_index_access_expressions_or_the_right_hand_side_of_an_import_declaration_or_export_assignment: { code: 2475, category: ts.DiagnosticCategory.Error, key: "const_enums_can_only_be_used_in_property_or_index_access_expressions_or_the_right_hand_side_of_an_im_2475", message: "'const' enums can only be used in property or index access expressions or the right hand side of an import declaration or export assignment." },
A_const_enum_member_can_only_be_accessed_using_a_string_literal: { code: 2476, category: ts.DiagnosticCategory.Error, key: "A_const_enum_member_can_only_be_accessed_using_a_string_literal_2476", message: "A const enum member can only be accessed using a string literal." },
const_enum_member_initializer_was_evaluated_to_a_non_finite_value: { code: 2477, category: ts.DiagnosticCategory.Error, key: "const_enum_member_initializer_was_evaluated_to_a_non_finite_value_2477", message: "'const' enum member initializer was evaluated to a non-finite value." },
const_enum_member_initializer_was_evaluated_to_disallowed_value_NaN: { code: 2478, category: ts.DiagnosticCategory.Error, key: "const_enum_member_initializer_was_evaluated_to_disallowed_value_NaN_2478", message: "'const' enum member initializer was evaluated to disallowed value 'NaN'." },
Property_0_does_not_exist_on_const_enum_1: { code: 2479, category: ts.DiagnosticCategory.Error, key: "Property_0_does_not_exist_on_const_enum_1_2479", message: "Property '{0}' does not exist on 'const' enum '{1}'." },
let_is_not_allowed_to_be_used_as_a_name_in_let_or_const_declarations: { code: 2480, category: ts.DiagnosticCategory.Error, key: "let_is_not_allowed_to_be_used_as_a_name_in_let_or_const_declarations_2480", message: "'let' is not allowed to be used as a name in 'let' or 'const' declarations." },
Cannot_initialize_outer_scoped_variable_0_in_the_same_scope_as_block_scoped_declaration_1: { code: 2481, category: ts.DiagnosticCategory.Error, key: "Cannot_initialize_outer_scoped_variable_0_in_the_same_scope_as_block_scoped_declaration_1_2481", message: "Cannot initialize outer scoped variable '{0}' in the same scope as block scoped declaration '{1}'." },
The_left_hand_side_of_a_for_of_statement_cannot_use_a_type_annotation: { code: 2483, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_a_for_of_statement_cannot_use_a_type_annotation_2483", message: "The left-hand side of a 'for...of' statement cannot use a type annotation." },
Export_declaration_conflicts_with_exported_declaration_of_0: { code: 2484, category: ts.DiagnosticCategory.Error, key: "Export_declaration_conflicts_with_exported_declaration_of_0_2484", message: "Export declaration conflicts with exported declaration of '{0}'" },
The_left_hand_side_of_a_for_of_statement_must_be_a_variable_or_a_property_access: { code: 2487, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_a_for_of_statement_must_be_a_variable_or_a_property_access_2487", message: "The left-hand side of a 'for...of' statement must be a variable or a property access." },
Type_must_have_a_Symbol_iterator_method_that_returns_an_iterator: { code: 2488, category: ts.DiagnosticCategory.Error, key: "Type_must_have_a_Symbol_iterator_method_that_returns_an_iterator_2488", message: "Type must have a '[Symbol.iterator]()' method that returns an iterator." },
An_iterator_must_have_a_next_method: { code: 2489, category: ts.DiagnosticCategory.Error, key: "An_iterator_must_have_a_next_method_2489", message: "An iterator must have a 'next()' method." },
The_type_returned_by_the_next_method_of_an_iterator_must_have_a_value_property: { code: 2490, category: ts.DiagnosticCategory.Error, key: "The_type_returned_by_the_next_method_of_an_iterator_must_have_a_value_property_2490", message: "The type returned by the 'next()' method of an iterator must have a 'value' property." },
The_left_hand_side_of_a_for_in_statement_cannot_be_a_destructuring_pattern: { code: 2491, category: ts.DiagnosticCategory.Error, key: "The_left_hand_side_of_a_for_in_statement_cannot_be_a_destructuring_pattern_2491", message: "The left-hand side of a 'for...in' statement cannot be a destructuring pattern." },
Cannot_redeclare_identifier_0_in_catch_clause: { code: 2492, category: ts.DiagnosticCategory.Error, key: "Cannot_redeclare_identifier_0_in_catch_clause_2492", message: "Cannot redeclare identifier '{0}' in catch clause" },
Tuple_type_0_with_length_1_cannot_be_assigned_to_tuple_with_length_2: { code: 2493, category: ts.DiagnosticCategory.Error, key: "Tuple_type_0_with_length_1_cannot_be_assigned_to_tuple_with_length_2_2493", message: "Tuple type '{0}' with length '{1}' cannot be assigned to tuple with length '{2}'." },
Using_a_string_in_a_for_of_statement_is_only_supported_in_ECMAScript_5_and_higher: { code: 2494, category: ts.DiagnosticCategory.Error, key: "Using_a_string_in_a_for_of_statement_is_only_supported_in_ECMAScript_5_and_higher_2494", message: "Using a string in a 'for...of' statement is only supported in ECMAScript 5 and higher." },
Type_0_is_not_an_array_type_or_a_string_type: { code: 2495, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_an_array_type_or_a_string_type_2495", message: "Type '{0}' is not an array type or a string type." },
The_arguments_object_cannot_be_referenced_in_an_arrow_function_in_ES3_and_ES5_Consider_using_a_standard_function_expression: { code: 2496, category: ts.DiagnosticCategory.Error, key: "The_arguments_object_cannot_be_referenced_in_an_arrow_function_in_ES3_and_ES5_Consider_using_a_stand_2496", message: "The 'arguments' object cannot be referenced in an arrow function in ES3 and ES5. Consider using a standard function expression." },
Module_0_resolves_to_a_non_module_entity_and_cannot_be_imported_using_this_construct: { code: 2497, category: ts.DiagnosticCategory.Error, key: "Module_0_resolves_to_a_non_module_entity_and_cannot_be_imported_using_this_construct_2497", message: "Module '{0}' resolves to a non-module entity and cannot be imported using this construct." },
Module_0_uses_export_and_cannot_be_used_with_export_Asterisk: { code: 2498, category: ts.DiagnosticCategory.Error, key: "Module_0_uses_export_and_cannot_be_used_with_export_Asterisk_2498", message: "Module '{0}' uses 'export =' and cannot be used with 'export *'." },
An_interface_can_only_extend_an_identifier_Slashqualified_name_with_optional_type_arguments: { code: 2499, category: ts.DiagnosticCategory.Error, key: "An_interface_can_only_extend_an_identifier_Slashqualified_name_with_optional_type_arguments_2499", message: "An interface can only extend an identifier/qualified-name with optional type arguments." },
A_class_can_only_implement_an_identifier_Slashqualified_name_with_optional_type_arguments: { code: 2500, category: ts.DiagnosticCategory.Error, key: "A_class_can_only_implement_an_identifier_Slashqualified_name_with_optional_type_arguments_2500", message: "A class can only implement an identifier/qualified-name with optional type arguments." },
A_rest_element_cannot_contain_a_binding_pattern: { code: 2501, category: ts.DiagnosticCategory.Error, key: "A_rest_element_cannot_contain_a_binding_pattern_2501", message: "A rest element cannot contain a binding pattern." },
_0_is_referenced_directly_or_indirectly_in_its_own_type_annotation: { code: 2502, category: ts.DiagnosticCategory.Error, key: "_0_is_referenced_directly_or_indirectly_in_its_own_type_annotation_2502", message: "'{0}' is referenced directly or indirectly in its own type annotation." },
Cannot_find_namespace_0: { code: 2503, category: ts.DiagnosticCategory.Error, key: "Cannot_find_namespace_0_2503", message: "Cannot find namespace '{0}'." },
A_generator_cannot_have_a_void_type_annotation: { code: 2505, category: ts.DiagnosticCategory.Error, key: "A_generator_cannot_have_a_void_type_annotation_2505", message: "A generator cannot have a 'void' type annotation." },
_0_is_referenced_directly_or_indirectly_in_its_own_base_expression: { code: 2506, category: ts.DiagnosticCategory.Error, key: "_0_is_referenced_directly_or_indirectly_in_its_own_base_expression_2506", message: "'{0}' is referenced directly or indirectly in its own base expression." },
Type_0_is_not_a_constructor_function_type: { code: 2507, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_a_constructor_function_type_2507", message: "Type '{0}' is not a constructor function type." },
No_base_constructor_has_the_specified_number_of_type_arguments: { code: 2508, category: ts.DiagnosticCategory.Error, key: "No_base_constructor_has_the_specified_number_of_type_arguments_2508", message: "No base constructor has the specified number of type arguments." },
Base_constructor_return_type_0_is_not_a_class_or_interface_type: { code: 2509, category: ts.DiagnosticCategory.Error, key: "Base_constructor_return_type_0_is_not_a_class_or_interface_type_2509", message: "Base constructor return type '{0}' is not a class or interface type." },
Base_constructors_must_all_have_the_same_return_type: { code: 2510, category: ts.DiagnosticCategory.Error, key: "Base_constructors_must_all_have_the_same_return_type_2510", message: "Base constructors must all have the same return type." },
Cannot_create_an_instance_of_the_abstract_class_0: { code: 2511, category: ts.DiagnosticCategory.Error, key: "Cannot_create_an_instance_of_the_abstract_class_0_2511", message: "Cannot create an instance of the abstract class '{0}'." },
Overload_signatures_must_all_be_abstract_or_non_abstract: { code: 2512, category: ts.DiagnosticCategory.Error, key: "Overload_signatures_must_all_be_abstract_or_non_abstract_2512", message: "Overload signatures must all be abstract or non-abstract." },
Abstract_method_0_in_class_1_cannot_be_accessed_via_super_expression: { code: 2513, category: ts.DiagnosticCategory.Error, key: "Abstract_method_0_in_class_1_cannot_be_accessed_via_super_expression_2513", message: "Abstract method '{0}' in class '{1}' cannot be accessed via super expression." },
Classes_containing_abstract_methods_must_be_marked_abstract: { code: 2514, category: ts.DiagnosticCategory.Error, key: "Classes_containing_abstract_methods_must_be_marked_abstract_2514", message: "Classes containing abstract methods must be marked abstract." },
Non_abstract_class_0_does_not_implement_inherited_abstract_member_1_from_class_2: { code: 2515, category: ts.DiagnosticCategory.Error, key: "Non_abstract_class_0_does_not_implement_inherited_abstract_member_1_from_class_2_2515", message: "Non-abstract class '{0}' does not implement inherited abstract member '{1}' from class '{2}'." },
All_declarations_of_an_abstract_method_must_be_consecutive: { code: 2516, category: ts.DiagnosticCategory.Error, key: "All_declarations_of_an_abstract_method_must_be_consecutive_2516", message: "All declarations of an abstract method must be consecutive." },
Cannot_assign_an_abstract_constructor_type_to_a_non_abstract_constructor_type: { code: 2517, category: ts.DiagnosticCategory.Error, key: "Cannot_assign_an_abstract_constructor_type_to_a_non_abstract_constructor_type_2517", message: "Cannot assign an abstract constructor type to a non-abstract constructor type." },
A_this_based_type_guard_is_not_compatible_with_a_parameter_based_type_guard: { code: 2518, category: ts.DiagnosticCategory.Error, key: "A_this_based_type_guard_is_not_compatible_with_a_parameter_based_type_guard_2518", message: "A 'this'-based type guard is not compatible with a parameter-based type guard." },
Duplicate_identifier_0_Compiler_uses_declaration_1_to_support_async_functions: { code: 2520, category: ts.DiagnosticCategory.Error, key: "Duplicate_identifier_0_Compiler_uses_declaration_1_to_support_async_functions_2520", message: "Duplicate identifier '{0}'. Compiler uses declaration '{1}' to support async functions." },
Expression_resolves_to_variable_declaration_0_that_compiler_uses_to_support_async_functions: { code: 2521, category: ts.DiagnosticCategory.Error, key: "Expression_resolves_to_variable_declaration_0_that_compiler_uses_to_support_async_functions_2521", message: "Expression resolves to variable declaration '{0}' that compiler uses to support async functions." },
The_arguments_object_cannot_be_referenced_in_an_async_function_or_method_in_ES3_and_ES5_Consider_using_a_standard_function_or_method: { code: 2522, category: ts.DiagnosticCategory.Error, key: "The_arguments_object_cannot_be_referenced_in_an_async_function_or_method_in_ES3_and_ES5_Consider_usi_2522", message: "The 'arguments' object cannot be referenced in an async function or method in ES3 and ES5. Consider using a standard function or method." },
yield_expressions_cannot_be_used_in_a_parameter_initializer: { code: 2523, category: ts.DiagnosticCategory.Error, key: "yield_expressions_cannot_be_used_in_a_parameter_initializer_2523", message: "'yield' expressions cannot be used in a parameter initializer." },
await_expressions_cannot_be_used_in_a_parameter_initializer: { code: 2524, category: ts.DiagnosticCategory.Error, key: "await_expressions_cannot_be_used_in_a_parameter_initializer_2524", message: "'await' expressions cannot be used in a parameter initializer." },
Initializer_provides_no_value_for_this_binding_element_and_the_binding_element_has_no_default_value: { code: 2525, category: ts.DiagnosticCategory.Error, key: "Initializer_provides_no_value_for_this_binding_element_and_the_binding_element_has_no_default_value_2525", message: "Initializer provides no value for this binding element and the binding element has no default value." },
A_this_type_is_available_only_in_a_non_static_member_of_a_class_or_interface: { code: 2526, category: ts.DiagnosticCategory.Error, key: "A_this_type_is_available_only_in_a_non_static_member_of_a_class_or_interface_2526", message: "A 'this' type is available only in a non-static member of a class or interface." },
The_inferred_type_of_0_references_an_inaccessible_this_type_A_type_annotation_is_necessary: { code: 2527, category: ts.DiagnosticCategory.Error, key: "The_inferred_type_of_0_references_an_inaccessible_this_type_A_type_annotation_is_necessary_2527", message: "The inferred type of '{0}' references an inaccessible 'this' type. A type annotation is necessary." },
A_module_cannot_have_multiple_default_exports: { code: 2528, category: ts.DiagnosticCategory.Error, key: "A_module_cannot_have_multiple_default_exports_2528", message: "A module cannot have multiple default exports." },
Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module_containing_async_functions: { code: 2529, category: ts.DiagnosticCategory.Error, key: "Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module_containing_async_func_2529", message: "Duplicate identifier '{0}'. Compiler reserves name '{1}' in top level scope of a module containing async functions." },
Property_0_is_incompatible_with_index_signature: { code: 2530, category: ts.DiagnosticCategory.Error, key: "Property_0_is_incompatible_with_index_signature_2530", message: "Property '{0}' is incompatible with index signature." },
Object_is_possibly_null: { code: 2531, category: ts.DiagnosticCategory.Error, key: "Object_is_possibly_null_2531", message: "Object is possibly 'null'." },
Object_is_possibly_undefined: { code: 2532, category: ts.DiagnosticCategory.Error, key: "Object_is_possibly_undefined_2532", message: "Object is possibly 'undefined'." },
Object_is_possibly_null_or_undefined: { code: 2533, category: ts.DiagnosticCategory.Error, key: "Object_is_possibly_null_or_undefined_2533", message: "Object is possibly 'null' or 'undefined'." },
A_function_returning_never_cannot_have_a_reachable_end_point: { code: 2534, category: ts.DiagnosticCategory.Error, key: "A_function_returning_never_cannot_have_a_reachable_end_point_2534", message: "A function returning 'never' cannot have a reachable end point." },
Enum_type_0_has_members_with_initializers_that_are_not_literals: { code: 2535, category: ts.DiagnosticCategory.Error, key: "Enum_type_0_has_members_with_initializers_that_are_not_literals_2535", message: "Enum type '{0}' has members with initializers that are not literals." },
Type_0_is_not_constrained_to_keyof_1: { code: 2536, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_constrained_to_keyof_1_2536", message: "Type '{0}' is not constrained to 'keyof {1}'." },
Type_0_has_no_matching_index_signature_for_type_1: { code: 2537, category: ts.DiagnosticCategory.Error, key: "Type_0_has_no_matching_index_signature_for_type_1_2537", message: "Type '{0}' has no matching index signature for type '{1}'." },
Type_0_cannot_be_used_as_an_index_type: { code: 2538, category: ts.DiagnosticCategory.Error, key: "Type_0_cannot_be_used_as_an_index_type_2538", message: "Type '{0}' cannot be used as an index type." },
Cannot_assign_to_0_because_it_is_not_a_variable: { code: 2539, category: ts.DiagnosticCategory.Error, key: "Cannot_assign_to_0_because_it_is_not_a_variable_2539", message: "Cannot assign to '{0}' because it is not a variable." },
Cannot_assign_to_0_because_it_is_a_constant_or_a_read_only_property: { code: 2540, category: ts.DiagnosticCategory.Error, key: "Cannot_assign_to_0_because_it_is_a_constant_or_a_read_only_property_2540", message: "Cannot assign to '{0}' because it is a constant or a read-only property." },
The_target_of_an_assignment_must_be_a_variable_or_a_property_access: { code: 2541, category: ts.DiagnosticCategory.Error, key: "The_target_of_an_assignment_must_be_a_variable_or_a_property_access_2541", message: "The target of an assignment must be a variable or a property access." },
Index_signature_in_type_0_only_permits_reading: { code: 2542, category: ts.DiagnosticCategory.Error, key: "Index_signature_in_type_0_only_permits_reading_2542", message: "Index signature in type '{0}' only permits reading." },
JSX_element_attributes_type_0_may_not_be_a_union_type: { code: 2600, category: ts.DiagnosticCategory.Error, key: "JSX_element_attributes_type_0_may_not_be_a_union_type_2600", message: "JSX element attributes type '{0}' may not be a union type." },
The_return_type_of_a_JSX_element_constructor_must_return_an_object_type: { code: 2601, category: ts.DiagnosticCategory.Error, key: "The_return_type_of_a_JSX_element_constructor_must_return_an_object_type_2601", message: "The return type of a JSX element constructor must return an object type." },
JSX_element_implicitly_has_type_any_because_the_global_type_JSX_Element_does_not_exist: { code: 2602, category: ts.DiagnosticCategory.Error, key: "JSX_element_implicitly_has_type_any_because_the_global_type_JSX_Element_does_not_exist_2602", message: "JSX element implicitly has type 'any' because the global type 'JSX.Element' does not exist." },
Property_0_in_type_1_is_not_assignable_to_type_2: { code: 2603, category: ts.DiagnosticCategory.Error, key: "Property_0_in_type_1_is_not_assignable_to_type_2_2603", message: "Property '{0}' in type '{1}' is not assignable to type '{2}'" },
JSX_element_type_0_does_not_have_any_construct_or_call_signatures: { code: 2604, category: ts.DiagnosticCategory.Error, key: "JSX_element_type_0_does_not_have_any_construct_or_call_signatures_2604", message: "JSX element type '{0}' does not have any construct or call signatures." },
JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements: { code: 2605, category: ts.DiagnosticCategory.Error, key: "JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements_2605", message: "JSX element type '{0}' is not a constructor function for JSX elements." },
Property_0_of_JSX_spread_attribute_is_not_assignable_to_target_property: { code: 2606, category: ts.DiagnosticCategory.Error, key: "Property_0_of_JSX_spread_attribute_is_not_assignable_to_target_property_2606", message: "Property '{0}' of JSX spread attribute is not assignable to target property." },
JSX_element_class_does_not_support_attributes_because_it_does_not_have_a_0_property: { code: 2607, category: ts.DiagnosticCategory.Error, key: "JSX_element_class_does_not_support_attributes_because_it_does_not_have_a_0_property_2607", message: "JSX element class does not support attributes because it does not have a '{0}' property" },
The_global_type_JSX_0_may_not_have_more_than_one_property: { code: 2608, category: ts.DiagnosticCategory.Error, key: "The_global_type_JSX_0_may_not_have_more_than_one_property_2608", message: "The global type 'JSX.{0}' may not have more than one property" },
Cannot_emit_namespaced_JSX_elements_in_React: { code: 2650, category: ts.DiagnosticCategory.Error, key: "Cannot_emit_namespaced_JSX_elements_in_React_2650", message: "Cannot emit namespaced JSX elements in React" },
A_member_initializer_in_a_enum_declaration_cannot_reference_members_declared_after_it_including_members_defined_in_other_enums: { code: 2651, category: ts.DiagnosticCategory.Error, key: "A_member_initializer_in_a_enum_declaration_cannot_reference_members_declared_after_it_including_memb_2651", message: "A member initializer in a enum declaration cannot reference members declared after it, including members defined in other enums." },
Merged_declaration_0_cannot_include_a_default_export_declaration_Consider_adding_a_separate_export_default_0_declaration_instead: { code: 2652, category: ts.DiagnosticCategory.Error, key: "Merged_declaration_0_cannot_include_a_default_export_declaration_Consider_adding_a_separate_export_d_2652", message: "Merged declaration '{0}' cannot include a default export declaration. Consider adding a separate 'export default {0}' declaration instead." },
Non_abstract_class_expression_does_not_implement_inherited_abstract_member_0_from_class_1: { code: 2653, category: ts.DiagnosticCategory.Error, key: "Non_abstract_class_expression_does_not_implement_inherited_abstract_member_0_from_class_1_2653", message: "Non-abstract class expression does not implement inherited abstract member '{0}' from class '{1}'." },
Exported_external_package_typings_file_cannot_contain_tripleslash_references_Please_contact_the_package_author_to_update_the_package_definition: { code: 2654, category: ts.DiagnosticCategory.Error, key: "Exported_external_package_typings_file_cannot_contain_tripleslash_references_Please_contact_the_pack_2654", message: "Exported external package typings file cannot contain tripleslash references. Please contact the package author to update the package definition." },
Exported_external_package_typings_file_0_is_not_a_module_Please_contact_the_package_author_to_update_the_package_definition: { code: 2656, category: ts.DiagnosticCategory.Error, key: "Exported_external_package_typings_file_0_is_not_a_module_Please_contact_the_package_author_to_update_2656", message: "Exported external package typings file '{0}' is not a module. Please contact the package author to update the package definition." },
JSX_expressions_must_have_one_parent_element: { code: 2657, category: ts.DiagnosticCategory.Error, key: "JSX_expressions_must_have_one_parent_element_2657", message: "JSX expressions must have one parent element" },
Type_0_provides_no_match_for_the_signature_1: { code: 2658, category: ts.DiagnosticCategory.Error, key: "Type_0_provides_no_match_for_the_signature_1_2658", message: "Type '{0}' provides no match for the signature '{1}'" },
super_is_only_allowed_in_members_of_object_literal_expressions_when_option_target_is_ES2015_or_higher: { code: 2659, category: ts.DiagnosticCategory.Error, key: "super_is_only_allowed_in_members_of_object_literal_expressions_when_option_target_is_ES2015_or_highe_2659", message: "'super' is only allowed in members of object literal expressions when option 'target' is 'ES2015' or higher." },
super_can_only_be_referenced_in_members_of_derived_classes_or_object_literal_expressions: { code: 2660, category: ts.DiagnosticCategory.Error, key: "super_can_only_be_referenced_in_members_of_derived_classes_or_object_literal_expressions_2660", message: "'super' can only be referenced in members of derived classes or object literal expressions." },
Cannot_export_0_Only_local_declarations_can_be_exported_from_a_module: { code: 2661, category: ts.DiagnosticCategory.Error, key: "Cannot_export_0_Only_local_declarations_can_be_exported_from_a_module_2661", message: "Cannot export '{0}'. Only local declarations can be exported from a module." },
Cannot_find_name_0_Did_you_mean_the_static_member_1_0: { code: 2662, category: ts.DiagnosticCategory.Error, key: "Cannot_find_name_0_Did_you_mean_the_static_member_1_0_2662", message: "Cannot find name '{0}'. Did you mean the static member '{1}.{0}'?" },
Cannot_find_name_0_Did_you_mean_the_instance_member_this_0: { code: 2663, category: ts.DiagnosticCategory.Error, key: "Cannot_find_name_0_Did_you_mean_the_instance_member_this_0_2663", message: "Cannot find name '{0}'. Did you mean the instance member 'this.{0}'?" },
Invalid_module_name_in_augmentation_module_0_cannot_be_found: { code: 2664, category: ts.DiagnosticCategory.Error, key: "Invalid_module_name_in_augmentation_module_0_cannot_be_found_2664", message: "Invalid module name in augmentation, module '{0}' cannot be found." },
Invalid_module_name_in_augmentation_Module_0_resolves_to_an_untyped_module_at_1_which_cannot_be_augmented: { code: 2665, category: ts.DiagnosticCategory.Error, key: "Invalid_module_name_in_augmentation_Module_0_resolves_to_an_untyped_module_at_1_which_cannot_be_augm_2665", message: "Invalid module name in augmentation. Module '{0}' resolves to an untyped module at '{1}', which cannot be augmented." },
Exports_and_export_assignments_are_not_permitted_in_module_augmentations: { code: 2666, category: ts.DiagnosticCategory.Error, key: "Exports_and_export_assignments_are_not_permitted_in_module_augmentations_2666", message: "Exports and export assignments are not permitted in module augmentations." },
Imports_are_not_permitted_in_module_augmentations_Consider_moving_them_to_the_enclosing_external_module: { code: 2667, category: ts.DiagnosticCategory.Error, key: "Imports_are_not_permitted_in_module_augmentations_Consider_moving_them_to_the_enclosing_external_mod_2667", message: "Imports are not permitted in module augmentations. Consider moving them to the enclosing external module." },
export_modifier_cannot_be_applied_to_ambient_modules_and_module_augmentations_since_they_are_always_visible: { code: 2668, category: ts.DiagnosticCategory.Error, key: "export_modifier_cannot_be_applied_to_ambient_modules_and_module_augmentations_since_they_are_always__2668", message: "'export' modifier cannot be applied to ambient modules and module augmentations since they are always visible." },
Augmentations_for_the_global_scope_can_only_be_directly_nested_in_external_modules_or_ambient_module_declarations: { code: 2669, category: ts.DiagnosticCategory.Error, key: "Augmentations_for_the_global_scope_can_only_be_directly_nested_in_external_modules_or_ambient_module_2669", message: "Augmentations for the global scope can only be directly nested in external modules or ambient module declarations." },
Augmentations_for_the_global_scope_should_have_declare_modifier_unless_they_appear_in_already_ambient_context: { code: 2670, category: ts.DiagnosticCategory.Error, key: "Augmentations_for_the_global_scope_should_have_declare_modifier_unless_they_appear_in_already_ambien_2670", message: "Augmentations for the global scope should have 'declare' modifier unless they appear in already ambient context." },
Cannot_augment_module_0_because_it_resolves_to_a_non_module_entity: { code: 2671, category: ts.DiagnosticCategory.Error, key: "Cannot_augment_module_0_because_it_resolves_to_a_non_module_entity_2671", message: "Cannot augment module '{0}' because it resolves to a non-module entity." },
Cannot_assign_a_0_constructor_type_to_a_1_constructor_type: { code: 2672, category: ts.DiagnosticCategory.Error, key: "Cannot_assign_a_0_constructor_type_to_a_1_constructor_type_2672", message: "Cannot assign a '{0}' constructor type to a '{1}' constructor type." },
Constructor_of_class_0_is_private_and_only_accessible_within_the_class_declaration: { code: 2673, category: ts.DiagnosticCategory.Error, key: "Constructor_of_class_0_is_private_and_only_accessible_within_the_class_declaration_2673", message: "Constructor of class '{0}' is private and only accessible within the class declaration." },
Constructor_of_class_0_is_protected_and_only_accessible_within_the_class_declaration: { code: 2674, category: ts.DiagnosticCategory.Error, key: "Constructor_of_class_0_is_protected_and_only_accessible_within_the_class_declaration_2674", message: "Constructor of class '{0}' is protected and only accessible within the class declaration." },
Cannot_extend_a_class_0_Class_constructor_is_marked_as_private: { code: 2675, category: ts.DiagnosticCategory.Error, key: "Cannot_extend_a_class_0_Class_constructor_is_marked_as_private_2675", message: "Cannot extend a class '{0}'. Class constructor is marked as private." },
Accessors_must_both_be_abstract_or_non_abstract: { code: 2676, category: ts.DiagnosticCategory.Error, key: "Accessors_must_both_be_abstract_or_non_abstract_2676", message: "Accessors must both be abstract or non-abstract." },
A_type_predicate_s_type_must_be_assignable_to_its_parameter_s_type: { code: 2677, category: ts.DiagnosticCategory.Error, key: "A_type_predicate_s_type_must_be_assignable_to_its_parameter_s_type_2677", message: "A type predicate's type must be assignable to its parameter's type." },
Type_0_is_not_comparable_to_type_1: { code: 2678, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_comparable_to_type_1_2678", message: "Type '{0}' is not comparable to type '{1}'." },
A_function_that_is_called_with_the_new_keyword_cannot_have_a_this_type_that_is_void: { code: 2679, category: ts.DiagnosticCategory.Error, key: "A_function_that_is_called_with_the_new_keyword_cannot_have_a_this_type_that_is_void_2679", message: "A function that is called with the 'new' keyword cannot have a 'this' type that is 'void'." },
A_this_parameter_must_be_the_first_parameter: { code: 2680, category: ts.DiagnosticCategory.Error, key: "A_this_parameter_must_be_the_first_parameter_2680", message: "A 'this' parameter must be the first parameter." },
A_constructor_cannot_have_a_this_parameter: { code: 2681, category: ts.DiagnosticCategory.Error, key: "A_constructor_cannot_have_a_this_parameter_2681", message: "A constructor cannot have a 'this' parameter." },
get_and_set_accessor_must_have_the_same_this_type: { code: 2682, category: ts.DiagnosticCategory.Error, key: "get_and_set_accessor_must_have_the_same_this_type_2682", message: "'get' and 'set' accessor must have the same 'this' type." },
this_implicitly_has_type_any_because_it_does_not_have_a_type_annotation: { code: 2683, category: ts.DiagnosticCategory.Error, key: "this_implicitly_has_type_any_because_it_does_not_have_a_type_annotation_2683", message: "'this' implicitly has type 'any' because it does not have a type annotation." },
The_this_context_of_type_0_is_not_assignable_to_method_s_this_of_type_1: { code: 2684, category: ts.DiagnosticCategory.Error, key: "The_this_context_of_type_0_is_not_assignable_to_method_s_this_of_type_1_2684", message: "The 'this' context of type '{0}' is not assignable to method's 'this' of type '{1}'." },
The_this_types_of_each_signature_are_incompatible: { code: 2685, category: ts.DiagnosticCategory.Error, key: "The_this_types_of_each_signature_are_incompatible_2685", message: "The 'this' types of each signature are incompatible." },
_0_refers_to_a_UMD_global_but_the_current_file_is_a_module_Consider_adding_an_import_instead: { code: 2686, category: ts.DiagnosticCategory.Error, key: "_0_refers_to_a_UMD_global_but_the_current_file_is_a_module_Consider_adding_an_import_instead_2686", message: "'{0}' refers to a UMD global, but the current file is a module. Consider adding an import instead." },
All_declarations_of_0_must_have_identical_modifiers: { code: 2687, category: ts.DiagnosticCategory.Error, key: "All_declarations_of_0_must_have_identical_modifiers_2687", message: "All declarations of '{0}' must have identical modifiers." },
Cannot_find_type_definition_file_for_0: { code: 2688, category: ts.DiagnosticCategory.Error, key: "Cannot_find_type_definition_file_for_0_2688", message: "Cannot find type definition file for '{0}'." },
Cannot_extend_an_interface_0_Did_you_mean_implements: { code: 2689, category: ts.DiagnosticCategory.Error, key: "Cannot_extend_an_interface_0_Did_you_mean_implements_2689", message: "Cannot extend an interface '{0}'. Did you mean 'implements'?" },
A_class_must_be_declared_after_its_base_class: { code: 2690, category: ts.DiagnosticCategory.Error, key: "A_class_must_be_declared_after_its_base_class_2690", message: "A class must be declared after its base class." },
An_import_path_cannot_end_with_a_0_extension_Consider_importing_1_instead: { code: 2691, category: ts.DiagnosticCategory.Error, key: "An_import_path_cannot_end_with_a_0_extension_Consider_importing_1_instead_2691", message: "An import path cannot end with a '{0}' extension. Consider importing '{1}' instead." },
_0_is_a_primitive_but_1_is_a_wrapper_object_Prefer_using_0_when_possible: { code: 2692, category: ts.DiagnosticCategory.Error, key: "_0_is_a_primitive_but_1_is_a_wrapper_object_Prefer_using_0_when_possible_2692", message: "'{0}' is a primitive, but '{1}' is a wrapper object. Prefer using '{0}' when possible." },
_0_only_refers_to_a_type_but_is_being_used_as_a_value_here: { code: 2693, category: ts.DiagnosticCategory.Error, key: "_0_only_refers_to_a_type_but_is_being_used_as_a_value_here_2693", message: "'{0}' only refers to a type, but is being used as a value here." },
Namespace_0_has_no_exported_member_1: { code: 2694, category: ts.DiagnosticCategory.Error, key: "Namespace_0_has_no_exported_member_1_2694", message: "Namespace '{0}' has no exported member '{1}'." },
Left_side_of_comma_operator_is_unused_and_has_no_side_effects: { code: 2695, category: ts.DiagnosticCategory.Error, key: "Left_side_of_comma_operator_is_unused_and_has_no_side_effects_2695", message: "Left side of comma operator is unused and has no side effects." },
The_Object_type_is_assignable_to_very_few_other_types_Did_you_mean_to_use_the_any_type_instead: { code: 2696, category: ts.DiagnosticCategory.Error, key: "The_Object_type_is_assignable_to_very_few_other_types_Did_you_mean_to_use_the_any_type_instead_2696", message: "The 'Object' type is assignable to very few other types. Did you mean to use the 'any' type instead?" },
An_async_function_or_method_must_return_a_Promise_Make_sure_you_have_a_declaration_for_Promise_or_include_ES2015_in_your_lib_option: { code: 2697, category: ts.DiagnosticCategory.Error, key: "An_async_function_or_method_must_return_a_Promise_Make_sure_you_have_a_declaration_for_Promise_or_in_2697", message: "An async function or method must return a 'Promise'. Make sure you have a declaration for 'Promise' or include 'ES2015' in your `--lib` option." },
Spread_types_may_only_be_created_from_object_types: { code: 2698, category: ts.DiagnosticCategory.Error, key: "Spread_types_may_only_be_created_from_object_types_2698", message: "Spread types may only be created from object types." },
Rest_types_may_only_be_created_from_object_types: { code: 2700, category: ts.DiagnosticCategory.Error, key: "Rest_types_may_only_be_created_from_object_types_2700", message: "Rest types may only be created from object types." },
An_object_rest_element_must_be_an_identifier: { code: 2701, category: ts.DiagnosticCategory.Error, key: "An_object_rest_element_must_be_an_identifier_2701", message: "An object rest element must be an identifier." },
Import_declaration_0_is_using_private_name_1: { code: 4000, category: ts.DiagnosticCategory.Error, key: "Import_declaration_0_is_using_private_name_1_4000", message: "Import declaration '{0}' is using private name '{1}'." },
Type_parameter_0_of_exported_class_has_or_is_using_private_name_1: { code: 4002, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_exported_class_has_or_is_using_private_name_1_4002", message: "Type parameter '{0}' of exported class has or is using private name '{1}'." },
Type_parameter_0_of_exported_interface_has_or_is_using_private_name_1: { code: 4004, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_exported_interface_has_or_is_using_private_name_1_4004", message: "Type parameter '{0}' of exported interface has or is using private name '{1}'." },
Type_parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_1: { code: 4006, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_1_4006", message: "Type parameter '{0}' of constructor signature from exported interface has or is using private name '{1}'." },
Type_parameter_0_of_call_signature_from_exported_interface_has_or_is_using_private_name_1: { code: 4008, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_call_signature_from_exported_interface_has_or_is_using_private_name_1_4008", message: "Type parameter '{0}' of call signature from exported interface has or is using private name '{1}'." },
Type_parameter_0_of_public_static_method_from_exported_class_has_or_is_using_private_name_1: { code: 4010, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_public_static_method_from_exported_class_has_or_is_using_private_name_1_4010", message: "Type parameter '{0}' of public static method from exported class has or is using private name '{1}'." },
Type_parameter_0_of_public_method_from_exported_class_has_or_is_using_private_name_1: { code: 4012, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_public_method_from_exported_class_has_or_is_using_private_name_1_4012", message: "Type parameter '{0}' of public method from exported class has or is using private name '{1}'." },
Type_parameter_0_of_method_from_exported_interface_has_or_is_using_private_name_1: { code: 4014, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_method_from_exported_interface_has_or_is_using_private_name_1_4014", message: "Type parameter '{0}' of method from exported interface has or is using private name '{1}'." },
Type_parameter_0_of_exported_function_has_or_is_using_private_name_1: { code: 4016, category: ts.DiagnosticCategory.Error, key: "Type_parameter_0_of_exported_function_has_or_is_using_private_name_1_4016", message: "Type parameter '{0}' of exported function has or is using private name '{1}'." },
Implements_clause_of_exported_class_0_has_or_is_using_private_name_1: { code: 4019, category: ts.DiagnosticCategory.Error, key: "Implements_clause_of_exported_class_0_has_or_is_using_private_name_1_4019", message: "Implements clause of exported class '{0}' has or is using private name '{1}'." },
Extends_clause_of_exported_class_0_has_or_is_using_private_name_1: { code: 4020, category: ts.DiagnosticCategory.Error, key: "Extends_clause_of_exported_class_0_has_or_is_using_private_name_1_4020", message: "Extends clause of exported class '{0}' has or is using private name '{1}'." },
Extends_clause_of_exported_interface_0_has_or_is_using_private_name_1: { code: 4022, category: ts.DiagnosticCategory.Error, key: "Extends_clause_of_exported_interface_0_has_or_is_using_private_name_1_4022", message: "Extends clause of exported interface '{0}' has or is using private name '{1}'." },
Exported_variable_0_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named: { code: 4023, category: ts.DiagnosticCategory.Error, key: "Exported_variable_0_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named_4023", message: "Exported variable '{0}' has or is using name '{1}' from external module {2} but cannot be named." },
Exported_variable_0_has_or_is_using_name_1_from_private_module_2: { code: 4024, category: ts.DiagnosticCategory.Error, key: "Exported_variable_0_has_or_is_using_name_1_from_private_module_2_4024", message: "Exported variable '{0}' has or is using name '{1}' from private module '{2}'." },
Exported_variable_0_has_or_is_using_private_name_1: { code: 4025, category: ts.DiagnosticCategory.Error, key: "Exported_variable_0_has_or_is_using_private_name_1_4025", message: "Exported variable '{0}' has or is using private name '{1}'." },
Public_static_property_0_of_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named: { code: 4026, category: ts.DiagnosticCategory.Error, key: "Public_static_property_0_of_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot__4026", message: "Public static property '{0}' of exported class has or is using name '{1}' from external module {2} but cannot be named." },
Public_static_property_0_of_exported_class_has_or_is_using_name_1_from_private_module_2: { code: 4027, category: ts.DiagnosticCategory.Error, key: "Public_static_property_0_of_exported_class_has_or_is_using_name_1_from_private_module_2_4027", message: "Public static property '{0}' of exported class has or is using name '{1}' from private module '{2}'." },
Public_static_property_0_of_exported_class_has_or_is_using_private_name_1: { code: 4028, category: ts.DiagnosticCategory.Error, key: "Public_static_property_0_of_exported_class_has_or_is_using_private_name_1_4028", message: "Public static property '{0}' of exported class has or is using private name '{1}'." },
Public_property_0_of_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named: { code: 4029, category: ts.DiagnosticCategory.Error, key: "Public_property_0_of_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_name_4029", message: "Public property '{0}' of exported class has or is using name '{1}' from external module {2} but cannot be named." },
Public_property_0_of_exported_class_has_or_is_using_name_1_from_private_module_2: { code: 4030, category: ts.DiagnosticCategory.Error, key: "Public_property_0_of_exported_class_has_or_is_using_name_1_from_private_module_2_4030", message: "Public property '{0}' of exported class has or is using name '{1}' from private module '{2}'." },
Public_property_0_of_exported_class_has_or_is_using_private_name_1: { code: 4031, category: ts.DiagnosticCategory.Error, key: "Public_property_0_of_exported_class_has_or_is_using_private_name_1_4031", message: "Public property '{0}' of exported class has or is using private name '{1}'." },
Property_0_of_exported_interface_has_or_is_using_name_1_from_private_module_2: { code: 4032, category: ts.DiagnosticCategory.Error, key: "Property_0_of_exported_interface_has_or_is_using_name_1_from_private_module_2_4032", message: "Property '{0}' of exported interface has or is using name '{1}' from private module '{2}'." },
Property_0_of_exported_interface_has_or_is_using_private_name_1: { code: 4033, category: ts.DiagnosticCategory.Error, key: "Property_0_of_exported_interface_has_or_is_using_private_name_1_4033", message: "Property '{0}' of exported interface has or is using private name '{1}'." },
Parameter_0_of_public_static_property_setter_from_exported_class_has_or_is_using_name_1_from_private_module_2: { code: 4034, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_static_property_setter_from_exported_class_has_or_is_using_name_1_from_private_4034", message: "Parameter '{0}' of public static property setter from exported class has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_public_static_property_setter_from_exported_class_has_or_is_using_private_name_1: { code: 4035, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_static_property_setter_from_exported_class_has_or_is_using_private_name_1_4035", message: "Parameter '{0}' of public static property setter from exported class has or is using private name '{1}'." },
Parameter_0_of_public_property_setter_from_exported_class_has_or_is_using_name_1_from_private_module_2: { code: 4036, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_property_setter_from_exported_class_has_or_is_using_name_1_from_private_module_4036", message: "Parameter '{0}' of public property setter from exported class has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_public_property_setter_from_exported_class_has_or_is_using_private_name_1: { code: 4037, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_property_setter_from_exported_class_has_or_is_using_private_name_1_4037", message: "Parameter '{0}' of public property setter from exported class has or is using private name '{1}'." },
Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named: { code: 4038, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_name_0_from_externa_4038", message: "Return type of public static property getter from exported class has or is using name '{0}' from external module {1} but cannot be named." },
Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_name_0_from_private_module_1: { code: 4039, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_name_0_from_private_4039", message: "Return type of public static property getter from exported class has or is using name '{0}' from private module '{1}'." },
Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_private_name_0: { code: 4040, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_private_name_0_4040", message: "Return type of public static property getter from exported class has or is using private name '{0}'." },
Return_type_of_public_property_getter_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named: { code: 4041, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_property_getter_from_exported_class_has_or_is_using_name_0_from_external_modul_4041", message: "Return type of public property getter from exported class has or is using name '{0}' from external module {1} but cannot be named." },
Return_type_of_public_property_getter_from_exported_class_has_or_is_using_name_0_from_private_module_1: { code: 4042, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_property_getter_from_exported_class_has_or_is_using_name_0_from_private_module_4042", message: "Return type of public property getter from exported class has or is using name '{0}' from private module '{1}'." },
Return_type_of_public_property_getter_from_exported_class_has_or_is_using_private_name_0: { code: 4043, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_property_getter_from_exported_class_has_or_is_using_private_name_0_4043", message: "Return type of public property getter from exported class has or is using private name '{0}'." },
Return_type_of_constructor_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1: { code: 4044, category: ts.DiagnosticCategory.Error, key: "Return_type_of_constructor_signature_from_exported_interface_has_or_is_using_name_0_from_private_mod_4044", message: "Return type of constructor signature from exported interface has or is using name '{0}' from private module '{1}'." },
Return_type_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_0: { code: 4045, category: ts.DiagnosticCategory.Error, key: "Return_type_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_0_4045", message: "Return type of constructor signature from exported interface has or is using private name '{0}'." },
Return_type_of_call_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1: { code: 4046, category: ts.DiagnosticCategory.Error, key: "Return_type_of_call_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1_4046", message: "Return type of call signature from exported interface has or is using name '{0}' from private module '{1}'." },
Return_type_of_call_signature_from_exported_interface_has_or_is_using_private_name_0: { code: 4047, category: ts.DiagnosticCategory.Error, key: "Return_type_of_call_signature_from_exported_interface_has_or_is_using_private_name_0_4047", message: "Return type of call signature from exported interface has or is using private name '{0}'." },
Return_type_of_index_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1: { code: 4048, category: ts.DiagnosticCategory.Error, key: "Return_type_of_index_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1_4048", message: "Return type of index signature from exported interface has or is using name '{0}' from private module '{1}'." },
Return_type_of_index_signature_from_exported_interface_has_or_is_using_private_name_0: { code: 4049, category: ts.DiagnosticCategory.Error, key: "Return_type_of_index_signature_from_exported_interface_has_or_is_using_private_name_0_4049", message: "Return type of index signature from exported interface has or is using private name '{0}'." },
Return_type_of_public_static_method_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named: { code: 4050, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_static_method_from_exported_class_has_or_is_using_name_0_from_external_module__4050", message: "Return type of public static method from exported class has or is using name '{0}' from external module {1} but cannot be named." },
Return_type_of_public_static_method_from_exported_class_has_or_is_using_name_0_from_private_module_1: { code: 4051, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_static_method_from_exported_class_has_or_is_using_name_0_from_private_module_1_4051", message: "Return type of public static method from exported class has or is using name '{0}' from private module '{1}'." },
Return_type_of_public_static_method_from_exported_class_has_or_is_using_private_name_0: { code: 4052, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_static_method_from_exported_class_has_or_is_using_private_name_0_4052", message: "Return type of public static method from exported class has or is using private name '{0}'." },
Return_type_of_public_method_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named: { code: 4053, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_method_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_c_4053", message: "Return type of public method from exported class has or is using name '{0}' from external module {1} but cannot be named." },
Return_type_of_public_method_from_exported_class_has_or_is_using_name_0_from_private_module_1: { code: 4054, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_method_from_exported_class_has_or_is_using_name_0_from_private_module_1_4054", message: "Return type of public method from exported class has or is using name '{0}' from private module '{1}'." },
Return_type_of_public_method_from_exported_class_has_or_is_using_private_name_0: { code: 4055, category: ts.DiagnosticCategory.Error, key: "Return_type_of_public_method_from_exported_class_has_or_is_using_private_name_0_4055", message: "Return type of public method from exported class has or is using private name '{0}'." },
Return_type_of_method_from_exported_interface_has_or_is_using_name_0_from_private_module_1: { code: 4056, category: ts.DiagnosticCategory.Error, key: "Return_type_of_method_from_exported_interface_has_or_is_using_name_0_from_private_module_1_4056", message: "Return type of method from exported interface has or is using name '{0}' from private module '{1}'." },
Return_type_of_method_from_exported_interface_has_or_is_using_private_name_0: { code: 4057, category: ts.DiagnosticCategory.Error, key: "Return_type_of_method_from_exported_interface_has_or_is_using_private_name_0_4057", message: "Return type of method from exported interface has or is using private name '{0}'." },
Return_type_of_exported_function_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named: { code: 4058, category: ts.DiagnosticCategory.Error, key: "Return_type_of_exported_function_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named_4058", message: "Return type of exported function has or is using name '{0}' from external module {1} but cannot be named." },
Return_type_of_exported_function_has_or_is_using_name_0_from_private_module_1: { code: 4059, category: ts.DiagnosticCategory.Error, key: "Return_type_of_exported_function_has_or_is_using_name_0_from_private_module_1_4059", message: "Return type of exported function has or is using name '{0}' from private module '{1}'." },
Return_type_of_exported_function_has_or_is_using_private_name_0: { code: 4060, category: ts.DiagnosticCategory.Error, key: "Return_type_of_exported_function_has_or_is_using_private_name_0_4060", message: "Return type of exported function has or is using private name '{0}'." },
Parameter_0_of_constructor_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named: { code: 4061, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_constructor_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_can_4061", message: "Parameter '{0}' of constructor from exported class has or is using name '{1}' from external module {2} but cannot be named." },
Parameter_0_of_constructor_from_exported_class_has_or_is_using_name_1_from_private_module_2: { code: 4062, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_constructor_from_exported_class_has_or_is_using_name_1_from_private_module_2_4062", message: "Parameter '{0}' of constructor from exported class has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_constructor_from_exported_class_has_or_is_using_private_name_1: { code: 4063, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_constructor_from_exported_class_has_or_is_using_private_name_1_4063", message: "Parameter '{0}' of constructor from exported class has or is using private name '{1}'." },
Parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_name_1_from_private_module_2: { code: 4064, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_name_1_from_private_mod_4064", message: "Parameter '{0}' of constructor signature from exported interface has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_1: { code: 4065, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_1_4065", message: "Parameter '{0}' of constructor signature from exported interface has or is using private name '{1}'." },
Parameter_0_of_call_signature_from_exported_interface_has_or_is_using_name_1_from_private_module_2: { code: 4066, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_call_signature_from_exported_interface_has_or_is_using_name_1_from_private_module_2_4066", message: "Parameter '{0}' of call signature from exported interface has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_call_signature_from_exported_interface_has_or_is_using_private_name_1: { code: 4067, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_call_signature_from_exported_interface_has_or_is_using_private_name_1_4067", message: "Parameter '{0}' of call signature from exported interface has or is using private name '{1}'." },
Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named: { code: 4068, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_name_1_from_external_module__4068", message: "Parameter '{0}' of public static method from exported class has or is using name '{1}' from external module {2} but cannot be named." },
Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_name_1_from_private_module_2: { code: 4069, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_name_1_from_private_module_2_4069", message: "Parameter '{0}' of public static method from exported class has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_private_name_1: { code: 4070, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_private_name_1_4070", message: "Parameter '{0}' of public static method from exported class has or is using private name '{1}'." },
Parameter_0_of_public_method_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named: { code: 4071, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_method_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_c_4071", message: "Parameter '{0}' of public method from exported class has or is using name '{1}' from external module {2} but cannot be named." },
Parameter_0_of_public_method_from_exported_class_has_or_is_using_name_1_from_private_module_2: { code: 4072, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_method_from_exported_class_has_or_is_using_name_1_from_private_module_2_4072", message: "Parameter '{0}' of public method from exported class has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_public_method_from_exported_class_has_or_is_using_private_name_1: { code: 4073, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_public_method_from_exported_class_has_or_is_using_private_name_1_4073", message: "Parameter '{0}' of public method from exported class has or is using private name '{1}'." },
Parameter_0_of_method_from_exported_interface_has_or_is_using_name_1_from_private_module_2: { code: 4074, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_method_from_exported_interface_has_or_is_using_name_1_from_private_module_2_4074", message: "Parameter '{0}' of method from exported interface has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_method_from_exported_interface_has_or_is_using_private_name_1: { code: 4075, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_method_from_exported_interface_has_or_is_using_private_name_1_4075", message: "Parameter '{0}' of method from exported interface has or is using private name '{1}'." },
Parameter_0_of_exported_function_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named: { code: 4076, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_exported_function_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named_4076", message: "Parameter '{0}' of exported function has or is using name '{1}' from external module {2} but cannot be named." },
Parameter_0_of_exported_function_has_or_is_using_name_1_from_private_module_2: { code: 4077, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_exported_function_has_or_is_using_name_1_from_private_module_2_4077", message: "Parameter '{0}' of exported function has or is using name '{1}' from private module '{2}'." },
Parameter_0_of_exported_function_has_or_is_using_private_name_1: { code: 4078, category: ts.DiagnosticCategory.Error, key: "Parameter_0_of_exported_function_has_or_is_using_private_name_1_4078", message: "Parameter '{0}' of exported function has or is using private name '{1}'." },
Exported_type_alias_0_has_or_is_using_private_name_1: { code: 4081, category: ts.DiagnosticCategory.Error, key: "Exported_type_alias_0_has_or_is_using_private_name_1_4081", message: "Exported type alias '{0}' has or is using private name '{1}'." },
Default_export_of_the_module_has_or_is_using_private_name_0: { code: 4082, category: ts.DiagnosticCategory.Error, key: "Default_export_of_the_module_has_or_is_using_private_name_0_4082", message: "Default export of the module has or is using private name '{0}'." },
Conflicting_definitions_for_0_found_at_1_and_2_Consider_installing_a_specific_version_of_this_library_to_resolve_the_conflict: { code: 4090, category: ts.DiagnosticCategory.Message, key: "Conflicting_definitions_for_0_found_at_1_and_2_Consider_installing_a_specific_version_of_this_librar_4090", message: "Conflicting definitions for '{0}' found at '{1}' and '{2}'. Consider installing a specific version of this library to resolve the conflict." },
The_current_host_does_not_support_the_0_option: { code: 5001, category: ts.DiagnosticCategory.Error, key: "The_current_host_does_not_support_the_0_option_5001", message: "The current host does not support the '{0}' option." },
Cannot_find_the_common_subdirectory_path_for_the_input_files: { code: 5009, category: ts.DiagnosticCategory.Error, key: "Cannot_find_the_common_subdirectory_path_for_the_input_files_5009", message: "Cannot find the common subdirectory path for the input files." },
File_specification_cannot_end_in_a_recursive_directory_wildcard_Asterisk_Asterisk_Colon_0: { code: 5010, category: ts.DiagnosticCategory.Error, key: "File_specification_cannot_end_in_a_recursive_directory_wildcard_Asterisk_Asterisk_Colon_0_5010", message: "File specification cannot end in a recursive directory wildcard ('**'): '{0}'." },
File_specification_cannot_contain_multiple_recursive_directory_wildcards_Asterisk_Asterisk_Colon_0: { code: 5011, category: ts.DiagnosticCategory.Error, key: "File_specification_cannot_contain_multiple_recursive_directory_wildcards_Asterisk_Asterisk_Colon_0_5011", message: "File specification cannot contain multiple recursive directory wildcards ('**'): '{0}'." },
Cannot_read_file_0_Colon_1: { code: 5012, category: ts.DiagnosticCategory.Error, key: "Cannot_read_file_0_Colon_1_5012", message: "Cannot read file '{0}': {1}" },
Unsupported_file_encoding: { code: 5013, category: ts.DiagnosticCategory.Error, key: "Unsupported_file_encoding_5013", message: "Unsupported file encoding." },
Failed_to_parse_file_0_Colon_1: { code: 5014, category: ts.DiagnosticCategory.Error, key: "Failed_to_parse_file_0_Colon_1_5014", message: "Failed to parse file '{0}': {1}." },
Unknown_compiler_option_0: { code: 5023, category: ts.DiagnosticCategory.Error, key: "Unknown_compiler_option_0_5023", message: "Unknown compiler option '{0}'." },
Compiler_option_0_requires_a_value_of_type_1: { code: 5024, category: ts.DiagnosticCategory.Error, key: "Compiler_option_0_requires_a_value_of_type_1_5024", message: "Compiler option '{0}' requires a value of type {1}." },
Could_not_write_file_0_Colon_1: { code: 5033, category: ts.DiagnosticCategory.Error, key: "Could_not_write_file_0_Colon_1_5033", message: "Could not write file '{0}': {1}" },
Option_project_cannot_be_mixed_with_source_files_on_a_command_line: { code: 5042, category: ts.DiagnosticCategory.Error, key: "Option_project_cannot_be_mixed_with_source_files_on_a_command_line_5042", message: "Option 'project' cannot be mixed with source files on a command line." },
Option_isolatedModules_can_only_be_used_when_either_option_module_is_provided_or_option_target_is_ES2015_or_higher: { code: 5047, category: ts.DiagnosticCategory.Error, key: "Option_isolatedModules_can_only_be_used_when_either_option_module_is_provided_or_option_target_is_ES_5047", message: "Option 'isolatedModules' can only be used when either option '--module' is provided or option 'target' is 'ES2015' or higher." },
Option_0_can_only_be_used_when_either_option_inlineSourceMap_or_option_sourceMap_is_provided: { code: 5051, category: ts.DiagnosticCategory.Error, key: "Option_0_can_only_be_used_when_either_option_inlineSourceMap_or_option_sourceMap_is_provided_5051", message: "Option '{0} can only be used when either option '--inlineSourceMap' or option '--sourceMap' is provided." },
Option_0_cannot_be_specified_without_specifying_option_1: { code: 5052, category: ts.DiagnosticCategory.Error, key: "Option_0_cannot_be_specified_without_specifying_option_1_5052", message: "Option '{0}' cannot be specified without specifying option '{1}'." },
Option_0_cannot_be_specified_with_option_1: { code: 5053, category: ts.DiagnosticCategory.Error, key: "Option_0_cannot_be_specified_with_option_1_5053", message: "Option '{0}' cannot be specified with option '{1}'." },
A_tsconfig_json_file_is_already_defined_at_Colon_0: { code: 5054, category: ts.DiagnosticCategory.Error, key: "A_tsconfig_json_file_is_already_defined_at_Colon_0_5054", message: "A 'tsconfig.json' file is already defined at: '{0}'." },
Cannot_write_file_0_because_it_would_overwrite_input_file: { code: 5055, category: ts.DiagnosticCategory.Error, key: "Cannot_write_file_0_because_it_would_overwrite_input_file_5055", message: "Cannot write file '{0}' because it would overwrite input file." },
Cannot_write_file_0_because_it_would_be_overwritten_by_multiple_input_files: { code: 5056, category: ts.DiagnosticCategory.Error, key: "Cannot_write_file_0_because_it_would_be_overwritten_by_multiple_input_files_5056", message: "Cannot write file '{0}' because it would be overwritten by multiple input files." },
Cannot_find_a_tsconfig_json_file_at_the_specified_directory_Colon_0: { code: 5057, category: ts.DiagnosticCategory.Error, key: "Cannot_find_a_tsconfig_json_file_at_the_specified_directory_Colon_0_5057", message: "Cannot find a tsconfig.json file at the specified directory: '{0}'" },
The_specified_path_does_not_exist_Colon_0: { code: 5058, category: ts.DiagnosticCategory.Error, key: "The_specified_path_does_not_exist_Colon_0_5058", message: "The specified path does not exist: '{0}'" },
Invalid_value_for_reactNamespace_0_is_not_a_valid_identifier: { code: 5059, category: ts.DiagnosticCategory.Error, key: "Invalid_value_for_reactNamespace_0_is_not_a_valid_identifier_5059", message: "Invalid value for '--reactNamespace'. '{0}' is not a valid identifier." },
Option_paths_cannot_be_used_without_specifying_baseUrl_option: { code: 5060, category: ts.DiagnosticCategory.Error, key: "Option_paths_cannot_be_used_without_specifying_baseUrl_option_5060", message: "Option 'paths' cannot be used without specifying '--baseUrl' option." },
Pattern_0_can_have_at_most_one_Asterisk_character: { code: 5061, category: ts.DiagnosticCategory.Error, key: "Pattern_0_can_have_at_most_one_Asterisk_character_5061", message: "Pattern '{0}' can have at most one '*' character" },
Substitution_0_in_pattern_1_in_can_have_at_most_one_Asterisk_character: { code: 5062, category: ts.DiagnosticCategory.Error, key: "Substitution_0_in_pattern_1_in_can_have_at_most_one_Asterisk_character_5062", message: "Substitution '{0}' in pattern '{1}' in can have at most one '*' character" },
Substitutions_for_pattern_0_should_be_an_array: { code: 5063, category: ts.DiagnosticCategory.Error, key: "Substitutions_for_pattern_0_should_be_an_array_5063", message: "Substitutions for pattern '{0}' should be an array." },
Substitution_0_for_pattern_1_has_incorrect_type_expected_string_got_2: { code: 5064, category: ts.DiagnosticCategory.Error, key: "Substitution_0_for_pattern_1_has_incorrect_type_expected_string_got_2_5064", message: "Substitution '{0}' for pattern '{1}' has incorrect type, expected 'string', got '{2}'." },
File_specification_cannot_contain_a_parent_directory_that_appears_after_a_recursive_directory_wildcard_Asterisk_Asterisk_Colon_0: { code: 5065, category: ts.DiagnosticCategory.Error, key: "File_specification_cannot_contain_a_parent_directory_that_appears_after_a_recursive_directory_wildca_5065", message: "File specification cannot contain a parent directory ('..') that appears after a recursive directory wildcard ('**'): '{0}'." },
Substitutions_for_pattern_0_shouldn_t_be_an_empty_array: { code: 5066, category: ts.DiagnosticCategory.Error, key: "Substitutions_for_pattern_0_shouldn_t_be_an_empty_array_5066", message: "Substitutions for pattern '{0}' shouldn't be an empty array." },
Invalid_value_for_jsxFactory_0_is_not_a_valid_identifier_or_qualified_name: { code: 5067, category: ts.DiagnosticCategory.Error, key: "Invalid_value_for_jsxFactory_0_is_not_a_valid_identifier_or_qualified_name_5067", message: "Invalid value for 'jsxFactory'. '{0}' is not a valid identifier or qualified-name." },
Concatenate_and_emit_output_to_single_file: { code: 6001, category: ts.DiagnosticCategory.Message, key: "Concatenate_and_emit_output_to_single_file_6001", message: "Concatenate and emit output to single file." },
Generates_corresponding_d_ts_file: { code: 6002, category: ts.DiagnosticCategory.Message, key: "Generates_corresponding_d_ts_file_6002", message: "Generates corresponding '.d.ts' file." },
Specify_the_location_where_debugger_should_locate_map_files_instead_of_generated_locations: { code: 6003, category: ts.DiagnosticCategory.Message, key: "Specify_the_location_where_debugger_should_locate_map_files_instead_of_generated_locations_6003", message: "Specify the location where debugger should locate map files instead of generated locations." },
Specify_the_location_where_debugger_should_locate_TypeScript_files_instead_of_source_locations: { code: 6004, category: ts.DiagnosticCategory.Message, key: "Specify_the_location_where_debugger_should_locate_TypeScript_files_instead_of_source_locations_6004", message: "Specify the location where debugger should locate TypeScript files instead of source locations." },
Watch_input_files: { code: 6005, category: ts.DiagnosticCategory.Message, key: "Watch_input_files_6005", message: "Watch input files." },
Redirect_output_structure_to_the_directory: { code: 6006, category: ts.DiagnosticCategory.Message, key: "Redirect_output_structure_to_the_directory_6006", message: "Redirect output structure to the directory." },
Do_not_erase_const_enum_declarations_in_generated_code: { code: 6007, category: ts.DiagnosticCategory.Message, key: "Do_not_erase_const_enum_declarations_in_generated_code_6007", message: "Do not erase const enum declarations in generated code." },
Do_not_emit_outputs_if_any_errors_were_reported: { code: 6008, category: ts.DiagnosticCategory.Message, key: "Do_not_emit_outputs_if_any_errors_were_reported_6008", message: "Do not emit outputs if any errors were reported." },
Do_not_emit_comments_to_output: { code: 6009, category: ts.DiagnosticCategory.Message, key: "Do_not_emit_comments_to_output_6009", message: "Do not emit comments to output." },
Do_not_emit_outputs: { code: 6010, category: ts.DiagnosticCategory.Message, key: "Do_not_emit_outputs_6010", message: "Do not emit outputs." },
Allow_default_imports_from_modules_with_no_default_export_This_does_not_affect_code_emit_just_typechecking: { code: 6011, category: ts.DiagnosticCategory.Message, key: "Allow_default_imports_from_modules_with_no_default_export_This_does_not_affect_code_emit_just_typech_6011", message: "Allow default imports from modules with no default export. This does not affect code emit, just typechecking." },
Skip_type_checking_of_declaration_files: { code: 6012, category: ts.DiagnosticCategory.Message, key: "Skip_type_checking_of_declaration_files_6012", message: "Skip type checking of declaration files." },
Specify_ECMAScript_target_version_Colon_ES3_default_ES5_or_ES2015: { code: 6015, category: ts.DiagnosticCategory.Message, key: "Specify_ECMAScript_target_version_Colon_ES3_default_ES5_or_ES2015_6015", message: "Specify ECMAScript target version: 'ES3' (default), 'ES5', or 'ES2015'" },
Specify_module_code_generation_Colon_commonjs_amd_system_umd_or_es2015: { code: 6016, category: ts.DiagnosticCategory.Message, key: "Specify_module_code_generation_Colon_commonjs_amd_system_umd_or_es2015_6016", message: "Specify module code generation: 'commonjs', 'amd', 'system', 'umd' or 'es2015'" },
Print_this_message: { code: 6017, category: ts.DiagnosticCategory.Message, key: "Print_this_message_6017", message: "Print this message." },
Print_the_compiler_s_version: { code: 6019, category: ts.DiagnosticCategory.Message, key: "Print_the_compiler_s_version_6019", message: "Print the compiler's version." },
Compile_the_project_in_the_given_directory: { code: 6020, category: ts.DiagnosticCategory.Message, key: "Compile_the_project_in_the_given_directory_6020", message: "Compile the project in the given directory." },
Syntax_Colon_0: { code: 6023, category: ts.DiagnosticCategory.Message, key: "Syntax_Colon_0_6023", message: "Syntax: {0}" },
options: { code: 6024, category: ts.DiagnosticCategory.Message, key: "options_6024", message: "options" },
file: { code: 6025, category: ts.DiagnosticCategory.Message, key: "file_6025", message: "file" },
Examples_Colon_0: { code: 6026, category: ts.DiagnosticCategory.Message, key: "Examples_Colon_0_6026", message: "Examples: {0}" },
Options_Colon: { code: 6027, category: ts.DiagnosticCategory.Message, key: "Options_Colon_6027", message: "Options:" },
Version_0: { code: 6029, category: ts.DiagnosticCategory.Message, key: "Version_0_6029", message: "Version {0}" },
Insert_command_line_options_and_files_from_a_file: { code: 6030, category: ts.DiagnosticCategory.Message, key: "Insert_command_line_options_and_files_from_a_file_6030", message: "Insert command line options and files from a file." },
File_change_detected_Starting_incremental_compilation: { code: 6032, category: ts.DiagnosticCategory.Message, key: "File_change_detected_Starting_incremental_compilation_6032", message: "File change detected. Starting incremental compilation..." },
KIND: { code: 6034, category: ts.DiagnosticCategory.Message, key: "KIND_6034", message: "KIND" },
FILE: { code: 6035, category: ts.DiagnosticCategory.Message, key: "FILE_6035", message: "FILE" },
VERSION: { code: 6036, category: ts.DiagnosticCategory.Message, key: "VERSION_6036", message: "VERSION" },
LOCATION: { code: 6037, category: ts.DiagnosticCategory.Message, key: "LOCATION_6037", message: "LOCATION" },
DIRECTORY: { code: 6038, category: ts.DiagnosticCategory.Message, key: "DIRECTORY_6038", message: "DIRECTORY" },
STRATEGY: { code: 6039, category: ts.DiagnosticCategory.Message, key: "STRATEGY_6039", message: "STRATEGY" },
Compilation_complete_Watching_for_file_changes: { code: 6042, category: ts.DiagnosticCategory.Message, key: "Compilation_complete_Watching_for_file_changes_6042", message: "Compilation complete. Watching for file changes." },
Generates_corresponding_map_file: { code: 6043, category: ts.DiagnosticCategory.Message, key: "Generates_corresponding_map_file_6043", message: "Generates corresponding '.map' file." },
Compiler_option_0_expects_an_argument: { code: 6044, category: ts.DiagnosticCategory.Error, key: "Compiler_option_0_expects_an_argument_6044", message: "Compiler option '{0}' expects an argument." },
Unterminated_quoted_string_in_response_file_0: { code: 6045, category: ts.DiagnosticCategory.Error, key: "Unterminated_quoted_string_in_response_file_0_6045", message: "Unterminated quoted string in response file '{0}'." },
Argument_for_0_option_must_be_Colon_1: { code: 6046, category: ts.DiagnosticCategory.Error, key: "Argument_for_0_option_must_be_Colon_1_6046", message: "Argument for '{0}' option must be: {1}" },
Locale_must_be_of_the_form_language_or_language_territory_For_example_0_or_1: { code: 6048, category: ts.DiagnosticCategory.Error, key: "Locale_must_be_of_the_form_language_or_language_territory_For_example_0_or_1_6048", message: "Locale must be of the form <language> or <language>-<territory>. For example '{0}' or '{1}'." },
Unsupported_locale_0: { code: 6049, category: ts.DiagnosticCategory.Error, key: "Unsupported_locale_0_6049", message: "Unsupported locale '{0}'." },
Unable_to_open_file_0: { code: 6050, category: ts.DiagnosticCategory.Error, key: "Unable_to_open_file_0_6050", message: "Unable to open file '{0}'." },
Corrupted_locale_file_0: { code: 6051, category: ts.DiagnosticCategory.Error, key: "Corrupted_locale_file_0_6051", message: "Corrupted locale file {0}." },
Raise_error_on_expressions_and_declarations_with_an_implied_any_type: { code: 6052, category: ts.DiagnosticCategory.Message, key: "Raise_error_on_expressions_and_declarations_with_an_implied_any_type_6052", message: "Raise error on expressions and declarations with an implied 'any' type." },
File_0_not_found: { code: 6053, category: ts.DiagnosticCategory.Error, key: "File_0_not_found_6053", message: "File '{0}' not found." },
File_0_has_unsupported_extension_The_only_supported_extensions_are_1: { code: 6054, category: ts.DiagnosticCategory.Error, key: "File_0_has_unsupported_extension_The_only_supported_extensions_are_1_6054", message: "File '{0}' has unsupported extension. The only supported extensions are {1}." },
Suppress_noImplicitAny_errors_for_indexing_objects_lacking_index_signatures: { code: 6055, category: ts.DiagnosticCategory.Message, key: "Suppress_noImplicitAny_errors_for_indexing_objects_lacking_index_signatures_6055", message: "Suppress noImplicitAny errors for indexing objects lacking index signatures." },
Do_not_emit_declarations_for_code_that_has_an_internal_annotation: { code: 6056, category: ts.DiagnosticCategory.Message, key: "Do_not_emit_declarations_for_code_that_has_an_internal_annotation_6056", message: "Do not emit declarations for code that has an '@internal' annotation." },
Specify_the_root_directory_of_input_files_Use_to_control_the_output_directory_structure_with_outDir: { code: 6058, category: ts.DiagnosticCategory.Message, key: "Specify_the_root_directory_of_input_files_Use_to_control_the_output_directory_structure_with_outDir_6058", message: "Specify the root directory of input files. Use to control the output directory structure with --outDir." },
File_0_is_not_under_rootDir_1_rootDir_is_expected_to_contain_all_source_files: { code: 6059, category: ts.DiagnosticCategory.Error, key: "File_0_is_not_under_rootDir_1_rootDir_is_expected_to_contain_all_source_files_6059", message: "File '{0}' is not under 'rootDir' '{1}'. 'rootDir' is expected to contain all source files." },
Specify_the_end_of_line_sequence_to_be_used_when_emitting_files_Colon_CRLF_dos_or_LF_unix: { code: 6060, category: ts.DiagnosticCategory.Message, key: "Specify_the_end_of_line_sequence_to_be_used_when_emitting_files_Colon_CRLF_dos_or_LF_unix_6060", message: "Specify the end of line sequence to be used when emitting files: 'CRLF' (dos) or 'LF' (unix)." },
NEWLINE: { code: 6061, category: ts.DiagnosticCategory.Message, key: "NEWLINE_6061", message: "NEWLINE" },
Option_0_can_only_be_specified_in_tsconfig_json_file: { code: 6064, category: ts.DiagnosticCategory.Error, key: "Option_0_can_only_be_specified_in_tsconfig_json_file_6064", message: "Option '{0}' can only be specified in 'tsconfig.json' file." },
Enables_experimental_support_for_ES7_decorators: { code: 6065, category: ts.DiagnosticCategory.Message, key: "Enables_experimental_support_for_ES7_decorators_6065", message: "Enables experimental support for ES7 decorators." },
Enables_experimental_support_for_emitting_type_metadata_for_decorators: { code: 6066, category: ts.DiagnosticCategory.Message, key: "Enables_experimental_support_for_emitting_type_metadata_for_decorators_6066", message: "Enables experimental support for emitting type metadata for decorators." },
Enables_experimental_support_for_ES7_async_functions: { code: 6068, category: ts.DiagnosticCategory.Message, key: "Enables_experimental_support_for_ES7_async_functions_6068", message: "Enables experimental support for ES7 async functions." },
Specify_module_resolution_strategy_Colon_node_Node_js_or_classic_TypeScript_pre_1_6: { code: 6069, category: ts.DiagnosticCategory.Message, key: "Specify_module_resolution_strategy_Colon_node_Node_js_or_classic_TypeScript_pre_1_6_6069", message: "Specify module resolution strategy: 'node' (Node.js) or 'classic' (TypeScript pre-1.6)." },
Initializes_a_TypeScript_project_and_creates_a_tsconfig_json_file: { code: 6070, category: ts.DiagnosticCategory.Message, key: "Initializes_a_TypeScript_project_and_creates_a_tsconfig_json_file_6070", message: "Initializes a TypeScript project and creates a tsconfig.json file." },
Successfully_created_a_tsconfig_json_file: { code: 6071, category: ts.DiagnosticCategory.Message, key: "Successfully_created_a_tsconfig_json_file_6071", message: "Successfully created a tsconfig.json file." },
Suppress_excess_property_checks_for_object_literals: { code: 6072, category: ts.DiagnosticCategory.Message, key: "Suppress_excess_property_checks_for_object_literals_6072", message: "Suppress excess property checks for object literals." },
Stylize_errors_and_messages_using_color_and_context_experimental: { code: 6073, category: ts.DiagnosticCategory.Message, key: "Stylize_errors_and_messages_using_color_and_context_experimental_6073", message: "Stylize errors and messages using color and context. (experimental)" },
Do_not_report_errors_on_unused_labels: { code: 6074, category: ts.DiagnosticCategory.Message, key: "Do_not_report_errors_on_unused_labels_6074", message: "Do not report errors on unused labels." },
Report_error_when_not_all_code_paths_in_function_return_a_value: { code: 6075, category: ts.DiagnosticCategory.Message, key: "Report_error_when_not_all_code_paths_in_function_return_a_value_6075", message: "Report error when not all code paths in function return a value." },
Report_errors_for_fallthrough_cases_in_switch_statement: { code: 6076, category: ts.DiagnosticCategory.Message, key: "Report_errors_for_fallthrough_cases_in_switch_statement_6076", message: "Report errors for fallthrough cases in switch statement." },
Do_not_report_errors_on_unreachable_code: { code: 6077, category: ts.DiagnosticCategory.Message, key: "Do_not_report_errors_on_unreachable_code_6077", message: "Do not report errors on unreachable code." },
Disallow_inconsistently_cased_references_to_the_same_file: { code: 6078, category: ts.DiagnosticCategory.Message, key: "Disallow_inconsistently_cased_references_to_the_same_file_6078", message: "Disallow inconsistently-cased references to the same file." },
Specify_library_files_to_be_included_in_the_compilation_Colon: { code: 6079, category: ts.DiagnosticCategory.Message, key: "Specify_library_files_to_be_included_in_the_compilation_Colon_6079", message: "Specify library files to be included in the compilation: " },
Specify_JSX_code_generation_Colon_preserve_or_react: { code: 6080, category: ts.DiagnosticCategory.Message, key: "Specify_JSX_code_generation_Colon_preserve_or_react_6080", message: "Specify JSX code generation: 'preserve' or 'react'" },
Only_amd_and_system_modules_are_supported_alongside_0: { code: 6082, category: ts.DiagnosticCategory.Error, key: "Only_amd_and_system_modules_are_supported_alongside_0_6082", message: "Only 'amd' and 'system' modules are supported alongside --{0}." },
Base_directory_to_resolve_non_absolute_module_names: { code: 6083, category: ts.DiagnosticCategory.Message, key: "Base_directory_to_resolve_non_absolute_module_names_6083", message: "Base directory to resolve non-absolute module names." },
Specify_the_object_invoked_for_createElement_and_spread_when_targeting_react_JSX_emit: { code: 6084, category: ts.DiagnosticCategory.Message, key: "Specify_the_object_invoked_for_createElement_and_spread_when_targeting_react_JSX_emit_6084", message: "Specify the object invoked for createElement and __spread when targeting 'react' JSX emit" },
Enable_tracing_of_the_name_resolution_process: { code: 6085, category: ts.DiagnosticCategory.Message, key: "Enable_tracing_of_the_name_resolution_process_6085", message: "Enable tracing of the name resolution process." },
Resolving_module_0_from_1: { code: 6086, category: ts.DiagnosticCategory.Message, key: "Resolving_module_0_from_1_6086", message: "======== Resolving module '{0}' from '{1}'. ========" },
Explicitly_specified_module_resolution_kind_Colon_0: { code: 6087, category: ts.DiagnosticCategory.Message, key: "Explicitly_specified_module_resolution_kind_Colon_0_6087", message: "Explicitly specified module resolution kind: '{0}'." },
Module_resolution_kind_is_not_specified_using_0: { code: 6088, category: ts.DiagnosticCategory.Message, key: "Module_resolution_kind_is_not_specified_using_0_6088", message: "Module resolution kind is not specified, using '{0}'." },
Module_name_0_was_successfully_resolved_to_1: { code: 6089, category: ts.DiagnosticCategory.Message, key: "Module_name_0_was_successfully_resolved_to_1_6089", message: "======== Module name '{0}' was successfully resolved to '{1}'. ========" },
Module_name_0_was_not_resolved: { code: 6090, category: ts.DiagnosticCategory.Message, key: "Module_name_0_was_not_resolved_6090", message: "======== Module name '{0}' was not resolved. ========" },
paths_option_is_specified_looking_for_a_pattern_to_match_module_name_0: { code: 6091, category: ts.DiagnosticCategory.Message, key: "paths_option_is_specified_looking_for_a_pattern_to_match_module_name_0_6091", message: "'paths' option is specified, looking for a pattern to match module name '{0}'." },
Module_name_0_matched_pattern_1: { code: 6092, category: ts.DiagnosticCategory.Message, key: "Module_name_0_matched_pattern_1_6092", message: "Module name '{0}', matched pattern '{1}'." },
Trying_substitution_0_candidate_module_location_Colon_1: { code: 6093, category: ts.DiagnosticCategory.Message, key: "Trying_substitution_0_candidate_module_location_Colon_1_6093", message: "Trying substitution '{0}', candidate module location: '{1}'." },
Resolving_module_name_0_relative_to_base_url_1_2: { code: 6094, category: ts.DiagnosticCategory.Message, key: "Resolving_module_name_0_relative_to_base_url_1_2_6094", message: "Resolving module name '{0}' relative to base url '{1}' - '{2}'." },
Loading_module_as_file_Slash_folder_candidate_module_location_0: { code: 6095, category: ts.DiagnosticCategory.Message, key: "Loading_module_as_file_Slash_folder_candidate_module_location_0_6095", message: "Loading module as file / folder, candidate module location '{0}'." },
File_0_does_not_exist: { code: 6096, category: ts.DiagnosticCategory.Message, key: "File_0_does_not_exist_6096", message: "File '{0}' does not exist." },
File_0_exist_use_it_as_a_name_resolution_result: { code: 6097, category: ts.DiagnosticCategory.Message, key: "File_0_exist_use_it_as_a_name_resolution_result_6097", message: "File '{0}' exist - use it as a name resolution result." },
Loading_module_0_from_node_modules_folder: { code: 6098, category: ts.DiagnosticCategory.Message, key: "Loading_module_0_from_node_modules_folder_6098", message: "Loading module '{0}' from 'node_modules' folder." },
Found_package_json_at_0: { code: 6099, category: ts.DiagnosticCategory.Message, key: "Found_package_json_at_0_6099", message: "Found 'package.json' at '{0}'." },
package_json_does_not_have_a_types_or_main_field: { code: 6100, category: ts.DiagnosticCategory.Message, key: "package_json_does_not_have_a_types_or_main_field_6100", message: "'package.json' does not have a 'types' or 'main' field." },
package_json_has_0_field_1_that_references_2: { code: 6101, category: ts.DiagnosticCategory.Message, key: "package_json_has_0_field_1_that_references_2_6101", message: "'package.json' has '{0}' field '{1}' that references '{2}'." },
Allow_javascript_files_to_be_compiled: { code: 6102, category: ts.DiagnosticCategory.Message, key: "Allow_javascript_files_to_be_compiled_6102", message: "Allow javascript files to be compiled." },
Option_0_should_have_array_of_strings_as_a_value: { code: 6103, category: ts.DiagnosticCategory.Error, key: "Option_0_should_have_array_of_strings_as_a_value_6103", message: "Option '{0}' should have array of strings as a value." },
Checking_if_0_is_the_longest_matching_prefix_for_1_2: { code: 6104, category: ts.DiagnosticCategory.Message, key: "Checking_if_0_is_the_longest_matching_prefix_for_1_2_6104", message: "Checking if '{0}' is the longest matching prefix for '{1}' - '{2}'." },
Expected_type_of_0_field_in_package_json_to_be_string_got_1: { code: 6105, category: ts.DiagnosticCategory.Message, key: "Expected_type_of_0_field_in_package_json_to_be_string_got_1_6105", message: "Expected type of '{0}' field in 'package.json' to be 'string', got '{1}'." },
baseUrl_option_is_set_to_0_using_this_value_to_resolve_non_relative_module_name_1: { code: 6106, category: ts.DiagnosticCategory.Message, key: "baseUrl_option_is_set_to_0_using_this_value_to_resolve_non_relative_module_name_1_6106", message: "'baseUrl' option is set to '{0}', using this value to resolve non-relative module name '{1}'" },
rootDirs_option_is_set_using_it_to_resolve_relative_module_name_0: { code: 6107, category: ts.DiagnosticCategory.Message, key: "rootDirs_option_is_set_using_it_to_resolve_relative_module_name_0_6107", message: "'rootDirs' option is set, using it to resolve relative module name '{0}'" },
Longest_matching_prefix_for_0_is_1: { code: 6108, category: ts.DiagnosticCategory.Message, key: "Longest_matching_prefix_for_0_is_1_6108", message: "Longest matching prefix for '{0}' is '{1}'" },
Loading_0_from_the_root_dir_1_candidate_location_2: { code: 6109, category: ts.DiagnosticCategory.Message, key: "Loading_0_from_the_root_dir_1_candidate_location_2_6109", message: "Loading '{0}' from the root dir '{1}', candidate location '{2}'" },
Trying_other_entries_in_rootDirs: { code: 6110, category: ts.DiagnosticCategory.Message, key: "Trying_other_entries_in_rootDirs_6110", message: "Trying other entries in 'rootDirs'" },
Module_resolution_using_rootDirs_has_failed: { code: 6111, category: ts.DiagnosticCategory.Message, key: "Module_resolution_using_rootDirs_has_failed_6111", message: "Module resolution using 'rootDirs' has failed" },
Do_not_emit_use_strict_directives_in_module_output: { code: 6112, category: ts.DiagnosticCategory.Message, key: "Do_not_emit_use_strict_directives_in_module_output_6112", message: "Do not emit 'use strict' directives in module output." },
Enable_strict_null_checks: { code: 6113, category: ts.DiagnosticCategory.Message, key: "Enable_strict_null_checks_6113", message: "Enable strict null checks." },
Unknown_option_excludes_Did_you_mean_exclude: { code: 6114, category: ts.DiagnosticCategory.Error, key: "Unknown_option_excludes_Did_you_mean_exclude_6114", message: "Unknown option 'excludes'. Did you mean 'exclude'?" },
Raise_error_on_this_expressions_with_an_implied_any_type: { code: 6115, category: ts.DiagnosticCategory.Message, key: "Raise_error_on_this_expressions_with_an_implied_any_type_6115", message: "Raise error on 'this' expressions with an implied 'any' type." },
Resolving_type_reference_directive_0_containing_file_1_root_directory_2: { code: 6116, category: ts.DiagnosticCategory.Message, key: "Resolving_type_reference_directive_0_containing_file_1_root_directory_2_6116", message: "======== Resolving type reference directive '{0}', containing file '{1}', root directory '{2}'. ========" },
Resolving_using_primary_search_paths: { code: 6117, category: ts.DiagnosticCategory.Message, key: "Resolving_using_primary_search_paths_6117", message: "Resolving using primary search paths..." },
Resolving_from_node_modules_folder: { code: 6118, category: ts.DiagnosticCategory.Message, key: "Resolving_from_node_modules_folder_6118", message: "Resolving from node_modules folder..." },
Type_reference_directive_0_was_successfully_resolved_to_1_primary_Colon_2: { code: 6119, category: ts.DiagnosticCategory.Message, key: "Type_reference_directive_0_was_successfully_resolved_to_1_primary_Colon_2_6119", message: "======== Type reference directive '{0}' was successfully resolved to '{1}', primary: {2}. ========" },
Type_reference_directive_0_was_not_resolved: { code: 6120, category: ts.DiagnosticCategory.Message, key: "Type_reference_directive_0_was_not_resolved_6120", message: "======== Type reference directive '{0}' was not resolved. ========" },
Resolving_with_primary_search_path_0: { code: 6121, category: ts.DiagnosticCategory.Message, key: "Resolving_with_primary_search_path_0_6121", message: "Resolving with primary search path '{0}'" },
Root_directory_cannot_be_determined_skipping_primary_search_paths: { code: 6122, category: ts.DiagnosticCategory.Message, key: "Root_directory_cannot_be_determined_skipping_primary_search_paths_6122", message: "Root directory cannot be determined, skipping primary search paths." },
Resolving_type_reference_directive_0_containing_file_1_root_directory_not_set: { code: 6123, category: ts.DiagnosticCategory.Message, key: "Resolving_type_reference_directive_0_containing_file_1_root_directory_not_set_6123", message: "======== Resolving type reference directive '{0}', containing file '{1}', root directory not set. ========" },
Type_declaration_files_to_be_included_in_compilation: { code: 6124, category: ts.DiagnosticCategory.Message, key: "Type_declaration_files_to_be_included_in_compilation_6124", message: "Type declaration files to be included in compilation." },
Looking_up_in_node_modules_folder_initial_location_0: { code: 6125, category: ts.DiagnosticCategory.Message, key: "Looking_up_in_node_modules_folder_initial_location_0_6125", message: "Looking up in 'node_modules' folder, initial location '{0}'" },
Containing_file_is_not_specified_and_root_directory_cannot_be_determined_skipping_lookup_in_node_modules_folder: { code: 6126, category: ts.DiagnosticCategory.Message, key: "Containing_file_is_not_specified_and_root_directory_cannot_be_determined_skipping_lookup_in_node_mod_6126", message: "Containing file is not specified and root directory cannot be determined, skipping lookup in 'node_modules' folder." },
Resolving_type_reference_directive_0_containing_file_not_set_root_directory_1: { code: 6127, category: ts.DiagnosticCategory.Message, key: "Resolving_type_reference_directive_0_containing_file_not_set_root_directory_1_6127", message: "======== Resolving type reference directive '{0}', containing file not set, root directory '{1}'. ========" },
Resolving_type_reference_directive_0_containing_file_not_set_root_directory_not_set: { code: 6128, category: ts.DiagnosticCategory.Message, key: "Resolving_type_reference_directive_0_containing_file_not_set_root_directory_not_set_6128", message: "======== Resolving type reference directive '{0}', containing file not set, root directory not set. ========" },
The_config_file_0_found_doesn_t_contain_any_source_files: { code: 6129, category: ts.DiagnosticCategory.Error, key: "The_config_file_0_found_doesn_t_contain_any_source_files_6129", message: "The config file '{0}' found doesn't contain any source files." },
Resolving_real_path_for_0_result_1: { code: 6130, category: ts.DiagnosticCategory.Message, key: "Resolving_real_path_for_0_result_1_6130", message: "Resolving real path for '{0}', result '{1}'" },
Cannot_compile_modules_using_option_0_unless_the_module_flag_is_amd_or_system: { code: 6131, category: ts.DiagnosticCategory.Error, key: "Cannot_compile_modules_using_option_0_unless_the_module_flag_is_amd_or_system_6131", message: "Cannot compile modules using option '{0}' unless the '--module' flag is 'amd' or 'system'." },
File_name_0_has_a_1_extension_stripping_it: { code: 6132, category: ts.DiagnosticCategory.Message, key: "File_name_0_has_a_1_extension_stripping_it_6132", message: "File name '{0}' has a '{1}' extension - stripping it" },
_0_is_declared_but_never_used: { code: 6133, category: ts.DiagnosticCategory.Error, key: "_0_is_declared_but_never_used_6133", message: "'{0}' is declared but never used." },
Report_errors_on_unused_locals: { code: 6134, category: ts.DiagnosticCategory.Message, key: "Report_errors_on_unused_locals_6134", message: "Report errors on unused locals." },
Report_errors_on_unused_parameters: { code: 6135, category: ts.DiagnosticCategory.Message, key: "Report_errors_on_unused_parameters_6135", message: "Report errors on unused parameters." },
The_maximum_dependency_depth_to_search_under_node_modules_and_load_JavaScript_files: { code: 6136, category: ts.DiagnosticCategory.Message, key: "The_maximum_dependency_depth_to_search_under_node_modules_and_load_JavaScript_files_6136", message: "The maximum dependency depth to search under node_modules and load JavaScript files" },
No_types_specified_in_package_json_so_returning_main_value_of_0: { code: 6137, category: ts.DiagnosticCategory.Message, key: "No_types_specified_in_package_json_so_returning_main_value_of_0_6137", message: "No types specified in 'package.json', so returning 'main' value of '{0}'" },
Property_0_is_declared_but_never_used: { code: 6138, category: ts.DiagnosticCategory.Error, key: "Property_0_is_declared_but_never_used_6138", message: "Property '{0}' is declared but never used." },
Import_emit_helpers_from_tslib: { code: 6139, category: ts.DiagnosticCategory.Message, key: "Import_emit_helpers_from_tslib_6139", message: "Import emit helpers from 'tslib'." },
Auto_discovery_for_typings_is_enabled_in_project_0_Running_extra_resolution_pass_for_module_1_using_cache_location_2: { code: 6140, category: ts.DiagnosticCategory.Error, key: "Auto_discovery_for_typings_is_enabled_in_project_0_Running_extra_resolution_pass_for_module_1_using__6140", message: "Auto discovery for typings is enabled in project '{0}'. Running extra resolution pass for module '{1}' using cache location '{2}'." },
Parse_in_strict_mode_and_emit_use_strict_for_each_source_file: { code: 6141, category: ts.DiagnosticCategory.Message, key: "Parse_in_strict_mode_and_emit_use_strict_for_each_source_file_6141", message: "Parse in strict mode and emit \"use strict\" for each source file" },
Module_0_was_resolved_to_1_but_jsx_is_not_set: { code: 6142, category: ts.DiagnosticCategory.Error, key: "Module_0_was_resolved_to_1_but_jsx_is_not_set_6142", message: "Module '{0}' was resolved to '{1}', but '--jsx' is not set." },
Module_0_was_resolved_to_1_but_allowJs_is_not_set: { code: 6143, category: ts.DiagnosticCategory.Error, key: "Module_0_was_resolved_to_1_but_allowJs_is_not_set_6143", message: "Module '{0}' was resolved to '{1}', but '--allowJs' is not set." },
Module_0_was_resolved_as_locally_declared_ambient_module_in_file_1: { code: 6144, category: ts.DiagnosticCategory.Message, key: "Module_0_was_resolved_as_locally_declared_ambient_module_in_file_1_6144", message: "Module '{0}' was resolved as locally declared ambient module in file '{1}'." },
Module_0_was_resolved_as_ambient_module_declared_in_1_since_this_file_was_not_modified: { code: 6145, category: ts.DiagnosticCategory.Message, key: "Module_0_was_resolved_as_ambient_module_declared_in_1_since_this_file_was_not_modified_6145", message: "Module '{0}' was resolved as ambient module declared in '{1}' since this file was not modified." },
Specify_the_JSX_factory_function_to_use_when_targeting_react_JSX_emit_e_g_React_createElement_or_h: { code: 6146, category: ts.DiagnosticCategory.Message, key: "Specify_the_JSX_factory_function_to_use_when_targeting_react_JSX_emit_e_g_React_createElement_or_h_6146", message: "Specify the JSX factory function to use when targeting 'react' JSX emit, e.g. 'React.createElement' or 'h'." },
Variable_0_implicitly_has_an_1_type: { code: 7005, category: ts.DiagnosticCategory.Error, key: "Variable_0_implicitly_has_an_1_type_7005", message: "Variable '{0}' implicitly has an '{1}' type." },
Parameter_0_implicitly_has_an_1_type: { code: 7006, category: ts.DiagnosticCategory.Error, key: "Parameter_0_implicitly_has_an_1_type_7006", message: "Parameter '{0}' implicitly has an '{1}' type." },
Member_0_implicitly_has_an_1_type: { code: 7008, category: ts.DiagnosticCategory.Error, key: "Member_0_implicitly_has_an_1_type_7008", message: "Member '{0}' implicitly has an '{1}' type." },
new_expression_whose_target_lacks_a_construct_signature_implicitly_has_an_any_type: { code: 7009, category: ts.DiagnosticCategory.Error, key: "new_expression_whose_target_lacks_a_construct_signature_implicitly_has_an_any_type_7009", message: "'new' expression, whose target lacks a construct signature, implicitly has an 'any' type." },
_0_which_lacks_return_type_annotation_implicitly_has_an_1_return_type: { code: 7010, category: ts.DiagnosticCategory.Error, key: "_0_which_lacks_return_type_annotation_implicitly_has_an_1_return_type_7010", message: "'{0}', which lacks return-type annotation, implicitly has an '{1}' return type." },
Function_expression_which_lacks_return_type_annotation_implicitly_has_an_0_return_type: { code: 7011, category: ts.DiagnosticCategory.Error, key: "Function_expression_which_lacks_return_type_annotation_implicitly_has_an_0_return_type_7011", message: "Function expression, which lacks return-type annotation, implicitly has an '{0}' return type." },
Construct_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type: { code: 7013, category: ts.DiagnosticCategory.Error, key: "Construct_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type_7013", message: "Construct signature, which lacks return-type annotation, implicitly has an 'any' return type." },
Element_implicitly_has_an_any_type_because_index_expression_is_not_of_type_number: { code: 7015, category: ts.DiagnosticCategory.Error, key: "Element_implicitly_has_an_any_type_because_index_expression_is_not_of_type_number_7015", message: "Element implicitly has an 'any' type because index expression is not of type 'number'." },
Could_not_find_a_declaration_file_for_module_0_1_implicitly_has_an_any_type: { code: 7016, category: ts.DiagnosticCategory.Error, key: "Could_not_find_a_declaration_file_for_module_0_1_implicitly_has_an_any_type_7016", message: "Could not find a declaration file for module '{0}'. '{1}' implicitly has an 'any' type." },
Element_implicitly_has_an_any_type_because_type_0_has_no_index_signature: { code: 7017, category: ts.DiagnosticCategory.Error, key: "Element_implicitly_has_an_any_type_because_type_0_has_no_index_signature_7017", message: "Element implicitly has an 'any' type because type '{0}' has no index signature." },
Object_literal_s_property_0_implicitly_has_an_1_type: { code: 7018, category: ts.DiagnosticCategory.Error, key: "Object_literal_s_property_0_implicitly_has_an_1_type_7018", message: "Object literal's property '{0}' implicitly has an '{1}' type." },
Rest_parameter_0_implicitly_has_an_any_type: { code: 7019, category: ts.DiagnosticCategory.Error, key: "Rest_parameter_0_implicitly_has_an_any_type_7019", message: "Rest parameter '{0}' implicitly has an 'any[]' type." },
Call_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type: { code: 7020, category: ts.DiagnosticCategory.Error, key: "Call_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type_7020", message: "Call signature, which lacks return-type annotation, implicitly has an 'any' return type." },
_0_implicitly_has_type_any_because_it_does_not_have_a_type_annotation_and_is_referenced_directly_or_indirectly_in_its_own_initializer: { code: 7022, category: ts.DiagnosticCategory.Error, key: "_0_implicitly_has_type_any_because_it_does_not_have_a_type_annotation_and_is_referenced_directly_or__7022", message: "'{0}' implicitly has type 'any' because it does not have a type annotation and is referenced directly or indirectly in its own initializer." },
_0_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions: { code: 7023, category: ts.DiagnosticCategory.Error, key: "_0_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_reference_7023", message: "'{0}' implicitly has return type 'any' because it does not have a return type annotation and is referenced directly or indirectly in one of its return expressions." },
Function_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions: { code: 7024, category: ts.DiagnosticCategory.Error, key: "Function_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_ref_7024", message: "Function implicitly has return type 'any' because it does not have a return type annotation and is referenced directly or indirectly in one of its return expressions." },
Generator_implicitly_has_type_0_because_it_does_not_yield_any_values_Consider_supplying_a_return_type: { code: 7025, category: ts.DiagnosticCategory.Error, key: "Generator_implicitly_has_type_0_because_it_does_not_yield_any_values_Consider_supplying_a_return_typ_7025", message: "Generator implicitly has type '{0}' because it does not yield any values. Consider supplying a return type." },
JSX_element_implicitly_has_type_any_because_no_interface_JSX_0_exists: { code: 7026, category: ts.DiagnosticCategory.Error, key: "JSX_element_implicitly_has_type_any_because_no_interface_JSX_0_exists_7026", message: "JSX element implicitly has type 'any' because no interface 'JSX.{0}' exists" },
Unreachable_code_detected: { code: 7027, category: ts.DiagnosticCategory.Error, key: "Unreachable_code_detected_7027", message: "Unreachable code detected." },
Unused_label: { code: 7028, category: ts.DiagnosticCategory.Error, key: "Unused_label_7028", message: "Unused label." },
Fallthrough_case_in_switch: { code: 7029, category: ts.DiagnosticCategory.Error, key: "Fallthrough_case_in_switch_7029", message: "Fallthrough case in switch." },
Not_all_code_paths_return_a_value: { code: 7030, category: ts.DiagnosticCategory.Error, key: "Not_all_code_paths_return_a_value_7030", message: "Not all code paths return a value." },
Binding_element_0_implicitly_has_an_1_type: { code: 7031, category: ts.DiagnosticCategory.Error, key: "Binding_element_0_implicitly_has_an_1_type_7031", message: "Binding element '{0}' implicitly has an '{1}' type." },
Property_0_implicitly_has_type_any_because_its_set_accessor_lacks_a_parameter_type_annotation: { code: 7032, category: ts.DiagnosticCategory.Error, key: "Property_0_implicitly_has_type_any_because_its_set_accessor_lacks_a_parameter_type_annotation_7032", message: "Property '{0}' implicitly has type 'any', because its set accessor lacks a parameter type annotation." },
Property_0_implicitly_has_type_any_because_its_get_accessor_lacks_a_return_type_annotation: { code: 7033, category: ts.DiagnosticCategory.Error, key: "Property_0_implicitly_has_type_any_because_its_get_accessor_lacks_a_return_type_annotation_7033", message: "Property '{0}' implicitly has type 'any', because its get accessor lacks a return type annotation." },
Variable_0_implicitly_has_type_1_in_some_locations_where_its_type_cannot_be_determined: { code: 7034, category: ts.DiagnosticCategory.Error, key: "Variable_0_implicitly_has_type_1_in_some_locations_where_its_type_cannot_be_determined_7034", message: "Variable '{0}' implicitly has type '{1}' in some locations where its type cannot be determined." },
You_cannot_rename_this_element: { code: 8000, category: ts.DiagnosticCategory.Error, key: "You_cannot_rename_this_element_8000", message: "You cannot rename this element." },
You_cannot_rename_elements_that_are_defined_in_the_standard_TypeScript_library: { code: 8001, category: ts.DiagnosticCategory.Error, key: "You_cannot_rename_elements_that_are_defined_in_the_standard_TypeScript_library_8001", message: "You cannot rename elements that are defined in the standard TypeScript library." },
import_can_only_be_used_in_a_ts_file: { code: 8002, category: ts.DiagnosticCategory.Error, key: "import_can_only_be_used_in_a_ts_file_8002", message: "'import ... =' can only be used in a .ts file." },
export_can_only_be_used_in_a_ts_file: { code: 8003, category: ts.DiagnosticCategory.Error, key: "export_can_only_be_used_in_a_ts_file_8003", message: "'export=' can only be used in a .ts file." },
type_parameter_declarations_can_only_be_used_in_a_ts_file: { code: 8004, category: ts.DiagnosticCategory.Error, key: "type_parameter_declarations_can_only_be_used_in_a_ts_file_8004", message: "'type parameter declarations' can only be used in a .ts file." },
implements_clauses_can_only_be_used_in_a_ts_file: { code: 8005, category: ts.DiagnosticCategory.Error, key: "implements_clauses_can_only_be_used_in_a_ts_file_8005", message: "'implements clauses' can only be used in a .ts file." },
interface_declarations_can_only_be_used_in_a_ts_file: { code: 8006, category: ts.DiagnosticCategory.Error, key: "interface_declarations_can_only_be_used_in_a_ts_file_8006", message: "'interface declarations' can only be used in a .ts file." },
module_declarations_can_only_be_used_in_a_ts_file: { code: 8007, category: ts.DiagnosticCategory.Error, key: "module_declarations_can_only_be_used_in_a_ts_file_8007", message: "'module declarations' can only be used in a .ts file." },
type_aliases_can_only_be_used_in_a_ts_file: { code: 8008, category: ts.DiagnosticCategory.Error, key: "type_aliases_can_only_be_used_in_a_ts_file_8008", message: "'type aliases' can only be used in a .ts file." },
_0_can_only_be_used_in_a_ts_file: { code: 8009, category: ts.DiagnosticCategory.Error, key: "_0_can_only_be_used_in_a_ts_file_8009", message: "'{0}' can only be used in a .ts file." },
types_can_only_be_used_in_a_ts_file: { code: 8010, category: ts.DiagnosticCategory.Error, key: "types_can_only_be_used_in_a_ts_file_8010", message: "'types' can only be used in a .ts file." },
type_arguments_can_only_be_used_in_a_ts_file: { code: 8011, category: ts.DiagnosticCategory.Error, key: "type_arguments_can_only_be_used_in_a_ts_file_8011", message: "'type arguments' can only be used in a .ts file." },
parameter_modifiers_can_only_be_used_in_a_ts_file: { code: 8012, category: ts.DiagnosticCategory.Error, key: "parameter_modifiers_can_only_be_used_in_a_ts_file_8012", message: "'parameter modifiers' can only be used in a .ts file." },
enum_declarations_can_only_be_used_in_a_ts_file: { code: 8015, category: ts.DiagnosticCategory.Error, key: "enum_declarations_can_only_be_used_in_a_ts_file_8015", message: "'enum declarations' can only be used in a .ts file." },
type_assertion_expressions_can_only_be_used_in_a_ts_file: { code: 8016, category: ts.DiagnosticCategory.Error, key: "type_assertion_expressions_can_only_be_used_in_a_ts_file_8016", message: "'type assertion expressions' can only be used in a .ts file." },
Only_identifiers_Slashqualified_names_with_optional_type_arguments_are_currently_supported_in_a_class_extends_clauses: { code: 9002, category: ts.DiagnosticCategory.Error, key: "Only_identifiers_Slashqualified_names_with_optional_type_arguments_are_currently_supported_in_a_clas_9002", message: "Only identifiers/qualified-names with optional type arguments are currently supported in a class 'extends' clauses." },
class_expressions_are_not_currently_supported: { code: 9003, category: ts.DiagnosticCategory.Error, key: "class_expressions_are_not_currently_supported_9003", message: "'class' expressions are not currently supported." },
JSX_attributes_must_only_be_assigned_a_non_empty_expression: { code: 17000, category: ts.DiagnosticCategory.Error, key: "JSX_attributes_must_only_be_assigned_a_non_empty_expression_17000", message: "JSX attributes must only be assigned a non-empty 'expression'." },
JSX_elements_cannot_have_multiple_attributes_with_the_same_name: { code: 17001, category: ts.DiagnosticCategory.Error, key: "JSX_elements_cannot_have_multiple_attributes_with_the_same_name_17001", message: "JSX elements cannot have multiple attributes with the same name." },
Expected_corresponding_JSX_closing_tag_for_0: { code: 17002, category: ts.DiagnosticCategory.Error, key: "Expected_corresponding_JSX_closing_tag_for_0_17002", message: "Expected corresponding JSX closing tag for '{0}'." },
JSX_attribute_expected: { code: 17003, category: ts.DiagnosticCategory.Error, key: "JSX_attribute_expected_17003", message: "JSX attribute expected." },
Cannot_use_JSX_unless_the_jsx_flag_is_provided: { code: 17004, category: ts.DiagnosticCategory.Error, key: "Cannot_use_JSX_unless_the_jsx_flag_is_provided_17004", message: "Cannot use JSX unless the '--jsx' flag is provided." },
A_constructor_cannot_contain_a_super_call_when_its_class_extends_null: { code: 17005, category: ts.DiagnosticCategory.Error, key: "A_constructor_cannot_contain_a_super_call_when_its_class_extends_null_17005", message: "A constructor cannot contain a 'super' call when its class extends 'null'" },
An_unary_expression_with_the_0_operator_is_not_allowed_in_the_left_hand_side_of_an_exponentiation_expression_Consider_enclosing_the_expression_in_parentheses: { code: 17006, category: ts.DiagnosticCategory.Error, key: "An_unary_expression_with_the_0_operator_is_not_allowed_in_the_left_hand_side_of_an_exponentiation_ex_17006", message: "An unary expression with the '{0}' operator is not allowed in the left-hand side of an exponentiation expression. Consider enclosing the expression in parentheses." },
A_type_assertion_expression_is_not_allowed_in_the_left_hand_side_of_an_exponentiation_expression_Consider_enclosing_the_expression_in_parentheses: { code: 17007, category: ts.DiagnosticCategory.Error, key: "A_type_assertion_expression_is_not_allowed_in_the_left_hand_side_of_an_exponentiation_expression_Con_17007", message: "A type assertion expression is not allowed in the left-hand side of an exponentiation expression. Consider enclosing the expression in parentheses." },
JSX_element_0_has_no_corresponding_closing_tag: { code: 17008, category: ts.DiagnosticCategory.Error, key: "JSX_element_0_has_no_corresponding_closing_tag_17008", message: "JSX element '{0}' has no corresponding closing tag." },
super_must_be_called_before_accessing_this_in_the_constructor_of_a_derived_class: { code: 17009, category: ts.DiagnosticCategory.Error, key: "super_must_be_called_before_accessing_this_in_the_constructor_of_a_derived_class_17009", message: "'super' must be called before accessing 'this' in the constructor of a derived class." },
Unknown_typing_option_0: { code: 17010, category: ts.DiagnosticCategory.Error, key: "Unknown_typing_option_0_17010", message: "Unknown typing option '{0}'." },
Circularity_detected_while_resolving_configuration_Colon_0: { code: 18000, category: ts.DiagnosticCategory.Error, key: "Circularity_detected_while_resolving_configuration_Colon_0_18000", message: "Circularity detected while resolving configuration: {0}" },
The_path_in_an_extends_options_must_be_relative_or_rooted: { code: 18001, category: ts.DiagnosticCategory.Error, key: "The_path_in_an_extends_options_must_be_relative_or_rooted_18001", message: "The path in an 'extends' options must be relative or rooted." },
The_files_list_in_config_file_0_is_empty: { code: 18002, category: ts.DiagnosticCategory.Error, key: "The_files_list_in_config_file_0_is_empty_18002", message: "The 'files' list in config file '{0}' is empty." },
No_inputs_were_found_in_config_file_0_Specified_include_paths_were_1_and_exclude_paths_were_2: { code: 18003, category: ts.DiagnosticCategory.Error, key: "No_inputs_were_found_in_config_file_0_Specified_include_paths_were_1_and_exclude_paths_were_2_18003", message: "No inputs were found in config file '{0}'. Specified 'include' paths were '{1}' and 'exclude' paths were '{2}'." },
Add_missing_super_call: { code: 90001, category: ts.DiagnosticCategory.Message, key: "Add_missing_super_call_90001", message: "Add missing 'super()' call." },
Make_super_call_the_first_statement_in_the_constructor: { code: 90002, category: ts.DiagnosticCategory.Message, key: "Make_super_call_the_first_statement_in_the_constructor_90002", message: "Make 'super()' call the first statement in the constructor." },
Change_extends_to_implements: { code: 90003, category: ts.DiagnosticCategory.Message, key: "Change_extends_to_implements_90003", message: "Change 'extends' to 'implements'" },
Remove_unused_identifiers: { code: 90004, category: ts.DiagnosticCategory.Message, key: "Remove_unused_identifiers_90004", message: "Remove unused identifiers" },
Implement_interface_on_reference: { code: 90005, category: ts.DiagnosticCategory.Message, key: "Implement_interface_on_reference_90005", message: "Implement interface on reference" },
Implement_interface_on_class: { code: 90006, category: ts.DiagnosticCategory.Message, key: "Implement_interface_on_class_90006", message: "Implement interface on class" },
Implement_inherited_abstract_class: { code: 90007, category: ts.DiagnosticCategory.Message, key: "Implement_inherited_abstract_class_90007", message: "Implement inherited abstract class" },
Adding_a_tsconfig_json_file_will_help_organize_projects_that_contain_both_TypeScript_and_JavaScript_files_Learn_more_at_https_Colon_Slash_Slashaka_ms_Slashtsconfig: { code: 90009, category: ts.DiagnosticCategory.Error, key: "Adding_a_tsconfig_json_file_will_help_organize_projects_that_contain_both_TypeScript_and_JavaScript__90009", message: "Adding a tsconfig.json file will help organize projects that contain both TypeScript and JavaScript files. Learn more at https://aka.ms/tsconfig" },
Type_0_is_not_assignable_to_type_1_Two_different_types_with_this_name_exist_but_they_are_unrelated: { code: 90010, category: ts.DiagnosticCategory.Error, key: "Type_0_is_not_assignable_to_type_1_Two_different_types_with_this_name_exist_but_they_are_unrelated_90010", message: "Type '{0}' is not assignable to type '{1}'. Two different types with this name exist, but they are unrelated." },
};
})(ts || (ts = {}));
/// <reference path="core.ts"/>
/// <reference path="diagnosticInformationMap.generated.ts"/>
var ts;
(function (ts) {
/* @internal */
function tokenIsIdentifierOrKeyword(token) {
return token >= 70 /* Identifier */;
}
ts.tokenIsIdentifierOrKeyword = tokenIsIdentifierOrKeyword;
var textToToken = ts.createMap({
"abstract": 116 /* AbstractKeyword */,
"any": 118 /* AnyKeyword */,
"as": 117 /* AsKeyword */,
"boolean": 121 /* BooleanKeyword */,
"break": 71 /* BreakKeyword */,
"case": 72 /* CaseKeyword */,
"catch": 73 /* CatchKeyword */,
"class": 74 /* ClassKeyword */,
"continue": 76 /* ContinueKeyword */,
"const": 75 /* ConstKeyword */,
"constructor": 122 /* ConstructorKeyword */,
"debugger": 77 /* DebuggerKeyword */,
"declare": 123 /* DeclareKeyword */,
"default": 78 /* DefaultKeyword */,
"delete": 79 /* DeleteKeyword */,
"do": 80 /* DoKeyword */,
"else": 81 /* ElseKeyword */,
"enum": 82 /* EnumKeyword */,
"export": 83 /* ExportKeyword */,
"extends": 84 /* ExtendsKeyword */,
"false": 85 /* FalseKeyword */,
"finally": 86 /* FinallyKeyword */,
"for": 87 /* ForKeyword */,
"from": 138 /* FromKeyword */,
"function": 88 /* FunctionKeyword */,
"get": 124 /* GetKeyword */,
"if": 89 /* IfKeyword */,
"implements": 107 /* ImplementsKeyword */,
"import": 90 /* ImportKeyword */,
"in": 91 /* InKeyword */,
"instanceof": 92 /* InstanceOfKeyword */,
"interface": 108 /* InterfaceKeyword */,
"is": 125 /* IsKeyword */,
"keyof": 126 /* KeyOfKeyword */,
"let": 109 /* LetKeyword */,
"module": 127 /* ModuleKeyword */,
"namespace": 128 /* NamespaceKeyword */,
"never": 129 /* NeverKeyword */,
"new": 93 /* NewKeyword */,
"null": 94 /* NullKeyword */,
"number": 132 /* NumberKeyword */,
"package": 110 /* PackageKeyword */,
"private": 111 /* PrivateKeyword */,
"protected": 112 /* ProtectedKeyword */,
"public": 113 /* PublicKeyword */,
"readonly": 130 /* ReadonlyKeyword */,
"require": 131 /* RequireKeyword */,
"global": 139 /* GlobalKeyword */,
"return": 95 /* ReturnKeyword */,
"set": 133 /* SetKeyword */,
"static": 114 /* StaticKeyword */,
"string": 134 /* StringKeyword */,
"super": 96 /* SuperKeyword */,
"switch": 97 /* SwitchKeyword */,
"symbol": 135 /* SymbolKeyword */,
"this": 98 /* ThisKeyword */,
"throw": 99 /* ThrowKeyword */,
"true": 100 /* TrueKeyword */,
"try": 101 /* TryKeyword */,
"type": 136 /* TypeKeyword */,
"typeof": 102 /* TypeOfKeyword */,
"undefined": 137 /* UndefinedKeyword */,
"var": 103 /* VarKeyword */,
"void": 104 /* VoidKeyword */,
"while": 105 /* WhileKeyword */,
"with": 106 /* WithKeyword */,
"yield": 115 /* YieldKeyword */,
"async": 119 /* AsyncKeyword */,
"await": 120 /* AwaitKeyword */,
"of": 140 /* OfKeyword */,
"{": 16 /* OpenBraceToken */,
"}": 17 /* CloseBraceToken */,
"(": 18 /* OpenParenToken */,
")": 19 /* CloseParenToken */,
"[": 20 /* OpenBracketToken */,
"]": 21 /* CloseBracketToken */,
".": 22 /* DotToken */,
"...": 23 /* DotDotDotToken */,
";": 24 /* SemicolonToken */,
",": 25 /* CommaToken */,
"<": 26 /* LessThanToken */,
">": 28 /* GreaterThanToken */,
"<=": 29 /* LessThanEqualsToken */,
">=": 30 /* GreaterThanEqualsToken */,
"==": 31 /* EqualsEqualsToken */,
"!=": 32 /* ExclamationEqualsToken */,
"===": 33 /* EqualsEqualsEqualsToken */,
"!==": 34 /* ExclamationEqualsEqualsToken */,
"=>": 35 /* EqualsGreaterThanToken */,
"+": 36 /* PlusToken */,
"-": 37 /* MinusToken */,
"**": 39 /* AsteriskAsteriskToken */,
"*": 38 /* AsteriskToken */,
"/": 40 /* SlashToken */,
"%": 41 /* PercentToken */,
"++": 42 /* PlusPlusToken */,
"--": 43 /* MinusMinusToken */,
"<<": 44 /* LessThanLessThanToken */,
"</": 27 /* LessThanSlashToken */,
">>": 45 /* GreaterThanGreaterThanToken */,
">>>": 46 /* GreaterThanGreaterThanGreaterThanToken */,
"&": 47 /* AmpersandToken */,
"|": 48 /* BarToken */,
"^": 49 /* CaretToken */,
"!": 50 /* ExclamationToken */,
"~": 51 /* TildeToken */,
"&&": 52 /* AmpersandAmpersandToken */,
"||": 53 /* BarBarToken */,
"?": 54 /* QuestionToken */,
":": 55 /* ColonToken */,
"=": 57 /* EqualsToken */,
"+=": 58 /* PlusEqualsToken */,
"-=": 59 /* MinusEqualsToken */,
"*=": 60 /* AsteriskEqualsToken */,
"**=": 61 /* AsteriskAsteriskEqualsToken */,
"/=": 62 /* SlashEqualsToken */,
"%=": 63 /* PercentEqualsToken */,
"<<=": 64 /* LessThanLessThanEqualsToken */,
">>=": 65 /* GreaterThanGreaterThanEqualsToken */,
">>>=": 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */,
"&=": 67 /* AmpersandEqualsToken */,
"|=": 68 /* BarEqualsToken */,
"^=": 69 /* CaretEqualsToken */,
"@": 56 /* AtToken */,
});
/*
As per ECMAScript Language Specification 3th Edition, Section 7.6: Identifiers
IdentifierStart ::
Can contain Unicode 3.0.0 categories:
Uppercase letter (Lu),
Lowercase letter (Ll),
Titlecase letter (Lt),
Modifier letter (Lm),
Other letter (Lo), or
Letter number (Nl).
IdentifierPart :: =
Can contain IdentifierStart + Unicode 3.0.0 categories:
Non-spacing mark (Mn),
Combining spacing mark (Mc),
Decimal number (Nd), or
Connector punctuation (Pc).
Codepoint ranges for ES3 Identifiers are extracted from the Unicode 3.0.0 specification at:
http://www.unicode.org/Public/3.0-Update/UnicodeData-3.0.0.txt
*/
var unicodeES3IdentifierStart = [170, 170, 181, 181, 186, 186, 192, 214, 216, 246, 248, 543, 546, 563, 592, 685, 688, 696, 699, 705, 720, 721, 736, 740, 750, 750, 890, 890, 902, 902, 904, 906, 908, 908, 910, 929, 931, 974, 976, 983, 986, 1011, 1024, 1153, 1164, 1220, 1223, 1224, 1227, 1228, 1232, 1269, 1272, 1273, 1329, 1366, 1369, 1369, 1377, 1415, 1488, 1514, 1520, 1522, 1569, 1594, 1600, 1610, 1649, 1747, 1749, 1749, 1765, 1766, 1786, 1788, 1808, 1808, 1810, 1836, 1920, 1957, 2309, 2361, 2365, 2365, 2384, 2384, 2392, 2401, 2437, 2444, 2447, 2448, 2451, 2472, 2474, 2480, 2482, 2482, 2486, 2489, 2524, 2525, 2527, 2529, 2544, 2545, 2565, 2570, 2575, 2576, 2579, 2600, 2602, 2608, 2610, 2611, 2613, 2614, 2616, 2617, 2649, 2652, 2654, 2654, 2674, 2676, 2693, 2699, 2701, 2701, 2703, 2705, 2707, 2728, 2730, 2736, 2738, 2739, 2741, 2745, 2749, 2749, 2768, 2768, 2784, 2784, 2821, 2828, 2831, 2832, 2835, 2856, 2858, 2864, 2866, 2867, 2870, 2873, 2877, 2877, 2908, 2909, 2911, 2913, 2949, 2954, 2958, 2960, 2962, 2965, 2969, 2970, 2972, 2972, 2974, 2975, 2979, 2980, 2984, 2986, 2990, 2997, 2999, 3001, 3077, 3084, 3086, 3088, 3090, 3112, 3114, 3123, 3125, 3129, 3168, 3169, 3205, 3212, 3214, 3216, 3218, 3240, 3242, 3251, 3253, 3257, 3294, 3294, 3296, 3297, 3333, 3340, 3342, 3344, 3346, 3368, 3370, 3385, 3424, 3425, 3461, 3478, 3482, 3505, 3507, 3515, 3517, 3517, 3520, 3526, 3585, 3632, 3634, 3635, 3648, 3654, 3713, 3714, 3716, 3716, 3719, 3720, 3722, 3722, 3725, 3725, 3732, 3735, 3737, 3743, 3745, 3747, 3749, 3749, 3751, 3751, 3754, 3755, 3757, 3760, 3762, 3763, 3773, 3773, 3776, 3780, 3782, 3782, 3804, 3805, 3840, 3840, 3904, 3911, 3913, 3946, 3976, 3979, 4096, 4129, 4131, 4135, 4137, 4138, 4176, 4181, 4256, 4293, 4304, 4342, 4352, 4441, 4447, 4514, 4520, 4601, 4608, 4614, 4616, 4678, 4680, 4680, 4682, 4685, 4688, 4694, 4696, 4696, 4698, 4701, 4704, 4742, 4744, 4744, 4746, 4749, 4752, 4782, 4784, 4784, 4786, 4789, 4792, 4798, 4800, 4800, 4802, 4805, 4808, 4814, 4816, 4822, 4824, 4846, 4848, 4878, 4880, 4880, 4882, 4885, 4888, 4894, 4896, 4934, 4936, 4954, 5024, 5108, 5121, 5740, 5743, 5750, 5761, 5786, 5792, 5866, 6016, 6067, 6176, 6263, 6272, 6312, 7680, 7835, 7840, 7929, 7936, 7957, 7960, 7965, 7968, 8005, 8008, 8013, 8016, 8023, 8025, 8025, 8027, 8027, 8029, 8029, 8031, 8061, 8064, 8116, 8118, 8124, 8126, 8126, 8130, 8132, 8134, 8140, 8144, 8147, 8150, 8155, 8160, 8172, 8178, 8180, 8182, 8188, 8319, 8319, 8450, 8450, 8455, 8455, 8458, 8467, 8469, 8469, 8473, 8477, 8484, 8484, 8486, 8486, 8488, 8488, 8490, 8493, 8495, 8497, 8499, 8505, 8544, 8579, 12293, 12295, 12321, 12329, 12337, 12341, 12344, 12346, 12353, 12436, 12445, 12446, 12449, 12538, 12540, 12542, 12549, 12588, 12593, 12686, 12704, 12727, 13312, 19893, 19968, 40869, 40960, 42124, 44032, 55203, 63744, 64045, 64256, 64262, 64275, 64279, 64285, 64285, 64287, 64296, 64298, 64310, 64312, 64316, 64318, 64318, 64320, 64321, 64323, 64324, 64326, 64433, 64467, 64829, 64848, 64911, 64914, 64967, 65008, 65019, 65136, 65138, 65140, 65140, 65142, 65276, 65313, 65338, 65345, 65370, 65382, 65470, 65474, 65479, 65482, 65487, 65490, 65495, 65498, 65500,];
var unicodeES3IdentifierPart = [170, 170, 181, 181, 186, 186, 192, 214, 216, 246, 248, 543, 546, 563, 592, 685, 688, 696, 699, 705, 720, 721, 736, 740, 750, 750, 768, 846, 864, 866, 890, 890, 902, 902, 904, 906, 908, 908, 910, 929, 931, 974, 976, 983, 986, 1011, 1024, 1153, 1155, 1158, 1164, 1220, 1223, 1224, 1227, 1228, 1232, 1269, 1272, 1273, 1329, 1366, 1369, 1369, 1377, 1415, 1425, 1441, 1443, 1465, 1467, 1469, 1471, 1471, 1473, 1474, 1476, 1476, 1488, 1514, 1520, 1522, 1569, 1594, 1600, 1621, 1632, 1641, 1648, 1747, 1749, 1756, 1759, 1768, 1770, 1773, 1776, 1788, 1808, 1836, 1840, 1866, 1920, 1968, 2305, 2307, 2309, 2361, 2364, 2381, 2384, 2388, 2392, 2403, 2406, 2415, 2433, 2435, 2437, 2444, 2447, 2448, 2451, 2472, 2474, 2480, 2482, 2482, 2486, 2489, 2492, 2492, 2494, 2500, 2503, 2504, 2507, 2509, 2519, 2519, 2524, 2525, 2527, 2531, 2534, 2545, 2562, 2562, 2565, 2570, 2575, 2576, 2579, 2600, 2602, 2608, 2610, 2611, 2613, 2614, 2616, 2617, 2620, 2620, 2622, 2626, 2631, 2632, 2635, 2637, 2649, 2652, 2654, 2654, 2662, 2676, 2689, 2691, 2693, 2699, 2701, 2701, 2703, 2705, 2707, 2728, 2730, 2736, 2738, 2739, 2741, 2745, 2748, 2757, 2759, 2761, 2763, 2765, 2768, 2768, 2784, 2784, 2790, 2799, 2817, 2819, 2821, 2828, 2831, 2832, 2835, 2856, 2858, 2864, 2866, 2867, 2870, 2873, 2876, 2883, 2887, 2888, 2891, 2893, 2902, 2903, 2908, 2909, 2911, 2913, 2918, 2927, 2946, 2947, 2949, 2954, 2958, 2960, 2962, 2965, 2969, 2970, 2972, 2972, 2974, 2975, 2979, 2980, 2984, 2986, 2990, 2997, 2999, 3001, 3006, 3010, 3014, 3016, 3018, 3021, 3031, 3031, 3047, 3055, 3073, 3075, 3077, 3084, 3086, 3088, 3090, 3112, 3114, 3123, 3125, 3129, 3134, 3140, 3142, 3144, 3146, 3149, 3157, 3158, 3168, 3169, 3174, 3183, 3202, 3203, 3205, 3212, 3214, 3216, 3218, 3240, 3242, 3251, 3253, 3257, 3262, 3268, 3270, 3272, 3274, 3277, 3285, 3286, 3294, 3294, 3296, 3297, 3302, 3311, 3330, 3331, 3333, 3340, 3342, 3344, 3346, 3368, 3370, 3385, 3390, 3395, 3398, 3400, 3402, 3405, 3415, 3415, 3424, 3425, 3430, 3439, 3458, 3459, 3461, 3478, 3482, 3505, 3507, 3515, 3517, 3517, 3520, 3526, 3530, 3530, 3535, 3540, 3542, 3542, 3544, 3551, 3570, 3571, 3585, 3642, 3648, 3662, 3664, 3673, 3713, 3714, 3716, 3716, 3719, 3720, 3722, 3722, 3725, 3725, 3732, 3735, 3737, 3743, 3745, 3747, 3749, 3749, 3751, 3751, 3754, 3755, 3757, 3769, 3771, 3773, 3776, 3780, 3782, 3782, 3784, 3789, 3792, 3801, 3804, 3805, 3840, 3840, 3864, 3865, 3872, 3881, 3893, 3893, 3895, 3895, 3897, 3897, 3902, 3911, 3913, 3946, 3953, 3972, 3974, 3979, 3984, 3991, 3993, 4028, 4038, 4038, 4096, 4129, 4131, 4135, 4137, 4138, 4140, 4146, 4150, 4153, 4160, 4169, 4176, 4185, 4256, 4293, 4304, 4342, 4352, 4441, 4447, 4514, 4520, 4601, 4608, 4614, 4616, 4678, 4680, 4680, 4682, 4685, 4688, 4694, 4696, 4696, 4698, 4701, 4704, 4742, 4744, 4744, 4746, 4749, 4752, 4782, 4784, 4784, 4786, 4789, 4792, 4798, 4800, 4800, 4802, 4805, 4808, 4814, 4816, 4822, 4824, 4846, 4848, 4878, 4880, 4880, 4882, 4885, 4888, 4894, 4896, 4934, 4936, 4954, 4969, 4977, 5024, 5108, 5121, 5740, 5743, 5750, 5761, 5786, 5792, 5866, 6016, 6099, 6112, 6121, 6160, 6169, 6176, 6263, 6272, 6313, 7680, 7835, 7840, 7929, 7936, 7957, 7960, 7965, 7968, 8005, 8008, 8013, 8016, 8023, 8025, 8025, 8027, 8027, 8029, 8029, 8031, 8061, 8064, 8116, 8118, 8124, 8126, 8126, 8130, 8132, 8134, 8140, 8144, 8147, 8150, 8155, 8160, 8172, 8178, 8180, 8182, 8188, 8255, 8256, 8319, 8319, 8400, 8412, 8417, 8417, 8450, 8450, 8455, 8455, 8458, 8467, 8469, 8469, 8473, 8477, 8484, 8484, 8486, 8486, 8488, 8488, 8490, 8493, 8495, 8497, 8499, 8505, 8544, 8579, 12293, 12295, 12321, 12335, 12337, 12341, 12344, 12346, 12353, 12436, 12441, 12442, 12445, 12446, 12449, 12542, 12549, 12588, 12593, 12686, 12704, 12727, 13312, 19893, 19968, 40869, 40960, 42124, 44032, 55203, 63744, 64045, 64256, 64262, 64275, 64279, 64285, 64296, 64298, 64310, 64312, 64316, 64318, 64318, 64320, 64321, 64323, 64324, 64326, 64433, 64467, 64829, 64848, 64911, 64914, 64967, 65008, 65019, 65056, 65059, 65075, 65076, 65101, 65103, 65136, 65138, 65140, 65140, 65142, 65276, 65296, 65305, 65313, 65338, 65343, 65343, 65345, 65370, 65381, 65470, 65474, 65479, 65482, 65487, 65490, 65495, 65498, 65500,];
/*
As per ECMAScript Language Specification 5th Edition, Section 7.6: ISyntaxToken Names and Identifiers
IdentifierStart ::
Can contain Unicode 6.2 categories:
Uppercase letter (Lu),
Lowercase letter (Ll),
Titlecase letter (Lt),
Modifier letter (Lm),
Other letter (Lo), or
Letter number (Nl).
IdentifierPart ::
Can contain IdentifierStart + Unicode 6.2 categories:
Non-spacing mark (Mn),
Combining spacing mark (Mc),
Decimal number (Nd),
Connector punctuation (Pc),
<ZWNJ>, or
<ZWJ>.
Codepoint ranges for ES5 Identifiers are extracted from the Unicode 6.2 specification at:
http://www.unicode.org/Public/6.2.0/ucd/UnicodeData.txt
*/
var unicodeES5IdentifierStart = [170, 170, 181, 181, 186, 186, 192, 214, 216, 246, 248, 705, 710, 721, 736, 740, 748, 748, 750, 750, 880, 884, 886, 887, 890, 893, 902, 902, 904, 906, 908, 908, 910, 929, 931, 1013, 1015, 1153, 1162, 1319, 1329, 1366, 1369, 1369, 1377, 1415, 1488, 1514, 1520, 1522, 1568, 1610, 1646, 1647, 1649, 1747, 1749, 1749, 1765, 1766, 1774, 1775, 1786, 1788, 1791, 1791, 1808, 1808, 1810, 1839, 1869, 1957, 1969, 1969, 1994, 2026, 2036, 2037, 2042, 2042, 2048, 2069, 2074, 2074, 2084, 2084, 2088, 2088, 2112, 2136, 2208, 2208, 2210, 2220, 2308, 2361, 2365, 2365, 2384, 2384, 2392, 2401, 2417, 2423, 2425, 2431, 2437, 2444, 2447, 2448, 2451, 2472, 2474, 2480, 2482, 2482, 2486, 2489, 2493, 2493, 2510, 2510, 2524, 2525, 2527, 2529, 2544, 2545, 2565, 2570, 2575, 2576, 2579, 2600, 2602, 2608, 2610, 2611, 2613, 2614, 2616, 2617, 2649, 2652, 2654, 2654, 2674, 2676, 2693, 2701, 2703, 2705, 2707, 2728, 2730, 2736, 2738, 2739, 2741, 2745, 2749, 2749, 2768, 2768, 2784, 2785, 2821, 2828, 2831, 2832, 2835, 2856, 2858, 2864, 2866, 2867, 2869, 2873, 2877, 2877, 2908, 2909, 2911, 2913, 2929, 2929, 2947, 2947, 2949, 2954, 2958, 2960, 2962, 2965, 2969, 2970, 2972, 2972, 2974, 2975, 2979, 2980, 2984, 2986, 2990, 3001, 3024, 3024, 3077, 3084, 3086, 3088, 3090, 3112, 3114, 3123, 3125, 3129, 3133, 3133, 3160, 3161, 3168, 3169, 3205, 3212, 3214, 3216, 3218, 3240, 3242, 3251, 3253, 3257, 3261, 3261, 3294, 3294, 3296, 3297, 3313, 3314, 3333, 3340, 3342, 3344, 3346, 3386, 3389, 3389, 3406, 3406, 3424, 3425, 3450, 3455, 3461, 3478, 3482, 3505, 3507, 3515, 3517, 3517, 3520, 3526, 3585, 3632, 3634, 3635, 3648, 3654, 3713, 3714, 3716, 3716, 3719, 3720, 3722, 3722, 3725, 3725, 3732, 3735, 3737, 3743, 3745, 3747, 3749, 3749, 3751, 3751, 3754, 3755, 3757, 3760, 3762, 3763, 3773, 3773, 3776, 3780, 3782, 3782, 3804, 3807, 3840, 3840, 3904, 3911, 3913, 3948, 3976, 3980, 4096, 4138, 4159, 4159, 4176, 4181, 4186, 4189, 4193, 4193, 4197, 4198, 4206, 4208, 4213, 4225, 4238, 4238, 4256, 4293, 4295, 4295, 4301, 4301, 4304, 4346, 4348, 4680, 4682, 4685, 4688, 4694, 4696, 4696, 4698, 4701, 4704, 4744, 4746, 4749, 4752, 4784, 4786, 4789, 4792, 4798, 4800, 4800, 4802, 4805, 4808, 4822, 4824, 4880, 4882, 4885, 4888, 4954, 4992, 5007, 5024, 5108, 5121, 5740, 5743, 5759, 5761, 5786, 5792, 5866, 5870, 5872, 5888, 5900, 5902, 5905, 5920, 5937, 5952, 5969, 5984, 5996, 5998, 6000, 6016, 6067, 6103, 6103, 6108, 6108, 6176, 6263, 6272, 6312, 6314, 6314, 6320, 6389, 6400, 6428, 6480, 6509, 6512, 6516, 6528, 6571, 6593, 6599, 6656, 6678, 6688, 6740, 6823, 6823, 6917, 6963, 6981, 6987, 7043, 7072, 7086, 7087, 7098, 7141, 7168, 7203, 7245, 7247, 7258, 7293, 7401, 7404, 7406, 7409, 7413, 7414, 7424, 7615, 7680, 7957, 7960, 7965, 7968, 8005, 8008, 8013, 8016, 8023, 8025, 8025, 8027, 8027, 8029, 8029, 8031, 8061, 8064, 8116, 8118, 8124, 8126, 8126, 8130, 8132, 8134, 8140, 8144, 8147, 8150, 8155, 8160, 8172, 8178, 8180, 8182, 8188, 8305, 8305, 8319, 8319, 8336, 8348, 8450, 8450, 8455, 8455, 8458, 8467, 8469, 8469, 8473, 8477, 8484, 8484, 8486, 8486, 8488, 8488, 8490, 8493, 8495, 8505, 8508, 8511, 8517, 8521, 8526, 8526, 8544, 8584, 11264, 11310, 11312, 11358, 11360, 11492, 11499, 11502, 11506, 11507, 11520, 11557, 11559, 11559, 11565, 11565, 11568, 11623, 11631, 11631, 11648, 11670, 11680, 11686, 11688, 11694, 11696, 11702, 11704, 11710, 11712, 11718, 11720, 11726, 11728, 11734, 11736, 11742, 11823, 11823, 12293, 12295, 12321, 12329, 12337, 12341, 12344, 12348, 12353, 12438, 12445, 12447, 12449, 12538, 12540, 12543, 12549, 12589, 12593, 12686, 12704, 12730, 12784, 12799, 13312, 19893, 19968, 40908, 40960, 42124, 42192, 42237, 42240, 42508, 42512, 42527, 42538, 42539, 42560, 42606, 42623, 42647, 42656, 42735, 42775, 42783, 42786, 42888, 42891, 42894, 42896, 42899, 42912, 42922, 43000, 43009, 43011, 43013, 43015, 43018, 43020, 43042, 43072, 43123, 43138, 43187, 43250, 43255, 43259, 43259, 43274, 43301, 43312, 43334, 43360, 43388, 43396, 43442, 43471, 43471, 43520, 43560, 43584, 43586, 43588, 43595, 43616, 43638, 43642, 43642, 43648, 43695, 43697, 43697, 43701, 43702, 43705, 43709, 43712, 43712, 43714, 43714, 43739, 43741, 43744, 43754, 43762, 43764, 43777, 43782, 43785, 43790, 43793, 43798, 43808, 43814, 43816, 43822, 43968, 44002, 44032, 55203, 55216, 55238, 55243, 55291, 63744, 64109, 64112, 64217, 64256, 64262, 64275, 64279, 64285, 64285, 64287, 64296, 64298, 64310, 64312, 64316, 64318, 64318, 64320, 64321, 64323, 64324, 64326, 64433, 64467, 64829, 64848, 64911, 64914, 64967, 65008, 65019, 65136, 65140, 65142, 65276, 65313, 65338, 65345, 65370, 65382, 65470, 65474, 65479, 65482, 65487, 65490, 65495, 65498, 65500,];
var unicodeES5IdentifierPart = [170, 170, 181, 181, 186, 186, 192, 214, 216, 246, 248, 705, 710, 721, 736, 740, 748, 748, 750, 750, 768, 884, 886, 887, 890, 893, 902, 902, 904, 906, 908, 908, 910, 929, 931, 1013, 1015, 1153, 1155, 1159, 1162, 1319, 1329, 1366, 1369, 1369, 1377, 1415, 1425, 1469, 1471, 1471, 1473, 1474, 1476, 1477, 1479, 1479, 1488, 1514, 1520, 1522, 1552, 1562, 1568, 1641, 1646, 1747, 1749, 1756, 1759, 1768, 1770, 1788, 1791, 1791, 1808, 1866, 1869, 1969, 1984, 2037, 2042, 2042, 2048, 2093, 2112, 2139, 2208, 2208, 2210, 2220, 2276, 2302, 2304, 2403, 2406, 2415, 2417, 2423, 2425, 2431, 2433, 2435, 2437, 2444, 2447, 2448, 2451, 2472, 2474, 2480, 2482, 2482, 2486, 2489, 2492, 2500, 2503, 2504, 2507, 2510, 2519, 2519, 2524, 2525, 2527, 2531, 2534, 2545, 2561, 2563, 2565, 2570, 2575, 2576, 2579, 2600, 2602, 2608, 2610, 2611, 2613, 2614, 2616, 2617, 2620, 2620, 2622, 2626, 2631, 2632, 2635, 2637, 2641, 2641, 2649, 2652, 2654, 2654, 2662, 2677, 2689, 2691, 2693, 2701, 2703, 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3515, 3517, 3517, 3520, 3526, 3530, 3530, 3535, 3540, 3542, 3542, 3544, 3551, 3570, 3571, 3585, 3642, 3648, 3662, 3664, 3673, 3713, 3714, 3716, 3716, 3719, 3720, 3722, 3722, 3725, 3725, 3732, 3735, 3737, 3743, 3745, 3747, 3749, 3749, 3751, 3751, 3754, 3755, 3757, 3769, 3771, 3773, 3776, 3780, 3782, 3782, 3784, 3789, 3792, 3801, 3804, 3807, 3840, 3840, 3864, 3865, 3872, 3881, 3893, 3893, 3895, 3895, 3897, 3897, 3902, 3911, 3913, 3948, 3953, 3972, 3974, 3991, 3993, 4028, 4038, 4038, 4096, 4169, 4176, 4253, 4256, 4293, 4295, 4295, 4301, 4301, 4304, 4346, 4348, 4680, 4682, 4685, 4688, 4694, 4696, 4696, 4698, 4701, 4704, 4744, 4746, 4749, 4752, 4784, 4786, 4789, 4792, 4798, 4800, 4800, 4802, 4805, 4808, 4822, 4824, 4880, 4882, 4885, 4888, 4954, 4957, 4959, 4992, 5007, 5024, 5108, 5121, 5740, 5743, 5759, 5761, 5786, 5792, 5866, 5870, 5872, 5888, 5900, 5902, 5908, 5920, 5940, 5952, 5971, 5984, 5996, 5998, 6000, 6002, 6003, 6016, 6099, 6103, 6103, 6108, 6109, 6112, 6121, 6155, 6157, 6160, 6169, 6176, 6263, 6272, 6314, 6320, 6389, 6400, 6428, 6432, 6443, 6448, 6459, 6470, 6509, 6512, 6516, 6528, 6571, 6576, 6601, 6608, 6617, 6656, 6683, 6688, 6750, 6752, 6780, 6783, 6793, 6800, 6809, 6823, 6823, 6912, 6987, 6992, 7001, 7019, 7027, 7040, 7155, 7168, 7223, 7232, 7241, 7245, 7293, 7376, 7378, 7380, 7414, 7424, 7654, 7676, 7957, 7960, 7965, 7968, 8005, 8008, 8013, 8016, 8023, 8025, 8025, 8027, 8027, 8029, 8029, 8031, 8061, 8064, 8116, 8118, 8124, 8126, 8126, 8130, 8132, 8134, 8140, 8144, 8147, 8150, 8155, 8160, 8172, 8178, 8180, 8182, 8188, 8204, 8205, 8255, 8256, 8276, 8276, 8305, 8305, 8319, 8319, 8336, 8348, 8400, 8412, 8417, 8417, 8421, 8432, 8450, 8450, 8455, 8455, 8458, 8467, 8469, 8469, 8473, 8477, 8484, 8484, 8486, 8486, 8488, 8488, 8490, 8493, 8495, 8505, 8508, 8511, 8517, 8521, 8526, 8526, 8544, 8584, 11264, 11310, 11312, 11358, 11360, 11492, 11499, 11507, 11520, 11557, 11559, 11559, 11565, 11565, 11568, 11623, 11631, 11631, 11647, 11670, 11680, 11686, 11688, 11694, 11696, 11702, 11704, 11710, 11712, 11718, 11720, 11726, 11728, 11734, 11736, 11742, 11744, 11775, 11823, 11823, 12293, 12295, 12321, 12335, 12337, 12341, 12344, 12348, 12353, 12438, 12441, 12442, 12445, 12447, 12449, 12538, 12540, 12543, 12549, 12589, 12593, 12686, 12704, 12730, 12784, 12799, 13312, 19893, 19968, 40908, 40960, 42124, 42192, 42237, 42240, 42508, 42512, 42539, 42560, 42607, 42612, 42621, 42623, 42647, 42655, 42737, 42775, 42783, 42786, 42888, 42891, 42894, 42896, 42899, 42912, 42922, 43000, 43047, 43072, 43123, 43136, 43204, 43216, 43225, 43232, 43255, 43259, 43259, 43264, 43309, 43312, 43347, 43360, 43388, 43392, 43456, 43471, 43481, 43520, 43574, 43584, 43597, 43600, 43609, 43616, 43638, 43642, 43643, 43648, 43714, 43739, 43741, 43744, 43759, 43762, 43766, 43777, 43782, 43785, 43790, 43793, 43798, 43808, 43814, 43816, 43822, 43968, 44010, 44012, 44013, 44016, 44025, 44032, 55203, 55216, 55238, 55243, 55291, 63744, 64109, 64112, 64217, 64256, 64262, 64275, 64279, 64285, 64296, 64298, 64310, 64312, 64316, 64318, 64318, 64320, 64321, 64323, 64324, 64326, 64433, 64467, 64829, 64848, 64911, 64914, 64967, 65008, 65019, 65024, 65039, 65056, 65062, 65075, 65076, 65101, 65103, 65136, 65140, 65142, 65276, 65296, 65305, 65313, 65338, 65343, 65343, 65345, 65370, 65382, 65470, 65474, 65479, 65482, 65487, 65490, 65495, 65498, 65500,];
function lookupInUnicodeMap(code, map) {
// Bail out quickly if it couldn't possibly be in the map.
if (code < map[0]) {
return false;
}
// Perform binary search in one of the Unicode range maps
var lo = 0;
var hi = map.length;
var mid;
while (lo + 1 < hi) {
mid = lo + (hi - lo) / 2;
// mid has to be even to catch a range's beginning
mid -= mid % 2;
if (map[mid] <= code && code <= map[mid + 1]) {
return true;
}
if (code < map[mid]) {
hi = mid;
}
else {
lo = mid + 2;
}
}
return false;
}
/* @internal */ function isUnicodeIdentifierStart(code, languageVersion) {
return languageVersion >= 1 /* ES5 */ ?
lookupInUnicodeMap(code, unicodeES5IdentifierStart) :
lookupInUnicodeMap(code, unicodeES3IdentifierStart);
}
ts.isUnicodeIdentifierStart = isUnicodeIdentifierStart;
function isUnicodeIdentifierPart(code, languageVersion) {
return languageVersion >= 1 /* ES5 */ ?
lookupInUnicodeMap(code, unicodeES5IdentifierPart) :
lookupInUnicodeMap(code, unicodeES3IdentifierPart);
}
function makeReverseMap(source) {
var result = [];
for (var name_4 in source) {
result[source[name_4]] = name_4;
}
return result;
}
var tokenStrings = makeReverseMap(textToToken);
function tokenToString(t) {
return tokenStrings[t];
}
ts.tokenToString = tokenToString;
/* @internal */
function stringToToken(s) {
return textToToken[s];
}
ts.stringToToken = stringToToken;
/* @internal */
function computeLineStarts(text) {
var result = new Array();
var pos = 0;
var lineStart = 0;
while (pos < text.length) {
var ch = text.charCodeAt(pos);
pos++;
switch (ch) {
case 13 /* carriageReturn */:
if (text.charCodeAt(pos) === 10 /* lineFeed */) {
pos++;
}
case 10 /* lineFeed */:
result.push(lineStart);
lineStart = pos;
break;
default:
if (ch > 127 /* maxAsciiCharacter */ && isLineBreak(ch)) {
result.push(lineStart);
lineStart = pos;
}
break;
}
}
result.push(lineStart);
return result;
}
ts.computeLineStarts = computeLineStarts;
function getPositionOfLineAndCharacter(sourceFile, line, character) {
return computePositionOfLineAndCharacter(getLineStarts(sourceFile), line, character);
}
ts.getPositionOfLineAndCharacter = getPositionOfLineAndCharacter;
/* @internal */
function computePositionOfLineAndCharacter(lineStarts, line, character) {
ts.Debug.assert(line >= 0 && line < lineStarts.length);
return lineStarts[line] + character;
}
ts.computePositionOfLineAndCharacter = computePositionOfLineAndCharacter;
/* @internal */
function getLineStarts(sourceFile) {
return sourceFile.lineMap || (sourceFile.lineMap = computeLineStarts(sourceFile.text));
}
ts.getLineStarts = getLineStarts;
/* @internal */
/**
* We assume the first line starts at position 0 and 'position' is non-negative.
*/
function computeLineAndCharacterOfPosition(lineStarts, position) {
var lineNumber = ts.binarySearch(lineStarts, position);
if (lineNumber < 0) {
// If the actual position was not found,
// the binary search returns the 2's-complement of the next line start
// e.g. if the line starts at [5, 10, 23, 80] and the position requested was 20
// then the search will return -2.
//
// We want the index of the previous line start, so we subtract 1.
// Review 2's-complement if this is confusing.
lineNumber = ~lineNumber - 1;
ts.Debug.assert(lineNumber !== -1, "position cannot precede the beginning of the file");
}
return {
line: lineNumber,
character: position - lineStarts[lineNumber]
};
}
ts.computeLineAndCharacterOfPosition = computeLineAndCharacterOfPosition;
function getLineAndCharacterOfPosition(sourceFile, position) {
return computeLineAndCharacterOfPosition(getLineStarts(sourceFile), position);
}
ts.getLineAndCharacterOfPosition = getLineAndCharacterOfPosition;
var hasOwnProperty = Object.prototype.hasOwnProperty;
function isWhiteSpace(ch) {
return isWhiteSpaceSingleLine(ch) || isLineBreak(ch);
}
ts.isWhiteSpace = isWhiteSpace;
/** Does not include line breaks. For that, see isWhiteSpaceLike. */
function isWhiteSpaceSingleLine(ch) {
// Note: nextLine is in the Zs space, and should be considered to be a whitespace.
// It is explicitly not a line-break as it isn't in the exact set specified by EcmaScript.
return ch === 32 /* space */ ||
ch === 9 /* tab */ ||
ch === 11 /* verticalTab */ ||
ch === 12 /* formFeed */ ||
ch === 160 /* nonBreakingSpace */ ||
ch === 133 /* nextLine */ ||
ch === 5760 /* ogham */ ||
ch >= 8192 /* enQuad */ && ch <= 8203 /* zeroWidthSpace */ ||
ch === 8239 /* narrowNoBreakSpace */ ||
ch === 8287 /* mathematicalSpace */ ||
ch === 12288 /* ideographicSpace */ ||
ch === 65279 /* byteOrderMark */;
}
ts.isWhiteSpaceSingleLine = isWhiteSpaceSingleLine;
function isLineBreak(ch) {
// ES5 7.3:
// The ECMAScript line terminator characters are listed in Table 3.
// Table 3: Line Terminator Characters
// Code Unit Value Name Formal Name
// \u000A Line Feed <LF>
// \u000D Carriage Return <CR>
// \u2028 Line separator <LS>
// \u2029 Paragraph separator <PS>
// Only the characters in Table 3 are treated as line terminators. Other new line or line
// breaking characters are treated as white space but not as line terminators.
return ch === 10 /* lineFeed */ ||
ch === 13 /* carriageReturn */ ||
ch === 8232 /* lineSeparator */ ||
ch === 8233 /* paragraphSeparator */;
}
ts.isLineBreak = isLineBreak;
function isDigit(ch) {
return ch >= 48 /* _0 */ && ch <= 57 /* _9 */;
}
/* @internal */
function isOctalDigit(ch) {
return ch >= 48 /* _0 */ && ch <= 55 /* _7 */;
}
ts.isOctalDigit = isOctalDigit;
function couldStartTrivia(text, pos) {
// Keep in sync with skipTrivia
var ch = text.charCodeAt(pos);
switch (ch) {
case 13 /* carriageReturn */:
case 10 /* lineFeed */:
case 9 /* tab */:
case 11 /* verticalTab */:
case 12 /* formFeed */:
case 32 /* space */:
case 47 /* slash */:
// starts of normal trivia
case 60 /* lessThan */:
case 61 /* equals */:
case 62 /* greaterThan */:
// Starts of conflict marker trivia
return true;
case 35 /* hash */:
// Only if its the beginning can we have #! trivia
return pos === 0;
default:
return ch > 127 /* maxAsciiCharacter */;
}
}
ts.couldStartTrivia = couldStartTrivia;
/* @internal */
function skipTrivia(text, pos, stopAfterLineBreak, stopAtComments) {
if (stopAtComments === void 0) { stopAtComments = false; }
if (ts.positionIsSynthesized(pos)) {
return pos;
}
// Keep in sync with couldStartTrivia
while (true) {
var ch = text.charCodeAt(pos);
switch (ch) {
case 13 /* carriageReturn */:
if (text.charCodeAt(pos + 1) === 10 /* lineFeed */) {
pos++;
}
case 10 /* lineFeed */:
pos++;
if (stopAfterLineBreak) {
return pos;
}
continue;
case 9 /* tab */:
case 11 /* verticalTab */:
case 12 /* formFeed */:
case 32 /* space */:
pos++;
continue;
case 47 /* slash */:
if (stopAtComments) {
break;
}
if (text.charCodeAt(pos + 1) === 47 /* slash */) {
pos += 2;
while (pos < text.length) {
if (isLineBreak(text.charCodeAt(pos))) {
break;
}
pos++;
}
continue;
}
if (text.charCodeAt(pos + 1) === 42 /* asterisk */) {
pos += 2;
while (pos < text.length) {
if (text.charCodeAt(pos) === 42 /* asterisk */ && text.charCodeAt(pos + 1) === 47 /* slash */) {
pos += 2;
break;
}
pos++;
}
continue;
}
break;
case 60 /* lessThan */:
case 61 /* equals */:
case 62 /* greaterThan */:
if (isConflictMarkerTrivia(text, pos)) {
pos = scanConflictMarkerTrivia(text, pos);
continue;
}
break;
case 35 /* hash */:
if (pos === 0 && isShebangTrivia(text, pos)) {
pos = scanShebangTrivia(text, pos);
continue;
}
break;
default:
if (ch > 127 /* maxAsciiCharacter */ && (isWhiteSpace(ch))) {
pos++;
continue;
}
break;
}
return pos;
}
}
ts.skipTrivia = skipTrivia;
// All conflict markers consist of the same character repeated seven times. If it is
// a <<<<<<< or >>>>>>> marker then it is also followed by a space.
var mergeConflictMarkerLength = "<<<<<<<".length;
function isConflictMarkerTrivia(text, pos) {
ts.Debug.assert(pos >= 0);
// Conflict markers must be at the start of a line.
if (pos === 0 || isLineBreak(text.charCodeAt(pos - 1))) {
var ch = text.charCodeAt(pos);
if ((pos + mergeConflictMarkerLength) < text.length) {
for (var i = 0, n = mergeConflictMarkerLength; i < n; i++) {
if (text.charCodeAt(pos + i) !== ch) {
return false;
}
}
return ch === 61 /* equals */ ||
text.charCodeAt(pos + mergeConflictMarkerLength) === 32 /* space */;
}
}
return false;
}
function scanConflictMarkerTrivia(text, pos, error) {
if (error) {
error(ts.Diagnostics.Merge_conflict_marker_encountered, mergeConflictMarkerLength);
}
var ch = text.charCodeAt(pos);
var len = text.length;
if (ch === 60 /* lessThan */ || ch === 62 /* greaterThan */) {
while (pos < len && !isLineBreak(text.charCodeAt(pos))) {
pos++;
}
}
else {
ts.Debug.assert(ch === 61 /* equals */);
// Consume everything from the start of the mid-conflict marker to the start of the next
// end-conflict marker.
while (pos < len) {
var ch_1 = text.charCodeAt(pos);
if (ch_1 === 62 /* greaterThan */ && isConflictMarkerTrivia(text, pos)) {
break;
}
pos++;
}
}
return pos;
}
var shebangTriviaRegex = /^#!.*/;
function isShebangTrivia(text, pos) {
// Shebangs check must only be done at the start of the file
ts.Debug.assert(pos === 0);
return shebangTriviaRegex.test(text);
}
function scanShebangTrivia(text, pos) {
var shebang = shebangTriviaRegex.exec(text)[0];
pos = pos + shebang.length;
return pos;
}
/**
* Invokes a callback for each comment range following the provided position.
*
* Single-line comment ranges include the leading double-slash characters but not the ending
* line break. Multi-line comment ranges include the leading slash-asterisk and trailing
* asterisk-slash characters.
*
* @param reduce If true, accumulates the result of calling the callback in a fashion similar
* to reduceLeft. If false, iteration stops when the callback returns a truthy value.
* @param text The source text to scan.
* @param pos The position at which to start scanning.
* @param trailing If false, whitespace is skipped until the first line break and comments
* between that location and the next token are returned. If true, comments occurring
* between the given position and the next line break are returned.
* @param cb The callback to execute as each comment range is encountered.
* @param state A state value to pass to each iteration of the callback.
* @param initial An initial value to pass when accumulating results (when "reduce" is true).
* @returns If "reduce" is true, the accumulated value. If "reduce" is false, the first truthy
* return value of the callback.
*/
function iterateCommentRanges(reduce, text, pos, trailing, cb, state, initial) {
var pendingPos;
var pendingEnd;
var pendingKind;
var pendingHasTrailingNewLine;
var hasPendingCommentRange = false;
var collecting = trailing || pos === 0;
var accumulator = initial;
scan: while (pos >= 0 && pos < text.length) {
var ch = text.charCodeAt(pos);
switch (ch) {
case 13 /* carriageReturn */:
if (text.charCodeAt(pos + 1) === 10 /* lineFeed */) {
pos++;
}
case 10 /* lineFeed */:
pos++;
if (trailing) {
break scan;
}
collecting = true;
if (hasPendingCommentRange) {
pendingHasTrailingNewLine = true;
}
continue;
case 9 /* tab */:
case 11 /* verticalTab */:
case 12 /* formFeed */:
case 32 /* space */:
pos++;
continue;
case 47 /* slash */:
var nextChar = text.charCodeAt(pos + 1);
var hasTrailingNewLine = false;
if (nextChar === 47 /* slash */ || nextChar === 42 /* asterisk */) {
var kind = nextChar === 47 /* slash */ ? 2 /* SingleLineCommentTrivia */ : 3 /* MultiLineCommentTrivia */;
var startPos = pos;
pos += 2;
if (nextChar === 47 /* slash */) {
while (pos < text.length) {
if (isLineBreak(text.charCodeAt(pos))) {
hasTrailingNewLine = true;
break;
}
pos++;
}
}
else {
while (pos < text.length) {
if (text.charCodeAt(pos) === 42 /* asterisk */ && text.charCodeAt(pos + 1) === 47 /* slash */) {
pos += 2;
break;
}
pos++;
}
}
if (collecting) {
if (hasPendingCommentRange) {
accumulator = cb(pendingPos, pendingEnd, pendingKind, pendingHasTrailingNewLine, state, accumulator);
if (!reduce && accumulator) {
// If we are not reducing and we have a truthy result, return it.
return accumulator;
}
hasPendingCommentRange = false;
}
pendingPos = startPos;
pendingEnd = pos;
pendingKind = kind;
pendingHasTrailingNewLine = hasTrailingNewLine;
hasPendingCommentRange = true;
}
continue;
}
break scan;
default:
if (ch > 127 /* maxAsciiCharacter */ && (isWhiteSpace(ch))) {
if (hasPendingCommentRange && isLineBreak(ch)) {
pendingHasTrailingNewLine = true;
}
pos++;
continue;
}
break scan;
}
}
if (hasPendingCommentRange) {
accumulator = cb(pendingPos, pendingEnd, pendingKind, pendingHasTrailingNewLine, state, accumulator);
}
return accumulator;
}
function forEachLeadingCommentRange(text, pos, cb, state) {
return iterateCommentRanges(/*reduce*/ false, text, pos, /*trailing*/ false, cb, state);
}
ts.forEachLeadingCommentRange = forEachLeadingCommentRange;
function forEachTrailingCommentRange(text, pos, cb, state) {
return iterateCommentRanges(/*reduce*/ false, text, pos, /*trailing*/ true, cb, state);
}
ts.forEachTrailingCommentRange = forEachTrailingCommentRange;
function reduceEachLeadingCommentRange(text, pos, cb, state, initial) {
return iterateCommentRanges(/*reduce*/ true, text, pos, /*trailing*/ false, cb, state, initial);
}
ts.reduceEachLeadingCommentRange = reduceEachLeadingCommentRange;
function reduceEachTrailingCommentRange(text, pos, cb, state, initial) {
return iterateCommentRanges(/*reduce*/ true, text, pos, /*trailing*/ true, cb, state, initial);
}
ts.reduceEachTrailingCommentRange = reduceEachTrailingCommentRange;
function appendCommentRange(pos, end, kind, hasTrailingNewLine, _state, comments) {
if (!comments) {
comments = [];
}
comments.push({ pos: pos, end: end, hasTrailingNewLine: hasTrailingNewLine, kind: kind });
return comments;
}
function getLeadingCommentRanges(text, pos) {
return reduceEachLeadingCommentRange(text, pos, appendCommentRange, undefined, undefined);
}
ts.getLeadingCommentRanges = getLeadingCommentRanges;
function getTrailingCommentRanges(text, pos) {
return reduceEachTrailingCommentRange(text, pos, appendCommentRange, undefined, undefined);
}
ts.getTrailingCommentRanges = getTrailingCommentRanges;
/** Optionally, get the shebang */
function getShebang(text) {
return shebangTriviaRegex.test(text)
? shebangTriviaRegex.exec(text)[0]
: undefined;
}
ts.getShebang = getShebang;
function isIdentifierStart(ch, languageVersion) {
return ch >= 65 /* A */ && ch <= 90 /* Z */ || ch >= 97 /* a */ && ch <= 122 /* z */ ||
ch === 36 /* $ */ || ch === 95 /* _ */ ||
ch > 127 /* maxAsciiCharacter */ && isUnicodeIdentifierStart(ch, languageVersion);
}
ts.isIdentifierStart = isIdentifierStart;
function isIdentifierPart(ch, languageVersion) {
return ch >= 65 /* A */ && ch <= 90 /* Z */ || ch >= 97 /* a */ && ch <= 122 /* z */ ||
ch >= 48 /* _0 */ && ch <= 57 /* _9 */ || ch === 36 /* $ */ || ch === 95 /* _ */ ||
ch > 127 /* maxAsciiCharacter */ && isUnicodeIdentifierPart(ch, languageVersion);
}
ts.isIdentifierPart = isIdentifierPart;
/* @internal */
function isIdentifierText(name, languageVersion) {
if (!isIdentifierStart(name.charCodeAt(0), languageVersion)) {
return false;
}
for (var i = 1, n = name.length; i < n; i++) {
if (!isIdentifierPart(name.charCodeAt(i), languageVersion)) {
return false;
}
}
return true;
}
ts.isIdentifierText = isIdentifierText;
// Creates a scanner over a (possibly unspecified) range of a piece of text.
function createScanner(languageVersion, skipTrivia, languageVariant, text, onError, start, length) {
if (languageVariant === void 0) { languageVariant = 0 /* Standard */; }
// Current position (end position of text of current token)
var pos;
// end of text
var end;
// Start position of whitespace before current token
var startPos;
// Start position of text of current token
var tokenPos;
var token;
var tokenValue;
var precedingLineBreak;
var hasExtendedUnicodeEscape;
var tokenIsUnterminated;
setText(text, start, length);
return {
getStartPos: function () { return startPos; },
getTextPos: function () { return pos; },
getToken: function () { return token; },
getTokenPos: function () { return tokenPos; },
getTokenText: function () { return text.substring(tokenPos, pos); },
getTokenValue: function () { return tokenValue; },
hasExtendedUnicodeEscape: function () { return hasExtendedUnicodeEscape; },
hasPrecedingLineBreak: function () { return precedingLineBreak; },
isIdentifier: function () { return token === 70 /* Identifier */ || token > 106 /* LastReservedWord */; },
isReservedWord: function () { return token >= 71 /* FirstReservedWord */ && token <= 106 /* LastReservedWord */; },
isUnterminated: function () { return tokenIsUnterminated; },
reScanGreaterToken: reScanGreaterToken,
reScanSlashToken: reScanSlashToken,
reScanTemplateToken: reScanTemplateToken,
scanJsxIdentifier: scanJsxIdentifier,
scanJsxAttributeValue: scanJsxAttributeValue,
reScanJsxToken: reScanJsxToken,
scanJsxToken: scanJsxToken,
scanJSDocToken: scanJSDocToken,
scan: scan,
getText: getText,
setText: setText,
setScriptTarget: setScriptTarget,
setLanguageVariant: setLanguageVariant,
setOnError: setOnError,
setTextPos: setTextPos,
tryScan: tryScan,
lookAhead: lookAhead,
scanRange: scanRange,
};
function error(message, length) {
if (onError) {
onError(message, length || 0);
}
}
function scanNumber() {
var start = pos;
while (isDigit(text.charCodeAt(pos)))
pos++;
if (text.charCodeAt(pos) === 46 /* dot */) {
pos++;
while (isDigit(text.charCodeAt(pos)))
pos++;
}
var end = pos;
if (text.charCodeAt(pos) === 69 /* E */ || text.charCodeAt(pos) === 101 /* e */) {
pos++;
if (text.charCodeAt(pos) === 43 /* plus */ || text.charCodeAt(pos) === 45 /* minus */)
pos++;
if (isDigit(text.charCodeAt(pos))) {
pos++;
while (isDigit(text.charCodeAt(pos)))
pos++;
end = pos;
}
else {
error(ts.Diagnostics.Digit_expected);
}
}
return "" + +(text.substring(start, end));
}
function scanOctalDigits() {
var start = pos;
while (isOctalDigit(text.charCodeAt(pos))) {
pos++;
}
return +(text.substring(start, pos));
}
/**
* Scans the given number of hexadecimal digits in the text,
* returning -1 if the given number is unavailable.
*/
function scanExactNumberOfHexDigits(count) {
return scanHexDigits(/*minCount*/ count, /*scanAsManyAsPossible*/ false);
}
/**
* Scans as many hexadecimal digits as are available in the text,
* returning -1 if the given number of digits was unavailable.
*/
function scanMinimumNumberOfHexDigits(count) {
return scanHexDigits(/*minCount*/ count, /*scanAsManyAsPossible*/ true);
}
function scanHexDigits(minCount, scanAsManyAsPossible) {
var digits = 0;
var value = 0;
while (digits < minCount || scanAsManyAsPossible) {
var ch = text.charCodeAt(pos);
if (ch >= 48 /* _0 */ && ch <= 57 /* _9 */) {
value = value * 16 + ch - 48 /* _0 */;
}
else if (ch >= 65 /* A */ && ch <= 70 /* F */) {
value = value * 16 + ch - 65 /* A */ + 10;
}
else if (ch >= 97 /* a */ && ch <= 102 /* f */) {
value = value * 16 + ch - 97 /* a */ + 10;
}
else {
break;
}
pos++;
digits++;
}
if (digits < minCount) {
value = -1;
}
return value;
}
function scanString(allowEscapes) {
if (allowEscapes === void 0) { allowEscapes = true; }
var quote = text.charCodeAt(pos);
pos++;
var result = "";
var start = pos;
while (true) {
if (pos >= end) {
result += text.substring(start, pos);
tokenIsUnterminated = true;
error(ts.Diagnostics.Unterminated_string_literal);
break;
}
var ch = text.charCodeAt(pos);
if (ch === quote) {
result += text.substring(start, pos);
pos++;
break;
}
if (ch === 92 /* backslash */ && allowEscapes) {
result += text.substring(start, pos);
result += scanEscapeSequence();
start = pos;
continue;
}
if (isLineBreak(ch)) {
result += text.substring(start, pos);
tokenIsUnterminated = true;
error(ts.Diagnostics.Unterminated_string_literal);
break;
}
pos++;
}
return result;
}
/**
* Sets the current 'tokenValue' and returns a NoSubstitutionTemplateLiteral or
* a literal component of a TemplateExpression.
*/
function scanTemplateAndSetTokenValue() {
var startedWithBacktick = text.charCodeAt(pos) === 96 /* backtick */;
pos++;
var start = pos;
var contents = "";
var resultingToken;
while (true) {
if (pos >= end) {
contents += text.substring(start, pos);
tokenIsUnterminated = true;
error(ts.Diagnostics.Unterminated_template_literal);
resultingToken = startedWithBacktick ? 12 /* NoSubstitutionTemplateLiteral */ : 15 /* TemplateTail */;
break;
}
var currChar = text.charCodeAt(pos);
// '`'
if (currChar === 96 /* backtick */) {
contents += text.substring(start, pos);
pos++;
resultingToken = startedWithBacktick ? 12 /* NoSubstitutionTemplateLiteral */ : 15 /* TemplateTail */;
break;
}
// '${'
if (currChar === 36 /* $ */ && pos + 1 < end && text.charCodeAt(pos + 1) === 123 /* openBrace */) {
contents += text.substring(start, pos);
pos += 2;
resultingToken = startedWithBacktick ? 13 /* TemplateHead */ : 14 /* TemplateMiddle */;
break;
}
// Escape character
if (currChar === 92 /* backslash */) {
contents += text.substring(start, pos);
contents += scanEscapeSequence();
start = pos;
continue;
}
// Speculated ECMAScript 6 Spec 11.8.6.1:
// <CR><LF> and <CR> LineTerminatorSequences are normalized to <LF> for Template Values
if (currChar === 13 /* carriageReturn */) {
contents += text.substring(start, pos);
pos++;
if (pos < end && text.charCodeAt(pos) === 10 /* lineFeed */) {
pos++;
}
contents += "\n";
start = pos;
continue;
}
pos++;
}
ts.Debug.assert(resultingToken !== undefined);
tokenValue = contents;
return resultingToken;
}
function scanEscapeSequence() {
pos++;
if (pos >= end) {
error(ts.Diagnostics.Unexpected_end_of_text);
return "";
}
var ch = text.charCodeAt(pos);
pos++;
switch (ch) {
case 48 /* _0 */:
return "\0";
case 98 /* b */:
return "\b";
case 116 /* t */:
return "\t";
case 110 /* n */:
return "\n";
case 118 /* v */:
return "\v";
case 102 /* f */:
return "\f";
case 114 /* r */:
return "\r";
case 39 /* singleQuote */:
return "\'";
case 34 /* doubleQuote */:
return "\"";
case 117 /* u */:
// '\u{DDDDDDDD}'
if (pos < end && text.charCodeAt(pos) === 123 /* openBrace */) {
hasExtendedUnicodeEscape = true;
pos++;
return scanExtendedUnicodeEscape();
}
// '\uDDDD'
return scanHexadecimalEscape(/*numDigits*/ 4);
case 120 /* x */:
// '\xDD'
return scanHexadecimalEscape(/*numDigits*/ 2);
// when encountering a LineContinuation (i.e. a backslash and a line terminator sequence),
// the line terminator is interpreted to be "the empty code unit sequence".
case 13 /* carriageReturn */:
if (pos < end && text.charCodeAt(pos) === 10 /* lineFeed */) {
pos++;
}
// fall through
case 10 /* lineFeed */:
case 8232 /* lineSeparator */:
case 8233 /* paragraphSeparator */:
return "";
default:
return String.fromCharCode(ch);
}
}
function scanHexadecimalEscape(numDigits) {
var escapedValue = scanExactNumberOfHexDigits(numDigits);
if (escapedValue >= 0) {
return String.fromCharCode(escapedValue);
}
else {
error(ts.Diagnostics.Hexadecimal_digit_expected);
return "";
}
}
function scanExtendedUnicodeEscape() {
var escapedValue = scanMinimumNumberOfHexDigits(1);
var isInvalidExtendedEscape = false;
// Validate the value of the digit
if (escapedValue < 0) {
error(ts.Diagnostics.Hexadecimal_digit_expected);
isInvalidExtendedEscape = true;
}
else if (escapedValue > 0x10FFFF) {
error(ts.Diagnostics.An_extended_Unicode_escape_value_must_be_between_0x0_and_0x10FFFF_inclusive);
isInvalidExtendedEscape = true;
}
if (pos >= end) {
error(ts.Diagnostics.Unexpected_end_of_text);
isInvalidExtendedEscape = true;
}
else if (text.charCodeAt(pos) === 125 /* closeBrace */) {
// Only swallow the following character up if it's a '}'.
pos++;
}
else {
error(ts.Diagnostics.Unterminated_Unicode_escape_sequence);
isInvalidExtendedEscape = true;
}
if (isInvalidExtendedEscape) {
return "";
}
return utf16EncodeAsString(escapedValue);
}
// Derived from the 10.1.1 UTF16Encoding of the ES6 Spec.
function utf16EncodeAsString(codePoint) {
ts.Debug.assert(0x0 <= codePoint && codePoint <= 0x10FFFF);
if (codePoint <= 65535) {
return String.fromCharCode(codePoint);
}
var codeUnit1 = Math.floor((codePoint - 65536) / 1024) + 0xD800;
var codeUnit2 = ((codePoint - 65536) % 1024) + 0xDC00;
return String.fromCharCode(codeUnit1, codeUnit2);
}
// Current character is known to be a backslash. Check for Unicode escape of the form '\uXXXX'
// and return code point value if valid Unicode escape is found. Otherwise return -1.
function peekUnicodeEscape() {
if (pos + 5 < end && text.charCodeAt(pos + 1) === 117 /* u */) {
var start_1 = pos;
pos += 2;
var value = scanExactNumberOfHexDigits(4);
pos = start_1;
return value;
}
return -1;
}
function scanIdentifierParts() {
var result = "";
var start = pos;
while (pos < end) {
var ch = text.charCodeAt(pos);
if (isIdentifierPart(ch, languageVersion)) {
pos++;
}
else if (ch === 92 /* backslash */) {
ch = peekUnicodeEscape();
if (!(ch >= 0 && isIdentifierPart(ch, languageVersion))) {
break;
}
result += text.substring(start, pos);
result += String.fromCharCode(ch);
// Valid Unicode escape is always six characters
pos += 6;
start = pos;
}
else {
break;
}
}
result += text.substring(start, pos);
return result;
}
function getIdentifierToken() {
// Reserved words are between 2 and 11 characters long and start with a lowercase letter
var len = tokenValue.length;
if (len >= 2 && len <= 11) {
var ch = tokenValue.charCodeAt(0);
if (ch >= 97 /* a */ && ch <= 122 /* z */ && hasOwnProperty.call(textToToken, tokenValue)) {
return token = textToToken[tokenValue];
}
}
return token = 70 /* Identifier */;
}
function scanBinaryOrOctalDigits(base) {
ts.Debug.assert(base === 2 || base === 8, "Expected either base 2 or base 8");
var value = 0;
// For counting number of digits; Valid binaryIntegerLiteral must have at least one binary digit following B or b.
// Similarly valid octalIntegerLiteral must have at least one octal digit following o or O.
var numberOfDigits = 0;
while (true) {
var ch = text.charCodeAt(pos);
var valueOfCh = ch - 48 /* _0 */;
if (!isDigit(ch) || valueOfCh >= base) {
break;
}
value = value * base + valueOfCh;
pos++;
numberOfDigits++;
}
// Invalid binaryIntegerLiteral or octalIntegerLiteral
if (numberOfDigits === 0) {
return -1;
}
return value;
}
function scan() {
startPos = pos;
hasExtendedUnicodeEscape = false;
precedingLineBreak = false;
tokenIsUnterminated = false;
while (true) {
tokenPos = pos;
if (pos >= end) {
return token = 1 /* EndOfFileToken */;
}
var ch = text.charCodeAt(pos);
// Special handling for shebang
if (ch === 35 /* hash */ && pos === 0 && isShebangTrivia(text, pos)) {
pos = scanShebangTrivia(text, pos);
if (skipTrivia) {
continue;
}
else {
return token = 6 /* ShebangTrivia */;
}
}
switch (ch) {
case 10 /* lineFeed */:
case 13 /* carriageReturn */:
precedingLineBreak = true;
if (skipTrivia) {
pos++;
continue;
}
else {
if (ch === 13 /* carriageReturn */ && pos + 1 < end && text.charCodeAt(pos + 1) === 10 /* lineFeed */) {
// consume both CR and LF
pos += 2;
}
else {
pos++;
}
return token = 4 /* NewLineTrivia */;
}
case 9 /* tab */:
case 11 /* verticalTab */:
case 12 /* formFeed */:
case 32 /* space */:
if (skipTrivia) {
pos++;
continue;
}
else {
while (pos < end && isWhiteSpaceSingleLine(text.charCodeAt(pos))) {
pos++;
}
return token = 5 /* WhitespaceTrivia */;
}
case 33 /* exclamation */:
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
if (text.charCodeAt(pos + 2) === 61 /* equals */) {
return pos += 3, token = 34 /* ExclamationEqualsEqualsToken */;
}
return pos += 2, token = 32 /* ExclamationEqualsToken */;
}
pos++;
return token = 50 /* ExclamationToken */;
case 34 /* doubleQuote */:
case 39 /* singleQuote */:
tokenValue = scanString();
return token = 9 /* StringLiteral */;
case 96 /* backtick */:
return token = scanTemplateAndSetTokenValue();
case 37 /* percent */:
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 63 /* PercentEqualsToken */;
}
pos++;
return token = 41 /* PercentToken */;
case 38 /* ampersand */:
if (text.charCodeAt(pos + 1) === 38 /* ampersand */) {
return pos += 2, token = 52 /* AmpersandAmpersandToken */;
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 67 /* AmpersandEqualsToken */;
}
pos++;
return token = 47 /* AmpersandToken */;
case 40 /* openParen */:
pos++;
return token = 18 /* OpenParenToken */;
case 41 /* closeParen */:
pos++;
return token = 19 /* CloseParenToken */;
case 42 /* asterisk */:
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 60 /* AsteriskEqualsToken */;
}
if (text.charCodeAt(pos + 1) === 42 /* asterisk */) {
if (text.charCodeAt(pos + 2) === 61 /* equals */) {
return pos += 3, token = 61 /* AsteriskAsteriskEqualsToken */;
}
return pos += 2, token = 39 /* AsteriskAsteriskToken */;
}
pos++;
return token = 38 /* AsteriskToken */;
case 43 /* plus */:
if (text.charCodeAt(pos + 1) === 43 /* plus */) {
return pos += 2, token = 42 /* PlusPlusToken */;
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 58 /* PlusEqualsToken */;
}
pos++;
return token = 36 /* PlusToken */;
case 44 /* comma */:
pos++;
return token = 25 /* CommaToken */;
case 45 /* minus */:
if (text.charCodeAt(pos + 1) === 45 /* minus */) {
return pos += 2, token = 43 /* MinusMinusToken */;
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 59 /* MinusEqualsToken */;
}
pos++;
return token = 37 /* MinusToken */;
case 46 /* dot */:
if (isDigit(text.charCodeAt(pos + 1))) {
tokenValue = scanNumber();
return token = 8 /* NumericLiteral */;
}
if (text.charCodeAt(pos + 1) === 46 /* dot */ && text.charCodeAt(pos + 2) === 46 /* dot */) {
return pos += 3, token = 23 /* DotDotDotToken */;
}
pos++;
return token = 22 /* DotToken */;
case 47 /* slash */:
// Single-line comment
if (text.charCodeAt(pos + 1) === 47 /* slash */) {
pos += 2;
while (pos < end) {
if (isLineBreak(text.charCodeAt(pos))) {
break;
}
pos++;
}
if (skipTrivia) {
continue;
}
else {
return token = 2 /* SingleLineCommentTrivia */;
}
}
// Multi-line comment
if (text.charCodeAt(pos + 1) === 42 /* asterisk */) {
pos += 2;
var commentClosed = false;
while (pos < end) {
var ch_2 = text.charCodeAt(pos);
if (ch_2 === 42 /* asterisk */ && text.charCodeAt(pos + 1) === 47 /* slash */) {
pos += 2;
commentClosed = true;
break;
}
if (isLineBreak(ch_2)) {
precedingLineBreak = true;
}
pos++;
}
if (!commentClosed) {
error(ts.Diagnostics.Asterisk_Slash_expected);
}
if (skipTrivia) {
continue;
}
else {
tokenIsUnterminated = !commentClosed;
return token = 3 /* MultiLineCommentTrivia */;
}
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 62 /* SlashEqualsToken */;
}
pos++;
return token = 40 /* SlashToken */;
case 48 /* _0 */:
if (pos + 2 < end && (text.charCodeAt(pos + 1) === 88 /* X */ || text.charCodeAt(pos + 1) === 120 /* x */)) {
pos += 2;
var value = scanMinimumNumberOfHexDigits(1);
if (value < 0) {
error(ts.Diagnostics.Hexadecimal_digit_expected);
value = 0;
}
tokenValue = "" + value;
return token = 8 /* NumericLiteral */;
}
else if (pos + 2 < end && (text.charCodeAt(pos + 1) === 66 /* B */ || text.charCodeAt(pos + 1) === 98 /* b */)) {
pos += 2;
var value = scanBinaryOrOctalDigits(/* base */ 2);
if (value < 0) {
error(ts.Diagnostics.Binary_digit_expected);
value = 0;
}
tokenValue = "" + value;
return token = 8 /* NumericLiteral */;
}
else if (pos + 2 < end && (text.charCodeAt(pos + 1) === 79 /* O */ || text.charCodeAt(pos + 1) === 111 /* o */)) {
pos += 2;
var value = scanBinaryOrOctalDigits(/* base */ 8);
if (value < 0) {
error(ts.Diagnostics.Octal_digit_expected);
value = 0;
}
tokenValue = "" + value;
return token = 8 /* NumericLiteral */;
}
// Try to parse as an octal
if (pos + 1 < end && isOctalDigit(text.charCodeAt(pos + 1))) {
tokenValue = "" + scanOctalDigits();
return token = 8 /* NumericLiteral */;
}
// This fall-through is a deviation from the EcmaScript grammar. The grammar says that a leading zero
// can only be followed by an octal digit, a dot, or the end of the number literal. However, we are being
// permissive and allowing decimal digits of the form 08* and 09* (which many browsers also do).
case 49 /* _1 */:
case 50 /* _2 */:
case 51 /* _3 */:
case 52 /* _4 */:
case 53 /* _5 */:
case 54 /* _6 */:
case 55 /* _7 */:
case 56 /* _8 */:
case 57 /* _9 */:
tokenValue = scanNumber();
return token = 8 /* NumericLiteral */;
case 58 /* colon */:
pos++;
return token = 55 /* ColonToken */;
case 59 /* semicolon */:
pos++;
return token = 24 /* SemicolonToken */;
case 60 /* lessThan */:
if (isConflictMarkerTrivia(text, pos)) {
pos = scanConflictMarkerTrivia(text, pos, error);
if (skipTrivia) {
continue;
}
else {
return token = 7 /* ConflictMarkerTrivia */;
}
}
if (text.charCodeAt(pos + 1) === 60 /* lessThan */) {
if (text.charCodeAt(pos + 2) === 61 /* equals */) {
return pos += 3, token = 64 /* LessThanLessThanEqualsToken */;
}
return pos += 2, token = 44 /* LessThanLessThanToken */;
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 29 /* LessThanEqualsToken */;
}
if (languageVariant === 1 /* JSX */ &&
text.charCodeAt(pos + 1) === 47 /* slash */ &&
text.charCodeAt(pos + 2) !== 42 /* asterisk */) {
return pos += 2, token = 27 /* LessThanSlashToken */;
}
pos++;
return token = 26 /* LessThanToken */;
case 61 /* equals */:
if (isConflictMarkerTrivia(text, pos)) {
pos = scanConflictMarkerTrivia(text, pos, error);
if (skipTrivia) {
continue;
}
else {
return token = 7 /* ConflictMarkerTrivia */;
}
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
if (text.charCodeAt(pos + 2) === 61 /* equals */) {
return pos += 3, token = 33 /* EqualsEqualsEqualsToken */;
}
return pos += 2, token = 31 /* EqualsEqualsToken */;
}
if (text.charCodeAt(pos + 1) === 62 /* greaterThan */) {
return pos += 2, token = 35 /* EqualsGreaterThanToken */;
}
pos++;
return token = 57 /* EqualsToken */;
case 62 /* greaterThan */:
if (isConflictMarkerTrivia(text, pos)) {
pos = scanConflictMarkerTrivia(text, pos, error);
if (skipTrivia) {
continue;
}
else {
return token = 7 /* ConflictMarkerTrivia */;
}
}
pos++;
return token = 28 /* GreaterThanToken */;
case 63 /* question */:
pos++;
return token = 54 /* QuestionToken */;
case 91 /* openBracket */:
pos++;
return token = 20 /* OpenBracketToken */;
case 93 /* closeBracket */:
pos++;
return token = 21 /* CloseBracketToken */;
case 94 /* caret */:
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 69 /* CaretEqualsToken */;
}
pos++;
return token = 49 /* CaretToken */;
case 123 /* openBrace */:
pos++;
return token = 16 /* OpenBraceToken */;
case 124 /* bar */:
if (text.charCodeAt(pos + 1) === 124 /* bar */) {
return pos += 2, token = 53 /* BarBarToken */;
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 68 /* BarEqualsToken */;
}
pos++;
return token = 48 /* BarToken */;
case 125 /* closeBrace */:
pos++;
return token = 17 /* CloseBraceToken */;
case 126 /* tilde */:
pos++;
return token = 51 /* TildeToken */;
case 64 /* at */:
pos++;
return token = 56 /* AtToken */;
case 92 /* backslash */:
var cookedChar = peekUnicodeEscape();
if (cookedChar >= 0 && isIdentifierStart(cookedChar, languageVersion)) {
pos += 6;
tokenValue = String.fromCharCode(cookedChar) + scanIdentifierParts();
return token = getIdentifierToken();
}
error(ts.Diagnostics.Invalid_character);
pos++;
return token = 0 /* Unknown */;
default:
if (isIdentifierStart(ch, languageVersion)) {
pos++;
while (pos < end && isIdentifierPart(ch = text.charCodeAt(pos), languageVersion))
pos++;
tokenValue = text.substring(tokenPos, pos);
if (ch === 92 /* backslash */) {
tokenValue += scanIdentifierParts();
}
return token = getIdentifierToken();
}
else if (isWhiteSpaceSingleLine(ch)) {
pos++;
continue;
}
else if (isLineBreak(ch)) {
precedingLineBreak = true;
pos++;
continue;
}
error(ts.Diagnostics.Invalid_character);
pos++;
return token = 0 /* Unknown */;
}
}
}
function reScanGreaterToken() {
if (token === 28 /* GreaterThanToken */) {
if (text.charCodeAt(pos) === 62 /* greaterThan */) {
if (text.charCodeAt(pos + 1) === 62 /* greaterThan */) {
if (text.charCodeAt(pos + 2) === 61 /* equals */) {
return pos += 3, token = 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */;
}
return pos += 2, token = 46 /* GreaterThanGreaterThanGreaterThanToken */;
}
if (text.charCodeAt(pos + 1) === 61 /* equals */) {
return pos += 2, token = 65 /* GreaterThanGreaterThanEqualsToken */;
}
pos++;
return token = 45 /* GreaterThanGreaterThanToken */;
}
if (text.charCodeAt(pos) === 61 /* equals */) {
pos++;
return token = 30 /* GreaterThanEqualsToken */;
}
}
return token;
}
function reScanSlashToken() {
if (token === 40 /* SlashToken */ || token === 62 /* SlashEqualsToken */) {
var p = tokenPos + 1;
var inEscape = false;
var inCharacterClass = false;
while (true) {
// If we reach the end of a file, or hit a newline, then this is an unterminated
// regex. Report error and return what we have so far.
if (p >= end) {
tokenIsUnterminated = true;
error(ts.Diagnostics.Unterminated_regular_expression_literal);
break;
}
var ch = text.charCodeAt(p);
if (isLineBreak(ch)) {
tokenIsUnterminated = true;
error(ts.Diagnostics.Unterminated_regular_expression_literal);
break;
}
if (inEscape) {
// Parsing an escape character;
// reset the flag and just advance to the next char.
inEscape = false;
}
else if (ch === 47 /* slash */ && !inCharacterClass) {
// A slash within a character class is permissible,
// but in general it signals the end of the regexp literal.
p++;
break;
}
else if (ch === 91 /* openBracket */) {
inCharacterClass = true;
}
else if (ch === 92 /* backslash */) {
inEscape = true;
}
else if (ch === 93 /* closeBracket */) {
inCharacterClass = false;
}
p++;
}
while (p < end && isIdentifierPart(text.charCodeAt(p), languageVersion)) {
p++;
}
pos = p;
tokenValue = text.substring(tokenPos, pos);
token = 11 /* RegularExpressionLiteral */;
}
return token;
}
/**
* Unconditionally back up and scan a template expression portion.
*/
function reScanTemplateToken() {
ts.Debug.assert(token === 17 /* CloseBraceToken */, "'reScanTemplateToken' should only be called on a '}'");
pos = tokenPos;
return token = scanTemplateAndSetTokenValue();
}
function reScanJsxToken() {
pos = tokenPos = startPos;
return token = scanJsxToken();
}
function scanJsxToken() {
startPos = tokenPos = pos;
if (pos >= end) {
return token = 1 /* EndOfFileToken */;
}
var char = text.charCodeAt(pos);
if (char === 60 /* lessThan */) {
if (text.charCodeAt(pos + 1) === 47 /* slash */) {
pos += 2;
return token = 27 /* LessThanSlashToken */;
}
pos++;
return token = 26 /* LessThanToken */;
}
if (char === 123 /* openBrace */) {
pos++;
return token = 16 /* OpenBraceToken */;
}
while (pos < end) {
pos++;
char = text.charCodeAt(pos);
if ((char === 123 /* openBrace */) || (char === 60 /* lessThan */)) {
break;
}
}
return token = 10 /* JsxText */;
}
// Scans a JSX identifier; these differ from normal identifiers in that
// they allow dashes
function scanJsxIdentifier() {
if (tokenIsIdentifierOrKeyword(token)) {
var firstCharPosition = pos;
while (pos < end) {
var ch = text.charCodeAt(pos);
if (ch === 45 /* minus */ || ((firstCharPosition === pos) ? isIdentifierStart(ch, languageVersion) : isIdentifierPart(ch, languageVersion))) {
pos++;
}
else {
break;
}
}
tokenValue += text.substr(firstCharPosition, pos - firstCharPosition);
}
return token;
}
function scanJsxAttributeValue() {
startPos = pos;
switch (text.charCodeAt(pos)) {
case 34 /* doubleQuote */:
case 39 /* singleQuote */:
tokenValue = scanString(/*allowEscapes*/ false);
return token = 9 /* StringLiteral */;
default:
// If this scans anything other than `{`, it's a parse error.
return scan();
}
}
function scanJSDocToken() {
if (pos >= end) {
return token = 1 /* EndOfFileToken */;
}
startPos = pos;
tokenPos = pos;
var ch = text.charCodeAt(pos);
switch (ch) {
case 9 /* tab */:
case 11 /* verticalTab */:
case 12 /* formFeed */:
case 32 /* space */:
while (pos < end && isWhiteSpaceSingleLine(text.charCodeAt(pos))) {
pos++;
}
return token = 5 /* WhitespaceTrivia */;
case 64 /* at */:
pos++;
return token = 56 /* AtToken */;
case 10 /* lineFeed */:
case 13 /* carriageReturn */:
pos++;
return token = 4 /* NewLineTrivia */;
case 42 /* asterisk */:
pos++;
return token = 38 /* AsteriskToken */;
case 123 /* openBrace */:
pos++;
return token = 16 /* OpenBraceToken */;
case 125 /* closeBrace */:
pos++;
return token = 17 /* CloseBraceToken */;
case 91 /* openBracket */:
pos++;
return token = 20 /* OpenBracketToken */;
case 93 /* closeBracket */:
pos++;
return token = 21 /* CloseBracketToken */;
case 61 /* equals */:
pos++;
return token = 57 /* EqualsToken */;
case 44 /* comma */:
pos++;
return token = 25 /* CommaToken */;
case 46 /* dot */:
pos++;
return token = 22 /* DotToken */;
}
if (isIdentifierStart(ch, 5 /* Latest */)) {
pos++;
while (isIdentifierPart(text.charCodeAt(pos), 5 /* Latest */) && pos < end) {
pos++;
}
return token = 70 /* Identifier */;
}
else {
return pos += 1, token = 0 /* Unknown */;
}
}
function speculationHelper(callback, isLookahead) {
var savePos = pos;
var saveStartPos = startPos;
var saveTokenPos = tokenPos;
var saveToken = token;
var saveTokenValue = tokenValue;
var savePrecedingLineBreak = precedingLineBreak;
var result = callback();
// If our callback returned something 'falsy' or we're just looking ahead,
// then unconditionally restore us to where we were.
if (!result || isLookahead) {
pos = savePos;
startPos = saveStartPos;
tokenPos = saveTokenPos;
token = saveToken;
tokenValue = saveTokenValue;
precedingLineBreak = savePrecedingLineBreak;
}
return result;
}
function scanRange(start, length, callback) {
var saveEnd = end;
var savePos = pos;
var saveStartPos = startPos;
var saveTokenPos = tokenPos;
var saveToken = token;
var savePrecedingLineBreak = precedingLineBreak;
var saveTokenValue = tokenValue;
var saveHasExtendedUnicodeEscape = hasExtendedUnicodeEscape;
var saveTokenIsUnterminated = tokenIsUnterminated;
setText(text, start, length);
var result = callback();
end = saveEnd;
pos = savePos;
startPos = saveStartPos;
tokenPos = saveTokenPos;
token = saveToken;
precedingLineBreak = savePrecedingLineBreak;
tokenValue = saveTokenValue;
hasExtendedUnicodeEscape = saveHasExtendedUnicodeEscape;
tokenIsUnterminated = saveTokenIsUnterminated;
return result;
}
function lookAhead(callback) {
return speculationHelper(callback, /*isLookahead*/ true);
}
function tryScan(callback) {
return speculationHelper(callback, /*isLookahead*/ false);
}
function getText() {
return text;
}
function setText(newText, start, length) {
text = newText || "";
end = length === undefined ? text.length : start + length;
setTextPos(start || 0);
}
function setOnError(errorCallback) {
onError = errorCallback;
}
function setScriptTarget(scriptTarget) {
languageVersion = scriptTarget;
}
function setLanguageVariant(variant) {
languageVariant = variant;
}
function setTextPos(textPos) {
ts.Debug.assert(textPos >= 0);
pos = textPos;
startPos = textPos;
tokenPos = textPos;
token = 0 /* Unknown */;
precedingLineBreak = false;
tokenValue = undefined;
hasExtendedUnicodeEscape = false;
tokenIsUnterminated = false;
}
}
ts.createScanner = createScanner;
})(ts || (ts = {}));
/// <reference path="sys.ts" />
/* @internal */
var ts;
(function (ts) {
ts.externalHelpersModuleNameText = "tslib";
function getDeclarationOfKind(symbol, kind) {
var declarations = symbol.declarations;
if (declarations) {
for (var _i = 0, declarations_1 = declarations; _i < declarations_1.length; _i++) {
var declaration = declarations_1[_i];
if (declaration.kind === kind) {
return declaration;
}
}
}
return undefined;
}
ts.getDeclarationOfKind = getDeclarationOfKind;
// Pool writers to avoid needing to allocate them for every symbol we write.
var stringWriters = [];
function getSingleLineStringWriter() {
if (stringWriters.length === 0) {
var str_1 = "";
var writeText = function (text) { return str_1 += text; };
return {
string: function () { return str_1; },
writeKeyword: writeText,
writeOperator: writeText,
writePunctuation: writeText,
writeSpace: writeText,
writeStringLiteral: writeText,
writeParameter: writeText,
writeSymbol: writeText,
// Completely ignore indentation for string writers. And map newlines to
// a single space.
writeLine: function () { return str_1 += " "; },
increaseIndent: ts.noop,
decreaseIndent: ts.noop,
clear: function () { return str_1 = ""; },
trackSymbol: ts.noop,
reportInaccessibleThisError: ts.noop
};
}
return stringWriters.pop();
}
ts.getSingleLineStringWriter = getSingleLineStringWriter;
function releaseStringWriter(writer) {
writer.clear();
stringWriters.push(writer);
}
ts.releaseStringWriter = releaseStringWriter;
function getFullWidth(node) {
return node.end - node.pos;
}
ts.getFullWidth = getFullWidth;
function hasResolvedModule(sourceFile, moduleNameText) {
return !!(sourceFile && sourceFile.resolvedModules && sourceFile.resolvedModules[moduleNameText]);
}
ts.hasResolvedModule = hasResolvedModule;
function getResolvedModule(sourceFile, moduleNameText) {
return hasResolvedModule(sourceFile, moduleNameText) ? sourceFile.resolvedModules[moduleNameText] : undefined;
}
ts.getResolvedModule = getResolvedModule;
function setResolvedModule(sourceFile, moduleNameText, resolvedModule) {
if (!sourceFile.resolvedModules) {
sourceFile.resolvedModules = ts.createMap();
}
sourceFile.resolvedModules[moduleNameText] = resolvedModule;
}
ts.setResolvedModule = setResolvedModule;
function setResolvedTypeReferenceDirective(sourceFile, typeReferenceDirectiveName, resolvedTypeReferenceDirective) {
if (!sourceFile.resolvedTypeReferenceDirectiveNames) {
sourceFile.resolvedTypeReferenceDirectiveNames = ts.createMap();
}
sourceFile.resolvedTypeReferenceDirectiveNames[typeReferenceDirectiveName] = resolvedTypeReferenceDirective;
}
ts.setResolvedTypeReferenceDirective = setResolvedTypeReferenceDirective;
/* @internal */
function moduleResolutionIsEqualTo(oldResolution, newResolution) {
return oldResolution.isExternalLibraryImport === newResolution.isExternalLibraryImport &&
oldResolution.extension === newResolution.extension &&
oldResolution.resolvedFileName === newResolution.resolvedFileName;
}
ts.moduleResolutionIsEqualTo = moduleResolutionIsEqualTo;
/* @internal */
function typeDirectiveIsEqualTo(oldResolution, newResolution) {
return oldResolution.resolvedFileName === newResolution.resolvedFileName && oldResolution.primary === newResolution.primary;
}
ts.typeDirectiveIsEqualTo = typeDirectiveIsEqualTo;
/* @internal */
function hasChangesInResolutions(names, newResolutions, oldResolutions, comparer) {
if (names.length !== newResolutions.length) {
return false;
}
for (var i = 0; i < names.length; i++) {
var newResolution = newResolutions[i];
var oldResolution = oldResolutions && oldResolutions[names[i]];
var changed = oldResolution
? !newResolution || !comparer(oldResolution, newResolution)
: newResolution;
if (changed) {
return true;
}
}
return false;
}
ts.hasChangesInResolutions = hasChangesInResolutions;
// Returns true if this node contains a parse error anywhere underneath it.
function containsParseError(node) {
aggregateChildData(node);
return (node.flags & 4194304 /* ThisNodeOrAnySubNodesHasError */) !== 0;
}
ts.containsParseError = containsParseError;
function aggregateChildData(node) {
if (!(node.flags & 8388608 /* HasAggregatedChildData */)) {
// A node is considered to contain a parse error if:
// a) the parser explicitly marked that it had an error
// b) any of it's children reported that it had an error.
var thisNodeOrAnySubNodesHasError = ((node.flags & 1048576 /* ThisNodeHasError */) !== 0) ||
ts.forEachChild(node, containsParseError);
// If so, mark ourselves accordingly.
if (thisNodeOrAnySubNodesHasError) {
node.flags |= 4194304 /* ThisNodeOrAnySubNodesHasError */;
}
// Also mark that we've propagated the child information to this node. This way we can
// always consult the bit directly on this node without needing to check its children
// again.
node.flags |= 8388608 /* HasAggregatedChildData */;
}
}
function getSourceFileOfNode(node) {
while (node && node.kind !== 261 /* SourceFile */) {
node = node.parent;
}
return node;
}
ts.getSourceFileOfNode = getSourceFileOfNode;
function isStatementWithLocals(node) {
switch (node.kind) {
case 204 /* Block */:
case 232 /* CaseBlock */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
return true;
}
return false;
}
ts.isStatementWithLocals = isStatementWithLocals;
function getStartPositionOfLine(line, sourceFile) {
ts.Debug.assert(line >= 0);
return ts.getLineStarts(sourceFile)[line];
}
ts.getStartPositionOfLine = getStartPositionOfLine;
// This is a useful function for debugging purposes.
function nodePosToString(node) {
var file = getSourceFileOfNode(node);
var loc = ts.getLineAndCharacterOfPosition(file, node.pos);
return file.fileName + "(" + (loc.line + 1) + "," + (loc.character + 1) + ")";
}
ts.nodePosToString = nodePosToString;
function getStartPosOfNode(node) {
return node.pos;
}
ts.getStartPosOfNode = getStartPosOfNode;
function isDefined(value) {
return value !== undefined;
}
ts.isDefined = isDefined;
function getEndLinePosition(line, sourceFile) {
ts.Debug.assert(line >= 0);
var lineStarts = ts.getLineStarts(sourceFile);
var lineIndex = line;
var sourceText = sourceFile.text;
if (lineIndex + 1 === lineStarts.length) {
// last line - return EOF
return sourceText.length - 1;
}
else {
// current line start
var start = lineStarts[lineIndex];
// take the start position of the next line - 1 = it should be some line break
var pos = lineStarts[lineIndex + 1] - 1;
ts.Debug.assert(ts.isLineBreak(sourceText.charCodeAt(pos)));
// walk backwards skipping line breaks, stop the the beginning of current line.
// i.e:
// <some text>
// $ <- end of line for this position should match the start position
while (start <= pos && ts.isLineBreak(sourceText.charCodeAt(pos))) {
pos--;
}
return pos;
}
}
ts.getEndLinePosition = getEndLinePosition;
// Returns true if this node is missing from the actual source code. A 'missing' node is different
// from 'undefined/defined'. When a node is undefined (which can happen for optional nodes
// in the tree), it is definitely missing. However, a node may be defined, but still be
// missing. This happens whenever the parser knows it needs to parse something, but can't
// get anything in the source code that it expects at that location. For example:
//
// let a: ;
//
// Here, the Type in the Type-Annotation is not-optional (as there is a colon in the source
// code). So the parser will attempt to parse out a type, and will create an actual node.
// However, this node will be 'missing' in the sense that no actual source-code/tokens are
// contained within it.
function nodeIsMissing(node) {
if (node === undefined) {
return true;
}
return node.pos === node.end && node.pos >= 0 && node.kind !== 1 /* EndOfFileToken */;
}
ts.nodeIsMissing = nodeIsMissing;
function nodeIsPresent(node) {
return !nodeIsMissing(node);
}
ts.nodeIsPresent = nodeIsPresent;
function getTokenPosOfNode(node, sourceFile, includeJsDocComment) {
// With nodes that have no width (i.e. 'Missing' nodes), we actually *don't*
// want to skip trivia because this will launch us forward to the next token.
if (nodeIsMissing(node)) {
return node.pos;
}
if (isJSDocNode(node)) {
return ts.skipTrivia((sourceFile || getSourceFileOfNode(node)).text, node.pos, /*stopAfterLineBreak*/ false, /*stopAtComments*/ true);
}
if (includeJsDocComment && node.jsDocComments && node.jsDocComments.length > 0) {
return getTokenPosOfNode(node.jsDocComments[0]);
}
// For a syntax list, it is possible that one of its children has JSDocComment nodes, while
// the syntax list itself considers them as normal trivia. Therefore if we simply skip
// trivia for the list, we may have skipped the JSDocComment as well. So we should process its
// first child to determine the actual position of its first token.
if (node.kind === 291 /* SyntaxList */ && node._children.length > 0) {
return getTokenPosOfNode(node._children[0], sourceFile, includeJsDocComment);
}
return ts.skipTrivia((sourceFile || getSourceFileOfNode(node)).text, node.pos);
}
ts.getTokenPosOfNode = getTokenPosOfNode;
function isJSDocNode(node) {
return node.kind >= 262 /* FirstJSDocNode */ && node.kind <= 287 /* LastJSDocNode */;
}
ts.isJSDocNode = isJSDocNode;
function isJSDocTag(node) {
return node.kind >= 278 /* FirstJSDocTagNode */ && node.kind <= 290 /* LastJSDocTagNode */;
}
ts.isJSDocTag = isJSDocTag;
function getNonDecoratorTokenPosOfNode(node, sourceFile) {
if (nodeIsMissing(node) || !node.decorators) {
return getTokenPosOfNode(node, sourceFile);
}
return ts.skipTrivia((sourceFile || getSourceFileOfNode(node)).text, node.decorators.end);
}
ts.getNonDecoratorTokenPosOfNode = getNonDecoratorTokenPosOfNode;
function getSourceTextOfNodeFromSourceFile(sourceFile, node, includeTrivia) {
if (includeTrivia === void 0) { includeTrivia = false; }
if (nodeIsMissing(node)) {
return "";
}
var text = sourceFile.text;
return text.substring(includeTrivia ? node.pos : ts.skipTrivia(text, node.pos), node.end);
}
ts.getSourceTextOfNodeFromSourceFile = getSourceTextOfNodeFromSourceFile;
function getTextOfNodeFromSourceText(sourceText, node) {
if (nodeIsMissing(node)) {
return "";
}
return sourceText.substring(ts.skipTrivia(sourceText, node.pos), node.end);
}
ts.getTextOfNodeFromSourceText = getTextOfNodeFromSourceText;
function getTextOfNode(node, includeTrivia) {
if (includeTrivia === void 0) { includeTrivia = false; }
return getSourceTextOfNodeFromSourceFile(getSourceFileOfNode(node), node, includeTrivia);
}
ts.getTextOfNode = getTextOfNode;
function getLiteralText(node, sourceFile, languageVersion) {
// Any template literal or string literal with an extended escape
// (e.g. "\u{0067}") will need to be downleveled as a escaped string literal.
if (languageVersion < 2 /* ES2015 */ && (isTemplateLiteralKind(node.kind) || node.hasExtendedUnicodeEscape)) {
return getQuotedEscapedLiteralText('"', node.text, '"');
}
// If we don't need to downlevel and we can reach the original source text using
// the node's parent reference, then simply get the text as it was originally written.
if (!nodeIsSynthesized(node) && node.parent) {
var text = getSourceTextOfNodeFromSourceFile(sourceFile, node);
if (languageVersion < 2 /* ES2015 */ && isBinaryOrOctalIntegerLiteral(node, text)) {
return node.text;
}
return text;
}
// If we can't reach the original source text, use the canonical form if it's a number,
// or an escaped quoted form of the original text if it's string-like.
switch (node.kind) {
case 9 /* StringLiteral */:
return getQuotedEscapedLiteralText('"', node.text, '"');
case 12 /* NoSubstitutionTemplateLiteral */:
return getQuotedEscapedLiteralText("`", node.text, "`");
case 13 /* TemplateHead */:
return getQuotedEscapedLiteralText("`", node.text, "${");
case 14 /* TemplateMiddle */:
return getQuotedEscapedLiteralText("}", node.text, "${");
case 15 /* TemplateTail */:
return getQuotedEscapedLiteralText("}", node.text, "`");
case 8 /* NumericLiteral */:
return node.text;
}
ts.Debug.fail("Literal kind '" + node.kind + "' not accounted for.");
}
ts.getLiteralText = getLiteralText;
function isBinaryOrOctalIntegerLiteral(node, text) {
if (node.kind === 8 /* NumericLiteral */ && text.length > 1) {
switch (text.charCodeAt(1)) {
case 98 /* b */:
case 66 /* B */:
case 111 /* o */:
case 79 /* O */:
return true;
}
}
return false;
}
ts.isBinaryOrOctalIntegerLiteral = isBinaryOrOctalIntegerLiteral;
function getQuotedEscapedLiteralText(leftQuote, text, rightQuote) {
return leftQuote + escapeNonAsciiCharacters(escapeString(text)) + rightQuote;
}
// Add an extra underscore to identifiers that start with two underscores to avoid issues with magic names like '__proto__'
function escapeIdentifier(identifier) {
return identifier.length >= 2 && identifier.charCodeAt(0) === 95 /* _ */ && identifier.charCodeAt(1) === 95 /* _ */ ? "_" + identifier : identifier;
}
ts.escapeIdentifier = escapeIdentifier;
// Remove extra underscore from escaped identifier
function unescapeIdentifier(identifier) {
return identifier.length >= 3 && identifier.charCodeAt(0) === 95 /* _ */ && identifier.charCodeAt(1) === 95 /* _ */ && identifier.charCodeAt(2) === 95 /* _ */ ? identifier.substr(1) : identifier;
}
ts.unescapeIdentifier = unescapeIdentifier;
// Make an identifier from an external module name by extracting the string after the last "/" and replacing
// all non-alphanumeric characters with underscores
function makeIdentifierFromModuleName(moduleName) {
return ts.getBaseFileName(moduleName).replace(/^(\d)/, "_$1").replace(/\W/g, "_");
}
ts.makeIdentifierFromModuleName = makeIdentifierFromModuleName;
function isBlockOrCatchScoped(declaration) {
return (ts.getCombinedNodeFlags(declaration) & 3 /* BlockScoped */) !== 0 ||
isCatchClauseVariableDeclarationOrBindingElement(declaration);
}
ts.isBlockOrCatchScoped = isBlockOrCatchScoped;
function isCatchClauseVariableDeclarationOrBindingElement(declaration) {
var node = getRootDeclaration(declaration);
return node.kind === 223 /* VariableDeclaration */ && node.parent.kind === 256 /* CatchClause */;
}
ts.isCatchClauseVariableDeclarationOrBindingElement = isCatchClauseVariableDeclarationOrBindingElement;
function isAmbientModule(node) {
return node && node.kind === 230 /* ModuleDeclaration */ &&
(node.name.kind === 9 /* StringLiteral */ || isGlobalScopeAugmentation(node));
}
ts.isAmbientModule = isAmbientModule;
/** Given a symbol for a module, checks that it is either an untyped import or a shorthand ambient module. */
function isShorthandAmbientModuleSymbol(moduleSymbol) {
return isShorthandAmbientModule(moduleSymbol.valueDeclaration);
}
ts.isShorthandAmbientModuleSymbol = isShorthandAmbientModuleSymbol;
function isShorthandAmbientModule(node) {
// The only kind of module that can be missing a body is a shorthand ambient module.
return node.kind === 230 /* ModuleDeclaration */ && (!node.body);
}
function isBlockScopedContainerTopLevel(node) {
return node.kind === 261 /* SourceFile */ ||
node.kind === 230 /* ModuleDeclaration */ ||
isFunctionLike(node);
}
ts.isBlockScopedContainerTopLevel = isBlockScopedContainerTopLevel;
function isGlobalScopeAugmentation(module) {
return !!(module.flags & 512 /* GlobalAugmentation */);
}
ts.isGlobalScopeAugmentation = isGlobalScopeAugmentation;
function isExternalModuleAugmentation(node) {
// external module augmentation is a ambient module declaration that is either:
// - defined in the top level scope and source file is an external module
// - defined inside ambient module declaration located in the top level scope and source file not an external module
if (!node || !isAmbientModule(node)) {
return false;
}
switch (node.parent.kind) {
case 261 /* SourceFile */:
return ts.isExternalModule(node.parent);
case 231 /* ModuleBlock */:
return isAmbientModule(node.parent.parent) && !ts.isExternalModule(node.parent.parent.parent);
}
return false;
}
ts.isExternalModuleAugmentation = isExternalModuleAugmentation;
function isBlockScope(node, parentNode) {
switch (node.kind) {
case 261 /* SourceFile */:
case 232 /* CaseBlock */:
case 256 /* CatchClause */:
case 230 /* ModuleDeclaration */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 150 /* Constructor */:
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return true;
case 204 /* Block */:
// function block is not considered block-scope container
// see comment in binder.ts: bind(...), case for SyntaxKind.Block
return parentNode && !isFunctionLike(parentNode);
}
return false;
}
ts.isBlockScope = isBlockScope;
// Gets the nearest enclosing block scope container that has the provided node
// as a descendant, that is not the provided node.
function getEnclosingBlockScopeContainer(node) {
var current = node.parent;
while (current) {
if (isBlockScope(current, current.parent)) {
return current;
}
current = current.parent;
}
}
ts.getEnclosingBlockScopeContainer = getEnclosingBlockScopeContainer;
// Return display name of an identifier
// Computed property names will just be emitted as "[<expr>]", where <expr> is the source
// text of the expression in the computed property.
function declarationNameToString(name) {
return getFullWidth(name) === 0 ? "(Missing)" : getTextOfNode(name);
}
ts.declarationNameToString = declarationNameToString;
function getTextOfPropertyName(name) {
switch (name.kind) {
case 70 /* Identifier */:
return name.text;
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
return name.text;
case 142 /* ComputedPropertyName */:
if (isStringOrNumericLiteral(name.expression.kind)) {
return name.expression.text;
}
}
return undefined;
}
ts.getTextOfPropertyName = getTextOfPropertyName;
function entityNameToString(name) {
switch (name.kind) {
case 70 /* Identifier */:
return getFullWidth(name) === 0 ? unescapeIdentifier(name.text) : getTextOfNode(name);
case 141 /* QualifiedName */:
return entityNameToString(name.left) + "." + entityNameToString(name.right);
case 177 /* PropertyAccessExpression */:
return entityNameToString(name.expression) + "." + entityNameToString(name.name);
}
}
ts.entityNameToString = entityNameToString;
function createDiagnosticForNode(node, message, arg0, arg1, arg2) {
var sourceFile = getSourceFileOfNode(node);
return createDiagnosticForNodeInSourceFile(sourceFile, node, message, arg0, arg1, arg2);
}
ts.createDiagnosticForNode = createDiagnosticForNode;
function createDiagnosticForNodeInSourceFile(sourceFile, node, message, arg0, arg1, arg2) {
var span = getErrorSpanForNode(sourceFile, node);
return ts.createFileDiagnostic(sourceFile, span.start, span.length, message, arg0, arg1, arg2);
}
ts.createDiagnosticForNodeInSourceFile = createDiagnosticForNodeInSourceFile;
function createDiagnosticForNodeFromMessageChain(node, messageChain) {
var sourceFile = getSourceFileOfNode(node);
var span = getErrorSpanForNode(sourceFile, node);
return {
file: sourceFile,
start: span.start,
length: span.length,
code: messageChain.code,
category: messageChain.category,
messageText: messageChain.next ? messageChain : messageChain.messageText
};
}
ts.createDiagnosticForNodeFromMessageChain = createDiagnosticForNodeFromMessageChain;
function getSpanOfTokenAtPosition(sourceFile, pos) {
var scanner = ts.createScanner(sourceFile.languageVersion, /*skipTrivia*/ true, sourceFile.languageVariant, sourceFile.text, /*onError:*/ undefined, pos);
scanner.scan();
var start = scanner.getTokenPos();
return ts.createTextSpanFromBounds(start, scanner.getTextPos());
}
ts.getSpanOfTokenAtPosition = getSpanOfTokenAtPosition;
function getErrorSpanForArrowFunction(sourceFile, node) {
var pos = ts.skipTrivia(sourceFile.text, node.pos);
if (node.body && node.body.kind === 204 /* Block */) {
var startLine = ts.getLineAndCharacterOfPosition(sourceFile, node.body.pos).line;
var endLine = ts.getLineAndCharacterOfPosition(sourceFile, node.body.end).line;
if (startLine < endLine) {
// The arrow function spans multiple lines,
// make the error span be the first line, inclusive.
return ts.createTextSpan(pos, getEndLinePosition(startLine, sourceFile) - pos + 1);
}
}
return ts.createTextSpanFromBounds(pos, node.end);
}
function getErrorSpanForNode(sourceFile, node) {
var errorNode = node;
switch (node.kind) {
case 261 /* SourceFile */:
var pos_1 = ts.skipTrivia(sourceFile.text, 0, /*stopAfterLineBreak*/ false);
if (pos_1 === sourceFile.text.length) {
// file is empty - return span for the beginning of the file
return ts.createTextSpan(0, 0);
}
return getSpanOfTokenAtPosition(sourceFile, pos_1);
// This list is a work in progress. Add missing node kinds to improve their error
// spans.
case 223 /* VariableDeclaration */:
case 174 /* BindingElement */:
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
case 230 /* ModuleDeclaration */:
case 229 /* EnumDeclaration */:
case 260 /* EnumMember */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 228 /* TypeAliasDeclaration */:
errorNode = node.name;
break;
case 185 /* ArrowFunction */:
return getErrorSpanForArrowFunction(sourceFile, node);
}
if (errorNode === undefined) {
// If we don't have a better node, then just set the error on the first token of
// construct.
return getSpanOfTokenAtPosition(sourceFile, node.pos);
}
var pos = nodeIsMissing(errorNode)
? errorNode.pos
: ts.skipTrivia(sourceFile.text, errorNode.pos);
return ts.createTextSpanFromBounds(pos, errorNode.end);
}
ts.getErrorSpanForNode = getErrorSpanForNode;
function isExternalOrCommonJsModule(file) {
return (file.externalModuleIndicator || file.commonJsModuleIndicator) !== undefined;
}
ts.isExternalOrCommonJsModule = isExternalOrCommonJsModule;
function isDeclarationFile(file) {
return file.isDeclarationFile;
}
ts.isDeclarationFile = isDeclarationFile;
function isConstEnumDeclaration(node) {
return node.kind === 229 /* EnumDeclaration */ && isConst(node);
}
ts.isConstEnumDeclaration = isConstEnumDeclaration;
function isConst(node) {
return !!(ts.getCombinedNodeFlags(node) & 2 /* Const */)
|| !!(ts.getCombinedModifierFlags(node) & 2048 /* Const */);
}
ts.isConst = isConst;
function isLet(node) {
return !!(ts.getCombinedNodeFlags(node) & 1 /* Let */);
}
ts.isLet = isLet;
function isSuperCall(n) {
return n.kind === 179 /* CallExpression */ && n.expression.kind === 96 /* SuperKeyword */;
}
ts.isSuperCall = isSuperCall;
function isPrologueDirective(node) {
return node.kind === 207 /* ExpressionStatement */ && node.expression.kind === 9 /* StringLiteral */;
}
ts.isPrologueDirective = isPrologueDirective;
function getLeadingCommentRangesOfNode(node, sourceFileOfNode) {
return ts.getLeadingCommentRanges(sourceFileOfNode.text, node.pos);
}
ts.getLeadingCommentRangesOfNode = getLeadingCommentRangesOfNode;
function getLeadingCommentRangesOfNodeFromText(node, text) {
return ts.getLeadingCommentRanges(text, node.pos);
}
ts.getLeadingCommentRangesOfNodeFromText = getLeadingCommentRangesOfNodeFromText;
function getJsDocComments(node, sourceFileOfNode) {
return getJsDocCommentsFromText(node, sourceFileOfNode.text);
}
ts.getJsDocComments = getJsDocComments;
function getJsDocCommentsFromText(node, text) {
var commentRanges = (node.kind === 144 /* Parameter */ ||
node.kind === 143 /* TypeParameter */ ||
node.kind === 184 /* FunctionExpression */ ||
node.kind === 185 /* ArrowFunction */) ?
ts.concatenate(ts.getTrailingCommentRanges(text, node.pos), ts.getLeadingCommentRanges(text, node.pos)) :
getLeadingCommentRangesOfNodeFromText(node, text);
return ts.filter(commentRanges, isJsDocComment);
function isJsDocComment(comment) {
// True if the comment starts with '/**' but not if it is '/**/'
return text.charCodeAt(comment.pos + 1) === 42 /* asterisk */ &&
text.charCodeAt(comment.pos + 2) === 42 /* asterisk */ &&
text.charCodeAt(comment.pos + 3) !== 47 /* slash */;
}
}
ts.getJsDocCommentsFromText = getJsDocCommentsFromText;
ts.fullTripleSlashReferencePathRegEx = /^(\/\/\/\s*<reference\s+path\s*=\s*)('|")(.+?)\2.*?\/>/;
ts.fullTripleSlashReferenceTypeReferenceDirectiveRegEx = /^(\/\/\/\s*<reference\s+types\s*=\s*)('|")(.+?)\2.*?\/>/;
ts.fullTripleSlashAMDReferencePathRegEx = /^(\/\/\/\s*<amd-dependency\s+path\s*=\s*)('|")(.+?)\2.*?\/>/;
function isPartOfTypeNode(node) {
if (156 /* FirstTypeNode */ <= node.kind && node.kind <= 171 /* LastTypeNode */) {
return true;
}
switch (node.kind) {
case 118 /* AnyKeyword */:
case 132 /* NumberKeyword */:
case 134 /* StringKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 137 /* UndefinedKeyword */:
case 129 /* NeverKeyword */:
return true;
case 104 /* VoidKeyword */:
return node.parent.kind !== 188 /* VoidExpression */;
case 199 /* ExpressionWithTypeArguments */:
return !isExpressionWithTypeArgumentsInClassExtendsClause(node);
// Identifiers and qualified names may be type nodes, depending on their context. Climb
// above them to find the lowest container
case 70 /* Identifier */:
// If the identifier is the RHS of a qualified name, then it's a type iff its parent is.
if (node.parent.kind === 141 /* QualifiedName */ && node.parent.right === node) {
node = node.parent;
}
else if (node.parent.kind === 177 /* PropertyAccessExpression */ && node.parent.name === node) {
node = node.parent;
}
// At this point, node is either a qualified name or an identifier
ts.Debug.assert(node.kind === 70 /* Identifier */ || node.kind === 141 /* QualifiedName */ || node.kind === 177 /* PropertyAccessExpression */, "'node' was expected to be a qualified name, identifier or property access in 'isPartOfTypeNode'.");
case 141 /* QualifiedName */:
case 177 /* PropertyAccessExpression */:
case 98 /* ThisKeyword */:
var parent_1 = node.parent;
if (parent_1.kind === 160 /* TypeQuery */) {
return false;
}
// Do not recursively call isPartOfTypeNode on the parent. In the example:
//
// let a: A.B.C;
//
// Calling isPartOfTypeNode would consider the qualified name A.B a type node. Only C or
// A.B.C is a type node.
if (156 /* FirstTypeNode */ <= parent_1.kind && parent_1.kind <= 171 /* LastTypeNode */) {
return true;
}
switch (parent_1.kind) {
case 199 /* ExpressionWithTypeArguments */:
return !isExpressionWithTypeArgumentsInClassExtendsClause(parent_1);
case 143 /* TypeParameter */:
return node === parent_1.constraint;
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 144 /* Parameter */:
case 223 /* VariableDeclaration */:
return node === parent_1.type;
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 150 /* Constructor */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return node === parent_1.type;
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
return node === parent_1.type;
case 182 /* TypeAssertionExpression */:
return node === parent_1.type;
case 179 /* CallExpression */:
case 180 /* NewExpression */:
return parent_1.typeArguments && ts.indexOf(parent_1.typeArguments, node) >= 0;
case 181 /* TaggedTemplateExpression */:
// TODO (drosen): TaggedTemplateExpressions may eventually support type arguments.
return false;
}
}
return false;
}
ts.isPartOfTypeNode = isPartOfTypeNode;
// Warning: This has the same semantics as the forEach family of functions,
// in that traversal terminates in the event that 'visitor' supplies a truthy value.
function forEachReturnStatement(body, visitor) {
return traverse(body);
function traverse(node) {
switch (node.kind) {
case 216 /* ReturnStatement */:
return visitor(node);
case 232 /* CaseBlock */:
case 204 /* Block */:
case 208 /* IfStatement */:
case 209 /* DoStatement */:
case 210 /* WhileStatement */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 217 /* WithStatement */:
case 218 /* SwitchStatement */:
case 253 /* CaseClause */:
case 254 /* DefaultClause */:
case 219 /* LabeledStatement */:
case 221 /* TryStatement */:
case 256 /* CatchClause */:
return ts.forEachChild(node, traverse);
}
}
}
ts.forEachReturnStatement = forEachReturnStatement;
function forEachYieldExpression(body, visitor) {
return traverse(body);
function traverse(node) {
switch (node.kind) {
case 195 /* YieldExpression */:
visitor(node);
var operand = node.expression;
if (operand) {
traverse(operand);
}
case 229 /* EnumDeclaration */:
case 227 /* InterfaceDeclaration */:
case 230 /* ModuleDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
// These are not allowed inside a generator now, but eventually they may be allowed
// as local types. Regardless, any yield statements contained within them should be
// skipped in this traversal.
return;
default:
if (isFunctionLike(node)) {
var name_5 = node.name;
if (name_5 && name_5.kind === 142 /* ComputedPropertyName */) {
// Note that we will not include methods/accessors of a class because they would require
// first descending into the class. This is by design.
traverse(name_5.expression);
return;
}
}
else if (!isPartOfTypeNode(node)) {
// This is the general case, which should include mostly expressions and statements.
// Also includes NodeArrays.
ts.forEachChild(node, traverse);
}
}
}
}
ts.forEachYieldExpression = forEachYieldExpression;
function isVariableLike(node) {
if (node) {
switch (node.kind) {
case 174 /* BindingElement */:
case 260 /* EnumMember */:
case 144 /* Parameter */:
case 257 /* PropertyAssignment */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 258 /* ShorthandPropertyAssignment */:
case 223 /* VariableDeclaration */:
return true;
}
}
return false;
}
ts.isVariableLike = isVariableLike;
function isAccessor(node) {
return node && (node.kind === 151 /* GetAccessor */ || node.kind === 152 /* SetAccessor */);
}
ts.isAccessor = isAccessor;
function isClassLike(node) {
return node && (node.kind === 226 /* ClassDeclaration */ || node.kind === 197 /* ClassExpression */);
}
ts.isClassLike = isClassLike;
function isFunctionLike(node) {
return node && isFunctionLikeKind(node.kind);
}
ts.isFunctionLike = isFunctionLike;
function isFunctionLikeKind(kind) {
switch (kind) {
case 150 /* Constructor */:
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
case 185 /* ArrowFunction */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
return true;
}
return false;
}
ts.isFunctionLikeKind = isFunctionLikeKind;
function introducesArgumentsExoticObject(node) {
switch (node.kind) {
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
return true;
}
return false;
}
ts.introducesArgumentsExoticObject = introducesArgumentsExoticObject;
function isIterationStatement(node, lookInLabeledStatements) {
switch (node.kind) {
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 209 /* DoStatement */:
case 210 /* WhileStatement */:
return true;
case 219 /* LabeledStatement */:
return lookInLabeledStatements && isIterationStatement(node.statement, lookInLabeledStatements);
}
return false;
}
ts.isIterationStatement = isIterationStatement;
function isFunctionBlock(node) {
return node && node.kind === 204 /* Block */ && isFunctionLike(node.parent);
}
ts.isFunctionBlock = isFunctionBlock;
function isObjectLiteralMethod(node) {
return node && node.kind === 149 /* MethodDeclaration */ && node.parent.kind === 176 /* ObjectLiteralExpression */;
}
ts.isObjectLiteralMethod = isObjectLiteralMethod;
function isObjectLiteralOrClassExpressionMethod(node) {
return node.kind === 149 /* MethodDeclaration */ &&
(node.parent.kind === 176 /* ObjectLiteralExpression */ ||
node.parent.kind === 197 /* ClassExpression */);
}
ts.isObjectLiteralOrClassExpressionMethod = isObjectLiteralOrClassExpressionMethod;
function isIdentifierTypePredicate(predicate) {
return predicate && predicate.kind === 1 /* Identifier */;
}
ts.isIdentifierTypePredicate = isIdentifierTypePredicate;
function isThisTypePredicate(predicate) {
return predicate && predicate.kind === 0 /* This */;
}
ts.isThisTypePredicate = isThisTypePredicate;
function getContainingFunction(node) {
while (true) {
node = node.parent;
if (!node || isFunctionLike(node)) {
return node;
}
}
}
ts.getContainingFunction = getContainingFunction;
function getContainingClass(node) {
while (true) {
node = node.parent;
if (!node || isClassLike(node)) {
return node;
}
}
}
ts.getContainingClass = getContainingClass;
function getThisContainer(node, includeArrowFunctions) {
while (true) {
node = node.parent;
if (!node) {
return undefined;
}
switch (node.kind) {
case 142 /* ComputedPropertyName */:
// If the grandparent node is an object literal (as opposed to a class),
// then the computed property is not a 'this' container.
// A computed property name in a class needs to be a this container
// so that we can error on it.
if (isClassLike(node.parent.parent)) {
return node;
}
// If this is a computed property, then the parent should not
// make it a this container. The parent might be a property
// in an object literal, like a method or accessor. But in order for
// such a parent to be a this container, the reference must be in
// the *body* of the container.
node = node.parent;
break;
case 145 /* Decorator */:
// Decorators are always applied outside of the body of a class or method.
if (node.parent.kind === 144 /* Parameter */ && isClassElement(node.parent.parent)) {
// If the decorator's parent is a Parameter, we resolve the this container from
// the grandparent class declaration.
node = node.parent.parent;
}
else if (isClassElement(node.parent)) {
// If the decorator's parent is a class element, we resolve the 'this' container
// from the parent class declaration.
node = node.parent;
}
break;
case 185 /* ArrowFunction */:
if (!includeArrowFunctions) {
continue;
}
// Fall through
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 230 /* ModuleDeclaration */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 229 /* EnumDeclaration */:
case 261 /* SourceFile */:
return node;
}
}
}
ts.getThisContainer = getThisContainer;
/**
* Given an super call/property node, returns the closest node where
* - a super call/property access is legal in the node and not legal in the parent node the node.
* i.e. super call is legal in constructor but not legal in the class body.
* - the container is an arrow function (so caller might need to call getSuperContainer again in case it needs to climb higher)
* - a super call/property is definitely illegal in the container (but might be legal in some subnode)
* i.e. super property access is illegal in function declaration but can be legal in the statement list
*/
function getSuperContainer(node, stopOnFunctions) {
while (true) {
node = node.parent;
if (!node) {
return node;
}
switch (node.kind) {
case 142 /* ComputedPropertyName */:
node = node.parent;
break;
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
if (!stopOnFunctions) {
continue;
}
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return node;
case 145 /* Decorator */:
// Decorators are always applied outside of the body of a class or method.
if (node.parent.kind === 144 /* Parameter */ && isClassElement(node.parent.parent)) {
// If the decorator's parent is a Parameter, we resolve the this container from
// the grandparent class declaration.
node = node.parent.parent;
}
else if (isClassElement(node.parent)) {
// If the decorator's parent is a class element, we resolve the 'this' container
// from the parent class declaration.
node = node.parent;
}
break;
}
}
}
ts.getSuperContainer = getSuperContainer;
function getImmediatelyInvokedFunctionExpression(func) {
if (func.kind === 184 /* FunctionExpression */ || func.kind === 185 /* ArrowFunction */) {
var prev = func;
var parent_2 = func.parent;
while (parent_2.kind === 183 /* ParenthesizedExpression */) {
prev = parent_2;
parent_2 = parent_2.parent;
}
if (parent_2.kind === 179 /* CallExpression */ && parent_2.expression === prev) {
return parent_2;
}
}
}
ts.getImmediatelyInvokedFunctionExpression = getImmediatelyInvokedFunctionExpression;
/**
* Determines whether a node is a property or element access expression for super.
*/
function isSuperProperty(node) {
var kind = node.kind;
return (kind === 177 /* PropertyAccessExpression */ || kind === 178 /* ElementAccessExpression */)
&& node.expression.kind === 96 /* SuperKeyword */;
}
ts.isSuperProperty = isSuperProperty;
function getEntityNameFromTypeNode(node) {
switch (node.kind) {
case 157 /* TypeReference */:
case 272 /* JSDocTypeReference */:
return node.typeName;
case 199 /* ExpressionWithTypeArguments */:
return isEntityNameExpression(node.expression)
? node.expression
: undefined;
case 70 /* Identifier */:
case 141 /* QualifiedName */:
return node;
}
return undefined;
}
ts.getEntityNameFromTypeNode = getEntityNameFromTypeNode;
function isCallLikeExpression(node) {
switch (node.kind) {
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 181 /* TaggedTemplateExpression */:
case 145 /* Decorator */:
return true;
default:
return false;
}
}
ts.isCallLikeExpression = isCallLikeExpression;
function getInvokedExpression(node) {
if (node.kind === 181 /* TaggedTemplateExpression */) {
return node.tag;
}
// Will either be a CallExpression, NewExpression, or Decorator.
return node.expression;
}
ts.getInvokedExpression = getInvokedExpression;
function nodeCanBeDecorated(node) {
switch (node.kind) {
case 226 /* ClassDeclaration */:
// classes are valid targets
return true;
case 147 /* PropertyDeclaration */:
// property declarations are valid if their parent is a class declaration.
return node.parent.kind === 226 /* ClassDeclaration */;
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 149 /* MethodDeclaration */:
// if this method has a body and its parent is a class declaration, this is a valid target.
return node.body !== undefined
&& node.parent.kind === 226 /* ClassDeclaration */;
case 144 /* Parameter */:
// if the parameter's parent has a body and its grandparent is a class declaration, this is a valid target;
return node.parent.body !== undefined
&& (node.parent.kind === 150 /* Constructor */
|| node.parent.kind === 149 /* MethodDeclaration */
|| node.parent.kind === 152 /* SetAccessor */)
&& node.parent.parent.kind === 226 /* ClassDeclaration */;
}
return false;
}
ts.nodeCanBeDecorated = nodeCanBeDecorated;
function nodeIsDecorated(node) {
return node.decorators !== undefined
&& nodeCanBeDecorated(node);
}
ts.nodeIsDecorated = nodeIsDecorated;
function nodeOrChildIsDecorated(node) {
return nodeIsDecorated(node) || childIsDecorated(node);
}
ts.nodeOrChildIsDecorated = nodeOrChildIsDecorated;
function childIsDecorated(node) {
switch (node.kind) {
case 226 /* ClassDeclaration */:
return ts.forEach(node.members, nodeOrChildIsDecorated);
case 149 /* MethodDeclaration */:
case 152 /* SetAccessor */:
return ts.forEach(node.parameters, nodeIsDecorated);
}
}
ts.childIsDecorated = childIsDecorated;
function isJSXTagName(node) {
var parent = node.parent;
if (parent.kind === 248 /* JsxOpeningElement */ ||
parent.kind === 247 /* JsxSelfClosingElement */ ||
parent.kind === 249 /* JsxClosingElement */) {
return parent.tagName === node;
}
return false;
}
ts.isJSXTagName = isJSXTagName;
function isPartOfExpression(node) {
switch (node.kind) {
case 98 /* ThisKeyword */:
case 96 /* SuperKeyword */:
case 94 /* NullKeyword */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
case 11 /* RegularExpressionLiteral */:
case 175 /* ArrayLiteralExpression */:
case 176 /* ObjectLiteralExpression */:
case 177 /* PropertyAccessExpression */:
case 178 /* ElementAccessExpression */:
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 181 /* TaggedTemplateExpression */:
case 200 /* AsExpression */:
case 182 /* TypeAssertionExpression */:
case 201 /* NonNullExpression */:
case 183 /* ParenthesizedExpression */:
case 184 /* FunctionExpression */:
case 197 /* ClassExpression */:
case 185 /* ArrowFunction */:
case 188 /* VoidExpression */:
case 186 /* DeleteExpression */:
case 187 /* TypeOfExpression */:
case 190 /* PrefixUnaryExpression */:
case 191 /* PostfixUnaryExpression */:
case 192 /* BinaryExpression */:
case 193 /* ConditionalExpression */:
case 196 /* SpreadElement */:
case 194 /* TemplateExpression */:
case 12 /* NoSubstitutionTemplateLiteral */:
case 198 /* OmittedExpression */:
case 246 /* JsxElement */:
case 247 /* JsxSelfClosingElement */:
case 195 /* YieldExpression */:
case 189 /* AwaitExpression */:
return true;
case 141 /* QualifiedName */:
while (node.parent.kind === 141 /* QualifiedName */) {
node = node.parent;
}
return node.parent.kind === 160 /* TypeQuery */ || isJSXTagName(node);
case 70 /* Identifier */:
if (node.parent.kind === 160 /* TypeQuery */ || isJSXTagName(node)) {
return true;
}
// fall through
case 8 /* NumericLiteral */:
case 9 /* StringLiteral */:
case 98 /* ThisKeyword */:
var parent_3 = node.parent;
switch (parent_3.kind) {
case 223 /* VariableDeclaration */:
case 144 /* Parameter */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 260 /* EnumMember */:
case 257 /* PropertyAssignment */:
case 174 /* BindingElement */:
return parent_3.initializer === node;
case 207 /* ExpressionStatement */:
case 208 /* IfStatement */:
case 209 /* DoStatement */:
case 210 /* WhileStatement */:
case 216 /* ReturnStatement */:
case 217 /* WithStatement */:
case 218 /* SwitchStatement */:
case 253 /* CaseClause */:
case 220 /* ThrowStatement */:
case 218 /* SwitchStatement */:
return parent_3.expression === node;
case 211 /* ForStatement */:
var forStatement = parent_3;
return (forStatement.initializer === node && forStatement.initializer.kind !== 224 /* VariableDeclarationList */) ||
forStatement.condition === node ||
forStatement.incrementor === node;
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
var forInStatement = parent_3;
return (forInStatement.initializer === node && forInStatement.initializer.kind !== 224 /* VariableDeclarationList */) ||
forInStatement.expression === node;
case 182 /* TypeAssertionExpression */:
case 200 /* AsExpression */:
return node === parent_3.expression;
case 202 /* TemplateSpan */:
return node === parent_3.expression;
case 142 /* ComputedPropertyName */:
return node === parent_3.expression;
case 145 /* Decorator */:
case 252 /* JsxExpression */:
case 251 /* JsxSpreadAttribute */:
return true;
case 199 /* ExpressionWithTypeArguments */:
return parent_3.expression === node && isExpressionWithTypeArgumentsInClassExtendsClause(parent_3);
default:
if (isPartOfExpression(parent_3)) {
return true;
}
}
}
return false;
}
ts.isPartOfExpression = isPartOfExpression;
function isInstantiatedModule(node, preserveConstEnums) {
var moduleState = ts.getModuleInstanceState(node);
return moduleState === 1 /* Instantiated */ ||
(preserveConstEnums && moduleState === 2 /* ConstEnumOnly */);
}
ts.isInstantiatedModule = isInstantiatedModule;
function isExternalModuleImportEqualsDeclaration(node) {
return node.kind === 234 /* ImportEqualsDeclaration */ && node.moduleReference.kind === 245 /* ExternalModuleReference */;
}
ts.isExternalModuleImportEqualsDeclaration = isExternalModuleImportEqualsDeclaration;
function getExternalModuleImportEqualsDeclarationExpression(node) {
ts.Debug.assert(isExternalModuleImportEqualsDeclaration(node));
return node.moduleReference.expression;
}
ts.getExternalModuleImportEqualsDeclarationExpression = getExternalModuleImportEqualsDeclarationExpression;
function isInternalModuleImportEqualsDeclaration(node) {
return node.kind === 234 /* ImportEqualsDeclaration */ && node.moduleReference.kind !== 245 /* ExternalModuleReference */;
}
ts.isInternalModuleImportEqualsDeclaration = isInternalModuleImportEqualsDeclaration;
function isSourceFileJavaScript(file) {
return isInJavaScriptFile(file);
}
ts.isSourceFileJavaScript = isSourceFileJavaScript;
function isInJavaScriptFile(node) {
return node && !!(node.flags & 2097152 /* JavaScriptFile */);
}
ts.isInJavaScriptFile = isInJavaScriptFile;
/**
* Returns true if the node is a CallExpression to the identifier 'require' with
* exactly one argument.
* This function does not test if the node is in a JavaScript file or not.
*/
function isRequireCall(expression, checkArgumentIsStringLiteral) {
// of the form 'require("name")'
var isRequire = expression.kind === 179 /* CallExpression */ &&
expression.expression.kind === 70 /* Identifier */ &&
expression.expression.text === "require" &&
expression.arguments.length === 1;
return isRequire && (!checkArgumentIsStringLiteral || expression.arguments[0].kind === 9 /* StringLiteral */);
}
ts.isRequireCall = isRequireCall;
function isSingleOrDoubleQuote(charCode) {
return charCode === 39 /* singleQuote */ || charCode === 34 /* doubleQuote */;
}
ts.isSingleOrDoubleQuote = isSingleOrDoubleQuote;
/**
* Returns true if the node is a variable declaration whose initializer is a function expression.
* This function does not test if the node is in a JavaScript file or not.
*/
function isDeclarationOfFunctionExpression(s) {
if (s.valueDeclaration && s.valueDeclaration.kind === 223 /* VariableDeclaration */) {
var declaration = s.valueDeclaration;
return declaration.initializer && declaration.initializer.kind === 184 /* FunctionExpression */;
}
return false;
}
ts.isDeclarationOfFunctionExpression = isDeclarationOfFunctionExpression;
/// Given a BinaryExpression, returns SpecialPropertyAssignmentKind for the various kinds of property
/// assignments we treat as special in the binder
function getSpecialPropertyAssignmentKind(expression) {
if (!isInJavaScriptFile(expression)) {
return 0 /* None */;
}
if (expression.kind !== 192 /* BinaryExpression */) {
return 0 /* None */;
}
var expr = expression;
if (expr.operatorToken.kind !== 57 /* EqualsToken */ || expr.left.kind !== 177 /* PropertyAccessExpression */) {
return 0 /* None */;
}
var lhs = expr.left;
if (lhs.expression.kind === 70 /* Identifier */) {
var lhsId = lhs.expression;
if (lhsId.text === "exports") {
// exports.name = expr
return 1 /* ExportsProperty */;
}
else if (lhsId.text === "module" && lhs.name.text === "exports") {
// module.exports = expr
return 2 /* ModuleExports */;
}
}
else if (lhs.expression.kind === 98 /* ThisKeyword */) {
return 4 /* ThisProperty */;
}
else if (lhs.expression.kind === 177 /* PropertyAccessExpression */) {
// chained dot, e.g. x.y.z = expr; this var is the 'x.y' part
var innerPropertyAccess = lhs.expression;
if (innerPropertyAccess.expression.kind === 70 /* Identifier */) {
// module.exports.name = expr
var innerPropertyAccessIdentifier = innerPropertyAccess.expression;
if (innerPropertyAccessIdentifier.text === "module" && innerPropertyAccess.name.text === "exports") {
return 1 /* ExportsProperty */;
}
if (innerPropertyAccess.name.text === "prototype") {
return 3 /* PrototypeProperty */;
}
}
}
return 0 /* None */;
}
ts.getSpecialPropertyAssignmentKind = getSpecialPropertyAssignmentKind;
function getExternalModuleName(node) {
if (node.kind === 235 /* ImportDeclaration */) {
return node.moduleSpecifier;
}
if (node.kind === 234 /* ImportEqualsDeclaration */) {
var reference = node.moduleReference;
if (reference.kind === 245 /* ExternalModuleReference */) {
return reference.expression;
}
}
if (node.kind === 241 /* ExportDeclaration */) {
return node.moduleSpecifier;
}
if (node.kind === 230 /* ModuleDeclaration */ && node.name.kind === 9 /* StringLiteral */) {
return node.name;
}
}
ts.getExternalModuleName = getExternalModuleName;
function getNamespaceDeclarationNode(node) {
if (node.kind === 234 /* ImportEqualsDeclaration */) {
return node;
}
var importClause = node.importClause;
if (importClause && importClause.namedBindings && importClause.namedBindings.kind === 237 /* NamespaceImport */) {
return importClause.namedBindings;
}
}
ts.getNamespaceDeclarationNode = getNamespaceDeclarationNode;
function isDefaultImport(node) {
return node.kind === 235 /* ImportDeclaration */
&& node.importClause
&& !!node.importClause.name;
}
ts.isDefaultImport = isDefaultImport;
function hasQuestionToken(node) {
if (node) {
switch (node.kind) {
case 144 /* Parameter */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 258 /* ShorthandPropertyAssignment */:
case 257 /* PropertyAssignment */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
return node.questionToken !== undefined;
}
}
return false;
}
ts.hasQuestionToken = hasQuestionToken;
function isJSDocConstructSignature(node) {
return node.kind === 274 /* JSDocFunctionType */ &&
node.parameters.length > 0 &&
node.parameters[0].type.kind === 276 /* JSDocConstructorType */;
}
ts.isJSDocConstructSignature = isJSDocConstructSignature;
function getJSDocTag(node, kind, checkParentVariableStatement) {
if (!node) {
return undefined;
}
var jsDocTags = getJSDocTags(node, checkParentVariableStatement);
if (!jsDocTags) {
return undefined;
}
for (var _i = 0, jsDocTags_1 = jsDocTags; _i < jsDocTags_1.length; _i++) {
var tag = jsDocTags_1[_i];
if (tag.kind === kind) {
return tag;
}
}
}
function append(previous, additional) {
if (additional) {
if (!previous) {
previous = [];
}
for (var _i = 0, additional_1 = additional; _i < additional_1.length; _i++) {
var x = additional_1[_i];
previous.push(x);
}
}
return previous;
}
function getJSDocComments(node, checkParentVariableStatement) {
return getJSDocs(node, checkParentVariableStatement, function (docs) { return ts.map(docs, function (doc) { return doc.comment; }); }, function (tags) { return ts.map(tags, function (tag) { return tag.comment; }); });
}
ts.getJSDocComments = getJSDocComments;
function getJSDocTags(node, checkParentVariableStatement) {
return getJSDocs(node, checkParentVariableStatement, function (docs) {
var result = [];
for (var _i = 0, docs_1 = docs; _i < docs_1.length; _i++) {
var doc = docs_1[_i];
if (doc.tags) {
result.push.apply(result, doc.tags);
}
}
return result;
}, function (tags) { return tags; });
}
function getJSDocs(node, checkParentVariableStatement, getDocs, getTags) {
// TODO: Get rid of getJsDocComments and friends (note the lowercase 's' in Js)
// TODO: A lot of this work should be cached, maybe. I guess it's only used in services right now...
var result = undefined;
// prepend documentation from parent sources
if (checkParentVariableStatement) {
// Try to recognize this pattern when node is initializer of variable declaration and JSDoc comments are on containing variable statement.
// /**
// * @param {number} name
// * @returns {number}
// */
// var x = function(name) { return name.length; }
var isInitializerOfVariableDeclarationInStatement = isVariableLike(node.parent) &&
(node.parent).initializer === node &&
node.parent.parent.parent.kind === 205 /* VariableStatement */;
var isVariableOfVariableDeclarationStatement = isVariableLike(node) &&
node.parent.parent.kind === 205 /* VariableStatement */;
var variableStatementNode = isInitializerOfVariableDeclarationInStatement ? node.parent.parent.parent :
isVariableOfVariableDeclarationStatement ? node.parent.parent :
undefined;
if (variableStatementNode) {
result = append(result, getJSDocs(variableStatementNode, checkParentVariableStatement, getDocs, getTags));
}
if (node.kind === 230 /* ModuleDeclaration */ &&
node.parent && node.parent.kind === 230 /* ModuleDeclaration */) {
result = append(result, getJSDocs(node.parent, checkParentVariableStatement, getDocs, getTags));
}
// Also recognize when the node is the RHS of an assignment expression
var parent_4 = node.parent;
var isSourceOfAssignmentExpressionStatement = parent_4 && parent_4.parent &&
parent_4.kind === 192 /* BinaryExpression */ &&
parent_4.operatorToken.kind === 57 /* EqualsToken */ &&
parent_4.parent.kind === 207 /* ExpressionStatement */;
if (isSourceOfAssignmentExpressionStatement) {
result = append(result, getJSDocs(parent_4.parent, checkParentVariableStatement, getDocs, getTags));
}
var isPropertyAssignmentExpression = parent_4 && parent_4.kind === 257 /* PropertyAssignment */;
if (isPropertyAssignmentExpression) {
result = append(result, getJSDocs(parent_4, checkParentVariableStatement, getDocs, getTags));
}
// Pull parameter comments from declaring function as well
if (node.kind === 144 /* Parameter */) {
var paramTags = getJSDocParameterTag(node, checkParentVariableStatement);
if (paramTags) {
result = append(result, getTags(paramTags));
}
}
}
if (isVariableLike(node) && node.initializer) {
result = append(result, getJSDocs(node.initializer, /*checkParentVariableStatement*/ false, getDocs, getTags));
}
if (node.jsDocComments) {
if (result) {
result = append(result, getDocs(node.jsDocComments));
}
else {
return getDocs(node.jsDocComments);
}
}
return result;
}
function getJSDocParameterTag(param, checkParentVariableStatement) {
var func = param.parent;
var tags = getJSDocTags(func, checkParentVariableStatement);
if (!param.name) {
// this is an anonymous jsdoc param from a `function(type1, type2): type3` specification
var i = func.parameters.indexOf(param);
var paramTags = ts.filter(tags, function (tag) { return tag.kind === 280 /* JSDocParameterTag */; });
if (paramTags && 0 <= i && i < paramTags.length) {
return [paramTags[i]];
}
}
else if (param.name.kind === 70 /* Identifier */) {
var name_6 = param.name.text;
var paramTags = ts.filter(tags, function (tag) { return tag.kind === 280 /* JSDocParameterTag */ && tag.parameterName.text === name_6; });
if (paramTags) {
return paramTags;
}
}
else {
// TODO: it's a destructured parameter, so it should look up an "object type" series of multiple lines
// But multi-line object types aren't supported yet either
return undefined;
}
}
function getJSDocTypeTag(node) {
return getJSDocTag(node, 282 /* JSDocTypeTag */, /*checkParentVariableStatement*/ false);
}
ts.getJSDocTypeTag = getJSDocTypeTag;
function getJSDocReturnTag(node) {
return getJSDocTag(node, 281 /* JSDocReturnTag */, /*checkParentVariableStatement*/ true);
}
ts.getJSDocReturnTag = getJSDocReturnTag;
function getJSDocTemplateTag(node) {
return getJSDocTag(node, 283 /* JSDocTemplateTag */, /*checkParentVariableStatement*/ false);
}
ts.getJSDocTemplateTag = getJSDocTemplateTag;
function getCorrespondingJSDocParameterTag(parameter) {
if (parameter.name && parameter.name.kind === 70 /* Identifier */) {
// If it's a parameter, see if the parent has a jsdoc comment with an @param
// annotation.
var parameterName = parameter.name.text;
var jsDocTags = getJSDocTags(parameter.parent, /*checkParentVariableStatement*/ true);
if (!jsDocTags) {
return undefined;
}
for (var _i = 0, jsDocTags_2 = jsDocTags; _i < jsDocTags_2.length; _i++) {
var tag = jsDocTags_2[_i];
if (tag.kind === 280 /* JSDocParameterTag */) {
var parameterTag = tag;
if (parameterTag.parameterName.text === parameterName) {
return parameterTag;
}
}
}
}
return undefined;
}
ts.getCorrespondingJSDocParameterTag = getCorrespondingJSDocParameterTag;
function hasRestParameter(s) {
return isRestParameter(ts.lastOrUndefined(s.parameters));
}
ts.hasRestParameter = hasRestParameter;
function hasDeclaredRestParameter(s) {
return isDeclaredRestParam(ts.lastOrUndefined(s.parameters));
}
ts.hasDeclaredRestParameter = hasDeclaredRestParameter;
function isRestParameter(node) {
if (node && (node.flags & 2097152 /* JavaScriptFile */)) {
if (node.type && node.type.kind === 275 /* JSDocVariadicType */) {
return true;
}
var paramTag = getCorrespondingJSDocParameterTag(node);
if (paramTag && paramTag.typeExpression) {
return paramTag.typeExpression.type.kind === 275 /* JSDocVariadicType */;
}
}
return isDeclaredRestParam(node);
}
ts.isRestParameter = isRestParameter;
function isDeclaredRestParam(node) {
return node && node.dotDotDotToken !== undefined;
}
ts.isDeclaredRestParam = isDeclaredRestParam;
var AssignmentKind;
(function (AssignmentKind) {
AssignmentKind[AssignmentKind["None"] = 0] = "None";
AssignmentKind[AssignmentKind["Definite"] = 1] = "Definite";
AssignmentKind[AssignmentKind["Compound"] = 2] = "Compound";
})(AssignmentKind = ts.AssignmentKind || (ts.AssignmentKind = {}));
function getAssignmentTargetKind(node) {
var parent = node.parent;
while (true) {
switch (parent.kind) {
case 192 /* BinaryExpression */:
var binaryOperator = parent.operatorToken.kind;
return isAssignmentOperator(binaryOperator) && parent.left === node ?
binaryOperator === 57 /* EqualsToken */ ? 1 /* Definite */ : 2 /* Compound */ :
0 /* None */;
case 190 /* PrefixUnaryExpression */:
case 191 /* PostfixUnaryExpression */:
var unaryOperator = parent.operator;
return unaryOperator === 42 /* PlusPlusToken */ || unaryOperator === 43 /* MinusMinusToken */ ? 2 /* Compound */ : 0 /* None */;
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
return parent.initializer === node ? 1 /* Definite */ : 0 /* None */;
case 183 /* ParenthesizedExpression */:
case 175 /* ArrayLiteralExpression */:
case 196 /* SpreadElement */:
node = parent;
break;
case 258 /* ShorthandPropertyAssignment */:
if (parent.name !== node) {
return 0 /* None */;
}
// Fall through
case 257 /* PropertyAssignment */:
node = parent.parent;
break;
default:
return 0 /* None */;
}
parent = node.parent;
}
}
ts.getAssignmentTargetKind = getAssignmentTargetKind;
// A node is an assignment target if it is on the left hand side of an '=' token, if it is parented by a property
// assignment in an object literal that is an assignment target, or if it is parented by an array literal that is
// an assignment target. Examples include 'a = xxx', '{ p: a } = xxx', '[{ p: a}] = xxx'.
function isAssignmentTarget(node) {
return getAssignmentTargetKind(node) !== 0 /* None */;
}
ts.isAssignmentTarget = isAssignmentTarget;
function isNodeDescendantOf(node, ancestor) {
while (node) {
if (node === ancestor)
return true;
node = node.parent;
}
return false;
}
ts.isNodeDescendantOf = isNodeDescendantOf;
function isInAmbientContext(node) {
while (node) {
if (hasModifier(node, 2 /* Ambient */) || (node.kind === 261 /* SourceFile */ && node.isDeclarationFile)) {
return true;
}
node = node.parent;
}
return false;
}
ts.isInAmbientContext = isInAmbientContext;
// True if the given identifier, string literal, or number literal is the name of a declaration node
function isDeclarationName(name) {
if (name.kind !== 70 /* Identifier */ && name.kind !== 9 /* StringLiteral */ && name.kind !== 8 /* NumericLiteral */) {
return false;
}
var parent = name.parent;
if (parent.kind === 239 /* ImportSpecifier */ || parent.kind === 243 /* ExportSpecifier */) {
if (parent.propertyName) {
return true;
}
}
if (isDeclaration(parent)) {
return parent.name === name;
}
return false;
}
ts.isDeclarationName = isDeclarationName;
function isLiteralComputedPropertyDeclarationName(node) {
return (node.kind === 9 /* StringLiteral */ || node.kind === 8 /* NumericLiteral */) &&
node.parent.kind === 142 /* ComputedPropertyName */ &&
isDeclaration(node.parent.parent);
}
ts.isLiteralComputedPropertyDeclarationName = isLiteralComputedPropertyDeclarationName;
// Return true if the given identifier is classified as an IdentifierName
function isIdentifierName(node) {
var parent = node.parent;
switch (parent.kind) {
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 260 /* EnumMember */:
case 257 /* PropertyAssignment */:
case 177 /* PropertyAccessExpression */:
// Name in member declaration or property name in property access
return parent.name === node;
case 141 /* QualifiedName */:
// Name on right hand side of dot in a type query
if (parent.right === node) {
while (parent.kind === 141 /* QualifiedName */) {
parent = parent.parent;
}
return parent.kind === 160 /* TypeQuery */;
}
return false;
case 174 /* BindingElement */:
case 239 /* ImportSpecifier */:
// Property name in binding element or import specifier
return parent.propertyName === node;
case 243 /* ExportSpecifier */:
// Any name in an export specifier
return true;
}
return false;
}
ts.isIdentifierName = isIdentifierName;
// An alias symbol is created by one of the following declarations:
// import <symbol> = ...
// import <symbol> from ...
// import * as <symbol> from ...
// import { x as <symbol> } from ...
// export { x as <symbol> } from ...
// export = <EntityNameExpression>
// export default <EntityNameExpression>
function isAliasSymbolDeclaration(node) {
return node.kind === 234 /* ImportEqualsDeclaration */ ||
node.kind === 233 /* NamespaceExportDeclaration */ ||
node.kind === 236 /* ImportClause */ && !!node.name ||
node.kind === 237 /* NamespaceImport */ ||
node.kind === 239 /* ImportSpecifier */ ||
node.kind === 243 /* ExportSpecifier */ ||
node.kind === 240 /* ExportAssignment */ && exportAssignmentIsAlias(node);
}
ts.isAliasSymbolDeclaration = isAliasSymbolDeclaration;
function exportAssignmentIsAlias(node) {
return isEntityNameExpression(node.expression);
}
ts.exportAssignmentIsAlias = exportAssignmentIsAlias;
function getClassExtendsHeritageClauseElement(node) {
var heritageClause = getHeritageClause(node.heritageClauses, 84 /* ExtendsKeyword */);
return heritageClause && heritageClause.types.length > 0 ? heritageClause.types[0] : undefined;
}
ts.getClassExtendsHeritageClauseElement = getClassExtendsHeritageClauseElement;
function getClassImplementsHeritageClauseElements(node) {
var heritageClause = getHeritageClause(node.heritageClauses, 107 /* ImplementsKeyword */);
return heritageClause ? heritageClause.types : undefined;
}
ts.getClassImplementsHeritageClauseElements = getClassImplementsHeritageClauseElements;
function getInterfaceBaseTypeNodes(node) {
var heritageClause = getHeritageClause(node.heritageClauses, 84 /* ExtendsKeyword */);
return heritageClause ? heritageClause.types : undefined;
}
ts.getInterfaceBaseTypeNodes = getInterfaceBaseTypeNodes;
function getHeritageClause(clauses, kind) {
if (clauses) {
for (var _i = 0, clauses_1 = clauses; _i < clauses_1.length; _i++) {
var clause = clauses_1[_i];
if (clause.token === kind) {
return clause;
}
}
}
return undefined;
}
ts.getHeritageClause = getHeritageClause;
function tryResolveScriptReference(host, sourceFile, reference) {
if (!host.getCompilerOptions().noResolve) {
var referenceFileName = ts.isRootedDiskPath(reference.fileName) ? reference.fileName : ts.combinePaths(ts.getDirectoryPath(sourceFile.fileName), reference.fileName);
return host.getSourceFile(referenceFileName);
}
}
ts.tryResolveScriptReference = tryResolveScriptReference;
function getAncestor(node, kind) {
while (node) {
if (node.kind === kind) {
return node;
}
node = node.parent;
}
return undefined;
}
ts.getAncestor = getAncestor;
function getFileReferenceFromReferencePath(comment, commentRange) {
var simpleReferenceRegEx = /^\/\/\/\s*<reference\s+/gim;
var isNoDefaultLibRegEx = /^(\/\/\/\s*<reference\s+no-default-lib\s*=\s*)('|")(.+?)\2\s*\/>/gim;
if (simpleReferenceRegEx.test(comment)) {
if (isNoDefaultLibRegEx.test(comment)) {
return {
isNoDefaultLib: true
};
}
else {
var refMatchResult = ts.fullTripleSlashReferencePathRegEx.exec(comment);
var refLibResult = !refMatchResult && ts.fullTripleSlashReferenceTypeReferenceDirectiveRegEx.exec(comment);
if (refMatchResult || refLibResult) {
var start = commentRange.pos;
var end = commentRange.end;
return {
fileReference: {
pos: start,
end: end,
fileName: (refMatchResult || refLibResult)[3]
},
isNoDefaultLib: false,
isTypeReferenceDirective: !!refLibResult
};
}
return {
diagnosticMessage: ts.Diagnostics.Invalid_reference_directive_syntax,
isNoDefaultLib: false
};
}
}
return undefined;
}
ts.getFileReferenceFromReferencePath = getFileReferenceFromReferencePath;
function isKeyword(token) {
return 71 /* FirstKeyword */ <= token && token <= 140 /* LastKeyword */;
}
ts.isKeyword = isKeyword;
function isTrivia(token) {
return 2 /* FirstTriviaToken */ <= token && token <= 7 /* LastTriviaToken */;
}
ts.isTrivia = isTrivia;
function isAsyncFunctionLike(node) {
return isFunctionLike(node) && hasModifier(node, 256 /* Async */) && !isAccessor(node);
}
ts.isAsyncFunctionLike = isAsyncFunctionLike;
function isStringOrNumericLiteral(kind) {
return kind === 9 /* StringLiteral */ || kind === 8 /* NumericLiteral */;
}
ts.isStringOrNumericLiteral = isStringOrNumericLiteral;
/**
* A declaration has a dynamic name if both of the following are true:
* 1. The declaration has a computed property name
* 2. The computed name is *not* expressed as Symbol.<name>, where name
* is a property of the Symbol constructor that denotes a built in
* Symbol.
*/
function hasDynamicName(declaration) {
return declaration.name && isDynamicName(declaration.name);
}
ts.hasDynamicName = hasDynamicName;
function isDynamicName(name) {
return name.kind === 142 /* ComputedPropertyName */ &&
!isStringOrNumericLiteral(name.expression.kind) &&
!isWellKnownSymbolSyntactically(name.expression);
}
ts.isDynamicName = isDynamicName;
/**
* Checks if the expression is of the form:
* Symbol.name
* where Symbol is literally the word "Symbol", and name is any identifierName
*/
function isWellKnownSymbolSyntactically(node) {
return isPropertyAccessExpression(node) && isESSymbolIdentifier(node.expression);
}
ts.isWellKnownSymbolSyntactically = isWellKnownSymbolSyntactically;
function getPropertyNameForPropertyNameNode(name) {
if (name.kind === 70 /* Identifier */ || name.kind === 9 /* StringLiteral */ || name.kind === 8 /* NumericLiteral */ || name.kind === 144 /* Parameter */) {
return name.text;
}
if (name.kind === 142 /* ComputedPropertyName */) {
var nameExpression = name.expression;
if (isWellKnownSymbolSyntactically(nameExpression)) {
var rightHandSideName = nameExpression.name.text;
return getPropertyNameForKnownSymbolName(rightHandSideName);
}
else if (nameExpression.kind === 9 /* StringLiteral */ || nameExpression.kind === 8 /* NumericLiteral */) {
return nameExpression.text;
}
}
return undefined;
}
ts.getPropertyNameForPropertyNameNode = getPropertyNameForPropertyNameNode;
function getPropertyNameForKnownSymbolName(symbolName) {
return "__@" + symbolName;
}
ts.getPropertyNameForKnownSymbolName = getPropertyNameForKnownSymbolName;
/**
* Includes the word "Symbol" with unicode escapes
*/
function isESSymbolIdentifier(node) {
return node.kind === 70 /* Identifier */ && node.text === "Symbol";
}
ts.isESSymbolIdentifier = isESSymbolIdentifier;
function isPushOrUnshiftIdentifier(node) {
return node.text === "push" || node.text === "unshift";
}
ts.isPushOrUnshiftIdentifier = isPushOrUnshiftIdentifier;
function isModifierKind(token) {
switch (token) {
case 116 /* AbstractKeyword */:
case 119 /* AsyncKeyword */:
case 75 /* ConstKeyword */:
case 123 /* DeclareKeyword */:
case 78 /* DefaultKeyword */:
case 83 /* ExportKeyword */:
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 130 /* ReadonlyKeyword */:
case 114 /* StaticKeyword */:
return true;
}
return false;
}
ts.isModifierKind = isModifierKind;
function isParameterDeclaration(node) {
var root = getRootDeclaration(node);
return root.kind === 144 /* Parameter */;
}
ts.isParameterDeclaration = isParameterDeclaration;
function getRootDeclaration(node) {
while (node.kind === 174 /* BindingElement */) {
node = node.parent.parent;
}
return node;
}
ts.getRootDeclaration = getRootDeclaration;
function nodeStartsNewLexicalEnvironment(node) {
var kind = node.kind;
return kind === 150 /* Constructor */
|| kind === 184 /* FunctionExpression */
|| kind === 225 /* FunctionDeclaration */
|| kind === 185 /* ArrowFunction */
|| kind === 149 /* MethodDeclaration */
|| kind === 151 /* GetAccessor */
|| kind === 152 /* SetAccessor */
|| kind === 230 /* ModuleDeclaration */
|| kind === 261 /* SourceFile */;
}
ts.nodeStartsNewLexicalEnvironment = nodeStartsNewLexicalEnvironment;
function nodeIsSynthesized(node) {
return ts.positionIsSynthesized(node.pos)
|| ts.positionIsSynthesized(node.end);
}
ts.nodeIsSynthesized = nodeIsSynthesized;
function getOriginalNode(node, nodeTest) {
if (node) {
while (node.original !== undefined) {
node = node.original;
}
}
return !nodeTest || nodeTest(node) ? node : undefined;
}
ts.getOriginalNode = getOriginalNode;
/**
* Gets a value indicating whether a node originated in the parse tree.
*
* @param node The node to test.
*/
function isParseTreeNode(node) {
return (node.flags & 8 /* Synthesized */) === 0;
}
ts.isParseTreeNode = isParseTreeNode;
function getParseTreeNode(node, nodeTest) {
if (isParseTreeNode(node)) {
return node;
}
node = getOriginalNode(node);
if (isParseTreeNode(node) && (!nodeTest || nodeTest(node))) {
return node;
}
return undefined;
}
ts.getParseTreeNode = getParseTreeNode;
function getOriginalSourceFiles(sourceFiles) {
var originalSourceFiles = [];
for (var _i = 0, sourceFiles_1 = sourceFiles; _i < sourceFiles_1.length; _i++) {
var sourceFile = sourceFiles_1[_i];
var originalSourceFile = getParseTreeNode(sourceFile, isSourceFile);
if (originalSourceFile) {
originalSourceFiles.push(originalSourceFile);
}
}
return originalSourceFiles;
}
ts.getOriginalSourceFiles = getOriginalSourceFiles;
function getOriginalNodeId(node) {
node = getOriginalNode(node);
return node ? ts.getNodeId(node) : 0;
}
ts.getOriginalNodeId = getOriginalNodeId;
var Associativity;
(function (Associativity) {
Associativity[Associativity["Left"] = 0] = "Left";
Associativity[Associativity["Right"] = 1] = "Right";
})(Associativity = ts.Associativity || (ts.Associativity = {}));
function getExpressionAssociativity(expression) {
var operator = getOperator(expression);
var hasArguments = expression.kind === 180 /* NewExpression */ && expression.arguments !== undefined;
return getOperatorAssociativity(expression.kind, operator, hasArguments);
}
ts.getExpressionAssociativity = getExpressionAssociativity;
function getOperatorAssociativity(kind, operator, hasArguments) {
switch (kind) {
case 180 /* NewExpression */:
return hasArguments ? 0 /* Left */ : 1 /* Right */;
case 190 /* PrefixUnaryExpression */:
case 187 /* TypeOfExpression */:
case 188 /* VoidExpression */:
case 186 /* DeleteExpression */:
case 189 /* AwaitExpression */:
case 193 /* ConditionalExpression */:
case 195 /* YieldExpression */:
return 1 /* Right */;
case 192 /* BinaryExpression */:
switch (operator) {
case 39 /* AsteriskAsteriskToken */:
case 57 /* EqualsToken */:
case 58 /* PlusEqualsToken */:
case 59 /* MinusEqualsToken */:
case 61 /* AsteriskAsteriskEqualsToken */:
case 60 /* AsteriskEqualsToken */:
case 62 /* SlashEqualsToken */:
case 63 /* PercentEqualsToken */:
case 64 /* LessThanLessThanEqualsToken */:
case 65 /* GreaterThanGreaterThanEqualsToken */:
case 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */:
case 67 /* AmpersandEqualsToken */:
case 69 /* CaretEqualsToken */:
case 68 /* BarEqualsToken */:
return 1 /* Right */;
}
}
return 0 /* Left */;
}
ts.getOperatorAssociativity = getOperatorAssociativity;
function getExpressionPrecedence(expression) {
var operator = getOperator(expression);
var hasArguments = expression.kind === 180 /* NewExpression */ && expression.arguments !== undefined;
return getOperatorPrecedence(expression.kind, operator, hasArguments);
}
ts.getExpressionPrecedence = getExpressionPrecedence;
function getOperator(expression) {
if (expression.kind === 192 /* BinaryExpression */) {
return expression.operatorToken.kind;
}
else if (expression.kind === 190 /* PrefixUnaryExpression */ || expression.kind === 191 /* PostfixUnaryExpression */) {
return expression.operator;
}
else {
return expression.kind;
}
}
ts.getOperator = getOperator;
function getOperatorPrecedence(nodeKind, operatorKind, hasArguments) {
switch (nodeKind) {
case 98 /* ThisKeyword */:
case 96 /* SuperKeyword */:
case 70 /* Identifier */:
case 94 /* NullKeyword */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
case 8 /* NumericLiteral */:
case 9 /* StringLiteral */:
case 175 /* ArrayLiteralExpression */:
case 176 /* ObjectLiteralExpression */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 197 /* ClassExpression */:
case 246 /* JsxElement */:
case 247 /* JsxSelfClosingElement */:
case 11 /* RegularExpressionLiteral */:
case 12 /* NoSubstitutionTemplateLiteral */:
case 194 /* TemplateExpression */:
case 183 /* ParenthesizedExpression */:
case 198 /* OmittedExpression */:
return 19;
case 181 /* TaggedTemplateExpression */:
case 177 /* PropertyAccessExpression */:
case 178 /* ElementAccessExpression */:
return 18;
case 180 /* NewExpression */:
return hasArguments ? 18 : 17;
case 179 /* CallExpression */:
return 17;
case 191 /* PostfixUnaryExpression */:
return 16;
case 190 /* PrefixUnaryExpression */:
case 187 /* TypeOfExpression */:
case 188 /* VoidExpression */:
case 186 /* DeleteExpression */:
case 189 /* AwaitExpression */:
return 15;
case 192 /* BinaryExpression */:
switch (operatorKind) {
case 50 /* ExclamationToken */:
case 51 /* TildeToken */:
return 15;
case 39 /* AsteriskAsteriskToken */:
case 38 /* AsteriskToken */:
case 40 /* SlashToken */:
case 41 /* PercentToken */:
return 14;
case 36 /* PlusToken */:
case 37 /* MinusToken */:
return 13;
case 44 /* LessThanLessThanToken */:
case 45 /* GreaterThanGreaterThanToken */:
case 46 /* GreaterThanGreaterThanGreaterThanToken */:
return 12;
case 26 /* LessThanToken */:
case 29 /* LessThanEqualsToken */:
case 28 /* GreaterThanToken */:
case 30 /* GreaterThanEqualsToken */:
case 91 /* InKeyword */:
case 92 /* InstanceOfKeyword */:
return 11;
case 31 /* EqualsEqualsToken */:
case 33 /* EqualsEqualsEqualsToken */:
case 32 /* ExclamationEqualsToken */:
case 34 /* ExclamationEqualsEqualsToken */:
return 10;
case 47 /* AmpersandToken */:
return 9;
case 49 /* CaretToken */:
return 8;
case 48 /* BarToken */:
return 7;
case 52 /* AmpersandAmpersandToken */:
return 6;
case 53 /* BarBarToken */:
return 5;
case 57 /* EqualsToken */:
case 58 /* PlusEqualsToken */:
case 59 /* MinusEqualsToken */:
case 61 /* AsteriskAsteriskEqualsToken */:
case 60 /* AsteriskEqualsToken */:
case 62 /* SlashEqualsToken */:
case 63 /* PercentEqualsToken */:
case 64 /* LessThanLessThanEqualsToken */:
case 65 /* GreaterThanGreaterThanEqualsToken */:
case 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */:
case 67 /* AmpersandEqualsToken */:
case 69 /* CaretEqualsToken */:
case 68 /* BarEqualsToken */:
return 3;
case 25 /* CommaToken */:
return 0;
default:
return -1;
}
case 193 /* ConditionalExpression */:
return 4;
case 195 /* YieldExpression */:
return 2;
case 196 /* SpreadElement */:
return 1;
default:
return -1;
}
}
ts.getOperatorPrecedence = getOperatorPrecedence;
function createDiagnosticCollection() {
var nonFileDiagnostics = [];
var fileDiagnostics = ts.createMap();
var diagnosticsModified = false;
var modificationCount = 0;
return {
add: add,
getGlobalDiagnostics: getGlobalDiagnostics,
getDiagnostics: getDiagnostics,
getModificationCount: getModificationCount,
reattachFileDiagnostics: reattachFileDiagnostics
};
function getModificationCount() {
return modificationCount;
}
function reattachFileDiagnostics(newFile) {
if (!ts.hasProperty(fileDiagnostics, newFile.fileName)) {
return;
}
for (var _i = 0, _a = fileDiagnostics[newFile.fileName]; _i < _a.length; _i++) {
var diagnostic = _a[_i];
diagnostic.file = newFile;
}
}
function add(diagnostic) {
var diagnostics;
if (diagnostic.file) {
diagnostics = fileDiagnostics[diagnostic.file.fileName];
if (!diagnostics) {
diagnostics = [];
fileDiagnostics[diagnostic.file.fileName] = diagnostics;
}
}
else {
diagnostics = nonFileDiagnostics;
}
diagnostics.push(diagnostic);
diagnosticsModified = true;
modificationCount++;
}
function getGlobalDiagnostics() {
sortAndDeduplicate();
return nonFileDiagnostics;
}
function getDiagnostics(fileName) {
sortAndDeduplicate();
if (fileName) {
return fileDiagnostics[fileName] || [];
}
var allDiagnostics = [];
function pushDiagnostic(d) {
allDiagnostics.push(d);
}
ts.forEach(nonFileDiagnostics, pushDiagnostic);
for (var key in fileDiagnostics) {
ts.forEach(fileDiagnostics[key], pushDiagnostic);
}
return ts.sortAndDeduplicateDiagnostics(allDiagnostics);
}
function sortAndDeduplicate() {
if (!diagnosticsModified) {
return;
}
diagnosticsModified = false;
nonFileDiagnostics = ts.sortAndDeduplicateDiagnostics(nonFileDiagnostics);
for (var key in fileDiagnostics) {
fileDiagnostics[key] = ts.sortAndDeduplicateDiagnostics(fileDiagnostics[key]);
}
}
}
ts.createDiagnosticCollection = createDiagnosticCollection;
// This consists of the first 19 unprintable ASCII characters, canonical escapes, lineSeparator,
// paragraphSeparator, and nextLine. The latter three are just desirable to suppress new lines in
// the language service. These characters should be escaped when printing, and if any characters are added,
// the map below must be updated. Note that this regexp *does not* include the 'delete' character.
// There is no reason for this other than that JSON.stringify does not handle it either.
var escapedCharsRegExp = /[\\\"\u0000-\u001f\t\v\f\b\r\n\u2028\u2029\u0085]/g;
var escapedCharsMap = ts.createMap({
"\0": "\\0",
"\t": "\\t",
"\v": "\\v",
"\f": "\\f",
"\b": "\\b",
"\r": "\\r",
"\n": "\\n",
"\\": "\\\\",
"\"": "\\\"",
"\u2028": "\\u2028",
"\u2029": "\\u2029",
"\u0085": "\\u0085" // nextLine
});
/**
* Based heavily on the abstract 'Quote'/'QuoteJSONString' operation from ECMA-262 (24.3.2.2),
* but augmented for a few select characters (e.g. lineSeparator, paragraphSeparator, nextLine)
* Note that this doesn't actually wrap the input in double quotes.
*/
function escapeString(s) {
s = escapedCharsRegExp.test(s) ? s.replace(escapedCharsRegExp, getReplacement) : s;
return s;
function getReplacement(c) {
return escapedCharsMap[c] || get16BitUnicodeEscapeSequence(c.charCodeAt(0));
}
}
ts.escapeString = escapeString;
function isIntrinsicJsxName(name) {
var ch = name.substr(0, 1);
return ch.toLowerCase() === ch;
}
ts.isIntrinsicJsxName = isIntrinsicJsxName;
function get16BitUnicodeEscapeSequence(charCode) {
var hexCharCode = charCode.toString(16).toUpperCase();
var paddedHexCode = ("0000" + hexCharCode).slice(-4);
return "\\u" + paddedHexCode;
}
var nonAsciiCharacters = /[^\u0000-\u007F]/g;
function escapeNonAsciiCharacters(s) {
// Replace non-ASCII characters with '\uNNNN' escapes if any exist.
// Otherwise just return the original string.
return nonAsciiCharacters.test(s) ?
s.replace(nonAsciiCharacters, function (c) { return get16BitUnicodeEscapeSequence(c.charCodeAt(0)); }) :
s;
}
ts.escapeNonAsciiCharacters = escapeNonAsciiCharacters;
var indentStrings = ["", " "];
function getIndentString(level) {
if (indentStrings[level] === undefined) {
indentStrings[level] = getIndentString(level - 1) + indentStrings[1];
}
return indentStrings[level];
}
ts.getIndentString = getIndentString;
function getIndentSize() {
return indentStrings[1].length;
}
ts.getIndentSize = getIndentSize;
function createTextWriter(newLine) {
var output;
var indent;
var lineStart;
var lineCount;
var linePos;
function write(s) {
if (s && s.length) {
if (lineStart) {
output += getIndentString(indent);
lineStart = false;
}
output += s;
}
}
function reset() {
output = "";
indent = 0;
lineStart = true;
lineCount = 0;
linePos = 0;
}
function rawWrite(s) {
if (s !== undefined) {
if (lineStart) {
lineStart = false;
}
output += s;
}
}
function writeLiteral(s) {
if (s && s.length) {
write(s);
var lineStartsOfS = ts.computeLineStarts(s);
if (lineStartsOfS.length > 1) {
lineCount = lineCount + lineStartsOfS.length - 1;
linePos = output.length - s.length + ts.lastOrUndefined(lineStartsOfS);
}
}
}
function writeLine() {
if (!lineStart) {
output += newLine;
lineCount++;
linePos = output.length;
lineStart = true;
}
}
function writeTextOfNode(text, node) {
write(getTextOfNodeFromSourceText(text, node));
}
reset();
return {
write: write,
rawWrite: rawWrite,
writeTextOfNode: writeTextOfNode,
writeLiteral: writeLiteral,
writeLine: writeLine,
increaseIndent: function () { indent++; },
decreaseIndent: function () { indent--; },
getIndent: function () { return indent; },
getTextPos: function () { return output.length; },
getLine: function () { return lineCount + 1; },
getColumn: function () { return lineStart ? indent * getIndentSize() + 1 : output.length - linePos + 1; },
getText: function () { return output; },
isAtStartOfLine: function () { return lineStart; },
reset: reset
};
}
ts.createTextWriter = createTextWriter;
function getResolvedExternalModuleName(host, file) {
return file.moduleName || getExternalModuleNameFromPath(host, file.fileName);
}
ts.getResolvedExternalModuleName = getResolvedExternalModuleName;
function getExternalModuleNameFromDeclaration(host, resolver, declaration) {
var file = resolver.getExternalModuleFileFromDeclaration(declaration);
if (!file || isDeclarationFile(file)) {
return undefined;
}
return getResolvedExternalModuleName(host, file);
}
ts.getExternalModuleNameFromDeclaration = getExternalModuleNameFromDeclaration;
/**
* Resolves a local path to a path which is absolute to the base of the emit
*/
function getExternalModuleNameFromPath(host, fileName) {
var getCanonicalFileName = function (f) { return host.getCanonicalFileName(f); };
var dir = ts.toPath(host.getCommonSourceDirectory(), host.getCurrentDirectory(), getCanonicalFileName);
var filePath = ts.getNormalizedAbsolutePath(fileName, host.getCurrentDirectory());
var relativePath = ts.getRelativePathToDirectoryOrUrl(dir, filePath, dir, getCanonicalFileName, /*isAbsolutePathAnUrl*/ false);
return ts.removeFileExtension(relativePath);
}
ts.getExternalModuleNameFromPath = getExternalModuleNameFromPath;
function getOwnEmitOutputFilePath(sourceFile, host, extension) {
var compilerOptions = host.getCompilerOptions();
var emitOutputFilePathWithoutExtension;
if (compilerOptions.outDir) {
emitOutputFilePathWithoutExtension = ts.removeFileExtension(getSourceFilePathInNewDir(sourceFile, host, compilerOptions.outDir));
}
else {
emitOutputFilePathWithoutExtension = ts.removeFileExtension(sourceFile.fileName);
}
return emitOutputFilePathWithoutExtension + extension;
}
ts.getOwnEmitOutputFilePath = getOwnEmitOutputFilePath;
function getDeclarationEmitOutputFilePath(sourceFile, host) {
var options = host.getCompilerOptions();
var outputDir = options.declarationDir || options.outDir; // Prefer declaration folder if specified
var path = outputDir
? getSourceFilePathInNewDir(sourceFile, host, outputDir)
: sourceFile.fileName;
return ts.removeFileExtension(path) + ".d.ts";
}
ts.getDeclarationEmitOutputFilePath = getDeclarationEmitOutputFilePath;
/**
* Gets the source files that are expected to have an emit output.
*
* Originally part of `forEachExpectedEmitFile`, this functionality was extracted to support
* transformations.
*
* @param host An EmitHost.
* @param targetSourceFile An optional target source file to emit.
*/
function getSourceFilesToEmit(host, targetSourceFile) {
var options = host.getCompilerOptions();
if (options.outFile || options.out) {
var moduleKind = ts.getEmitModuleKind(options);
var moduleEmitEnabled = moduleKind === ts.ModuleKind.AMD || moduleKind === ts.ModuleKind.System;
var sourceFiles = getAllEmittableSourceFiles();
// Can emit only sources that are not declaration file and are either non module code or module with --module or --target es6 specified
return ts.filter(sourceFiles, moduleEmitEnabled ? isNonDeclarationFile : isBundleEmitNonExternalModule);
}
else {
var sourceFiles = targetSourceFile === undefined ? getAllEmittableSourceFiles() : [targetSourceFile];
return filterSourceFilesInDirectory(sourceFiles, function (file) { return host.isSourceFileFromExternalLibrary(file); });
}
function getAllEmittableSourceFiles() {
return options.noEmitForJsFiles ? ts.filter(host.getSourceFiles(), function (sourceFile) { return !isSourceFileJavaScript(sourceFile); }) : host.getSourceFiles();
}
}
ts.getSourceFilesToEmit = getSourceFilesToEmit;
/** Don't call this for `--outFile`, just for `--outDir` or plain emit. */
function filterSourceFilesInDirectory(sourceFiles, isSourceFileFromExternalLibrary) {
return ts.filter(sourceFiles, function (file) { return shouldEmitInDirectory(file, isSourceFileFromExternalLibrary); });
}
ts.filterSourceFilesInDirectory = filterSourceFilesInDirectory;
function isNonDeclarationFile(sourceFile) {
return !isDeclarationFile(sourceFile);
}
/**
* Whether a file should be emitted in a non-`--outFile` case.
* Don't emit if source file is a declaration file, or was located under node_modules
*/
function shouldEmitInDirectory(sourceFile, isSourceFileFromExternalLibrary) {
return isNonDeclarationFile(sourceFile) && !isSourceFileFromExternalLibrary(sourceFile);
}
function isBundleEmitNonExternalModule(sourceFile) {
return isNonDeclarationFile(sourceFile) && !ts.isExternalModule(sourceFile);
}
/**
* Iterates over each source file to emit. The source files are expected to have been
* transformed for use by the pretty printer.
*
* Originally part of `forEachExpectedEmitFile`, this functionality was extracted to support
* transformations.
*
* @param host An EmitHost.
* @param sourceFiles The transformed source files to emit.
* @param action The action to execute.
*/
function forEachTransformedEmitFile(host, sourceFiles, action, emitOnlyDtsFiles) {
var options = host.getCompilerOptions();
// Emit on each source file
if (options.outFile || options.out) {
onBundledEmit(sourceFiles);
}
else {
for (var _i = 0, sourceFiles_2 = sourceFiles; _i < sourceFiles_2.length; _i++) {
var sourceFile = sourceFiles_2[_i];
// Don't emit if source file is a declaration file, or was located under node_modules
if (!isDeclarationFile(sourceFile) && !host.isSourceFileFromExternalLibrary(sourceFile)) {
onSingleFileEmit(host, sourceFile);
}
}
}
function onSingleFileEmit(host, sourceFile) {
// JavaScript files are always LanguageVariant.JSX, as JSX syntax is allowed in .js files also.
// So for JavaScript files, '.jsx' is only emitted if the input was '.jsx', and JsxEmit.Preserve.
// For TypeScript, the only time to emit with a '.jsx' extension, is on JSX input, and JsxEmit.Preserve
var extension = ".js";
if (options.jsx === 1 /* Preserve */) {
if (isSourceFileJavaScript(sourceFile)) {
if (ts.fileExtensionIs(sourceFile.fileName, ".jsx")) {
extension = ".jsx";
}
}
else if (sourceFile.languageVariant === 1 /* JSX */) {
// TypeScript source file preserving JSX syntax
extension = ".jsx";
}
}
var jsFilePath = getOwnEmitOutputFilePath(sourceFile, host, extension);
var sourceMapFilePath = getSourceMapFilePath(jsFilePath, options);
var declarationFilePath = !isSourceFileJavaScript(sourceFile) && (options.declaration || emitOnlyDtsFiles) ? getDeclarationEmitOutputFilePath(sourceFile, host) : undefined;
action(jsFilePath, sourceMapFilePath, declarationFilePath, [sourceFile], /*isBundledEmit*/ false);
}
function onBundledEmit(sourceFiles) {
if (sourceFiles.length) {
var jsFilePath = options.outFile || options.out;
var sourceMapFilePath = getSourceMapFilePath(jsFilePath, options);
var declarationFilePath = options.declaration ? ts.removeFileExtension(jsFilePath) + ".d.ts" : undefined;
action(jsFilePath, sourceMapFilePath, declarationFilePath, sourceFiles, /*isBundledEmit*/ true);
}
}
}
ts.forEachTransformedEmitFile = forEachTransformedEmitFile;
function getSourceMapFilePath(jsFilePath, options) {
return options.sourceMap ? jsFilePath + ".map" : undefined;
}
/**
* Iterates over the source files that are expected to have an emit output. This function
* is used by the legacy emitter and the declaration emitter and should not be used by
* the tree transforming emitter.
*
* @param host An EmitHost.
* @param action The action to execute.
* @param targetSourceFile An optional target source file to emit.
*/
function forEachExpectedEmitFile(host, action, targetSourceFile, emitOnlyDtsFiles) {
var options = host.getCompilerOptions();
// Emit on each source file
if (options.outFile || options.out) {
onBundledEmit(host);
}
else {
var sourceFiles = targetSourceFile === undefined ? getSourceFilesToEmit(host) : [targetSourceFile];
for (var _i = 0, sourceFiles_3 = sourceFiles; _i < sourceFiles_3.length; _i++) {
var sourceFile = sourceFiles_3[_i];
if (shouldEmitInDirectory(sourceFile, function (file) { return host.isSourceFileFromExternalLibrary(file); })) {
onSingleFileEmit(host, sourceFile);
}
}
}
function onSingleFileEmit(host, sourceFile) {
// JavaScript files are always LanguageVariant.JSX, as JSX syntax is allowed in .js files also.
// So for JavaScript files, '.jsx' is only emitted if the input was '.jsx', and JsxEmit.Preserve.
// For TypeScript, the only time to emit with a '.jsx' extension, is on JSX input, and JsxEmit.Preserve
var extension = ".js";
if (options.jsx === 1 /* Preserve */) {
if (isSourceFileJavaScript(sourceFile)) {
if (ts.fileExtensionIs(sourceFile.fileName, ".jsx")) {
extension = ".jsx";
}
}
else if (sourceFile.languageVariant === 1 /* JSX */) {
// TypeScript source file preserving JSX syntax
extension = ".jsx";
}
}
var jsFilePath = getOwnEmitOutputFilePath(sourceFile, host, extension);
var declarationFilePath = !isSourceFileJavaScript(sourceFile) && (emitOnlyDtsFiles || options.declaration) ? getDeclarationEmitOutputFilePath(sourceFile, host) : undefined;
var emitFileNames = {
jsFilePath: jsFilePath,
sourceMapFilePath: getSourceMapFilePath(jsFilePath, options),
declarationFilePath: declarationFilePath
};
action(emitFileNames, [sourceFile], /*isBundledEmit*/ false, emitOnlyDtsFiles);
}
function onBundledEmit(host) {
// Can emit only sources that are not declaration file and are either non module code or module with
// --module or --target es6 specified. Files included by searching under node_modules are also not emitted.
var bundledSources = ts.filter(getSourceFilesToEmit(host), function (sourceFile) { return !isDeclarationFile(sourceFile) &&
!host.isSourceFileFromExternalLibrary(sourceFile) &&
(!ts.isExternalModule(sourceFile) ||
!!ts.getEmitModuleKind(options)); });
if (bundledSources.length) {
var jsFilePath = options.outFile || options.out;
var emitFileNames = {
jsFilePath: jsFilePath,
sourceMapFilePath: getSourceMapFilePath(jsFilePath, options),
declarationFilePath: options.declaration ? ts.removeFileExtension(jsFilePath) + ".d.ts" : undefined
};
action(emitFileNames, bundledSources, /*isBundledEmit*/ true, emitOnlyDtsFiles);
}
}
}
ts.forEachExpectedEmitFile = forEachExpectedEmitFile;
function getSourceFilePathInNewDir(sourceFile, host, newDirPath) {
var sourceFilePath = ts.getNormalizedAbsolutePath(sourceFile.fileName, host.getCurrentDirectory());
var commonSourceDirectory = host.getCommonSourceDirectory();
var isSourceFileInCommonSourceDirectory = host.getCanonicalFileName(sourceFilePath).indexOf(host.getCanonicalFileName(commonSourceDirectory)) === 0;
sourceFilePath = isSourceFileInCommonSourceDirectory ? sourceFilePath.substring(commonSourceDirectory.length) : sourceFilePath;
return ts.combinePaths(newDirPath, sourceFilePath);
}
ts.getSourceFilePathInNewDir = getSourceFilePathInNewDir;
function writeFile(host, diagnostics, fileName, data, writeByteOrderMark, sourceFiles) {
host.writeFile(fileName, data, writeByteOrderMark, function (hostErrorMessage) {
diagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Could_not_write_file_0_Colon_1, fileName, hostErrorMessage));
}, sourceFiles);
}
ts.writeFile = writeFile;
function getLineOfLocalPosition(currentSourceFile, pos) {
return ts.getLineAndCharacterOfPosition(currentSourceFile, pos).line;
}
ts.getLineOfLocalPosition = getLineOfLocalPosition;
function getLineOfLocalPositionFromLineMap(lineMap, pos) {
return ts.computeLineAndCharacterOfPosition(lineMap, pos).line;
}
ts.getLineOfLocalPositionFromLineMap = getLineOfLocalPositionFromLineMap;
function getFirstConstructorWithBody(node) {
return ts.forEach(node.members, function (member) {
if (member.kind === 150 /* Constructor */ && nodeIsPresent(member.body)) {
return member;
}
});
}
ts.getFirstConstructorWithBody = getFirstConstructorWithBody;
/** Get the type annotaion for the value parameter. */
function getSetAccessorTypeAnnotationNode(accessor) {
if (accessor && accessor.parameters.length > 0) {
var hasThis = accessor.parameters.length === 2 && parameterIsThisKeyword(accessor.parameters[0]);
return accessor.parameters[hasThis ? 1 : 0].type;
}
}
ts.getSetAccessorTypeAnnotationNode = getSetAccessorTypeAnnotationNode;
function getThisParameter(signature) {
if (signature.parameters.length) {
var thisParameter = signature.parameters[0];
if (parameterIsThisKeyword(thisParameter)) {
return thisParameter;
}
}
}
ts.getThisParameter = getThisParameter;
function parameterIsThisKeyword(parameter) {
return isThisIdentifier(parameter.name);
}
ts.parameterIsThisKeyword = parameterIsThisKeyword;
function isThisIdentifier(node) {
return node && node.kind === 70 /* Identifier */ && identifierIsThisKeyword(node);
}
ts.isThisIdentifier = isThisIdentifier;
function identifierIsThisKeyword(id) {
return id.originalKeywordKind === 98 /* ThisKeyword */;
}
ts.identifierIsThisKeyword = identifierIsThisKeyword;
function getAllAccessorDeclarations(declarations, accessor) {
var firstAccessor;
var secondAccessor;
var getAccessor;
var setAccessor;
if (hasDynamicName(accessor)) {
firstAccessor = accessor;
if (accessor.kind === 151 /* GetAccessor */) {
getAccessor = accessor;
}
else if (accessor.kind === 152 /* SetAccessor */) {
setAccessor = accessor;
}
else {
ts.Debug.fail("Accessor has wrong kind");
}
}
else {
ts.forEach(declarations, function (member) {
if ((member.kind === 151 /* GetAccessor */ || member.kind === 152 /* SetAccessor */)
&& hasModifier(member, 32 /* Static */) === hasModifier(accessor, 32 /* Static */)) {
var memberName = getPropertyNameForPropertyNameNode(member.name);
var accessorName = getPropertyNameForPropertyNameNode(accessor.name);
if (memberName === accessorName) {
if (!firstAccessor) {
firstAccessor = member;
}
else if (!secondAccessor) {
secondAccessor = member;
}
if (member.kind === 151 /* GetAccessor */ && !getAccessor) {
getAccessor = member;
}
if (member.kind === 152 /* SetAccessor */ && !setAccessor) {
setAccessor = member;
}
}
}
});
}
return {
firstAccessor: firstAccessor,
secondAccessor: secondAccessor,
getAccessor: getAccessor,
setAccessor: setAccessor
};
}
ts.getAllAccessorDeclarations = getAllAccessorDeclarations;
function emitNewLineBeforeLeadingComments(lineMap, writer, node, leadingComments) {
emitNewLineBeforeLeadingCommentsOfPosition(lineMap, writer, node.pos, leadingComments);
}
ts.emitNewLineBeforeLeadingComments = emitNewLineBeforeLeadingComments;
function emitNewLineBeforeLeadingCommentsOfPosition(lineMap, writer, pos, leadingComments) {
// If the leading comments start on different line than the start of node, write new line
if (leadingComments && leadingComments.length && pos !== leadingComments[0].pos &&
getLineOfLocalPositionFromLineMap(lineMap, pos) !== getLineOfLocalPositionFromLineMap(lineMap, leadingComments[0].pos)) {
writer.writeLine();
}
}
ts.emitNewLineBeforeLeadingCommentsOfPosition = emitNewLineBeforeLeadingCommentsOfPosition;
function emitNewLineBeforeLeadingCommentOfPosition(lineMap, writer, pos, commentPos) {
// If the leading comments start on different line than the start of node, write new line
if (pos !== commentPos &&
getLineOfLocalPositionFromLineMap(lineMap, pos) !== getLineOfLocalPositionFromLineMap(lineMap, commentPos)) {
writer.writeLine();
}
}
ts.emitNewLineBeforeLeadingCommentOfPosition = emitNewLineBeforeLeadingCommentOfPosition;
function emitComments(text, lineMap, writer, comments, leadingSeparator, trailingSeparator, newLine, writeComment) {
if (comments && comments.length > 0) {
if (leadingSeparator) {
writer.write(" ");
}
var emitInterveningSeparator = false;
for (var _i = 0, comments_1 = comments; _i < comments_1.length; _i++) {
var comment = comments_1[_i];
if (emitInterveningSeparator) {
writer.write(" ");
emitInterveningSeparator = false;
}
writeComment(text, lineMap, writer, comment.pos, comment.end, newLine);
if (comment.hasTrailingNewLine) {
writer.writeLine();
}
else {
emitInterveningSeparator = true;
}
}
if (emitInterveningSeparator && trailingSeparator) {
writer.write(" ");
}
}
}
ts.emitComments = emitComments;
/**
* Detached comment is a comment at the top of file or function body that is separated from
* the next statement by space.
*/
function emitDetachedComments(text, lineMap, writer, writeComment, node, newLine, removeComments) {
var leadingComments;
var currentDetachedCommentInfo;
if (removeComments) {
// removeComments is true, only reserve pinned comment at the top of file
// For example:
// /*! Pinned Comment */
//
// var x = 10;
if (node.pos === 0) {
leadingComments = ts.filter(ts.getLeadingCommentRanges(text, node.pos), isPinnedComment);
}
}
else {
// removeComments is false, just get detached as normal and bypass the process to filter comment
leadingComments = ts.getLeadingCommentRanges(text, node.pos);
}
if (leadingComments) {
var detachedComments = [];
var lastComment = void 0;
for (var _i = 0, leadingComments_1 = leadingComments; _i < leadingComments_1.length; _i++) {
var comment = leadingComments_1[_i];
if (lastComment) {
var lastCommentLine = getLineOfLocalPositionFromLineMap(lineMap, lastComment.end);
var commentLine = getLineOfLocalPositionFromLineMap(lineMap, comment.pos);
if (commentLine >= lastCommentLine + 2) {
// There was a blank line between the last comment and this comment. This
// comment is not part of the copyright comments. Return what we have so
// far.
break;
}
}
detachedComments.push(comment);
lastComment = comment;
}
if (detachedComments.length) {
// All comments look like they could have been part of the copyright header. Make
// sure there is at least one blank line between it and the node. If not, it's not
// a copyright header.
var lastCommentLine = getLineOfLocalPositionFromLineMap(lineMap, ts.lastOrUndefined(detachedComments).end);
var nodeLine = getLineOfLocalPositionFromLineMap(lineMap, ts.skipTrivia(text, node.pos));
if (nodeLine >= lastCommentLine + 2) {
// Valid detachedComments
emitNewLineBeforeLeadingComments(lineMap, writer, node, leadingComments);
emitComments(text, lineMap, writer, detachedComments, /*leadingSeparator*/ false, /*trailingSeparator*/ true, newLine, writeComment);
currentDetachedCommentInfo = { nodePos: node.pos, detachedCommentEndPos: ts.lastOrUndefined(detachedComments).end };
}
}
}
return currentDetachedCommentInfo;
function isPinnedComment(comment) {
return text.charCodeAt(comment.pos + 1) === 42 /* asterisk */ &&
text.charCodeAt(comment.pos + 2) === 33 /* exclamation */;
}
}
ts.emitDetachedComments = emitDetachedComments;
function writeCommentRange(text, lineMap, writer, commentPos, commentEnd, newLine) {
if (text.charCodeAt(commentPos + 1) === 42 /* asterisk */) {
var firstCommentLineAndCharacter = ts.computeLineAndCharacterOfPosition(lineMap, commentPos);
var lineCount = lineMap.length;
var firstCommentLineIndent = void 0;
for (var pos = commentPos, currentLine = firstCommentLineAndCharacter.line; pos < commentEnd; currentLine++) {
var nextLineStart = (currentLine + 1) === lineCount
? text.length + 1
: lineMap[currentLine + 1];
if (pos !== commentPos) {
// If we are not emitting first line, we need to write the spaces to adjust the alignment
if (firstCommentLineIndent === undefined) {
firstCommentLineIndent = calculateIndent(text, lineMap[firstCommentLineAndCharacter.line], commentPos);
}
// These are number of spaces writer is going to write at current indent
var currentWriterIndentSpacing = writer.getIndent() * getIndentSize();
// Number of spaces we want to be writing
// eg: Assume writer indent
// module m {
// /* starts at character 9 this is line 1
// * starts at character pos 4 line --1 = 8 - 8 + 3
// More left indented comment */ --2 = 8 - 8 + 2
// class c { }
// }
// module m {
// /* this is line 1 -- Assume current writer indent 8
// * line --3 = 8 - 4 + 5
// More right indented comment */ --4 = 8 - 4 + 11
// class c { }
// }
var spacesToEmit = currentWriterIndentSpacing - firstCommentLineIndent + calculateIndent(text, pos, nextLineStart);
if (spacesToEmit > 0) {
var numberOfSingleSpacesToEmit = spacesToEmit % getIndentSize();
var indentSizeSpaceString = getIndentString((spacesToEmit - numberOfSingleSpacesToEmit) / getIndentSize());
// Write indent size string ( in eg 1: = "", 2: "" , 3: string with 8 spaces 4: string with 12 spaces
writer.rawWrite(indentSizeSpaceString);
// Emit the single spaces (in eg: 1: 3 spaces, 2: 2 spaces, 3: 1 space, 4: 3 spaces)
while (numberOfSingleSpacesToEmit) {
writer.rawWrite(" ");
numberOfSingleSpacesToEmit--;
}
}
else {
// No spaces to emit write empty string
writer.rawWrite("");
}
}
// Write the comment line text
writeTrimmedCurrentLine(text, commentEnd, writer, newLine, pos, nextLineStart);
pos = nextLineStart;
}
}
else {
// Single line comment of style //....
writer.write(text.substring(commentPos, commentEnd));
}
}
ts.writeCommentRange = writeCommentRange;
function writeTrimmedCurrentLine(text, commentEnd, writer, newLine, pos, nextLineStart) {
var end = Math.min(commentEnd, nextLineStart - 1);
var currentLineText = text.substring(pos, end).replace(/^\s+|\s+$/g, "");
if (currentLineText) {
// trimmed forward and ending spaces text
writer.write(currentLineText);
if (end !== commentEnd) {
writer.writeLine();
}
}
else {
// Empty string - make sure we write empty line
writer.writeLiteral(newLine);
}
}
function calculateIndent(text, pos, end) {
var currentLineIndent = 0;
for (; pos < end && ts.isWhiteSpaceSingleLine(text.charCodeAt(pos)); pos++) {
if (text.charCodeAt(pos) === 9 /* tab */) {
// Tabs = TabSize = indent size and go to next tabStop
currentLineIndent += getIndentSize() - (currentLineIndent % getIndentSize());
}
else {
// Single space
currentLineIndent++;
}
}
return currentLineIndent;
}
function hasModifiers(node) {
return getModifierFlags(node) !== 0 /* None */;
}
ts.hasModifiers = hasModifiers;
function hasModifier(node, flags) {
return (getModifierFlags(node) & flags) !== 0;
}
ts.hasModifier = hasModifier;
function getModifierFlags(node) {
if (node.modifierFlagsCache & 536870912 /* HasComputedFlags */) {
return node.modifierFlagsCache & ~536870912 /* HasComputedFlags */;
}
var flags = 0 /* None */;
if (node.modifiers) {
for (var _i = 0, _a = node.modifiers; _i < _a.length; _i++) {
var modifier = _a[_i];
flags |= modifierToFlag(modifier.kind);
}
}
if (node.flags & 4 /* NestedNamespace */ || (node.kind === 70 /* Identifier */ && node.isInJSDocNamespace)) {
flags |= 1 /* Export */;
}
node.modifierFlagsCache = flags | 536870912 /* HasComputedFlags */;
return flags;
}
ts.getModifierFlags = getModifierFlags;
function modifierToFlag(token) {
switch (token) {
case 114 /* StaticKeyword */: return 32 /* Static */;
case 113 /* PublicKeyword */: return 4 /* Public */;
case 112 /* ProtectedKeyword */: return 16 /* Protected */;
case 111 /* PrivateKeyword */: return 8 /* Private */;
case 116 /* AbstractKeyword */: return 128 /* Abstract */;
case 83 /* ExportKeyword */: return 1 /* Export */;
case 123 /* DeclareKeyword */: return 2 /* Ambient */;
case 75 /* ConstKeyword */: return 2048 /* Const */;
case 78 /* DefaultKeyword */: return 512 /* Default */;
case 119 /* AsyncKeyword */: return 256 /* Async */;
case 130 /* ReadonlyKeyword */: return 64 /* Readonly */;
}
return 0 /* None */;
}
ts.modifierToFlag = modifierToFlag;
function isLogicalOperator(token) {
return token === 53 /* BarBarToken */
|| token === 52 /* AmpersandAmpersandToken */
|| token === 50 /* ExclamationToken */;
}
ts.isLogicalOperator = isLogicalOperator;
function isAssignmentOperator(token) {
return token >= 57 /* FirstAssignment */ && token <= 69 /* LastAssignment */;
}
ts.isAssignmentOperator = isAssignmentOperator;
/** Get `C` given `N` if `N` is in the position `class C extends N` where `N` is an ExpressionWithTypeArguments. */
function tryGetClassExtendingExpressionWithTypeArguments(node) {
if (node.kind === 199 /* ExpressionWithTypeArguments */ &&
node.parent.token === 84 /* ExtendsKeyword */ &&
isClassLike(node.parent.parent)) {
return node.parent.parent;
}
}
ts.tryGetClassExtendingExpressionWithTypeArguments = tryGetClassExtendingExpressionWithTypeArguments;
function isAssignmentExpression(node) {
return isBinaryExpression(node)
&& isAssignmentOperator(node.operatorToken.kind)
&& isLeftHandSideExpression(node.left);
}
ts.isAssignmentExpression = isAssignmentExpression;
function isDestructuringAssignment(node) {
if (isBinaryExpression(node)) {
if (node.operatorToken.kind === 57 /* EqualsToken */) {
var kind = node.left.kind;
return kind === 176 /* ObjectLiteralExpression */
|| kind === 175 /* ArrayLiteralExpression */;
}
}
return false;
}
ts.isDestructuringAssignment = isDestructuringAssignment;
// Returns false if this heritage clause element's expression contains something unsupported
// (i.e. not a name or dotted name).
function isSupportedExpressionWithTypeArguments(node) {
return isSupportedExpressionWithTypeArgumentsRest(node.expression);
}
ts.isSupportedExpressionWithTypeArguments = isSupportedExpressionWithTypeArguments;
function isSupportedExpressionWithTypeArgumentsRest(node) {
if (node.kind === 70 /* Identifier */) {
return true;
}
else if (isPropertyAccessExpression(node)) {
return isSupportedExpressionWithTypeArgumentsRest(node.expression);
}
else {
return false;
}
}
function isExpressionWithTypeArgumentsInClassExtendsClause(node) {
return tryGetClassExtendingExpressionWithTypeArguments(node) !== undefined;
}
ts.isExpressionWithTypeArgumentsInClassExtendsClause = isExpressionWithTypeArgumentsInClassExtendsClause;
function isEntityNameExpression(node) {
return node.kind === 70 /* Identifier */ ||
node.kind === 177 /* PropertyAccessExpression */ && isEntityNameExpression(node.expression);
}
ts.isEntityNameExpression = isEntityNameExpression;
function isRightSideOfQualifiedNameOrPropertyAccess(node) {
return (node.parent.kind === 141 /* QualifiedName */ && node.parent.right === node) ||
(node.parent.kind === 177 /* PropertyAccessExpression */ && node.parent.name === node);
}
ts.isRightSideOfQualifiedNameOrPropertyAccess = isRightSideOfQualifiedNameOrPropertyAccess;
function isEmptyObjectLiteralOrArrayLiteral(expression) {
var kind = expression.kind;
if (kind === 176 /* ObjectLiteralExpression */) {
return expression.properties.length === 0;
}
if (kind === 175 /* ArrayLiteralExpression */) {
return expression.elements.length === 0;
}
return false;
}
ts.isEmptyObjectLiteralOrArrayLiteral = isEmptyObjectLiteralOrArrayLiteral;
function getLocalSymbolForExportDefault(symbol) {
return symbol && symbol.valueDeclaration && hasModifier(symbol.valueDeclaration, 512 /* Default */) ? symbol.valueDeclaration.localSymbol : undefined;
}
ts.getLocalSymbolForExportDefault = getLocalSymbolForExportDefault;
/** Return ".ts", ".d.ts", or ".tsx", if that is the extension. */
function tryExtractTypeScriptExtension(fileName) {
return ts.find(ts.supportedTypescriptExtensionsForExtractExtension, function (extension) { return ts.fileExtensionIs(fileName, extension); });
}
ts.tryExtractTypeScriptExtension = tryExtractTypeScriptExtension;
/**
* Replace each instance of non-ascii characters by one, two, three, or four escape sequences
* representing the UTF-8 encoding of the character, and return the expanded char code list.
*/
function getExpandedCharCodes(input) {
var output = [];
var length = input.length;
for (var i = 0; i < length; i++) {
var charCode = input.charCodeAt(i);
// handel utf8
if (charCode < 0x80) {
output.push(charCode);
}
else if (charCode < 0x800) {
output.push((charCode >> 6) | 192);
output.push((charCode & 63) | 128);
}
else if (charCode < 0x10000) {
output.push((charCode >> 12) | 224);
output.push(((charCode >> 6) & 63) | 128);
output.push((charCode & 63) | 128);
}
else if (charCode < 0x20000) {
output.push((charCode >> 18) | 240);
output.push(((charCode >> 12) & 63) | 128);
output.push(((charCode >> 6) & 63) | 128);
output.push((charCode & 63) | 128);
}
else {
ts.Debug.assert(false, "Unexpected code point");
}
}
return output;
}
/**
* Serialize an object graph into a JSON string. This is intended only for use on an acyclic graph
* as the fallback implementation does not check for circular references by default.
*/
ts.stringify = typeof JSON !== "undefined" && JSON.stringify
? JSON.stringify
: stringifyFallback;
/**
* Serialize an object graph into a JSON string.
*/
function stringifyFallback(value) {
// JSON.stringify returns `undefined` here, instead of the string "undefined".
return value === undefined ? undefined : stringifyValue(value);
}
function stringifyValue(value) {
return typeof value === "string" ? "\"" + escapeString(value) + "\""
: typeof value === "number" ? isFinite(value) ? String(value) : "null"
: typeof value === "boolean" ? value ? "true" : "false"
: typeof value === "object" && value ? ts.isArray(value) ? cycleCheck(stringifyArray, value) : cycleCheck(stringifyObject, value)
: "null";
}
function cycleCheck(cb, value) {
ts.Debug.assert(!value.hasOwnProperty("__cycle"), "Converting circular structure to JSON");
value.__cycle = true;
var result = cb(value);
delete value.__cycle;
return result;
}
function stringifyArray(value) {
return "[" + ts.reduceLeft(value, stringifyElement, "") + "]";
}
function stringifyElement(memo, value) {
return (memo ? memo + "," : memo) + stringifyValue(value);
}
function stringifyObject(value) {
return "{" + ts.reduceOwnProperties(value, stringifyProperty, "") + "}";
}
function stringifyProperty(memo, value, key) {
return value === undefined || typeof value === "function" || key === "__cycle" ? memo
: (memo ? memo + "," : memo) + ("\"" + escapeString(key) + "\":" + stringifyValue(value));
}
var base64Digits = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/=";
/**
* Converts a string to a base-64 encoded ASCII string.
*/
function convertToBase64(input) {
var result = "";
var charCodes = getExpandedCharCodes(input);
var i = 0;
var length = charCodes.length;
var byte1, byte2, byte3, byte4;
while (i < length) {
// Convert every 6-bits in the input 3 character points
// into a base64 digit
byte1 = charCodes[i] >> 2;
byte2 = (charCodes[i] & 3) << 4 | charCodes[i + 1] >> 4;
byte3 = (charCodes[i + 1] & 15) << 2 | charCodes[i + 2] >> 6;
byte4 = charCodes[i + 2] & 63;
// We are out of characters in the input, set the extra
// digits to 64 (padding character).
if (i + 1 >= length) {
byte3 = byte4 = 64;
}
else if (i + 2 >= length) {
byte4 = 64;
}
// Write to the output
result += base64Digits.charAt(byte1) + base64Digits.charAt(byte2) + base64Digits.charAt(byte3) + base64Digits.charAt(byte4);
i += 3;
}
return result;
}
ts.convertToBase64 = convertToBase64;
var carriageReturnLineFeed = "\r\n";
var lineFeed = "\n";
function getNewLineCharacter(options) {
if (options.newLine === 0 /* CarriageReturnLineFeed */) {
return carriageReturnLineFeed;
}
else if (options.newLine === 1 /* LineFeed */) {
return lineFeed;
}
else if (ts.sys) {
return ts.sys.newLine;
}
return carriageReturnLineFeed;
}
ts.getNewLineCharacter = getNewLineCharacter;
/**
* Tests whether a node and its subtree is simple enough to have its position
* information ignored when emitting source maps in a destructuring assignment.
*
* @param node The expression to test.
*/
function isSimpleExpression(node) {
return isSimpleExpressionWorker(node, 0);
}
ts.isSimpleExpression = isSimpleExpression;
function isSimpleExpressionWorker(node, depth) {
if (depth <= 5) {
var kind = node.kind;
if (kind === 9 /* StringLiteral */
|| kind === 8 /* NumericLiteral */
|| kind === 11 /* RegularExpressionLiteral */
|| kind === 12 /* NoSubstitutionTemplateLiteral */
|| kind === 70 /* Identifier */
|| kind === 98 /* ThisKeyword */
|| kind === 96 /* SuperKeyword */
|| kind === 100 /* TrueKeyword */
|| kind === 85 /* FalseKeyword */
|| kind === 94 /* NullKeyword */) {
return true;
}
else if (kind === 177 /* PropertyAccessExpression */) {
return isSimpleExpressionWorker(node.expression, depth + 1);
}
else if (kind === 178 /* ElementAccessExpression */) {
return isSimpleExpressionWorker(node.expression, depth + 1)
&& isSimpleExpressionWorker(node.argumentExpression, depth + 1);
}
else if (kind === 190 /* PrefixUnaryExpression */
|| kind === 191 /* PostfixUnaryExpression */) {
return isSimpleExpressionWorker(node.operand, depth + 1);
}
else if (kind === 192 /* BinaryExpression */) {
return node.operatorToken.kind !== 39 /* AsteriskAsteriskToken */
&& isSimpleExpressionWorker(node.left, depth + 1)
&& isSimpleExpressionWorker(node.right, depth + 1);
}
else if (kind === 193 /* ConditionalExpression */) {
return isSimpleExpressionWorker(node.condition, depth + 1)
&& isSimpleExpressionWorker(node.whenTrue, depth + 1)
&& isSimpleExpressionWorker(node.whenFalse, depth + 1);
}
else if (kind === 188 /* VoidExpression */
|| kind === 187 /* TypeOfExpression */
|| kind === 186 /* DeleteExpression */) {
return isSimpleExpressionWorker(node.expression, depth + 1);
}
else if (kind === 175 /* ArrayLiteralExpression */) {
return node.elements.length === 0;
}
else if (kind === 176 /* ObjectLiteralExpression */) {
return node.properties.length === 0;
}
else if (kind === 179 /* CallExpression */) {
if (!isSimpleExpressionWorker(node.expression, depth + 1)) {
return false;
}
for (var _i = 0, _a = node.arguments; _i < _a.length; _i++) {
var argument = _a[_i];
if (!isSimpleExpressionWorker(argument, depth + 1)) {
return false;
}
}
return true;
}
}
return false;
}
var syntaxKindCache = ts.createMap();
function formatSyntaxKind(kind) {
var syntaxKindEnum = ts.SyntaxKind;
if (syntaxKindEnum) {
if (syntaxKindCache[kind]) {
return syntaxKindCache[kind];
}
for (var name_7 in syntaxKindEnum) {
if (syntaxKindEnum[name_7] === kind) {
return syntaxKindCache[kind] = kind.toString() + " (" + name_7 + ")";
}
}
}
else {
return kind.toString();
}
}
ts.formatSyntaxKind = formatSyntaxKind;
/**
* Increases (or decreases) a position by the provided amount.
*
* @param pos The position.
* @param value The delta.
*/
function movePos(pos, value) {
return ts.positionIsSynthesized(pos) ? -1 : pos + value;
}
ts.movePos = movePos;
/**
* Creates a new TextRange from the provided pos and end.
*
* @param pos The start position.
* @param end The end position.
*/
function createRange(pos, end) {
return { pos: pos, end: end };
}
ts.createRange = createRange;
/**
* Creates a new TextRange from a provided range with a new end position.
*
* @param range A TextRange.
* @param end The new end position.
*/
function moveRangeEnd(range, end) {
return createRange(range.pos, end);
}
ts.moveRangeEnd = moveRangeEnd;
/**
* Creates a new TextRange from a provided range with a new start position.
*
* @param range A TextRange.
* @param pos The new Start position.
*/
function moveRangePos(range, pos) {
return createRange(pos, range.end);
}
ts.moveRangePos = moveRangePos;
/**
* Moves the start position of a range past any decorators.
*/
function moveRangePastDecorators(node) {
return node.decorators && node.decorators.length > 0
? moveRangePos(node, node.decorators.end)
: node;
}
ts.moveRangePastDecorators = moveRangePastDecorators;
/**
* Moves the start position of a range past any decorators or modifiers.
*/
function moveRangePastModifiers(node) {
return node.modifiers && node.modifiers.length > 0
? moveRangePos(node, node.modifiers.end)
: moveRangePastDecorators(node);
}
ts.moveRangePastModifiers = moveRangePastModifiers;
/**
* Determines whether a TextRange has the same start and end positions.
*
* @param range A TextRange.
*/
function isCollapsedRange(range) {
return range.pos === range.end;
}
ts.isCollapsedRange = isCollapsedRange;
/**
* Creates a new TextRange from a provided range with its end position collapsed to its
* start position.
*
* @param range A TextRange.
*/
function collapseRangeToStart(range) {
return isCollapsedRange(range) ? range : moveRangeEnd(range, range.pos);
}
ts.collapseRangeToStart = collapseRangeToStart;
/**
* Creates a new TextRange from a provided range with its start position collapsed to its
* end position.
*
* @param range A TextRange.
*/
function collapseRangeToEnd(range) {
return isCollapsedRange(range) ? range : moveRangePos(range, range.end);
}
ts.collapseRangeToEnd = collapseRangeToEnd;
/**
* Creates a new TextRange for a token at the provides start position.
*
* @param pos The start position.
* @param token The token.
*/
function createTokenRange(pos, token) {
return createRange(pos, pos + ts.tokenToString(token).length);
}
ts.createTokenRange = createTokenRange;
function rangeIsOnSingleLine(range, sourceFile) {
return rangeStartIsOnSameLineAsRangeEnd(range, range, sourceFile);
}
ts.rangeIsOnSingleLine = rangeIsOnSingleLine;
function rangeStartPositionsAreOnSameLine(range1, range2, sourceFile) {
return positionsAreOnSameLine(getStartPositionOfRange(range1, sourceFile), getStartPositionOfRange(range2, sourceFile), sourceFile);
}
ts.rangeStartPositionsAreOnSameLine = rangeStartPositionsAreOnSameLine;
function rangeEndPositionsAreOnSameLine(range1, range2, sourceFile) {
return positionsAreOnSameLine(range1.end, range2.end, sourceFile);
}
ts.rangeEndPositionsAreOnSameLine = rangeEndPositionsAreOnSameLine;
function rangeStartIsOnSameLineAsRangeEnd(range1, range2, sourceFile) {
return positionsAreOnSameLine(getStartPositionOfRange(range1, sourceFile), range2.end, sourceFile);
}
ts.rangeStartIsOnSameLineAsRangeEnd = rangeStartIsOnSameLineAsRangeEnd;
function rangeEndIsOnSameLineAsRangeStart(range1, range2, sourceFile) {
return positionsAreOnSameLine(range1.end, getStartPositionOfRange(range2, sourceFile), sourceFile);
}
ts.rangeEndIsOnSameLineAsRangeStart = rangeEndIsOnSameLineAsRangeStart;
function positionsAreOnSameLine(pos1, pos2, sourceFile) {
return pos1 === pos2 ||
getLineOfLocalPosition(sourceFile, pos1) === getLineOfLocalPosition(sourceFile, pos2);
}
ts.positionsAreOnSameLine = positionsAreOnSameLine;
function getStartPositionOfRange(range, sourceFile) {
return ts.positionIsSynthesized(range.pos) ? -1 : ts.skipTrivia(sourceFile.text, range.pos);
}
ts.getStartPositionOfRange = getStartPositionOfRange;
function collectExternalModuleInfo(sourceFile, resolver) {
var externalImports = [];
var exportSpecifiers = ts.createMap();
var exportedBindings = ts.createMap();
var uniqueExports = ts.createMap();
var hasExportDefault = false;
var exportEquals = undefined;
var hasExportStarsToExportValues = false;
for (var _i = 0, _a = sourceFile.statements; _i < _a.length; _i++) {
var node = _a[_i];
switch (node.kind) {
case 235 /* ImportDeclaration */:
// import "mod"
// import x from "mod"
// import * as x from "mod"
// import { x, y } from "mod"
externalImports.push(node);
break;
case 234 /* ImportEqualsDeclaration */:
if (node.moduleReference.kind === 245 /* ExternalModuleReference */) {
// import x = require("mod")
externalImports.push(node);
}
break;
case 241 /* ExportDeclaration */:
if (node.moduleSpecifier) {
if (!node.exportClause) {
// export * from "mod"
externalImports.push(node);
hasExportStarsToExportValues = true;
}
else {
// export { x, y } from "mod"
externalImports.push(node);
}
}
else {
// export { x, y }
for (var _b = 0, _c = node.exportClause.elements; _b < _c.length; _b++) {
var specifier = _c[_b];
if (!uniqueExports[specifier.name.text]) {
var name_8 = specifier.propertyName || specifier.name;
ts.multiMapAdd(exportSpecifiers, name_8.text, specifier);
var decl = resolver.getReferencedImportDeclaration(name_8)
|| resolver.getReferencedValueDeclaration(name_8);
if (decl) {
ts.multiMapAdd(exportedBindings, getOriginalNodeId(decl), specifier.name);
}
uniqueExports[specifier.name.text] = specifier.name;
}
}
}
break;
case 240 /* ExportAssignment */:
if (node.isExportEquals && !exportEquals) {
// export = x
exportEquals = node;
}
break;
case 205 /* VariableStatement */:
if (hasModifier(node, 1 /* Export */)) {
for (var _d = 0, _e = node.declarationList.declarations; _d < _e.length; _d++) {
var decl = _e[_d];
collectExportedVariableInfo(decl, uniqueExports);
}
}
break;
case 225 /* FunctionDeclaration */:
if (hasModifier(node, 1 /* Export */)) {
if (hasModifier(node, 512 /* Default */)) {
// export default function() { }
if (!hasExportDefault) {
ts.multiMapAdd(exportedBindings, getOriginalNodeId(node), ts.getDeclarationName(node));
hasExportDefault = true;
}
}
else {
// export function x() { }
var name_9 = node.name;
if (!uniqueExports[name_9.text]) {
ts.multiMapAdd(exportedBindings, getOriginalNodeId(node), name_9);
uniqueExports[name_9.text] = name_9;
}
}
}
break;
case 226 /* ClassDeclaration */:
if (hasModifier(node, 1 /* Export */)) {
if (hasModifier(node, 512 /* Default */)) {
// export default class { }
if (!hasExportDefault) {
ts.multiMapAdd(exportedBindings, getOriginalNodeId(node), ts.getDeclarationName(node));
hasExportDefault = true;
}
}
else {
// export class x { }
var name_10 = node.name;
if (!uniqueExports[name_10.text]) {
ts.multiMapAdd(exportedBindings, getOriginalNodeId(node), name_10);
uniqueExports[name_10.text] = name_10;
}
}
}
break;
}
}
var exportedNames;
for (var key in uniqueExports) {
exportedNames = ts.append(exportedNames, uniqueExports[key]);
}
return { externalImports: externalImports, exportSpecifiers: exportSpecifiers, exportEquals: exportEquals, hasExportStarsToExportValues: hasExportStarsToExportValues, exportedBindings: exportedBindings, exportedNames: exportedNames };
}
ts.collectExternalModuleInfo = collectExternalModuleInfo;
function collectExportedVariableInfo(decl, uniqueExports) {
if (isBindingPattern(decl.name)) {
for (var _i = 0, _a = decl.name.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (!isOmittedExpression(element)) {
collectExportedVariableInfo(element, uniqueExports);
}
}
}
else if (!isGeneratedIdentifier(decl.name)) {
if (!uniqueExports[decl.name.text]) {
uniqueExports[decl.name.text] = decl.name;
}
}
}
/**
* Determines whether a name was originally the declaration name of an enum or namespace
* declaration.
*/
function isDeclarationNameOfEnumOrNamespace(node) {
var parseNode = getParseTreeNode(node);
if (parseNode) {
switch (parseNode.parent.kind) {
case 229 /* EnumDeclaration */:
case 230 /* ModuleDeclaration */:
return parseNode === parseNode.parent.name;
}
}
return false;
}
ts.isDeclarationNameOfEnumOrNamespace = isDeclarationNameOfEnumOrNamespace;
function getInitializedVariables(node) {
return ts.filter(node.declarations, isInitializedVariable);
}
ts.getInitializedVariables = getInitializedVariables;
function isInitializedVariable(node) {
return node.initializer !== undefined;
}
/**
* Gets a value indicating whether a node is merged with a class declaration in the same scope.
*/
function isMergedWithClass(node) {
if (node.symbol) {
for (var _i = 0, _a = node.symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (declaration.kind === 226 /* ClassDeclaration */ && declaration !== node) {
return true;
}
}
}
return false;
}
ts.isMergedWithClass = isMergedWithClass;
/**
* Gets a value indicating whether a node is the first declaration of its kind.
*
* @param node A Declaration node.
* @param kind The SyntaxKind to find among related declarations.
*/
function isFirstDeclarationOfKind(node, kind) {
return node.symbol && getDeclarationOfKind(node.symbol, kind) === node;
}
ts.isFirstDeclarationOfKind = isFirstDeclarationOfKind;
// Node tests
//
// All node tests in the following list should *not* reference parent pointers so that
// they may be used with transformations.
// Node Arrays
function isNodeArray(array) {
return array.hasOwnProperty("pos")
&& array.hasOwnProperty("end");
}
ts.isNodeArray = isNodeArray;
// Literals
function isNoSubstitutionTemplateLiteral(node) {
return node.kind === 12 /* NoSubstitutionTemplateLiteral */;
}
ts.isNoSubstitutionTemplateLiteral = isNoSubstitutionTemplateLiteral;
function isLiteralKind(kind) {
return 8 /* FirstLiteralToken */ <= kind && kind <= 12 /* LastLiteralToken */;
}
ts.isLiteralKind = isLiteralKind;
function isTextualLiteralKind(kind) {
return kind === 9 /* StringLiteral */ || kind === 12 /* NoSubstitutionTemplateLiteral */;
}
ts.isTextualLiteralKind = isTextualLiteralKind;
function isLiteralExpression(node) {
return isLiteralKind(node.kind);
}
ts.isLiteralExpression = isLiteralExpression;
// Pseudo-literals
function isTemplateLiteralKind(kind) {
return 12 /* FirstTemplateToken */ <= kind && kind <= 15 /* LastTemplateToken */;
}
ts.isTemplateLiteralKind = isTemplateLiteralKind;
function isTemplateHead(node) {
return node.kind === 13 /* TemplateHead */;
}
ts.isTemplateHead = isTemplateHead;
function isTemplateMiddleOrTemplateTail(node) {
var kind = node.kind;
return kind === 14 /* TemplateMiddle */
|| kind === 15 /* TemplateTail */;
}
ts.isTemplateMiddleOrTemplateTail = isTemplateMiddleOrTemplateTail;
// Identifiers
function isIdentifier(node) {
return node.kind === 70 /* Identifier */;
}
ts.isIdentifier = isIdentifier;
function isGeneratedIdentifier(node) {
// Using `>` here catches both `GeneratedIdentifierKind.None` and `undefined`.
return isIdentifier(node) && node.autoGenerateKind > 0 /* None */;
}
ts.isGeneratedIdentifier = isGeneratedIdentifier;
// Keywords
function isModifier(node) {
return isModifierKind(node.kind);
}
ts.isModifier = isModifier;
// Names
function isQualifiedName(node) {
return node.kind === 141 /* QualifiedName */;
}
ts.isQualifiedName = isQualifiedName;
function isComputedPropertyName(node) {
return node.kind === 142 /* ComputedPropertyName */;
}
ts.isComputedPropertyName = isComputedPropertyName;
function isEntityName(node) {
var kind = node.kind;
return kind === 141 /* QualifiedName */
|| kind === 70 /* Identifier */;
}
ts.isEntityName = isEntityName;
function isPropertyName(node) {
var kind = node.kind;
return kind === 70 /* Identifier */
|| kind === 9 /* StringLiteral */
|| kind === 8 /* NumericLiteral */
|| kind === 142 /* ComputedPropertyName */;
}
ts.isPropertyName = isPropertyName;
function isModuleName(node) {
var kind = node.kind;
return kind === 70 /* Identifier */
|| kind === 9 /* StringLiteral */;
}
ts.isModuleName = isModuleName;
function isBindingName(node) {
var kind = node.kind;
return kind === 70 /* Identifier */
|| kind === 172 /* ObjectBindingPattern */
|| kind === 173 /* ArrayBindingPattern */;
}
ts.isBindingName = isBindingName;
// Signature elements
function isTypeParameter(node) {
return node.kind === 143 /* TypeParameter */;
}
ts.isTypeParameter = isTypeParameter;
function isParameter(node) {
return node.kind === 144 /* Parameter */;
}
ts.isParameter = isParameter;
function isDecorator(node) {
return node.kind === 145 /* Decorator */;
}
ts.isDecorator = isDecorator;
// Type members
function isMethodDeclaration(node) {
return node.kind === 149 /* MethodDeclaration */;
}
ts.isMethodDeclaration = isMethodDeclaration;
function isClassElement(node) {
var kind = node.kind;
return kind === 150 /* Constructor */
|| kind === 147 /* PropertyDeclaration */
|| kind === 149 /* MethodDeclaration */
|| kind === 151 /* GetAccessor */
|| kind === 152 /* SetAccessor */
|| kind === 155 /* IndexSignature */
|| kind === 203 /* SemicolonClassElement */;
}
ts.isClassElement = isClassElement;
function isObjectLiteralElementLike(node) {
var kind = node.kind;
return kind === 257 /* PropertyAssignment */
|| kind === 258 /* ShorthandPropertyAssignment */
|| kind === 259 /* SpreadAssignment */
|| kind === 149 /* MethodDeclaration */
|| kind === 151 /* GetAccessor */
|| kind === 152 /* SetAccessor */
|| kind === 244 /* MissingDeclaration */;
}
ts.isObjectLiteralElementLike = isObjectLiteralElementLike;
// Type
function isTypeNodeKind(kind) {
return (kind >= 156 /* FirstTypeNode */ && kind <= 171 /* LastTypeNode */)
|| kind === 118 /* AnyKeyword */
|| kind === 132 /* NumberKeyword */
|| kind === 121 /* BooleanKeyword */
|| kind === 134 /* StringKeyword */
|| kind === 135 /* SymbolKeyword */
|| kind === 104 /* VoidKeyword */
|| kind === 129 /* NeverKeyword */
|| kind === 199 /* ExpressionWithTypeArguments */;
}
/**
* Node test that determines whether a node is a valid type node.
* This differs from the `isPartOfTypeNode` function which determines whether a node is *part*
* of a TypeNode.
*/
function isTypeNode(node) {
return isTypeNodeKind(node.kind);
}
ts.isTypeNode = isTypeNode;
// Binding patterns
function isBindingPattern(node) {
if (node) {
var kind = node.kind;
return kind === 173 /* ArrayBindingPattern */
|| kind === 172 /* ObjectBindingPattern */;
}
return false;
}
ts.isBindingPattern = isBindingPattern;
function isBindingElement(node) {
return node.kind === 174 /* BindingElement */;
}
ts.isBindingElement = isBindingElement;
function isArrayBindingElement(node) {
var kind = node.kind;
return kind === 174 /* BindingElement */
|| kind === 198 /* OmittedExpression */;
}
ts.isArrayBindingElement = isArrayBindingElement;
// Expression
function isArrayLiteralExpression(node) {
return node.kind === 175 /* ArrayLiteralExpression */;
}
ts.isArrayLiteralExpression = isArrayLiteralExpression;
function isObjectLiteralExpression(node) {
return node.kind === 176 /* ObjectLiteralExpression */;
}
ts.isObjectLiteralExpression = isObjectLiteralExpression;
function isPropertyAccessExpression(node) {
return node.kind === 177 /* PropertyAccessExpression */;
}
ts.isPropertyAccessExpression = isPropertyAccessExpression;
function isElementAccessExpression(node) {
return node.kind === 178 /* ElementAccessExpression */;
}
ts.isElementAccessExpression = isElementAccessExpression;
function isBinaryExpression(node) {
return node.kind === 192 /* BinaryExpression */;
}
ts.isBinaryExpression = isBinaryExpression;
function isConditionalExpression(node) {
return node.kind === 193 /* ConditionalExpression */;
}
ts.isConditionalExpression = isConditionalExpression;
function isCallExpression(node) {
return node.kind === 179 /* CallExpression */;
}
ts.isCallExpression = isCallExpression;
function isTemplateLiteral(node) {
var kind = node.kind;
return kind === 194 /* TemplateExpression */
|| kind === 12 /* NoSubstitutionTemplateLiteral */;
}
ts.isTemplateLiteral = isTemplateLiteral;
function isSpreadExpression(node) {
return node.kind === 196 /* SpreadElement */;
}
ts.isSpreadExpression = isSpreadExpression;
function isExpressionWithTypeArguments(node) {
return node.kind === 199 /* ExpressionWithTypeArguments */;
}
ts.isExpressionWithTypeArguments = isExpressionWithTypeArguments;
function isLeftHandSideExpressionKind(kind) {
return kind === 177 /* PropertyAccessExpression */
|| kind === 178 /* ElementAccessExpression */
|| kind === 180 /* NewExpression */
|| kind === 179 /* CallExpression */
|| kind === 246 /* JsxElement */
|| kind === 247 /* JsxSelfClosingElement */
|| kind === 181 /* TaggedTemplateExpression */
|| kind === 175 /* ArrayLiteralExpression */
|| kind === 183 /* ParenthesizedExpression */
|| kind === 176 /* ObjectLiteralExpression */
|| kind === 197 /* ClassExpression */
|| kind === 184 /* FunctionExpression */
|| kind === 70 /* Identifier */
|| kind === 11 /* RegularExpressionLiteral */
|| kind === 8 /* NumericLiteral */
|| kind === 9 /* StringLiteral */
|| kind === 12 /* NoSubstitutionTemplateLiteral */
|| kind === 194 /* TemplateExpression */
|| kind === 85 /* FalseKeyword */
|| kind === 94 /* NullKeyword */
|| kind === 98 /* ThisKeyword */
|| kind === 100 /* TrueKeyword */
|| kind === 96 /* SuperKeyword */
|| kind === 201 /* NonNullExpression */;
}
function isLeftHandSideExpression(node) {
return isLeftHandSideExpressionKind(ts.skipPartiallyEmittedExpressions(node).kind);
}
ts.isLeftHandSideExpression = isLeftHandSideExpression;
function isUnaryExpressionKind(kind) {
return kind === 190 /* PrefixUnaryExpression */
|| kind === 191 /* PostfixUnaryExpression */
|| kind === 186 /* DeleteExpression */
|| kind === 187 /* TypeOfExpression */
|| kind === 188 /* VoidExpression */
|| kind === 189 /* AwaitExpression */
|| kind === 182 /* TypeAssertionExpression */
|| isLeftHandSideExpressionKind(kind);
}
function isUnaryExpression(node) {
return isUnaryExpressionKind(ts.skipPartiallyEmittedExpressions(node).kind);
}
ts.isUnaryExpression = isUnaryExpression;
function isExpressionKind(kind) {
return kind === 193 /* ConditionalExpression */
|| kind === 195 /* YieldExpression */
|| kind === 185 /* ArrowFunction */
|| kind === 192 /* BinaryExpression */
|| kind === 196 /* SpreadElement */
|| kind === 200 /* AsExpression */
|| kind === 198 /* OmittedExpression */
|| isUnaryExpressionKind(kind);
}
function isExpression(node) {
return isExpressionKind(ts.skipPartiallyEmittedExpressions(node).kind);
}
ts.isExpression = isExpression;
function isAssertionExpression(node) {
var kind = node.kind;
return kind === 182 /* TypeAssertionExpression */
|| kind === 200 /* AsExpression */;
}
ts.isAssertionExpression = isAssertionExpression;
function isPartiallyEmittedExpression(node) {
return node.kind === 293 /* PartiallyEmittedExpression */;
}
ts.isPartiallyEmittedExpression = isPartiallyEmittedExpression;
function isNotEmittedStatement(node) {
return node.kind === 292 /* NotEmittedStatement */;
}
ts.isNotEmittedStatement = isNotEmittedStatement;
function isNotEmittedOrPartiallyEmittedNode(node) {
return isNotEmittedStatement(node)
|| isPartiallyEmittedExpression(node);
}
ts.isNotEmittedOrPartiallyEmittedNode = isNotEmittedOrPartiallyEmittedNode;
function isOmittedExpression(node) {
return node.kind === 198 /* OmittedExpression */;
}
ts.isOmittedExpression = isOmittedExpression;
// Misc
function isTemplateSpan(node) {
return node.kind === 202 /* TemplateSpan */;
}
ts.isTemplateSpan = isTemplateSpan;
// Element
function isBlock(node) {
return node.kind === 204 /* Block */;
}
ts.isBlock = isBlock;
function isConciseBody(node) {
return isBlock(node)
|| isExpression(node);
}
ts.isConciseBody = isConciseBody;
function isFunctionBody(node) {
return isBlock(node);
}
ts.isFunctionBody = isFunctionBody;
function isForInitializer(node) {
return isVariableDeclarationList(node)
|| isExpression(node);
}
ts.isForInitializer = isForInitializer;
function isVariableDeclaration(node) {
return node.kind === 223 /* VariableDeclaration */;
}
ts.isVariableDeclaration = isVariableDeclaration;
function isVariableDeclarationList(node) {
return node.kind === 224 /* VariableDeclarationList */;
}
ts.isVariableDeclarationList = isVariableDeclarationList;
function isCaseBlock(node) {
return node.kind === 232 /* CaseBlock */;
}
ts.isCaseBlock = isCaseBlock;
function isModuleBody(node) {
var kind = node.kind;
return kind === 231 /* ModuleBlock */
|| kind === 230 /* ModuleDeclaration */;
}
ts.isModuleBody = isModuleBody;
function isImportEqualsDeclaration(node) {
return node.kind === 234 /* ImportEqualsDeclaration */;
}
ts.isImportEqualsDeclaration = isImportEqualsDeclaration;
function isImportClause(node) {
return node.kind === 236 /* ImportClause */;
}
ts.isImportClause = isImportClause;
function isNamedImportBindings(node) {
var kind = node.kind;
return kind === 238 /* NamedImports */
|| kind === 237 /* NamespaceImport */;
}
ts.isNamedImportBindings = isNamedImportBindings;
function isImportSpecifier(node) {
return node.kind === 239 /* ImportSpecifier */;
}
ts.isImportSpecifier = isImportSpecifier;
function isNamedExports(node) {
return node.kind === 242 /* NamedExports */;
}
ts.isNamedExports = isNamedExports;
function isExportSpecifier(node) {
return node.kind === 243 /* ExportSpecifier */;
}
ts.isExportSpecifier = isExportSpecifier;
function isModuleOrEnumDeclaration(node) {
return node.kind === 230 /* ModuleDeclaration */ || node.kind === 229 /* EnumDeclaration */;
}
ts.isModuleOrEnumDeclaration = isModuleOrEnumDeclaration;
function isDeclarationKind(kind) {
return kind === 185 /* ArrowFunction */
|| kind === 174 /* BindingElement */
|| kind === 226 /* ClassDeclaration */
|| kind === 197 /* ClassExpression */
|| kind === 150 /* Constructor */
|| kind === 229 /* EnumDeclaration */
|| kind === 260 /* EnumMember */
|| kind === 243 /* ExportSpecifier */
|| kind === 225 /* FunctionDeclaration */
|| kind === 184 /* FunctionExpression */
|| kind === 151 /* GetAccessor */
|| kind === 236 /* ImportClause */
|| kind === 234 /* ImportEqualsDeclaration */
|| kind === 239 /* ImportSpecifier */
|| kind === 227 /* InterfaceDeclaration */
|| kind === 149 /* MethodDeclaration */
|| kind === 148 /* MethodSignature */
|| kind === 230 /* ModuleDeclaration */
|| kind === 233 /* NamespaceExportDeclaration */
|| kind === 237 /* NamespaceImport */
|| kind === 144 /* Parameter */
|| kind === 257 /* PropertyAssignment */
|| kind === 147 /* PropertyDeclaration */
|| kind === 146 /* PropertySignature */
|| kind === 152 /* SetAccessor */
|| kind === 258 /* ShorthandPropertyAssignment */
|| kind === 228 /* TypeAliasDeclaration */
|| kind === 143 /* TypeParameter */
|| kind === 223 /* VariableDeclaration */
|| kind === 284 /* JSDocTypedefTag */;
}
function isDeclarationStatementKind(kind) {
return kind === 225 /* FunctionDeclaration */
|| kind === 244 /* MissingDeclaration */
|| kind === 226 /* ClassDeclaration */
|| kind === 227 /* InterfaceDeclaration */
|| kind === 228 /* TypeAliasDeclaration */
|| kind === 229 /* EnumDeclaration */
|| kind === 230 /* ModuleDeclaration */
|| kind === 235 /* ImportDeclaration */
|| kind === 234 /* ImportEqualsDeclaration */
|| kind === 241 /* ExportDeclaration */
|| kind === 240 /* ExportAssignment */
|| kind === 233 /* NamespaceExportDeclaration */;
}
function isStatementKindButNotDeclarationKind(kind) {
return kind === 215 /* BreakStatement */
|| kind === 214 /* ContinueStatement */
|| kind === 222 /* DebuggerStatement */
|| kind === 209 /* DoStatement */
|| kind === 207 /* ExpressionStatement */
|| kind === 206 /* EmptyStatement */
|| kind === 212 /* ForInStatement */
|| kind === 213 /* ForOfStatement */
|| kind === 211 /* ForStatement */
|| kind === 208 /* IfStatement */
|| kind === 219 /* LabeledStatement */
|| kind === 216 /* ReturnStatement */
|| kind === 218 /* SwitchStatement */
|| kind === 220 /* ThrowStatement */
|| kind === 221 /* TryStatement */
|| kind === 205 /* VariableStatement */
|| kind === 210 /* WhileStatement */
|| kind === 217 /* WithStatement */
|| kind === 292 /* NotEmittedStatement */
|| kind === 295 /* EndOfDeclarationMarker */
|| kind === 294 /* MergeDeclarationMarker */;
}
function isDeclaration(node) {
return isDeclarationKind(node.kind);
}
ts.isDeclaration = isDeclaration;
function isDeclarationStatement(node) {
return isDeclarationStatementKind(node.kind);
}
ts.isDeclarationStatement = isDeclarationStatement;
/**
* Determines whether the node is a statement that is not also a declaration
*/
function isStatementButNotDeclaration(node) {
return isStatementKindButNotDeclarationKind(node.kind);
}
ts.isStatementButNotDeclaration = isStatementButNotDeclaration;
function isStatement(node) {
var kind = node.kind;
return isStatementKindButNotDeclarationKind(kind)
|| isDeclarationStatementKind(kind)
|| kind === 204 /* Block */;
}
ts.isStatement = isStatement;
// Module references
function isModuleReference(node) {
var kind = node.kind;
return kind === 245 /* ExternalModuleReference */
|| kind === 141 /* QualifiedName */
|| kind === 70 /* Identifier */;
}
ts.isModuleReference = isModuleReference;
// JSX
function isJsxOpeningElement(node) {
return node.kind === 248 /* JsxOpeningElement */;
}
ts.isJsxOpeningElement = isJsxOpeningElement;
function isJsxClosingElement(node) {
return node.kind === 249 /* JsxClosingElement */;
}
ts.isJsxClosingElement = isJsxClosingElement;
function isJsxTagNameExpression(node) {
var kind = node.kind;
return kind === 98 /* ThisKeyword */
|| kind === 70 /* Identifier */
|| kind === 177 /* PropertyAccessExpression */;
}
ts.isJsxTagNameExpression = isJsxTagNameExpression;
function isJsxChild(node) {
var kind = node.kind;
return kind === 246 /* JsxElement */
|| kind === 252 /* JsxExpression */
|| kind === 247 /* JsxSelfClosingElement */
|| kind === 10 /* JsxText */;
}
ts.isJsxChild = isJsxChild;
function isJsxAttributeLike(node) {
var kind = node.kind;
return kind === 250 /* JsxAttribute */
|| kind === 251 /* JsxSpreadAttribute */;
}
ts.isJsxAttributeLike = isJsxAttributeLike;
function isJsxSpreadAttribute(node) {
return node.kind === 251 /* JsxSpreadAttribute */;
}
ts.isJsxSpreadAttribute = isJsxSpreadAttribute;
function isJsxAttribute(node) {
return node.kind === 250 /* JsxAttribute */;
}
ts.isJsxAttribute = isJsxAttribute;
function isStringLiteralOrJsxExpression(node) {
var kind = node.kind;
return kind === 9 /* StringLiteral */
|| kind === 252 /* JsxExpression */;
}
ts.isStringLiteralOrJsxExpression = isStringLiteralOrJsxExpression;
// Clauses
function isCaseOrDefaultClause(node) {
var kind = node.kind;
return kind === 253 /* CaseClause */
|| kind === 254 /* DefaultClause */;
}
ts.isCaseOrDefaultClause = isCaseOrDefaultClause;
function isHeritageClause(node) {
return node.kind === 255 /* HeritageClause */;
}
ts.isHeritageClause = isHeritageClause;
function isCatchClause(node) {
return node.kind === 256 /* CatchClause */;
}
ts.isCatchClause = isCatchClause;
// Property assignments
function isPropertyAssignment(node) {
return node.kind === 257 /* PropertyAssignment */;
}
ts.isPropertyAssignment = isPropertyAssignment;
function isShorthandPropertyAssignment(node) {
return node.kind === 258 /* ShorthandPropertyAssignment */;
}
ts.isShorthandPropertyAssignment = isShorthandPropertyAssignment;
// Enum
function isEnumMember(node) {
return node.kind === 260 /* EnumMember */;
}
ts.isEnumMember = isEnumMember;
// Top-level nodes
function isSourceFile(node) {
return node.kind === 261 /* SourceFile */;
}
ts.isSourceFile = isSourceFile;
function isWatchSet(options) {
// Firefox has Object.prototype.watch
return options.watch && options.hasOwnProperty("watch");
}
ts.isWatchSet = isWatchSet;
})(ts || (ts = {}));
(function (ts) {
function getDefaultLibFileName(options) {
switch (options.target) {
case 5 /* ESNext */:
case 4 /* ES2017 */:
return "lib.es2017.d.ts";
case 3 /* ES2016 */:
return "lib.es2016.d.ts";
case 2 /* ES2015 */:
return "lib.es6.d.ts";
default:
return "lib.d.ts";
}
}
ts.getDefaultLibFileName = getDefaultLibFileName;
function textSpanEnd(span) {
return span.start + span.length;
}
ts.textSpanEnd = textSpanEnd;
function textSpanIsEmpty(span) {
return span.length === 0;
}
ts.textSpanIsEmpty = textSpanIsEmpty;
function textSpanContainsPosition(span, position) {
return position >= span.start && position < textSpanEnd(span);
}
ts.textSpanContainsPosition = textSpanContainsPosition;
// Returns true if 'span' contains 'other'.
function textSpanContainsTextSpan(span, other) {
return other.start >= span.start && textSpanEnd(other) <= textSpanEnd(span);
}
ts.textSpanContainsTextSpan = textSpanContainsTextSpan;
function textSpanOverlapsWith(span, other) {
var overlapStart = Math.max(span.start, other.start);
var overlapEnd = Math.min(textSpanEnd(span), textSpanEnd(other));
return overlapStart < overlapEnd;
}
ts.textSpanOverlapsWith = textSpanOverlapsWith;
function textSpanOverlap(span1, span2) {
var overlapStart = Math.max(span1.start, span2.start);
var overlapEnd = Math.min(textSpanEnd(span1), textSpanEnd(span2));
if (overlapStart < overlapEnd) {
return createTextSpanFromBounds(overlapStart, overlapEnd);
}
return undefined;
}
ts.textSpanOverlap = textSpanOverlap;
function textSpanIntersectsWithTextSpan(span, other) {
return other.start <= textSpanEnd(span) && textSpanEnd(other) >= span.start;
}
ts.textSpanIntersectsWithTextSpan = textSpanIntersectsWithTextSpan;
function textSpanIntersectsWith(span, start, length) {
var end = start + length;
return start <= textSpanEnd(span) && end >= span.start;
}
ts.textSpanIntersectsWith = textSpanIntersectsWith;
function decodedTextSpanIntersectsWith(start1, length1, start2, length2) {
var end1 = start1 + length1;
var end2 = start2 + length2;
return start2 <= end1 && end2 >= start1;
}
ts.decodedTextSpanIntersectsWith = decodedTextSpanIntersectsWith;
function textSpanIntersectsWithPosition(span, position) {
return position <= textSpanEnd(span) && position >= span.start;
}
ts.textSpanIntersectsWithPosition = textSpanIntersectsWithPosition;
function textSpanIntersection(span1, span2) {
var intersectStart = Math.max(span1.start, span2.start);
var intersectEnd = Math.min(textSpanEnd(span1), textSpanEnd(span2));
if (intersectStart <= intersectEnd) {
return createTextSpanFromBounds(intersectStart, intersectEnd);
}
return undefined;
}
ts.textSpanIntersection = textSpanIntersection;
function createTextSpan(start, length) {
if (start < 0) {
throw new Error("start < 0");
}
if (length < 0) {
throw new Error("length < 0");
}
return { start: start, length: length };
}
ts.createTextSpan = createTextSpan;
function createTextSpanFromBounds(start, end) {
return createTextSpan(start, end - start);
}
ts.createTextSpanFromBounds = createTextSpanFromBounds;
function textChangeRangeNewSpan(range) {
return createTextSpan(range.span.start, range.newLength);
}
ts.textChangeRangeNewSpan = textChangeRangeNewSpan;
function textChangeRangeIsUnchanged(range) {
return textSpanIsEmpty(range.span) && range.newLength === 0;
}
ts.textChangeRangeIsUnchanged = textChangeRangeIsUnchanged;
function createTextChangeRange(span, newLength) {
if (newLength < 0) {
throw new Error("newLength < 0");
}
return { span: span, newLength: newLength };
}
ts.createTextChangeRange = createTextChangeRange;
ts.unchangedTextChangeRange = createTextChangeRange(createTextSpan(0, 0), 0);
/**
* Called to merge all the changes that occurred across several versions of a script snapshot
* into a single change. i.e. if a user keeps making successive edits to a script we will
* have a text change from V1 to V2, V2 to V3, ..., Vn.
*
* This function will then merge those changes into a single change range valid between V1 and
* Vn.
*/
function collapseTextChangeRangesAcrossMultipleVersions(changes) {
if (changes.length === 0) {
return ts.unchangedTextChangeRange;
}
if (changes.length === 1) {
return changes[0];
}
// We change from talking about { { oldStart, oldLength }, newLength } to { oldStart, oldEnd, newEnd }
// as it makes things much easier to reason about.
var change0 = changes[0];
var oldStartN = change0.span.start;
var oldEndN = textSpanEnd(change0.span);
var newEndN = oldStartN + change0.newLength;
for (var i = 1; i < changes.length; i++) {
var nextChange = changes[i];
// Consider the following case:
// i.e. two edits. The first represents the text change range { { 10, 50 }, 30 }. i.e. The span starting
// at 10, with length 50 is reduced to length 30. The second represents the text change range { { 30, 30 }, 40 }.
// i.e. the span starting at 30 with length 30 is increased to length 40.
//
// 0 10 20 30 40 50 60 70 80 90 100
// -------------------------------------------------------------------------------------------------------
// | /
// | /----
// T1 | /----
// | /----
// | /----
// -------------------------------------------------------------------------------------------------------
// | \
// | \
// T2 | \
// | \
// | \
// -------------------------------------------------------------------------------------------------------
//
// Merging these turns out to not be too difficult. First, determining the new start of the change is trivial
// it's just the min of the old and new starts. i.e.:
//
// 0 10 20 30 40 50 60 70 80 90 100
// ------------------------------------------------------------*------------------------------------------
// | /
// | /----
// T1 | /----
// | /----
// | /----
// ----------------------------------------$-------------------$------------------------------------------
// . | \
// . | \
// T2 . | \
// . | \
// . | \
// ----------------------------------------------------------------------*--------------------------------
//
// (Note the dots represent the newly inferred start.
// Determining the new and old end is also pretty simple. Basically it boils down to paying attention to the
// absolute positions at the asterisks, and the relative change between the dollar signs. Basically, we see
// which if the two $'s precedes the other, and we move that one forward until they line up. in this case that
// means:
//
// 0 10 20 30 40 50 60 70 80 90 100
// --------------------------------------------------------------------------------*----------------------
// | /
// | /----
// T1 | /----
// | /----
// | /----
// ------------------------------------------------------------$------------------------------------------
// . | \
// . | \
// T2 . | \
// . | \
// . | \
// ----------------------------------------------------------------------*--------------------------------
//
// In other words (in this case), we're recognizing that the second edit happened after where the first edit
// ended with a delta of 20 characters (60 - 40). Thus, if we go back in time to where the first edit started
// that's the same as if we started at char 80 instead of 60.
//
// As it so happens, the same logic applies if the second edit precedes the first edit. In that case rather
// than pushing the first edit forward to match the second, we'll push the second edit forward to match the
// first.
//
// In this case that means we have { oldStart: 10, oldEnd: 80, newEnd: 70 } or, in TextChangeRange
// semantics: { { start: 10, length: 70 }, newLength: 60 }
//
// The math then works out as follows.
// If we have { oldStart1, oldEnd1, newEnd1 } and { oldStart2, oldEnd2, newEnd2 } then we can compute the
// final result like so:
//
// {
// oldStart3: Min(oldStart1, oldStart2),
// oldEnd3 : Max(oldEnd1, oldEnd1 + (oldEnd2 - newEnd1)),
// newEnd3 : Max(newEnd2, newEnd2 + (newEnd1 - oldEnd2))
// }
var oldStart1 = oldStartN;
var oldEnd1 = oldEndN;
var newEnd1 = newEndN;
var oldStart2 = nextChange.span.start;
var oldEnd2 = textSpanEnd(nextChange.span);
var newEnd2 = oldStart2 + nextChange.newLength;
oldStartN = Math.min(oldStart1, oldStart2);
oldEndN = Math.max(oldEnd1, oldEnd1 + (oldEnd2 - newEnd1));
newEndN = Math.max(newEnd2, newEnd2 + (newEnd1 - oldEnd2));
}
return createTextChangeRange(createTextSpanFromBounds(oldStartN, oldEndN), /*newLength:*/ newEndN - oldStartN);
}
ts.collapseTextChangeRangesAcrossMultipleVersions = collapseTextChangeRangesAcrossMultipleVersions;
function getTypeParameterOwner(d) {
if (d && d.kind === 143 /* TypeParameter */) {
for (var current = d; current; current = current.parent) {
if (ts.isFunctionLike(current) || ts.isClassLike(current) || current.kind === 227 /* InterfaceDeclaration */) {
return current;
}
}
}
}
ts.getTypeParameterOwner = getTypeParameterOwner;
function isParameterPropertyDeclaration(node) {
return ts.hasModifier(node, 92 /* ParameterPropertyModifier */) && node.parent.kind === 150 /* Constructor */ && ts.isClassLike(node.parent.parent);
}
ts.isParameterPropertyDeclaration = isParameterPropertyDeclaration;
function walkUpBindingElementsAndPatterns(node) {
while (node && (node.kind === 174 /* BindingElement */ || ts.isBindingPattern(node))) {
node = node.parent;
}
return node;
}
function getCombinedModifierFlags(node) {
node = walkUpBindingElementsAndPatterns(node);
var flags = ts.getModifierFlags(node);
if (node.kind === 223 /* VariableDeclaration */) {
node = node.parent;
}
if (node && node.kind === 224 /* VariableDeclarationList */) {
flags |= ts.getModifierFlags(node);
node = node.parent;
}
if (node && node.kind === 205 /* VariableStatement */) {
flags |= ts.getModifierFlags(node);
}
return flags;
}
ts.getCombinedModifierFlags = getCombinedModifierFlags;
// Returns the node flags for this node and all relevant parent nodes. This is done so that
// nodes like variable declarations and binding elements can returned a view of their flags
// that includes the modifiers from their container. i.e. flags like export/declare aren't
// stored on the variable declaration directly, but on the containing variable statement
// (if it has one). Similarly, flags for let/const are store on the variable declaration
// list. By calling this function, all those flags are combined so that the client can treat
// the node as if it actually had those flags.
function getCombinedNodeFlags(node) {
node = walkUpBindingElementsAndPatterns(node);
var flags = node.flags;
if (node.kind === 223 /* VariableDeclaration */) {
node = node.parent;
}
if (node && node.kind === 224 /* VariableDeclarationList */) {
flags |= node.flags;
node = node.parent;
}
if (node && node.kind === 205 /* VariableStatement */) {
flags |= node.flags;
}
return flags;
}
ts.getCombinedNodeFlags = getCombinedNodeFlags;
})(ts || (ts = {}));
/// <reference path="core.ts"/>
/// <reference path="utilities.ts"/>
/* @internal */
var ts;
(function (ts) {
var NodeConstructor;
var SourceFileConstructor;
function createNode(kind, location, flags) {
var ConstructorForKind = kind === 261 /* SourceFile */
? (SourceFileConstructor || (SourceFileConstructor = ts.objectAllocator.getSourceFileConstructor()))
: (NodeConstructor || (NodeConstructor = ts.objectAllocator.getNodeConstructor()));
var node = location
? new ConstructorForKind(kind, location.pos, location.end)
: new ConstructorForKind(kind, /*pos*/ -1, /*end*/ -1);
node.flags = flags | 8 /* Synthesized */;
return node;
}
function updateNode(updated, original) {
if (updated !== original) {
setOriginalNode(updated, original);
if (original.startsOnNewLine) {
updated.startsOnNewLine = true;
}
ts.aggregateTransformFlags(updated);
}
return updated;
}
ts.updateNode = updateNode;
function createNodeArray(elements, location, hasTrailingComma) {
if (elements) {
if (ts.isNodeArray(elements)) {
return elements;
}
}
else {
elements = [];
}
var array = elements;
if (location) {
array.pos = location.pos;
array.end = location.end;
}
else {
array.pos = -1;
array.end = -1;
}
if (hasTrailingComma) {
array.hasTrailingComma = true;
}
return array;
}
ts.createNodeArray = createNodeArray;
function createSynthesizedNode(kind, startsOnNewLine) {
var node = createNode(kind, /*location*/ undefined);
node.startsOnNewLine = startsOnNewLine;
return node;
}
ts.createSynthesizedNode = createSynthesizedNode;
function createSynthesizedNodeArray(elements) {
return createNodeArray(elements, /*location*/ undefined);
}
ts.createSynthesizedNodeArray = createSynthesizedNodeArray;
/**
* Creates a shallow, memberwise clone of a node with no source map location.
*/
function getSynthesizedClone(node) {
// We don't use "clone" from core.ts here, as we need to preserve the prototype chain of
// the original node. We also need to exclude specific properties and only include own-
// properties (to skip members already defined on the shared prototype).
var clone = createNode(node.kind, /*location*/ undefined, node.flags);
setOriginalNode(clone, node);
for (var key in node) {
if (clone.hasOwnProperty(key) || !node.hasOwnProperty(key)) {
continue;
}
clone[key] = node[key];
}
return clone;
}
ts.getSynthesizedClone = getSynthesizedClone;
/**
* Creates a shallow, memberwise clone of a node for mutation.
*/
function getMutableClone(node) {
var clone = getSynthesizedClone(node);
clone.pos = node.pos;
clone.end = node.end;
clone.parent = node.parent;
return clone;
}
ts.getMutableClone = getMutableClone;
function createLiteral(value, location) {
if (typeof value === "number") {
var node = createNode(8 /* NumericLiteral */, location, /*flags*/ undefined);
node.text = value.toString();
return node;
}
else if (typeof value === "boolean") {
return createNode(value ? 100 /* TrueKeyword */ : 85 /* FalseKeyword */, location, /*flags*/ undefined);
}
else if (typeof value === "string") {
var node = createNode(9 /* StringLiteral */, location, /*flags*/ undefined);
node.text = value;
return node;
}
else if (value) {
var node = createNode(9 /* StringLiteral */, location, /*flags*/ undefined);
node.textSourceNode = value;
node.text = value.text;
return node;
}
}
ts.createLiteral = createLiteral;
// Identifiers
var nextAutoGenerateId = 0;
function createIdentifier(text, location) {
var node = createNode(70 /* Identifier */, location);
node.text = ts.escapeIdentifier(text);
node.originalKeywordKind = ts.stringToToken(text);
node.autoGenerateKind = 0 /* None */;
node.autoGenerateId = 0;
return node;
}
ts.createIdentifier = createIdentifier;
function createTempVariable(recordTempVariable, location) {
var name = createNode(70 /* Identifier */, location);
name.text = "";
name.originalKeywordKind = 0 /* Unknown */;
name.autoGenerateKind = 1 /* Auto */;
name.autoGenerateId = nextAutoGenerateId;
nextAutoGenerateId++;
if (recordTempVariable) {
recordTempVariable(name);
}
return name;
}
ts.createTempVariable = createTempVariable;
function createLoopVariable(location) {
var name = createNode(70 /* Identifier */, location);
name.text = "";
name.originalKeywordKind = 0 /* Unknown */;
name.autoGenerateKind = 2 /* Loop */;
name.autoGenerateId = nextAutoGenerateId;
nextAutoGenerateId++;
return name;
}
ts.createLoopVariable = createLoopVariable;
function createUniqueName(text, location) {
var name = createNode(70 /* Identifier */, location);
name.text = text;
name.originalKeywordKind = 0 /* Unknown */;
name.autoGenerateKind = 3 /* Unique */;
name.autoGenerateId = nextAutoGenerateId;
nextAutoGenerateId++;
return name;
}
ts.createUniqueName = createUniqueName;
function getGeneratedNameForNode(node, location) {
var name = createNode(70 /* Identifier */, location);
name.original = node;
name.text = "";
name.originalKeywordKind = 0 /* Unknown */;
name.autoGenerateKind = 4 /* Node */;
name.autoGenerateId = nextAutoGenerateId;
nextAutoGenerateId++;
return name;
}
ts.getGeneratedNameForNode = getGeneratedNameForNode;
// Punctuation
function createToken(token) {
return createNode(token);
}
ts.createToken = createToken;
// Reserved words
function createSuper() {
var node = createNode(96 /* SuperKeyword */);
return node;
}
ts.createSuper = createSuper;
function createThis(location) {
var node = createNode(98 /* ThisKeyword */, location);
return node;
}
ts.createThis = createThis;
function createNull() {
var node = createNode(94 /* NullKeyword */);
return node;
}
ts.createNull = createNull;
// Names
function createComputedPropertyName(expression, location) {
var node = createNode(142 /* ComputedPropertyName */, location);
node.expression = expression;
return node;
}
ts.createComputedPropertyName = createComputedPropertyName;
function updateComputedPropertyName(node, expression) {
if (node.expression !== expression) {
return updateNode(createComputedPropertyName(expression, node), node);
}
return node;
}
ts.updateComputedPropertyName = updateComputedPropertyName;
// Signature elements
function createParameter(decorators, modifiers, dotDotDotToken, name, questionToken, type, initializer, location, flags) {
var node = createNode(144 /* Parameter */, location, flags);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.dotDotDotToken = dotDotDotToken;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.questionToken = questionToken;
node.type = type;
node.initializer = initializer ? parenthesizeExpressionForList(initializer) : undefined;
return node;
}
ts.createParameter = createParameter;
function updateParameter(node, decorators, modifiers, name, type, initializer) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.name !== name || node.type !== type || node.initializer !== initializer) {
return updateNode(createParameter(decorators, modifiers, node.dotDotDotToken, name, node.questionToken, type, initializer, /*location*/ node, /*flags*/ node.flags), node);
}
return node;
}
ts.updateParameter = updateParameter;
// Type members
function createProperty(decorators, modifiers, name, questionToken, type, initializer, location) {
var node = createNode(147 /* PropertyDeclaration */, location);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.questionToken = questionToken;
node.type = type;
node.initializer = initializer;
return node;
}
ts.createProperty = createProperty;
function updateProperty(node, decorators, modifiers, name, type, initializer) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.name !== name || node.type !== type || node.initializer !== initializer) {
return updateNode(createProperty(decorators, modifiers, name, node.questionToken, type, initializer, node), node);
}
return node;
}
ts.updateProperty = updateProperty;
function createMethod(decorators, modifiers, asteriskToken, name, typeParameters, parameters, type, body, location, flags) {
var node = createNode(149 /* MethodDeclaration */, location, flags);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.asteriskToken = asteriskToken;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.typeParameters = typeParameters ? createNodeArray(typeParameters) : undefined;
node.parameters = createNodeArray(parameters);
node.type = type;
node.body = body;
return node;
}
ts.createMethod = createMethod;
function updateMethod(node, decorators, modifiers, name, typeParameters, parameters, type, body) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.name !== name || node.typeParameters !== typeParameters || node.parameters !== parameters || node.type !== type || node.body !== body) {
return updateNode(createMethod(decorators, modifiers, node.asteriskToken, name, typeParameters, parameters, type, body, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateMethod = updateMethod;
function createConstructor(decorators, modifiers, parameters, body, location, flags) {
var node = createNode(150 /* Constructor */, location, flags);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.typeParameters = undefined;
node.parameters = createNodeArray(parameters);
node.type = undefined;
node.body = body;
return node;
}
ts.createConstructor = createConstructor;
function updateConstructor(node, decorators, modifiers, parameters, body) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.parameters !== parameters || node.body !== body) {
return updateNode(createConstructor(decorators, modifiers, parameters, body, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateConstructor = updateConstructor;
function createGetAccessor(decorators, modifiers, name, parameters, type, body, location, flags) {
var node = createNode(151 /* GetAccessor */, location, flags);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.typeParameters = undefined;
node.parameters = createNodeArray(parameters);
node.type = type;
node.body = body;
return node;
}
ts.createGetAccessor = createGetAccessor;
function updateGetAccessor(node, decorators, modifiers, name, parameters, type, body) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.name !== name || node.parameters !== parameters || node.type !== type || node.body !== body) {
return updateNode(createGetAccessor(decorators, modifiers, name, parameters, type, body, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateGetAccessor = updateGetAccessor;
function createSetAccessor(decorators, modifiers, name, parameters, body, location, flags) {
var node = createNode(152 /* SetAccessor */, location, flags);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.typeParameters = undefined;
node.parameters = createNodeArray(parameters);
node.body = body;
return node;
}
ts.createSetAccessor = createSetAccessor;
function updateSetAccessor(node, decorators, modifiers, name, parameters, body) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.name !== name || node.parameters !== parameters || node.body !== body) {
return updateNode(createSetAccessor(decorators, modifiers, name, parameters, body, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateSetAccessor = updateSetAccessor;
// Binding Patterns
function createObjectBindingPattern(elements, location) {
var node = createNode(172 /* ObjectBindingPattern */, location);
node.elements = createNodeArray(elements);
return node;
}
ts.createObjectBindingPattern = createObjectBindingPattern;
function updateObjectBindingPattern(node, elements) {
if (node.elements !== elements) {
return updateNode(createObjectBindingPattern(elements, node), node);
}
return node;
}
ts.updateObjectBindingPattern = updateObjectBindingPattern;
function createArrayBindingPattern(elements, location) {
var node = createNode(173 /* ArrayBindingPattern */, location);
node.elements = createNodeArray(elements);
return node;
}
ts.createArrayBindingPattern = createArrayBindingPattern;
function updateArrayBindingPattern(node, elements) {
if (node.elements !== elements) {
return updateNode(createArrayBindingPattern(elements, node), node);
}
return node;
}
ts.updateArrayBindingPattern = updateArrayBindingPattern;
function createBindingElement(propertyName, dotDotDotToken, name, initializer, location) {
var node = createNode(174 /* BindingElement */, location);
node.propertyName = typeof propertyName === "string" ? createIdentifier(propertyName) : propertyName;
node.dotDotDotToken = dotDotDotToken;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.initializer = initializer;
return node;
}
ts.createBindingElement = createBindingElement;
function updateBindingElement(node, propertyName, name, initializer) {
if (node.propertyName !== propertyName || node.name !== name || node.initializer !== initializer) {
return updateNode(createBindingElement(propertyName, node.dotDotDotToken, name, initializer, node), node);
}
return node;
}
ts.updateBindingElement = updateBindingElement;
// Expression
function createArrayLiteral(elements, location, multiLine) {
var node = createNode(175 /* ArrayLiteralExpression */, location);
node.elements = parenthesizeListElements(createNodeArray(elements));
if (multiLine) {
node.multiLine = true;
}
return node;
}
ts.createArrayLiteral = createArrayLiteral;
function updateArrayLiteral(node, elements) {
if (node.elements !== elements) {
return updateNode(createArrayLiteral(elements, node, node.multiLine), node);
}
return node;
}
ts.updateArrayLiteral = updateArrayLiteral;
function createObjectLiteral(properties, location, multiLine) {
var node = createNode(176 /* ObjectLiteralExpression */, location);
node.properties = createNodeArray(properties);
if (multiLine) {
node.multiLine = true;
}
return node;
}
ts.createObjectLiteral = createObjectLiteral;
function updateObjectLiteral(node, properties) {
if (node.properties !== properties) {
return updateNode(createObjectLiteral(properties, node, node.multiLine), node);
}
return node;
}
ts.updateObjectLiteral = updateObjectLiteral;
function createPropertyAccess(expression, name, location, flags) {
var node = createNode(177 /* PropertyAccessExpression */, location, flags);
node.expression = parenthesizeForAccess(expression);
(node.emitNode || (node.emitNode = {})).flags |= 1048576 /* NoIndentation */;
node.name = typeof name === "string" ? createIdentifier(name) : name;
return node;
}
ts.createPropertyAccess = createPropertyAccess;
function updatePropertyAccess(node, expression, name) {
if (node.expression !== expression || node.name !== name) {
var propertyAccess = createPropertyAccess(expression, name, /*location*/ node, node.flags);
// Because we are updating existed propertyAccess we want to inherit its emitFlags instead of using default from createPropertyAccess
(propertyAccess.emitNode || (propertyAccess.emitNode = {})).flags = getEmitFlags(node);
return updateNode(propertyAccess, node);
}
return node;
}
ts.updatePropertyAccess = updatePropertyAccess;
function createElementAccess(expression, index, location) {
var node = createNode(178 /* ElementAccessExpression */, location);
node.expression = parenthesizeForAccess(expression);
node.argumentExpression = typeof index === "number" ? createLiteral(index) : index;
return node;
}
ts.createElementAccess = createElementAccess;
function updateElementAccess(node, expression, argumentExpression) {
if (node.expression !== expression || node.argumentExpression !== argumentExpression) {
return updateNode(createElementAccess(expression, argumentExpression, node), node);
}
return node;
}
ts.updateElementAccess = updateElementAccess;
function createCall(expression, typeArguments, argumentsArray, location, flags) {
var node = createNode(179 /* CallExpression */, location, flags);
node.expression = parenthesizeForAccess(expression);
if (typeArguments) {
node.typeArguments = createNodeArray(typeArguments);
}
node.arguments = parenthesizeListElements(createNodeArray(argumentsArray));
return node;
}
ts.createCall = createCall;
function updateCall(node, expression, typeArguments, argumentsArray) {
if (expression !== node.expression || typeArguments !== node.typeArguments || argumentsArray !== node.arguments) {
return updateNode(createCall(expression, typeArguments, argumentsArray, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateCall = updateCall;
function createNew(expression, typeArguments, argumentsArray, location, flags) {
var node = createNode(180 /* NewExpression */, location, flags);
node.expression = parenthesizeForNew(expression);
node.typeArguments = typeArguments ? createNodeArray(typeArguments) : undefined;
node.arguments = argumentsArray ? parenthesizeListElements(createNodeArray(argumentsArray)) : undefined;
return node;
}
ts.createNew = createNew;
function updateNew(node, expression, typeArguments, argumentsArray) {
if (node.expression !== expression || node.typeArguments !== typeArguments || node.arguments !== argumentsArray) {
return updateNode(createNew(expression, typeArguments, argumentsArray, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateNew = updateNew;
function createTaggedTemplate(tag, template, location) {
var node = createNode(181 /* TaggedTemplateExpression */, location);
node.tag = parenthesizeForAccess(tag);
node.template = template;
return node;
}
ts.createTaggedTemplate = createTaggedTemplate;
function updateTaggedTemplate(node, tag, template) {
if (node.tag !== tag || node.template !== template) {
return updateNode(createTaggedTemplate(tag, template, node), node);
}
return node;
}
ts.updateTaggedTemplate = updateTaggedTemplate;
function createParen(expression, location) {
var node = createNode(183 /* ParenthesizedExpression */, location);
node.expression = expression;
return node;
}
ts.createParen = createParen;
function updateParen(node, expression) {
if (node.expression !== expression) {
return updateNode(createParen(expression, node), node);
}
return node;
}
ts.updateParen = updateParen;
function createFunctionExpression(modifiers, asteriskToken, name, typeParameters, parameters, type, body, location, flags) {
var node = createNode(184 /* FunctionExpression */, location, flags);
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.asteriskToken = asteriskToken;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.typeParameters = typeParameters ? createNodeArray(typeParameters) : undefined;
node.parameters = createNodeArray(parameters);
node.type = type;
node.body = body;
return node;
}
ts.createFunctionExpression = createFunctionExpression;
function updateFunctionExpression(node, modifiers, name, typeParameters, parameters, type, body) {
if (node.name !== name || node.modifiers !== modifiers || node.typeParameters !== typeParameters || node.parameters !== parameters || node.type !== type || node.body !== body) {
return updateNode(createFunctionExpression(modifiers, node.asteriskToken, name, typeParameters, parameters, type, body, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateFunctionExpression = updateFunctionExpression;
function createArrowFunction(modifiers, typeParameters, parameters, type, equalsGreaterThanToken, body, location, flags) {
var node = createNode(185 /* ArrowFunction */, location, flags);
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.typeParameters = typeParameters ? createNodeArray(typeParameters) : undefined;
node.parameters = createNodeArray(parameters);
node.type = type;
node.equalsGreaterThanToken = equalsGreaterThanToken || createToken(35 /* EqualsGreaterThanToken */);
node.body = parenthesizeConciseBody(body);
return node;
}
ts.createArrowFunction = createArrowFunction;
function updateArrowFunction(node, modifiers, typeParameters, parameters, type, body) {
if (node.modifiers !== modifiers || node.typeParameters !== typeParameters || node.parameters !== parameters || node.type !== type || node.body !== body) {
return updateNode(createArrowFunction(modifiers, typeParameters, parameters, type, node.equalsGreaterThanToken, body, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateArrowFunction = updateArrowFunction;
function createDelete(expression, location) {
var node = createNode(186 /* DeleteExpression */, location);
node.expression = parenthesizePrefixOperand(expression);
return node;
}
ts.createDelete = createDelete;
function updateDelete(node, expression) {
if (node.expression !== expression) {
return updateNode(createDelete(expression, node), expression);
}
return node;
}
ts.updateDelete = updateDelete;
function createTypeOf(expression, location) {
var node = createNode(187 /* TypeOfExpression */, location);
node.expression = parenthesizePrefixOperand(expression);
return node;
}
ts.createTypeOf = createTypeOf;
function updateTypeOf(node, expression) {
if (node.expression !== expression) {
return updateNode(createTypeOf(expression, node), expression);
}
return node;
}
ts.updateTypeOf = updateTypeOf;
function createVoid(expression, location) {
var node = createNode(188 /* VoidExpression */, location);
node.expression = parenthesizePrefixOperand(expression);
return node;
}
ts.createVoid = createVoid;
function updateVoid(node, expression) {
if (node.expression !== expression) {
return updateNode(createVoid(expression, node), node);
}
return node;
}
ts.updateVoid = updateVoid;
function createAwait(expression, location) {
var node = createNode(189 /* AwaitExpression */, location);
node.expression = parenthesizePrefixOperand(expression);
return node;
}
ts.createAwait = createAwait;
function updateAwait(node, expression) {
if (node.expression !== expression) {
return updateNode(createAwait(expression, node), node);
}
return node;
}
ts.updateAwait = updateAwait;
function createPrefix(operator, operand, location) {
var node = createNode(190 /* PrefixUnaryExpression */, location);
node.operator = operator;
node.operand = parenthesizePrefixOperand(operand);
return node;
}
ts.createPrefix = createPrefix;
function updatePrefix(node, operand) {
if (node.operand !== operand) {
return updateNode(createPrefix(node.operator, operand, node), node);
}
return node;
}
ts.updatePrefix = updatePrefix;
function createPostfix(operand, operator, location) {
var node = createNode(191 /* PostfixUnaryExpression */, location);
node.operand = parenthesizePostfixOperand(operand);
node.operator = operator;
return node;
}
ts.createPostfix = createPostfix;
function updatePostfix(node, operand) {
if (node.operand !== operand) {
return updateNode(createPostfix(operand, node.operator, node), node);
}
return node;
}
ts.updatePostfix = updatePostfix;
function createBinary(left, operator, right, location) {
var operatorToken = typeof operator === "number" ? createToken(operator) : operator;
var operatorKind = operatorToken.kind;
var node = createNode(192 /* BinaryExpression */, location);
node.left = parenthesizeBinaryOperand(operatorKind, left, /*isLeftSideOfBinary*/ true, /*leftOperand*/ undefined);
node.operatorToken = operatorToken;
node.right = parenthesizeBinaryOperand(operatorKind, right, /*isLeftSideOfBinary*/ false, node.left);
return node;
}
ts.createBinary = createBinary;
function updateBinary(node, left, right) {
if (node.left !== left || node.right !== right) {
return updateNode(createBinary(left, node.operatorToken, right, /*location*/ node), node);
}
return node;
}
ts.updateBinary = updateBinary;
function createConditional(condition, questionToken, whenTrue, colonToken, whenFalse, location) {
var node = createNode(193 /* ConditionalExpression */, location);
node.condition = condition;
node.questionToken = questionToken;
node.whenTrue = whenTrue;
node.colonToken = colonToken;
node.whenFalse = whenFalse;
return node;
}
ts.createConditional = createConditional;
function updateConditional(node, condition, whenTrue, whenFalse) {
if (node.condition !== condition || node.whenTrue !== whenTrue || node.whenFalse !== whenFalse) {
return updateNode(createConditional(condition, node.questionToken, whenTrue, node.colonToken, whenFalse, node), node);
}
return node;
}
ts.updateConditional = updateConditional;
function createTemplateExpression(head, templateSpans, location) {
var node = createNode(194 /* TemplateExpression */, location);
node.head = head;
node.templateSpans = createNodeArray(templateSpans);
return node;
}
ts.createTemplateExpression = createTemplateExpression;
function updateTemplateExpression(node, head, templateSpans) {
if (node.head !== head || node.templateSpans !== templateSpans) {
return updateNode(createTemplateExpression(head, templateSpans, node), node);
}
return node;
}
ts.updateTemplateExpression = updateTemplateExpression;
function createYield(asteriskToken, expression, location) {
var node = createNode(195 /* YieldExpression */, location);
node.asteriskToken = asteriskToken;
node.expression = expression;
return node;
}
ts.createYield = createYield;
function updateYield(node, expression) {
if (node.expression !== expression) {
return updateNode(createYield(node.asteriskToken, expression, node), node);
}
return node;
}
ts.updateYield = updateYield;
function createSpread(expression, location) {
var node = createNode(196 /* SpreadElement */, location);
node.expression = parenthesizeExpressionForList(expression);
return node;
}
ts.createSpread = createSpread;
function updateSpread(node, expression) {
if (node.expression !== expression) {
return updateNode(createSpread(expression, node), node);
}
return node;
}
ts.updateSpread = updateSpread;
function createClassExpression(modifiers, name, typeParameters, heritageClauses, members, location) {
var node = createNode(197 /* ClassExpression */, location);
node.decorators = undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.name = name;
node.typeParameters = typeParameters ? createNodeArray(typeParameters) : undefined;
node.heritageClauses = createNodeArray(heritageClauses);
node.members = createNodeArray(members);
return node;
}
ts.createClassExpression = createClassExpression;
function updateClassExpression(node, modifiers, name, typeParameters, heritageClauses, members) {
if (node.modifiers !== modifiers || node.name !== name || node.typeParameters !== typeParameters || node.heritageClauses !== heritageClauses || node.members !== members) {
return updateNode(createClassExpression(modifiers, name, typeParameters, heritageClauses, members, node), node);
}
return node;
}
ts.updateClassExpression = updateClassExpression;
function createOmittedExpression(location) {
var node = createNode(198 /* OmittedExpression */, location);
return node;
}
ts.createOmittedExpression = createOmittedExpression;
function createExpressionWithTypeArguments(typeArguments, expression, location) {
var node = createNode(199 /* ExpressionWithTypeArguments */, location);
node.typeArguments = typeArguments ? createNodeArray(typeArguments) : undefined;
node.expression = parenthesizeForAccess(expression);
return node;
}
ts.createExpressionWithTypeArguments = createExpressionWithTypeArguments;
function updateExpressionWithTypeArguments(node, typeArguments, expression) {
if (node.typeArguments !== typeArguments || node.expression !== expression) {
return updateNode(createExpressionWithTypeArguments(typeArguments, expression, node), node);
}
return node;
}
ts.updateExpressionWithTypeArguments = updateExpressionWithTypeArguments;
// Misc
function createTemplateSpan(expression, literal, location) {
var node = createNode(202 /* TemplateSpan */, location);
node.expression = expression;
node.literal = literal;
return node;
}
ts.createTemplateSpan = createTemplateSpan;
function updateTemplateSpan(node, expression, literal) {
if (node.expression !== expression || node.literal !== literal) {
return updateNode(createTemplateSpan(expression, literal, node), node);
}
return node;
}
ts.updateTemplateSpan = updateTemplateSpan;
// Element
function createBlock(statements, location, multiLine, flags) {
var block = createNode(204 /* Block */, location, flags);
block.statements = createNodeArray(statements);
if (multiLine) {
block.multiLine = true;
}
return block;
}
ts.createBlock = createBlock;
function updateBlock(node, statements) {
if (statements !== node.statements) {
return updateNode(createBlock(statements, /*location*/ node, node.multiLine, node.flags), node);
}
return node;
}
ts.updateBlock = updateBlock;
function createVariableStatement(modifiers, declarationList, location, flags) {
var node = createNode(205 /* VariableStatement */, location, flags);
node.decorators = undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.declarationList = ts.isArray(declarationList) ? createVariableDeclarationList(declarationList) : declarationList;
return node;
}
ts.createVariableStatement = createVariableStatement;
function updateVariableStatement(node, modifiers, declarationList) {
if (node.modifiers !== modifiers || node.declarationList !== declarationList) {
return updateNode(createVariableStatement(modifiers, declarationList, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateVariableStatement = updateVariableStatement;
function createVariableDeclarationList(declarations, location, flags) {
var node = createNode(224 /* VariableDeclarationList */, location, flags);
node.declarations = createNodeArray(declarations);
return node;
}
ts.createVariableDeclarationList = createVariableDeclarationList;
function updateVariableDeclarationList(node, declarations) {
if (node.declarations !== declarations) {
return updateNode(createVariableDeclarationList(declarations, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateVariableDeclarationList = updateVariableDeclarationList;
function createVariableDeclaration(name, type, initializer, location, flags) {
var node = createNode(223 /* VariableDeclaration */, location, flags);
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.type = type;
node.initializer = initializer !== undefined ? parenthesizeExpressionForList(initializer) : undefined;
return node;
}
ts.createVariableDeclaration = createVariableDeclaration;
function updateVariableDeclaration(node, name, type, initializer) {
if (node.name !== name || node.type !== type || node.initializer !== initializer) {
return updateNode(createVariableDeclaration(name, type, initializer, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateVariableDeclaration = updateVariableDeclaration;
function createEmptyStatement(location) {
return createNode(206 /* EmptyStatement */, location);
}
ts.createEmptyStatement = createEmptyStatement;
function createStatement(expression, location, flags) {
var node = createNode(207 /* ExpressionStatement */, location, flags);
node.expression = parenthesizeExpressionForExpressionStatement(expression);
return node;
}
ts.createStatement = createStatement;
function updateStatement(node, expression) {
if (node.expression !== expression) {
return updateNode(createStatement(expression, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateStatement = updateStatement;
function createIf(expression, thenStatement, elseStatement, location) {
var node = createNode(208 /* IfStatement */, location);
node.expression = expression;
node.thenStatement = thenStatement;
node.elseStatement = elseStatement;
return node;
}
ts.createIf = createIf;
function updateIf(node, expression, thenStatement, elseStatement) {
if (node.expression !== expression || node.thenStatement !== thenStatement || node.elseStatement !== elseStatement) {
return updateNode(createIf(expression, thenStatement, elseStatement, /*location*/ node), node);
}
return node;
}
ts.updateIf = updateIf;
function createDo(statement, expression, location) {
var node = createNode(209 /* DoStatement */, location);
node.statement = statement;
node.expression = expression;
return node;
}
ts.createDo = createDo;
function updateDo(node, statement, expression) {
if (node.statement !== statement || node.expression !== expression) {
return updateNode(createDo(statement, expression, node), node);
}
return node;
}
ts.updateDo = updateDo;
function createWhile(expression, statement, location) {
var node = createNode(210 /* WhileStatement */, location);
node.expression = expression;
node.statement = statement;
return node;
}
ts.createWhile = createWhile;
function updateWhile(node, expression, statement) {
if (node.expression !== expression || node.statement !== statement) {
return updateNode(createWhile(expression, statement, node), node);
}
return node;
}
ts.updateWhile = updateWhile;
function createFor(initializer, condition, incrementor, statement, location) {
var node = createNode(211 /* ForStatement */, location, /*flags*/ undefined);
node.initializer = initializer;
node.condition = condition;
node.incrementor = incrementor;
node.statement = statement;
return node;
}
ts.createFor = createFor;
function updateFor(node, initializer, condition, incrementor, statement) {
if (node.initializer !== initializer || node.condition !== condition || node.incrementor !== incrementor || node.statement !== statement) {
return updateNode(createFor(initializer, condition, incrementor, statement, node), node);
}
return node;
}
ts.updateFor = updateFor;
function createForIn(initializer, expression, statement, location) {
var node = createNode(212 /* ForInStatement */, location);
node.initializer = initializer;
node.expression = expression;
node.statement = statement;
return node;
}
ts.createForIn = createForIn;
function updateForIn(node, initializer, expression, statement) {
if (node.initializer !== initializer || node.expression !== expression || node.statement !== statement) {
return updateNode(createForIn(initializer, expression, statement, node), node);
}
return node;
}
ts.updateForIn = updateForIn;
function createForOf(initializer, expression, statement, location) {
var node = createNode(213 /* ForOfStatement */, location);
node.initializer = initializer;
node.expression = expression;
node.statement = statement;
return node;
}
ts.createForOf = createForOf;
function updateForOf(node, initializer, expression, statement) {
if (node.initializer !== initializer || node.expression !== expression || node.statement !== statement) {
return updateNode(createForOf(initializer, expression, statement, node), node);
}
return node;
}
ts.updateForOf = updateForOf;
function createContinue(label, location) {
var node = createNode(214 /* ContinueStatement */, location);
if (label) {
node.label = label;
}
return node;
}
ts.createContinue = createContinue;
function updateContinue(node, label) {
if (node.label !== label) {
return updateNode(createContinue(label, node), node);
}
return node;
}
ts.updateContinue = updateContinue;
function createBreak(label, location) {
var node = createNode(215 /* BreakStatement */, location);
if (label) {
node.label = label;
}
return node;
}
ts.createBreak = createBreak;
function updateBreak(node, label) {
if (node.label !== label) {
return updateNode(createBreak(label, node), node);
}
return node;
}
ts.updateBreak = updateBreak;
function createReturn(expression, location) {
var node = createNode(216 /* ReturnStatement */, location);
node.expression = expression;
return node;
}
ts.createReturn = createReturn;
function updateReturn(node, expression) {
if (node.expression !== expression) {
return updateNode(createReturn(expression, /*location*/ node), node);
}
return node;
}
ts.updateReturn = updateReturn;
function createWith(expression, statement, location) {
var node = createNode(217 /* WithStatement */, location);
node.expression = expression;
node.statement = statement;
return node;
}
ts.createWith = createWith;
function updateWith(node, expression, statement) {
if (node.expression !== expression || node.statement !== statement) {
return updateNode(createWith(expression, statement, node), node);
}
return node;
}
ts.updateWith = updateWith;
function createSwitch(expression, caseBlock, location) {
var node = createNode(218 /* SwitchStatement */, location);
node.expression = parenthesizeExpressionForList(expression);
node.caseBlock = caseBlock;
return node;
}
ts.createSwitch = createSwitch;
function updateSwitch(node, expression, caseBlock) {
if (node.expression !== expression || node.caseBlock !== caseBlock) {
return updateNode(createSwitch(expression, caseBlock, node), node);
}
return node;
}
ts.updateSwitch = updateSwitch;
function createLabel(label, statement, location) {
var node = createNode(219 /* LabeledStatement */, location);
node.label = typeof label === "string" ? createIdentifier(label) : label;
node.statement = statement;
return node;
}
ts.createLabel = createLabel;
function updateLabel(node, label, statement) {
if (node.label !== label || node.statement !== statement) {
return updateNode(createLabel(label, statement, node), node);
}
return node;
}
ts.updateLabel = updateLabel;
function createThrow(expression, location) {
var node = createNode(220 /* ThrowStatement */, location);
node.expression = expression;
return node;
}
ts.createThrow = createThrow;
function updateThrow(node, expression) {
if (node.expression !== expression) {
return updateNode(createThrow(expression, node), node);
}
return node;
}
ts.updateThrow = updateThrow;
function createTry(tryBlock, catchClause, finallyBlock, location) {
var node = createNode(221 /* TryStatement */, location);
node.tryBlock = tryBlock;
node.catchClause = catchClause;
node.finallyBlock = finallyBlock;
return node;
}
ts.createTry = createTry;
function updateTry(node, tryBlock, catchClause, finallyBlock) {
if (node.tryBlock !== tryBlock || node.catchClause !== catchClause || node.finallyBlock !== finallyBlock) {
return updateNode(createTry(tryBlock, catchClause, finallyBlock, node), node);
}
return node;
}
ts.updateTry = updateTry;
function createCaseBlock(clauses, location) {
var node = createNode(232 /* CaseBlock */, location);
node.clauses = createNodeArray(clauses);
return node;
}
ts.createCaseBlock = createCaseBlock;
function updateCaseBlock(node, clauses) {
if (node.clauses !== clauses) {
return updateNode(createCaseBlock(clauses, node), node);
}
return node;
}
ts.updateCaseBlock = updateCaseBlock;
function createFunctionDeclaration(decorators, modifiers, asteriskToken, name, typeParameters, parameters, type, body, location, flags) {
var node = createNode(225 /* FunctionDeclaration */, location, flags);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.asteriskToken = asteriskToken;
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.typeParameters = typeParameters ? createNodeArray(typeParameters) : undefined;
node.parameters = createNodeArray(parameters);
node.type = type;
node.body = body;
return node;
}
ts.createFunctionDeclaration = createFunctionDeclaration;
function updateFunctionDeclaration(node, decorators, modifiers, name, typeParameters, parameters, type, body) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.name !== name || node.typeParameters !== typeParameters || node.parameters !== parameters || node.type !== type || node.body !== body) {
return updateNode(createFunctionDeclaration(decorators, modifiers, node.asteriskToken, name, typeParameters, parameters, type, body, /*location*/ node, node.flags), node);
}
return node;
}
ts.updateFunctionDeclaration = updateFunctionDeclaration;
function createClassDeclaration(decorators, modifiers, name, typeParameters, heritageClauses, members, location) {
var node = createNode(226 /* ClassDeclaration */, location);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.name = name;
node.typeParameters = typeParameters ? createNodeArray(typeParameters) : undefined;
node.heritageClauses = createNodeArray(heritageClauses);
node.members = createNodeArray(members);
return node;
}
ts.createClassDeclaration = createClassDeclaration;
function updateClassDeclaration(node, decorators, modifiers, name, typeParameters, heritageClauses, members) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.name !== name || node.typeParameters !== typeParameters || node.heritageClauses !== heritageClauses || node.members !== members) {
return updateNode(createClassDeclaration(decorators, modifiers, name, typeParameters, heritageClauses, members, node), node);
}
return node;
}
ts.updateClassDeclaration = updateClassDeclaration;
function createImportDeclaration(decorators, modifiers, importClause, moduleSpecifier, location) {
var node = createNode(235 /* ImportDeclaration */, location);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.importClause = importClause;
node.moduleSpecifier = moduleSpecifier;
return node;
}
ts.createImportDeclaration = createImportDeclaration;
function updateImportDeclaration(node, decorators, modifiers, importClause, moduleSpecifier) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.importClause !== importClause || node.moduleSpecifier !== moduleSpecifier) {
return updateNode(createImportDeclaration(decorators, modifiers, importClause, moduleSpecifier, node), node);
}
return node;
}
ts.updateImportDeclaration = updateImportDeclaration;
function createImportClause(name, namedBindings, location) {
var node = createNode(236 /* ImportClause */, location);
node.name = name;
node.namedBindings = namedBindings;
return node;
}
ts.createImportClause = createImportClause;
function updateImportClause(node, name, namedBindings) {
if (node.name !== name || node.namedBindings !== namedBindings) {
return updateNode(createImportClause(name, namedBindings, node), node);
}
return node;
}
ts.updateImportClause = updateImportClause;
function createNamespaceImport(name, location) {
var node = createNode(237 /* NamespaceImport */, location);
node.name = name;
return node;
}
ts.createNamespaceImport = createNamespaceImport;
function updateNamespaceImport(node, name) {
if (node.name !== name) {
return updateNode(createNamespaceImport(name, node), node);
}
return node;
}
ts.updateNamespaceImport = updateNamespaceImport;
function createNamedImports(elements, location) {
var node = createNode(238 /* NamedImports */, location);
node.elements = createNodeArray(elements);
return node;
}
ts.createNamedImports = createNamedImports;
function updateNamedImports(node, elements) {
if (node.elements !== elements) {
return updateNode(createNamedImports(elements, node), node);
}
return node;
}
ts.updateNamedImports = updateNamedImports;
function createImportSpecifier(propertyName, name, location) {
var node = createNode(239 /* ImportSpecifier */, location);
node.propertyName = propertyName;
node.name = name;
return node;
}
ts.createImportSpecifier = createImportSpecifier;
function updateImportSpecifier(node, propertyName, name) {
if (node.propertyName !== propertyName || node.name !== name) {
return updateNode(createImportSpecifier(propertyName, name, node), node);
}
return node;
}
ts.updateImportSpecifier = updateImportSpecifier;
function createExportAssignment(decorators, modifiers, isExportEquals, expression, location) {
var node = createNode(240 /* ExportAssignment */, location);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.isExportEquals = isExportEquals;
node.expression = expression;
return node;
}
ts.createExportAssignment = createExportAssignment;
function updateExportAssignment(node, decorators, modifiers, expression) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.expression !== expression) {
return updateNode(createExportAssignment(decorators, modifiers, node.isExportEquals, expression, node), node);
}
return node;
}
ts.updateExportAssignment = updateExportAssignment;
function createExportDeclaration(decorators, modifiers, exportClause, moduleSpecifier, location) {
var node = createNode(241 /* ExportDeclaration */, location);
node.decorators = decorators ? createNodeArray(decorators) : undefined;
node.modifiers = modifiers ? createNodeArray(modifiers) : undefined;
node.exportClause = exportClause;
node.moduleSpecifier = moduleSpecifier;
return node;
}
ts.createExportDeclaration = createExportDeclaration;
function updateExportDeclaration(node, decorators, modifiers, exportClause, moduleSpecifier) {
if (node.decorators !== decorators || node.modifiers !== modifiers || node.exportClause !== exportClause || node.moduleSpecifier !== moduleSpecifier) {
return updateNode(createExportDeclaration(decorators, modifiers, exportClause, moduleSpecifier, node), node);
}
return node;
}
ts.updateExportDeclaration = updateExportDeclaration;
function createNamedExports(elements, location) {
var node = createNode(242 /* NamedExports */, location);
node.elements = createNodeArray(elements);
return node;
}
ts.createNamedExports = createNamedExports;
function updateNamedExports(node, elements) {
if (node.elements !== elements) {
return updateNode(createNamedExports(elements, node), node);
}
return node;
}
ts.updateNamedExports = updateNamedExports;
function createExportSpecifier(name, propertyName, location) {
var node = createNode(243 /* ExportSpecifier */, location);
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.propertyName = typeof propertyName === "string" ? createIdentifier(propertyName) : propertyName;
return node;
}
ts.createExportSpecifier = createExportSpecifier;
function updateExportSpecifier(node, name, propertyName) {
if (node.name !== name || node.propertyName !== propertyName) {
return updateNode(createExportSpecifier(name, propertyName, node), node);
}
return node;
}
ts.updateExportSpecifier = updateExportSpecifier;
// JSX
function createJsxElement(openingElement, children, closingElement, location) {
var node = createNode(246 /* JsxElement */, location);
node.openingElement = openingElement;
node.children = createNodeArray(children);
node.closingElement = closingElement;
return node;
}
ts.createJsxElement = createJsxElement;
function updateJsxElement(node, openingElement, children, closingElement) {
if (node.openingElement !== openingElement || node.children !== children || node.closingElement !== closingElement) {
return updateNode(createJsxElement(openingElement, children, closingElement, node), node);
}
return node;
}
ts.updateJsxElement = updateJsxElement;
function createJsxSelfClosingElement(tagName, attributes, location) {
var node = createNode(247 /* JsxSelfClosingElement */, location);
node.tagName = tagName;
node.attributes = createNodeArray(attributes);
return node;
}
ts.createJsxSelfClosingElement = createJsxSelfClosingElement;
function updateJsxSelfClosingElement(node, tagName, attributes) {
if (node.tagName !== tagName || node.attributes !== attributes) {
return updateNode(createJsxSelfClosingElement(tagName, attributes, node), node);
}
return node;
}
ts.updateJsxSelfClosingElement = updateJsxSelfClosingElement;
function createJsxOpeningElement(tagName, attributes, location) {
var node = createNode(248 /* JsxOpeningElement */, location);
node.tagName = tagName;
node.attributes = createNodeArray(attributes);
return node;
}
ts.createJsxOpeningElement = createJsxOpeningElement;
function updateJsxOpeningElement(node, tagName, attributes) {
if (node.tagName !== tagName || node.attributes !== attributes) {
return updateNode(createJsxOpeningElement(tagName, attributes, node), node);
}
return node;
}
ts.updateJsxOpeningElement = updateJsxOpeningElement;
function createJsxClosingElement(tagName, location) {
var node = createNode(249 /* JsxClosingElement */, location);
node.tagName = tagName;
return node;
}
ts.createJsxClosingElement = createJsxClosingElement;
function updateJsxClosingElement(node, tagName) {
if (node.tagName !== tagName) {
return updateNode(createJsxClosingElement(tagName, node), node);
}
return node;
}
ts.updateJsxClosingElement = updateJsxClosingElement;
function createJsxAttribute(name, initializer, location) {
var node = createNode(250 /* JsxAttribute */, location);
node.name = name;
node.initializer = initializer;
return node;
}
ts.createJsxAttribute = createJsxAttribute;
function updateJsxAttribute(node, name, initializer) {
if (node.name !== name || node.initializer !== initializer) {
return updateNode(createJsxAttribute(name, initializer, node), node);
}
return node;
}
ts.updateJsxAttribute = updateJsxAttribute;
function createJsxSpreadAttribute(expression, location) {
var node = createNode(251 /* JsxSpreadAttribute */, location);
node.expression = expression;
return node;
}
ts.createJsxSpreadAttribute = createJsxSpreadAttribute;
function updateJsxSpreadAttribute(node, expression) {
if (node.expression !== expression) {
return updateNode(createJsxSpreadAttribute(expression, node), node);
}
return node;
}
ts.updateJsxSpreadAttribute = updateJsxSpreadAttribute;
function createJsxExpression(expression, location) {
var node = createNode(252 /* JsxExpression */, location);
node.expression = expression;
return node;
}
ts.createJsxExpression = createJsxExpression;
function updateJsxExpression(node, expression) {
if (node.expression !== expression) {
return updateNode(createJsxExpression(expression, node), node);
}
return node;
}
ts.updateJsxExpression = updateJsxExpression;
// Clauses
function createHeritageClause(token, types, location) {
var node = createNode(255 /* HeritageClause */, location);
node.token = token;
node.types = createNodeArray(types);
return node;
}
ts.createHeritageClause = createHeritageClause;
function updateHeritageClause(node, types) {
if (node.types !== types) {
return updateNode(createHeritageClause(node.token, types, node), node);
}
return node;
}
ts.updateHeritageClause = updateHeritageClause;
function createCaseClause(expression, statements, location) {
var node = createNode(253 /* CaseClause */, location);
node.expression = parenthesizeExpressionForList(expression);
node.statements = createNodeArray(statements);
return node;
}
ts.createCaseClause = createCaseClause;
function updateCaseClause(node, expression, statements) {
if (node.expression !== expression || node.statements !== statements) {
return updateNode(createCaseClause(expression, statements, node), node);
}
return node;
}
ts.updateCaseClause = updateCaseClause;
function createDefaultClause(statements, location) {
var node = createNode(254 /* DefaultClause */, location);
node.statements = createNodeArray(statements);
return node;
}
ts.createDefaultClause = createDefaultClause;
function updateDefaultClause(node, statements) {
if (node.statements !== statements) {
return updateNode(createDefaultClause(statements, node), node);
}
return node;
}
ts.updateDefaultClause = updateDefaultClause;
function createCatchClause(variableDeclaration, block, location) {
var node = createNode(256 /* CatchClause */, location);
node.variableDeclaration = typeof variableDeclaration === "string" ? createVariableDeclaration(variableDeclaration) : variableDeclaration;
node.block = block;
return node;
}
ts.createCatchClause = createCatchClause;
function updateCatchClause(node, variableDeclaration, block) {
if (node.variableDeclaration !== variableDeclaration || node.block !== block) {
return updateNode(createCatchClause(variableDeclaration, block, node), node);
}
return node;
}
ts.updateCatchClause = updateCatchClause;
// Property assignments
function createPropertyAssignment(name, initializer, location) {
var node = createNode(257 /* PropertyAssignment */, location);
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.questionToken = undefined;
node.initializer = initializer !== undefined ? parenthesizeExpressionForList(initializer) : undefined;
return node;
}
ts.createPropertyAssignment = createPropertyAssignment;
function updatePropertyAssignment(node, name, initializer) {
if (node.name !== name || node.initializer !== initializer) {
return updateNode(createPropertyAssignment(name, initializer, node), node);
}
return node;
}
ts.updatePropertyAssignment = updatePropertyAssignment;
function createShorthandPropertyAssignment(name, objectAssignmentInitializer, location) {
var node = createNode(258 /* ShorthandPropertyAssignment */, location);
node.name = typeof name === "string" ? createIdentifier(name) : name;
node.objectAssignmentInitializer = objectAssignmentInitializer !== undefined ? parenthesizeExpressionForList(objectAssignmentInitializer) : undefined;
return node;
}
ts.createShorthandPropertyAssignment = createShorthandPropertyAssignment;
function createSpreadAssignment(expression, location) {
var node = createNode(259 /* SpreadAssignment */, location);
node.expression = expression !== undefined ? parenthesizeExpressionForList(expression) : undefined;
return node;
}
ts.createSpreadAssignment = createSpreadAssignment;
function updateShorthandPropertyAssignment(node, name, objectAssignmentInitializer) {
if (node.name !== name || node.objectAssignmentInitializer !== objectAssignmentInitializer) {
return updateNode(createShorthandPropertyAssignment(name, objectAssignmentInitializer, node), node);
}
return node;
}
ts.updateShorthandPropertyAssignment = updateShorthandPropertyAssignment;
function updateSpreadAssignment(node, expression) {
if (node.expression !== expression) {
return updateNode(createSpreadAssignment(expression, node), node);
}
return node;
}
ts.updateSpreadAssignment = updateSpreadAssignment;
// Top-level nodes
function updateSourceFileNode(node, statements) {
if (node.statements !== statements) {
var updated = createNode(261 /* SourceFile */, /*location*/ node, node.flags);
updated.statements = createNodeArray(statements);
updated.endOfFileToken = node.endOfFileToken;
updated.fileName = node.fileName;
updated.path = node.path;
updated.text = node.text;
if (node.amdDependencies !== undefined)
updated.amdDependencies = node.amdDependencies;
if (node.moduleName !== undefined)
updated.moduleName = node.moduleName;
if (node.referencedFiles !== undefined)
updated.referencedFiles = node.referencedFiles;
if (node.typeReferenceDirectives !== undefined)
updated.typeReferenceDirectives = node.typeReferenceDirectives;
if (node.languageVariant !== undefined)
updated.languageVariant = node.languageVariant;
if (node.isDeclarationFile !== undefined)
updated.isDeclarationFile = node.isDeclarationFile;
if (node.renamedDependencies !== undefined)
updated.renamedDependencies = node.renamedDependencies;
if (node.hasNoDefaultLib !== undefined)
updated.hasNoDefaultLib = node.hasNoDefaultLib;
if (node.languageVersion !== undefined)
updated.languageVersion = node.languageVersion;
if (node.scriptKind !== undefined)
updated.scriptKind = node.scriptKind;
if (node.externalModuleIndicator !== undefined)
updated.externalModuleIndicator = node.externalModuleIndicator;
if (node.commonJsModuleIndicator !== undefined)
updated.commonJsModuleIndicator = node.commonJsModuleIndicator;
if (node.identifiers !== undefined)
updated.identifiers = node.identifiers;
if (node.nodeCount !== undefined)
updated.nodeCount = node.nodeCount;
if (node.identifierCount !== undefined)
updated.identifierCount = node.identifierCount;
if (node.symbolCount !== undefined)
updated.symbolCount = node.symbolCount;
if (node.parseDiagnostics !== undefined)
updated.parseDiagnostics = node.parseDiagnostics;
if (node.bindDiagnostics !== undefined)
updated.bindDiagnostics = node.bindDiagnostics;
if (node.lineMap !== undefined)
updated.lineMap = node.lineMap;
if (node.classifiableNames !== undefined)
updated.classifiableNames = node.classifiableNames;
if (node.resolvedModules !== undefined)
updated.resolvedModules = node.resolvedModules;
if (node.resolvedTypeReferenceDirectiveNames !== undefined)
updated.resolvedTypeReferenceDirectiveNames = node.resolvedTypeReferenceDirectiveNames;
if (node.imports !== undefined)
updated.imports = node.imports;
if (node.moduleAugmentations !== undefined)
updated.moduleAugmentations = node.moduleAugmentations;
if (node.externalHelpersModuleName !== undefined)
updated.externalHelpersModuleName = node.externalHelpersModuleName;
return updateNode(updated, node);
}
return node;
}
ts.updateSourceFileNode = updateSourceFileNode;
// Transformation nodes
/**
* Creates a synthetic statement to act as a placeholder for a not-emitted statement in
* order to preserve comments.
*
* @param original The original statement.
*/
function createNotEmittedStatement(original) {
var node = createNode(292 /* NotEmittedStatement */, /*location*/ original);
node.original = original;
return node;
}
ts.createNotEmittedStatement = createNotEmittedStatement;
/**
* Creates a synthetic element to act as a placeholder for the end of an emitted declaration in
* order to properly emit exports.
*/
function createEndOfDeclarationMarker(original) {
var node = createNode(295 /* EndOfDeclarationMarker */);
node.emitNode = {};
node.original = original;
return node;
}
ts.createEndOfDeclarationMarker = createEndOfDeclarationMarker;
/**
* Creates a synthetic element to act as a placeholder for the beginning of a merged declaration in
* order to properly emit exports.
*/
function createMergeDeclarationMarker(original) {
var node = createNode(294 /* MergeDeclarationMarker */);
node.emitNode = {};
node.original = original;
return node;
}
ts.createMergeDeclarationMarker = createMergeDeclarationMarker;
/**
* Creates a synthetic expression to act as a placeholder for a not-emitted expression in
* order to preserve comments or sourcemap positions.
*
* @param expression The inner expression to emit.
* @param original The original outer expression.
* @param location The location for the expression. Defaults to the positions from "original" if provided.
*/
function createPartiallyEmittedExpression(expression, original, location) {
var node = createNode(293 /* PartiallyEmittedExpression */, /*location*/ location || original);
node.expression = expression;
node.original = original;
return node;
}
ts.createPartiallyEmittedExpression = createPartiallyEmittedExpression;
function updatePartiallyEmittedExpression(node, expression) {
if (node.expression !== expression) {
return updateNode(createPartiallyEmittedExpression(expression, node.original, node), node);
}
return node;
}
ts.updatePartiallyEmittedExpression = updatePartiallyEmittedExpression;
// Compound nodes
function createComma(left, right) {
return createBinary(left, 25 /* CommaToken */, right);
}
ts.createComma = createComma;
function createLessThan(left, right, location) {
return createBinary(left, 26 /* LessThanToken */, right, location);
}
ts.createLessThan = createLessThan;
function createAssignment(left, right, location) {
return createBinary(left, 57 /* EqualsToken */, right, location);
}
ts.createAssignment = createAssignment;
function createStrictEquality(left, right) {
return createBinary(left, 33 /* EqualsEqualsEqualsToken */, right);
}
ts.createStrictEquality = createStrictEquality;
function createStrictInequality(left, right) {
return createBinary(left, 34 /* ExclamationEqualsEqualsToken */, right);
}
ts.createStrictInequality = createStrictInequality;
function createAdd(left, right) {
return createBinary(left, 36 /* PlusToken */, right);
}
ts.createAdd = createAdd;
function createSubtract(left, right) {
return createBinary(left, 37 /* MinusToken */, right);
}
ts.createSubtract = createSubtract;
function createPostfixIncrement(operand, location) {
return createPostfix(operand, 42 /* PlusPlusToken */, location);
}
ts.createPostfixIncrement = createPostfixIncrement;
function createLogicalAnd(left, right) {
return createBinary(left, 52 /* AmpersandAmpersandToken */, right);
}
ts.createLogicalAnd = createLogicalAnd;
function createLogicalOr(left, right) {
return createBinary(left, 53 /* BarBarToken */, right);
}
ts.createLogicalOr = createLogicalOr;
function createLogicalNot(operand) {
return createPrefix(50 /* ExclamationToken */, operand);
}
ts.createLogicalNot = createLogicalNot;
function createVoidZero() {
return createVoid(createLiteral(0));
}
ts.createVoidZero = createVoidZero;
function createMemberAccessForPropertyName(target, memberName, location) {
if (ts.isComputedPropertyName(memberName)) {
return createElementAccess(target, memberName.expression, location);
}
else {
var expression = ts.isIdentifier(memberName) ? createPropertyAccess(target, memberName, location) : createElementAccess(target, memberName, location);
(expression.emitNode || (expression.emitNode = {})).flags |= 2048 /* NoNestedSourceMaps */;
return expression;
}
}
ts.createMemberAccessForPropertyName = createMemberAccessForPropertyName;
function createFunctionCall(func, thisArg, argumentsList, location) {
return createCall(createPropertyAccess(func, "call"),
/*typeArguments*/ undefined, [
thisArg
].concat(argumentsList), location);
}
ts.createFunctionCall = createFunctionCall;
function createFunctionApply(func, thisArg, argumentsExpression, location) {
return createCall(createPropertyAccess(func, "apply"),
/*typeArguments*/ undefined, [
thisArg,
argumentsExpression
], location);
}
ts.createFunctionApply = createFunctionApply;
function createArraySlice(array, start) {
var argumentsList = [];
if (start !== undefined) {
argumentsList.push(typeof start === "number" ? createLiteral(start) : start);
}
return createCall(createPropertyAccess(array, "slice"), /*typeArguments*/ undefined, argumentsList);
}
ts.createArraySlice = createArraySlice;
function createArrayConcat(array, values) {
return createCall(createPropertyAccess(array, "concat"),
/*typeArguments*/ undefined, values);
}
ts.createArrayConcat = createArrayConcat;
function createMathPow(left, right, location) {
return createCall(createPropertyAccess(createIdentifier("Math"), "pow"),
/*typeArguments*/ undefined, [left, right], location);
}
ts.createMathPow = createMathPow;
function createReactNamespace(reactNamespace, parent) {
// To ensure the emit resolver can properly resolve the namespace, we need to
// treat this identifier as if it were a source tree node by clearing the `Synthesized`
// flag and setting a parent node.
var react = createIdentifier(reactNamespace || "React");
react.flags &= ~8 /* Synthesized */;
// Set the parent that is in parse tree
// this makes sure that parent chain is intact for checker to traverse complete scope tree
react.parent = ts.getParseTreeNode(parent);
return react;
}
function createJsxFactoryExpressionFromEntityName(jsxFactory, parent) {
if (ts.isQualifiedName(jsxFactory)) {
return createPropertyAccess(createJsxFactoryExpressionFromEntityName(jsxFactory.left, parent), setEmitFlags(getMutableClone(jsxFactory.right), 1536 /* NoSourceMap */));
}
else {
return createReactNamespace(jsxFactory.text, parent);
}
}
function createJsxFactoryExpression(jsxFactoryEntity, reactNamespace, parent) {
return jsxFactoryEntity ?
createJsxFactoryExpressionFromEntityName(jsxFactoryEntity, parent) :
createPropertyAccess(createReactNamespace(reactNamespace, parent), "createElement");
}
function createExpressionForJsxElement(jsxFactoryEntity, reactNamespace, tagName, props, children, parentElement, location) {
var argumentsList = [tagName];
if (props) {
argumentsList.push(props);
}
if (children && children.length > 0) {
if (!props) {
argumentsList.push(createNull());
}
if (children.length > 1) {
for (var _i = 0, children_1 = children; _i < children_1.length; _i++) {
var child = children_1[_i];
child.startsOnNewLine = true;
argumentsList.push(child);
}
}
else {
argumentsList.push(children[0]);
}
}
return createCall(createJsxFactoryExpression(jsxFactoryEntity, reactNamespace, parentElement),
/*typeArguments*/ undefined, argumentsList, location);
}
ts.createExpressionForJsxElement = createExpressionForJsxElement;
function createExportDefault(expression) {
return createExportAssignment(/*decorators*/ undefined, /*modifiers*/ undefined, /*isExportEquals*/ false, expression);
}
ts.createExportDefault = createExportDefault;
function createExternalModuleExport(exportName) {
return createExportDeclaration(/*decorators*/ undefined, /*modifiers*/ undefined, createNamedExports([createExportSpecifier(exportName)]));
}
ts.createExternalModuleExport = createExternalModuleExport;
function createLetStatement(name, initializer, location) {
return createVariableStatement(/*modifiers*/ undefined, createLetDeclarationList([createVariableDeclaration(name, /*type*/ undefined, initializer)]), location);
}
ts.createLetStatement = createLetStatement;
function createLetDeclarationList(declarations, location) {
return createVariableDeclarationList(declarations, location, 1 /* Let */);
}
ts.createLetDeclarationList = createLetDeclarationList;
function createConstDeclarationList(declarations, location) {
return createVariableDeclarationList(declarations, location, 2 /* Const */);
}
ts.createConstDeclarationList = createConstDeclarationList;
// Helpers
function createHelperName(externalHelpersModuleName, name) {
return externalHelpersModuleName
? createPropertyAccess(externalHelpersModuleName, name)
: createIdentifier(name);
}
ts.createHelperName = createHelperName;
function createExtendsHelper(externalHelpersModuleName, name) {
return createCall(createHelperName(externalHelpersModuleName, "__extends"),
/*typeArguments*/ undefined, [
name,
createIdentifier("_super")
]);
}
ts.createExtendsHelper = createExtendsHelper;
function createAssignHelper(externalHelpersModuleName, attributesSegments) {
return createCall(createHelperName(externalHelpersModuleName, "__assign"),
/*typeArguments*/ undefined, attributesSegments);
}
ts.createAssignHelper = createAssignHelper;
function createParamHelper(externalHelpersModuleName, expression, parameterOffset, location) {
return createCall(createHelperName(externalHelpersModuleName, "__param"),
/*typeArguments*/ undefined, [
createLiteral(parameterOffset),
expression
], location);
}
ts.createParamHelper = createParamHelper;
function createMetadataHelper(externalHelpersModuleName, metadataKey, metadataValue) {
return createCall(createHelperName(externalHelpersModuleName, "__metadata"),
/*typeArguments*/ undefined, [
createLiteral(metadataKey),
metadataValue
]);
}
ts.createMetadataHelper = createMetadataHelper;
function createDecorateHelper(externalHelpersModuleName, decoratorExpressions, target, memberName, descriptor, location) {
var argumentsArray = [];
argumentsArray.push(createArrayLiteral(decoratorExpressions, /*location*/ undefined, /*multiLine*/ true));
argumentsArray.push(target);
if (memberName) {
argumentsArray.push(memberName);
if (descriptor) {
argumentsArray.push(descriptor);
}
}
return createCall(createHelperName(externalHelpersModuleName, "__decorate"), /*typeArguments*/ undefined, argumentsArray, location);
}
ts.createDecorateHelper = createDecorateHelper;
function createAwaiterHelper(externalHelpersModuleName, hasLexicalArguments, promiseConstructor, body) {
var generatorFunc = createFunctionExpression(
/*modifiers*/ undefined, createToken(38 /* AsteriskToken */),
/*name*/ undefined,
/*typeParameters*/ undefined,
/*parameters*/ [],
/*type*/ undefined, body);
// Mark this node as originally an async function
(generatorFunc.emitNode || (generatorFunc.emitNode = {})).flags |= 2097152 /* AsyncFunctionBody */;
return createCall(createHelperName(externalHelpersModuleName, "__awaiter"),
/*typeArguments*/ undefined, [
createThis(),
hasLexicalArguments ? createIdentifier("arguments") : createVoidZero(),
promiseConstructor ? createExpressionFromEntityName(promiseConstructor) : createVoidZero(),
generatorFunc
]);
}
ts.createAwaiterHelper = createAwaiterHelper;
function createHasOwnProperty(target, propertyName) {
return createCall(createPropertyAccess(target, "hasOwnProperty"),
/*typeArguments*/ undefined, [propertyName]);
}
ts.createHasOwnProperty = createHasOwnProperty;
function createObjectCreate(prototype) {
return createCall(createPropertyAccess(createIdentifier("Object"), "create"),
/*typeArguments*/ undefined, [prototype]);
}
function createGeti(target) {
// name => super[name]
return createArrowFunction(
/*modifiers*/ undefined,
/*typeParameters*/ undefined, [createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "name")],
/*type*/ undefined, createToken(35 /* EqualsGreaterThanToken */), createElementAccess(target, createIdentifier("name")));
}
function createSeti(target) {
// (name, value) => super[name] = value
return createArrowFunction(
/*modifiers*/ undefined,
/*typeParameters*/ undefined, [
createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "name"),
createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "value")
],
/*type*/ undefined, createToken(35 /* EqualsGreaterThanToken */), createAssignment(createElementAccess(target, createIdentifier("name")), createIdentifier("value")));
}
function createAdvancedAsyncSuperHelper() {
// const _super = (function (geti, seti) {
// const cache = Object.create(null);
// return name => cache[name] || (cache[name] = { get value() { return geti(name); }, set value(v) { seti(name, v); } });
// })(name => super[name], (name, value) => super[name] = value);
// const cache = Object.create(null);
var createCache = createVariableStatement(
/*modifiers*/ undefined, createConstDeclarationList([
createVariableDeclaration("cache",
/*type*/ undefined, createObjectCreate(createNull()))
]));
// get value() { return geti(name); }
var getter = createGetAccessor(
/*decorators*/ undefined,
/*modifiers*/ undefined, "value",
/*parameters*/ [],
/*type*/ undefined, createBlock([
createReturn(createCall(createIdentifier("geti"),
/*typeArguments*/ undefined, [createIdentifier("name")]))
]));
// set value(v) { seti(name, v); }
var setter = createSetAccessor(
/*decorators*/ undefined,
/*modifiers*/ undefined, "value", [createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "v")], createBlock([
createStatement(createCall(createIdentifier("seti"),
/*typeArguments*/ undefined, [
createIdentifier("name"),
createIdentifier("v")
]))
]));
// return name => cache[name] || ...
var getOrCreateAccessorsForName = createReturn(createArrowFunction(
/*modifiers*/ undefined,
/*typeParameters*/ undefined, [createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "name")],
/*type*/ undefined, createToken(35 /* EqualsGreaterThanToken */), createLogicalOr(createElementAccess(createIdentifier("cache"), createIdentifier("name")), createParen(createAssignment(createElementAccess(createIdentifier("cache"), createIdentifier("name")), createObjectLiteral([
getter,
setter
]))))));
// const _super = (function (geti, seti) {
// const cache = Object.create(null);
// return name => cache[name] || (cache[name] = { get value() { return geti(name); }, set value(v) { seti(name, v); } });
// })(name => super[name], (name, value) => super[name] = value);
return createVariableStatement(
/*modifiers*/ undefined, createConstDeclarationList([
createVariableDeclaration("_super",
/*type*/ undefined, createCall(createParen(createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, [
createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "geti"),
createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "seti")
],
/*type*/ undefined, createBlock([
createCache,
getOrCreateAccessorsForName
]))),
/*typeArguments*/ undefined, [
createGeti(createSuper()),
createSeti(createSuper())
]))
]));
}
ts.createAdvancedAsyncSuperHelper = createAdvancedAsyncSuperHelper;
function createSimpleAsyncSuperHelper() {
return createVariableStatement(
/*modifiers*/ undefined, createConstDeclarationList([
createVariableDeclaration("_super",
/*type*/ undefined, createGeti(createSuper()))
]));
}
ts.createSimpleAsyncSuperHelper = createSimpleAsyncSuperHelper;
function shouldBeCapturedInTempVariable(node, cacheIdentifiers) {
var target = skipParentheses(node);
switch (target.kind) {
case 70 /* Identifier */:
return cacheIdentifiers;
case 98 /* ThisKeyword */:
case 8 /* NumericLiteral */:
case 9 /* StringLiteral */:
return false;
case 175 /* ArrayLiteralExpression */:
var elements = target.elements;
if (elements.length === 0) {
return false;
}
return true;
case 176 /* ObjectLiteralExpression */:
return target.properties.length > 0;
default:
return true;
}
}
function createCallBinding(expression, recordTempVariable, languageVersion, cacheIdentifiers) {
var callee = skipOuterExpressions(expression, 7 /* All */);
var thisArg;
var target;
if (ts.isSuperProperty(callee)) {
thisArg = createThis();
target = callee;
}
else if (callee.kind === 96 /* SuperKeyword */) {
thisArg = createThis();
target = languageVersion < 2 /* ES2015 */ ? createIdentifier("_super", /*location*/ callee) : callee;
}
else {
switch (callee.kind) {
case 177 /* PropertyAccessExpression */: {
if (shouldBeCapturedInTempVariable(callee.expression, cacheIdentifiers)) {
// for `a.b()` target is `(_a = a).b` and thisArg is `_a`
thisArg = createTempVariable(recordTempVariable);
target = createPropertyAccess(createAssignment(thisArg, callee.expression,
/*location*/ callee.expression), callee.name,
/*location*/ callee);
}
else {
thisArg = callee.expression;
target = callee;
}
break;
}
case 178 /* ElementAccessExpression */: {
if (shouldBeCapturedInTempVariable(callee.expression, cacheIdentifiers)) {
// for `a[b]()` target is `(_a = a)[b]` and thisArg is `_a`
thisArg = createTempVariable(recordTempVariable);
target = createElementAccess(createAssignment(thisArg, callee.expression,
/*location*/ callee.expression), callee.argumentExpression,
/*location*/ callee);
}
else {
thisArg = callee.expression;
target = callee;
}
break;
}
default: {
// for `a()` target is `a` and thisArg is `void 0`
thisArg = createVoidZero();
target = parenthesizeForAccess(expression);
break;
}
}
}
return { target: target, thisArg: thisArg };
}
ts.createCallBinding = createCallBinding;
function inlineExpressions(expressions) {
return ts.reduceLeft(expressions, createComma);
}
ts.inlineExpressions = inlineExpressions;
function createExpressionFromEntityName(node) {
if (ts.isQualifiedName(node)) {
var left = createExpressionFromEntityName(node.left);
var right = getMutableClone(node.right);
return createPropertyAccess(left, right, /*location*/ node);
}
else {
return getMutableClone(node);
}
}
ts.createExpressionFromEntityName = createExpressionFromEntityName;
function createExpressionForPropertyName(memberName) {
if (ts.isIdentifier(memberName)) {
return createLiteral(memberName, /*location*/ undefined);
}
else if (ts.isComputedPropertyName(memberName)) {
return getMutableClone(memberName.expression);
}
else {
return getMutableClone(memberName);
}
}
ts.createExpressionForPropertyName = createExpressionForPropertyName;
function createExpressionForObjectLiteralElementLike(node, property, receiver) {
switch (property.kind) {
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return createExpressionForAccessorDeclaration(node.properties, property, receiver, node.multiLine);
case 257 /* PropertyAssignment */:
return createExpressionForPropertyAssignment(property, receiver);
case 258 /* ShorthandPropertyAssignment */:
return createExpressionForShorthandPropertyAssignment(property, receiver);
case 149 /* MethodDeclaration */:
return createExpressionForMethodDeclaration(property, receiver);
}
}
ts.createExpressionForObjectLiteralElementLike = createExpressionForObjectLiteralElementLike;
function createExpressionForAccessorDeclaration(properties, property, receiver, multiLine) {
var _a = ts.getAllAccessorDeclarations(properties, property), firstAccessor = _a.firstAccessor, getAccessor = _a.getAccessor, setAccessor = _a.setAccessor;
if (property === firstAccessor) {
var properties_1 = [];
if (getAccessor) {
var getterFunction = createFunctionExpression(getAccessor.modifiers,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, getAccessor.parameters,
/*type*/ undefined, getAccessor.body,
/*location*/ getAccessor);
setOriginalNode(getterFunction, getAccessor);
var getter = createPropertyAssignment("get", getterFunction);
properties_1.push(getter);
}
if (setAccessor) {
var setterFunction = createFunctionExpression(setAccessor.modifiers,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, setAccessor.parameters,
/*type*/ undefined, setAccessor.body,
/*location*/ setAccessor);
setOriginalNode(setterFunction, setAccessor);
var setter = createPropertyAssignment("set", setterFunction);
properties_1.push(setter);
}
properties_1.push(createPropertyAssignment("enumerable", createLiteral(true)));
properties_1.push(createPropertyAssignment("configurable", createLiteral(true)));
var expression = createCall(createPropertyAccess(createIdentifier("Object"), "defineProperty"),
/*typeArguments*/ undefined, [
receiver,
createExpressionForPropertyName(property.name),
createObjectLiteral(properties_1, /*location*/ undefined, multiLine)
],
/*location*/ firstAccessor);
return ts.aggregateTransformFlags(expression);
}
return undefined;
}
function createExpressionForPropertyAssignment(property, receiver) {
return ts.aggregateTransformFlags(setOriginalNode(createAssignment(createMemberAccessForPropertyName(receiver, property.name, /*location*/ property.name), property.initializer,
/*location*/ property),
/*original*/ property));
}
function createExpressionForShorthandPropertyAssignment(property, receiver) {
return ts.aggregateTransformFlags(setOriginalNode(createAssignment(createMemberAccessForPropertyName(receiver, property.name, /*location*/ property.name), getSynthesizedClone(property.name),
/*location*/ property),
/*original*/ property));
}
function createExpressionForMethodDeclaration(method, receiver) {
return ts.aggregateTransformFlags(setOriginalNode(createAssignment(createMemberAccessForPropertyName(receiver, method.name, /*location*/ method.name), setOriginalNode(createFunctionExpression(method.modifiers, method.asteriskToken,
/*name*/ undefined,
/*typeParameters*/ undefined, method.parameters,
/*type*/ undefined, method.body,
/*location*/ method),
/*original*/ method),
/*location*/ method),
/*original*/ method));
}
/**
* Gets the local name of a declaration. This is primarily used for declarations that can be
* referred to by name in the declaration's immediate scope (classes, enums, namespaces). A
* local name will *never* be prefixed with an module or namespace export modifier like
* "exports." when emitted as an expression.
*
* @param node The declaration.
* @param allowComments A value indicating whether comments may be emitted for the name.
* @param allowSourceMaps A value indicating whether source maps may be emitted for the name.
*/
function getLocalName(node, allowComments, allowSourceMaps) {
return getName(node, allowComments, allowSourceMaps, 262144 /* LocalName */);
}
ts.getLocalName = getLocalName;
/**
* Gets whether an identifier should only be referred to by its local name.
*/
function isLocalName(node) {
return (getEmitFlags(node) & 262144 /* LocalName */) !== 0;
}
ts.isLocalName = isLocalName;
/**
* Gets the export name of a declaration. This is primarily used for declarations that can be
* referred to by name in the declaration's immediate scope (classes, enums, namespaces). An
* export name will *always* be prefixed with an module or namespace export modifier like
* `"exports."` when emitted as an expression if the name points to an exported symbol.
*
* @param node The declaration.
* @param allowComments A value indicating whether comments may be emitted for the name.
* @param allowSourceMaps A value indicating whether source maps may be emitted for the name.
*/
function getExportName(node, allowComments, allowSourceMaps) {
return getName(node, allowComments, allowSourceMaps, 131072 /* ExportName */);
}
ts.getExportName = getExportName;
/**
* Gets whether an identifier should only be referred to by its export representation if the
* name points to an exported symbol.
*/
function isExportName(node) {
return (getEmitFlags(node) & 131072 /* ExportName */) !== 0;
}
ts.isExportName = isExportName;
/**
* Gets the name of a declaration for use in declarations.
*
* @param node The declaration.
* @param allowComments A value indicating whether comments may be emitted for the name.
* @param allowSourceMaps A value indicating whether source maps may be emitted for the name.
*/
function getDeclarationName(node, allowComments, allowSourceMaps) {
return getName(node, allowComments, allowSourceMaps);
}
ts.getDeclarationName = getDeclarationName;
function getName(node, allowComments, allowSourceMaps, emitFlags) {
if (node.name && ts.isIdentifier(node.name) && !ts.isGeneratedIdentifier(node.name)) {
var name_11 = getMutableClone(node.name);
emitFlags |= getEmitFlags(node.name);
if (!allowSourceMaps)
emitFlags |= 1536 /* NoSourceMap */;
if (!allowComments)
emitFlags |= 49152 /* NoComments */;
if (emitFlags)
setEmitFlags(name_11, emitFlags);
return name_11;
}
return getGeneratedNameForNode(node);
}
/**
* Gets the exported name of a declaration for use in expressions.
*
* An exported name will *always* be prefixed with an module or namespace export modifier like
* "exports." if the name points to an exported symbol.
*
* @param ns The namespace identifier.
* @param node The declaration.
* @param allowComments A value indicating whether comments may be emitted for the name.
* @param allowSourceMaps A value indicating whether source maps may be emitted for the name.
*/
function getExternalModuleOrNamespaceExportName(ns, node, allowComments, allowSourceMaps) {
if (ns && ts.hasModifier(node, 1 /* Export */)) {
return getNamespaceMemberName(ns, getName(node), allowComments, allowSourceMaps);
}
return getExportName(node, allowComments, allowSourceMaps);
}
ts.getExternalModuleOrNamespaceExportName = getExternalModuleOrNamespaceExportName;
/**
* Gets a namespace-qualified name for use in expressions.
*
* @param ns The namespace identifier.
* @param name The name.
* @param allowComments A value indicating whether comments may be emitted for the name.
* @param allowSourceMaps A value indicating whether source maps may be emitted for the name.
*/
function getNamespaceMemberName(ns, name, allowComments, allowSourceMaps) {
var qualifiedName = createPropertyAccess(ns, ts.nodeIsSynthesized(name) ? name : getSynthesizedClone(name), /*location*/ name);
var emitFlags;
if (!allowSourceMaps)
emitFlags |= 1536 /* NoSourceMap */;
if (!allowComments)
emitFlags |= 49152 /* NoComments */;
if (emitFlags)
setEmitFlags(qualifiedName, emitFlags);
return qualifiedName;
}
ts.getNamespaceMemberName = getNamespaceMemberName;
// Utilities
function isUseStrictPrologue(node) {
return node.expression.text === "use strict";
}
/**
* Add any necessary prologue-directives into target statement-array.
* The function needs to be called during each transformation step.
* This function needs to be called whenever we transform the statement
* list of a source file, namespace, or function-like body.
*
* @param target: result statements array
* @param source: origin statements array
* @param ensureUseStrict: boolean determining whether the function need to add prologue-directives
* @param visitor: Optional callback used to visit any custom prologue directives.
*/
function addPrologueDirectives(target, source, ensureUseStrict, visitor) {
ts.Debug.assert(target.length === 0, "Prologue directives should be at the first statement in the target statements array");
var foundUseStrict = false;
var statementOffset = 0;
var numStatements = source.length;
while (statementOffset < numStatements) {
var statement = source[statementOffset];
if (ts.isPrologueDirective(statement)) {
if (isUseStrictPrologue(statement)) {
foundUseStrict = true;
}
target.push(statement);
}
else {
break;
}
statementOffset++;
}
if (ensureUseStrict && !foundUseStrict) {
target.push(startOnNewLine(createStatement(createLiteral("use strict"))));
}
while (statementOffset < numStatements) {
var statement = source[statementOffset];
if (getEmitFlags(statement) & 8388608 /* CustomPrologue */) {
target.push(visitor ? ts.visitNode(statement, visitor, ts.isStatement) : statement);
}
else {
break;
}
statementOffset++;
}
return statementOffset;
}
ts.addPrologueDirectives = addPrologueDirectives;
/**
* Ensures "use strict" directive is added
*
* @param node source file
*/
function ensureUseStrict(node) {
var foundUseStrict = false;
for (var _i = 0, _a = node.statements; _i < _a.length; _i++) {
var statement = _a[_i];
if (ts.isPrologueDirective(statement)) {
if (isUseStrictPrologue(statement)) {
foundUseStrict = true;
break;
}
}
else {
break;
}
}
if (!foundUseStrict) {
var statements = [];
statements.push(startOnNewLine(createStatement(createLiteral("use strict"))));
// add "use strict" as the first statement
return updateSourceFileNode(node, statements.concat(node.statements));
}
return node;
}
ts.ensureUseStrict = ensureUseStrict;
/**
* Wraps the operand to a BinaryExpression in parentheses if they are needed to preserve the intended
* order of operations.
*
* @param binaryOperator The operator for the BinaryExpression.
* @param operand The operand for the BinaryExpression.
* @param isLeftSideOfBinary A value indicating whether the operand is the left side of the
* BinaryExpression.
*/
function parenthesizeBinaryOperand(binaryOperator, operand, isLeftSideOfBinary, leftOperand) {
var skipped = skipPartiallyEmittedExpressions(operand);
// If the resulting expression is already parenthesized, we do not need to do any further processing.
if (skipped.kind === 183 /* ParenthesizedExpression */) {
return operand;
}
return binaryOperandNeedsParentheses(binaryOperator, operand, isLeftSideOfBinary, leftOperand)
? createParen(operand)
: operand;
}
ts.parenthesizeBinaryOperand = parenthesizeBinaryOperand;
/**
* Determines whether the operand to a BinaryExpression needs to be parenthesized.
*
* @param binaryOperator The operator for the BinaryExpression.
* @param operand The operand for the BinaryExpression.
* @param isLeftSideOfBinary A value indicating whether the operand is the left side of the
* BinaryExpression.
*/
function binaryOperandNeedsParentheses(binaryOperator, operand, isLeftSideOfBinary, leftOperand) {
// If the operand has lower precedence, then it needs to be parenthesized to preserve the
// intent of the expression. For example, if the operand is `a + b` and the operator is
// `*`, then we need to parenthesize the operand to preserve the intended order of
// operations: `(a + b) * x`.
//
// If the operand has higher precedence, then it does not need to be parenthesized. For
// example, if the operand is `a * b` and the operator is `+`, then we do not need to
// parenthesize to preserve the intended order of operations: `a * b + x`.
//
// If the operand has the same precedence, then we need to check the associativity of
// the operator based on whether this is the left or right operand of the expression.
//
// For example, if `a / d` is on the right of operator `*`, we need to parenthesize
// to preserve the intended order of operations: `x * (a / d)`
//
// If `a ** d` is on the left of operator `**`, we need to parenthesize to preserve
// the intended order of operations: `(a ** b) ** c`
var binaryOperatorPrecedence = ts.getOperatorPrecedence(192 /* BinaryExpression */, binaryOperator);
var binaryOperatorAssociativity = ts.getOperatorAssociativity(192 /* BinaryExpression */, binaryOperator);
var emittedOperand = skipPartiallyEmittedExpressions(operand);
var operandPrecedence = ts.getExpressionPrecedence(emittedOperand);
switch (ts.compareValues(operandPrecedence, binaryOperatorPrecedence)) {
case -1 /* LessThan */:
// If the operand is the right side of a right-associative binary operation
// and is a yield expression, then we do not need parentheses.
if (!isLeftSideOfBinary
&& binaryOperatorAssociativity === 1 /* Right */
&& operand.kind === 195 /* YieldExpression */) {
return false;
}
return true;
case 1 /* GreaterThan */:
return false;
case 0 /* EqualTo */:
if (isLeftSideOfBinary) {
// No need to parenthesize the left operand when the binary operator is
// left associative:
// (a*b)/x -> a*b/x
// (a**b)/x -> a**b/x
//
// Parentheses are needed for the left operand when the binary operator is
// right associative:
// (a/b)**x -> (a/b)**x
// (a**b)**x -> (a**b)**x
return binaryOperatorAssociativity === 1 /* Right */;
}
else {
if (ts.isBinaryExpression(emittedOperand)
&& emittedOperand.operatorToken.kind === binaryOperator) {
// No need to parenthesize the right operand when the binary operator and
// operand are the same and one of the following:
// x*(a*b) => x*a*b
// x|(a|b) => x|a|b
// x&(a&b) => x&a&b
// x^(a^b) => x^a^b
if (operatorHasAssociativeProperty(binaryOperator)) {
return false;
}
// No need to parenthesize the right operand when the binary operator
// is plus (+) if both the left and right operands consist solely of either
// literals of the same kind or binary plus (+) expressions for literals of
// the same kind (recursively).
// "a"+(1+2) => "a"+(1+2)
// "a"+("b"+"c") => "a"+"b"+"c"
if (binaryOperator === 36 /* PlusToken */) {
var leftKind = leftOperand ? getLiteralKindOfBinaryPlusOperand(leftOperand) : 0 /* Unknown */;
if (ts.isLiteralKind(leftKind) && leftKind === getLiteralKindOfBinaryPlusOperand(emittedOperand)) {
return false;
}
}
}
// No need to parenthesize the right operand when the operand is right
// associative:
// x/(a**b) -> x/a**b
// x**(a**b) -> x**a**b
//
// Parentheses are needed for the right operand when the operand is left
// associative:
// x/(a*b) -> x/(a*b)
// x**(a/b) -> x**(a/b)
var operandAssociativity = ts.getExpressionAssociativity(emittedOperand);
return operandAssociativity === 0 /* Left */;
}
}
}
/**
* Determines whether a binary operator is mathematically associative.
*
* @param binaryOperator The binary operator.
*/
function operatorHasAssociativeProperty(binaryOperator) {
// The following operators are associative in JavaScript:
// (a*b)*c -> a*(b*c) -> a*b*c
// (a|b)|c -> a|(b|c) -> a|b|c
// (a&b)&c -> a&(b&c) -> a&b&c
// (a^b)^c -> a^(b^c) -> a^b^c
//
// While addition is associative in mathematics, JavaScript's `+` is not
// guaranteed to be associative as it is overloaded with string concatenation.
return binaryOperator === 38 /* AsteriskToken */
|| binaryOperator === 48 /* BarToken */
|| binaryOperator === 47 /* AmpersandToken */
|| binaryOperator === 49 /* CaretToken */;
}
/**
* This function determines whether an expression consists of a homogeneous set of
* literal expressions or binary plus expressions that all share the same literal kind.
* It is used to determine whether the right-hand operand of a binary plus expression can be
* emitted without parentheses.
*/
function getLiteralKindOfBinaryPlusOperand(node) {
node = skipPartiallyEmittedExpressions(node);
if (ts.isLiteralKind(node.kind)) {
return node.kind;
}
if (node.kind === 192 /* BinaryExpression */ && node.operatorToken.kind === 36 /* PlusToken */) {
if (node.cachedLiteralKind !== undefined) {
return node.cachedLiteralKind;
}
var leftKind = getLiteralKindOfBinaryPlusOperand(node.left);
var literalKind = ts.isLiteralKind(leftKind)
&& leftKind === getLiteralKindOfBinaryPlusOperand(node.right)
? leftKind
: 0 /* Unknown */;
node.cachedLiteralKind = literalKind;
return literalKind;
}
return 0 /* Unknown */;
}
/**
* Wraps an expression in parentheses if it is needed in order to use the expression
* as the expression of a NewExpression node.
*
* @param expression The Expression node.
*/
function parenthesizeForNew(expression) {
var emittedExpression = skipPartiallyEmittedExpressions(expression);
switch (emittedExpression.kind) {
case 179 /* CallExpression */:
return createParen(expression);
case 180 /* NewExpression */:
return emittedExpression.arguments
? expression
: createParen(expression);
}
return parenthesizeForAccess(expression);
}
ts.parenthesizeForNew = parenthesizeForNew;
/**
* Wraps an expression in parentheses if it is needed in order to use the expression for
* property or element access.
*
* @param expr The expression node.
*/
function parenthesizeForAccess(expression) {
// isLeftHandSideExpression is almost the correct criterion for when it is not necessary
// to parenthesize the expression before a dot. The known exceptions are:
//
// NewExpression:
// new C.x -> not the same as (new C).x
// NumericLiteral
// 1.x -> not the same as (1).x
//
var emittedExpression = skipPartiallyEmittedExpressions(expression);
if (ts.isLeftHandSideExpression(emittedExpression)
&& (emittedExpression.kind !== 180 /* NewExpression */ || emittedExpression.arguments)
&& emittedExpression.kind !== 8 /* NumericLiteral */) {
return expression;
}
return createParen(expression, /*location*/ expression);
}
ts.parenthesizeForAccess = parenthesizeForAccess;
function parenthesizePostfixOperand(operand) {
return ts.isLeftHandSideExpression(operand)
? operand
: createParen(operand, /*location*/ operand);
}
ts.parenthesizePostfixOperand = parenthesizePostfixOperand;
function parenthesizePrefixOperand(operand) {
return ts.isUnaryExpression(operand)
? operand
: createParen(operand, /*location*/ operand);
}
ts.parenthesizePrefixOperand = parenthesizePrefixOperand;
function parenthesizeListElements(elements) {
var result;
for (var i = 0; i < elements.length; i++) {
var element = parenthesizeExpressionForList(elements[i]);
if (result !== undefined || element !== elements[i]) {
if (result === undefined) {
result = elements.slice(0, i);
}
result.push(element);
}
}
if (result !== undefined) {
return createNodeArray(result, elements, elements.hasTrailingComma);
}
return elements;
}
function parenthesizeExpressionForList(expression) {
var emittedExpression = skipPartiallyEmittedExpressions(expression);
var expressionPrecedence = ts.getExpressionPrecedence(emittedExpression);
var commaPrecedence = ts.getOperatorPrecedence(192 /* BinaryExpression */, 25 /* CommaToken */);
return expressionPrecedence > commaPrecedence
? expression
: createParen(expression, /*location*/ expression);
}
ts.parenthesizeExpressionForList = parenthesizeExpressionForList;
function parenthesizeExpressionForExpressionStatement(expression) {
var emittedExpression = skipPartiallyEmittedExpressions(expression);
if (ts.isCallExpression(emittedExpression)) {
var callee = emittedExpression.expression;
var kind = skipPartiallyEmittedExpressions(callee).kind;
if (kind === 184 /* FunctionExpression */ || kind === 185 /* ArrowFunction */) {
var mutableCall = getMutableClone(emittedExpression);
mutableCall.expression = createParen(callee, /*location*/ callee);
return recreatePartiallyEmittedExpressions(expression, mutableCall);
}
}
else {
var leftmostExpressionKind = getLeftmostExpression(emittedExpression).kind;
if (leftmostExpressionKind === 176 /* ObjectLiteralExpression */ || leftmostExpressionKind === 184 /* FunctionExpression */) {
return createParen(expression, /*location*/ expression);
}
}
return expression;
}
ts.parenthesizeExpressionForExpressionStatement = parenthesizeExpressionForExpressionStatement;
/**
* Clones a series of not-emitted expressions with a new inner expression.
*
* @param originalOuterExpression The original outer expression.
* @param newInnerExpression The new inner expression.
*/
function recreatePartiallyEmittedExpressions(originalOuterExpression, newInnerExpression) {
if (ts.isPartiallyEmittedExpression(originalOuterExpression)) {
var clone_1 = getMutableClone(originalOuterExpression);
clone_1.expression = recreatePartiallyEmittedExpressions(clone_1.expression, newInnerExpression);
return clone_1;
}
return newInnerExpression;
}
function getLeftmostExpression(node) {
while (true) {
switch (node.kind) {
case 191 /* PostfixUnaryExpression */:
node = node.operand;
continue;
case 192 /* BinaryExpression */:
node = node.left;
continue;
case 193 /* ConditionalExpression */:
node = node.condition;
continue;
case 179 /* CallExpression */:
case 178 /* ElementAccessExpression */:
case 177 /* PropertyAccessExpression */:
node = node.expression;
continue;
case 293 /* PartiallyEmittedExpression */:
node = node.expression;
continue;
}
return node;
}
}
function parenthesizeConciseBody(body) {
var emittedBody = skipPartiallyEmittedExpressions(body);
if (emittedBody.kind === 176 /* ObjectLiteralExpression */) {
return createParen(body, /*location*/ body);
}
return body;
}
ts.parenthesizeConciseBody = parenthesizeConciseBody;
var OuterExpressionKinds;
(function (OuterExpressionKinds) {
OuterExpressionKinds[OuterExpressionKinds["Parentheses"] = 1] = "Parentheses";
OuterExpressionKinds[OuterExpressionKinds["Assertions"] = 2] = "Assertions";
OuterExpressionKinds[OuterExpressionKinds["PartiallyEmittedExpressions"] = 4] = "PartiallyEmittedExpressions";
OuterExpressionKinds[OuterExpressionKinds["All"] = 7] = "All";
})(OuterExpressionKinds = ts.OuterExpressionKinds || (ts.OuterExpressionKinds = {}));
function skipOuterExpressions(node, kinds) {
if (kinds === void 0) { kinds = 7 /* All */; }
var previousNode;
do {
previousNode = node;
if (kinds & 1 /* Parentheses */) {
node = skipParentheses(node);
}
if (kinds & 2 /* Assertions */) {
node = skipAssertions(node);
}
if (kinds & 4 /* PartiallyEmittedExpressions */) {
node = skipPartiallyEmittedExpressions(node);
}
} while (previousNode !== node);
return node;
}
ts.skipOuterExpressions = skipOuterExpressions;
function skipParentheses(node) {
while (node.kind === 183 /* ParenthesizedExpression */) {
node = node.expression;
}
return node;
}
ts.skipParentheses = skipParentheses;
function skipAssertions(node) {
while (ts.isAssertionExpression(node)) {
node = node.expression;
}
return node;
}
ts.skipAssertions = skipAssertions;
function skipPartiallyEmittedExpressions(node) {
while (node.kind === 293 /* PartiallyEmittedExpression */) {
node = node.expression;
}
return node;
}
ts.skipPartiallyEmittedExpressions = skipPartiallyEmittedExpressions;
function startOnNewLine(node) {
node.startsOnNewLine = true;
return node;
}
ts.startOnNewLine = startOnNewLine;
function setOriginalNode(node, original) {
node.original = original;
if (original) {
var emitNode = original.emitNode;
if (emitNode)
node.emitNode = mergeEmitNode(emitNode, node.emitNode);
}
return node;
}
ts.setOriginalNode = setOriginalNode;
function mergeEmitNode(sourceEmitNode, destEmitNode) {
var flags = sourceEmitNode.flags, commentRange = sourceEmitNode.commentRange, sourceMapRange = sourceEmitNode.sourceMapRange, tokenSourceMapRanges = sourceEmitNode.tokenSourceMapRanges;
if (!destEmitNode && (flags || commentRange || sourceMapRange || tokenSourceMapRanges))
destEmitNode = {};
if (flags)
destEmitNode.flags = flags;
if (commentRange)
destEmitNode.commentRange = commentRange;
if (sourceMapRange)
destEmitNode.sourceMapRange = sourceMapRange;
if (tokenSourceMapRanges)
destEmitNode.tokenSourceMapRanges = mergeTokenSourceMapRanges(tokenSourceMapRanges, destEmitNode.tokenSourceMapRanges);
return destEmitNode;
}
function mergeTokenSourceMapRanges(sourceRanges, destRanges) {
if (!destRanges)
destRanges = ts.createMap();
ts.copyProperties(sourceRanges, destRanges);
return destRanges;
}
/**
* Clears any EmitNode entries from parse-tree nodes.
* @param sourceFile A source file.
*/
function disposeEmitNodes(sourceFile) {
// During transformation we may need to annotate a parse tree node with transient
// transformation properties. As parse tree nodes live longer than transformation
// nodes, we need to make sure we reclaim any memory allocated for custom ranges
// from these nodes to ensure we do not hold onto entire subtrees just for position
// information. We also need to reset these nodes to a pre-transformation state
// for incremental parsing scenarios so that we do not impact later emit.
sourceFile = ts.getSourceFileOfNode(ts.getParseTreeNode(sourceFile));
var emitNode = sourceFile && sourceFile.emitNode;
var annotatedNodes = emitNode && emitNode.annotatedNodes;
if (annotatedNodes) {
for (var _i = 0, annotatedNodes_1 = annotatedNodes; _i < annotatedNodes_1.length; _i++) {
var node = annotatedNodes_1[_i];
node.emitNode = undefined;
}
}
}
ts.disposeEmitNodes = disposeEmitNodes;
/**
* Associates a node with the current transformation, initializing
* various transient transformation properties.
*
* @param node The node.
*/
function getOrCreateEmitNode(node) {
if (!node.emitNode) {
if (ts.isParseTreeNode(node)) {
// To avoid holding onto transformation artifacts, we keep track of any
// parse tree node we are annotating. This allows us to clean them up after
// all transformations have completed.
if (node.kind === 261 /* SourceFile */) {
return node.emitNode = { annotatedNodes: [node] };
}
var sourceFile = ts.getSourceFileOfNode(node);
getOrCreateEmitNode(sourceFile).annotatedNodes.push(node);
}
node.emitNode = {};
}
return node.emitNode;
}
/**
* Gets flags that control emit behavior of a node.
*
* @param node The node.
*/
function getEmitFlags(node) {
var emitNode = node.emitNode;
return emitNode && emitNode.flags;
}
ts.getEmitFlags = getEmitFlags;
/**
* Sets flags that control emit behavior of a node.
*
* @param node The node.
* @param emitFlags The NodeEmitFlags for the node.
*/
function setEmitFlags(node, emitFlags) {
getOrCreateEmitNode(node).flags = emitFlags;
return node;
}
ts.setEmitFlags = setEmitFlags;
/**
* Sets a custom text range to use when emitting source maps.
*
* @param node The node.
* @param range The text range.
*/
function setSourceMapRange(node, range) {
getOrCreateEmitNode(node).sourceMapRange = range;
return node;
}
ts.setSourceMapRange = setSourceMapRange;
/**
* Sets the TextRange to use for source maps for a token of a node.
*
* @param node The node.
* @param token The token.
* @param range The text range.
*/
function setTokenSourceMapRange(node, token, range) {
var emitNode = getOrCreateEmitNode(node);
var tokenSourceMapRanges = emitNode.tokenSourceMapRanges || (emitNode.tokenSourceMapRanges = ts.createMap());
tokenSourceMapRanges[token] = range;
return node;
}
ts.setTokenSourceMapRange = setTokenSourceMapRange;
/**
* Sets a custom text range to use when emitting comments.
*/
function setCommentRange(node, range) {
getOrCreateEmitNode(node).commentRange = range;
return node;
}
ts.setCommentRange = setCommentRange;
/**
* Gets a custom text range to use when emitting comments.
*
* @param node The node.
*/
function getCommentRange(node) {
var emitNode = node.emitNode;
return (emitNode && emitNode.commentRange) || node;
}
ts.getCommentRange = getCommentRange;
/**
* Gets a custom text range to use when emitting source maps.
*
* @param node The node.
*/
function getSourceMapRange(node) {
var emitNode = node.emitNode;
return (emitNode && emitNode.sourceMapRange) || node;
}
ts.getSourceMapRange = getSourceMapRange;
/**
* Gets the TextRange to use for source maps for a token of a node.
*
* @param node The node.
* @param token The token.
*/
function getTokenSourceMapRange(node, token) {
var emitNode = node.emitNode;
var tokenSourceMapRanges = emitNode && emitNode.tokenSourceMapRanges;
return tokenSourceMapRanges && tokenSourceMapRanges[token];
}
ts.getTokenSourceMapRange = getTokenSourceMapRange;
/**
* Gets the constant value to emit for an expression.
*/
function getConstantValue(node) {
var emitNode = node.emitNode;
return emitNode && emitNode.constantValue;
}
ts.getConstantValue = getConstantValue;
/**
* Sets the constant value to emit for an expression.
*/
function setConstantValue(node, value) {
var emitNode = getOrCreateEmitNode(node);
emitNode.constantValue = value;
return node;
}
ts.setConstantValue = setConstantValue;
function setTextRange(node, location) {
if (location) {
node.pos = location.pos;
node.end = location.end;
}
return node;
}
ts.setTextRange = setTextRange;
function setNodeFlags(node, flags) {
node.flags = flags;
return node;
}
ts.setNodeFlags = setNodeFlags;
function setMultiLine(node, multiLine) {
node.multiLine = multiLine;
return node;
}
ts.setMultiLine = setMultiLine;
function setHasTrailingComma(nodes, hasTrailingComma) {
nodes.hasTrailingComma = hasTrailingComma;
return nodes;
}
ts.setHasTrailingComma = setHasTrailingComma;
/**
* Get the name of that target module from an import or export declaration
*/
function getLocalNameForExternalImport(node, sourceFile) {
var namespaceDeclaration = ts.getNamespaceDeclarationNode(node);
if (namespaceDeclaration && !ts.isDefaultImport(node)) {
var name_12 = namespaceDeclaration.name;
return ts.isGeneratedIdentifier(name_12) ? name_12 : createIdentifier(ts.getSourceTextOfNodeFromSourceFile(sourceFile, namespaceDeclaration.name));
}
if (node.kind === 235 /* ImportDeclaration */ && node.importClause) {
return getGeneratedNameForNode(node);
}
if (node.kind === 241 /* ExportDeclaration */ && node.moduleSpecifier) {
return getGeneratedNameForNode(node);
}
return undefined;
}
ts.getLocalNameForExternalImport = getLocalNameForExternalImport;
/**
* Get the name of a target module from an import/export declaration as should be written in the emitted output.
* The emitted output name can be different from the input if:
* 1. The module has a /// <amd-module name="<new name>" />
* 2. --out or --outFile is used, making the name relative to the rootDir
* 3- The containing SourceFile has an entry in renamedDependencies for the import as requested by some module loaders (e.g. System).
* Otherwise, a new StringLiteral node representing the module name will be returned.
*/
function getExternalModuleNameLiteral(importNode, sourceFile, host, resolver, compilerOptions) {
var moduleName = ts.getExternalModuleName(importNode);
if (moduleName.kind === 9 /* StringLiteral */) {
return tryGetModuleNameFromDeclaration(importNode, host, resolver, compilerOptions)
|| tryRenameExternalModule(moduleName, sourceFile)
|| getSynthesizedClone(moduleName);
}
return undefined;
}
ts.getExternalModuleNameLiteral = getExternalModuleNameLiteral;
/**
* Some bundlers (SystemJS builder) sometimes want to rename dependencies.
* Here we check if alternative name was provided for a given moduleName and return it if possible.
*/
function tryRenameExternalModule(moduleName, sourceFile) {
if (sourceFile.renamedDependencies && ts.hasProperty(sourceFile.renamedDependencies, moduleName.text)) {
return createLiteral(sourceFile.renamedDependencies[moduleName.text]);
}
return undefined;
}
/**
* Get the name of a module as should be written in the emitted output.
* The emitted output name can be different from the input if:
* 1. The module has a /// <amd-module name="<new name>" />
* 2. --out or --outFile is used, making the name relative to the rootDir
* Otherwise, a new StringLiteral node representing the module name will be returned.
*/
function tryGetModuleNameFromFile(file, host, options) {
if (!file) {
return undefined;
}
if (file.moduleName) {
return createLiteral(file.moduleName);
}
if (!ts.isDeclarationFile(file) && (options.out || options.outFile)) {
return createLiteral(ts.getExternalModuleNameFromPath(host, file.fileName));
}
return undefined;
}
ts.tryGetModuleNameFromFile = tryGetModuleNameFromFile;
function tryGetModuleNameFromDeclaration(declaration, host, resolver, compilerOptions) {
return tryGetModuleNameFromFile(resolver.getExternalModuleFileFromDeclaration(declaration), host, compilerOptions);
}
/**
* Transforms the body of a function-like node.
*
* @param node A function-like node.
*/
function transformFunctionBody(node, visitor, currentSourceFile, context, enableSubstitutionsForCapturedThis, convertObjectRest) {
var multiLine = false; // indicates whether the block *must* be emitted as multiple lines
var singleLine = false; // indicates whether the block *may* be emitted as a single line
var statementsLocation;
var closeBraceLocation;
var statements = [];
var body = node.body;
var statementOffset;
context.startLexicalEnvironment();
if (ts.isBlock(body)) {
// ensureUseStrict is false because no new prologue-directive should be added.
// addPrologueDirectives will simply put already-existing directives at the beginning of the target statement-array
statementOffset = addPrologueDirectives(statements, body.statements, /*ensureUseStrict*/ false, visitor);
}
addCaptureThisForNodeIfNeeded(statements, node, enableSubstitutionsForCapturedThis);
addDefaultValueAssignmentsIfNeeded(statements, node, visitor, convertObjectRest);
addRestParameterIfNeeded(statements, node, /*inConstructorWithSynthesizedSuper*/ false);
// If we added any generated statements, this must be a multi-line block.
if (!multiLine && statements.length > 0) {
multiLine = true;
}
if (ts.isBlock(body)) {
statementsLocation = body.statements;
ts.addRange(statements, ts.visitNodes(body.statements, visitor, ts.isStatement, statementOffset));
// If the original body was a multi-line block, this must be a multi-line block.
if (!multiLine && body.multiLine) {
multiLine = true;
}
}
else {
ts.Debug.assert(node.kind === 185 /* ArrowFunction */);
// To align with the old emitter, we use a synthetic end position on the location
// for the statement list we synthesize when we down-level an arrow function with
// an expression function body. This prevents both comments and source maps from
// being emitted for the end position only.
statementsLocation = ts.moveRangeEnd(body, -1);
var equalsGreaterThanToken = node.equalsGreaterThanToken;
if (!ts.nodeIsSynthesized(equalsGreaterThanToken) && !ts.nodeIsSynthesized(body)) {
if (ts.rangeEndIsOnSameLineAsRangeStart(equalsGreaterThanToken, body, currentSourceFile)) {
singleLine = true;
}
else {
multiLine = true;
}
}
var expression = ts.visitNode(body, visitor, ts.isExpression);
var returnStatement = createReturn(expression, /*location*/ body);
setEmitFlags(returnStatement, 12288 /* NoTokenSourceMaps */ | 1024 /* NoTrailingSourceMap */ | 32768 /* NoTrailingComments */);
statements.push(returnStatement);
// To align with the source map emit for the old emitter, we set a custom
// source map location for the close brace.
closeBraceLocation = body;
}
var lexicalEnvironment = context.endLexicalEnvironment();
ts.addRange(statements, lexicalEnvironment);
// If we added any final generated statements, this must be a multi-line block
if (!multiLine && lexicalEnvironment && lexicalEnvironment.length) {
multiLine = true;
}
var block = createBlock(createNodeArray(statements, statementsLocation), node.body, multiLine);
if (!multiLine && singleLine) {
setEmitFlags(block, 32 /* SingleLine */);
}
if (closeBraceLocation) {
setTokenSourceMapRange(block, 17 /* CloseBraceToken */, closeBraceLocation);
}
setOriginalNode(block, node.body);
return block;
}
ts.transformFunctionBody = transformFunctionBody;
/**
* Adds a statement to capture the `this` of a function declaration if it is needed.
*
* @param statements The statements for the new function body.
* @param node A node.
*/
function addCaptureThisForNodeIfNeeded(statements, node, enableSubstitutionsForCapturedThis) {
if (node.transformFlags & 524288 /* ContainsCapturedLexicalThis */ && node.kind !== 185 /* ArrowFunction */) {
captureThisForNode(statements, node, createThis(), enableSubstitutionsForCapturedThis);
}
}
ts.addCaptureThisForNodeIfNeeded = addCaptureThisForNodeIfNeeded;
function captureThisForNode(statements, node, initializer, enableSubstitutionsForCapturedThis, originalStatement) {
enableSubstitutionsForCapturedThis();
var captureThisStatement = createVariableStatement(
/*modifiers*/ undefined, createVariableDeclarationList([
createVariableDeclaration("_this",
/*type*/ undefined, initializer)
]), originalStatement);
setEmitFlags(captureThisStatement, 49152 /* NoComments */ | 8388608 /* CustomPrologue */);
setSourceMapRange(captureThisStatement, node);
statements.push(captureThisStatement);
}
ts.captureThisForNode = captureThisForNode;
/**
* Gets a value indicating whether we need to add default value assignments for a
* function-like node.
*
* @param node A function-like node.
*/
function shouldAddDefaultValueAssignments(node) {
return (node.transformFlags & 2097152 /* ContainsDefaultValueAssignments */) !== 0;
}
/**
* Adds statements to the body of a function-like node if it contains parameters with
* binding patterns or initializers.
*
* @param statements The statements for the new function body.
* @param node A function-like node.
*/
function addDefaultValueAssignmentsIfNeeded(statements, node, visitor, convertObjectRest) {
if (!shouldAddDefaultValueAssignments(node)) {
return;
}
for (var _i = 0, _a = node.parameters; _i < _a.length; _i++) {
var parameter = _a[_i];
var name_13 = parameter.name, initializer = parameter.initializer, dotDotDotToken = parameter.dotDotDotToken;
// A rest parameter cannot have a binding pattern or an initializer,
// so let's just ignore it.
if (dotDotDotToken) {
continue;
}
if (ts.isBindingPattern(name_13)) {
addDefaultValueAssignmentForBindingPattern(statements, parameter, name_13, initializer, visitor, convertObjectRest);
}
else if (initializer) {
addDefaultValueAssignmentForInitializer(statements, parameter, name_13, initializer, visitor);
}
}
}
ts.addDefaultValueAssignmentsIfNeeded = addDefaultValueAssignmentsIfNeeded;
/**
* Adds statements to the body of a function-like node for parameters with binding patterns
*
* @param statements The statements for the new function body.
* @param parameter The parameter for the function.
* @param name The name of the parameter.
* @param initializer The initializer for the parameter.
*/
function addDefaultValueAssignmentForBindingPattern(statements, parameter, name, initializer, visitor, convertObjectRest) {
var temp = getGeneratedNameForNode(parameter);
// In cases where a binding pattern is simply '[]' or '{}',
// we usually don't want to emit a var declaration; however, in the presence
// of an initializer, we must emit that expression to preserve side effects.
if (name.elements.length > 0) {
statements.push(setEmitFlags(createVariableStatement(
/*modifiers*/ undefined, createVariableDeclarationList(ts.flattenParameterDestructuring(parameter, temp, visitor, convertObjectRest))), 8388608 /* CustomPrologue */));
}
else if (initializer) {
statements.push(setEmitFlags(createStatement(createAssignment(temp, ts.visitNode(initializer, visitor, ts.isExpression))), 8388608 /* CustomPrologue */));
}
}
/**
* Adds statements to the body of a function-like node for parameters with initializers.
*
* @param statements The statements for the new function body.
* @param parameter The parameter for the function.
* @param name The name of the parameter.
* @param initializer The initializer for the parameter.
*/
function addDefaultValueAssignmentForInitializer(statements, parameter, name, initializer, visitor) {
initializer = ts.visitNode(initializer, visitor, ts.isExpression);
var statement = createIf(createStrictEquality(getSynthesizedClone(name), createVoidZero()), setEmitFlags(createBlock([
createStatement(createAssignment(setEmitFlags(getMutableClone(name), 1536 /* NoSourceMap */), setEmitFlags(initializer, 1536 /* NoSourceMap */ | getEmitFlags(initializer)),
/*location*/ parameter))
], /*location*/ parameter), 32 /* SingleLine */ | 1024 /* NoTrailingSourceMap */ | 12288 /* NoTokenSourceMaps */),
/*elseStatement*/ undefined,
/*location*/ parameter);
statement.startsOnNewLine = true;
setEmitFlags(statement, 12288 /* NoTokenSourceMaps */ | 1024 /* NoTrailingSourceMap */ | 8388608 /* CustomPrologue */);
statements.push(statement);
}
/**
* Gets a value indicating whether we need to add statements to handle a rest parameter.
*
* @param node A ParameterDeclaration node.
* @param inConstructorWithSynthesizedSuper A value indicating whether the parameter is
* part of a constructor declaration with a
* synthesized call to `super`
*/
function shouldAddRestParameter(node, inConstructorWithSynthesizedSuper) {
return node && node.dotDotDotToken && node.name.kind === 70 /* Identifier */ && !inConstructorWithSynthesizedSuper;
}
/**
* Adds statements to the body of a function-like node if it contains a rest parameter.
*
* @param statements The statements for the new function body.
* @param node A function-like node.
* @param inConstructorWithSynthesizedSuper A value indicating whether the parameter is
* part of a constructor declaration with a
* synthesized call to `super`
*/
function addRestParameterIfNeeded(statements, node, inConstructorWithSynthesizedSuper) {
var parameter = ts.lastOrUndefined(node.parameters);
if (!shouldAddRestParameter(parameter, inConstructorWithSynthesizedSuper)) {
return;
}
// `declarationName` is the name of the local declaration for the parameter.
var declarationName = getMutableClone(parameter.name);
setEmitFlags(declarationName, 1536 /* NoSourceMap */);
// `expressionName` is the name of the parameter used in expressions.
var expressionName = getSynthesizedClone(parameter.name);
var restIndex = node.parameters.length - 1;
var temp = createLoopVariable();
// var param = [];
statements.push(setEmitFlags(createVariableStatement(
/*modifiers*/ undefined, createVariableDeclarationList([
createVariableDeclaration(declarationName,
/*type*/ undefined, createArrayLiteral([]))
]),
/*location*/ parameter), 8388608 /* CustomPrologue */));
// for (var _i = restIndex; _i < arguments.length; _i++) {
// param[_i - restIndex] = arguments[_i];
// }
var forStatement = createFor(createVariableDeclarationList([
createVariableDeclaration(temp, /*type*/ undefined, createLiteral(restIndex))
], /*location*/ parameter), createLessThan(temp, createPropertyAccess(createIdentifier("arguments"), "length"),
/*location*/ parameter), createPostfixIncrement(temp, /*location*/ parameter), createBlock([
startOnNewLine(createStatement(createAssignment(createElementAccess(expressionName, createSubtract(temp, createLiteral(restIndex))), createElementAccess(createIdentifier("arguments"), temp)),
/*location*/ parameter))
]));
setEmitFlags(forStatement, 8388608 /* CustomPrologue */);
startOnNewLine(forStatement);
statements.push(forStatement);
}
ts.addRestParameterIfNeeded = addRestParameterIfNeeded;
function convertForOf(node, convertedLoopBodyStatements, visitor, enableSubstitutionsForBlockScopedBindings, context, convertObjectRest) {
// The following ES6 code:
//
// for (let v of expr) { }
//
// should be emitted as
//
// for (var _i = 0, _a = expr; _i < _a.length; _i++) {
// var v = _a[_i];
// }
//
// where _a and _i are temps emitted to capture the RHS and the counter,
// respectively.
// When the left hand side is an expression instead of a let declaration,
// the "let v" is not emitted.
// When the left hand side is a let/const, the v is renamed if there is
// another v in scope.
// Note that all assignments to the LHS are emitted in the body, including
// all destructuring.
// Note also that because an extra statement is needed to assign to the LHS,
// for-of bodies are always emitted as blocks.
var expression = ts.visitNode(node.expression, visitor, ts.isExpression);
var initializer = node.initializer;
var statements = [];
// In the case where the user wrote an identifier as the RHS, like this:
//
// for (let v of arr) { }
//
// we don't want to emit a temporary variable for the RHS, just use it directly.
var counter = convertObjectRest ? undefined : createLoopVariable();
var rhsReference = expression.kind === 70 /* Identifier */
? createUniqueName(expression.text)
: createTempVariable(/*recordTempVariable*/ undefined);
var elementAccess = convertObjectRest ? rhsReference : createElementAccess(rhsReference, counter);
// Initialize LHS
// var v = _a[_i];
if (ts.isVariableDeclarationList(initializer)) {
if (initializer.flags & 3 /* BlockScoped */) {
enableSubstitutionsForBlockScopedBindings();
}
var firstOriginalDeclaration = ts.firstOrUndefined(initializer.declarations);
if (firstOriginalDeclaration && ts.isBindingPattern(firstOriginalDeclaration.name)) {
// This works whether the declaration is a var, let, or const.
// It will use rhsIterationValue _a[_i] as the initializer.
var declarations = ts.flattenVariableDestructuring(firstOriginalDeclaration, elementAccess, visitor,
/*recordTempVariable*/ undefined, convertObjectRest);
var declarationList = createVariableDeclarationList(declarations, /*location*/ initializer);
setOriginalNode(declarationList, initializer);
// Adjust the source map range for the first declaration to align with the old
// emitter.
var firstDeclaration = declarations[0];
var lastDeclaration = ts.lastOrUndefined(declarations);
setSourceMapRange(declarationList, ts.createRange(firstDeclaration.pos, lastDeclaration.end));
statements.push(createVariableStatement(
/*modifiers*/ undefined, declarationList));
}
else {
// The following call does not include the initializer, so we have
// to emit it separately.
statements.push(createVariableStatement(
/*modifiers*/ undefined, setOriginalNode(createVariableDeclarationList([
createVariableDeclaration(firstOriginalDeclaration ? firstOriginalDeclaration.name : createTempVariable(/*recordTempVariable*/ undefined),
/*type*/ undefined, createElementAccess(rhsReference, counter))
], /*location*/ ts.moveRangePos(initializer, -1)), initializer),
/*location*/ ts.moveRangeEnd(initializer, -1)));
}
}
else {
// Initializer is an expression. Emit the expression in the body, so that it's
// evaluated on every iteration.
var assignment = createAssignment(initializer, elementAccess);
if (ts.isDestructuringAssignment(assignment)) {
// This is a destructuring pattern, so we flatten the destructuring instead.
statements.push(createStatement(ts.flattenDestructuringAssignment(context, assignment,
/*needsValue*/ false, context.hoistVariableDeclaration, visitor, convertObjectRest)));
}
else {
// Currently there is not way to check that assignment is binary expression of destructing assignment
// so we have to cast never type to binaryExpression
assignment.end = initializer.end;
statements.push(createStatement(assignment, /*location*/ ts.moveRangeEnd(initializer, -1)));
}
}
var bodyLocation;
var statementsLocation;
if (convertedLoopBodyStatements) {
ts.addRange(statements, convertedLoopBodyStatements);
}
else {
var statement = ts.visitNode(node.statement, visitor, ts.isStatement);
if (ts.isBlock(statement)) {
ts.addRange(statements, statement.statements);
bodyLocation = statement;
statementsLocation = statement.statements;
}
else {
statements.push(statement);
}
}
// The old emitter does not emit source maps for the expression
setEmitFlags(expression, 1536 /* NoSourceMap */ | getEmitFlags(expression));
// The old emitter does not emit source maps for the block.
// We add the location to preserve comments.
var body = createBlock(createNodeArray(statements, /*location*/ statementsLocation),
/*location*/ bodyLocation);
setEmitFlags(body, 1536 /* NoSourceMap */ | 12288 /* NoTokenSourceMaps */);
var forStatement;
if (convertObjectRest) {
forStatement = createForOf(createVariableDeclarationList([
createVariableDeclaration(rhsReference, /*type*/ undefined, /*initializer*/ undefined, /*location*/ node.expression)
], /*location*/ node.expression), node.expression, body,
/*location*/ node);
}
else {
forStatement = createFor(setEmitFlags(createVariableDeclarationList([
createVariableDeclaration(counter, /*type*/ undefined, createLiteral(0), /*location*/ ts.moveRangePos(node.expression, -1)),
createVariableDeclaration(rhsReference, /*type*/ undefined, expression, /*location*/ node.expression)
], /*location*/ node.expression), 16777216 /* NoHoisting */), createLessThan(counter, createPropertyAccess(rhsReference, "length"),
/*location*/ node.expression), createPostfixIncrement(counter, /*location*/ node.expression), body,
/*location*/ node);
}
// Disable trailing source maps for the OpenParenToken to align source map emit with the old emitter.
setEmitFlags(forStatement, 8192 /* NoTokenTrailingSourceMaps */);
return forStatement;
}
ts.convertForOf = convertForOf;
})(ts || (ts = {}));
/// <reference path="utilities.ts"/>
/// <reference path="scanner.ts"/>
/// <reference path="factory.ts"/>
var ts;
(function (ts) {
var NodeConstructor;
var TokenConstructor;
var IdentifierConstructor;
var SourceFileConstructor;
function createNode(kind, pos, end) {
if (kind === 261 /* SourceFile */) {
return new (SourceFileConstructor || (SourceFileConstructor = ts.objectAllocator.getSourceFileConstructor()))(kind, pos, end);
}
else if (kind === 70 /* Identifier */) {
return new (IdentifierConstructor || (IdentifierConstructor = ts.objectAllocator.getIdentifierConstructor()))(kind, pos, end);
}
else if (kind < 141 /* FirstNode */) {
return new (TokenConstructor || (TokenConstructor = ts.objectAllocator.getTokenConstructor()))(kind, pos, end);
}
else {
return new (NodeConstructor || (NodeConstructor = ts.objectAllocator.getNodeConstructor()))(kind, pos, end);
}
}
ts.createNode = createNode;
function visitNode(cbNode, node) {
if (node) {
return cbNode(node);
}
}
function visitNodeArray(cbNodes, nodes) {
if (nodes) {
return cbNodes(nodes);
}
}
function visitEachNode(cbNode, nodes) {
if (nodes) {
for (var _i = 0, nodes_1 = nodes; _i < nodes_1.length; _i++) {
var node = nodes_1[_i];
var result = cbNode(node);
if (result) {
return result;
}
}
}
}
// Invokes a callback for each child of the given node. The 'cbNode' callback is invoked for all child nodes
// stored in properties. If a 'cbNodes' callback is specified, it is invoked for embedded arrays; otherwise,
// embedded arrays are flattened and the 'cbNode' callback is invoked for each element. If a callback returns
// a truthy value, iteration stops and that value is returned. Otherwise, undefined is returned.
function forEachChild(node, cbNode, cbNodeArray) {
if (!node) {
return;
}
// The visitXXX functions could be written as local functions that close over the cbNode and cbNodeArray
// callback parameters, but that causes a closure allocation for each invocation with noticeable effects
// on performance.
var visitNodes = cbNodeArray ? visitNodeArray : visitEachNode;
var cbNodes = cbNodeArray || cbNode;
switch (node.kind) {
case 141 /* QualifiedName */:
return visitNode(cbNode, node.left) ||
visitNode(cbNode, node.right);
case 143 /* TypeParameter */:
return visitNode(cbNode, node.name) ||
visitNode(cbNode, node.constraint) ||
visitNode(cbNode, node.expression);
case 258 /* ShorthandPropertyAssignment */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.name) ||
visitNode(cbNode, node.questionToken) ||
visitNode(cbNode, node.equalsToken) ||
visitNode(cbNode, node.objectAssignmentInitializer);
case 259 /* SpreadAssignment */:
return visitNode(cbNode, node.expression);
case 144 /* Parameter */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 257 /* PropertyAssignment */:
case 223 /* VariableDeclaration */:
case 174 /* BindingElement */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.propertyName) ||
visitNode(cbNode, node.dotDotDotToken) ||
visitNode(cbNode, node.name) ||
visitNode(cbNode, node.questionToken) ||
visitNode(cbNode, node.type) ||
visitNode(cbNode, node.initializer);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNodes(cbNodes, node.typeParameters) ||
visitNodes(cbNodes, node.parameters) ||
visitNode(cbNode, node.type);
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
case 185 /* ArrowFunction */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.asteriskToken) ||
visitNode(cbNode, node.name) ||
visitNode(cbNode, node.questionToken) ||
visitNodes(cbNodes, node.typeParameters) ||
visitNodes(cbNodes, node.parameters) ||
visitNode(cbNode, node.type) ||
visitNode(cbNode, node.equalsGreaterThanToken) ||
visitNode(cbNode, node.body);
case 157 /* TypeReference */:
return visitNode(cbNode, node.typeName) ||
visitNodes(cbNodes, node.typeArguments);
case 156 /* TypePredicate */:
return visitNode(cbNode, node.parameterName) ||
visitNode(cbNode, node.type);
case 160 /* TypeQuery */:
return visitNode(cbNode, node.exprName);
case 161 /* TypeLiteral */:
return visitNodes(cbNodes, node.members);
case 162 /* ArrayType */:
return visitNode(cbNode, node.elementType);
case 163 /* TupleType */:
return visitNodes(cbNodes, node.elementTypes);
case 164 /* UnionType */:
case 165 /* IntersectionType */:
return visitNodes(cbNodes, node.types);
case 166 /* ParenthesizedType */:
case 168 /* TypeOperator */:
return visitNode(cbNode, node.type);
case 169 /* IndexedAccessType */:
return visitNode(cbNode, node.objectType) ||
visitNode(cbNode, node.indexType);
case 170 /* MappedType */:
return visitNode(cbNode, node.readonlyToken) ||
visitNode(cbNode, node.typeParameter) ||
visitNode(cbNode, node.questionToken) ||
visitNode(cbNode, node.type);
case 171 /* LiteralType */:
return visitNode(cbNode, node.literal);
case 172 /* ObjectBindingPattern */:
case 173 /* ArrayBindingPattern */:
return visitNodes(cbNodes, node.elements);
case 175 /* ArrayLiteralExpression */:
return visitNodes(cbNodes, node.elements);
case 176 /* ObjectLiteralExpression */:
return visitNodes(cbNodes, node.properties);
case 177 /* PropertyAccessExpression */:
return visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.name);
case 178 /* ElementAccessExpression */:
return visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.argumentExpression);
case 179 /* CallExpression */:
case 180 /* NewExpression */:
return visitNode(cbNode, node.expression) ||
visitNodes(cbNodes, node.typeArguments) ||
visitNodes(cbNodes, node.arguments);
case 181 /* TaggedTemplateExpression */:
return visitNode(cbNode, node.tag) ||
visitNode(cbNode, node.template);
case 182 /* TypeAssertionExpression */:
return visitNode(cbNode, node.type) ||
visitNode(cbNode, node.expression);
case 183 /* ParenthesizedExpression */:
return visitNode(cbNode, node.expression);
case 186 /* DeleteExpression */:
return visitNode(cbNode, node.expression);
case 187 /* TypeOfExpression */:
return visitNode(cbNode, node.expression);
case 188 /* VoidExpression */:
return visitNode(cbNode, node.expression);
case 190 /* PrefixUnaryExpression */:
return visitNode(cbNode, node.operand);
case 195 /* YieldExpression */:
return visitNode(cbNode, node.asteriskToken) ||
visitNode(cbNode, node.expression);
case 189 /* AwaitExpression */:
return visitNode(cbNode, node.expression);
case 191 /* PostfixUnaryExpression */:
return visitNode(cbNode, node.operand);
case 192 /* BinaryExpression */:
return visitNode(cbNode, node.left) ||
visitNode(cbNode, node.operatorToken) ||
visitNode(cbNode, node.right);
case 200 /* AsExpression */:
return visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.type);
case 201 /* NonNullExpression */:
return visitNode(cbNode, node.expression);
case 193 /* ConditionalExpression */:
return visitNode(cbNode, node.condition) ||
visitNode(cbNode, node.questionToken) ||
visitNode(cbNode, node.whenTrue) ||
visitNode(cbNode, node.colonToken) ||
visitNode(cbNode, node.whenFalse);
case 196 /* SpreadElement */:
return visitNode(cbNode, node.expression);
case 204 /* Block */:
case 231 /* ModuleBlock */:
return visitNodes(cbNodes, node.statements);
case 261 /* SourceFile */:
return visitNodes(cbNodes, node.statements) ||
visitNode(cbNode, node.endOfFileToken);
case 205 /* VariableStatement */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.declarationList);
case 224 /* VariableDeclarationList */:
return visitNodes(cbNodes, node.declarations);
case 207 /* ExpressionStatement */:
return visitNode(cbNode, node.expression);
case 208 /* IfStatement */:
return visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.thenStatement) ||
visitNode(cbNode, node.elseStatement);
case 209 /* DoStatement */:
return visitNode(cbNode, node.statement) ||
visitNode(cbNode, node.expression);
case 210 /* WhileStatement */:
return visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.statement);
case 211 /* ForStatement */:
return visitNode(cbNode, node.initializer) ||
visitNode(cbNode, node.condition) ||
visitNode(cbNode, node.incrementor) ||
visitNode(cbNode, node.statement);
case 212 /* ForInStatement */:
return visitNode(cbNode, node.initializer) ||
visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.statement);
case 213 /* ForOfStatement */:
return visitNode(cbNode, node.initializer) ||
visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.statement);
case 214 /* ContinueStatement */:
case 215 /* BreakStatement */:
return visitNode(cbNode, node.label);
case 216 /* ReturnStatement */:
return visitNode(cbNode, node.expression);
case 217 /* WithStatement */:
return visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.statement);
case 218 /* SwitchStatement */:
return visitNode(cbNode, node.expression) ||
visitNode(cbNode, node.caseBlock);
case 232 /* CaseBlock */:
return visitNodes(cbNodes, node.clauses);
case 253 /* CaseClause */:
return visitNode(cbNode, node.expression) ||
visitNodes(cbNodes, node.statements);
case 254 /* DefaultClause */:
return visitNodes(cbNodes, node.statements);
case 219 /* LabeledStatement */:
return visitNode(cbNode, node.label) ||
visitNode(cbNode, node.statement);
case 220 /* ThrowStatement */:
return visitNode(cbNode, node.expression);
case 221 /* TryStatement */:
return visitNode(cbNode, node.tryBlock) ||
visitNode(cbNode, node.catchClause) ||
visitNode(cbNode, node.finallyBlock);
case 256 /* CatchClause */:
return visitNode(cbNode, node.variableDeclaration) ||
visitNode(cbNode, node.block);
case 145 /* Decorator */:
return visitNode(cbNode, node.expression);
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.name) ||
visitNodes(cbNodes, node.typeParameters) ||
visitNodes(cbNodes, node.heritageClauses) ||
visitNodes(cbNodes, node.members);
case 227 /* InterfaceDeclaration */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.name) ||
visitNodes(cbNodes, node.typeParameters) ||
visitNodes(cbNodes, node.heritageClauses) ||
visitNodes(cbNodes, node.members);
case 228 /* TypeAliasDeclaration */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.name) ||
visitNodes(cbNodes, node.typeParameters) ||
visitNode(cbNode, node.type);
case 229 /* EnumDeclaration */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.name) ||
visitNodes(cbNodes, node.members);
case 260 /* EnumMember */:
return visitNode(cbNode, node.name) ||
visitNode(cbNode, node.initializer);
case 230 /* ModuleDeclaration */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.name) ||
visitNode(cbNode, node.body);
case 234 /* ImportEqualsDeclaration */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.name) ||
visitNode(cbNode, node.moduleReference);
case 235 /* ImportDeclaration */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.importClause) ||
visitNode(cbNode, node.moduleSpecifier);
case 236 /* ImportClause */:
return visitNode(cbNode, node.name) ||
visitNode(cbNode, node.namedBindings);
case 233 /* NamespaceExportDeclaration */:
return visitNode(cbNode, node.name);
case 237 /* NamespaceImport */:
return visitNode(cbNode, node.name);
case 238 /* NamedImports */:
case 242 /* NamedExports */:
return visitNodes(cbNodes, node.elements);
case 241 /* ExportDeclaration */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.exportClause) ||
visitNode(cbNode, node.moduleSpecifier);
case 239 /* ImportSpecifier */:
case 243 /* ExportSpecifier */:
return visitNode(cbNode, node.propertyName) ||
visitNode(cbNode, node.name);
case 240 /* ExportAssignment */:
return visitNodes(cbNodes, node.decorators) ||
visitNodes(cbNodes, node.modifiers) ||
visitNode(cbNode, node.expression);
case 194 /* TemplateExpression */:
return visitNode(cbNode, node.head) || visitNodes(cbNodes, node.templateSpans);
case 202 /* TemplateSpan */:
return visitNode(cbNode, node.expression) || visitNode(cbNode, node.literal);
case 142 /* ComputedPropertyName */:
return visitNode(cbNode, node.expression);
case 255 /* HeritageClause */:
return visitNodes(cbNodes, node.types);
case 199 /* ExpressionWithTypeArguments */:
return visitNode(cbNode, node.expression) ||
visitNodes(cbNodes, node.typeArguments);
case 245 /* ExternalModuleReference */:
return visitNode(cbNode, node.expression);
case 244 /* MissingDeclaration */:
return visitNodes(cbNodes, node.decorators);
case 246 /* JsxElement */:
return visitNode(cbNode, node.openingElement) ||
visitNodes(cbNodes, node.children) ||
visitNode(cbNode, node.closingElement);
case 247 /* JsxSelfClosingElement */:
case 248 /* JsxOpeningElement */:
return visitNode(cbNode, node.tagName) ||
visitNodes(cbNodes, node.attributes);
case 250 /* JsxAttribute */:
return visitNode(cbNode, node.name) ||
visitNode(cbNode, node.initializer);
case 251 /* JsxSpreadAttribute */:
return visitNode(cbNode, node.expression);
case 252 /* JsxExpression */:
return visitNode(cbNode, node.expression);
case 249 /* JsxClosingElement */:
return visitNode(cbNode, node.tagName);
case 262 /* JSDocTypeExpression */:
return visitNode(cbNode, node.type);
case 266 /* JSDocUnionType */:
return visitNodes(cbNodes, node.types);
case 267 /* JSDocTupleType */:
return visitNodes(cbNodes, node.types);
case 265 /* JSDocArrayType */:
return visitNode(cbNode, node.elementType);
case 269 /* JSDocNonNullableType */:
return visitNode(cbNode, node.type);
case 268 /* JSDocNullableType */:
return visitNode(cbNode, node.type);
case 270 /* JSDocRecordType */:
return visitNode(cbNode, node.literal);
case 272 /* JSDocTypeReference */:
return visitNode(cbNode, node.name) ||
visitNodes(cbNodes, node.typeArguments);
case 273 /* JSDocOptionalType */:
return visitNode(cbNode, node.type);
case 274 /* JSDocFunctionType */:
return visitNodes(cbNodes, node.parameters) ||
visitNode(cbNode, node.type);
case 275 /* JSDocVariadicType */:
return visitNode(cbNode, node.type);
case 276 /* JSDocConstructorType */:
return visitNode(cbNode, node.type);
case 277 /* JSDocThisType */:
return visitNode(cbNode, node.type);
case 271 /* JSDocRecordMember */:
return visitNode(cbNode, node.name) ||
visitNode(cbNode, node.type);
case 278 /* JSDocComment */:
return visitNodes(cbNodes, node.tags);
case 280 /* JSDocParameterTag */:
return visitNode(cbNode, node.preParameterName) ||
visitNode(cbNode, node.typeExpression) ||
visitNode(cbNode, node.postParameterName);
case 281 /* JSDocReturnTag */:
return visitNode(cbNode, node.typeExpression);
case 282 /* JSDocTypeTag */:
return visitNode(cbNode, node.typeExpression);
case 283 /* JSDocTemplateTag */:
return visitNodes(cbNodes, node.typeParameters);
case 284 /* JSDocTypedefTag */:
return visitNode(cbNode, node.typeExpression) ||
visitNode(cbNode, node.fullName) ||
visitNode(cbNode, node.name) ||
visitNode(cbNode, node.jsDocTypeLiteral);
case 286 /* JSDocTypeLiteral */:
return visitNodes(cbNodes, node.jsDocPropertyTags);
case 285 /* JSDocPropertyTag */:
return visitNode(cbNode, node.typeExpression) ||
visitNode(cbNode, node.name);
case 293 /* PartiallyEmittedExpression */:
return visitNode(cbNode, node.expression);
case 287 /* JSDocLiteralType */:
return visitNode(cbNode, node.literal);
}
}
ts.forEachChild = forEachChild;
function createSourceFile(fileName, sourceText, languageVersion, setParentNodes, scriptKind) {
if (setParentNodes === void 0) { setParentNodes = false; }
ts.performance.mark("beforeParse");
var result = Parser.parseSourceFile(fileName, sourceText, languageVersion, /*syntaxCursor*/ undefined, setParentNodes, scriptKind);
ts.performance.mark("afterParse");
ts.performance.measure("Parse", "beforeParse", "afterParse");
return result;
}
ts.createSourceFile = createSourceFile;
function parseIsolatedEntityName(text, languageVersion) {
return Parser.parseIsolatedEntityName(text, languageVersion);
}
ts.parseIsolatedEntityName = parseIsolatedEntityName;
function isExternalModule(file) {
return file.externalModuleIndicator !== undefined;
}
ts.isExternalModule = isExternalModule;
// Produces a new SourceFile for the 'newText' provided. The 'textChangeRange' parameter
// indicates what changed between the 'text' that this SourceFile has and the 'newText'.
// The SourceFile will be created with the compiler attempting to reuse as many nodes from
// this file as possible.
//
// Note: this function mutates nodes from this SourceFile. That means any existing nodes
// from this SourceFile that are being held onto may change as a result (including
// becoming detached from any SourceFile). It is recommended that this SourceFile not
// be used once 'update' is called on it.
function updateSourceFile(sourceFile, newText, textChangeRange, aggressiveChecks) {
return IncrementalParser.updateSourceFile(sourceFile, newText, textChangeRange, aggressiveChecks);
}
ts.updateSourceFile = updateSourceFile;
/* @internal */
function parseIsolatedJSDocComment(content, start, length) {
var result = Parser.JSDocParser.parseIsolatedJSDocComment(content, start, length);
if (result && result.jsDoc) {
// because the jsDocComment was parsed out of the source file, it might
// not be covered by the fixupParentReferences.
Parser.fixupParentReferences(result.jsDoc);
}
return result;
}
ts.parseIsolatedJSDocComment = parseIsolatedJSDocComment;
/* @internal */
// Exposed only for testing.
function parseJSDocTypeExpressionForTests(content, start, length) {
return Parser.JSDocParser.parseJSDocTypeExpressionForTests(content, start, length);
}
ts.parseJSDocTypeExpressionForTests = parseJSDocTypeExpressionForTests;
// Implement the parser as a singleton module. We do this for perf reasons because creating
// parser instances can actually be expensive enough to impact us on projects with many source
// files.
var Parser;
(function (Parser) {
// Share a single scanner across all calls to parse a source file. This helps speed things
// up by avoiding the cost of creating/compiling scanners over and over again.
var scanner = ts.createScanner(5 /* Latest */, /*skipTrivia*/ true);
var disallowInAndDecoratorContext = 65536 /* DisallowInContext */ | 262144 /* DecoratorContext */;
// capture constructors in 'initializeState' to avoid null checks
var NodeConstructor;
var TokenConstructor;
var IdentifierConstructor;
var SourceFileConstructor;
var sourceFile;
var parseDiagnostics;
var syntaxCursor;
var currentToken;
var sourceText;
var nodeCount;
var identifiers;
var identifierCount;
var parsingContext;
// Flags that dictate what parsing context we're in. For example:
// Whether or not we are in strict parsing mode. All that changes in strict parsing mode is
// that some tokens that would be considered identifiers may be considered keywords.
//
// When adding more parser context flags, consider which is the more common case that the
// flag will be in. This should be the 'false' state for that flag. The reason for this is
// that we don't store data in our nodes unless the value is in the *non-default* state. So,
// for example, more often than code 'allows-in' (or doesn't 'disallow-in'). We opt for
// 'disallow-in' set to 'false'. Otherwise, if we had 'allowsIn' set to 'true', then almost
// all nodes would need extra state on them to store this info.
//
// Note: 'allowIn' and 'allowYield' track 1:1 with the [in] and [yield] concepts in the ES6
// grammar specification.
//
// An important thing about these context concepts. By default they are effectively inherited
// while parsing through every grammar production. i.e. if you don't change them, then when
// you parse a sub-production, it will have the same context values as the parent production.
// This is great most of the time. After all, consider all the 'expression' grammar productions
// and how nearly all of them pass along the 'in' and 'yield' context values:
//
// EqualityExpression[In, Yield] :
// RelationalExpression[?In, ?Yield]
// EqualityExpression[?In, ?Yield] == RelationalExpression[?In, ?Yield]
// EqualityExpression[?In, ?Yield] != RelationalExpression[?In, ?Yield]
// EqualityExpression[?In, ?Yield] === RelationalExpression[?In, ?Yield]
// EqualityExpression[?In, ?Yield] !== RelationalExpression[?In, ?Yield]
//
// Where you have to be careful is then understanding what the points are in the grammar
// where the values are *not* passed along. For example:
//
// SingleNameBinding[Yield,GeneratorParameter]
// [+GeneratorParameter]BindingIdentifier[Yield] Initializer[In]opt
// [~GeneratorParameter]BindingIdentifier[?Yield]Initializer[In, ?Yield]opt
//
// Here this is saying that if the GeneratorParameter context flag is set, that we should
// explicitly set the 'yield' context flag to false before calling into the BindingIdentifier
// and we should explicitly unset the 'yield' context flag before calling into the Initializer.
// production. Conversely, if the GeneratorParameter context flag is not set, then we
// should leave the 'yield' context flag alone.
//
// Getting this all correct is tricky and requires careful reading of the grammar to
// understand when these values should be changed versus when they should be inherited.
//
// Note: it should not be necessary to save/restore these flags during speculative/lookahead
// parsing. These context flags are naturally stored and restored through normal recursive
// descent parsing and unwinding.
var contextFlags;
// Whether or not we've had a parse error since creating the last AST node. If we have
// encountered an error, it will be stored on the next AST node we create. Parse errors
// can be broken down into three categories:
//
// 1) An error that occurred during scanning. For example, an unterminated literal, or a
// character that was completely not understood.
//
// 2) A token was expected, but was not present. This type of error is commonly produced
// by the 'parseExpected' function.
//
// 3) A token was present that no parsing function was able to consume. This type of error
// only occurs in the 'abortParsingListOrMoveToNextToken' function when the parser
// decides to skip the token.
//
// In all of these cases, we want to mark the next node as having had an error before it.
// With this mark, we can know in incremental settings if this node can be reused, or if
// we have to reparse it. If we don't keep this information around, we may just reuse the
// node. in that event we would then not produce the same errors as we did before, causing
// significant confusion problems.
//
// Note: it is necessary that this value be saved/restored during speculative/lookahead
// parsing. During lookahead parsing, we will often create a node. That node will have
// this value attached, and then this value will be set back to 'false'. If we decide to
// rewind, we must get back to the same value we had prior to the lookahead.
//
// Note: any errors at the end of the file that do not precede a regular node, should get
// attached to the EOF token.
var parseErrorBeforeNextFinishedNode = false;
function parseSourceFile(fileName, sourceText, languageVersion, syntaxCursor, setParentNodes, scriptKind) {
scriptKind = ts.ensureScriptKind(fileName, scriptKind);
initializeState(sourceText, languageVersion, syntaxCursor, scriptKind);
var result = parseSourceFileWorker(fileName, languageVersion, setParentNodes, scriptKind);
clearState();
return result;
}
Parser.parseSourceFile = parseSourceFile;
function parseIsolatedEntityName(content, languageVersion) {
initializeState(content, languageVersion, /*syntaxCursor*/ undefined, 1 /* JS */);
// Prime the scanner.
nextToken();
var entityName = parseEntityName(/*allowReservedWords*/ true);
var isInvalid = token() === 1 /* EndOfFileToken */ && !parseDiagnostics.length;
clearState();
return isInvalid ? entityName : undefined;
}
Parser.parseIsolatedEntityName = parseIsolatedEntityName;
function getLanguageVariant(scriptKind) {
// .tsx and .jsx files are treated as jsx language variant.
return scriptKind === 4 /* TSX */ || scriptKind === 2 /* JSX */ || scriptKind === 1 /* JS */ ? 1 /* JSX */ : 0 /* Standard */;
}
function initializeState(_sourceText, languageVersion, _syntaxCursor, scriptKind) {
NodeConstructor = ts.objectAllocator.getNodeConstructor();
TokenConstructor = ts.objectAllocator.getTokenConstructor();
IdentifierConstructor = ts.objectAllocator.getIdentifierConstructor();
SourceFileConstructor = ts.objectAllocator.getSourceFileConstructor();
sourceText = _sourceText;
syntaxCursor = _syntaxCursor;
parseDiagnostics = [];
parsingContext = 0;
identifiers = ts.createMap();
identifierCount = 0;
nodeCount = 0;
contextFlags = scriptKind === 1 /* JS */ || scriptKind === 2 /* JSX */ ? 2097152 /* JavaScriptFile */ : 0 /* None */;
parseErrorBeforeNextFinishedNode = false;
// Initialize and prime the scanner before parsing the source elements.
scanner.setText(sourceText);
scanner.setOnError(scanError);
scanner.setScriptTarget(languageVersion);
scanner.setLanguageVariant(getLanguageVariant(scriptKind));
}
function clearState() {
// Clear out the text the scanner is pointing at, so it doesn't keep anything alive unnecessarily.
scanner.setText("");
scanner.setOnError(undefined);
// Clear any data. We don't want to accidentally hold onto it for too long.
parseDiagnostics = undefined;
sourceFile = undefined;
identifiers = undefined;
syntaxCursor = undefined;
sourceText = undefined;
}
function parseSourceFileWorker(fileName, languageVersion, setParentNodes, scriptKind) {
sourceFile = createSourceFile(fileName, languageVersion, scriptKind);
sourceFile.flags = contextFlags;
// Prime the scanner.
nextToken();
processReferenceComments(sourceFile);
sourceFile.statements = parseList(0 /* SourceElements */, parseStatement);
ts.Debug.assert(token() === 1 /* EndOfFileToken */);
sourceFile.endOfFileToken = parseTokenNode();
setExternalModuleIndicator(sourceFile);
sourceFile.nodeCount = nodeCount;
sourceFile.identifierCount = identifierCount;
sourceFile.identifiers = identifiers;
sourceFile.parseDiagnostics = parseDiagnostics;
if (setParentNodes) {
fixupParentReferences(sourceFile);
}
return sourceFile;
}
function addJSDocComment(node) {
var comments = ts.getJsDocCommentsFromText(node, sourceFile.text);
if (comments) {
for (var _i = 0, comments_2 = comments; _i < comments_2.length; _i++) {
var comment = comments_2[_i];
var jsDoc = JSDocParser.parseJSDocComment(node, comment.pos, comment.end - comment.pos);
if (!jsDoc) {
continue;
}
if (!node.jsDocComments) {
node.jsDocComments = [];
}
node.jsDocComments.push(jsDoc);
}
}
return node;
}
function fixupParentReferences(rootNode) {
// normally parent references are set during binding. However, for clients that only need
// a syntax tree, and no semantic features, then the binding process is an unnecessary
// overhead. This functions allows us to set all the parents, without all the expense of
// binding.
var parent = rootNode;
forEachChild(rootNode, visitNode);
return;
function visitNode(n) {
// walk down setting parents that differ from the parent we think it should be. This
// allows us to quickly bail out of setting parents for subtrees during incremental
// parsing
if (n.parent !== parent) {
n.parent = parent;
var saveParent = parent;
parent = n;
forEachChild(n, visitNode);
if (n.jsDocComments) {
for (var _i = 0, _a = n.jsDocComments; _i < _a.length; _i++) {
var jsDocComment = _a[_i];
jsDocComment.parent = n;
parent = jsDocComment;
forEachChild(jsDocComment, visitNode);
}
}
parent = saveParent;
}
}
}
Parser.fixupParentReferences = fixupParentReferences;
function createSourceFile(fileName, languageVersion, scriptKind) {
// code from createNode is inlined here so createNode won't have to deal with special case of creating source files
// this is quite rare comparing to other nodes and createNode should be as fast as possible
var sourceFile = new SourceFileConstructor(261 /* SourceFile */, /*pos*/ 0, /* end */ sourceText.length);
nodeCount++;
sourceFile.text = sourceText;
sourceFile.bindDiagnostics = [];
sourceFile.languageVersion = languageVersion;
sourceFile.fileName = ts.normalizePath(fileName);
sourceFile.languageVariant = getLanguageVariant(scriptKind);
sourceFile.isDeclarationFile = ts.fileExtensionIs(sourceFile.fileName, ".d.ts");
sourceFile.scriptKind = scriptKind;
return sourceFile;
}
function setContextFlag(val, flag) {
if (val) {
contextFlags |= flag;
}
else {
contextFlags &= ~flag;
}
}
function setDisallowInContext(val) {
setContextFlag(val, 65536 /* DisallowInContext */);
}
function setYieldContext(val) {
setContextFlag(val, 131072 /* YieldContext */);
}
function setDecoratorContext(val) {
setContextFlag(val, 262144 /* DecoratorContext */);
}
function setAwaitContext(val) {
setContextFlag(val, 524288 /* AwaitContext */);
}
function doOutsideOfContext(context, func) {
// contextFlagsToClear will contain only the context flags that are
// currently set that we need to temporarily clear
// We don't just blindly reset to the previous flags to ensure
// that we do not mutate cached flags for the incremental
// parser (ThisNodeHasError, ThisNodeOrAnySubNodesHasError, and
// HasAggregatedChildData).
var contextFlagsToClear = context & contextFlags;
if (contextFlagsToClear) {
// clear the requested context flags
setContextFlag(/*val*/ false, contextFlagsToClear);
var result = func();
// restore the context flags we just cleared
setContextFlag(/*val*/ true, contextFlagsToClear);
return result;
}
// no need to do anything special as we are not in any of the requested contexts
return func();
}
function doInsideOfContext(context, func) {
// contextFlagsToSet will contain only the context flags that
// are not currently set that we need to temporarily enable.
// We don't just blindly reset to the previous flags to ensure
// that we do not mutate cached flags for the incremental
// parser (ThisNodeHasError, ThisNodeOrAnySubNodesHasError, and
// HasAggregatedChildData).
var contextFlagsToSet = context & ~contextFlags;
if (contextFlagsToSet) {
// set the requested context flags
setContextFlag(/*val*/ true, contextFlagsToSet);
var result = func();
// reset the context flags we just set
setContextFlag(/*val*/ false, contextFlagsToSet);
return result;
}
// no need to do anything special as we are already in all of the requested contexts
return func();
}
function allowInAnd(func) {
return doOutsideOfContext(65536 /* DisallowInContext */, func);
}
function disallowInAnd(func) {
return doInsideOfContext(65536 /* DisallowInContext */, func);
}
function doInYieldContext(func) {
return doInsideOfContext(131072 /* YieldContext */, func);
}
function doInDecoratorContext(func) {
return doInsideOfContext(262144 /* DecoratorContext */, func);
}
function doInAwaitContext(func) {
return doInsideOfContext(524288 /* AwaitContext */, func);
}
function doOutsideOfAwaitContext(func) {
return doOutsideOfContext(524288 /* AwaitContext */, func);
}
function doInYieldAndAwaitContext(func) {
return doInsideOfContext(131072 /* YieldContext */ | 524288 /* AwaitContext */, func);
}
function inContext(flags) {
return (contextFlags & flags) !== 0;
}
function inYieldContext() {
return inContext(131072 /* YieldContext */);
}
function inDisallowInContext() {
return inContext(65536 /* DisallowInContext */);
}
function inDecoratorContext() {
return inContext(262144 /* DecoratorContext */);
}
function inAwaitContext() {
return inContext(524288 /* AwaitContext */);
}
function parseErrorAtCurrentToken(message, arg0) {
var start = scanner.getTokenPos();
var length = scanner.getTextPos() - start;
parseErrorAtPosition(start, length, message, arg0);
}
function parseErrorAtPosition(start, length, message, arg0) {
// Don't report another error if it would just be at the same position as the last error.
var lastError = ts.lastOrUndefined(parseDiagnostics);
if (!lastError || start !== lastError.start) {
parseDiagnostics.push(ts.createFileDiagnostic(sourceFile, start, length, message, arg0));
}
// Mark that we've encountered an error. We'll set an appropriate bit on the next
// node we finish so that it can't be reused incrementally.
parseErrorBeforeNextFinishedNode = true;
}
function scanError(message, length) {
var pos = scanner.getTextPos();
parseErrorAtPosition(pos, length || 0, message);
}
function getNodePos() {
return scanner.getStartPos();
}
function getNodeEnd() {
return scanner.getStartPos();
}
// Use this function to access the current token instead of reading the currentToken
// variable. Since function results aren't narrowed in control flow analysis, this ensures
// that the type checker doesn't make wrong assumptions about the type of the current
// token (e.g. a call to nextToken() changes the current token but the checker doesn't
// reason about this side effect). Mainstream VMs inline simple functions like this, so
// there is no performance penalty.
function token() {
return currentToken;
}
function nextToken() {
return currentToken = scanner.scan();
}
function reScanGreaterToken() {
return currentToken = scanner.reScanGreaterToken();
}
function reScanSlashToken() {
return currentToken = scanner.reScanSlashToken();
}
function reScanTemplateToken() {
return currentToken = scanner.reScanTemplateToken();
}
function scanJsxIdentifier() {
return currentToken = scanner.scanJsxIdentifier();
}
function scanJsxText() {
return currentToken = scanner.scanJsxToken();
}
function scanJsxAttributeValue() {
return currentToken = scanner.scanJsxAttributeValue();
}
function speculationHelper(callback, isLookAhead) {
// Keep track of the state we'll need to rollback to if lookahead fails (or if the
// caller asked us to always reset our state).
var saveToken = currentToken;
var saveParseDiagnosticsLength = parseDiagnostics.length;
var saveParseErrorBeforeNextFinishedNode = parseErrorBeforeNextFinishedNode;
// Note: it is not actually necessary to save/restore the context flags here. That's
// because the saving/restoring of these flags happens naturally through the recursive
// descent nature of our parser. However, we still store this here just so we can
// assert that invariant holds.
var saveContextFlags = contextFlags;
// If we're only looking ahead, then tell the scanner to only lookahead as well.
// Otherwise, if we're actually speculatively parsing, then tell the scanner to do the
// same.
var result = isLookAhead
? scanner.lookAhead(callback)
: scanner.tryScan(callback);
ts.Debug.assert(saveContextFlags === contextFlags);
// If our callback returned something 'falsy' or we're just looking ahead,
// then unconditionally restore us to where we were.
if (!result || isLookAhead) {
currentToken = saveToken;
parseDiagnostics.length = saveParseDiagnosticsLength;
parseErrorBeforeNextFinishedNode = saveParseErrorBeforeNextFinishedNode;
}
return result;
}
/** Invokes the provided callback then unconditionally restores the parser to the state it
* was in immediately prior to invoking the callback. The result of invoking the callback
* is returned from this function.
*/
function lookAhead(callback) {
return speculationHelper(callback, /*isLookAhead*/ true);
}
/** Invokes the provided callback. If the callback returns something falsy, then it restores
* the parser to the state it was in immediately prior to invoking the callback. If the
* callback returns something truthy, then the parser state is not rolled back. The result
* of invoking the callback is returned from this function.
*/
function tryParse(callback) {
return speculationHelper(callback, /*isLookAhead*/ false);
}
// Ignore strict mode flag because we will report an error in type checker instead.
function isIdentifier() {
if (token() === 70 /* Identifier */) {
return true;
}
// If we have a 'yield' keyword, and we're in the [yield] context, then 'yield' is
// considered a keyword and is not an identifier.
if (token() === 115 /* YieldKeyword */ && inYieldContext()) {
return false;
}
// If we have a 'await' keyword, and we're in the [Await] context, then 'await' is
// considered a keyword and is not an identifier.
if (token() === 120 /* AwaitKeyword */ && inAwaitContext()) {
return false;
}
return token() > 106 /* LastReservedWord */;
}
function parseExpected(kind, diagnosticMessage, shouldAdvance) {
if (shouldAdvance === void 0) { shouldAdvance = true; }
if (token() === kind) {
if (shouldAdvance) {
nextToken();
}
return true;
}
// Report specific message if provided with one. Otherwise, report generic fallback message.
if (diagnosticMessage) {
parseErrorAtCurrentToken(diagnosticMessage);
}
else {
parseErrorAtCurrentToken(ts.Diagnostics._0_expected, ts.tokenToString(kind));
}
return false;
}
function parseOptional(t) {
if (token() === t) {
nextToken();
return true;
}
return false;
}
function parseOptionalToken(t) {
if (token() === t) {
return parseTokenNode();
}
return undefined;
}
function parseExpectedToken(t, reportAtCurrentPosition, diagnosticMessage, arg0) {
return parseOptionalToken(t) ||
createMissingNode(t, reportAtCurrentPosition, diagnosticMessage, arg0);
}
function parseTokenNode() {
var node = createNode(token());
nextToken();
return finishNode(node);
}
function canParseSemicolon() {
// If there's a real semicolon, then we can always parse it out.
if (token() === 24 /* SemicolonToken */) {
return true;
}
// We can parse out an optional semicolon in ASI cases in the following cases.
return token() === 17 /* CloseBraceToken */ || token() === 1 /* EndOfFileToken */ || scanner.hasPrecedingLineBreak();
}
function parseSemicolon() {
if (canParseSemicolon()) {
if (token() === 24 /* SemicolonToken */) {
// consume the semicolon if it was explicitly provided.
nextToken();
}
return true;
}
else {
return parseExpected(24 /* SemicolonToken */);
}
}
// note: this function creates only node
function createNode(kind, pos) {
nodeCount++;
if (!(pos >= 0)) {
pos = scanner.getStartPos();
}
return kind >= 141 /* FirstNode */ ? new NodeConstructor(kind, pos, pos) :
kind === 70 /* Identifier */ ? new IdentifierConstructor(kind, pos, pos) :
new TokenConstructor(kind, pos, pos);
}
function createNodeArray(elements, pos) {
var array = (elements || []);
if (!(pos >= 0)) {
pos = getNodePos();
}
array.pos = pos;
array.end = pos;
return array;
}
function finishNode(node, end) {
node.end = end === undefined ? scanner.getStartPos() : end;
if (contextFlags) {
node.flags |= contextFlags;
}
// Keep track on the node if we encountered an error while parsing it. If we did, then
// we cannot reuse the node incrementally. Once we've marked this node, clear out the
// flag so that we don't mark any subsequent nodes.
if (parseErrorBeforeNextFinishedNode) {
parseErrorBeforeNextFinishedNode = false;
node.flags |= 1048576 /* ThisNodeHasError */;
}
return node;
}
function createMissingNode(kind, reportAtCurrentPosition, diagnosticMessage, arg0) {
if (reportAtCurrentPosition) {
parseErrorAtPosition(scanner.getStartPos(), 0, diagnosticMessage, arg0);
}
else {
parseErrorAtCurrentToken(diagnosticMessage, arg0);
}
var result = createNode(kind, scanner.getStartPos());
result.text = "";
return finishNode(result);
}
function internIdentifier(text) {
text = ts.escapeIdentifier(text);
return identifiers[text] || (identifiers[text] = text);
}
// An identifier that starts with two underscores has an extra underscore character prepended to it to avoid issues
// with magic property names like '__proto__'. The 'identifiers' object is used to share a single string instance for
// each identifier in order to reduce memory consumption.
function createIdentifier(isIdentifier, diagnosticMessage) {
identifierCount++;
if (isIdentifier) {
var node = createNode(70 /* Identifier */);
// Store original token kind if it is not just an Identifier so we can report appropriate error later in type checker
if (token() !== 70 /* Identifier */) {
node.originalKeywordKind = token();
}
node.text = internIdentifier(scanner.getTokenValue());
nextToken();
return finishNode(node);
}
return createMissingNode(70 /* Identifier */, /*reportAtCurrentPosition*/ false, diagnosticMessage || ts.Diagnostics.Identifier_expected);
}
function parseIdentifier(diagnosticMessage) {
return createIdentifier(isIdentifier(), diagnosticMessage);
}
function parseIdentifierName() {
return createIdentifier(ts.tokenIsIdentifierOrKeyword(token()));
}
function isLiteralPropertyName() {
return ts.tokenIsIdentifierOrKeyword(token()) ||
token() === 9 /* StringLiteral */ ||
token() === 8 /* NumericLiteral */;
}
function parsePropertyNameWorker(allowComputedPropertyNames) {
if (token() === 9 /* StringLiteral */ || token() === 8 /* NumericLiteral */) {
return parseLiteralNode(/*internName*/ true);
}
if (allowComputedPropertyNames && token() === 20 /* OpenBracketToken */) {
return parseComputedPropertyName();
}
return parseIdentifierName();
}
function parsePropertyName() {
return parsePropertyNameWorker(/*allowComputedPropertyNames*/ true);
}
function parseSimplePropertyName() {
return parsePropertyNameWorker(/*allowComputedPropertyNames*/ false);
}
function isSimplePropertyName() {
return token() === 9 /* StringLiteral */ || token() === 8 /* NumericLiteral */ || ts.tokenIsIdentifierOrKeyword(token());
}
function parseComputedPropertyName() {
// PropertyName [Yield]:
// LiteralPropertyName
// ComputedPropertyName[?Yield]
var node = createNode(142 /* ComputedPropertyName */);
parseExpected(20 /* OpenBracketToken */);
// We parse any expression (including a comma expression). But the grammar
// says that only an assignment expression is allowed, so the grammar checker
// will error if it sees a comma expression.
node.expression = allowInAnd(parseExpression);
parseExpected(21 /* CloseBracketToken */);
return finishNode(node);
}
function parseContextualModifier(t) {
return token() === t && tryParse(nextTokenCanFollowModifier);
}
function nextTokenIsOnSameLineAndCanFollowModifier() {
nextToken();
if (scanner.hasPrecedingLineBreak()) {
return false;
}
return canFollowModifier();
}
function nextTokenCanFollowModifier() {
if (token() === 75 /* ConstKeyword */) {
// 'const' is only a modifier if followed by 'enum'.
return nextToken() === 82 /* EnumKeyword */;
}
if (token() === 83 /* ExportKeyword */) {
nextToken();
if (token() === 78 /* DefaultKeyword */) {
return lookAhead(nextTokenIsClassOrFunctionOrAsync);
}
return token() !== 38 /* AsteriskToken */ && token() !== 117 /* AsKeyword */ && token() !== 16 /* OpenBraceToken */ && canFollowModifier();
}
if (token() === 78 /* DefaultKeyword */) {
return nextTokenIsClassOrFunctionOrAsync();
}
if (token() === 114 /* StaticKeyword */) {
nextToken();
return canFollowModifier();
}
return nextTokenIsOnSameLineAndCanFollowModifier();
}
function parseAnyContextualModifier() {
return ts.isModifierKind(token()) && tryParse(nextTokenCanFollowModifier);
}
function canFollowModifier() {
return token() === 20 /* OpenBracketToken */
|| token() === 16 /* OpenBraceToken */
|| token() === 38 /* AsteriskToken */
|| token() === 23 /* DotDotDotToken */
|| isLiteralPropertyName();
}
function nextTokenIsClassOrFunctionOrAsync() {
nextToken();
return token() === 74 /* ClassKeyword */ || token() === 88 /* FunctionKeyword */ ||
(token() === 119 /* AsyncKeyword */ && lookAhead(nextTokenIsFunctionKeywordOnSameLine));
}
// True if positioned at the start of a list element
function isListElement(parsingContext, inErrorRecovery) {
var node = currentNode(parsingContext);
if (node) {
return true;
}
switch (parsingContext) {
case 0 /* SourceElements */:
case 1 /* BlockStatements */:
case 3 /* SwitchClauseStatements */:
// If we're in error recovery, then we don't want to treat ';' as an empty statement.
// The problem is that ';' can show up in far too many contexts, and if we see one
// and assume it's a statement, then we may bail out inappropriately from whatever
// we're parsing. For example, if we have a semicolon in the middle of a class, then
// we really don't want to assume the class is over and we're on a statement in the
// outer module. We just want to consume and move on.
return !(token() === 24 /* SemicolonToken */ && inErrorRecovery) && isStartOfStatement();
case 2 /* SwitchClauses */:
return token() === 72 /* CaseKeyword */ || token() === 78 /* DefaultKeyword */;
case 4 /* TypeMembers */:
return lookAhead(isTypeMemberStart);
case 5 /* ClassMembers */:
// We allow semicolons as class elements (as specified by ES6) as long as we're
// not in error recovery. If we're in error recovery, we don't want an errant
// semicolon to be treated as a class member (since they're almost always used
// for statements.
return lookAhead(isClassMemberStart) || (token() === 24 /* SemicolonToken */ && !inErrorRecovery);
case 6 /* EnumMembers */:
// Include open bracket computed properties. This technically also lets in indexers,
// which would be a candidate for improved error reporting.
return token() === 20 /* OpenBracketToken */ || isLiteralPropertyName();
case 12 /* ObjectLiteralMembers */:
return token() === 20 /* OpenBracketToken */ || token() === 38 /* AsteriskToken */ || token() === 23 /* DotDotDotToken */ || isLiteralPropertyName();
case 17 /* RestProperties */:
return isLiteralPropertyName();
case 9 /* ObjectBindingElements */:
return token() === 20 /* OpenBracketToken */ || token() === 23 /* DotDotDotToken */ || isLiteralPropertyName();
case 7 /* HeritageClauseElement */:
// If we see { } then only consume it as an expression if it is followed by , or {
// That way we won't consume the body of a class in its heritage clause.
if (token() === 16 /* OpenBraceToken */) {
return lookAhead(isValidHeritageClauseObjectLiteral);
}
if (!inErrorRecovery) {
return isStartOfLeftHandSideExpression() && !isHeritageClauseExtendsOrImplementsKeyword();
}
else {
// If we're in error recovery we tighten up what we're willing to match.
// That way we don't treat something like "this" as a valid heritage clause
// element during recovery.
return isIdentifier() && !isHeritageClauseExtendsOrImplementsKeyword();
}
case 8 /* VariableDeclarations */:
return isIdentifierOrPattern();
case 10 /* ArrayBindingElements */:
return token() === 25 /* CommaToken */ || token() === 23 /* DotDotDotToken */ || isIdentifierOrPattern();
case 18 /* TypeParameters */:
return isIdentifier();
case 11 /* ArgumentExpressions */:
case 15 /* ArrayLiteralMembers */:
return token() === 25 /* CommaToken */ || token() === 23 /* DotDotDotToken */ || isStartOfExpression();
case 16 /* Parameters */:
return isStartOfParameter();
case 19 /* TypeArguments */:
case 20 /* TupleElementTypes */:
return token() === 25 /* CommaToken */ || isStartOfType();
case 21 /* HeritageClauses */:
return isHeritageClause();
case 22 /* ImportOrExportSpecifiers */:
return ts.tokenIsIdentifierOrKeyword(token());
case 13 /* JsxAttributes */:
return ts.tokenIsIdentifierOrKeyword(token()) || token() === 16 /* OpenBraceToken */;
case 14 /* JsxChildren */:
return true;
case 23 /* JSDocFunctionParameters */:
case 24 /* JSDocTypeArguments */:
case 26 /* JSDocTupleTypes */:
return JSDocParser.isJSDocType();
case 25 /* JSDocRecordMembers */:
return isSimplePropertyName();
}
ts.Debug.fail("Non-exhaustive case in 'isListElement'.");
}
function isValidHeritageClauseObjectLiteral() {
ts.Debug.assert(token() === 16 /* OpenBraceToken */);
if (nextToken() === 17 /* CloseBraceToken */) {
// if we see "extends {}" then only treat the {} as what we're extending (and not
// the class body) if we have:
//
// extends {} {
// extends {},
// extends {} extends
// extends {} implements
var next = nextToken();
return next === 25 /* CommaToken */ || next === 16 /* OpenBraceToken */ || next === 84 /* ExtendsKeyword */ || next === 107 /* ImplementsKeyword */;
}
return true;
}
function nextTokenIsIdentifier() {
nextToken();
return isIdentifier();
}
function nextTokenIsIdentifierOrKeyword() {
nextToken();
return ts.tokenIsIdentifierOrKeyword(token());
}
function isHeritageClauseExtendsOrImplementsKeyword() {
if (token() === 107 /* ImplementsKeyword */ ||
token() === 84 /* ExtendsKeyword */) {
return lookAhead(nextTokenIsStartOfExpression);
}
return false;
}
function nextTokenIsStartOfExpression() {
nextToken();
return isStartOfExpression();
}
// True if positioned at a list terminator
function isListTerminator(kind) {
if (token() === 1 /* EndOfFileToken */) {
// Being at the end of the file ends all lists.
return true;
}
switch (kind) {
case 1 /* BlockStatements */:
case 2 /* SwitchClauses */:
case 4 /* TypeMembers */:
case 5 /* ClassMembers */:
case 6 /* EnumMembers */:
case 12 /* ObjectLiteralMembers */:
case 9 /* ObjectBindingElements */:
case 22 /* ImportOrExportSpecifiers */:
return token() === 17 /* CloseBraceToken */;
case 3 /* SwitchClauseStatements */:
return token() === 17 /* CloseBraceToken */ || token() === 72 /* CaseKeyword */ || token() === 78 /* DefaultKeyword */;
case 7 /* HeritageClauseElement */:
return token() === 16 /* OpenBraceToken */ || token() === 84 /* ExtendsKeyword */ || token() === 107 /* ImplementsKeyword */;
case 8 /* VariableDeclarations */:
return isVariableDeclaratorListTerminator();
case 18 /* TypeParameters */:
// Tokens other than '>' are here for better error recovery
return token() === 28 /* GreaterThanToken */ || token() === 18 /* OpenParenToken */ || token() === 16 /* OpenBraceToken */ || token() === 84 /* ExtendsKeyword */ || token() === 107 /* ImplementsKeyword */;
case 11 /* ArgumentExpressions */:
// Tokens other than ')' are here for better error recovery
return token() === 19 /* CloseParenToken */ || token() === 24 /* SemicolonToken */;
case 15 /* ArrayLiteralMembers */:
case 20 /* TupleElementTypes */:
case 10 /* ArrayBindingElements */:
return token() === 21 /* CloseBracketToken */;
case 16 /* Parameters */:
case 17 /* RestProperties */:
// Tokens other than ')' and ']' (the latter for index signatures) are here for better error recovery
return token() === 19 /* CloseParenToken */ || token() === 21 /* CloseBracketToken */ /*|| token === SyntaxKind.OpenBraceToken*/;
case 19 /* TypeArguments */:
// All other tokens should cause the type-argument to terminate except comma token
return token() !== 25 /* CommaToken */;
case 21 /* HeritageClauses */:
return token() === 16 /* OpenBraceToken */ || token() === 17 /* CloseBraceToken */;
case 13 /* JsxAttributes */:
return token() === 28 /* GreaterThanToken */ || token() === 40 /* SlashToken */;
case 14 /* JsxChildren */:
return token() === 26 /* LessThanToken */ && lookAhead(nextTokenIsSlash);
case 23 /* JSDocFunctionParameters */:
return token() === 19 /* CloseParenToken */ || token() === 55 /* ColonToken */ || token() === 17 /* CloseBraceToken */;
case 24 /* JSDocTypeArguments */:
return token() === 28 /* GreaterThanToken */ || token() === 17 /* CloseBraceToken */;
case 26 /* JSDocTupleTypes */:
return token() === 21 /* CloseBracketToken */ || token() === 17 /* CloseBraceToken */;
case 25 /* JSDocRecordMembers */:
return token() === 17 /* CloseBraceToken */;
}
}
function isVariableDeclaratorListTerminator() {
// If we can consume a semicolon (either explicitly, or with ASI), then consider us done
// with parsing the list of variable declarators.
if (canParseSemicolon()) {
return true;
}
// in the case where we're parsing the variable declarator of a 'for-in' statement, we
// are done if we see an 'in' keyword in front of us. Same with for-of
if (isInOrOfKeyword(token())) {
return true;
}
// ERROR RECOVERY TWEAK:
// For better error recovery, if we see an '=>' then we just stop immediately. We've got an
// arrow function here and it's going to be very unlikely that we'll resynchronize and get
// another variable declaration.
if (token() === 35 /* EqualsGreaterThanToken */) {
return true;
}
// Keep trying to parse out variable declarators.
return false;
}
// True if positioned at element or terminator of the current list or any enclosing list
function isInSomeParsingContext() {
for (var kind = 0; kind < 27 /* Count */; kind++) {
if (parsingContext & (1 << kind)) {
if (isListElement(kind, /*inErrorRecovery*/ true) || isListTerminator(kind)) {
return true;
}
}
}
return false;
}
// Parses a list of elements
function parseList(kind, parseElement) {
var saveParsingContext = parsingContext;
parsingContext |= 1 << kind;
var result = createNodeArray();
while (!isListTerminator(kind)) {
if (isListElement(kind, /*inErrorRecovery*/ false)) {
var element = parseListElement(kind, parseElement);
result.push(element);
continue;
}
if (abortParsingListOrMoveToNextToken(kind)) {
break;
}
}
result.end = getNodeEnd();
parsingContext = saveParsingContext;
return result;
}
function parseListElement(parsingContext, parseElement) {
var node = currentNode(parsingContext);
if (node) {
return consumeNode(node);
}
return parseElement();
}
function currentNode(parsingContext) {
// If there is an outstanding parse error that we've encountered, but not attached to
// some node, then we cannot get a node from the old source tree. This is because we
// want to mark the next node we encounter as being unusable.
//
// Note: This may be too conservative. Perhaps we could reuse the node and set the bit
// on it (or its leftmost child) as having the error. For now though, being conservative
// is nice and likely won't ever affect perf.
if (parseErrorBeforeNextFinishedNode) {
return undefined;
}
if (!syntaxCursor) {
// if we don't have a cursor, we could never return a node from the old tree.
return undefined;
}
var node = syntaxCursor.currentNode(scanner.getStartPos());
// Can't reuse a missing node.
if (ts.nodeIsMissing(node)) {
return undefined;
}
// Can't reuse a node that intersected the change range.
if (node.intersectsChange) {
return undefined;
}
// Can't reuse a node that contains a parse error. This is necessary so that we
// produce the same set of errors again.
if (ts.containsParseError(node)) {
return undefined;
}
// We can only reuse a node if it was parsed under the same strict mode that we're
// currently in. i.e. if we originally parsed a node in non-strict mode, but then
// the user added 'using strict' at the top of the file, then we can't use that node
// again as the presence of strict mode may cause us to parse the tokens in the file
// differently.
//
// Note: we *can* reuse tokens when the strict mode changes. That's because tokens
// are unaffected by strict mode. It's just the parser will decide what to do with it
// differently depending on what mode it is in.
//
// This also applies to all our other context flags as well.
var nodeContextFlags = node.flags & 3080192 /* ContextFlags */;
if (nodeContextFlags !== contextFlags) {
return undefined;
}
// Ok, we have a node that looks like it could be reused. Now verify that it is valid
// in the current list parsing context that we're currently at.
if (!canReuseNode(node, parsingContext)) {
return undefined;
}
return node;
}
function consumeNode(node) {
// Move the scanner so it is after the node we just consumed.
scanner.setTextPos(node.end);
nextToken();
return node;
}
function canReuseNode(node, parsingContext) {
switch (parsingContext) {
case 5 /* ClassMembers */:
return isReusableClassMember(node);
case 2 /* SwitchClauses */:
return isReusableSwitchClause(node);
case 0 /* SourceElements */:
case 1 /* BlockStatements */:
case 3 /* SwitchClauseStatements */:
return isReusableStatement(node);
case 6 /* EnumMembers */:
return isReusableEnumMember(node);
case 4 /* TypeMembers */:
return isReusableTypeMember(node);
case 8 /* VariableDeclarations */:
return isReusableVariableDeclaration(node);
case 16 /* Parameters */:
return isReusableParameter(node);
case 17 /* RestProperties */:
return false;
// Any other lists we do not care about reusing nodes in. But feel free to add if
// you can do so safely. Danger areas involve nodes that may involve speculative
// parsing. If speculative parsing is involved with the node, then the range the
// parser reached while looking ahead might be in the edited range (see the example
// in canReuseVariableDeclaratorNode for a good case of this).
case 21 /* HeritageClauses */:
// This would probably be safe to reuse. There is no speculative parsing with
// heritage clauses.
case 18 /* TypeParameters */:
// This would probably be safe to reuse. There is no speculative parsing with
// type parameters. Note that that's because type *parameters* only occur in
// unambiguous *type* contexts. While type *arguments* occur in very ambiguous
// *expression* contexts.
case 20 /* TupleElementTypes */:
// This would probably be safe to reuse. There is no speculative parsing with
// tuple types.
// Technically, type argument list types are probably safe to reuse. While
// speculative parsing is involved with them (since type argument lists are only
// produced from speculative parsing a < as a type argument list), we only have
// the types because speculative parsing succeeded. Thus, the lookahead never
// went past the end of the list and rewound.
case 19 /* TypeArguments */:
// Note: these are almost certainly not safe to ever reuse. Expressions commonly
// need a large amount of lookahead, and we should not reuse them as they may
// have actually intersected the edit.
case 11 /* ArgumentExpressions */:
// This is not safe to reuse for the same reason as the 'AssignmentExpression'
// cases. i.e. a property assignment may end with an expression, and thus might
// have lookahead far beyond it's old node.
case 12 /* ObjectLiteralMembers */:
// This is probably not safe to reuse. There can be speculative parsing with
// type names in a heritage clause. There can be generic names in the type
// name list, and there can be left hand side expressions (which can have type
// arguments.)
case 7 /* HeritageClauseElement */:
// Perhaps safe to reuse, but it's unlikely we'd see more than a dozen attributes
// on any given element. Same for children.
case 13 /* JsxAttributes */:
case 14 /* JsxChildren */:
}
return false;
}
function isReusableClassMember(node) {
if (node) {
switch (node.kind) {
case 150 /* Constructor */:
case 155 /* IndexSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 147 /* PropertyDeclaration */:
case 203 /* SemicolonClassElement */:
return true;
case 149 /* MethodDeclaration */:
// Method declarations are not necessarily reusable. An object-literal
// may have a method calls "constructor(...)" and we must reparse that
// into an actual .ConstructorDeclaration.
var methodDeclaration = node;
var nameIsConstructor = methodDeclaration.name.kind === 70 /* Identifier */ &&
methodDeclaration.name.originalKeywordKind === 122 /* ConstructorKeyword */;
return !nameIsConstructor;
}
}
return false;
}
function isReusableSwitchClause(node) {
if (node) {
switch (node.kind) {
case 253 /* CaseClause */:
case 254 /* DefaultClause */:
return true;
}
}
return false;
}
function isReusableStatement(node) {
if (node) {
switch (node.kind) {
case 225 /* FunctionDeclaration */:
case 205 /* VariableStatement */:
case 204 /* Block */:
case 208 /* IfStatement */:
case 207 /* ExpressionStatement */:
case 220 /* ThrowStatement */:
case 216 /* ReturnStatement */:
case 218 /* SwitchStatement */:
case 215 /* BreakStatement */:
case 214 /* ContinueStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 211 /* ForStatement */:
case 210 /* WhileStatement */:
case 217 /* WithStatement */:
case 206 /* EmptyStatement */:
case 221 /* TryStatement */:
case 219 /* LabeledStatement */:
case 209 /* DoStatement */:
case 222 /* DebuggerStatement */:
case 235 /* ImportDeclaration */:
case 234 /* ImportEqualsDeclaration */:
case 241 /* ExportDeclaration */:
case 240 /* ExportAssignment */:
case 230 /* ModuleDeclaration */:
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 229 /* EnumDeclaration */:
case 228 /* TypeAliasDeclaration */:
return true;
}
}
return false;
}
function isReusableEnumMember(node) {
return node.kind === 260 /* EnumMember */;
}
function isReusableTypeMember(node) {
if (node) {
switch (node.kind) {
case 154 /* ConstructSignature */:
case 148 /* MethodSignature */:
case 155 /* IndexSignature */:
case 146 /* PropertySignature */:
case 153 /* CallSignature */:
return true;
}
}
return false;
}
function isReusableVariableDeclaration(node) {
if (node.kind !== 223 /* VariableDeclaration */) {
return false;
}
// Very subtle incremental parsing bug. Consider the following code:
//
// let v = new List < A, B
//
// This is actually legal code. It's a list of variable declarators "v = new List<A"
// on one side and "B" on the other. If you then change that to:
//
// let v = new List < A, B >()
//
// then we have a problem. "v = new List<A" doesn't intersect the change range, so we
// start reparsing at "B" and we completely fail to handle this properly.
//
// In order to prevent this, we do not allow a variable declarator to be reused if it
// has an initializer.
var variableDeclarator = node;
return variableDeclarator.initializer === undefined;
}
function isReusableParameter(node) {
if (node.kind !== 144 /* Parameter */) {
return false;
}
// See the comment in isReusableVariableDeclaration for why we do this.
var parameter = node;
return parameter.initializer === undefined;
}
// Returns true if we should abort parsing.
function abortParsingListOrMoveToNextToken(kind) {
parseErrorAtCurrentToken(parsingContextErrors(kind));
if (isInSomeParsingContext()) {
return true;
}
nextToken();
return false;
}
function parsingContextErrors(context) {
switch (context) {
case 0 /* SourceElements */: return ts.Diagnostics.Declaration_or_statement_expected;
case 1 /* BlockStatements */: return ts.Diagnostics.Declaration_or_statement_expected;
case 2 /* SwitchClauses */: return ts.Diagnostics.case_or_default_expected;
case 3 /* SwitchClauseStatements */: return ts.Diagnostics.Statement_expected;
case 17 /* RestProperties */: // fallthrough
case 4 /* TypeMembers */: return ts.Diagnostics.Property_or_signature_expected;
case 5 /* ClassMembers */: return ts.Diagnostics.Unexpected_token_A_constructor_method_accessor_or_property_was_expected;
case 6 /* EnumMembers */: return ts.Diagnostics.Enum_member_expected;
case 7 /* HeritageClauseElement */: return ts.Diagnostics.Expression_expected;
case 8 /* VariableDeclarations */: return ts.Diagnostics.Variable_declaration_expected;
case 9 /* ObjectBindingElements */: return ts.Diagnostics.Property_destructuring_pattern_expected;
case 10 /* ArrayBindingElements */: return ts.Diagnostics.Array_element_destructuring_pattern_expected;
case 11 /* ArgumentExpressions */: return ts.Diagnostics.Argument_expression_expected;
case 12 /* ObjectLiteralMembers */: return ts.Diagnostics.Property_assignment_expected;
case 15 /* ArrayLiteralMembers */: return ts.Diagnostics.Expression_or_comma_expected;
case 16 /* Parameters */: return ts.Diagnostics.Parameter_declaration_expected;
case 18 /* TypeParameters */: return ts.Diagnostics.Type_parameter_declaration_expected;
case 19 /* TypeArguments */: return ts.Diagnostics.Type_argument_expected;
case 20 /* TupleElementTypes */: return ts.Diagnostics.Type_expected;
case 21 /* HeritageClauses */: return ts.Diagnostics.Unexpected_token_expected;
case 22 /* ImportOrExportSpecifiers */: return ts.Diagnostics.Identifier_expected;
case 13 /* JsxAttributes */: return ts.Diagnostics.Identifier_expected;
case 14 /* JsxChildren */: return ts.Diagnostics.Identifier_expected;
case 23 /* JSDocFunctionParameters */: return ts.Diagnostics.Parameter_declaration_expected;
case 24 /* JSDocTypeArguments */: return ts.Diagnostics.Type_argument_expected;
case 26 /* JSDocTupleTypes */: return ts.Diagnostics.Type_expected;
case 25 /* JSDocRecordMembers */: return ts.Diagnostics.Property_assignment_expected;
}
}
;
// Parses a comma-delimited list of elements
function parseDelimitedList(kind, parseElement, considerSemicolonAsDelimiter) {
var saveParsingContext = parsingContext;
parsingContext |= 1 << kind;
var result = createNodeArray();
var commaStart = -1; // Meaning the previous token was not a comma
while (true) {
if (isListElement(kind, /*inErrorRecovery*/ false)) {
result.push(parseListElement(kind, parseElement));
commaStart = scanner.getTokenPos();
if (parseOptional(25 /* CommaToken */)) {
continue;
}
commaStart = -1; // Back to the state where the last token was not a comma
if (isListTerminator(kind)) {
break;
}
// We didn't get a comma, and the list wasn't terminated, explicitly parse
// out a comma so we give a good error message.
parseExpected(25 /* CommaToken */);
// If the token was a semicolon, and the caller allows that, then skip it and
// continue. This ensures we get back on track and don't result in tons of
// parse errors. For example, this can happen when people do things like use
// a semicolon to delimit object literal members. Note: we'll have already
// reported an error when we called parseExpected above.
if (considerSemicolonAsDelimiter && token() === 24 /* SemicolonToken */ && !scanner.hasPrecedingLineBreak()) {
nextToken();
}
continue;
}
if (isListTerminator(kind)) {
break;
}
if (abortParsingListOrMoveToNextToken(kind)) {
break;
}
}
// Recording the trailing comma is deliberately done after the previous
// loop, and not just if we see a list terminator. This is because the list
// may have ended incorrectly, but it is still important to know if there
// was a trailing comma.
// Check if the last token was a comma.
if (commaStart >= 0) {
// Always preserve a trailing comma by marking it on the NodeArray
result.hasTrailingComma = true;
}
result.end = getNodeEnd();
parsingContext = saveParsingContext;
return result;
}
function createMissingList() {
return createNodeArray();
}
function parseBracketedList(kind, parseElement, open, close) {
if (parseExpected(open)) {
var result = parseDelimitedList(kind, parseElement);
parseExpected(close);
return result;
}
return createMissingList();
}
// The allowReservedWords parameter controls whether reserved words are permitted after the first dot
function parseEntityName(allowReservedWords, diagnosticMessage) {
var entity = parseIdentifier(diagnosticMessage);
while (parseOptional(22 /* DotToken */)) {
var node = createNode(141 /* QualifiedName */, entity.pos); // !!!
node.left = entity;
node.right = parseRightSideOfDot(allowReservedWords);
entity = finishNode(node);
}
return entity;
}
function parseRightSideOfDot(allowIdentifierNames) {
// Technically a keyword is valid here as all identifiers and keywords are identifier names.
// However, often we'll encounter this in error situations when the identifier or keyword
// is actually starting another valid construct.
//
// So, we check for the following specific case:
//
// name.
// identifierOrKeyword identifierNameOrKeyword
//
// Note: the newlines are important here. For example, if that above code
// were rewritten into:
//
// name.identifierOrKeyword
// identifierNameOrKeyword
//
// Then we would consider it valid. That's because ASI would take effect and
// the code would be implicitly: "name.identifierOrKeyword; identifierNameOrKeyword".
// In the first case though, ASI will not take effect because there is not a
// line terminator after the identifier or keyword.
if (scanner.hasPrecedingLineBreak() && ts.tokenIsIdentifierOrKeyword(token())) {
var matchesPattern = lookAhead(nextTokenIsIdentifierOrKeywordOnSameLine);
if (matchesPattern) {
// Report that we need an identifier. However, report it right after the dot,
// and not on the next token. This is because the next token might actually
// be an identifier and the error would be quite confusing.
return createMissingNode(70 /* Identifier */, /*reportAtCurrentPosition*/ true, ts.Diagnostics.Identifier_expected);
}
}
return allowIdentifierNames ? parseIdentifierName() : parseIdentifier();
}
function parseTemplateExpression() {
var template = createNode(194 /* TemplateExpression */);
template.head = parseTemplateHead();
ts.Debug.assert(template.head.kind === 13 /* TemplateHead */, "Template head has wrong token kind");
var templateSpans = createNodeArray();
do {
templateSpans.push(parseTemplateSpan());
} while (ts.lastOrUndefined(templateSpans).literal.kind === 14 /* TemplateMiddle */);
templateSpans.end = getNodeEnd();
template.templateSpans = templateSpans;
return finishNode(template);
}
function parseTemplateSpan() {
var span = createNode(202 /* TemplateSpan */);
span.expression = allowInAnd(parseExpression);
var literal;
if (token() === 17 /* CloseBraceToken */) {
reScanTemplateToken();
literal = parseTemplateMiddleOrTemplateTail();
}
else {
literal = parseExpectedToken(15 /* TemplateTail */, /*reportAtCurrentPosition*/ false, ts.Diagnostics._0_expected, ts.tokenToString(17 /* CloseBraceToken */));
}
span.literal = literal;
return finishNode(span);
}
function parseLiteralNode(internName) {
return parseLiteralLikeNode(token(), internName);
}
function parseTemplateHead() {
var fragment = parseLiteralLikeNode(token(), /*internName*/ false);
ts.Debug.assert(fragment.kind === 13 /* TemplateHead */, "Template head has wrong token kind");
return fragment;
}
function parseTemplateMiddleOrTemplateTail() {
var fragment = parseLiteralLikeNode(token(), /*internName*/ false);
ts.Debug.assert(fragment.kind === 14 /* TemplateMiddle */ || fragment.kind === 15 /* TemplateTail */, "Template fragment has wrong token kind");
return fragment;
}
function parseLiteralLikeNode(kind, internName) {
var node = createNode(kind);
var text = scanner.getTokenValue();
node.text = internName ? internIdentifier(text) : text;
if (scanner.hasExtendedUnicodeEscape()) {
node.hasExtendedUnicodeEscape = true;
}
if (scanner.isUnterminated()) {
node.isUnterminated = true;
}
var tokenPos = scanner.getTokenPos();
nextToken();
finishNode(node);
// Octal literals are not allowed in strict mode or ES5
// Note that theoretically the following condition would hold true literals like 009,
// which is not octal.But because of how the scanner separates the tokens, we would
// never get a token like this. Instead, we would get 00 and 9 as two separate tokens.
// We also do not need to check for negatives because any prefix operator would be part of a
// parent unary expression.
if (node.kind === 8 /* NumericLiteral */
&& sourceText.charCodeAt(tokenPos) === 48 /* _0 */
&& ts.isOctalDigit(sourceText.charCodeAt(tokenPos + 1))) {
node.isOctalLiteral = true;
}
return node;
}
// TYPES
function parseTypeReference() {
var typeName = parseEntityName(/*allowReservedWords*/ false, ts.Diagnostics.Type_expected);
var node = createNode(157 /* TypeReference */, typeName.pos);
node.typeName = typeName;
if (!scanner.hasPrecedingLineBreak() && token() === 26 /* LessThanToken */) {
node.typeArguments = parseBracketedList(19 /* TypeArguments */, parseType, 26 /* LessThanToken */, 28 /* GreaterThanToken */);
}
return finishNode(node);
}
function parseThisTypePredicate(lhs) {
nextToken();
var node = createNode(156 /* TypePredicate */, lhs.pos);
node.parameterName = lhs;
node.type = parseType();
return finishNode(node);
}
function parseThisTypeNode() {
var node = createNode(167 /* ThisType */);
nextToken();
return finishNode(node);
}
function parseTypeQuery() {
var node = createNode(160 /* TypeQuery */);
parseExpected(102 /* TypeOfKeyword */);
node.exprName = parseEntityName(/*allowReservedWords*/ true);
return finishNode(node);
}
function parseTypeParameter() {
var node = createNode(143 /* TypeParameter */);
node.name = parseIdentifier();
if (parseOptional(84 /* ExtendsKeyword */)) {
// It's not uncommon for people to write improper constraints to a generic. If the
// user writes a constraint that is an expression and not an actual type, then parse
// it out as an expression (so we can recover well), but report that a type is needed
// instead.
if (isStartOfType() || !isStartOfExpression()) {
node.constraint = parseType();
}
else {
// It was not a type, and it looked like an expression. Parse out an expression
// here so we recover well. Note: it is important that we call parseUnaryExpression
// and not parseExpression here. If the user has:
//
// <T extends "">
//
// We do *not* want to consume the > as we're consuming the expression for "".
node.expression = parseUnaryExpressionOrHigher();
}
}
return finishNode(node);
}
function parseTypeParameters() {
if (token() === 26 /* LessThanToken */) {
return parseBracketedList(18 /* TypeParameters */, parseTypeParameter, 26 /* LessThanToken */, 28 /* GreaterThanToken */);
}
}
function parseParameterType() {
if (parseOptional(55 /* ColonToken */)) {
return parseType();
}
return undefined;
}
function isStartOfParameter() {
return token() === 23 /* DotDotDotToken */ || isIdentifierOrPattern() || ts.isModifierKind(token()) || token() === 56 /* AtToken */ || token() === 98 /* ThisKeyword */;
}
function parseParameter() {
var node = createNode(144 /* Parameter */);
if (token() === 98 /* ThisKeyword */) {
node.name = createIdentifier(/*isIdentifier*/ true, undefined);
node.type = parseParameterType();
return finishNode(node);
}
node.decorators = parseDecorators();
node.modifiers = parseModifiers();
node.dotDotDotToken = parseOptionalToken(23 /* DotDotDotToken */);
// FormalParameter [Yield,Await]:
// BindingElement[?Yield,?Await]
node.name = parseIdentifierOrPattern();
if (ts.getFullWidth(node.name) === 0 && !ts.hasModifiers(node) && ts.isModifierKind(token())) {
// in cases like
// 'use strict'
// function foo(static)
// isParameter('static') === true, because of isModifier('static')
// however 'static' is not a legal identifier in a strict mode.
// so result of this function will be ParameterDeclaration (flags = 0, name = missing, type = undefined, initializer = undefined)
// and current token will not change => parsing of the enclosing parameter list will last till the end of time (or OOM)
// to avoid this we'll advance cursor to the next token.
nextToken();
}
node.questionToken = parseOptionalToken(54 /* QuestionToken */);
node.type = parseParameterType();
node.initializer = parseBindingElementInitializer(/*inParameter*/ true);
// Do not check for initializers in an ambient context for parameters. This is not
// a grammar error because the grammar allows arbitrary call signatures in
// an ambient context.
// It is actually not necessary for this to be an error at all. The reason is that
// function/constructor implementations are syntactically disallowed in ambient
// contexts. In addition, parameter initializers are semantically disallowed in
// overload signatures. So parameter initializers are transitively disallowed in
// ambient contexts.
return addJSDocComment(finishNode(node));
}
function parseBindingElementInitializer(inParameter) {
return inParameter ? parseParameterInitializer() : parseNonParameterInitializer();
}
function parseParameterInitializer() {
return parseInitializer(/*inParameter*/ true);
}
function fillSignature(returnToken, yieldContext, awaitContext, requireCompleteParameterList, signature) {
var returnTokenRequired = returnToken === 35 /* EqualsGreaterThanToken */;
signature.typeParameters = parseTypeParameters();
signature.parameters = parseParameterList(yieldContext, awaitContext, requireCompleteParameterList);
if (returnTokenRequired) {
parseExpected(returnToken);
signature.type = parseTypeOrTypePredicate();
}
else if (parseOptional(returnToken)) {
signature.type = parseTypeOrTypePredicate();
}
}
function parseParameterList(yieldContext, awaitContext, requireCompleteParameterList) {
// FormalParameters [Yield,Await]: (modified)
// [empty]
// FormalParameterList[?Yield,Await]
//
// FormalParameter[Yield,Await]: (modified)
// BindingElement[?Yield,Await]
//
// BindingElement [Yield,Await]: (modified)
// SingleNameBinding[?Yield,?Await]
// BindingPattern[?Yield,?Await]Initializer [In, ?Yield,?Await] opt
//
// SingleNameBinding [Yield,Await]:
// BindingIdentifier[?Yield,?Await]Initializer [In, ?Yield,?Await] opt
if (parseExpected(18 /* OpenParenToken */)) {
var savedYieldContext = inYieldContext();
var savedAwaitContext = inAwaitContext();
setYieldContext(yieldContext);
setAwaitContext(awaitContext);
var result = parseDelimitedList(16 /* Parameters */, parseParameter);
setYieldContext(savedYieldContext);
setAwaitContext(savedAwaitContext);
if (!parseExpected(19 /* CloseParenToken */) && requireCompleteParameterList) {
// Caller insisted that we had to end with a ) We didn't. So just return
// undefined here.
return undefined;
}
return result;
}
// We didn't even have an open paren. If the caller requires a complete parameter list,
// we definitely can't provide that. However, if they're ok with an incomplete one,
// then just return an empty set of parameters.
return requireCompleteParameterList ? undefined : createMissingList();
}
function parseTypeMemberSemicolon() {
// We allow type members to be separated by commas or (possibly ASI) semicolons.
// First check if it was a comma. If so, we're done with the member.
if (parseOptional(25 /* CommaToken */)) {
return;
}
// Didn't have a comma. We must have a (possible ASI) semicolon.
parseSemicolon();
}
function parseSignatureMember(kind) {
var node = createNode(kind);
if (kind === 154 /* ConstructSignature */) {
parseExpected(93 /* NewKeyword */);
}
fillSignature(55 /* ColonToken */, /*yieldContext*/ false, /*awaitContext*/ false, /*requireCompleteParameterList*/ false, node);
parseTypeMemberSemicolon();
return addJSDocComment(finishNode(node));
}
function isIndexSignature() {
if (token() !== 20 /* OpenBracketToken */) {
return false;
}
return lookAhead(isUnambiguouslyIndexSignature);
}
function isUnambiguouslyIndexSignature() {
// The only allowed sequence is:
//
// [id:
//
// However, for error recovery, we also check the following cases:
//
// [...
// [id,
// [id?,
// [id?:
// [id?]
// [public id
// [private id
// [protected id
// []
//
nextToken();
if (token() === 23 /* DotDotDotToken */ || token() === 21 /* CloseBracketToken */) {
return true;
}
if (ts.isModifierKind(token())) {
nextToken();
if (isIdentifier()) {
return true;
}
}
else if (!isIdentifier()) {
return false;
}
else {
// Skip the identifier
nextToken();
}
// A colon signifies a well formed indexer
// A comma should be a badly formed indexer because comma expressions are not allowed
// in computed properties.
if (token() === 55 /* ColonToken */ || token() === 25 /* CommaToken */) {
return true;
}
// Question mark could be an indexer with an optional property,
// or it could be a conditional expression in a computed property.
if (token() !== 54 /* QuestionToken */) {
return false;
}
// If any of the following tokens are after the question mark, it cannot
// be a conditional expression, so treat it as an indexer.
nextToken();
return token() === 55 /* ColonToken */ || token() === 25 /* CommaToken */ || token() === 21 /* CloseBracketToken */;
}
function parseIndexSignatureDeclaration(fullStart, decorators, modifiers) {
var node = createNode(155 /* IndexSignature */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
node.parameters = parseBracketedList(16 /* Parameters */, parseParameter, 20 /* OpenBracketToken */, 21 /* CloseBracketToken */);
node.type = parseTypeAnnotation();
parseTypeMemberSemicolon();
return finishNode(node);
}
function parsePropertyOrMethodSignature(fullStart, modifiers) {
var name = parsePropertyName();
var questionToken = parseOptionalToken(54 /* QuestionToken */);
if (token() === 18 /* OpenParenToken */ || token() === 26 /* LessThanToken */) {
var method = createNode(148 /* MethodSignature */, fullStart);
method.modifiers = modifiers;
method.name = name;
method.questionToken = questionToken;
// Method signatures don't exist in expression contexts. So they have neither
// [Yield] nor [Await]
fillSignature(55 /* ColonToken */, /*yieldContext*/ false, /*awaitContext*/ false, /*requireCompleteParameterList*/ false, method);
parseTypeMemberSemicolon();
return addJSDocComment(finishNode(method));
}
else {
var property = createNode(146 /* PropertySignature */, fullStart);
property.modifiers = modifiers;
property.name = name;
property.questionToken = questionToken;
property.type = parseTypeAnnotation();
if (token() === 57 /* EqualsToken */) {
// Although type literal properties cannot not have initializers, we attempt
// to parse an initializer so we can report in the checker that an interface
// property or type literal property cannot have an initializer.
property.initializer = parseNonParameterInitializer();
}
parseTypeMemberSemicolon();
return addJSDocComment(finishNode(property));
}
}
function isTypeMemberStart() {
var idToken;
// Return true if we have the start of a signature member
if (token() === 18 /* OpenParenToken */ || token() === 26 /* LessThanToken */) {
return true;
}
// Eat up all modifiers, but hold on to the last one in case it is actually an identifier
while (ts.isModifierKind(token())) {
idToken = token();
nextToken();
}
// Index signatures and computed property names are type members
if (token() === 20 /* OpenBracketToken */) {
return true;
}
// Try to get the first property-like token following all modifiers
if (isLiteralPropertyName()) {
idToken = token();
nextToken();
}
// If we were able to get any potential identifier, check that it is
// the start of a member declaration
if (idToken) {
return token() === 18 /* OpenParenToken */ ||
token() === 26 /* LessThanToken */ ||
token() === 54 /* QuestionToken */ ||
token() === 55 /* ColonToken */ ||
token() === 25 /* CommaToken */ ||
canParseSemicolon();
}
return false;
}
function parseTypeMember() {
if (token() === 18 /* OpenParenToken */ || token() === 26 /* LessThanToken */) {
return parseSignatureMember(153 /* CallSignature */);
}
if (token() === 93 /* NewKeyword */ && lookAhead(isStartOfConstructSignature)) {
return parseSignatureMember(154 /* ConstructSignature */);
}
var fullStart = getNodePos();
var modifiers = parseModifiers();
if (isIndexSignature()) {
return parseIndexSignatureDeclaration(fullStart, /*decorators*/ undefined, modifiers);
}
return parsePropertyOrMethodSignature(fullStart, modifiers);
}
function isStartOfConstructSignature() {
nextToken();
return token() === 18 /* OpenParenToken */ || token() === 26 /* LessThanToken */;
}
function parseTypeLiteral() {
var node = createNode(161 /* TypeLiteral */);
node.members = parseObjectTypeMembers();
return finishNode(node);
}
function parseObjectTypeMembers() {
var members;
if (parseExpected(16 /* OpenBraceToken */)) {
members = parseList(4 /* TypeMembers */, parseTypeMember);
parseExpected(17 /* CloseBraceToken */);
}
else {
members = createMissingList();
}
return members;
}
function isStartOfMappedType() {
nextToken();
if (token() === 130 /* ReadonlyKeyword */) {
nextToken();
}
return token() === 20 /* OpenBracketToken */ && nextTokenIsIdentifier() && nextToken() === 91 /* InKeyword */;
}
function parseMappedTypeParameter() {
var node = createNode(143 /* TypeParameter */);
node.name = parseIdentifier();
parseExpected(91 /* InKeyword */);
node.constraint = parseType();
return finishNode(node);
}
function parseMappedType() {
var node = createNode(170 /* MappedType */);
parseExpected(16 /* OpenBraceToken */);
node.readonlyToken = parseOptionalToken(130 /* ReadonlyKeyword */);
parseExpected(20 /* OpenBracketToken */);
node.typeParameter = parseMappedTypeParameter();
parseExpected(21 /* CloseBracketToken */);
node.questionToken = parseOptionalToken(54 /* QuestionToken */);
node.type = parseTypeAnnotation();
parseSemicolon();
parseExpected(17 /* CloseBraceToken */);
return finishNode(node);
}
function parseTupleType() {
var node = createNode(163 /* TupleType */);
node.elementTypes = parseBracketedList(20 /* TupleElementTypes */, parseType, 20 /* OpenBracketToken */, 21 /* CloseBracketToken */);
return finishNode(node);
}
function parseParenthesizedType() {
var node = createNode(166 /* ParenthesizedType */);
parseExpected(18 /* OpenParenToken */);
node.type = parseType();
parseExpected(19 /* CloseParenToken */);
return finishNode(node);
}
function parseFunctionOrConstructorType(kind) {
var node = createNode(kind);
if (kind === 159 /* ConstructorType */) {
parseExpected(93 /* NewKeyword */);
}
fillSignature(35 /* EqualsGreaterThanToken */, /*yieldContext*/ false, /*awaitContext*/ false, /*requireCompleteParameterList*/ false, node);
return finishNode(node);
}
function parseKeywordAndNoDot() {
var node = parseTokenNode();
return token() === 22 /* DotToken */ ? undefined : node;
}
function parseLiteralTypeNode() {
var node = createNode(171 /* LiteralType */);
node.literal = parseSimpleUnaryExpression();
finishNode(node);
return node;
}
function nextTokenIsNumericLiteral() {
return nextToken() === 8 /* NumericLiteral */;
}
function parseNonArrayType() {
switch (token()) {
case 118 /* AnyKeyword */:
case 134 /* StringKeyword */:
case 132 /* NumberKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 137 /* UndefinedKeyword */:
case 129 /* NeverKeyword */:
// If these are followed by a dot, then parse these out as a dotted type reference instead.
var node = tryParse(parseKeywordAndNoDot);
return node || parseTypeReference();
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
return parseLiteralTypeNode();
case 37 /* MinusToken */:
return lookAhead(nextTokenIsNumericLiteral) ? parseLiteralTypeNode() : parseTypeReference();
case 104 /* VoidKeyword */:
case 94 /* NullKeyword */:
return parseTokenNode();
case 98 /* ThisKeyword */: {
var thisKeyword = parseThisTypeNode();
if (token() === 125 /* IsKeyword */ && !scanner.hasPrecedingLineBreak()) {
return parseThisTypePredicate(thisKeyword);
}
else {
return thisKeyword;
}
}
case 102 /* TypeOfKeyword */:
return parseTypeQuery();
case 16 /* OpenBraceToken */:
return lookAhead(isStartOfMappedType) ? parseMappedType() : parseTypeLiteral();
case 20 /* OpenBracketToken */:
return parseTupleType();
case 18 /* OpenParenToken */:
return parseParenthesizedType();
default:
return parseTypeReference();
}
}
function isStartOfType() {
switch (token()) {
case 118 /* AnyKeyword */:
case 134 /* StringKeyword */:
case 132 /* NumberKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 104 /* VoidKeyword */:
case 137 /* UndefinedKeyword */:
case 94 /* NullKeyword */:
case 98 /* ThisKeyword */:
case 102 /* TypeOfKeyword */:
case 129 /* NeverKeyword */:
case 16 /* OpenBraceToken */:
case 20 /* OpenBracketToken */:
case 26 /* LessThanToken */:
case 93 /* NewKeyword */:
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
return true;
case 37 /* MinusToken */:
return lookAhead(nextTokenIsNumericLiteral);
case 18 /* OpenParenToken */:
// Only consider '(' the start of a type if followed by ')', '...', an identifier, a modifier,
// or something that starts a type. We don't want to consider things like '(1)' a type.
return lookAhead(isStartOfParenthesizedOrFunctionType);
default:
return isIdentifier();
}
}
function isStartOfParenthesizedOrFunctionType() {
nextToken();
return token() === 19 /* CloseParenToken */ || isStartOfParameter() || isStartOfType();
}
function parseArrayTypeOrHigher() {
var type = parseNonArrayType();
while (!scanner.hasPrecedingLineBreak() && parseOptional(20 /* OpenBracketToken */)) {
if (isStartOfType()) {
var node = createNode(169 /* IndexedAccessType */, type.pos);
node.objectType = type;
node.indexType = parseType();
parseExpected(21 /* CloseBracketToken */);
type = finishNode(node);
}
else {
var node = createNode(162 /* ArrayType */, type.pos);
node.elementType = type;
parseExpected(21 /* CloseBracketToken */);
type = finishNode(node);
}
}
return type;
}
function parseTypeOperator(operator) {
var node = createNode(168 /* TypeOperator */);
parseExpected(operator);
node.operator = operator;
node.type = parseTypeOperatorOrHigher();
return finishNode(node);
}
function parseTypeOperatorOrHigher() {
switch (token()) {
case 126 /* KeyOfKeyword */:
return parseTypeOperator(126 /* KeyOfKeyword */);
}
return parseArrayTypeOrHigher();
}
function parseUnionOrIntersectionType(kind, parseConstituentType, operator) {
var type = parseConstituentType();
if (token() === operator) {
var types = createNodeArray([type], type.pos);
while (parseOptional(operator)) {
types.push(parseConstituentType());
}
types.end = getNodeEnd();
var node = createNode(kind, type.pos);
node.types = types;
type = finishNode(node);
}
return type;
}
function parseIntersectionTypeOrHigher() {
return parseUnionOrIntersectionType(165 /* IntersectionType */, parseTypeOperatorOrHigher, 47 /* AmpersandToken */);
}
function parseUnionTypeOrHigher() {
return parseUnionOrIntersectionType(164 /* UnionType */, parseIntersectionTypeOrHigher, 48 /* BarToken */);
}
function isStartOfFunctionType() {
if (token() === 26 /* LessThanToken */) {
return true;
}
return token() === 18 /* OpenParenToken */ && lookAhead(isUnambiguouslyStartOfFunctionType);
}
function skipParameterStart() {
if (ts.isModifierKind(token())) {
// Skip modifiers
parseModifiers();
}
if (isIdentifier() || token() === 98 /* ThisKeyword */) {
nextToken();
return true;
}
if (token() === 20 /* OpenBracketToken */ || token() === 16 /* OpenBraceToken */) {
// Return true if we can parse an array or object binding pattern with no errors
var previousErrorCount = parseDiagnostics.length;
parseIdentifierOrPattern();
return previousErrorCount === parseDiagnostics.length;
}
return false;
}
function isUnambiguouslyStartOfFunctionType() {
nextToken();
if (token() === 19 /* CloseParenToken */ || token() === 23 /* DotDotDotToken */) {
// ( )
// ( ...
return true;
}
if (skipParameterStart()) {
// We successfully skipped modifiers (if any) and an identifier or binding pattern,
// now see if we have something that indicates a parameter declaration
if (token() === 55 /* ColonToken */ || token() === 25 /* CommaToken */ ||
token() === 54 /* QuestionToken */ || token() === 57 /* EqualsToken */) {
// ( xxx :
// ( xxx ,
// ( xxx ?
// ( xxx =
return true;
}
if (token() === 19 /* CloseParenToken */) {
nextToken();
if (token() === 35 /* EqualsGreaterThanToken */) {
// ( xxx ) =>
return true;
}
}
}
return false;
}
function parseTypeOrTypePredicate() {
var typePredicateVariable = isIdentifier() && tryParse(parseTypePredicatePrefix);
var type = parseType();
if (typePredicateVariable) {
var node = createNode(156 /* TypePredicate */, typePredicateVariable.pos);
node.parameterName = typePredicateVariable;
node.type = type;
return finishNode(node);
}
else {
return type;
}
}
function parseTypePredicatePrefix() {
var id = parseIdentifier();
if (token() === 125 /* IsKeyword */ && !scanner.hasPrecedingLineBreak()) {
nextToken();
return id;
}
}
function parseType() {
// The rules about 'yield' only apply to actual code/expression contexts. They don't
// apply to 'type' contexts. So we disable these parameters here before moving on.
return doOutsideOfContext(655360 /* TypeExcludesFlags */, parseTypeWorker);
}
function parseTypeWorker() {
if (isStartOfFunctionType()) {
return parseFunctionOrConstructorType(158 /* FunctionType */);
}
if (token() === 93 /* NewKeyword */) {
return parseFunctionOrConstructorType(159 /* ConstructorType */);
}
return parseUnionTypeOrHigher();
}
function parseTypeAnnotation() {
return parseOptional(55 /* ColonToken */) ? parseType() : undefined;
}
// EXPRESSIONS
function isStartOfLeftHandSideExpression() {
switch (token()) {
case 98 /* ThisKeyword */:
case 96 /* SuperKeyword */:
case 94 /* NullKeyword */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
case 8 /* NumericLiteral */:
case 9 /* StringLiteral */:
case 12 /* NoSubstitutionTemplateLiteral */:
case 13 /* TemplateHead */:
case 18 /* OpenParenToken */:
case 20 /* OpenBracketToken */:
case 16 /* OpenBraceToken */:
case 88 /* FunctionKeyword */:
case 74 /* ClassKeyword */:
case 93 /* NewKeyword */:
case 40 /* SlashToken */:
case 62 /* SlashEqualsToken */:
case 70 /* Identifier */:
return true;
default:
return isIdentifier();
}
}
function isStartOfExpression() {
if (isStartOfLeftHandSideExpression()) {
return true;
}
switch (token()) {
case 36 /* PlusToken */:
case 37 /* MinusToken */:
case 51 /* TildeToken */:
case 50 /* ExclamationToken */:
case 79 /* DeleteKeyword */:
case 102 /* TypeOfKeyword */:
case 104 /* VoidKeyword */:
case 42 /* PlusPlusToken */:
case 43 /* MinusMinusToken */:
case 26 /* LessThanToken */:
case 120 /* AwaitKeyword */:
case 115 /* YieldKeyword */:
// Yield/await always starts an expression. Either it is an identifier (in which case
// it is definitely an expression). Or it's a keyword (either because we're in
// a generator or async function, or in strict mode (or both)) and it started a yield or await expression.
return true;
default:
// Error tolerance. If we see the start of some binary operator, we consider
// that the start of an expression. That way we'll parse out a missing identifier,
// give a good message about an identifier being missing, and then consume the
// rest of the binary expression.
if (isBinaryOperator()) {
return true;
}
return isIdentifier();
}
}
function isStartOfExpressionStatement() {
// As per the grammar, none of '{' or 'function' or 'class' can start an expression statement.
return token() !== 16 /* OpenBraceToken */ &&
token() !== 88 /* FunctionKeyword */ &&
token() !== 74 /* ClassKeyword */ &&
token() !== 56 /* AtToken */ &&
isStartOfExpression();
}
function parseExpression() {
// Expression[in]:
// AssignmentExpression[in]
// Expression[in] , AssignmentExpression[in]
// clear the decorator context when parsing Expression, as it should be unambiguous when parsing a decorator
var saveDecoratorContext = inDecoratorContext();
if (saveDecoratorContext) {
setDecoratorContext(/*val*/ false);
}
var expr = parseAssignmentExpressionOrHigher();
var operatorToken;
while ((operatorToken = parseOptionalToken(25 /* CommaToken */))) {
expr = makeBinaryExpression(expr, operatorToken, parseAssignmentExpressionOrHigher());
}
if (saveDecoratorContext) {
setDecoratorContext(/*val*/ true);
}
return expr;
}
function parseInitializer(inParameter) {
if (token() !== 57 /* EqualsToken */) {
// It's not uncommon during typing for the user to miss writing the '=' token. Check if
// there is no newline after the last token and if we're on an expression. If so, parse
// this as an equals-value clause with a missing equals.
// NOTE: There are two places where we allow equals-value clauses. The first is in a
// variable declarator. The second is with a parameter. For variable declarators
// it's more likely that a { would be a allowed (as an object literal). While this
// is also allowed for parameters, the risk is that we consume the { as an object
// literal when it really will be for the block following the parameter.
if (scanner.hasPrecedingLineBreak() || (inParameter && token() === 16 /* OpenBraceToken */) || !isStartOfExpression()) {
// preceding line break, open brace in a parameter (likely a function body) or current token is not an expression -
// do not try to parse initializer
return undefined;
}
}
// Initializer[In, Yield] :
// = AssignmentExpression[?In, ?Yield]
parseExpected(57 /* EqualsToken */);
return parseAssignmentExpressionOrHigher();
}
function parseAssignmentExpressionOrHigher() {
// AssignmentExpression[in,yield]:
// 1) ConditionalExpression[?in,?yield]
// 2) LeftHandSideExpression = AssignmentExpression[?in,?yield]
// 3) LeftHandSideExpression AssignmentOperator AssignmentExpression[?in,?yield]
// 4) ArrowFunctionExpression[?in,?yield]
// 5) AsyncArrowFunctionExpression[in,yield,await]
// 6) [+Yield] YieldExpression[?In]
//
// Note: for ease of implementation we treat productions '2' and '3' as the same thing.
// (i.e. they're both BinaryExpressions with an assignment operator in it).
// First, do the simple check if we have a YieldExpression (production '6').
if (isYieldExpression()) {
return parseYieldExpression();
}
// Then, check if we have an arrow function (production '4' and '5') that starts with a parenthesized
// parameter list or is an async arrow function.
// AsyncArrowFunctionExpression:
// 1) async[no LineTerminator here]AsyncArrowBindingIdentifier[?Yield][no LineTerminator here]=>AsyncConciseBody[?In]
// 2) CoverCallExpressionAndAsyncArrowHead[?Yield, ?Await][no LineTerminator here]=>AsyncConciseBody[?In]
// Production (1) of AsyncArrowFunctionExpression is parsed in "tryParseAsyncSimpleArrowFunctionExpression".
// And production (2) is parsed in "tryParseParenthesizedArrowFunctionExpression".
//
// If we do successfully parse arrow-function, we must *not* recurse for productions 1, 2 or 3. An ArrowFunction is
// not a LeftHandSideExpression, nor does it start a ConditionalExpression. So we are done
// with AssignmentExpression if we see one.
var arrowExpression = tryParseParenthesizedArrowFunctionExpression() || tryParseAsyncSimpleArrowFunctionExpression();
if (arrowExpression) {
return arrowExpression;
}
// Now try to see if we're in production '1', '2' or '3'. A conditional expression can
// start with a LogicalOrExpression, while the assignment productions can only start with
// LeftHandSideExpressions.
//
// So, first, we try to just parse out a BinaryExpression. If we get something that is a
// LeftHandSide or higher, then we can try to parse out the assignment expression part.
// Otherwise, we try to parse out the conditional expression bit. We want to allow any
// binary expression here, so we pass in the 'lowest' precedence here so that it matches
// and consumes anything.
var expr = parseBinaryExpressionOrHigher(/*precedence*/ 0);
// To avoid a look-ahead, we did not handle the case of an arrow function with a single un-parenthesized
// parameter ('x => ...') above. We handle it here by checking if the parsed expression was a single
// identifier and the current token is an arrow.
if (expr.kind === 70 /* Identifier */ && token() === 35 /* EqualsGreaterThanToken */) {
return parseSimpleArrowFunctionExpression(expr);
}
// Now see if we might be in cases '2' or '3'.
// If the expression was a LHS expression, and we have an assignment operator, then
// we're in '2' or '3'. Consume the assignment and return.
//
// Note: we call reScanGreaterToken so that we get an appropriately merged token
// for cases like > > = becoming >>=
if (ts.isLeftHandSideExpression(expr) && ts.isAssignmentOperator(reScanGreaterToken())) {
return makeBinaryExpression(expr, parseTokenNode(), parseAssignmentExpressionOrHigher());
}
// It wasn't an assignment or a lambda. This is a conditional expression:
return parseConditionalExpressionRest(expr);
}
function isYieldExpression() {
if (token() === 115 /* YieldKeyword */) {
// If we have a 'yield' keyword, and this is a context where yield expressions are
// allowed, then definitely parse out a yield expression.
if (inYieldContext()) {
return true;
}
// We're in a context where 'yield expr' is not allowed. However, if we can
// definitely tell that the user was trying to parse a 'yield expr' and not
// just a normal expr that start with a 'yield' identifier, then parse out
// a 'yield expr'. We can then report an error later that they are only
// allowed in generator expressions.
//
// for example, if we see 'yield(foo)', then we'll have to treat that as an
// invocation expression of something called 'yield'. However, if we have
// 'yield foo' then that is not legal as a normal expression, so we can
// definitely recognize this as a yield expression.
//
// for now we just check if the next token is an identifier. More heuristics
// can be added here later as necessary. We just need to make sure that we
// don't accidentally consume something legal.
return lookAhead(nextTokenIsIdentifierOrKeywordOrNumberOnSameLine);
}
return false;
}
function nextTokenIsIdentifierOnSameLine() {
nextToken();
return !scanner.hasPrecedingLineBreak() && isIdentifier();
}
function parseYieldExpression() {
var node = createNode(195 /* YieldExpression */);
// YieldExpression[In] :
// yield
// yield [no LineTerminator here] [Lexical goal InputElementRegExp]AssignmentExpression[?In, Yield]
// yield [no LineTerminator here] * [Lexical goal InputElementRegExp]AssignmentExpression[?In, Yield]
nextToken();
if (!scanner.hasPrecedingLineBreak() &&
(token() === 38 /* AsteriskToken */ || isStartOfExpression())) {
node.asteriskToken = parseOptionalToken(38 /* AsteriskToken */);
node.expression = parseAssignmentExpressionOrHigher();
return finishNode(node);
}
else {
// if the next token is not on the same line as yield. or we don't have an '*' or
// the start of an expression, then this is just a simple "yield" expression.
return finishNode(node);
}
}
function parseSimpleArrowFunctionExpression(identifier, asyncModifier) {
ts.Debug.assert(token() === 35 /* EqualsGreaterThanToken */, "parseSimpleArrowFunctionExpression should only have been called if we had a =>");
var node;
if (asyncModifier) {
node = createNode(185 /* ArrowFunction */, asyncModifier.pos);
node.modifiers = asyncModifier;
}
else {
node = createNode(185 /* ArrowFunction */, identifier.pos);
}
var parameter = createNode(144 /* Parameter */, identifier.pos);
parameter.name = identifier;
finishNode(parameter);
node.parameters = createNodeArray([parameter], parameter.pos);
node.parameters.end = parameter.end;
node.equalsGreaterThanToken = parseExpectedToken(35 /* EqualsGreaterThanToken */, /*reportAtCurrentPosition*/ false, ts.Diagnostics._0_expected, "=>");
node.body = parseArrowFunctionExpressionBody(/*isAsync*/ !!asyncModifier);
return addJSDocComment(finishNode(node));
}
function tryParseParenthesizedArrowFunctionExpression() {
var triState = isParenthesizedArrowFunctionExpression();
if (triState === 0 /* False */) {
// It's definitely not a parenthesized arrow function expression.
return undefined;
}
// If we definitely have an arrow function, then we can just parse one, not requiring a
// following => or { token. Otherwise, we *might* have an arrow function. Try to parse
// it out, but don't allow any ambiguity, and return 'undefined' if this could be an
// expression instead.
var arrowFunction = triState === 1 /* True */
? parseParenthesizedArrowFunctionExpressionHead(/*allowAmbiguity*/ true)
: tryParse(parsePossibleParenthesizedArrowFunctionExpressionHead);
if (!arrowFunction) {
// Didn't appear to actually be a parenthesized arrow function. Just bail out.
return undefined;
}
var isAsync = !!(ts.getModifierFlags(arrowFunction) & 256 /* Async */);
// If we have an arrow, then try to parse the body. Even if not, try to parse if we
// have an opening brace, just in case we're in an error state.
var lastToken = token();
arrowFunction.equalsGreaterThanToken = parseExpectedToken(35 /* EqualsGreaterThanToken */, /*reportAtCurrentPosition*/ false, ts.Diagnostics._0_expected, "=>");
arrowFunction.body = (lastToken === 35 /* EqualsGreaterThanToken */ || lastToken === 16 /* OpenBraceToken */)
? parseArrowFunctionExpressionBody(isAsync)
: parseIdentifier();
return addJSDocComment(finishNode(arrowFunction));
}
// True -> We definitely expect a parenthesized arrow function here.
// False -> There *cannot* be a parenthesized arrow function here.
// Unknown -> There *might* be a parenthesized arrow function here.
// Speculatively look ahead to be sure, and rollback if not.
function isParenthesizedArrowFunctionExpression() {
if (token() === 18 /* OpenParenToken */ || token() === 26 /* LessThanToken */ || token() === 119 /* AsyncKeyword */) {
return lookAhead(isParenthesizedArrowFunctionExpressionWorker);
}
if (token() === 35 /* EqualsGreaterThanToken */) {
// ERROR RECOVERY TWEAK:
// If we see a standalone => try to parse it as an arrow function expression as that's
// likely what the user intended to write.
return 1 /* True */;
}
// Definitely not a parenthesized arrow function.
return 0 /* False */;
}
function isParenthesizedArrowFunctionExpressionWorker() {
if (token() === 119 /* AsyncKeyword */) {
nextToken();
if (scanner.hasPrecedingLineBreak()) {
return 0 /* False */;
}
if (token() !== 18 /* OpenParenToken */ && token() !== 26 /* LessThanToken */) {
return 0 /* False */;
}
}
var first = token();
var second = nextToken();
if (first === 18 /* OpenParenToken */) {
if (second === 19 /* CloseParenToken */) {
// Simple cases: "() =>", "(): ", and "() {".
// This is an arrow function with no parameters.
// The last one is not actually an arrow function,
// but this is probably what the user intended.
var third = nextToken();
switch (third) {
case 35 /* EqualsGreaterThanToken */:
case 55 /* ColonToken */:
case 16 /* OpenBraceToken */:
return 1 /* True */;
default:
return 0 /* False */;
}
}
// If encounter "([" or "({", this could be the start of a binding pattern.
// Examples:
// ([ x ]) => { }
// ({ x }) => { }
// ([ x ])
// ({ x })
if (second === 20 /* OpenBracketToken */ || second === 16 /* OpenBraceToken */) {
return 2 /* Unknown */;
}
// Simple case: "(..."
// This is an arrow function with a rest parameter.
if (second === 23 /* DotDotDotToken */) {
return 1 /* True */;
}
// If we had "(" followed by something that's not an identifier,
// then this definitely doesn't look like a lambda.
// Note: we could be a little more lenient and allow
// "(public" or "(private". These would not ever actually be allowed,
// but we could provide a good error message instead of bailing out.
if (!isIdentifier()) {
return 0 /* False */;
}
// If we have something like "(a:", then we must have a
// type-annotated parameter in an arrow function expression.
if (nextToken() === 55 /* ColonToken */) {
return 1 /* True */;
}
// This *could* be a parenthesized arrow function.
// Return Unknown to let the caller know.
return 2 /* Unknown */;
}
else {
ts.Debug.assert(first === 26 /* LessThanToken */);
// If we have "<" not followed by an identifier,
// then this definitely is not an arrow function.
if (!isIdentifier()) {
return 0 /* False */;
}
// JSX overrides
if (sourceFile.languageVariant === 1 /* JSX */) {
var isArrowFunctionInJsx = lookAhead(function () {
var third = nextToken();
if (third === 84 /* ExtendsKeyword */) {
var fourth = nextToken();
switch (fourth) {
case 57 /* EqualsToken */:
case 28 /* GreaterThanToken */:
return false;
default:
return true;
}
}
else if (third === 25 /* CommaToken */) {
return true;
}
return false;
});
if (isArrowFunctionInJsx) {
return 1 /* True */;
}
return 0 /* False */;
}
// This *could* be a parenthesized arrow function.
return 2 /* Unknown */;
}
}
function parsePossibleParenthesizedArrowFunctionExpressionHead() {
return parseParenthesizedArrowFunctionExpressionHead(/*allowAmbiguity*/ false);
}
function tryParseAsyncSimpleArrowFunctionExpression() {
// We do a check here so that we won't be doing unnecessarily call to "lookAhead"
if (token() === 119 /* AsyncKeyword */) {
var isUnParenthesizedAsyncArrowFunction = lookAhead(isUnParenthesizedAsyncArrowFunctionWorker);
if (isUnParenthesizedAsyncArrowFunction === 1 /* True */) {
var asyncModifier = parseModifiersForArrowFunction();
var expr = parseBinaryExpressionOrHigher(/*precedence*/ 0);
return parseSimpleArrowFunctionExpression(expr, asyncModifier);
}
}
return undefined;
}
function isUnParenthesizedAsyncArrowFunctionWorker() {
// AsyncArrowFunctionExpression:
// 1) async[no LineTerminator here]AsyncArrowBindingIdentifier[?Yield][no LineTerminator here]=>AsyncConciseBody[?In]
// 2) CoverCallExpressionAndAsyncArrowHead[?Yield, ?Await][no LineTerminator here]=>AsyncConciseBody[?In]
if (token() === 119 /* AsyncKeyword */) {
nextToken();
// If the "async" is followed by "=>" token then it is not a begining of an async arrow-function
// but instead a simple arrow-function which will be parsed inside "parseAssignmentExpressionOrHigher"
if (scanner.hasPrecedingLineBreak() || token() === 35 /* EqualsGreaterThanToken */) {
return 0 /* False */;
}
// Check for un-parenthesized AsyncArrowFunction
var expr = parseBinaryExpressionOrHigher(/*precedence*/ 0);
if (!scanner.hasPrecedingLineBreak() && expr.kind === 70 /* Identifier */ && token() === 35 /* EqualsGreaterThanToken */) {
return 1 /* True */;
}
}
return 0 /* False */;
}
function parseParenthesizedArrowFunctionExpressionHead(allowAmbiguity) {
var node = createNode(185 /* ArrowFunction */);
node.modifiers = parseModifiersForArrowFunction();
var isAsync = !!(ts.getModifierFlags(node) & 256 /* Async */);
// Arrow functions are never generators.
//
// If we're speculatively parsing a signature for a parenthesized arrow function, then
// we have to have a complete parameter list. Otherwise we might see something like
// a => (b => c)
// And think that "(b =>" was actually a parenthesized arrow function with a missing
// close paren.
fillSignature(55 /* ColonToken */, /*yieldContext*/ false, /*awaitContext*/ isAsync, /*requireCompleteParameterList*/ !allowAmbiguity, node);
// If we couldn't get parameters, we definitely could not parse out an arrow function.
if (!node.parameters) {
return undefined;
}
// Parsing a signature isn't enough.
// Parenthesized arrow signatures often look like other valid expressions.
// For instance:
// - "(x = 10)" is an assignment expression parsed as a signature with a default parameter value.
// - "(x,y)" is a comma expression parsed as a signature with two parameters.
// - "a ? (b): c" will have "(b):" parsed as a signature with a return type annotation.
//
// So we need just a bit of lookahead to ensure that it can only be a signature.
if (!allowAmbiguity && token() !== 35 /* EqualsGreaterThanToken */ && token() !== 16 /* OpenBraceToken */) {
// Returning undefined here will cause our caller to rewind to where we started from.
return undefined;
}
return node;
}
function parseArrowFunctionExpressionBody(isAsync) {
if (token() === 16 /* OpenBraceToken */) {
return parseFunctionBlock(/*allowYield*/ false, /*allowAwait*/ isAsync, /*ignoreMissingOpenBrace*/ false);
}
if (token() !== 24 /* SemicolonToken */ &&
token() !== 88 /* FunctionKeyword */ &&
token() !== 74 /* ClassKeyword */ &&
isStartOfStatement() &&
!isStartOfExpressionStatement()) {
// Check if we got a plain statement (i.e. no expression-statements, no function/class expressions/declarations)
//
// Here we try to recover from a potential error situation in the case where the
// user meant to supply a block. For example, if the user wrote:
//
// a =>
// let v = 0;
// }
//
// they may be missing an open brace. Check to see if that's the case so we can
// try to recover better. If we don't do this, then the next close curly we see may end
// up preemptively closing the containing construct.
//
// Note: even when 'ignoreMissingOpenBrace' is passed as true, parseBody will still error.
return parseFunctionBlock(/*allowYield*/ false, /*allowAwait*/ isAsync, /*ignoreMissingOpenBrace*/ true);
}
return isAsync
? doInAwaitContext(parseAssignmentExpressionOrHigher)
: doOutsideOfAwaitContext(parseAssignmentExpressionOrHigher);
}
function parseConditionalExpressionRest(leftOperand) {
// Note: we are passed in an expression which was produced from parseBinaryExpressionOrHigher.
var questionToken = parseOptionalToken(54 /* QuestionToken */);
if (!questionToken) {
return leftOperand;
}
// Note: we explicitly 'allowIn' in the whenTrue part of the condition expression, and
// we do not that for the 'whenFalse' part.
var node = createNode(193 /* ConditionalExpression */, leftOperand.pos);
node.condition = leftOperand;
node.questionToken = questionToken;
node.whenTrue = doOutsideOfContext(disallowInAndDecoratorContext, parseAssignmentExpressionOrHigher);
node.colonToken = parseExpectedToken(55 /* ColonToken */, /*reportAtCurrentPosition*/ false, ts.Diagnostics._0_expected, ts.tokenToString(55 /* ColonToken */));
node.whenFalse = parseAssignmentExpressionOrHigher();
return finishNode(node);
}
function parseBinaryExpressionOrHigher(precedence) {
var leftOperand = parseUnaryExpressionOrHigher();
return parseBinaryExpressionRest(precedence, leftOperand);
}
function isInOrOfKeyword(t) {
return t === 91 /* InKeyword */ || t === 140 /* OfKeyword */;
}
function parseBinaryExpressionRest(precedence, leftOperand) {
while (true) {
// We either have a binary operator here, or we're finished. We call
// reScanGreaterToken so that we merge token sequences like > and = into >=
reScanGreaterToken();
var newPrecedence = getBinaryOperatorPrecedence();
// Check the precedence to see if we should "take" this operator
// - For left associative operator (all operator but **), consume the operator,
// recursively call the function below, and parse binaryExpression as a rightOperand
// of the caller if the new precedence of the operator is greater then or equal to the current precedence.
// For example:
// a - b - c;
// ^token; leftOperand = b. Return b to the caller as a rightOperand
// a * b - c
// ^token; leftOperand = b. Return b to the caller as a rightOperand
// a - b * c;
// ^token; leftOperand = b. Return b * c to the caller as a rightOperand
// - For right associative operator (**), consume the operator, recursively call the function
// and parse binaryExpression as a rightOperand of the caller if the new precedence of
// the operator is strictly grater than the current precedence
// For example:
// a ** b ** c;
// ^^token; leftOperand = b. Return b ** c to the caller as a rightOperand
// a - b ** c;
// ^^token; leftOperand = b. Return b ** c to the caller as a rightOperand
// a ** b - c
// ^token; leftOperand = b. Return b to the caller as a rightOperand
var consumeCurrentOperator = token() === 39 /* AsteriskAsteriskToken */ ?
newPrecedence >= precedence :
newPrecedence > precedence;
if (!consumeCurrentOperator) {
break;
}
if (token() === 91 /* InKeyword */ && inDisallowInContext()) {
break;
}
if (token() === 117 /* AsKeyword */) {
// Make sure we *do* perform ASI for constructs like this:
// var x = foo
// as (Bar)
// This should be parsed as an initialized variable, followed
// by a function call to 'as' with the argument 'Bar'
if (scanner.hasPrecedingLineBreak()) {
break;
}
else {
nextToken();
leftOperand = makeAsExpression(leftOperand, parseType());
}
}
else {
leftOperand = makeBinaryExpression(leftOperand, parseTokenNode(), parseBinaryExpressionOrHigher(newPrecedence));
}
}
return leftOperand;
}
function isBinaryOperator() {
if (inDisallowInContext() && token() === 91 /* InKeyword */) {
return false;
}
return getBinaryOperatorPrecedence() > 0;
}
function getBinaryOperatorPrecedence() {
switch (token()) {
case 53 /* BarBarToken */:
return 1;
case 52 /* AmpersandAmpersandToken */:
return 2;
case 48 /* BarToken */:
return 3;
case 49 /* CaretToken */:
return 4;
case 47 /* AmpersandToken */:
return 5;
case 31 /* EqualsEqualsToken */:
case 32 /* ExclamationEqualsToken */:
case 33 /* EqualsEqualsEqualsToken */:
case 34 /* ExclamationEqualsEqualsToken */:
return 6;
case 26 /* LessThanToken */:
case 28 /* GreaterThanToken */:
case 29 /* LessThanEqualsToken */:
case 30 /* GreaterThanEqualsToken */:
case 92 /* InstanceOfKeyword */:
case 91 /* InKeyword */:
case 117 /* AsKeyword */:
return 7;
case 44 /* LessThanLessThanToken */:
case 45 /* GreaterThanGreaterThanToken */:
case 46 /* GreaterThanGreaterThanGreaterThanToken */:
return 8;
case 36 /* PlusToken */:
case 37 /* MinusToken */:
return 9;
case 38 /* AsteriskToken */:
case 40 /* SlashToken */:
case 41 /* PercentToken */:
return 10;
case 39 /* AsteriskAsteriskToken */:
return 11;
}
// -1 is lower than all other precedences. Returning it will cause binary expression
// parsing to stop.
return -1;
}
function makeBinaryExpression(left, operatorToken, right) {
var node = createNode(192 /* BinaryExpression */, left.pos);
node.left = left;
node.operatorToken = operatorToken;
node.right = right;
return finishNode(node);
}
function makeAsExpression(left, right) {
var node = createNode(200 /* AsExpression */, left.pos);
node.expression = left;
node.type = right;
return finishNode(node);
}
function parsePrefixUnaryExpression() {
var node = createNode(190 /* PrefixUnaryExpression */);
node.operator = token();
nextToken();
node.operand = parseSimpleUnaryExpression();
return finishNode(node);
}
function parseDeleteExpression() {
var node = createNode(186 /* DeleteExpression */);
nextToken();
node.expression = parseSimpleUnaryExpression();
return finishNode(node);
}
function parseTypeOfExpression() {
var node = createNode(187 /* TypeOfExpression */);
nextToken();
node.expression = parseSimpleUnaryExpression();
return finishNode(node);
}
function parseVoidExpression() {
var node = createNode(188 /* VoidExpression */);
nextToken();
node.expression = parseSimpleUnaryExpression();
return finishNode(node);
}
function isAwaitExpression() {
if (token() === 120 /* AwaitKeyword */) {
if (inAwaitContext()) {
return true;
}
// here we are using similar heuristics as 'isYieldExpression'
return lookAhead(nextTokenIsIdentifierOnSameLine);
}
return false;
}
function parseAwaitExpression() {
var node = createNode(189 /* AwaitExpression */);
nextToken();
node.expression = parseSimpleUnaryExpression();
return finishNode(node);
}
/**
* Parse ES7 exponential expression and await expression
*
* ES7 ExponentiationExpression:
* 1) UnaryExpression[?Yield]
* 2) UpdateExpression[?Yield] ** ExponentiationExpression[?Yield]
*
*/
function parseUnaryExpressionOrHigher() {
/**
* ES7 UpdateExpression:
* 1) LeftHandSideExpression[?Yield]
* 2) LeftHandSideExpression[?Yield][no LineTerminator here]++
* 3) LeftHandSideExpression[?Yield][no LineTerminator here]--
* 4) ++UnaryExpression[?Yield]
* 5) --UnaryExpression[?Yield]
*/
if (isUpdateExpression()) {
var incrementExpression = parseIncrementExpression();
return token() === 39 /* AsteriskAsteriskToken */ ?
parseBinaryExpressionRest(getBinaryOperatorPrecedence(), incrementExpression) :
incrementExpression;
}
/**
* ES7 UnaryExpression:
* 1) UpdateExpression[?yield]
* 2) delete UpdateExpression[?yield]
* 3) void UpdateExpression[?yield]
* 4) typeof UpdateExpression[?yield]
* 5) + UpdateExpression[?yield]
* 6) - UpdateExpression[?yield]
* 7) ~ UpdateExpression[?yield]
* 8) ! UpdateExpression[?yield]
*/
var unaryOperator = token();
var simpleUnaryExpression = parseSimpleUnaryExpression();
if (token() === 39 /* AsteriskAsteriskToken */) {
var start = ts.skipTrivia(sourceText, simpleUnaryExpression.pos);
if (simpleUnaryExpression.kind === 182 /* TypeAssertionExpression */) {
parseErrorAtPosition(start, simpleUnaryExpression.end - start, ts.Diagnostics.A_type_assertion_expression_is_not_allowed_in_the_left_hand_side_of_an_exponentiation_expression_Consider_enclosing_the_expression_in_parentheses);
}
else {
parseErrorAtPosition(start, simpleUnaryExpression.end - start, ts.Diagnostics.An_unary_expression_with_the_0_operator_is_not_allowed_in_the_left_hand_side_of_an_exponentiation_expression_Consider_enclosing_the_expression_in_parentheses, ts.tokenToString(unaryOperator));
}
}
return simpleUnaryExpression;
}
/**
* Parse ES7 simple-unary expression or higher:
*
* ES7 UnaryExpression:
* 1) UpdateExpression[?yield]
* 2) delete UnaryExpression[?yield]
* 3) void UnaryExpression[?yield]
* 4) typeof UnaryExpression[?yield]
* 5) + UnaryExpression[?yield]
* 6) - UnaryExpression[?yield]
* 7) ~ UnaryExpression[?yield]
* 8) ! UnaryExpression[?yield]
* 9) [+Await] await UnaryExpression[?yield]
*/
function parseSimpleUnaryExpression() {
switch (token()) {
case 36 /* PlusToken */:
case 37 /* MinusToken */:
case 51 /* TildeToken */:
case 50 /* ExclamationToken */:
return parsePrefixUnaryExpression();
case 79 /* DeleteKeyword */:
return parseDeleteExpression();
case 102 /* TypeOfKeyword */:
return parseTypeOfExpression();
case 104 /* VoidKeyword */:
return parseVoidExpression();
case 26 /* LessThanToken */:
// This is modified UnaryExpression grammar in TypeScript
// UnaryExpression (modified):
// < type > UnaryExpression
return parseTypeAssertion();
case 120 /* AwaitKeyword */:
if (isAwaitExpression()) {
return parseAwaitExpression();
}
default:
return parseIncrementExpression();
}
}
/**
* Check if the current token can possibly be an ES7 increment expression.
*
* ES7 UpdateExpression:
* LeftHandSideExpression[?Yield]
* LeftHandSideExpression[?Yield][no LineTerminator here]++
* LeftHandSideExpression[?Yield][no LineTerminator here]--
* ++LeftHandSideExpression[?Yield]
* --LeftHandSideExpression[?Yield]
*/
function isUpdateExpression() {
// This function is called inside parseUnaryExpression to decide
// whether to call parseSimpleUnaryExpression or call parseIncrementExpression directly
switch (token()) {
case 36 /* PlusToken */:
case 37 /* MinusToken */:
case 51 /* TildeToken */:
case 50 /* ExclamationToken */:
case 79 /* DeleteKeyword */:
case 102 /* TypeOfKeyword */:
case 104 /* VoidKeyword */:
case 120 /* AwaitKeyword */:
return false;
case 26 /* LessThanToken */:
// If we are not in JSX context, we are parsing TypeAssertion which is an UnaryExpression
if (sourceFile.languageVariant !== 1 /* JSX */) {
return false;
}
// We are in JSX context and the token is part of JSXElement.
// Fall through
default:
return true;
}
}
/**
* Parse ES7 IncrementExpression. IncrementExpression is used instead of ES6's PostFixExpression.
*
* ES7 IncrementExpression[yield]:
* 1) LeftHandSideExpression[?yield]
* 2) LeftHandSideExpression[?yield] [[no LineTerminator here]]++
* 3) LeftHandSideExpression[?yield] [[no LineTerminator here]]--
* 4) ++LeftHandSideExpression[?yield]
* 5) --LeftHandSideExpression[?yield]
* In TypeScript (2), (3) are parsed as PostfixUnaryExpression. (4), (5) are parsed as PrefixUnaryExpression
*/
function parseIncrementExpression() {
if (token() === 42 /* PlusPlusToken */ || token() === 43 /* MinusMinusToken */) {
var node = createNode(190 /* PrefixUnaryExpression */);
node.operator = token();
nextToken();
node.operand = parseLeftHandSideExpressionOrHigher();
return finishNode(node);
}
else if (sourceFile.languageVariant === 1 /* JSX */ && token() === 26 /* LessThanToken */ && lookAhead(nextTokenIsIdentifierOrKeyword)) {
// JSXElement is part of primaryExpression
return parseJsxElementOrSelfClosingElement(/*inExpressionContext*/ true);
}
var expression = parseLeftHandSideExpressionOrHigher();
ts.Debug.assert(ts.isLeftHandSideExpression(expression));
if ((token() === 42 /* PlusPlusToken */ || token() === 43 /* MinusMinusToken */) && !scanner.hasPrecedingLineBreak()) {
var node = createNode(191 /* PostfixUnaryExpression */, expression.pos);
node.operand = expression;
node.operator = token();
nextToken();
return finishNode(node);
}
return expression;
}
function parseLeftHandSideExpressionOrHigher() {
// Original Ecma:
// LeftHandSideExpression: See 11.2
// NewExpression
// CallExpression
//
// Our simplification:
//
// LeftHandSideExpression: See 11.2
// MemberExpression
// CallExpression
//
// See comment in parseMemberExpressionOrHigher on how we replaced NewExpression with
// MemberExpression to make our lives easier.
//
// to best understand the below code, it's important to see how CallExpression expands
// out into its own productions:
//
// CallExpression:
// MemberExpression Arguments
// CallExpression Arguments
// CallExpression[Expression]
// CallExpression.IdentifierName
// super ( ArgumentListopt )
// super.IdentifierName
//
// Because of the recursion in these calls, we need to bottom out first. There are two
// bottom out states we can run into. Either we see 'super' which must start either of
// the last two CallExpression productions. Or we have a MemberExpression which either
// completes the LeftHandSideExpression, or starts the beginning of the first four
// CallExpression productions.
var expression = token() === 96 /* SuperKeyword */
? parseSuperExpression()
: parseMemberExpressionOrHigher();
// Now, we *may* be complete. However, we might have consumed the start of a
// CallExpression. As such, we need to consume the rest of it here to be complete.
return parseCallExpressionRest(expression);
}
function parseMemberExpressionOrHigher() {
// Note: to make our lives simpler, we decompose the the NewExpression productions and
// place ObjectCreationExpression and FunctionExpression into PrimaryExpression.
// like so:
//
// PrimaryExpression : See 11.1
// this
// Identifier
// Literal
// ArrayLiteral
// ObjectLiteral
// (Expression)
// FunctionExpression
// new MemberExpression Arguments?
//
// MemberExpression : See 11.2
// PrimaryExpression
// MemberExpression[Expression]
// MemberExpression.IdentifierName
//
// CallExpression : See 11.2
// MemberExpression
// CallExpression Arguments
// CallExpression[Expression]
// CallExpression.IdentifierName
//
// Technically this is ambiguous. i.e. CallExpression defines:
//
// CallExpression:
// CallExpression Arguments
//
// If you see: "new Foo()"
//
// Then that could be treated as a single ObjectCreationExpression, or it could be
// treated as the invocation of "new Foo". We disambiguate that in code (to match
// the original grammar) by making sure that if we see an ObjectCreationExpression
// we always consume arguments if they are there. So we treat "new Foo()" as an
// object creation only, and not at all as an invocation) Another way to think
// about this is that for every "new" that we see, we will consume an argument list if
// it is there as part of the *associated* object creation node. Any additional
// argument lists we see, will become invocation expressions.
//
// Because there are no other places in the grammar now that refer to FunctionExpression
// or ObjectCreationExpression, it is safe to push down into the PrimaryExpression
// production.
//
// Because CallExpression and MemberExpression are left recursive, we need to bottom out
// of the recursion immediately. So we parse out a primary expression to start with.
var expression = parsePrimaryExpression();
return parseMemberExpressionRest(expression);
}
function parseSuperExpression() {
var expression = parseTokenNode();
if (token() === 18 /* OpenParenToken */ || token() === 22 /* DotToken */ || token() === 20 /* OpenBracketToken */) {
return expression;
}
// If we have seen "super" it must be followed by '(' or '.'.
// If it wasn't then just try to parse out a '.' and report an error.
var node = createNode(177 /* PropertyAccessExpression */, expression.pos);
node.expression = expression;
parseExpectedToken(22 /* DotToken */, /*reportAtCurrentPosition*/ false, ts.Diagnostics.super_must_be_followed_by_an_argument_list_or_member_access);
node.name = parseRightSideOfDot(/*allowIdentifierNames*/ true);
return finishNode(node);
}
function tagNamesAreEquivalent(lhs, rhs) {
if (lhs.kind !== rhs.kind) {
return false;
}
if (lhs.kind === 70 /* Identifier */) {
return lhs.text === rhs.text;
}
if (lhs.kind === 98 /* ThisKeyword */) {
return true;
}
// If we are at this statement then we must have PropertyAccessExpression and because tag name in Jsx element can only
// take forms of JsxTagNameExpression which includes an identifier, "this" expression, or another propertyAccessExpression
// it is safe to case the expression property as such. See parseJsxElementName for how we parse tag name in Jsx element
return lhs.name.text === rhs.name.text &&
tagNamesAreEquivalent(lhs.expression, rhs.expression);
}
function parseJsxElementOrSelfClosingElement(inExpressionContext) {
var opening = parseJsxOpeningOrSelfClosingElement(inExpressionContext);
var result;
if (opening.kind === 248 /* JsxOpeningElement */) {
var node = createNode(246 /* JsxElement */, opening.pos);
node.openingElement = opening;
node.children = parseJsxChildren(node.openingElement.tagName);
node.closingElement = parseJsxClosingElement(inExpressionContext);
if (!tagNamesAreEquivalent(node.openingElement.tagName, node.closingElement.tagName)) {
parseErrorAtPosition(node.closingElement.pos, node.closingElement.end - node.closingElement.pos, ts.Diagnostics.Expected_corresponding_JSX_closing_tag_for_0, ts.getTextOfNodeFromSourceText(sourceText, node.openingElement.tagName));
}
result = finishNode(node);
}
else {
ts.Debug.assert(opening.kind === 247 /* JsxSelfClosingElement */);
// Nothing else to do for self-closing elements
result = opening;
}
// If the user writes the invalid code '<div></div><div></div>' in an expression context (i.e. not wrapped in
// an enclosing tag), we'll naively try to parse ^ this as a 'less than' operator and the remainder of the tag
// as garbage, which will cause the formatter to badly mangle the JSX. Perform a speculative parse of a JSX
// element if we see a < token so that we can wrap it in a synthetic binary expression so the formatter
// does less damage and we can report a better error.
// Since JSX elements are invalid < operands anyway, this lookahead parse will only occur in error scenarios
// of one sort or another.
if (inExpressionContext && token() === 26 /* LessThanToken */) {
var invalidElement = tryParse(function () { return parseJsxElementOrSelfClosingElement(/*inExpressionContext*/ true); });
if (invalidElement) {
parseErrorAtCurrentToken(ts.Diagnostics.JSX_expressions_must_have_one_parent_element);
var badNode = createNode(192 /* BinaryExpression */, result.pos);
badNode.end = invalidElement.end;
badNode.left = result;
badNode.right = invalidElement;
badNode.operatorToken = createMissingNode(25 /* CommaToken */, /*reportAtCurrentPosition*/ false, /*diagnosticMessage*/ undefined);
badNode.operatorToken.pos = badNode.operatorToken.end = badNode.right.pos;
return badNode;
}
}
return result;
}
function parseJsxText() {
var node = createNode(10 /* JsxText */, scanner.getStartPos());
currentToken = scanner.scanJsxToken();
return finishNode(node);
}
function parseJsxChild() {
switch (token()) {
case 10 /* JsxText */:
return parseJsxText();
case 16 /* OpenBraceToken */:
return parseJsxExpression(/*inExpressionContext*/ false);
case 26 /* LessThanToken */:
return parseJsxElementOrSelfClosingElement(/*inExpressionContext*/ false);
}
ts.Debug.fail("Unknown JSX child kind " + token());
}
function parseJsxChildren(openingTagName) {
var result = createNodeArray();
var saveParsingContext = parsingContext;
parsingContext |= 1 << 14 /* JsxChildren */;
while (true) {
currentToken = scanner.reScanJsxToken();
if (token() === 27 /* LessThanSlashToken */) {
// Closing tag
break;
}
else if (token() === 1 /* EndOfFileToken */) {
// If we hit EOF, issue the error at the tag that lacks the closing element
// rather than at the end of the file (which is useless)
parseErrorAtPosition(openingTagName.pos, openingTagName.end - openingTagName.pos, ts.Diagnostics.JSX_element_0_has_no_corresponding_closing_tag, ts.getTextOfNodeFromSourceText(sourceText, openingTagName));
break;
}
result.push(parseJsxChild());
}
result.end = scanner.getTokenPos();
parsingContext = saveParsingContext;
return result;
}
function parseJsxOpeningOrSelfClosingElement(inExpressionContext) {
var fullStart = scanner.getStartPos();
parseExpected(26 /* LessThanToken */);
var tagName = parseJsxElementName();
var attributes = parseList(13 /* JsxAttributes */, parseJsxAttribute);
var node;
if (token() === 28 /* GreaterThanToken */) {
// Closing tag, so scan the immediately-following text with the JSX scanning instead
// of regular scanning to avoid treating illegal characters (e.g. '#') as immediate
// scanning errors
node = createNode(248 /* JsxOpeningElement */, fullStart);
scanJsxText();
}
else {
parseExpected(40 /* SlashToken */);
if (inExpressionContext) {
parseExpected(28 /* GreaterThanToken */);
}
else {
parseExpected(28 /* GreaterThanToken */, /*diagnostic*/ undefined, /*shouldAdvance*/ false);
scanJsxText();
}
node = createNode(247 /* JsxSelfClosingElement */, fullStart);
}
node.tagName = tagName;
node.attributes = attributes;
return finishNode(node);
}
function parseJsxElementName() {
scanJsxIdentifier();
// JsxElement can have name in the form of
// propertyAccessExpression
// primaryExpression in the form of an identifier and "this" keyword
// We can't just simply use parseLeftHandSideExpressionOrHigher because then we will start consider class,function etc as a keyword
// We only want to consider "this" as a primaryExpression
var expression = token() === 98 /* ThisKeyword */ ?
parseTokenNode() : parseIdentifierName();
while (parseOptional(22 /* DotToken */)) {
var propertyAccess = createNode(177 /* PropertyAccessExpression */, expression.pos);
propertyAccess.expression = expression;
propertyAccess.name = parseRightSideOfDot(/*allowIdentifierNames*/ true);
expression = finishNode(propertyAccess);
}
return expression;
}
function parseJsxExpression(inExpressionContext) {
var node = createNode(252 /* JsxExpression */);
parseExpected(16 /* OpenBraceToken */);
if (token() !== 17 /* CloseBraceToken */) {
node.expression = parseAssignmentExpressionOrHigher();
}
if (inExpressionContext) {
parseExpected(17 /* CloseBraceToken */);
}
else {
parseExpected(17 /* CloseBraceToken */, /*message*/ undefined, /*shouldAdvance*/ false);
scanJsxText();
}
return finishNode(node);
}
function parseJsxAttribute() {
if (token() === 16 /* OpenBraceToken */) {
return parseJsxSpreadAttribute();
}
scanJsxIdentifier();
var node = createNode(250 /* JsxAttribute */);
node.name = parseIdentifierName();
if (token() === 57 /* EqualsToken */) {
switch (scanJsxAttributeValue()) {
case 9 /* StringLiteral */:
node.initializer = parseLiteralNode();
break;
default:
node.initializer = parseJsxExpression(/*inExpressionContext*/ true);
break;
}
}
return finishNode(node);
}
function parseJsxSpreadAttribute() {
var node = createNode(251 /* JsxSpreadAttribute */);
parseExpected(16 /* OpenBraceToken */);
parseExpected(23 /* DotDotDotToken */);
node.expression = parseExpression();
parseExpected(17 /* CloseBraceToken */);
return finishNode(node);
}
function parseJsxClosingElement(inExpressionContext) {
var node = createNode(249 /* JsxClosingElement */);
parseExpected(27 /* LessThanSlashToken */);
node.tagName = parseJsxElementName();
if (inExpressionContext) {
parseExpected(28 /* GreaterThanToken */);
}
else {
parseExpected(28 /* GreaterThanToken */, /*diagnostic*/ undefined, /*shouldAdvance*/ false);
scanJsxText();
}
return finishNode(node);
}
function parseTypeAssertion() {
var node = createNode(182 /* TypeAssertionExpression */);
parseExpected(26 /* LessThanToken */);
node.type = parseType();
parseExpected(28 /* GreaterThanToken */);
node.expression = parseSimpleUnaryExpression();
return finishNode(node);
}
function parseMemberExpressionRest(expression) {
while (true) {
var dotToken = parseOptionalToken(22 /* DotToken */);
if (dotToken) {
var propertyAccess = createNode(177 /* PropertyAccessExpression */, expression.pos);
propertyAccess.expression = expression;
propertyAccess.name = parseRightSideOfDot(/*allowIdentifierNames*/ true);
expression = finishNode(propertyAccess);
continue;
}
if (token() === 50 /* ExclamationToken */ && !scanner.hasPrecedingLineBreak()) {
nextToken();
var nonNullExpression = createNode(201 /* NonNullExpression */, expression.pos);
nonNullExpression.expression = expression;
expression = finishNode(nonNullExpression);
continue;
}
// when in the [Decorator] context, we do not parse ElementAccess as it could be part of a ComputedPropertyName
if (!inDecoratorContext() && parseOptional(20 /* OpenBracketToken */)) {
var indexedAccess = createNode(178 /* ElementAccessExpression */, expression.pos);
indexedAccess.expression = expression;
// It's not uncommon for a user to write: "new Type[]".
// Check for that common pattern and report a better error message.
if (token() !== 21 /* CloseBracketToken */) {
indexedAccess.argumentExpression = allowInAnd(parseExpression);
if (indexedAccess.argumentExpression.kind === 9 /* StringLiteral */ || indexedAccess.argumentExpression.kind === 8 /* NumericLiteral */) {
var literal = indexedAccess.argumentExpression;
literal.text = internIdentifier(literal.text);
}
}
parseExpected(21 /* CloseBracketToken */);
expression = finishNode(indexedAccess);
continue;
}
if (token() === 12 /* NoSubstitutionTemplateLiteral */ || token() === 13 /* TemplateHead */) {
var tagExpression = createNode(181 /* TaggedTemplateExpression */, expression.pos);
tagExpression.tag = expression;
tagExpression.template = token() === 12 /* NoSubstitutionTemplateLiteral */
? parseLiteralNode()
: parseTemplateExpression();
expression = finishNode(tagExpression);
continue;
}
return expression;
}
}
function parseCallExpressionRest(expression) {
while (true) {
expression = parseMemberExpressionRest(expression);
if (token() === 26 /* LessThanToken */) {
// See if this is the start of a generic invocation. If so, consume it and
// keep checking for postfix expressions. Otherwise, it's just a '<' that's
// part of an arithmetic expression. Break out so we consume it higher in the
// stack.
var typeArguments = tryParse(parseTypeArgumentsInExpression);
if (!typeArguments) {
return expression;
}
var callExpr = createNode(179 /* CallExpression */, expression.pos);
callExpr.expression = expression;
callExpr.typeArguments = typeArguments;
callExpr.arguments = parseArgumentList();
expression = finishNode(callExpr);
continue;
}
else if (token() === 18 /* OpenParenToken */) {
var callExpr = createNode(179 /* CallExpression */, expression.pos);
callExpr.expression = expression;
callExpr.arguments = parseArgumentList();
expression = finishNode(callExpr);
continue;
}
return expression;
}
}
function parseArgumentList() {
parseExpected(18 /* OpenParenToken */);
var result = parseDelimitedList(11 /* ArgumentExpressions */, parseArgumentExpression);
parseExpected(19 /* CloseParenToken */);
return result;
}
function parseTypeArgumentsInExpression() {
if (!parseOptional(26 /* LessThanToken */)) {
return undefined;
}
var typeArguments = parseDelimitedList(19 /* TypeArguments */, parseType);
if (!parseExpected(28 /* GreaterThanToken */)) {
// If it doesn't have the closing > then it's definitely not an type argument list.
return undefined;
}
// If we have a '<', then only parse this as a argument list if the type arguments
// are complete and we have an open paren. if we don't, rewind and return nothing.
return typeArguments && canFollowTypeArgumentsInExpression()
? typeArguments
: undefined;
}
function canFollowTypeArgumentsInExpression() {
switch (token()) {
case 18 /* OpenParenToken */: // foo<x>(
// this case are the only case where this token can legally follow a type argument
// list. So we definitely want to treat this as a type arg list.
case 22 /* DotToken */: // foo<x>.
case 19 /* CloseParenToken */: // foo<x>)
case 21 /* CloseBracketToken */: // foo<x>]
case 55 /* ColonToken */: // foo<x>:
case 24 /* SemicolonToken */: // foo<x>;
case 54 /* QuestionToken */: // foo<x>?
case 31 /* EqualsEqualsToken */: // foo<x> ==
case 33 /* EqualsEqualsEqualsToken */: // foo<x> ===
case 32 /* ExclamationEqualsToken */: // foo<x> !=
case 34 /* ExclamationEqualsEqualsToken */: // foo<x> !==
case 52 /* AmpersandAmpersandToken */: // foo<x> &&
case 53 /* BarBarToken */: // foo<x> ||
case 49 /* CaretToken */: // foo<x> ^
case 47 /* AmpersandToken */: // foo<x> &
case 48 /* BarToken */: // foo<x> |
case 17 /* CloseBraceToken */: // foo<x> }
case 1 /* EndOfFileToken */:
// these cases can't legally follow a type arg list. However, they're not legal
// expressions either. The user is probably in the middle of a generic type. So
// treat it as such.
return true;
case 25 /* CommaToken */: // foo<x>,
case 16 /* OpenBraceToken */: // foo<x> {
// We don't want to treat these as type arguments. Otherwise we'll parse this
// as an invocation expression. Instead, we want to parse out the expression
// in isolation from the type arguments.
default:
// Anything else treat as an expression.
return false;
}
}
function parsePrimaryExpression() {
switch (token()) {
case 8 /* NumericLiteral */:
case 9 /* StringLiteral */:
case 12 /* NoSubstitutionTemplateLiteral */:
return parseLiteralNode();
case 98 /* ThisKeyword */:
case 96 /* SuperKeyword */:
case 94 /* NullKeyword */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
return parseTokenNode();
case 18 /* OpenParenToken */:
return parseParenthesizedExpression();
case 20 /* OpenBracketToken */:
return parseArrayLiteralExpression();
case 16 /* OpenBraceToken */:
return parseObjectLiteralExpression();
case 119 /* AsyncKeyword */:
// Async arrow functions are parsed earlier in parseAssignmentExpressionOrHigher.
// If we encounter `async [no LineTerminator here] function` then this is an async
// function; otherwise, its an identifier.
if (!lookAhead(nextTokenIsFunctionKeywordOnSameLine)) {
break;
}
return parseFunctionExpression();
case 74 /* ClassKeyword */:
return parseClassExpression();
case 88 /* FunctionKeyword */:
return parseFunctionExpression();
case 93 /* NewKeyword */:
return parseNewExpression();
case 40 /* SlashToken */:
case 62 /* SlashEqualsToken */:
if (reScanSlashToken() === 11 /* RegularExpressionLiteral */) {
return parseLiteralNode();
}
break;
case 13 /* TemplateHead */:
return parseTemplateExpression();
}
return parseIdentifier(ts.Diagnostics.Expression_expected);
}
function parseParenthesizedExpression() {
var node = createNode(183 /* ParenthesizedExpression */);
parseExpected(18 /* OpenParenToken */);
node.expression = allowInAnd(parseExpression);
parseExpected(19 /* CloseParenToken */);
return finishNode(node);
}
function parseSpreadElement() {
var node = createNode(196 /* SpreadElement */);
parseExpected(23 /* DotDotDotToken */);
node.expression = parseAssignmentExpressionOrHigher();
return finishNode(node);
}
function parseArgumentOrArrayLiteralElement() {
return token() === 23 /* DotDotDotToken */ ? parseSpreadElement() :
token() === 25 /* CommaToken */ ? createNode(198 /* OmittedExpression */) :
parseAssignmentExpressionOrHigher();
}
function parseArgumentExpression() {
return doOutsideOfContext(disallowInAndDecoratorContext, parseArgumentOrArrayLiteralElement);
}
function parseArrayLiteralExpression() {
var node = createNode(175 /* ArrayLiteralExpression */);
parseExpected(20 /* OpenBracketToken */);
if (scanner.hasPrecedingLineBreak()) {
node.multiLine = true;
}
node.elements = parseDelimitedList(15 /* ArrayLiteralMembers */, parseArgumentOrArrayLiteralElement);
parseExpected(21 /* CloseBracketToken */);
return finishNode(node);
}
function tryParseAccessorDeclaration(fullStart, decorators, modifiers) {
if (parseContextualModifier(124 /* GetKeyword */)) {
return parseAccessorDeclaration(151 /* GetAccessor */, fullStart, decorators, modifiers);
}
else if (parseContextualModifier(133 /* SetKeyword */)) {
return parseAccessorDeclaration(152 /* SetAccessor */, fullStart, decorators, modifiers);
}
return undefined;
}
function parseObjectLiteralElement() {
var fullStart = scanner.getStartPos();
var dotDotDotToken = parseOptionalToken(23 /* DotDotDotToken */);
if (dotDotDotToken) {
var spreadElement = createNode(259 /* SpreadAssignment */, fullStart);
spreadElement.expression = parseAssignmentExpressionOrHigher();
return addJSDocComment(finishNode(spreadElement));
}
var decorators = parseDecorators();
var modifiers = parseModifiers();
var accessor = tryParseAccessorDeclaration(fullStart, decorators, modifiers);
if (accessor) {
return accessor;
}
var asteriskToken = parseOptionalToken(38 /* AsteriskToken */);
var tokenIsIdentifier = isIdentifier();
var propertyName = parsePropertyName();
// Disallowing of optional property assignments happens in the grammar checker.
var questionToken = parseOptionalToken(54 /* QuestionToken */);
if (asteriskToken || token() === 18 /* OpenParenToken */ || token() === 26 /* LessThanToken */) {
return parseMethodDeclaration(fullStart, decorators, modifiers, asteriskToken, propertyName, questionToken);
}
// check if it is short-hand property assignment or normal property assignment
// NOTE: if token is EqualsToken it is interpreted as CoverInitializedName production
// CoverInitializedName[Yield] :
// IdentifierReference[?Yield] Initializer[In, ?Yield]
// this is necessary because ObjectLiteral productions are also used to cover grammar for ObjectAssignmentPattern
var isShorthandPropertyAssignment = tokenIsIdentifier && (token() === 25 /* CommaToken */ || token() === 17 /* CloseBraceToken */ || token() === 57 /* EqualsToken */);
if (isShorthandPropertyAssignment) {
var shorthandDeclaration = createNode(258 /* ShorthandPropertyAssignment */, fullStart);
shorthandDeclaration.name = propertyName;
shorthandDeclaration.questionToken = questionToken;
var equalsToken = parseOptionalToken(57 /* EqualsToken */);
if (equalsToken) {
shorthandDeclaration.equalsToken = equalsToken;
shorthandDeclaration.objectAssignmentInitializer = allowInAnd(parseAssignmentExpressionOrHigher);
}
return addJSDocComment(finishNode(shorthandDeclaration));
}
else {
var propertyAssignment = createNode(257 /* PropertyAssignment */, fullStart);
propertyAssignment.modifiers = modifiers;
propertyAssignment.name = propertyName;
propertyAssignment.questionToken = questionToken;
parseExpected(55 /* ColonToken */);
propertyAssignment.initializer = allowInAnd(parseAssignmentExpressionOrHigher);
return addJSDocComment(finishNode(propertyAssignment));
}
}
function parseObjectLiteralExpression() {
var node = createNode(176 /* ObjectLiteralExpression */);
parseExpected(16 /* OpenBraceToken */);
if (scanner.hasPrecedingLineBreak()) {
node.multiLine = true;
}
node.properties = parseDelimitedList(12 /* ObjectLiteralMembers */, parseObjectLiteralElement, /*considerSemicolonAsDelimiter*/ true);
parseExpected(17 /* CloseBraceToken */);
return finishNode(node);
}
function parseFunctionExpression() {
// GeneratorExpression:
// function* BindingIdentifier [Yield][opt](FormalParameters[Yield]){ GeneratorBody }
//
// FunctionExpression:
// function BindingIdentifier[opt](FormalParameters){ FunctionBody }
var saveDecoratorContext = inDecoratorContext();
if (saveDecoratorContext) {
setDecoratorContext(/*val*/ false);
}
var node = createNode(184 /* FunctionExpression */);
node.modifiers = parseModifiers();
parseExpected(88 /* FunctionKeyword */);
node.asteriskToken = parseOptionalToken(38 /* AsteriskToken */);
var isGenerator = !!node.asteriskToken;
var isAsync = !!(ts.getModifierFlags(node) & 256 /* Async */);
node.name =
isGenerator && isAsync ? doInYieldAndAwaitContext(parseOptionalIdentifier) :
isGenerator ? doInYieldContext(parseOptionalIdentifier) :
isAsync ? doInAwaitContext(parseOptionalIdentifier) :
parseOptionalIdentifier();
fillSignature(55 /* ColonToken */, /*yieldContext*/ isGenerator, /*awaitContext*/ isAsync, /*requireCompleteParameterList*/ false, node);
node.body = parseFunctionBlock(/*allowYield*/ isGenerator, /*allowAwait*/ isAsync, /*ignoreMissingOpenBrace*/ false);
if (saveDecoratorContext) {
setDecoratorContext(/*val*/ true);
}
return addJSDocComment(finishNode(node));
}
function parseOptionalIdentifier() {
return isIdentifier() ? parseIdentifier() : undefined;
}
function parseNewExpression() {
var node = createNode(180 /* NewExpression */);
parseExpected(93 /* NewKeyword */);
node.expression = parseMemberExpressionOrHigher();
node.typeArguments = tryParse(parseTypeArgumentsInExpression);
if (node.typeArguments || token() === 18 /* OpenParenToken */) {
node.arguments = parseArgumentList();
}
return finishNode(node);
}
// STATEMENTS
function parseBlock(ignoreMissingOpenBrace, diagnosticMessage) {
var node = createNode(204 /* Block */);
if (parseExpected(16 /* OpenBraceToken */, diagnosticMessage) || ignoreMissingOpenBrace) {
if (scanner.hasPrecedingLineBreak()) {
node.multiLine = true;
}
node.statements = parseList(1 /* BlockStatements */, parseStatement);
parseExpected(17 /* CloseBraceToken */);
}
else {
node.statements = createMissingList();
}
return finishNode(node);
}
function parseFunctionBlock(allowYield, allowAwait, ignoreMissingOpenBrace, diagnosticMessage) {
var savedYieldContext = inYieldContext();
setYieldContext(allowYield);
var savedAwaitContext = inAwaitContext();
setAwaitContext(allowAwait);
// We may be in a [Decorator] context when parsing a function expression or
// arrow function. The body of the function is not in [Decorator] context.
var saveDecoratorContext = inDecoratorContext();
if (saveDecoratorContext) {
setDecoratorContext(/*val*/ false);
}
var block = parseBlock(ignoreMissingOpenBrace, diagnosticMessage);
if (saveDecoratorContext) {
setDecoratorContext(/*val*/ true);
}
setYieldContext(savedYieldContext);
setAwaitContext(savedAwaitContext);
return block;
}
function parseEmptyStatement() {
var node = createNode(206 /* EmptyStatement */);
parseExpected(24 /* SemicolonToken */);
return finishNode(node);
}
function parseIfStatement() {
var node = createNode(208 /* IfStatement */);
parseExpected(89 /* IfKeyword */);
parseExpected(18 /* OpenParenToken */);
node.expression = allowInAnd(parseExpression);
parseExpected(19 /* CloseParenToken */);
node.thenStatement = parseStatement();
node.elseStatement = parseOptional(81 /* ElseKeyword */) ? parseStatement() : undefined;
return finishNode(node);
}
function parseDoStatement() {
var node = createNode(209 /* DoStatement */);
parseExpected(80 /* DoKeyword */);
node.statement = parseStatement();
parseExpected(105 /* WhileKeyword */);
parseExpected(18 /* OpenParenToken */);
node.expression = allowInAnd(parseExpression);
parseExpected(19 /* CloseParenToken */);
// From: https://mail.mozilla.org/pipermail/es-discuss/2011-August/016188.html
// 157 min --- All allen at wirfs-brock.com CONF --- "do{;}while(false)false" prohibited in
// spec but allowed in consensus reality. Approved -- this is the de-facto standard whereby
// do;while(0)x will have a semicolon inserted before x.
parseOptional(24 /* SemicolonToken */);
return finishNode(node);
}
function parseWhileStatement() {
var node = createNode(210 /* WhileStatement */);
parseExpected(105 /* WhileKeyword */);
parseExpected(18 /* OpenParenToken */);
node.expression = allowInAnd(parseExpression);
parseExpected(19 /* CloseParenToken */);
node.statement = parseStatement();
return finishNode(node);
}
function parseForOrForInOrForOfStatement() {
var pos = getNodePos();
parseExpected(87 /* ForKeyword */);
parseExpected(18 /* OpenParenToken */);
var initializer = undefined;
if (token() !== 24 /* SemicolonToken */) {
if (token() === 103 /* VarKeyword */ || token() === 109 /* LetKeyword */ || token() === 75 /* ConstKeyword */) {
initializer = parseVariableDeclarationList(/*inForStatementInitializer*/ true);
}
else {
initializer = disallowInAnd(parseExpression);
}
}
var forOrForInOrForOfStatement;
if (parseOptional(91 /* InKeyword */)) {
var forInStatement = createNode(212 /* ForInStatement */, pos);
forInStatement.initializer = initializer;
forInStatement.expression = allowInAnd(parseExpression);
parseExpected(19 /* CloseParenToken */);
forOrForInOrForOfStatement = forInStatement;
}
else if (parseOptional(140 /* OfKeyword */)) {
var forOfStatement = createNode(213 /* ForOfStatement */, pos);
forOfStatement.initializer = initializer;
forOfStatement.expression = allowInAnd(parseAssignmentExpressionOrHigher);
parseExpected(19 /* CloseParenToken */);
forOrForInOrForOfStatement = forOfStatement;
}
else {
var forStatement = createNode(211 /* ForStatement */, pos);
forStatement.initializer = initializer;
parseExpected(24 /* SemicolonToken */);
if (token() !== 24 /* SemicolonToken */ && token() !== 19 /* CloseParenToken */) {
forStatement.condition = allowInAnd(parseExpression);
}
parseExpected(24 /* SemicolonToken */);
if (token() !== 19 /* CloseParenToken */) {
forStatement.incrementor = allowInAnd(parseExpression);
}
parseExpected(19 /* CloseParenToken */);
forOrForInOrForOfStatement = forStatement;
}
forOrForInOrForOfStatement.statement = parseStatement();
return finishNode(forOrForInOrForOfStatement);
}
function parseBreakOrContinueStatement(kind) {
var node = createNode(kind);
parseExpected(kind === 215 /* BreakStatement */ ? 71 /* BreakKeyword */ : 76 /* ContinueKeyword */);
if (!canParseSemicolon()) {
node.label = parseIdentifier();
}
parseSemicolon();
return finishNode(node);
}
function parseReturnStatement() {
var node = createNode(216 /* ReturnStatement */);
parseExpected(95 /* ReturnKeyword */);
if (!canParseSemicolon()) {
node.expression = allowInAnd(parseExpression);
}
parseSemicolon();
return finishNode(node);
}
function parseWithStatement() {
var node = createNode(217 /* WithStatement */);
parseExpected(106 /* WithKeyword */);
parseExpected(18 /* OpenParenToken */);
node.expression = allowInAnd(parseExpression);
parseExpected(19 /* CloseParenToken */);
node.statement = parseStatement();
return finishNode(node);
}
function parseCaseClause() {
var node = createNode(253 /* CaseClause */);
parseExpected(72 /* CaseKeyword */);
node.expression = allowInAnd(parseExpression);
parseExpected(55 /* ColonToken */);
node.statements = parseList(3 /* SwitchClauseStatements */, parseStatement);
return finishNode(node);
}
function parseDefaultClause() {
var node = createNode(254 /* DefaultClause */);
parseExpected(78 /* DefaultKeyword */);
parseExpected(55 /* ColonToken */);
node.statements = parseList(3 /* SwitchClauseStatements */, parseStatement);
return finishNode(node);
}
function parseCaseOrDefaultClause() {
return token() === 72 /* CaseKeyword */ ? parseCaseClause() : parseDefaultClause();
}
function parseSwitchStatement() {
var node = createNode(218 /* SwitchStatement */);
parseExpected(97 /* SwitchKeyword */);
parseExpected(18 /* OpenParenToken */);
node.expression = allowInAnd(parseExpression);
parseExpected(19 /* CloseParenToken */);
var caseBlock = createNode(232 /* CaseBlock */, scanner.getStartPos());
parseExpected(16 /* OpenBraceToken */);
caseBlock.clauses = parseList(2 /* SwitchClauses */, parseCaseOrDefaultClause);
parseExpected(17 /* CloseBraceToken */);
node.caseBlock = finishNode(caseBlock);
return finishNode(node);
}
function parseThrowStatement() {
// ThrowStatement[Yield] :
// throw [no LineTerminator here]Expression[In, ?Yield];
// Because of automatic semicolon insertion, we need to report error if this
// throw could be terminated with a semicolon. Note: we can't call 'parseExpression'
// directly as that might consume an expression on the following line.
// We just return 'undefined' in that case. The actual error will be reported in the
// grammar walker.
var node = createNode(220 /* ThrowStatement */);
parseExpected(99 /* ThrowKeyword */);
node.expression = scanner.hasPrecedingLineBreak() ? undefined : allowInAnd(parseExpression);
parseSemicolon();
return finishNode(node);
}
// TODO: Review for error recovery
function parseTryStatement() {
var node = createNode(221 /* TryStatement */);
parseExpected(101 /* TryKeyword */);
node.tryBlock = parseBlock(/*ignoreMissingOpenBrace*/ false);
node.catchClause = token() === 73 /* CatchKeyword */ ? parseCatchClause() : undefined;
// If we don't have a catch clause, then we must have a finally clause. Try to parse
// one out no matter what.
if (!node.catchClause || token() === 86 /* FinallyKeyword */) {
parseExpected(86 /* FinallyKeyword */);
node.finallyBlock = parseBlock(/*ignoreMissingOpenBrace*/ false);
}
return finishNode(node);
}
function parseCatchClause() {
var result = createNode(256 /* CatchClause */);
parseExpected(73 /* CatchKeyword */);
if (parseExpected(18 /* OpenParenToken */)) {
result.variableDeclaration = parseVariableDeclaration();
}
parseExpected(19 /* CloseParenToken */);
result.block = parseBlock(/*ignoreMissingOpenBrace*/ false);
return finishNode(result);
}
function parseDebuggerStatement() {
var node = createNode(222 /* DebuggerStatement */);
parseExpected(77 /* DebuggerKeyword */);
parseSemicolon();
return finishNode(node);
}
function parseExpressionOrLabeledStatement() {
// Avoiding having to do the lookahead for a labeled statement by just trying to parse
// out an expression, seeing if it is identifier and then seeing if it is followed by
// a colon.
var fullStart = scanner.getStartPos();
var expression = allowInAnd(parseExpression);
if (expression.kind === 70 /* Identifier */ && parseOptional(55 /* ColonToken */)) {
var labeledStatement = createNode(219 /* LabeledStatement */, fullStart);
labeledStatement.label = expression;
labeledStatement.statement = parseStatement();
return addJSDocComment(finishNode(labeledStatement));
}
else {
var expressionStatement = createNode(207 /* ExpressionStatement */, fullStart);
expressionStatement.expression = expression;
parseSemicolon();
return addJSDocComment(finishNode(expressionStatement));
}
}
function nextTokenIsIdentifierOrKeywordOnSameLine() {
nextToken();
return ts.tokenIsIdentifierOrKeyword(token()) && !scanner.hasPrecedingLineBreak();
}
function nextTokenIsFunctionKeywordOnSameLine() {
nextToken();
return token() === 88 /* FunctionKeyword */ && !scanner.hasPrecedingLineBreak();
}
function nextTokenIsIdentifierOrKeywordOrNumberOnSameLine() {
nextToken();
return (ts.tokenIsIdentifierOrKeyword(token()) || token() === 8 /* NumericLiteral */) && !scanner.hasPrecedingLineBreak();
}
function isDeclaration() {
while (true) {
switch (token()) {
case 103 /* VarKeyword */:
case 109 /* LetKeyword */:
case 75 /* ConstKeyword */:
case 88 /* FunctionKeyword */:
case 74 /* ClassKeyword */:
case 82 /* EnumKeyword */:
return true;
// 'declare', 'module', 'namespace', 'interface'* and 'type' are all legal JavaScript identifiers;
// however, an identifier cannot be followed by another identifier on the same line. This is what we
// count on to parse out the respective declarations. For instance, we exploit this to say that
//
// namespace n
//
// can be none other than the beginning of a namespace declaration, but need to respect that JavaScript sees
//
// namespace
// n
//
// as the identifier 'namespace' on one line followed by the identifier 'n' on another.
// We need to look one token ahead to see if it permissible to try parsing a declaration.
//
// *Note*: 'interface' is actually a strict mode reserved word. So while
//
// "use strict"
// interface
// I {}
//
// could be legal, it would add complexity for very little gain.
case 108 /* InterfaceKeyword */:
case 136 /* TypeKeyword */:
return nextTokenIsIdentifierOnSameLine();
case 127 /* ModuleKeyword */:
case 128 /* NamespaceKeyword */:
return nextTokenIsIdentifierOrStringLiteralOnSameLine();
case 116 /* AbstractKeyword */:
case 119 /* AsyncKeyword */:
case 123 /* DeclareKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 113 /* PublicKeyword */:
case 130 /* ReadonlyKeyword */:
nextToken();
// ASI takes effect for this modifier.
if (scanner.hasPrecedingLineBreak()) {
return false;
}
continue;
case 139 /* GlobalKeyword */:
nextToken();
return token() === 16 /* OpenBraceToken */ || token() === 70 /* Identifier */ || token() === 83 /* ExportKeyword */;
case 90 /* ImportKeyword */:
nextToken();
return token() === 9 /* StringLiteral */ || token() === 38 /* AsteriskToken */ ||
token() === 16 /* OpenBraceToken */ || ts.tokenIsIdentifierOrKeyword(token());
case 83 /* ExportKeyword */:
nextToken();
if (token() === 57 /* EqualsToken */ || token() === 38 /* AsteriskToken */ ||
token() === 16 /* OpenBraceToken */ || token() === 78 /* DefaultKeyword */ ||
token() === 117 /* AsKeyword */) {
return true;
}
continue;
case 114 /* StaticKeyword */:
nextToken();
continue;
default:
return false;
}
}
}
function isStartOfDeclaration() {
return lookAhead(isDeclaration);
}
function isStartOfStatement() {
switch (token()) {
case 56 /* AtToken */:
case 24 /* SemicolonToken */:
case 16 /* OpenBraceToken */:
case 103 /* VarKeyword */:
case 109 /* LetKeyword */:
case 88 /* FunctionKeyword */:
case 74 /* ClassKeyword */:
case 82 /* EnumKeyword */:
case 89 /* IfKeyword */:
case 80 /* DoKeyword */:
case 105 /* WhileKeyword */:
case 87 /* ForKeyword */:
case 76 /* ContinueKeyword */:
case 71 /* BreakKeyword */:
case 95 /* ReturnKeyword */:
case 106 /* WithKeyword */:
case 97 /* SwitchKeyword */:
case 99 /* ThrowKeyword */:
case 101 /* TryKeyword */:
case 77 /* DebuggerKeyword */:
// 'catch' and 'finally' do not actually indicate that the code is part of a statement,
// however, we say they are here so that we may gracefully parse them and error later.
case 73 /* CatchKeyword */:
case 86 /* FinallyKeyword */:
return true;
case 75 /* ConstKeyword */:
case 83 /* ExportKeyword */:
case 90 /* ImportKeyword */:
return isStartOfDeclaration();
case 119 /* AsyncKeyword */:
case 123 /* DeclareKeyword */:
case 108 /* InterfaceKeyword */:
case 127 /* ModuleKeyword */:
case 128 /* NamespaceKeyword */:
case 136 /* TypeKeyword */:
case 139 /* GlobalKeyword */:
// When these don't start a declaration, they're an identifier in an expression statement
return true;
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 114 /* StaticKeyword */:
case 130 /* ReadonlyKeyword */:
// When these don't start a declaration, they may be the start of a class member if an identifier
// immediately follows. Otherwise they're an identifier in an expression statement.
return isStartOfDeclaration() || !lookAhead(nextTokenIsIdentifierOrKeywordOnSameLine);
default:
return isStartOfExpression();
}
}
function nextTokenIsIdentifierOrStartOfDestructuring() {
nextToken();
return isIdentifier() || token() === 16 /* OpenBraceToken */ || token() === 20 /* OpenBracketToken */;
}
function isLetDeclaration() {
// In ES6 'let' always starts a lexical declaration if followed by an identifier or {
// or [.
return lookAhead(nextTokenIsIdentifierOrStartOfDestructuring);
}
function parseStatement() {
switch (token()) {
case 24 /* SemicolonToken */:
return parseEmptyStatement();
case 16 /* OpenBraceToken */:
return parseBlock(/*ignoreMissingOpenBrace*/ false);
case 103 /* VarKeyword */:
return parseVariableStatement(scanner.getStartPos(), /*decorators*/ undefined, /*modifiers*/ undefined);
case 109 /* LetKeyword */:
if (isLetDeclaration()) {
return parseVariableStatement(scanner.getStartPos(), /*decorators*/ undefined, /*modifiers*/ undefined);
}
break;
case 88 /* FunctionKeyword */:
return parseFunctionDeclaration(scanner.getStartPos(), /*decorators*/ undefined, /*modifiers*/ undefined);
case 74 /* ClassKeyword */:
return parseClassDeclaration(scanner.getStartPos(), /*decorators*/ undefined, /*modifiers*/ undefined);
case 89 /* IfKeyword */:
return parseIfStatement();
case 80 /* DoKeyword */:
return parseDoStatement();
case 105 /* WhileKeyword */:
return parseWhileStatement();
case 87 /* ForKeyword */:
return parseForOrForInOrForOfStatement();
case 76 /* ContinueKeyword */:
return parseBreakOrContinueStatement(214 /* ContinueStatement */);
case 71 /* BreakKeyword */:
return parseBreakOrContinueStatement(215 /* BreakStatement */);
case 95 /* ReturnKeyword */:
return parseReturnStatement();
case 106 /* WithKeyword */:
return parseWithStatement();
case 97 /* SwitchKeyword */:
return parseSwitchStatement();
case 99 /* ThrowKeyword */:
return parseThrowStatement();
case 101 /* TryKeyword */:
// Include 'catch' and 'finally' for error recovery.
case 73 /* CatchKeyword */:
case 86 /* FinallyKeyword */:
return parseTryStatement();
case 77 /* DebuggerKeyword */:
return parseDebuggerStatement();
case 56 /* AtToken */:
return parseDeclaration();
case 119 /* AsyncKeyword */:
case 108 /* InterfaceKeyword */:
case 136 /* TypeKeyword */:
case 127 /* ModuleKeyword */:
case 128 /* NamespaceKeyword */:
case 123 /* DeclareKeyword */:
case 75 /* ConstKeyword */:
case 82 /* EnumKeyword */:
case 83 /* ExportKeyword */:
case 90 /* ImportKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 113 /* PublicKeyword */:
case 116 /* AbstractKeyword */:
case 114 /* StaticKeyword */:
case 130 /* ReadonlyKeyword */:
case 139 /* GlobalKeyword */:
if (isStartOfDeclaration()) {
return parseDeclaration();
}
break;
}
return parseExpressionOrLabeledStatement();
}
function parseDeclaration() {
var fullStart = getNodePos();
var decorators = parseDecorators();
var modifiers = parseModifiers();
switch (token()) {
case 103 /* VarKeyword */:
case 109 /* LetKeyword */:
case 75 /* ConstKeyword */:
return parseVariableStatement(fullStart, decorators, modifiers);
case 88 /* FunctionKeyword */:
return parseFunctionDeclaration(fullStart, decorators, modifiers);
case 74 /* ClassKeyword */:
return parseClassDeclaration(fullStart, decorators, modifiers);
case 108 /* InterfaceKeyword */:
return parseInterfaceDeclaration(fullStart, decorators, modifiers);
case 136 /* TypeKeyword */:
return parseTypeAliasDeclaration(fullStart, decorators, modifiers);
case 82 /* EnumKeyword */:
return parseEnumDeclaration(fullStart, decorators, modifiers);
case 139 /* GlobalKeyword */:
case 127 /* ModuleKeyword */:
case 128 /* NamespaceKeyword */:
return parseModuleDeclaration(fullStart, decorators, modifiers);
case 90 /* ImportKeyword */:
return parseImportDeclarationOrImportEqualsDeclaration(fullStart, decorators, modifiers);
case 83 /* ExportKeyword */:
nextToken();
switch (token()) {
case 78 /* DefaultKeyword */:
case 57 /* EqualsToken */:
return parseExportAssignment(fullStart, decorators, modifiers);
case 117 /* AsKeyword */:
return parseNamespaceExportDeclaration(fullStart, decorators, modifiers);
default:
return parseExportDeclaration(fullStart, decorators, modifiers);
}
default:
if (decorators || modifiers) {
// We reached this point because we encountered decorators and/or modifiers and assumed a declaration
// would follow. For recovery and error reporting purposes, return an incomplete declaration.
var node = createMissingNode(244 /* MissingDeclaration */, /*reportAtCurrentPosition*/ true, ts.Diagnostics.Declaration_expected);
node.pos = fullStart;
node.decorators = decorators;
node.modifiers = modifiers;
return finishNode(node);
}
}
}
function nextTokenIsIdentifierOrStringLiteralOnSameLine() {
nextToken();
return !scanner.hasPrecedingLineBreak() && (isIdentifier() || token() === 9 /* StringLiteral */);
}
function parseFunctionBlockOrSemicolon(isGenerator, isAsync, diagnosticMessage) {
if (token() !== 16 /* OpenBraceToken */ && canParseSemicolon()) {
parseSemicolon();
return;
}
return parseFunctionBlock(isGenerator, isAsync, /*ignoreMissingOpenBrace*/ false, diagnosticMessage);
}
// DECLARATIONS
function parseArrayBindingElement() {
if (token() === 25 /* CommaToken */) {
return createNode(198 /* OmittedExpression */);
}
var node = createNode(174 /* BindingElement */);
node.dotDotDotToken = parseOptionalToken(23 /* DotDotDotToken */);
node.name = parseIdentifierOrPattern();
node.initializer = parseBindingElementInitializer(/*inParameter*/ false);
return finishNode(node);
}
function parseObjectBindingElement() {
var node = createNode(174 /* BindingElement */);
node.dotDotDotToken = parseOptionalToken(23 /* DotDotDotToken */);
var tokenIsIdentifier = isIdentifier();
var propertyName = parsePropertyName();
if (tokenIsIdentifier && token() !== 55 /* ColonToken */) {
node.name = propertyName;
}
else {
parseExpected(55 /* ColonToken */);
node.propertyName = propertyName;
node.name = parseIdentifierOrPattern();
}
node.initializer = parseBindingElementInitializer(/*inParameter*/ false);
return finishNode(node);
}
function parseObjectBindingPattern() {
var node = createNode(172 /* ObjectBindingPattern */);
parseExpected(16 /* OpenBraceToken */);
node.elements = parseDelimitedList(9 /* ObjectBindingElements */, parseObjectBindingElement);
parseExpected(17 /* CloseBraceToken */);
return finishNode(node);
}
function parseArrayBindingPattern() {
var node = createNode(173 /* ArrayBindingPattern */);
parseExpected(20 /* OpenBracketToken */);
node.elements = parseDelimitedList(10 /* ArrayBindingElements */, parseArrayBindingElement);
parseExpected(21 /* CloseBracketToken */);
return finishNode(node);
}
function isIdentifierOrPattern() {
return token() === 16 /* OpenBraceToken */ || token() === 20 /* OpenBracketToken */ || isIdentifier();
}
function parseIdentifierOrPattern() {
if (token() === 20 /* OpenBracketToken */) {
return parseArrayBindingPattern();
}
if (token() === 16 /* OpenBraceToken */) {
return parseObjectBindingPattern();
}
return parseIdentifier();
}
function parseVariableDeclaration() {
var node = createNode(223 /* VariableDeclaration */);
node.name = parseIdentifierOrPattern();
node.type = parseTypeAnnotation();
if (!isInOrOfKeyword(token())) {
node.initializer = parseInitializer(/*inParameter*/ false);
}
return finishNode(node);
}
function parseVariableDeclarationList(inForStatementInitializer) {
var node = createNode(224 /* VariableDeclarationList */);
switch (token()) {
case 103 /* VarKeyword */:
break;
case 109 /* LetKeyword */:
node.flags |= 1 /* Let */;
break;
case 75 /* ConstKeyword */:
node.flags |= 2 /* Const */;
break;
default:
ts.Debug.fail();
}
nextToken();
// The user may have written the following:
//
// for (let of X) { }
//
// In this case, we want to parse an empty declaration list, and then parse 'of'
// as a keyword. The reason this is not automatic is that 'of' is a valid identifier.
// So we need to look ahead to determine if 'of' should be treated as a keyword in
// this context.
// The checker will then give an error that there is an empty declaration list.
if (token() === 140 /* OfKeyword */ && lookAhead(canFollowContextualOfKeyword)) {
node.declarations = createMissingList();
}
else {
var savedDisallowIn = inDisallowInContext();
setDisallowInContext(inForStatementInitializer);
node.declarations = parseDelimitedList(8 /* VariableDeclarations */, parseVariableDeclaration);
setDisallowInContext(savedDisallowIn);
}
return finishNode(node);
}
function canFollowContextualOfKeyword() {
return nextTokenIsIdentifier() && nextToken() === 19 /* CloseParenToken */;
}
function parseVariableStatement(fullStart, decorators, modifiers) {
var node = createNode(205 /* VariableStatement */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
node.declarationList = parseVariableDeclarationList(/*inForStatementInitializer*/ false);
parseSemicolon();
return addJSDocComment(finishNode(node));
}
function parseFunctionDeclaration(fullStart, decorators, modifiers) {
var node = createNode(225 /* FunctionDeclaration */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
parseExpected(88 /* FunctionKeyword */);
node.asteriskToken = parseOptionalToken(38 /* AsteriskToken */);
node.name = ts.hasModifier(node, 512 /* Default */) ? parseOptionalIdentifier() : parseIdentifier();
var isGenerator = !!node.asteriskToken;
var isAsync = ts.hasModifier(node, 256 /* Async */);
fillSignature(55 /* ColonToken */, /*yieldContext*/ isGenerator, /*awaitContext*/ isAsync, /*requireCompleteParameterList*/ false, node);
node.body = parseFunctionBlockOrSemicolon(isGenerator, isAsync, ts.Diagnostics.or_expected);
return addJSDocComment(finishNode(node));
}
function parseConstructorDeclaration(pos, decorators, modifiers) {
var node = createNode(150 /* Constructor */, pos);
node.decorators = decorators;
node.modifiers = modifiers;
parseExpected(122 /* ConstructorKeyword */);
fillSignature(55 /* ColonToken */, /*yieldContext*/ false, /*awaitContext*/ false, /*requireCompleteParameterList*/ false, node);
node.body = parseFunctionBlockOrSemicolon(/*isGenerator*/ false, /*isAsync*/ false, ts.Diagnostics.or_expected);
return addJSDocComment(finishNode(node));
}
function parseMethodDeclaration(fullStart, decorators, modifiers, asteriskToken, name, questionToken, diagnosticMessage) {
var method = createNode(149 /* MethodDeclaration */, fullStart);
method.decorators = decorators;
method.modifiers = modifiers;
method.asteriskToken = asteriskToken;
method.name = name;
method.questionToken = questionToken;
var isGenerator = !!asteriskToken;
var isAsync = ts.hasModifier(method, 256 /* Async */);
fillSignature(55 /* ColonToken */, /*yieldContext*/ isGenerator, /*awaitContext*/ isAsync, /*requireCompleteParameterList*/ false, method);
method.body = parseFunctionBlockOrSemicolon(isGenerator, isAsync, diagnosticMessage);
return addJSDocComment(finishNode(method));
}
function parsePropertyDeclaration(fullStart, decorators, modifiers, name, questionToken) {
var property = createNode(147 /* PropertyDeclaration */, fullStart);
property.decorators = decorators;
property.modifiers = modifiers;
property.name = name;
property.questionToken = questionToken;
property.type = parseTypeAnnotation();
// For instance properties specifically, since they are evaluated inside the constructor,
// we do *not * want to parse yield expressions, so we specifically turn the yield context
// off. The grammar would look something like this:
//
// MemberVariableDeclaration[Yield]:
// AccessibilityModifier_opt PropertyName TypeAnnotation_opt Initializer_opt[In];
// AccessibilityModifier_opt static_opt PropertyName TypeAnnotation_opt Initializer_opt[In, ?Yield];
//
// The checker may still error in the static case to explicitly disallow the yield expression.
property.initializer = ts.hasModifier(property, 32 /* Static */)
? allowInAnd(parseNonParameterInitializer)
: doOutsideOfContext(131072 /* YieldContext */ | 65536 /* DisallowInContext */, parseNonParameterInitializer);
parseSemicolon();
return addJSDocComment(finishNode(property));
}
function parsePropertyOrMethodDeclaration(fullStart, decorators, modifiers) {
var asteriskToken = parseOptionalToken(38 /* AsteriskToken */);
var name = parsePropertyName();
// Note: this is not legal as per the grammar. But we allow it in the parser and
// report an error in the grammar checker.
var questionToken = parseOptionalToken(54 /* QuestionToken */);
if (asteriskToken || token() === 18 /* OpenParenToken */ || token() === 26 /* LessThanToken */) {
return parseMethodDeclaration(fullStart, decorators, modifiers, asteriskToken, name, questionToken, ts.Diagnostics.or_expected);
}
else {
return parsePropertyDeclaration(fullStart, decorators, modifiers, name, questionToken);
}
}
function parseNonParameterInitializer() {
return parseInitializer(/*inParameter*/ false);
}
function parseAccessorDeclaration(kind, fullStart, decorators, modifiers) {
var node = createNode(kind, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
node.name = parsePropertyName();
fillSignature(55 /* ColonToken */, /*yieldContext*/ false, /*awaitContext*/ false, /*requireCompleteParameterList*/ false, node);
node.body = parseFunctionBlockOrSemicolon(/*isGenerator*/ false, /*isAsync*/ false);
return addJSDocComment(finishNode(node));
}
function isClassMemberModifier(idToken) {
switch (idToken) {
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 114 /* StaticKeyword */:
case 130 /* ReadonlyKeyword */:
return true;
default:
return false;
}
}
function isClassMemberStart() {
var idToken;
if (token() === 56 /* AtToken */) {
return true;
}
// Eat up all modifiers, but hold on to the last one in case it is actually an identifier.
while (ts.isModifierKind(token())) {
idToken = token();
// If the idToken is a class modifier (protected, private, public, and static), it is
// certain that we are starting to parse class member. This allows better error recovery
// Example:
// public foo() ... // true
// public @dec blah ... // true; we will then report an error later
// export public ... // true; we will then report an error later
if (isClassMemberModifier(idToken)) {
return true;
}
nextToken();
}
if (token() === 38 /* AsteriskToken */) {
return true;
}
// Try to get the first property-like token following all modifiers.
// This can either be an identifier or the 'get' or 'set' keywords.
if (isLiteralPropertyName()) {
idToken = token();
nextToken();
}
// Index signatures and computed properties are class members; we can parse.
if (token() === 20 /* OpenBracketToken */) {
return true;
}
// If we were able to get any potential identifier...
if (idToken !== undefined) {
// If we have a non-keyword identifier, or if we have an accessor, then it's safe to parse.
if (!ts.isKeyword(idToken) || idToken === 133 /* SetKeyword */ || idToken === 124 /* GetKeyword */) {
return true;
}
// If it *is* a keyword, but not an accessor, check a little farther along
// to see if it should actually be parsed as a class member.
switch (token()) {
case 18 /* OpenParenToken */: // Method declaration
case 26 /* LessThanToken */: // Generic Method declaration
case 55 /* ColonToken */: // Type Annotation for declaration
case 57 /* EqualsToken */: // Initializer for declaration
case 54 /* QuestionToken */:
return true;
default:
// Covers
// - Semicolons (declaration termination)
// - Closing braces (end-of-class, must be declaration)
// - End-of-files (not valid, but permitted so that it gets caught later on)
// - Line-breaks (enabling *automatic semicolon insertion*)
return canParseSemicolon();
}
}
return false;
}
function parseDecorators() {
var decorators;
while (true) {
var decoratorStart = getNodePos();
if (!parseOptional(56 /* AtToken */)) {
break;
}
var decorator = createNode(145 /* Decorator */, decoratorStart);
decorator.expression = doInDecoratorContext(parseLeftHandSideExpressionOrHigher);
finishNode(decorator);
if (!decorators) {
decorators = createNodeArray([decorator], decoratorStart);
}
else {
decorators.push(decorator);
}
}
if (decorators) {
decorators.end = getNodeEnd();
}
return decorators;
}
/*
* There are situations in which a modifier like 'const' will appear unexpectedly, such as on a class member.
* In those situations, if we are entirely sure that 'const' is not valid on its own (such as when ASI takes effect
* and turns it into a standalone declaration), then it is better to parse it and report an error later.
*
* In such situations, 'permitInvalidConstAsModifier' should be set to true.
*/
function parseModifiers(permitInvalidConstAsModifier) {
var modifiers;
while (true) {
var modifierStart = scanner.getStartPos();
var modifierKind = token();
if (token() === 75 /* ConstKeyword */ && permitInvalidConstAsModifier) {
// We need to ensure that any subsequent modifiers appear on the same line
// so that when 'const' is a standalone declaration, we don't issue an error.
if (!tryParse(nextTokenIsOnSameLineAndCanFollowModifier)) {
break;
}
}
else {
if (!parseAnyContextualModifier()) {
break;
}
}
var modifier = finishNode(createNode(modifierKind, modifierStart));
if (!modifiers) {
modifiers = createNodeArray([modifier], modifierStart);
}
else {
modifiers.push(modifier);
}
}
if (modifiers) {
modifiers.end = scanner.getStartPos();
}
return modifiers;
}
function parseModifiersForArrowFunction() {
var modifiers;
if (token() === 119 /* AsyncKeyword */) {
var modifierStart = scanner.getStartPos();
var modifierKind = token();
nextToken();
var modifier = finishNode(createNode(modifierKind, modifierStart));
modifiers = createNodeArray([modifier], modifierStart);
modifiers.end = scanner.getStartPos();
}
return modifiers;
}
function parseClassElement() {
if (token() === 24 /* SemicolonToken */) {
var result = createNode(203 /* SemicolonClassElement */);
nextToken();
return finishNode(result);
}
var fullStart = getNodePos();
var decorators = parseDecorators();
var modifiers = parseModifiers(/*permitInvalidConstAsModifier*/ true);
var accessor = tryParseAccessorDeclaration(fullStart, decorators, modifiers);
if (accessor) {
return accessor;
}
if (token() === 122 /* ConstructorKeyword */) {
return parseConstructorDeclaration(fullStart, decorators, modifiers);
}
if (isIndexSignature()) {
return parseIndexSignatureDeclaration(fullStart, decorators, modifiers);
}
// It is very important that we check this *after* checking indexers because
// the [ token can start an index signature or a computed property name
if (ts.tokenIsIdentifierOrKeyword(token()) ||
token() === 9 /* StringLiteral */ ||
token() === 8 /* NumericLiteral */ ||
token() === 38 /* AsteriskToken */ ||
token() === 20 /* OpenBracketToken */) {
return parsePropertyOrMethodDeclaration(fullStart, decorators, modifiers);
}
if (decorators || modifiers) {
// treat this as a property declaration with a missing name.
var name_14 = createMissingNode(70 /* Identifier */, /*reportAtCurrentPosition*/ true, ts.Diagnostics.Declaration_expected);
return parsePropertyDeclaration(fullStart, decorators, modifiers, name_14, /*questionToken*/ undefined);
}
// 'isClassMemberStart' should have hinted not to attempt parsing.
ts.Debug.fail("Should not have attempted to parse class member declaration.");
}
function parseClassExpression() {
return parseClassDeclarationOrExpression(
/*fullStart*/ scanner.getStartPos(),
/*decorators*/ undefined,
/*modifiers*/ undefined, 197 /* ClassExpression */);
}
function parseClassDeclaration(fullStart, decorators, modifiers) {
return parseClassDeclarationOrExpression(fullStart, decorators, modifiers, 226 /* ClassDeclaration */);
}
function parseClassDeclarationOrExpression(fullStart, decorators, modifiers, kind) {
var node = createNode(kind, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
parseExpected(74 /* ClassKeyword */);
node.name = parseNameOfClassDeclarationOrExpression();
node.typeParameters = parseTypeParameters();
node.heritageClauses = parseHeritageClauses();
if (parseExpected(16 /* OpenBraceToken */)) {
// ClassTail[Yield,Await] : (Modified) See 14.5
// ClassHeritage[?Yield,?Await]opt { ClassBody[?Yield,?Await]opt }
node.members = parseClassMembers();
parseExpected(17 /* CloseBraceToken */);
}
else {
node.members = createMissingList();
}
return addJSDocComment(finishNode(node));
}
function parseNameOfClassDeclarationOrExpression() {
// implements is a future reserved word so
// 'class implements' might mean either
// - class expression with omitted name, 'implements' starts heritage clause
// - class with name 'implements'
// 'isImplementsClause' helps to disambiguate between these two cases
return isIdentifier() && !isImplementsClause()
? parseIdentifier()
: undefined;
}
function isImplementsClause() {
return token() === 107 /* ImplementsKeyword */ && lookAhead(nextTokenIsIdentifierOrKeyword);
}
function parseHeritageClauses() {
// ClassTail[Yield,Await] : (Modified) See 14.5
// ClassHeritage[?Yield,?Await]opt { ClassBody[?Yield,?Await]opt }
if (isHeritageClause()) {
return parseList(21 /* HeritageClauses */, parseHeritageClause);
}
return undefined;
}
function parseHeritageClause() {
if (token() === 84 /* ExtendsKeyword */ || token() === 107 /* ImplementsKeyword */) {
var node = createNode(255 /* HeritageClause */);
node.token = token();
nextToken();
node.types = parseDelimitedList(7 /* HeritageClauseElement */, parseExpressionWithTypeArguments);
return finishNode(node);
}
return undefined;
}
function parseExpressionWithTypeArguments() {
var node = createNode(199 /* ExpressionWithTypeArguments */);
node.expression = parseLeftHandSideExpressionOrHigher();
if (token() === 26 /* LessThanToken */) {
node.typeArguments = parseBracketedList(19 /* TypeArguments */, parseType, 26 /* LessThanToken */, 28 /* GreaterThanToken */);
}
return finishNode(node);
}
function isHeritageClause() {
return token() === 84 /* ExtendsKeyword */ || token() === 107 /* ImplementsKeyword */;
}
function parseClassMembers() {
return parseList(5 /* ClassMembers */, parseClassElement);
}
function parseInterfaceDeclaration(fullStart, decorators, modifiers) {
var node = createNode(227 /* InterfaceDeclaration */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
parseExpected(108 /* InterfaceKeyword */);
node.name = parseIdentifier();
node.typeParameters = parseTypeParameters();
node.heritageClauses = parseHeritageClauses();
node.members = parseObjectTypeMembers();
return addJSDocComment(finishNode(node));
}
function parseTypeAliasDeclaration(fullStart, decorators, modifiers) {
var node = createNode(228 /* TypeAliasDeclaration */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
parseExpected(136 /* TypeKeyword */);
node.name = parseIdentifier();
node.typeParameters = parseTypeParameters();
parseExpected(57 /* EqualsToken */);
node.type = parseType();
parseSemicolon();
return addJSDocComment(finishNode(node));
}
// In an ambient declaration, the grammar only allows integer literals as initializers.
// In a non-ambient declaration, the grammar allows uninitialized members only in a
// ConstantEnumMemberSection, which starts at the beginning of an enum declaration
// or any time an integer literal initializer is encountered.
function parseEnumMember() {
var node = createNode(260 /* EnumMember */, scanner.getStartPos());
node.name = parsePropertyName();
node.initializer = allowInAnd(parseNonParameterInitializer);
return addJSDocComment(finishNode(node));
}
function parseEnumDeclaration(fullStart, decorators, modifiers) {
var node = createNode(229 /* EnumDeclaration */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
parseExpected(82 /* EnumKeyword */);
node.name = parseIdentifier();
if (parseExpected(16 /* OpenBraceToken */)) {
node.members = parseDelimitedList(6 /* EnumMembers */, parseEnumMember);
parseExpected(17 /* CloseBraceToken */);
}
else {
node.members = createMissingList();
}
return addJSDocComment(finishNode(node));
}
function parseModuleBlock() {
var node = createNode(231 /* ModuleBlock */, scanner.getStartPos());
if (parseExpected(16 /* OpenBraceToken */)) {
node.statements = parseList(1 /* BlockStatements */, parseStatement);
parseExpected(17 /* CloseBraceToken */);
}
else {
node.statements = createMissingList();
}
return finishNode(node);
}
function parseModuleOrNamespaceDeclaration(fullStart, decorators, modifiers, flags) {
var node = createNode(230 /* ModuleDeclaration */, fullStart);
// If we are parsing a dotted namespace name, we want to
// propagate the 'Namespace' flag across the names if set.
var namespaceFlag = flags & 16 /* Namespace */;
node.decorators = decorators;
node.modifiers = modifiers;
node.flags |= flags;
node.name = parseIdentifier();
node.body = parseOptional(22 /* DotToken */)
? parseModuleOrNamespaceDeclaration(getNodePos(), /*decorators*/ undefined, /*modifiers*/ undefined, 4 /* NestedNamespace */ | namespaceFlag)
: parseModuleBlock();
return addJSDocComment(finishNode(node));
}
function parseAmbientExternalModuleDeclaration(fullStart, decorators, modifiers) {
var node = createNode(230 /* ModuleDeclaration */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
if (token() === 139 /* GlobalKeyword */) {
// parse 'global' as name of global scope augmentation
node.name = parseIdentifier();
node.flags |= 512 /* GlobalAugmentation */;
}
else {
node.name = parseLiteralNode(/*internName*/ true);
}
if (token() === 16 /* OpenBraceToken */) {
node.body = parseModuleBlock();
}
else {
parseSemicolon();
}
return finishNode(node);
}
function parseModuleDeclaration(fullStart, decorators, modifiers) {
var flags = 0;
if (token() === 139 /* GlobalKeyword */) {
// global augmentation
return parseAmbientExternalModuleDeclaration(fullStart, decorators, modifiers);
}
else if (parseOptional(128 /* NamespaceKeyword */)) {
flags |= 16 /* Namespace */;
}
else {
parseExpected(127 /* ModuleKeyword */);
if (token() === 9 /* StringLiteral */) {
return parseAmbientExternalModuleDeclaration(fullStart, decorators, modifiers);
}
}
return parseModuleOrNamespaceDeclaration(fullStart, decorators, modifiers, flags);
}
function isExternalModuleReference() {
return token() === 131 /* RequireKeyword */ &&
lookAhead(nextTokenIsOpenParen);
}
function nextTokenIsOpenParen() {
return nextToken() === 18 /* OpenParenToken */;
}
function nextTokenIsSlash() {
return nextToken() === 40 /* SlashToken */;
}
function parseNamespaceExportDeclaration(fullStart, decorators, modifiers) {
var exportDeclaration = createNode(233 /* NamespaceExportDeclaration */, fullStart);
exportDeclaration.decorators = decorators;
exportDeclaration.modifiers = modifiers;
parseExpected(117 /* AsKeyword */);
parseExpected(128 /* NamespaceKeyword */);
exportDeclaration.name = parseIdentifier();
parseSemicolon();
return finishNode(exportDeclaration);
}
function parseImportDeclarationOrImportEqualsDeclaration(fullStart, decorators, modifiers) {
parseExpected(90 /* ImportKeyword */);
var afterImportPos = scanner.getStartPos();
var identifier;
if (isIdentifier()) {
identifier = parseIdentifier();
if (token() !== 25 /* CommaToken */ && token() !== 138 /* FromKeyword */) {
// ImportEquals declaration of type:
// import x = require("mod"); or
// import x = M.x;
var importEqualsDeclaration = createNode(234 /* ImportEqualsDeclaration */, fullStart);
importEqualsDeclaration.decorators = decorators;
importEqualsDeclaration.modifiers = modifiers;
importEqualsDeclaration.name = identifier;
parseExpected(57 /* EqualsToken */);
importEqualsDeclaration.moduleReference = parseModuleReference();
parseSemicolon();
return addJSDocComment(finishNode(importEqualsDeclaration));
}
}
// Import statement
var importDeclaration = createNode(235 /* ImportDeclaration */, fullStart);
importDeclaration.decorators = decorators;
importDeclaration.modifiers = modifiers;
// ImportDeclaration:
// import ImportClause from ModuleSpecifier ;
// import ModuleSpecifier;
if (identifier ||
token() === 38 /* AsteriskToken */ ||
token() === 16 /* OpenBraceToken */) {
importDeclaration.importClause = parseImportClause(identifier, afterImportPos);
parseExpected(138 /* FromKeyword */);
}
importDeclaration.moduleSpecifier = parseModuleSpecifier();
parseSemicolon();
return finishNode(importDeclaration);
}
function parseImportClause(identifier, fullStart) {
// ImportClause:
// ImportedDefaultBinding
// NameSpaceImport
// NamedImports
// ImportedDefaultBinding, NameSpaceImport
// ImportedDefaultBinding, NamedImports
var importClause = createNode(236 /* ImportClause */, fullStart);
if (identifier) {
// ImportedDefaultBinding:
// ImportedBinding
importClause.name = identifier;
}
// If there was no default import or if there is comma token after default import
// parse namespace or named imports
if (!importClause.name ||
parseOptional(25 /* CommaToken */)) {
importClause.namedBindings = token() === 38 /* AsteriskToken */ ? parseNamespaceImport() : parseNamedImportsOrExports(238 /* NamedImports */);
}
return finishNode(importClause);
}
function parseModuleReference() {
return isExternalModuleReference()
? parseExternalModuleReference()
: parseEntityName(/*allowReservedWords*/ false);
}
function parseExternalModuleReference() {
var node = createNode(245 /* ExternalModuleReference */);
parseExpected(131 /* RequireKeyword */);
parseExpected(18 /* OpenParenToken */);
node.expression = parseModuleSpecifier();
parseExpected(19 /* CloseParenToken */);
return finishNode(node);
}
function parseModuleSpecifier() {
if (token() === 9 /* StringLiteral */) {
var result = parseLiteralNode();
internIdentifier(result.text);
return result;
}
else {
// We allow arbitrary expressions here, even though the grammar only allows string
// literals. We check to ensure that it is only a string literal later in the grammar
// check pass.
return parseExpression();
}
}
function parseNamespaceImport() {
// NameSpaceImport:
// * as ImportedBinding
var namespaceImport = createNode(237 /* NamespaceImport */);
parseExpected(38 /* AsteriskToken */);
parseExpected(117 /* AsKeyword */);
namespaceImport.name = parseIdentifier();
return finishNode(namespaceImport);
}
function parseNamedImportsOrExports(kind) {
var node = createNode(kind);
// NamedImports:
// { }
// { ImportsList }
// { ImportsList, }
// ImportsList:
// ImportSpecifier
// ImportsList, ImportSpecifier
node.elements = parseBracketedList(22 /* ImportOrExportSpecifiers */, kind === 238 /* NamedImports */ ? parseImportSpecifier : parseExportSpecifier, 16 /* OpenBraceToken */, 17 /* CloseBraceToken */);
return finishNode(node);
}
function parseExportSpecifier() {
return parseImportOrExportSpecifier(243 /* ExportSpecifier */);
}
function parseImportSpecifier() {
return parseImportOrExportSpecifier(239 /* ImportSpecifier */);
}
function parseImportOrExportSpecifier(kind) {
var node = createNode(kind);
// ImportSpecifier:
// BindingIdentifier
// IdentifierName as BindingIdentifier
// ExportSpecifier:
// IdentifierName
// IdentifierName as IdentifierName
var checkIdentifierIsKeyword = ts.isKeyword(token()) && !isIdentifier();
var checkIdentifierStart = scanner.getTokenPos();
var checkIdentifierEnd = scanner.getTextPos();
var identifierName = parseIdentifierName();
if (token() === 117 /* AsKeyword */) {
node.propertyName = identifierName;
parseExpected(117 /* AsKeyword */);
checkIdentifierIsKeyword = ts.isKeyword(token()) && !isIdentifier();
checkIdentifierStart = scanner.getTokenPos();
checkIdentifierEnd = scanner.getTextPos();
node.name = parseIdentifierName();
}
else {
node.name = identifierName;
}
if (kind === 239 /* ImportSpecifier */ && checkIdentifierIsKeyword) {
// Report error identifier expected
parseErrorAtPosition(checkIdentifierStart, checkIdentifierEnd - checkIdentifierStart, ts.Diagnostics.Identifier_expected);
}
return finishNode(node);
}
function parseExportDeclaration(fullStart, decorators, modifiers) {
var node = createNode(241 /* ExportDeclaration */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
if (parseOptional(38 /* AsteriskToken */)) {
parseExpected(138 /* FromKeyword */);
node.moduleSpecifier = parseModuleSpecifier();
}
else {
node.exportClause = parseNamedImportsOrExports(242 /* NamedExports */);
// It is not uncommon to accidentally omit the 'from' keyword. Additionally, in editing scenarios,
// the 'from' keyword can be parsed as a named export when the export clause is unterminated (i.e. `export { from "moduleName";`)
// If we don't have a 'from' keyword, see if we have a string literal such that ASI won't take effect.
if (token() === 138 /* FromKeyword */ || (token() === 9 /* StringLiteral */ && !scanner.hasPrecedingLineBreak())) {
parseExpected(138 /* FromKeyword */);
node.moduleSpecifier = parseModuleSpecifier();
}
}
parseSemicolon();
return finishNode(node);
}
function parseExportAssignment(fullStart, decorators, modifiers) {
var node = createNode(240 /* ExportAssignment */, fullStart);
node.decorators = decorators;
node.modifiers = modifiers;
if (parseOptional(57 /* EqualsToken */)) {
node.isExportEquals = true;
}
else {
parseExpected(78 /* DefaultKeyword */);
}
node.expression = parseAssignmentExpressionOrHigher();
parseSemicolon();
return finishNode(node);
}
function processReferenceComments(sourceFile) {
var triviaScanner = ts.createScanner(sourceFile.languageVersion, /*skipTrivia*/ false, 0 /* Standard */, sourceText);
var referencedFiles = [];
var typeReferenceDirectives = [];
var amdDependencies = [];
var amdModuleName;
// Keep scanning all the leading trivia in the file until we get to something that
// isn't trivia. Any single line comment will be analyzed to see if it is a
// reference comment.
while (true) {
var kind = triviaScanner.scan();
if (kind !== 2 /* SingleLineCommentTrivia */) {
if (ts.isTrivia(kind)) {
continue;
}
else {
break;
}
}
var range = { pos: triviaScanner.getTokenPos(), end: triviaScanner.getTextPos(), kind: triviaScanner.getToken() };
var comment = sourceText.substring(range.pos, range.end);
var referencePathMatchResult = ts.getFileReferenceFromReferencePath(comment, range);
if (referencePathMatchResult) {
var fileReference = referencePathMatchResult.fileReference;
sourceFile.hasNoDefaultLib = referencePathMatchResult.isNoDefaultLib;
var diagnosticMessage = referencePathMatchResult.diagnosticMessage;
if (fileReference) {
if (referencePathMatchResult.isTypeReferenceDirective) {
typeReferenceDirectives.push(fileReference);
}
else {
referencedFiles.push(fileReference);
}
}
if (diagnosticMessage) {
parseDiagnostics.push(ts.createFileDiagnostic(sourceFile, range.pos, range.end - range.pos, diagnosticMessage));
}
}
else {
var amdModuleNameRegEx = /^\/\/\/\s*<amd-module\s+name\s*=\s*('|")(.+?)\1/gim;
var amdModuleNameMatchResult = amdModuleNameRegEx.exec(comment);
if (amdModuleNameMatchResult) {
if (amdModuleName) {
parseDiagnostics.push(ts.createFileDiagnostic(sourceFile, range.pos, range.end - range.pos, ts.Diagnostics.An_AMD_module_cannot_have_multiple_name_assignments));
}
amdModuleName = amdModuleNameMatchResult[2];
}
var amdDependencyRegEx = /^\/\/\/\s*<amd-dependency\s/gim;
var pathRegex = /\spath\s*=\s*('|")(.+?)\1/gim;
var nameRegex = /\sname\s*=\s*('|")(.+?)\1/gim;
var amdDependencyMatchResult = amdDependencyRegEx.exec(comment);
if (amdDependencyMatchResult) {
var pathMatchResult = pathRegex.exec(comment);
var nameMatchResult = nameRegex.exec(comment);
if (pathMatchResult) {
var amdDependency = { path: pathMatchResult[2], name: nameMatchResult ? nameMatchResult[2] : undefined };
amdDependencies.push(amdDependency);
}
}
}
}
sourceFile.referencedFiles = referencedFiles;
sourceFile.typeReferenceDirectives = typeReferenceDirectives;
sourceFile.amdDependencies = amdDependencies;
sourceFile.moduleName = amdModuleName;
}
function setExternalModuleIndicator(sourceFile) {
sourceFile.externalModuleIndicator = ts.forEach(sourceFile.statements, function (node) {
return ts.hasModifier(node, 1 /* Export */)
|| node.kind === 234 /* ImportEqualsDeclaration */ && node.moduleReference.kind === 245 /* ExternalModuleReference */
|| node.kind === 235 /* ImportDeclaration */
|| node.kind === 240 /* ExportAssignment */
|| node.kind === 241 /* ExportDeclaration */
? node
: undefined;
});
}
var ParsingContext;
(function (ParsingContext) {
ParsingContext[ParsingContext["SourceElements"] = 0] = "SourceElements";
ParsingContext[ParsingContext["BlockStatements"] = 1] = "BlockStatements";
ParsingContext[ParsingContext["SwitchClauses"] = 2] = "SwitchClauses";
ParsingContext[ParsingContext["SwitchClauseStatements"] = 3] = "SwitchClauseStatements";
ParsingContext[ParsingContext["TypeMembers"] = 4] = "TypeMembers";
ParsingContext[ParsingContext["ClassMembers"] = 5] = "ClassMembers";
ParsingContext[ParsingContext["EnumMembers"] = 6] = "EnumMembers";
ParsingContext[ParsingContext["HeritageClauseElement"] = 7] = "HeritageClauseElement";
ParsingContext[ParsingContext["VariableDeclarations"] = 8] = "VariableDeclarations";
ParsingContext[ParsingContext["ObjectBindingElements"] = 9] = "ObjectBindingElements";
ParsingContext[ParsingContext["ArrayBindingElements"] = 10] = "ArrayBindingElements";
ParsingContext[ParsingContext["ArgumentExpressions"] = 11] = "ArgumentExpressions";
ParsingContext[ParsingContext["ObjectLiteralMembers"] = 12] = "ObjectLiteralMembers";
ParsingContext[ParsingContext["JsxAttributes"] = 13] = "JsxAttributes";
ParsingContext[ParsingContext["JsxChildren"] = 14] = "JsxChildren";
ParsingContext[ParsingContext["ArrayLiteralMembers"] = 15] = "ArrayLiteralMembers";
ParsingContext[ParsingContext["Parameters"] = 16] = "Parameters";
ParsingContext[ParsingContext["RestProperties"] = 17] = "RestProperties";
ParsingContext[ParsingContext["TypeParameters"] = 18] = "TypeParameters";
ParsingContext[ParsingContext["TypeArguments"] = 19] = "TypeArguments";
ParsingContext[ParsingContext["TupleElementTypes"] = 20] = "TupleElementTypes";
ParsingContext[ParsingContext["HeritageClauses"] = 21] = "HeritageClauses";
ParsingContext[ParsingContext["ImportOrExportSpecifiers"] = 22] = "ImportOrExportSpecifiers";
ParsingContext[ParsingContext["JSDocFunctionParameters"] = 23] = "JSDocFunctionParameters";
ParsingContext[ParsingContext["JSDocTypeArguments"] = 24] = "JSDocTypeArguments";
ParsingContext[ParsingContext["JSDocRecordMembers"] = 25] = "JSDocRecordMembers";
ParsingContext[ParsingContext["JSDocTupleTypes"] = 26] = "JSDocTupleTypes";
ParsingContext[ParsingContext["Count"] = 27] = "Count"; // Number of parsing contexts
})(ParsingContext || (ParsingContext = {}));
var Tristate;
(function (Tristate) {
Tristate[Tristate["False"] = 0] = "False";
Tristate[Tristate["True"] = 1] = "True";
Tristate[Tristate["Unknown"] = 2] = "Unknown";
})(Tristate || (Tristate = {}));
var JSDocParser;
(function (JSDocParser) {
function isJSDocType() {
switch (token()) {
case 38 /* AsteriskToken */:
case 54 /* QuestionToken */:
case 18 /* OpenParenToken */:
case 20 /* OpenBracketToken */:
case 50 /* ExclamationToken */:
case 16 /* OpenBraceToken */:
case 88 /* FunctionKeyword */:
case 23 /* DotDotDotToken */:
case 93 /* NewKeyword */:
case 98 /* ThisKeyword */:
return true;
}
return ts.tokenIsIdentifierOrKeyword(token());
}
JSDocParser.isJSDocType = isJSDocType;
function parseJSDocTypeExpressionForTests(content, start, length) {
initializeState(content, 5 /* Latest */, /*_syntaxCursor:*/ undefined, 1 /* JS */);
sourceFile = createSourceFile("file.js", 5 /* Latest */, 1 /* JS */);
scanner.setText(content, start, length);
currentToken = scanner.scan();
var jsDocTypeExpression = parseJSDocTypeExpression();
var diagnostics = parseDiagnostics;
clearState();
return jsDocTypeExpression ? { jsDocTypeExpression: jsDocTypeExpression, diagnostics: diagnostics } : undefined;
}
JSDocParser.parseJSDocTypeExpressionForTests = parseJSDocTypeExpressionForTests;
// Parses out a JSDoc type expression.
/* @internal */
function parseJSDocTypeExpression() {
var result = createNode(262 /* JSDocTypeExpression */, scanner.getTokenPos());
parseExpected(16 /* OpenBraceToken */);
result.type = parseJSDocTopLevelType();
parseExpected(17 /* CloseBraceToken */);
fixupParentReferences(result);
return finishNode(result);
}
JSDocParser.parseJSDocTypeExpression = parseJSDocTypeExpression;
function parseJSDocTopLevelType() {
var type = parseJSDocType();
if (token() === 48 /* BarToken */) {
var unionType = createNode(266 /* JSDocUnionType */, type.pos);
unionType.types = parseJSDocTypeList(type);
type = finishNode(unionType);
}
if (token() === 57 /* EqualsToken */) {
var optionalType = createNode(273 /* JSDocOptionalType */, type.pos);
nextToken();
optionalType.type = type;
type = finishNode(optionalType);
}
return type;
}
function parseJSDocType() {
var type = parseBasicTypeExpression();
while (true) {
if (token() === 20 /* OpenBracketToken */) {
var arrayType = createNode(265 /* JSDocArrayType */, type.pos);
arrayType.elementType = type;
nextToken();
parseExpected(21 /* CloseBracketToken */);
type = finishNode(arrayType);
}
else if (token() === 54 /* QuestionToken */) {
var nullableType = createNode(268 /* JSDocNullableType */, type.pos);
nullableType.type = type;
nextToken();
type = finishNode(nullableType);
}
else if (token() === 50 /* ExclamationToken */) {
var nonNullableType = createNode(269 /* JSDocNonNullableType */, type.pos);
nonNullableType.type = type;
nextToken();
type = finishNode(nonNullableType);
}
else {
break;
}
}
return type;
}
function parseBasicTypeExpression() {
switch (token()) {
case 38 /* AsteriskToken */:
return parseJSDocAllType();
case 54 /* QuestionToken */:
return parseJSDocUnknownOrNullableType();
case 18 /* OpenParenToken */:
return parseJSDocUnionType();
case 20 /* OpenBracketToken */:
return parseJSDocTupleType();
case 50 /* ExclamationToken */:
return parseJSDocNonNullableType();
case 16 /* OpenBraceToken */:
return parseJSDocRecordType();
case 88 /* FunctionKeyword */:
return parseJSDocFunctionType();
case 23 /* DotDotDotToken */:
return parseJSDocVariadicType();
case 93 /* NewKeyword */:
return parseJSDocConstructorType();
case 98 /* ThisKeyword */:
return parseJSDocThisType();
case 118 /* AnyKeyword */:
case 134 /* StringKeyword */:
case 132 /* NumberKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 104 /* VoidKeyword */:
case 94 /* NullKeyword */:
case 137 /* UndefinedKeyword */:
case 129 /* NeverKeyword */:
return parseTokenNode();
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
return parseJSDocLiteralType();
}
return parseJSDocTypeReference();
}
function parseJSDocThisType() {
var result = createNode(277 /* JSDocThisType */);
nextToken();
parseExpected(55 /* ColonToken */);
result.type = parseJSDocType();
return finishNode(result);
}
function parseJSDocConstructorType() {
var result = createNode(276 /* JSDocConstructorType */);
nextToken();
parseExpected(55 /* ColonToken */);
result.type = parseJSDocType();
return finishNode(result);
}
function parseJSDocVariadicType() {
var result = createNode(275 /* JSDocVariadicType */);
nextToken();
result.type = parseJSDocType();
return finishNode(result);
}
function parseJSDocFunctionType() {
var result = createNode(274 /* JSDocFunctionType */);
nextToken();
parseExpected(18 /* OpenParenToken */);
result.parameters = parseDelimitedList(23 /* JSDocFunctionParameters */, parseJSDocParameter);
checkForTrailingComma(result.parameters);
parseExpected(19 /* CloseParenToken */);
if (token() === 55 /* ColonToken */) {
nextToken();
result.type = parseJSDocType();
}
return finishNode(result);
}
function parseJSDocParameter() {
var parameter = createNode(144 /* Parameter */);
parameter.type = parseJSDocType();
if (parseOptional(57 /* EqualsToken */)) {
// TODO(rbuckton): Can this be changed to SyntaxKind.QuestionToken?
parameter.questionToken = createNode(57 /* EqualsToken */);
}
return finishNode(parameter);
}
function parseJSDocTypeReference() {
var result = createNode(272 /* JSDocTypeReference */);
result.name = parseSimplePropertyName();
if (token() === 26 /* LessThanToken */) {
result.typeArguments = parseTypeArguments();
}
else {
while (parseOptional(22 /* DotToken */)) {
if (token() === 26 /* LessThanToken */) {
result.typeArguments = parseTypeArguments();
break;
}
else {
result.name = parseQualifiedName(result.name);
}
}
}
return finishNode(result);
}
function parseTypeArguments() {
// Move past the <
nextToken();
var typeArguments = parseDelimitedList(24 /* JSDocTypeArguments */, parseJSDocType);
checkForTrailingComma(typeArguments);
checkForEmptyTypeArgumentList(typeArguments);
parseExpected(28 /* GreaterThanToken */);
return typeArguments;
}
function checkForEmptyTypeArgumentList(typeArguments) {
if (parseDiagnostics.length === 0 && typeArguments && typeArguments.length === 0) {
var start = typeArguments.pos - "<".length;
var end = ts.skipTrivia(sourceText, typeArguments.end) + ">".length;
return parseErrorAtPosition(start, end - start, ts.Diagnostics.Type_argument_list_cannot_be_empty);
}
}
function parseQualifiedName(left) {
var result = createNode(141 /* QualifiedName */, left.pos);
result.left = left;
result.right = parseIdentifierName();
return finishNode(result);
}
function parseJSDocRecordType() {
var result = createNode(270 /* JSDocRecordType */);
result.literal = parseTypeLiteral();
return finishNode(result);
}
function parseJSDocNonNullableType() {
var result = createNode(269 /* JSDocNonNullableType */);
nextToken();
result.type = parseJSDocType();
return finishNode(result);
}
function parseJSDocTupleType() {
var result = createNode(267 /* JSDocTupleType */);
nextToken();
result.types = parseDelimitedList(26 /* JSDocTupleTypes */, parseJSDocType);
checkForTrailingComma(result.types);
parseExpected(21 /* CloseBracketToken */);
return finishNode(result);
}
function checkForTrailingComma(list) {
if (parseDiagnostics.length === 0 && list.hasTrailingComma) {
var start = list.end - ",".length;
parseErrorAtPosition(start, ",".length, ts.Diagnostics.Trailing_comma_not_allowed);
}
}
function parseJSDocUnionType() {
var result = createNode(266 /* JSDocUnionType */);
nextToken();
result.types = parseJSDocTypeList(parseJSDocType());
parseExpected(19 /* CloseParenToken */);
return finishNode(result);
}
function parseJSDocTypeList(firstType) {
ts.Debug.assert(!!firstType);
var types = createNodeArray([firstType], firstType.pos);
while (parseOptional(48 /* BarToken */)) {
types.push(parseJSDocType());
}
types.end = scanner.getStartPos();
return types;
}
function parseJSDocAllType() {
var result = createNode(263 /* JSDocAllType */);
nextToken();
return finishNode(result);
}
function parseJSDocLiteralType() {
var result = createNode(287 /* JSDocLiteralType */);
result.literal = parseLiteralTypeNode();
return finishNode(result);
}
function parseJSDocUnknownOrNullableType() {
var pos = scanner.getStartPos();
// skip the ?
nextToken();
// Need to lookahead to decide if this is a nullable or unknown type.
// Here are cases where we'll pick the unknown type:
//
// Foo(?,
// { a: ? }
// Foo(?)
// Foo<?>
// Foo(?=
// (?|
if (token() === 25 /* CommaToken */ ||
token() === 17 /* CloseBraceToken */ ||
token() === 19 /* CloseParenToken */ ||
token() === 28 /* GreaterThanToken */ ||
token() === 57 /* EqualsToken */ ||
token() === 48 /* BarToken */) {
var result = createNode(264 /* JSDocUnknownType */, pos);
return finishNode(result);
}
else {
var result = createNode(268 /* JSDocNullableType */, pos);
result.type = parseJSDocType();
return finishNode(result);
}
}
function parseIsolatedJSDocComment(content, start, length) {
initializeState(content, 5 /* Latest */, /*_syntaxCursor:*/ undefined, 1 /* JS */);
sourceFile = { languageVariant: 0 /* Standard */, text: content };
var jsDoc = parseJSDocCommentWorker(start, length);
var diagnostics = parseDiagnostics;
clearState();
return jsDoc ? { jsDoc: jsDoc, diagnostics: diagnostics } : undefined;
}
JSDocParser.parseIsolatedJSDocComment = parseIsolatedJSDocComment;
function parseJSDocComment(parent, start, length) {
var saveToken = currentToken;
var saveParseDiagnosticsLength = parseDiagnostics.length;
var saveParseErrorBeforeNextFinishedNode = parseErrorBeforeNextFinishedNode;
var comment = parseJSDocCommentWorker(start, length);
if (comment) {
comment.parent = parent;
}
currentToken = saveToken;
parseDiagnostics.length = saveParseDiagnosticsLength;
parseErrorBeforeNextFinishedNode = saveParseErrorBeforeNextFinishedNode;
return comment;
}
JSDocParser.parseJSDocComment = parseJSDocComment;
var JSDocState;
(function (JSDocState) {
JSDocState[JSDocState["BeginningOfLine"] = 0] = "BeginningOfLine";
JSDocState[JSDocState["SawAsterisk"] = 1] = "SawAsterisk";
JSDocState[JSDocState["SavingComments"] = 2] = "SavingComments";
})(JSDocState || (JSDocState = {}));
function parseJSDocCommentWorker(start, length) {
var content = sourceText;
start = start || 0;
var end = length === undefined ? content.length : start + length;
length = end - start;
ts.Debug.assert(start >= 0);
ts.Debug.assert(start <= end);
ts.Debug.assert(end <= content.length);
var tags;
var comments = [];
var result;
// Check for /** (JSDoc opening part)
if (!isJsDocStart(content, start)) {
return result;
}
// + 3 for leading /**, - 5 in total for /** */
scanner.scanRange(start + 3, length - 5, function () {
// Initially we can parse out a tag. We also have seen a starting asterisk.
// This is so that /** * @type */ doesn't parse.
var advanceToken = true;
var state = 1 /* SawAsterisk */;
var margin = undefined;
// + 4 for leading '/** '
var indent = start - Math.max(content.lastIndexOf("\n", start), 0) + 4;
function pushComment(text) {
if (!margin) {
margin = indent;
}
comments.push(text);
indent += text.length;
}
nextJSDocToken();
while (token() === 5 /* WhitespaceTrivia */) {
nextJSDocToken();
}
if (token() === 4 /* NewLineTrivia */) {
state = 0 /* BeginningOfLine */;
indent = 0;
nextJSDocToken();
}
while (token() !== 1 /* EndOfFileToken */) {
switch (token()) {
case 56 /* AtToken */:
if (state === 0 /* BeginningOfLine */ || state === 1 /* SawAsterisk */) {
removeTrailingNewlines(comments);
parseTag(indent);
// NOTE: According to usejsdoc.org, a tag goes to end of line, except the last tag.
// Real-world comments may break this rule, so "BeginningOfLine" will not be a real line beginning
// for malformed examples like `/** @param {string} x @returns {number} the length */`
state = 0 /* BeginningOfLine */;
advanceToken = false;
margin = undefined;
indent++;
}
else {
pushComment(scanner.getTokenText());
}
break;
case 4 /* NewLineTrivia */:
comments.push(scanner.getTokenText());
state = 0 /* BeginningOfLine */;
indent = 0;
break;
case 38 /* AsteriskToken */:
var asterisk = scanner.getTokenText();
if (state === 1 /* SawAsterisk */) {
// If we've already seen an asterisk, then we can no longer parse a tag on this line
state = 2 /* SavingComments */;
pushComment(asterisk);
}
else {
// Ignore the first asterisk on a line
state = 1 /* SawAsterisk */;
indent += asterisk.length;
}
break;
case 70 /* Identifier */:
// Anything else is doc comment text. We just save it. Because it
// wasn't a tag, we can no longer parse a tag on this line until we hit the next
// line break.
pushComment(scanner.getTokenText());
state = 2 /* SavingComments */;
break;
case 5 /* WhitespaceTrivia */:
// only collect whitespace if we're already saving comments or have just crossed the comment indent margin
var whitespace = scanner.getTokenText();
if (state === 2 /* SavingComments */ || margin !== undefined && indent + whitespace.length > margin) {
comments.push(whitespace.slice(margin - indent - 1));
}
indent += whitespace.length;
break;
case 1 /* EndOfFileToken */:
break;
default:
pushComment(scanner.getTokenText());
break;
}
if (advanceToken) {
nextJSDocToken();
}
else {
advanceToken = true;
}
}
removeLeadingNewlines(comments);
removeTrailingNewlines(comments);
result = createJSDocComment();
});
return result;
function removeLeadingNewlines(comments) {
while (comments.length && (comments[0] === "\n" || comments[0] === "\r")) {
comments.shift();
}
}
function removeTrailingNewlines(comments) {
while (comments.length && (comments[comments.length - 1] === "\n" || comments[comments.length - 1] === "\r")) {
comments.pop();
}
}
function isJsDocStart(content, start) {
return content.charCodeAt(start) === 47 /* slash */ &&
content.charCodeAt(start + 1) === 42 /* asterisk */ &&
content.charCodeAt(start + 2) === 42 /* asterisk */ &&
content.charCodeAt(start + 3) !== 42 /* asterisk */;
}
function createJSDocComment() {
var result = createNode(278 /* JSDocComment */, start);
result.tags = tags;
result.comment = comments.length ? comments.join("") : undefined;
return finishNode(result, end);
}
function skipWhitespace() {
while (token() === 5 /* WhitespaceTrivia */ || token() === 4 /* NewLineTrivia */) {
nextJSDocToken();
}
}
function parseTag(indent) {
ts.Debug.assert(token() === 56 /* AtToken */);
var atToken = createNode(56 /* AtToken */, scanner.getTokenPos());
atToken.end = scanner.getTextPos();
nextJSDocToken();
var tagName = parseJSDocIdentifierName();
skipWhitespace();
if (!tagName) {
return;
}
var tag;
if (tagName) {
switch (tagName.text) {
case "param":
tag = parseParamTag(atToken, tagName);
break;
case "return":
case "returns":
tag = parseReturnTag(atToken, tagName);
break;
case "template":
tag = parseTemplateTag(atToken, tagName);
break;
case "type":
tag = parseTypeTag(atToken, tagName);
break;
case "typedef":
tag = parseTypedefTag(atToken, tagName);
break;
default:
tag = parseUnknownTag(atToken, tagName);
break;
}
}
else {
tag = parseUnknownTag(atToken, tagName);
}
if (!tag) {
// a badly malformed tag should not be added to the list of tags
return;
}
addTag(tag, parseTagComments(indent + tag.end - tag.pos));
}
function parseTagComments(indent) {
var comments = [];
var state = 1 /* SawAsterisk */;
var margin;
function pushComment(text) {
if (!margin) {
margin = indent;
}
comments.push(text);
indent += text.length;
}
while (token() !== 56 /* AtToken */ && token() !== 1 /* EndOfFileToken */) {
switch (token()) {
case 4 /* NewLineTrivia */:
if (state >= 1 /* SawAsterisk */) {
state = 0 /* BeginningOfLine */;
comments.push(scanner.getTokenText());
}
indent = 0;
break;
case 56 /* AtToken */:
// Done
break;
case 5 /* WhitespaceTrivia */:
if (state === 2 /* SavingComments */) {
pushComment(scanner.getTokenText());
}
else {
var whitespace = scanner.getTokenText();
// if the whitespace crosses the margin, take only the whitespace that passes the margin
if (margin !== undefined && indent + whitespace.length > margin) {
comments.push(whitespace.slice(margin - indent - 1));
}
indent += whitespace.length;
}
break;
case 38 /* AsteriskToken */:
if (state === 0 /* BeginningOfLine */) {
// leading asterisks start recording on the *next* (non-whitespace) token
state = 1 /* SawAsterisk */;
indent += scanner.getTokenText().length;
break;
}
// FALLTHROUGH otherwise to record the * as a comment
default:
state = 2 /* SavingComments */; // leading identifiers start recording as well
pushComment(scanner.getTokenText());
break;
}
if (token() === 56 /* AtToken */) {
// Done
break;
}
nextJSDocToken();
}
removeLeadingNewlines(comments);
removeTrailingNewlines(comments);
return comments;
}
function parseUnknownTag(atToken, tagName) {
var result = createNode(279 /* JSDocTag */, atToken.pos);
result.atToken = atToken;
result.tagName = tagName;
return finishNode(result);
}
function addTag(tag, comments) {
tag.comment = comments.join("");
if (!tags) {
tags = createNodeArray([tag], tag.pos);
}
else {
tags.push(tag);
}
tags.end = tag.end;
}
function tryParseTypeExpression() {
return tryParse(function () {
skipWhitespace();
if (token() !== 16 /* OpenBraceToken */) {
return undefined;
}
return parseJSDocTypeExpression();
});
}
function parseParamTag(atToken, tagName) {
var typeExpression = tryParseTypeExpression();
skipWhitespace();
var name;
var isBracketed;
// Looking for something like '[foo]' or 'foo'
if (parseOptionalToken(20 /* OpenBracketToken */)) {
name = parseJSDocIdentifierName();
skipWhitespace();
isBracketed = true;
// May have an optional default, e.g. '[foo = 42]'
if (parseOptionalToken(57 /* EqualsToken */)) {
parseExpression();
}
parseExpected(21 /* CloseBracketToken */);
}
else if (ts.tokenIsIdentifierOrKeyword(token())) {
name = parseJSDocIdentifierName();
}
if (!name) {
parseErrorAtPosition(scanner.getStartPos(), 0, ts.Diagnostics.Identifier_expected);
return undefined;
}
var preName, postName;
if (typeExpression) {
postName = name;
}
else {
preName = name;
}
if (!typeExpression) {
typeExpression = tryParseTypeExpression();
}
var result = createNode(280 /* JSDocParameterTag */, atToken.pos);
result.atToken = atToken;
result.tagName = tagName;
result.preParameterName = preName;
result.typeExpression = typeExpression;
result.postParameterName = postName;
result.parameterName = postName || preName;
result.isBracketed = isBracketed;
return finishNode(result);
}
function parseReturnTag(atToken, tagName) {
if (ts.forEach(tags, function (t) { return t.kind === 281 /* JSDocReturnTag */; })) {
parseErrorAtPosition(tagName.pos, scanner.getTokenPos() - tagName.pos, ts.Diagnostics._0_tag_already_specified, tagName.text);
}
var result = createNode(281 /* JSDocReturnTag */, atToken.pos);
result.atToken = atToken;
result.tagName = tagName;
result.typeExpression = tryParseTypeExpression();
return finishNode(result);
}
function parseTypeTag(atToken, tagName) {
if (ts.forEach(tags, function (t) { return t.kind === 282 /* JSDocTypeTag */; })) {
parseErrorAtPosition(tagName.pos, scanner.getTokenPos() - tagName.pos, ts.Diagnostics._0_tag_already_specified, tagName.text);
}
var result = createNode(282 /* JSDocTypeTag */, atToken.pos);
result.atToken = atToken;
result.tagName = tagName;
result.typeExpression = tryParseTypeExpression();
return finishNode(result);
}
function parsePropertyTag(atToken, tagName) {
var typeExpression = tryParseTypeExpression();
skipWhitespace();
var name = parseJSDocIdentifierName();
skipWhitespace();
if (!name) {
parseErrorAtPosition(scanner.getStartPos(), /*length*/ 0, ts.Diagnostics.Identifier_expected);
return undefined;
}
var result = createNode(285 /* JSDocPropertyTag */, atToken.pos);
result.atToken = atToken;
result.tagName = tagName;
result.name = name;
result.typeExpression = typeExpression;
return finishNode(result);
}
function parseTypedefTag(atToken, tagName) {
var typeExpression = tryParseTypeExpression();
skipWhitespace();
var typedefTag = createNode(284 /* JSDocTypedefTag */, atToken.pos);
typedefTag.atToken = atToken;
typedefTag.tagName = tagName;
typedefTag.fullName = parseJSDocTypeNameWithNamespace(/*flags*/ 0);
if (typedefTag.fullName) {
var rightNode = typedefTag.fullName;
while (rightNode.kind !== 70 /* Identifier */) {
rightNode = rightNode.body;
}
typedefTag.name = rightNode;
}
typedefTag.typeExpression = typeExpression;
skipWhitespace();
if (typeExpression) {
if (typeExpression.type.kind === 272 /* JSDocTypeReference */) {
var jsDocTypeReference = typeExpression.type;
if (jsDocTypeReference.name.kind === 70 /* Identifier */) {
var name_15 = jsDocTypeReference.name;
if (name_15.text === "Object") {
typedefTag.jsDocTypeLiteral = scanChildTags();
}
}
}
if (!typedefTag.jsDocTypeLiteral) {
typedefTag.jsDocTypeLiteral = typeExpression.type;
}
}
else {
typedefTag.jsDocTypeLiteral = scanChildTags();
}
return finishNode(typedefTag);
function scanChildTags() {
var jsDocTypeLiteral = createNode(286 /* JSDocTypeLiteral */, scanner.getStartPos());
var resumePos = scanner.getStartPos();
var canParseTag = true;
var seenAsterisk = false;
var parentTagTerminated = false;
while (token() !== 1 /* EndOfFileToken */ && !parentTagTerminated) {
nextJSDocToken();
switch (token()) {
case 56 /* AtToken */:
if (canParseTag) {
parentTagTerminated = !tryParseChildTag(jsDocTypeLiteral);
if (!parentTagTerminated) {
resumePos = scanner.getStartPos();
}
}
seenAsterisk = false;
break;
case 4 /* NewLineTrivia */:
resumePos = scanner.getStartPos() - 1;
canParseTag = true;
seenAsterisk = false;
break;
case 38 /* AsteriskToken */:
if (seenAsterisk) {
canParseTag = false;
}
seenAsterisk = true;
break;
case 70 /* Identifier */:
canParseTag = false;
case 1 /* EndOfFileToken */:
break;
}
}
scanner.setTextPos(resumePos);
return finishNode(jsDocTypeLiteral);
}
function parseJSDocTypeNameWithNamespace(flags) {
var pos = scanner.getTokenPos();
var typeNameOrNamespaceName = parseJSDocIdentifierName();
if (typeNameOrNamespaceName && parseOptional(22 /* DotToken */)) {
var jsDocNamespaceNode = createNode(230 /* ModuleDeclaration */, pos);
jsDocNamespaceNode.flags |= flags;
jsDocNamespaceNode.name = typeNameOrNamespaceName;
jsDocNamespaceNode.body = parseJSDocTypeNameWithNamespace(4 /* NestedNamespace */);
return jsDocNamespaceNode;
}
if (typeNameOrNamespaceName && flags & 4 /* NestedNamespace */) {
typeNameOrNamespaceName.isInJSDocNamespace = true;
}
return typeNameOrNamespaceName;
}
}
function tryParseChildTag(parentTag) {
ts.Debug.assert(token() === 56 /* AtToken */);
var atToken = createNode(56 /* AtToken */, scanner.getStartPos());
atToken.end = scanner.getTextPos();
nextJSDocToken();
var tagName = parseJSDocIdentifierName();
skipWhitespace();
if (!tagName) {
return false;
}
switch (tagName.text) {
case "type":
if (parentTag.jsDocTypeTag) {
// already has a @type tag, terminate the parent tag now.
return false;
}
parentTag.jsDocTypeTag = parseTypeTag(atToken, tagName);
return true;
case "prop":
case "property":
var propertyTag = parsePropertyTag(atToken, tagName);
if (propertyTag) {
if (!parentTag.jsDocPropertyTags) {
parentTag.jsDocPropertyTags = [];
}
parentTag.jsDocPropertyTags.push(propertyTag);
return true;
}
// Error parsing property tag
return false;
}
return false;
}
function parseTemplateTag(atToken, tagName) {
if (ts.forEach(tags, function (t) { return t.kind === 283 /* JSDocTemplateTag */; })) {
parseErrorAtPosition(tagName.pos, scanner.getTokenPos() - tagName.pos, ts.Diagnostics._0_tag_already_specified, tagName.text);
}
// Type parameter list looks like '@template T,U,V'
var typeParameters = createNodeArray();
while (true) {
var name_16 = parseJSDocIdentifierName();
skipWhitespace();
if (!name_16) {
parseErrorAtPosition(scanner.getStartPos(), 0, ts.Diagnostics.Identifier_expected);
return undefined;
}
var typeParameter = createNode(143 /* TypeParameter */, name_16.pos);
typeParameter.name = name_16;
finishNode(typeParameter);
typeParameters.push(typeParameter);
if (token() === 25 /* CommaToken */) {
nextJSDocToken();
skipWhitespace();
}
else {
break;
}
}
var result = createNode(283 /* JSDocTemplateTag */, atToken.pos);
result.atToken = atToken;
result.tagName = tagName;
result.typeParameters = typeParameters;
finishNode(result);
typeParameters.end = result.end;
return result;
}
function nextJSDocToken() {
return currentToken = scanner.scanJSDocToken();
}
function parseJSDocIdentifierName() {
return createJSDocIdentifier(ts.tokenIsIdentifierOrKeyword(token()));
}
function createJSDocIdentifier(isIdentifier) {
if (!isIdentifier) {
parseErrorAtCurrentToken(ts.Diagnostics.Identifier_expected);
return undefined;
}
var pos = scanner.getTokenPos();
var end = scanner.getTextPos();
var result = createNode(70 /* Identifier */, pos);
result.text = content.substring(pos, end);
finishNode(result, end);
nextJSDocToken();
return result;
}
}
JSDocParser.parseJSDocCommentWorker = parseJSDocCommentWorker;
})(JSDocParser = Parser.JSDocParser || (Parser.JSDocParser = {}));
})(Parser || (Parser = {}));
var IncrementalParser;
(function (IncrementalParser) {
function updateSourceFile(sourceFile, newText, textChangeRange, aggressiveChecks) {
aggressiveChecks = aggressiveChecks || ts.Debug.shouldAssert(2 /* Aggressive */);
checkChangeRange(sourceFile, newText, textChangeRange, aggressiveChecks);
if (ts.textChangeRangeIsUnchanged(textChangeRange)) {
// if the text didn't change, then we can just return our current source file as-is.
return sourceFile;
}
if (sourceFile.statements.length === 0) {
// If we don't have any statements in the current source file, then there's no real
// way to incrementally parse. So just do a full parse instead.
return Parser.parseSourceFile(sourceFile.fileName, newText, sourceFile.languageVersion, /*syntaxCursor*/ undefined, /*setParentNodes*/ true, sourceFile.scriptKind);
}
// Make sure we're not trying to incrementally update a source file more than once. Once
// we do an update the original source file is considered unusable from that point onwards.
//
// This is because we do incremental parsing in-place. i.e. we take nodes from the old
// tree and give them new positions and parents. From that point on, trusting the old
// tree at all is not possible as far too much of it may violate invariants.
var incrementalSourceFile = sourceFile;
ts.Debug.assert(!incrementalSourceFile.hasBeenIncrementallyParsed);
incrementalSourceFile.hasBeenIncrementallyParsed = true;
var oldText = sourceFile.text;
var syntaxCursor = createSyntaxCursor(sourceFile);
// Make the actual change larger so that we know to reparse anything whose lookahead
// might have intersected the change.
var changeRange = extendToAffectedRange(sourceFile, textChangeRange);
checkChangeRange(sourceFile, newText, changeRange, aggressiveChecks);
// Ensure that extending the affected range only moved the start of the change range
// earlier in the file.
ts.Debug.assert(changeRange.span.start <= textChangeRange.span.start);
ts.Debug.assert(ts.textSpanEnd(changeRange.span) === ts.textSpanEnd(textChangeRange.span));
ts.Debug.assert(ts.textSpanEnd(ts.textChangeRangeNewSpan(changeRange)) === ts.textSpanEnd(ts.textChangeRangeNewSpan(textChangeRange)));
// The is the amount the nodes after the edit range need to be adjusted. It can be
// positive (if the edit added characters), negative (if the edit deleted characters)
// or zero (if this was a pure overwrite with nothing added/removed).
var delta = ts.textChangeRangeNewSpan(changeRange).length - changeRange.span.length;
// If we added or removed characters during the edit, then we need to go and adjust all
// the nodes after the edit. Those nodes may move forward (if we inserted chars) or they
// may move backward (if we deleted chars).
//
// Doing this helps us out in two ways. First, it means that any nodes/tokens we want
// to reuse are already at the appropriate position in the new text. That way when we
// reuse them, we don't have to figure out if they need to be adjusted. Second, it makes
// it very easy to determine if we can reuse a node. If the node's position is at where
// we are in the text, then we can reuse it. Otherwise we can't. If the node's position
// is ahead of us, then we'll need to rescan tokens. If the node's position is behind
// us, then we'll need to skip it or crumble it as appropriate
//
// We will also adjust the positions of nodes that intersect the change range as well.
// By doing this, we ensure that all the positions in the old tree are consistent, not
// just the positions of nodes entirely before/after the change range. By being
// consistent, we can then easily map from positions to nodes in the old tree easily.
//
// Also, mark any syntax elements that intersect the changed span. We know, up front,
// that we cannot reuse these elements.
updateTokenPositionsAndMarkElements(incrementalSourceFile, changeRange.span.start, ts.textSpanEnd(changeRange.span), ts.textSpanEnd(ts.textChangeRangeNewSpan(changeRange)), delta, oldText, newText, aggressiveChecks);
// Now that we've set up our internal incremental state just proceed and parse the
// source file in the normal fashion. When possible the parser will retrieve and
// reuse nodes from the old tree.
//
// Note: passing in 'true' for setNodeParents is very important. When incrementally
// parsing, we will be reusing nodes from the old tree, and placing it into new
// parents. If we don't set the parents now, we'll end up with an observably
// inconsistent tree. Setting the parents on the new tree should be very fast. We
// will immediately bail out of walking any subtrees when we can see that their parents
// are already correct.
var result = Parser.parseSourceFile(sourceFile.fileName, newText, sourceFile.languageVersion, syntaxCursor, /*setParentNodes*/ true, sourceFile.scriptKind);
return result;
}
IncrementalParser.updateSourceFile = updateSourceFile;
function moveElementEntirelyPastChangeRange(element, isArray, delta, oldText, newText, aggressiveChecks) {
if (isArray) {
visitArray(element);
}
else {
visitNode(element);
}
return;
function visitNode(node) {
var text = "";
if (aggressiveChecks && shouldCheckNode(node)) {
text = oldText.substring(node.pos, node.end);
}
// Ditch any existing LS children we may have created. This way we can avoid
// moving them forward.
if (node._children) {
node._children = undefined;
}
node.pos += delta;
node.end += delta;
if (aggressiveChecks && shouldCheckNode(node)) {
ts.Debug.assert(text === newText.substring(node.pos, node.end));
}
forEachChild(node, visitNode, visitArray);
if (node.jsDocComments) {
for (var _i = 0, _a = node.jsDocComments; _i < _a.length; _i++) {
var jsDocComment = _a[_i];
forEachChild(jsDocComment, visitNode, visitArray);
}
}
checkNodePositions(node, aggressiveChecks);
}
function visitArray(array) {
array._children = undefined;
array.pos += delta;
array.end += delta;
for (var _i = 0, array_9 = array; _i < array_9.length; _i++) {
var node = array_9[_i];
visitNode(node);
}
}
}
function shouldCheckNode(node) {
switch (node.kind) {
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
case 70 /* Identifier */:
return true;
}
return false;
}
function adjustIntersectingElement(element, changeStart, changeRangeOldEnd, changeRangeNewEnd, delta) {
ts.Debug.assert(element.end >= changeStart, "Adjusting an element that was entirely before the change range");
ts.Debug.assert(element.pos <= changeRangeOldEnd, "Adjusting an element that was entirely after the change range");
ts.Debug.assert(element.pos <= element.end);
// We have an element that intersects the change range in some way. It may have its
// start, or its end (or both) in the changed range. We want to adjust any part
// that intersects such that the final tree is in a consistent state. i.e. all
// children have spans within the span of their parent, and all siblings are ordered
// properly.
// We may need to update both the 'pos' and the 'end' of the element.
// If the 'pos' is before the start of the change, then we don't need to touch it.
// If it isn't, then the 'pos' must be inside the change. How we update it will
// depend if delta is positive or negative. If delta is positive then we have
// something like:
//
// -------------------AAA-----------------
// -------------------BBBCCCCCCC-----------------
//
// In this case, we consider any node that started in the change range to still be
// starting at the same position.
//
// however, if the delta is negative, then we instead have something like this:
//
// -------------------XXXYYYYYYY-----------------
// -------------------ZZZ-----------------
//
// In this case, any element that started in the 'X' range will keep its position.
// However any element that started after that will have their pos adjusted to be
// at the end of the new range. i.e. any node that started in the 'Y' range will
// be adjusted to have their start at the end of the 'Z' range.
//
// The element will keep its position if possible. Or Move backward to the new-end
// if it's in the 'Y' range.
element.pos = Math.min(element.pos, changeRangeNewEnd);
// If the 'end' is after the change range, then we always adjust it by the delta
// amount. However, if the end is in the change range, then how we adjust it
// will depend on if delta is positive or negative. If delta is positive then we
// have something like:
//
// -------------------AAA-----------------
// -------------------BBBCCCCCCC-----------------
//
// In this case, we consider any node that ended inside the change range to keep its
// end position.
//
// however, if the delta is negative, then we instead have something like this:
//
// -------------------XXXYYYYYYY-----------------
// -------------------ZZZ-----------------
//
// In this case, any element that ended in the 'X' range will keep its position.
// However any element that ended after that will have their pos adjusted to be
// at the end of the new range. i.e. any node that ended in the 'Y' range will
// be adjusted to have their end at the end of the 'Z' range.
if (element.end >= changeRangeOldEnd) {
// Element ends after the change range. Always adjust the end pos.
element.end += delta;
}
else {
// Element ends in the change range. The element will keep its position if
// possible. Or Move backward to the new-end if it's in the 'Y' range.
element.end = Math.min(element.end, changeRangeNewEnd);
}
ts.Debug.assert(element.pos <= element.end);
if (element.parent) {
ts.Debug.assert(element.pos >= element.parent.pos);
ts.Debug.assert(element.end <= element.parent.end);
}
}
function checkNodePositions(node, aggressiveChecks) {
if (aggressiveChecks) {
var pos_2 = node.pos;
forEachChild(node, function (child) {
ts.Debug.assert(child.pos >= pos_2);
pos_2 = child.end;
});
ts.Debug.assert(pos_2 <= node.end);
}
}
function updateTokenPositionsAndMarkElements(sourceFile, changeStart, changeRangeOldEnd, changeRangeNewEnd, delta, oldText, newText, aggressiveChecks) {
visitNode(sourceFile);
return;
function visitNode(child) {
ts.Debug.assert(child.pos <= child.end);
if (child.pos > changeRangeOldEnd) {
// Node is entirely past the change range. We need to move both its pos and
// end, forward or backward appropriately.
moveElementEntirelyPastChangeRange(child, /*isArray*/ false, delta, oldText, newText, aggressiveChecks);
return;
}
// Check if the element intersects the change range. If it does, then it is not
// reusable. Also, we'll need to recurse to see what constituent portions we may
// be able to use.
var fullEnd = child.end;
if (fullEnd >= changeStart) {
child.intersectsChange = true;
child._children = undefined;
// Adjust the pos or end (or both) of the intersecting element accordingly.
adjustIntersectingElement(child, changeStart, changeRangeOldEnd, changeRangeNewEnd, delta);
forEachChild(child, visitNode, visitArray);
checkNodePositions(child, aggressiveChecks);
return;
}
// Otherwise, the node is entirely before the change range. No need to do anything with it.
ts.Debug.assert(fullEnd < changeStart);
}
function visitArray(array) {
ts.Debug.assert(array.pos <= array.end);
if (array.pos > changeRangeOldEnd) {
// Array is entirely after the change range. We need to move it, and move any of
// its children.
moveElementEntirelyPastChangeRange(array, /*isArray*/ true, delta, oldText, newText, aggressiveChecks);
return;
}
// Check if the element intersects the change range. If it does, then it is not
// reusable. Also, we'll need to recurse to see what constituent portions we may
// be able to use.
var fullEnd = array.end;
if (fullEnd >= changeStart) {
array.intersectsChange = true;
array._children = undefined;
// Adjust the pos or end (or both) of the intersecting array accordingly.
adjustIntersectingElement(array, changeStart, changeRangeOldEnd, changeRangeNewEnd, delta);
for (var _i = 0, array_10 = array; _i < array_10.length; _i++) {
var node = array_10[_i];
visitNode(node);
}
return;
}
// Otherwise, the array is entirely before the change range. No need to do anything with it.
ts.Debug.assert(fullEnd < changeStart);
}
}
function extendToAffectedRange(sourceFile, changeRange) {
// Consider the following code:
// void foo() { /; }
//
// If the text changes with an insertion of / just before the semicolon then we end up with:
// void foo() { //; }
//
// If we were to just use the changeRange a is, then we would not rescan the { token
// (as it does not intersect the actual original change range). Because an edit may
// change the token touching it, we actually need to look back *at least* one token so
// that the prior token sees that change.
var maxLookahead = 1;
var start = changeRange.span.start;
// the first iteration aligns us with the change start. subsequent iteration move us to
// the left by maxLookahead tokens. We only need to do this as long as we're not at the
// start of the tree.
for (var i = 0; start > 0 && i <= maxLookahead; i++) {
var nearestNode = findNearestNodeStartingBeforeOrAtPosition(sourceFile, start);
ts.Debug.assert(nearestNode.pos <= start);
var position = nearestNode.pos;
start = Math.max(0, position - 1);
}
var finalSpan = ts.createTextSpanFromBounds(start, ts.textSpanEnd(changeRange.span));
var finalLength = changeRange.newLength + (changeRange.span.start - start);
return ts.createTextChangeRange(finalSpan, finalLength);
}
function findNearestNodeStartingBeforeOrAtPosition(sourceFile, position) {
var bestResult = sourceFile;
var lastNodeEntirelyBeforePosition;
forEachChild(sourceFile, visit);
if (lastNodeEntirelyBeforePosition) {
var lastChildOfLastEntireNodeBeforePosition = getLastChild(lastNodeEntirelyBeforePosition);
if (lastChildOfLastEntireNodeBeforePosition.pos > bestResult.pos) {
bestResult = lastChildOfLastEntireNodeBeforePosition;
}
}
return bestResult;
function getLastChild(node) {
while (true) {
var lastChild = getLastChildWorker(node);
if (lastChild) {
node = lastChild;
}
else {
return node;
}
}
}
function getLastChildWorker(node) {
var last = undefined;
forEachChild(node, function (child) {
if (ts.nodeIsPresent(child)) {
last = child;
}
});
return last;
}
function visit(child) {
if (ts.nodeIsMissing(child)) {
// Missing nodes are effectively invisible to us. We never even consider them
// When trying to find the nearest node before us.
return;
}
// If the child intersects this position, then this node is currently the nearest
// node that starts before the position.
if (child.pos <= position) {
if (child.pos >= bestResult.pos) {
// This node starts before the position, and is closer to the position than
// the previous best node we found. It is now the new best node.
bestResult = child;
}
// Now, the node may overlap the position, or it may end entirely before the
// position. If it overlaps with the position, then either it, or one of its
// children must be the nearest node before the position. So we can just
// recurse into this child to see if we can find something better.
if (position < child.end) {
// The nearest node is either this child, or one of the children inside
// of it. We've already marked this child as the best so far. Recurse
// in case one of the children is better.
forEachChild(child, visit);
// Once we look at the children of this node, then there's no need to
// continue any further.
return true;
}
else {
ts.Debug.assert(child.end <= position);
// The child ends entirely before this position. Say you have the following
// (where $ is the position)
//
// <complex expr 1> ? <complex expr 2> $ : <...> <...>
//
// We would want to find the nearest preceding node in "complex expr 2".
// To support that, we keep track of this node, and once we're done searching
// for a best node, we recurse down this node to see if we can find a good
// result in it.
//
// This approach allows us to quickly skip over nodes that are entirely
// before the position, while still allowing us to find any nodes in the
// last one that might be what we want.
lastNodeEntirelyBeforePosition = child;
}
}
else {
ts.Debug.assert(child.pos > position);
// We're now at a node that is entirely past the position we're searching for.
// This node (and all following nodes) could never contribute to the result,
// so just skip them by returning 'true' here.
return true;
}
}
}
function checkChangeRange(sourceFile, newText, textChangeRange, aggressiveChecks) {
var oldText = sourceFile.text;
if (textChangeRange) {
ts.Debug.assert((oldText.length - textChangeRange.span.length + textChangeRange.newLength) === newText.length);
if (aggressiveChecks || ts.Debug.shouldAssert(3 /* VeryAggressive */)) {
var oldTextPrefix = oldText.substr(0, textChangeRange.span.start);
var newTextPrefix = newText.substr(0, textChangeRange.span.start);
ts.Debug.assert(oldTextPrefix === newTextPrefix);
var oldTextSuffix = oldText.substring(ts.textSpanEnd(textChangeRange.span), oldText.length);
var newTextSuffix = newText.substring(ts.textSpanEnd(ts.textChangeRangeNewSpan(textChangeRange)), newText.length);
ts.Debug.assert(oldTextSuffix === newTextSuffix);
}
}
}
function createSyntaxCursor(sourceFile) {
var currentArray = sourceFile.statements;
var currentArrayIndex = 0;
ts.Debug.assert(currentArrayIndex < currentArray.length);
var current = currentArray[currentArrayIndex];
var lastQueriedPosition = -1 /* Value */;
return {
currentNode: function (position) {
// Only compute the current node if the position is different than the last time
// we were asked. The parser commonly asks for the node at the same position
// twice. Once to know if can read an appropriate list element at a certain point,
// and then to actually read and consume the node.
if (position !== lastQueriedPosition) {
// Much of the time the parser will need the very next node in the array that
// we just returned a node from.So just simply check for that case and move
// forward in the array instead of searching for the node again.
if (current && current.end === position && currentArrayIndex < (currentArray.length - 1)) {
currentArrayIndex++;
current = currentArray[currentArrayIndex];
}
// If we don't have a node, or the node we have isn't in the right position,
// then try to find a viable node at the position requested.
if (!current || current.pos !== position) {
findHighestListElementThatStartsAtPosition(position);
}
}
// Cache this query so that we don't do any extra work if the parser calls back
// into us. Note: this is very common as the parser will make pairs of calls like
// 'isListElement -> parseListElement'. If we were unable to find a node when
// called with 'isListElement', we don't want to redo the work when parseListElement
// is called immediately after.
lastQueriedPosition = position;
// Either we don'd have a node, or we have a node at the position being asked for.
ts.Debug.assert(!current || current.pos === position);
return current;
}
};
// Finds the highest element in the tree we can find that starts at the provided position.
// The element must be a direct child of some node list in the tree. This way after we
// return it, we can easily return its next sibling in the list.
function findHighestListElementThatStartsAtPosition(position) {
// Clear out any cached state about the last node we found.
currentArray = undefined;
currentArrayIndex = -1 /* Value */;
current = undefined;
// Recurse into the source file to find the highest node at this position.
forEachChild(sourceFile, visitNode, visitArray);
return;
function visitNode(node) {
if (position >= node.pos && position < node.end) {
// Position was within this node. Keep searching deeper to find the node.
forEachChild(node, visitNode, visitArray);
// don't proceed any further in the search.
return true;
}
// position wasn't in this node, have to keep searching.
return false;
}
function visitArray(array) {
if (position >= array.pos && position < array.end) {
// position was in this array. Search through this array to see if we find a
// viable element.
for (var i = 0, n = array.length; i < n; i++) {
var child = array[i];
if (child) {
if (child.pos === position) {
// Found the right node. We're done.
currentArray = array;
currentArrayIndex = i;
current = child;
return true;
}
else {
if (child.pos < position && position < child.end) {
// Position in somewhere within this child. Search in it and
// stop searching in this array.
forEachChild(child, visitNode, visitArray);
return true;
}
}
}
}
}
// position wasn't in this array, have to keep searching.
return false;
}
}
}
var InvalidPosition;
(function (InvalidPosition) {
InvalidPosition[InvalidPosition["Value"] = -1] = "Value";
})(InvalidPosition || (InvalidPosition = {}));
})(IncrementalParser || (IncrementalParser = {}));
})(ts || (ts = {}));
/// <reference path="utilities.ts"/>
/// <reference path="parser.ts"/>
/* @internal */
var ts;
(function (ts) {
var ModuleInstanceState;
(function (ModuleInstanceState) {
ModuleInstanceState[ModuleInstanceState["NonInstantiated"] = 0] = "NonInstantiated";
ModuleInstanceState[ModuleInstanceState["Instantiated"] = 1] = "Instantiated";
ModuleInstanceState[ModuleInstanceState["ConstEnumOnly"] = 2] = "ConstEnumOnly";
})(ModuleInstanceState = ts.ModuleInstanceState || (ts.ModuleInstanceState = {}));
function getModuleInstanceState(node) {
// A module is uninstantiated if it contains only
// 1. interface declarations, type alias declarations
if (node.kind === 227 /* InterfaceDeclaration */ || node.kind === 228 /* TypeAliasDeclaration */) {
return 0 /* NonInstantiated */;
}
else if (ts.isConstEnumDeclaration(node)) {
return 2 /* ConstEnumOnly */;
}
else if ((node.kind === 235 /* ImportDeclaration */ || node.kind === 234 /* ImportEqualsDeclaration */) && !(ts.hasModifier(node, 1 /* Export */))) {
return 0 /* NonInstantiated */;
}
else if (node.kind === 231 /* ModuleBlock */) {
var state_1 = 0 /* NonInstantiated */;
ts.forEachChild(node, function (n) {
switch (getModuleInstanceState(n)) {
case 0 /* NonInstantiated */:
// child is non-instantiated - continue searching
return false;
case 2 /* ConstEnumOnly */:
// child is const enum only - record state and continue searching
state_1 = 2 /* ConstEnumOnly */;
return false;
case 1 /* Instantiated */:
// child is instantiated - record state and stop
state_1 = 1 /* Instantiated */;
return true;
}
});
return state_1;
}
else if (node.kind === 230 /* ModuleDeclaration */) {
var body = node.body;
return body ? getModuleInstanceState(body) : 1 /* Instantiated */;
}
else if (node.kind === 70 /* Identifier */ && node.isInJSDocNamespace) {
return 0 /* NonInstantiated */;
}
else {
return 1 /* Instantiated */;
}
}
ts.getModuleInstanceState = getModuleInstanceState;
var ContainerFlags;
(function (ContainerFlags) {
// The current node is not a container, and no container manipulation should happen before
// recursing into it.
ContainerFlags[ContainerFlags["None"] = 0] = "None";
// The current node is a container. It should be set as the current container (and block-
// container) before recursing into it. The current node does not have locals. Examples:
//
// Classes, ObjectLiterals, TypeLiterals, Interfaces...
ContainerFlags[ContainerFlags["IsContainer"] = 1] = "IsContainer";
// The current node is a block-scoped-container. It should be set as the current block-
// container before recursing into it. Examples:
//
// Blocks (when not parented by functions), Catch clauses, For/For-in/For-of statements...
ContainerFlags[ContainerFlags["IsBlockScopedContainer"] = 2] = "IsBlockScopedContainer";
// The current node is the container of a control flow path. The current control flow should
// be saved and restored, and a new control flow initialized within the container.
ContainerFlags[ContainerFlags["IsControlFlowContainer"] = 4] = "IsControlFlowContainer";
ContainerFlags[ContainerFlags["IsFunctionLike"] = 8] = "IsFunctionLike";
ContainerFlags[ContainerFlags["IsFunctionExpression"] = 16] = "IsFunctionExpression";
ContainerFlags[ContainerFlags["HasLocals"] = 32] = "HasLocals";
ContainerFlags[ContainerFlags["IsInterface"] = 64] = "IsInterface";
ContainerFlags[ContainerFlags["IsObjectLiteralOrClassExpressionMethod"] = 128] = "IsObjectLiteralOrClassExpressionMethod";
})(ContainerFlags || (ContainerFlags = {}));
var binder = createBinder();
function bindSourceFile(file, options) {
ts.performance.mark("beforeBind");
binder(file, options);
ts.performance.mark("afterBind");
ts.performance.measure("Bind", "beforeBind", "afterBind");
}
ts.bindSourceFile = bindSourceFile;
function createBinder() {
var file;
var options;
var languageVersion;
var parent;
var container;
var blockScopeContainer;
var lastContainer;
var seenThisKeyword;
// state used by control flow analysis
var currentFlow;
var currentBreakTarget;
var currentContinueTarget;
var currentReturnTarget;
var currentTrueTarget;
var currentFalseTarget;
var preSwitchCaseFlow;
var activeLabels;
var hasExplicitReturn;
// state used for emit helpers
var emitFlags;
// If this file is an external module, then it is automatically in strict-mode according to
// ES6. If it is not an external module, then we'll determine if it is in strict mode or
// not depending on if we see "use strict" in certain places or if we hit a class/namespace
// or if compiler options contain alwaysStrict.
var inStrictMode;
var symbolCount = 0;
var Symbol;
var classifiableNames;
var unreachableFlow = { flags: 1 /* Unreachable */ };
var reportedUnreachableFlow = { flags: 1 /* Unreachable */ };
// state used to aggregate transform flags during bind.
var subtreeTransformFlags = 0 /* None */;
var skipTransformFlagAggregation;
function bindSourceFile(f, opts) {
file = f;
options = opts;
languageVersion = ts.getEmitScriptTarget(options);
inStrictMode = bindInStrictMode(file, opts);
classifiableNames = ts.createMap();
symbolCount = 0;
skipTransformFlagAggregation = ts.isDeclarationFile(file);
Symbol = ts.objectAllocator.getSymbolConstructor();
if (!file.locals) {
bind(file);
file.symbolCount = symbolCount;
file.classifiableNames = classifiableNames;
}
file = undefined;
options = undefined;
languageVersion = undefined;
parent = undefined;
container = undefined;
blockScopeContainer = undefined;
lastContainer = undefined;
seenThisKeyword = false;
currentFlow = undefined;
currentBreakTarget = undefined;
currentContinueTarget = undefined;
currentReturnTarget = undefined;
currentTrueTarget = undefined;
currentFalseTarget = undefined;
activeLabels = undefined;
hasExplicitReturn = false;
emitFlags = 0 /* None */;
subtreeTransformFlags = 0 /* None */;
}
return bindSourceFile;
function bindInStrictMode(file, opts) {
if (opts.alwaysStrict && !ts.isDeclarationFile(file)) {
// bind in strict mode source files with alwaysStrict option
return true;
}
else {
return !!file.externalModuleIndicator;
}
}
function createSymbol(flags, name) {
symbolCount++;
return new Symbol(flags, name);
}
function addDeclarationToSymbol(symbol, node, symbolFlags) {
symbol.flags |= symbolFlags;
node.symbol = symbol;
if (!symbol.declarations) {
symbol.declarations = [];
}
symbol.declarations.push(node);
if (symbolFlags & 1952 /* HasExports */ && !symbol.exports) {
symbol.exports = ts.createMap();
}
if (symbolFlags & 6240 /* HasMembers */ && !symbol.members) {
symbol.members = ts.createMap();
}
if (symbolFlags & 107455 /* Value */) {
var valueDeclaration = symbol.valueDeclaration;
if (!valueDeclaration ||
(valueDeclaration.kind !== node.kind && valueDeclaration.kind === 230 /* ModuleDeclaration */)) {
// other kinds of value declarations take precedence over modules
symbol.valueDeclaration = node;
}
}
}
// Should not be called on a declaration with a computed property name,
// unless it is a well known Symbol.
function getDeclarationName(node) {
if (node.name) {
if (ts.isAmbientModule(node)) {
return ts.isGlobalScopeAugmentation(node) ? "__global" : "\"" + node.name.text + "\"";
}
if (node.name.kind === 142 /* ComputedPropertyName */) {
var nameExpression = node.name.expression;
// treat computed property names where expression is string/numeric literal as just string/numeric literal
if (ts.isStringOrNumericLiteral(nameExpression.kind)) {
return nameExpression.text;
}
ts.Debug.assert(ts.isWellKnownSymbolSyntactically(nameExpression));
return ts.getPropertyNameForKnownSymbolName(nameExpression.name.text);
}
return node.name.text;
}
switch (node.kind) {
case 150 /* Constructor */:
return "__constructor";
case 158 /* FunctionType */:
case 153 /* CallSignature */:
return "__call";
case 159 /* ConstructorType */:
case 154 /* ConstructSignature */:
return "__new";
case 155 /* IndexSignature */:
return "__index";
case 241 /* ExportDeclaration */:
return "__export";
case 240 /* ExportAssignment */:
return node.isExportEquals ? "export=" : "default";
case 192 /* BinaryExpression */:
switch (ts.getSpecialPropertyAssignmentKind(node)) {
case 2 /* ModuleExports */:
// module.exports = ...
return "export=";
case 1 /* ExportsProperty */:
case 4 /* ThisProperty */:
// exports.x = ... or this.y = ...
return node.left.name.text;
case 3 /* PrototypeProperty */:
// className.prototype.methodName = ...
return node.left.expression.name.text;
}
ts.Debug.fail("Unknown binary declaration kind");
break;
case 225 /* FunctionDeclaration */:
case 226 /* ClassDeclaration */:
return ts.hasModifier(node, 512 /* Default */) ? "default" : undefined;
case 274 /* JSDocFunctionType */:
return ts.isJSDocConstructSignature(node) ? "__new" : "__call";
case 144 /* Parameter */:
// Parameters with names are handled at the top of this function. Parameters
// without names can only come from JSDocFunctionTypes.
ts.Debug.assert(node.parent.kind === 274 /* JSDocFunctionType */);
var functionType = node.parent;
var index = ts.indexOf(functionType.parameters, node);
return "arg" + index;
case 284 /* JSDocTypedefTag */:
var parentNode = node.parent && node.parent.parent;
var nameFromParentNode = void 0;
if (parentNode && parentNode.kind === 205 /* VariableStatement */) {
if (parentNode.declarationList.declarations.length > 0) {
var nameIdentifier = parentNode.declarationList.declarations[0].name;
if (nameIdentifier.kind === 70 /* Identifier */) {
nameFromParentNode = nameIdentifier.text;
}
}
}
return nameFromParentNode;
}
}
function getDisplayName(node) {
return node.name ? ts.declarationNameToString(node.name) : getDeclarationName(node);
}
/**
* Declares a Symbol for the node and adds it to symbols. Reports errors for conflicting identifier names.
* @param symbolTable - The symbol table which node will be added to.
* @param parent - node's parent declaration.
* @param node - The declaration to be added to the symbol table
* @param includes - The SymbolFlags that node has in addition to its declaration type (eg: export, ambient, etc.)
* @param excludes - The flags which node cannot be declared alongside in a symbol table. Used to report forbidden declarations.
*/
function declareSymbol(symbolTable, parent, node, includes, excludes) {
ts.Debug.assert(!ts.hasDynamicName(node));
var isDefaultExport = ts.hasModifier(node, 512 /* Default */);
// The exported symbol for an export default function/class node is always named "default"
var name = isDefaultExport && parent ? "default" : getDeclarationName(node);
var symbol;
if (name === undefined) {
symbol = createSymbol(0 /* None */, "__missing");
}
else {
// Check and see if the symbol table already has a symbol with this name. If not,
// create a new symbol with this name and add it to the table. Note that we don't
// give the new symbol any flags *yet*. This ensures that it will not conflict
// with the 'excludes' flags we pass in.
//
// If we do get an existing symbol, see if it conflicts with the new symbol we're
// creating. For example, a 'var' symbol and a 'class' symbol will conflict within
// the same symbol table. If we have a conflict, report the issue on each
// declaration we have for this symbol, and then create a new symbol for this
// declaration.
//
// Note that when properties declared in Javascript constructors
// (marked by isReplaceableByMethod) conflict with another symbol, the property loses.
// Always. This allows the common Javascript pattern of overwriting a prototype method
// with an bound instance method of the same type: `this.method = this.method.bind(this)`
//
// If we created a new symbol, either because we didn't have a symbol with this name
// in the symbol table, or we conflicted with an existing symbol, then just add this
// node as the sole declaration of the new symbol.
//
// Otherwise, we'll be merging into a compatible existing symbol (for example when
// you have multiple 'vars' with the same name in the same container). In this case
// just add this node into the declarations list of the symbol.
symbol = symbolTable[name] || (symbolTable[name] = createSymbol(0 /* None */, name));
if (name && (includes & 788448 /* Classifiable */)) {
classifiableNames[name] = name;
}
if (symbol.flags & excludes) {
if (symbol.isReplaceableByMethod) {
// Javascript constructor-declared symbols can be discarded in favor of
// prototype symbols like methods.
symbol = symbolTable[name] = createSymbol(0 /* None */, name);
}
else {
if (node.name) {
node.name.parent = node;
}
// Report errors every position with duplicate declaration
// Report errors on previous encountered declarations
var message_1 = symbol.flags & 2 /* BlockScopedVariable */
? ts.Diagnostics.Cannot_redeclare_block_scoped_variable_0
: ts.Diagnostics.Duplicate_identifier_0;
if (symbol.declarations && symbol.declarations.length) {
// If the current node is a default export of some sort, then check if
// there are any other default exports that we need to error on.
// We'll know whether we have other default exports depending on if `symbol` already has a declaration list set.
if (isDefaultExport) {
message_1 = ts.Diagnostics.A_module_cannot_have_multiple_default_exports;
}
else {
// This is to properly report an error in the case "export default { }" is after export default of class declaration or function declaration.
// Error on multiple export default in the following case:
// 1. multiple export default of class declaration or function declaration by checking NodeFlags.Default
// 2. multiple export default of export assignment. This one doesn't have NodeFlags.Default on (as export default doesn't considered as modifiers)
if (symbol.declarations && symbol.declarations.length &&
(isDefaultExport || (node.kind === 240 /* ExportAssignment */ && !node.isExportEquals))) {
message_1 = ts.Diagnostics.A_module_cannot_have_multiple_default_exports;
}
}
}
ts.forEach(symbol.declarations, function (declaration) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(declaration.name || declaration, message_1, getDisplayName(declaration)));
});
file.bindDiagnostics.push(ts.createDiagnosticForNode(node.name || node, message_1, getDisplayName(node)));
symbol = createSymbol(0 /* None */, name);
}
}
}
addDeclarationToSymbol(symbol, node, includes);
symbol.parent = parent;
return symbol;
}
function declareModuleMember(node, symbolFlags, symbolExcludes) {
var hasExportModifier = ts.getCombinedModifierFlags(node) & 1 /* Export */;
if (symbolFlags & 8388608 /* Alias */) {
if (node.kind === 243 /* ExportSpecifier */ || (node.kind === 234 /* ImportEqualsDeclaration */ && hasExportModifier)) {
return declareSymbol(container.symbol.exports, container.symbol, node, symbolFlags, symbolExcludes);
}
else {
return declareSymbol(container.locals, undefined, node, symbolFlags, symbolExcludes);
}
}
else {
// Exported module members are given 2 symbols: A local symbol that is classified with an ExportValue,
// ExportType, or ExportContainer flag, and an associated export symbol with all the correct flags set
// on it. There are 2 main reasons:
//
// 1. We treat locals and exports of the same name as mutually exclusive within a container.
// That means the binder will issue a Duplicate Identifier error if you mix locals and exports
// with the same name in the same container.
// TODO: Make this a more specific error and decouple it from the exclusion logic.
// 2. When we checkIdentifier in the checker, we set its resolved symbol to the local symbol,
// but return the export symbol (by calling getExportSymbolOfValueSymbolIfExported). That way
// when the emitter comes back to it, it knows not to qualify the name if it was found in a containing scope.
// NOTE: Nested ambient modules always should go to to 'locals' table to prevent their automatic merge
// during global merging in the checker. Why? The only case when ambient module is permitted inside another module is module augmentation
// and this case is specially handled. Module augmentations should only be merged with original module definition
// and should never be merged directly with other augmentation, and the latter case would be possible if automatic merge is allowed.
var isJSDocTypedefInJSDocNamespace = node.kind === 284 /* JSDocTypedefTag */ &&
node.name &&
node.name.kind === 70 /* Identifier */ &&
node.name.isInJSDocNamespace;
if ((!ts.isAmbientModule(node) && (hasExportModifier || container.flags & 32 /* ExportContext */)) || isJSDocTypedefInJSDocNamespace) {
var exportKind = (symbolFlags & 107455 /* Value */ ? 1048576 /* ExportValue */ : 0) |
(symbolFlags & 793064 /* Type */ ? 2097152 /* ExportType */ : 0) |
(symbolFlags & 1920 /* Namespace */ ? 4194304 /* ExportNamespace */ : 0);
var local = declareSymbol(container.locals, undefined, node, exportKind, symbolExcludes);
local.exportSymbol = declareSymbol(container.symbol.exports, container.symbol, node, symbolFlags, symbolExcludes);
node.localSymbol = local;
return local;
}
else {
return declareSymbol(container.locals, undefined, node, symbolFlags, symbolExcludes);
}
}
}
// All container nodes are kept on a linked list in declaration order. This list is used by
// the getLocalNameOfContainer function in the type checker to validate that the local name
// used for a container is unique.
function bindContainer(node, containerFlags) {
// Before we recurse into a node's children, we first save the existing parent, container
// and block-container. Then after we pop out of processing the children, we restore
// these saved values.
var saveContainer = container;
var savedBlockScopeContainer = blockScopeContainer;
// Depending on what kind of node this is, we may have to adjust the current container
// and block-container. If the current node is a container, then it is automatically
// considered the current block-container as well. Also, for containers that we know
// may contain locals, we proactively initialize the .locals field. We do this because
// it's highly likely that the .locals will be needed to place some child in (for example,
// a parameter, or variable declaration).
//
// However, we do not proactively create the .locals for block-containers because it's
// totally normal and common for block-containers to never actually have a block-scoped
// variable in them. We don't want to end up allocating an object for every 'block' we
// run into when most of them won't be necessary.
//
// Finally, if this is a block-container, then we clear out any existing .locals object
// it may contain within it. This happens in incremental scenarios. Because we can be
// reusing a node from a previous compilation, that node may have had 'locals' created
// for it. We must clear this so we don't accidentally move any stale data forward from
// a previous compilation.
if (containerFlags & 1 /* IsContainer */) {
container = blockScopeContainer = node;
if (containerFlags & 32 /* HasLocals */) {
container.locals = ts.createMap();
}
addToContainerChain(container);
}
else if (containerFlags & 2 /* IsBlockScopedContainer */) {
blockScopeContainer = node;
blockScopeContainer.locals = undefined;
}
if (containerFlags & 4 /* IsControlFlowContainer */) {
var saveCurrentFlow = currentFlow;
var saveBreakTarget = currentBreakTarget;
var saveContinueTarget = currentContinueTarget;
var saveReturnTarget = currentReturnTarget;
var saveActiveLabels = activeLabels;
var saveHasExplicitReturn = hasExplicitReturn;
var isIIFE = containerFlags & 16 /* IsFunctionExpression */ && !ts.hasModifier(node, 256 /* Async */) && !!ts.getImmediatelyInvokedFunctionExpression(node);
// A non-async IIFE is considered part of the containing control flow. Return statements behave
// similarly to break statements that exit to a label just past the statement body.
if (isIIFE) {
currentReturnTarget = createBranchLabel();
}
else {
currentFlow = { flags: 2 /* Start */ };
if (containerFlags & (16 /* IsFunctionExpression */ | 128 /* IsObjectLiteralOrClassExpressionMethod */)) {
currentFlow.container = node;
}
currentReturnTarget = undefined;
}
currentBreakTarget = undefined;
currentContinueTarget = undefined;
activeLabels = undefined;
hasExplicitReturn = false;
bindChildren(node);
// Reset all reachability check related flags on node (for incremental scenarios)
// Reset all emit helper flags on node (for incremental scenarios)
node.flags &= ~64896 /* ReachabilityAndEmitFlags */;
if (!(currentFlow.flags & 1 /* Unreachable */) && containerFlags & 8 /* IsFunctionLike */ && ts.nodeIsPresent(node.body)) {
node.flags |= 128 /* HasImplicitReturn */;
if (hasExplicitReturn)
node.flags |= 256 /* HasExplicitReturn */;
}
if (node.kind === 261 /* SourceFile */) {
node.flags |= emitFlags;
}
if (isIIFE) {
addAntecedent(currentReturnTarget, currentFlow);
currentFlow = finishFlowLabel(currentReturnTarget);
}
else {
currentFlow = saveCurrentFlow;
}
currentBreakTarget = saveBreakTarget;
currentContinueTarget = saveContinueTarget;
currentReturnTarget = saveReturnTarget;
activeLabels = saveActiveLabels;
hasExplicitReturn = saveHasExplicitReturn;
}
else if (containerFlags & 64 /* IsInterface */) {
seenThisKeyword = false;
bindChildren(node);
node.flags = seenThisKeyword ? node.flags | 64 /* ContainsThis */ : node.flags & ~64 /* ContainsThis */;
}
else {
bindChildren(node);
}
container = saveContainer;
blockScopeContainer = savedBlockScopeContainer;
}
function bindChildren(node) {
if (skipTransformFlagAggregation) {
bindChildrenWorker(node);
}
else if (node.transformFlags & 536870912 /* HasComputedFlags */) {
skipTransformFlagAggregation = true;
bindChildrenWorker(node);
skipTransformFlagAggregation = false;
subtreeTransformFlags |= node.transformFlags & ~getTransformFlagsSubtreeExclusions(node.kind);
}
else {
var savedSubtreeTransformFlags = subtreeTransformFlags;
subtreeTransformFlags = 0;
bindChildrenWorker(node);
subtreeTransformFlags = savedSubtreeTransformFlags | computeTransformFlagsForNode(node, subtreeTransformFlags);
}
}
function bindChildrenWorker(node) {
// Binding of JsDocComment should be done before the current block scope container changes.
// because the scope of JsDocComment should not be affected by whether the current node is a
// container or not.
if (ts.isInJavaScriptFile(node) && node.jsDocComments) {
ts.forEach(node.jsDocComments, bind);
}
if (checkUnreachable(node)) {
ts.forEachChild(node, bind);
return;
}
switch (node.kind) {
case 210 /* WhileStatement */:
bindWhileStatement(node);
break;
case 209 /* DoStatement */:
bindDoStatement(node);
break;
case 211 /* ForStatement */:
bindForStatement(node);
break;
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
bindForInOrForOfStatement(node);
break;
case 208 /* IfStatement */:
bindIfStatement(node);
break;
case 216 /* ReturnStatement */:
case 220 /* ThrowStatement */:
bindReturnOrThrow(node);
break;
case 215 /* BreakStatement */:
case 214 /* ContinueStatement */:
bindBreakOrContinueStatement(node);
break;
case 221 /* TryStatement */:
bindTryStatement(node);
break;
case 218 /* SwitchStatement */:
bindSwitchStatement(node);
break;
case 232 /* CaseBlock */:
bindCaseBlock(node);
break;
case 253 /* CaseClause */:
bindCaseClause(node);
break;
case 219 /* LabeledStatement */:
bindLabeledStatement(node);
break;
case 190 /* PrefixUnaryExpression */:
bindPrefixUnaryExpressionFlow(node);
break;
case 191 /* PostfixUnaryExpression */:
bindPostfixUnaryExpressionFlow(node);
break;
case 192 /* BinaryExpression */:
bindBinaryExpressionFlow(node);
break;
case 186 /* DeleteExpression */:
bindDeleteExpressionFlow(node);
break;
case 193 /* ConditionalExpression */:
bindConditionalExpressionFlow(node);
break;
case 223 /* VariableDeclaration */:
bindVariableDeclarationFlow(node);
break;
case 179 /* CallExpression */:
bindCallExpressionFlow(node);
break;
default:
ts.forEachChild(node, bind);
break;
}
}
function isNarrowingExpression(expr) {
switch (expr.kind) {
case 70 /* Identifier */:
case 98 /* ThisKeyword */:
case 177 /* PropertyAccessExpression */:
return isNarrowableReference(expr);
case 179 /* CallExpression */:
return hasNarrowableArgument(expr);
case 183 /* ParenthesizedExpression */:
return isNarrowingExpression(expr.expression);
case 192 /* BinaryExpression */:
return isNarrowingBinaryExpression(expr);
case 190 /* PrefixUnaryExpression */:
return expr.operator === 50 /* ExclamationToken */ && isNarrowingExpression(expr.operand);
}
return false;
}
function isNarrowableReference(expr) {
return expr.kind === 70 /* Identifier */ ||
expr.kind === 98 /* ThisKeyword */ ||
expr.kind === 177 /* PropertyAccessExpression */ && isNarrowableReference(expr.expression);
}
function hasNarrowableArgument(expr) {
if (expr.arguments) {
for (var _i = 0, _a = expr.arguments; _i < _a.length; _i++) {
var argument = _a[_i];
if (isNarrowableReference(argument)) {
return true;
}
}
}
if (expr.expression.kind === 177 /* PropertyAccessExpression */ &&
isNarrowableReference(expr.expression.expression)) {
return true;
}
return false;
}
function isNarrowingTypeofOperands(expr1, expr2) {
return expr1.kind === 187 /* TypeOfExpression */ && isNarrowableOperand(expr1.expression) && expr2.kind === 9 /* StringLiteral */;
}
function isNarrowingBinaryExpression(expr) {
switch (expr.operatorToken.kind) {
case 57 /* EqualsToken */:
return isNarrowableReference(expr.left);
case 31 /* EqualsEqualsToken */:
case 32 /* ExclamationEqualsToken */:
case 33 /* EqualsEqualsEqualsToken */:
case 34 /* ExclamationEqualsEqualsToken */:
return isNarrowableOperand(expr.left) || isNarrowableOperand(expr.right) ||
isNarrowingTypeofOperands(expr.right, expr.left) || isNarrowingTypeofOperands(expr.left, expr.right);
case 92 /* InstanceOfKeyword */:
return isNarrowableOperand(expr.left);
case 25 /* CommaToken */:
return isNarrowingExpression(expr.right);
}
return false;
}
function isNarrowableOperand(expr) {
switch (expr.kind) {
case 183 /* ParenthesizedExpression */:
return isNarrowableOperand(expr.expression);
case 192 /* BinaryExpression */:
switch (expr.operatorToken.kind) {
case 57 /* EqualsToken */:
return isNarrowableOperand(expr.left);
case 25 /* CommaToken */:
return isNarrowableOperand(expr.right);
}
}
return isNarrowableReference(expr);
}
function createBranchLabel() {
return {
flags: 4 /* BranchLabel */,
antecedents: undefined
};
}
function createLoopLabel() {
return {
flags: 8 /* LoopLabel */,
antecedents: undefined
};
}
function setFlowNodeReferenced(flow) {
// On first reference we set the Referenced flag, thereafter we set the Shared flag
flow.flags |= flow.flags & 512 /* Referenced */ ? 1024 /* Shared */ : 512 /* Referenced */;
}
function addAntecedent(label, antecedent) {
if (!(antecedent.flags & 1 /* Unreachable */) && !ts.contains(label.antecedents, antecedent)) {
(label.antecedents || (label.antecedents = [])).push(antecedent);
setFlowNodeReferenced(antecedent);
}
}
function createFlowCondition(flags, antecedent, expression) {
if (antecedent.flags & 1 /* Unreachable */) {
return antecedent;
}
if (!expression) {
return flags & 32 /* TrueCondition */ ? antecedent : unreachableFlow;
}
if (expression.kind === 100 /* TrueKeyword */ && flags & 64 /* FalseCondition */ ||
expression.kind === 85 /* FalseKeyword */ && flags & 32 /* TrueCondition */) {
return unreachableFlow;
}
if (!isNarrowingExpression(expression)) {
return antecedent;
}
setFlowNodeReferenced(antecedent);
return {
flags: flags,
expression: expression,
antecedent: antecedent
};
}
function createFlowSwitchClause(antecedent, switchStatement, clauseStart, clauseEnd) {
if (!isNarrowingExpression(switchStatement.expression)) {
return antecedent;
}
setFlowNodeReferenced(antecedent);
return {
flags: 128 /* SwitchClause */,
switchStatement: switchStatement,
clauseStart: clauseStart,
clauseEnd: clauseEnd,
antecedent: antecedent
};
}
function createFlowAssignment(antecedent, node) {
setFlowNodeReferenced(antecedent);
return {
flags: 16 /* Assignment */,
antecedent: antecedent,
node: node
};
}
function createFlowArrayMutation(antecedent, node) {
setFlowNodeReferenced(antecedent);
return {
flags: 256 /* ArrayMutation */,
antecedent: antecedent,
node: node
};
}
function finishFlowLabel(flow) {
var antecedents = flow.antecedents;
if (!antecedents) {
return unreachableFlow;
}
if (antecedents.length === 1) {
return antecedents[0];
}
return flow;
}
function isStatementCondition(node) {
var parent = node.parent;
switch (parent.kind) {
case 208 /* IfStatement */:
case 210 /* WhileStatement */:
case 209 /* DoStatement */:
return parent.expression === node;
case 211 /* ForStatement */:
case 193 /* ConditionalExpression */:
return parent.condition === node;
}
return false;
}
function isLogicalExpression(node) {
while (true) {
if (node.kind === 183 /* ParenthesizedExpression */) {
node = node.expression;
}
else if (node.kind === 190 /* PrefixUnaryExpression */ && node.operator === 50 /* ExclamationToken */) {
node = node.operand;
}
else {
return node.kind === 192 /* BinaryExpression */ && (node.operatorToken.kind === 52 /* AmpersandAmpersandToken */ ||
node.operatorToken.kind === 53 /* BarBarToken */);
}
}
}
function isTopLevelLogicalExpression(node) {
while (node.parent.kind === 183 /* ParenthesizedExpression */ ||
node.parent.kind === 190 /* PrefixUnaryExpression */ &&
node.parent.operator === 50 /* ExclamationToken */) {
node = node.parent;
}
return !isStatementCondition(node) && !isLogicalExpression(node.parent);
}
function bindCondition(node, trueTarget, falseTarget) {
var saveTrueTarget = currentTrueTarget;
var saveFalseTarget = currentFalseTarget;
currentTrueTarget = trueTarget;
currentFalseTarget = falseTarget;
bind(node);
currentTrueTarget = saveTrueTarget;
currentFalseTarget = saveFalseTarget;
if (!node || !isLogicalExpression(node)) {
addAntecedent(trueTarget, createFlowCondition(32 /* TrueCondition */, currentFlow, node));
addAntecedent(falseTarget, createFlowCondition(64 /* FalseCondition */, currentFlow, node));
}
}
function bindIterativeStatement(node, breakTarget, continueTarget) {
var saveBreakTarget = currentBreakTarget;
var saveContinueTarget = currentContinueTarget;
currentBreakTarget = breakTarget;
currentContinueTarget = continueTarget;
bind(node);
currentBreakTarget = saveBreakTarget;
currentContinueTarget = saveContinueTarget;
}
function bindWhileStatement(node) {
var preWhileLabel = createLoopLabel();
var preBodyLabel = createBranchLabel();
var postWhileLabel = createBranchLabel();
addAntecedent(preWhileLabel, currentFlow);
currentFlow = preWhileLabel;
bindCondition(node.expression, preBodyLabel, postWhileLabel);
currentFlow = finishFlowLabel(preBodyLabel);
bindIterativeStatement(node.statement, postWhileLabel, preWhileLabel);
addAntecedent(preWhileLabel, currentFlow);
currentFlow = finishFlowLabel(postWhileLabel);
}
function bindDoStatement(node) {
var preDoLabel = createLoopLabel();
var enclosingLabeledStatement = node.parent.kind === 219 /* LabeledStatement */
? ts.lastOrUndefined(activeLabels)
: undefined;
// if do statement is wrapped in labeled statement then target labels for break/continue with or without
// label should be the same
var preConditionLabel = enclosingLabeledStatement ? enclosingLabeledStatement.continueTarget : createBranchLabel();
var postDoLabel = enclosingLabeledStatement ? enclosingLabeledStatement.breakTarget : createBranchLabel();
addAntecedent(preDoLabel, currentFlow);
currentFlow = preDoLabel;
bindIterativeStatement(node.statement, postDoLabel, preConditionLabel);
addAntecedent(preConditionLabel, currentFlow);
currentFlow = finishFlowLabel(preConditionLabel);
bindCondition(node.expression, preDoLabel, postDoLabel);
currentFlow = finishFlowLabel(postDoLabel);
}
function bindForStatement(node) {
var preLoopLabel = createLoopLabel();
var preBodyLabel = createBranchLabel();
var postLoopLabel = createBranchLabel();
bind(node.initializer);
addAntecedent(preLoopLabel, currentFlow);
currentFlow = preLoopLabel;
bindCondition(node.condition, preBodyLabel, postLoopLabel);
currentFlow = finishFlowLabel(preBodyLabel);
bindIterativeStatement(node.statement, postLoopLabel, preLoopLabel);
bind(node.incrementor);
addAntecedent(preLoopLabel, currentFlow);
currentFlow = finishFlowLabel(postLoopLabel);
}
function bindForInOrForOfStatement(node) {
var preLoopLabel = createLoopLabel();
var postLoopLabel = createBranchLabel();
addAntecedent(preLoopLabel, currentFlow);
currentFlow = preLoopLabel;
bind(node.expression);
addAntecedent(postLoopLabel, currentFlow);
bind(node.initializer);
if (node.initializer.kind !== 224 /* VariableDeclarationList */) {
bindAssignmentTargetFlow(node.initializer);
}
bindIterativeStatement(node.statement, postLoopLabel, preLoopLabel);
addAntecedent(preLoopLabel, currentFlow);
currentFlow = finishFlowLabel(postLoopLabel);
}
function bindIfStatement(node) {
var thenLabel = createBranchLabel();
var elseLabel = createBranchLabel();
var postIfLabel = createBranchLabel();
bindCondition(node.expression, thenLabel, elseLabel);
currentFlow = finishFlowLabel(thenLabel);
bind(node.thenStatement);
addAntecedent(postIfLabel, currentFlow);
currentFlow = finishFlowLabel(elseLabel);
bind(node.elseStatement);
addAntecedent(postIfLabel, currentFlow);
currentFlow = finishFlowLabel(postIfLabel);
}
function bindReturnOrThrow(node) {
bind(node.expression);
if (node.kind === 216 /* ReturnStatement */) {
hasExplicitReturn = true;
if (currentReturnTarget) {
addAntecedent(currentReturnTarget, currentFlow);
}
}
currentFlow = unreachableFlow;
}
function findActiveLabel(name) {
if (activeLabels) {
for (var _i = 0, activeLabels_1 = activeLabels; _i < activeLabels_1.length; _i++) {
var label = activeLabels_1[_i];
if (label.name === name) {
return label;
}
}
}
return undefined;
}
function bindbreakOrContinueFlow(node, breakTarget, continueTarget) {
var flowLabel = node.kind === 215 /* BreakStatement */ ? breakTarget : continueTarget;
if (flowLabel) {
addAntecedent(flowLabel, currentFlow);
currentFlow = unreachableFlow;
}
}
function bindBreakOrContinueStatement(node) {
bind(node.label);
if (node.label) {
var activeLabel = findActiveLabel(node.label.text);
if (activeLabel) {
activeLabel.referenced = true;
bindbreakOrContinueFlow(node, activeLabel.breakTarget, activeLabel.continueTarget);
}
}
else {
bindbreakOrContinueFlow(node, currentBreakTarget, currentContinueTarget);
}
}
function bindTryStatement(node) {
var preFinallyLabel = createBranchLabel();
var preTryFlow = currentFlow;
// TODO: Every statement in try block is potentially an exit point!
bind(node.tryBlock);
addAntecedent(preFinallyLabel, currentFlow);
var flowAfterTry = currentFlow;
var flowAfterCatch = unreachableFlow;
if (node.catchClause) {
currentFlow = preTryFlow;
bind(node.catchClause);
addAntecedent(preFinallyLabel, currentFlow);
flowAfterCatch = currentFlow;
}
if (node.finallyBlock) {
// in finally flow is combined from pre-try/flow from try/flow from catch
// pre-flow is necessary to make sure that finally is reachable even if finally flows in both try and finally blocks are unreachable
addAntecedent(preFinallyLabel, preTryFlow);
currentFlow = finishFlowLabel(preFinallyLabel);
bind(node.finallyBlock);
// if flow after finally is unreachable - keep it
// otherwise check if flows after try and after catch are unreachable
// if yes - convert current flow to unreachable
// i.e.
// try { return "1" } finally { console.log(1); }
// console.log(2); // this line should be unreachable even if flow falls out of finally block
if (!(currentFlow.flags & 1 /* Unreachable */)) {
if ((flowAfterTry.flags & 1 /* Unreachable */) && (flowAfterCatch.flags & 1 /* Unreachable */)) {
currentFlow = flowAfterTry === reportedUnreachableFlow || flowAfterCatch === reportedUnreachableFlow
? reportedUnreachableFlow
: unreachableFlow;
}
}
}
else {
currentFlow = finishFlowLabel(preFinallyLabel);
}
}
function bindSwitchStatement(node) {
var postSwitchLabel = createBranchLabel();
bind(node.expression);
var saveBreakTarget = currentBreakTarget;
var savePreSwitchCaseFlow = preSwitchCaseFlow;
currentBreakTarget = postSwitchLabel;
preSwitchCaseFlow = currentFlow;
bind(node.caseBlock);
addAntecedent(postSwitchLabel, currentFlow);
var hasDefault = ts.forEach(node.caseBlock.clauses, function (c) { return c.kind === 254 /* DefaultClause */; });
// We mark a switch statement as possibly exhaustive if it has no default clause and if all
// case clauses have unreachable end points (e.g. they all return).
node.possiblyExhaustive = !hasDefault && !postSwitchLabel.antecedents;
if (!hasDefault) {
addAntecedent(postSwitchLabel, createFlowSwitchClause(preSwitchCaseFlow, node, 0, 0));
}
currentBreakTarget = saveBreakTarget;
preSwitchCaseFlow = savePreSwitchCaseFlow;
currentFlow = finishFlowLabel(postSwitchLabel);
}
function bindCaseBlock(node) {
var clauses = node.clauses;
var fallthroughFlow = unreachableFlow;
for (var i = 0; i < clauses.length; i++) {
var clauseStart = i;
while (!clauses[i].statements.length && i + 1 < clauses.length) {
bind(clauses[i]);
i++;
}
var preCaseLabel = createBranchLabel();
addAntecedent(preCaseLabel, createFlowSwitchClause(preSwitchCaseFlow, node.parent, clauseStart, i + 1));
addAntecedent(preCaseLabel, fallthroughFlow);
currentFlow = finishFlowLabel(preCaseLabel);
var clause = clauses[i];
bind(clause);
fallthroughFlow = currentFlow;
if (!(currentFlow.flags & 1 /* Unreachable */) && i !== clauses.length - 1 && options.noFallthroughCasesInSwitch) {
errorOnFirstToken(clause, ts.Diagnostics.Fallthrough_case_in_switch);
}
}
}
function bindCaseClause(node) {
var saveCurrentFlow = currentFlow;
currentFlow = preSwitchCaseFlow;
bind(node.expression);
currentFlow = saveCurrentFlow;
ts.forEach(node.statements, bind);
}
function pushActiveLabel(name, breakTarget, continueTarget) {
var activeLabel = {
name: name,
breakTarget: breakTarget,
continueTarget: continueTarget,
referenced: false
};
(activeLabels || (activeLabels = [])).push(activeLabel);
return activeLabel;
}
function popActiveLabel() {
activeLabels.pop();
}
function bindLabeledStatement(node) {
var preStatementLabel = createLoopLabel();
var postStatementLabel = createBranchLabel();
bind(node.label);
addAntecedent(preStatementLabel, currentFlow);
var activeLabel = pushActiveLabel(node.label.text, postStatementLabel, preStatementLabel);
bind(node.statement);
popActiveLabel();
if (!activeLabel.referenced && !options.allowUnusedLabels) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(node.label, ts.Diagnostics.Unused_label));
}
if (!node.statement || node.statement.kind !== 209 /* DoStatement */) {
// do statement sets current flow inside bindDoStatement
addAntecedent(postStatementLabel, currentFlow);
currentFlow = finishFlowLabel(postStatementLabel);
}
}
function bindDestructuringTargetFlow(node) {
if (node.kind === 192 /* BinaryExpression */ && node.operatorToken.kind === 57 /* EqualsToken */) {
bindAssignmentTargetFlow(node.left);
}
else {
bindAssignmentTargetFlow(node);
}
}
function bindAssignmentTargetFlow(node) {
if (isNarrowableReference(node)) {
currentFlow = createFlowAssignment(currentFlow, node);
}
else if (node.kind === 175 /* ArrayLiteralExpression */) {
for (var _i = 0, _a = node.elements; _i < _a.length; _i++) {
var e = _a[_i];
if (e.kind === 196 /* SpreadElement */) {
bindAssignmentTargetFlow(e.expression);
}
else {
bindDestructuringTargetFlow(e);
}
}
}
else if (node.kind === 176 /* ObjectLiteralExpression */) {
for (var _b = 0, _c = node.properties; _b < _c.length; _b++) {
var p = _c[_b];
if (p.kind === 257 /* PropertyAssignment */) {
bindDestructuringTargetFlow(p.initializer);
}
else if (p.kind === 258 /* ShorthandPropertyAssignment */) {
bindAssignmentTargetFlow(p.name);
}
else if (p.kind === 259 /* SpreadAssignment */) {
bindAssignmentTargetFlow(p.expression);
}
}
}
}
function bindLogicalExpression(node, trueTarget, falseTarget) {
var preRightLabel = createBranchLabel();
if (node.operatorToken.kind === 52 /* AmpersandAmpersandToken */) {
bindCondition(node.left, preRightLabel, falseTarget);
}
else {
bindCondition(node.left, trueTarget, preRightLabel);
}
currentFlow = finishFlowLabel(preRightLabel);
bind(node.operatorToken);
bindCondition(node.right, trueTarget, falseTarget);
}
function bindPrefixUnaryExpressionFlow(node) {
if (node.operator === 50 /* ExclamationToken */) {
var saveTrueTarget = currentTrueTarget;
currentTrueTarget = currentFalseTarget;
currentFalseTarget = saveTrueTarget;
ts.forEachChild(node, bind);
currentFalseTarget = currentTrueTarget;
currentTrueTarget = saveTrueTarget;
}
else {
ts.forEachChild(node, bind);
if (node.operator === 42 /* PlusPlusToken */ || node.operator === 43 /* MinusMinusToken */) {
bindAssignmentTargetFlow(node.operand);
}
}
}
function bindPostfixUnaryExpressionFlow(node) {
ts.forEachChild(node, bind);
if (node.operator === 42 /* PlusPlusToken */ || node.operator === 43 /* MinusMinusToken */) {
bindAssignmentTargetFlow(node.operand);
}
}
function bindBinaryExpressionFlow(node) {
var operator = node.operatorToken.kind;
if (operator === 52 /* AmpersandAmpersandToken */ || operator === 53 /* BarBarToken */) {
if (isTopLevelLogicalExpression(node)) {
var postExpressionLabel = createBranchLabel();
bindLogicalExpression(node, postExpressionLabel, postExpressionLabel);
currentFlow = finishFlowLabel(postExpressionLabel);
}
else {
bindLogicalExpression(node, currentTrueTarget, currentFalseTarget);
}
}
else {
ts.forEachChild(node, bind);
if (ts.isAssignmentOperator(operator) && !ts.isAssignmentTarget(node)) {
bindAssignmentTargetFlow(node.left);
if (operator === 57 /* EqualsToken */ && node.left.kind === 178 /* ElementAccessExpression */) {
var elementAccess = node.left;
if (isNarrowableOperand(elementAccess.expression)) {
currentFlow = createFlowArrayMutation(currentFlow, node);
}
}
}
}
}
function bindDeleteExpressionFlow(node) {
ts.forEachChild(node, bind);
if (node.expression.kind === 177 /* PropertyAccessExpression */) {
bindAssignmentTargetFlow(node.expression);
}
}
function bindConditionalExpressionFlow(node) {
var trueLabel = createBranchLabel();
var falseLabel = createBranchLabel();
var postExpressionLabel = createBranchLabel();
bindCondition(node.condition, trueLabel, falseLabel);
currentFlow = finishFlowLabel(trueLabel);
bind(node.questionToken);
bind(node.whenTrue);
addAntecedent(postExpressionLabel, currentFlow);
currentFlow = finishFlowLabel(falseLabel);
bind(node.colonToken);
bind(node.whenFalse);
addAntecedent(postExpressionLabel, currentFlow);
currentFlow = finishFlowLabel(postExpressionLabel);
}
function bindInitializedVariableFlow(node) {
var name = !ts.isOmittedExpression(node) ? node.name : undefined;
if (ts.isBindingPattern(name)) {
for (var _i = 0, _a = name.elements; _i < _a.length; _i++) {
var child = _a[_i];
bindInitializedVariableFlow(child);
}
}
else {
currentFlow = createFlowAssignment(currentFlow, node);
}
}
function bindVariableDeclarationFlow(node) {
ts.forEachChild(node, bind);
if (node.initializer || node.parent.parent.kind === 212 /* ForInStatement */ || node.parent.parent.kind === 213 /* ForOfStatement */) {
bindInitializedVariableFlow(node);
}
}
function bindCallExpressionFlow(node) {
// If the target of the call expression is a function expression or arrow function we have
// an immediately invoked function expression (IIFE). Initialize the flowNode property to
// the current control flow (which includes evaluation of the IIFE arguments).
var expr = node.expression;
while (expr.kind === 183 /* ParenthesizedExpression */) {
expr = expr.expression;
}
if (expr.kind === 184 /* FunctionExpression */ || expr.kind === 185 /* ArrowFunction */) {
ts.forEach(node.typeArguments, bind);
ts.forEach(node.arguments, bind);
bind(node.expression);
}
else {
ts.forEachChild(node, bind);
}
if (node.expression.kind === 177 /* PropertyAccessExpression */) {
var propertyAccess = node.expression;
if (isNarrowableOperand(propertyAccess.expression) && ts.isPushOrUnshiftIdentifier(propertyAccess.name)) {
currentFlow = createFlowArrayMutation(currentFlow, node);
}
}
}
function getContainerFlags(node) {
switch (node.kind) {
case 197 /* ClassExpression */:
case 226 /* ClassDeclaration */:
case 229 /* EnumDeclaration */:
case 176 /* ObjectLiteralExpression */:
case 161 /* TypeLiteral */:
case 286 /* JSDocTypeLiteral */:
case 270 /* JSDocRecordType */:
return 1 /* IsContainer */;
case 227 /* InterfaceDeclaration */:
return 1 /* IsContainer */ | 64 /* IsInterface */;
case 274 /* JSDocFunctionType */:
case 230 /* ModuleDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 170 /* MappedType */:
return 1 /* IsContainer */ | 32 /* HasLocals */;
case 261 /* SourceFile */:
return 1 /* IsContainer */ | 4 /* IsControlFlowContainer */ | 32 /* HasLocals */;
case 149 /* MethodDeclaration */:
if (ts.isObjectLiteralOrClassExpressionMethod(node)) {
return 1 /* IsContainer */ | 4 /* IsControlFlowContainer */ | 32 /* HasLocals */ | 8 /* IsFunctionLike */ | 128 /* IsObjectLiteralOrClassExpressionMethod */;
}
case 150 /* Constructor */:
case 225 /* FunctionDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
return 1 /* IsContainer */ | 4 /* IsControlFlowContainer */ | 32 /* HasLocals */ | 8 /* IsFunctionLike */;
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return 1 /* IsContainer */ | 4 /* IsControlFlowContainer */ | 32 /* HasLocals */ | 8 /* IsFunctionLike */ | 16 /* IsFunctionExpression */;
case 231 /* ModuleBlock */:
return 4 /* IsControlFlowContainer */;
case 147 /* PropertyDeclaration */:
return node.initializer ? 4 /* IsControlFlowContainer */ : 0;
case 256 /* CatchClause */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 232 /* CaseBlock */:
return 2 /* IsBlockScopedContainer */;
case 204 /* Block */:
// do not treat blocks directly inside a function as a block-scoped-container.
// Locals that reside in this block should go to the function locals. Otherwise 'x'
// would not appear to be a redeclaration of a block scoped local in the following
// example:
//
// function foo() {
// var x;
// let x;
// }
//
// If we placed 'var x' into the function locals and 'let x' into the locals of
// the block, then there would be no collision.
//
// By not creating a new block-scoped-container here, we ensure that both 'var x'
// and 'let x' go into the Function-container's locals, and we do get a collision
// conflict.
return ts.isFunctionLike(node.parent) ? 0 /* None */ : 2 /* IsBlockScopedContainer */;
}
return 0 /* None */;
}
function addToContainerChain(next) {
if (lastContainer) {
lastContainer.nextContainer = next;
}
lastContainer = next;
}
function declareSymbolAndAddToSymbolTable(node, symbolFlags, symbolExcludes) {
// Just call this directly so that the return type of this function stays "void".
return declareSymbolAndAddToSymbolTableWorker(node, symbolFlags, symbolExcludes);
}
function declareSymbolAndAddToSymbolTableWorker(node, symbolFlags, symbolExcludes) {
switch (container.kind) {
// Modules, source files, and classes need specialized handling for how their
// members are declared (for example, a member of a class will go into a specific
// symbol table depending on if it is static or not). We defer to specialized
// handlers to take care of declaring these child members.
case 230 /* ModuleDeclaration */:
return declareModuleMember(node, symbolFlags, symbolExcludes);
case 261 /* SourceFile */:
return declareSourceFileMember(node, symbolFlags, symbolExcludes);
case 197 /* ClassExpression */:
case 226 /* ClassDeclaration */:
return declareClassMember(node, symbolFlags, symbolExcludes);
case 229 /* EnumDeclaration */:
return declareSymbol(container.symbol.exports, container.symbol, node, symbolFlags, symbolExcludes);
case 161 /* TypeLiteral */:
case 176 /* ObjectLiteralExpression */:
case 227 /* InterfaceDeclaration */:
case 270 /* JSDocRecordType */:
case 286 /* JSDocTypeLiteral */:
// Interface/Object-types always have their children added to the 'members' of
// their container. They are only accessible through an instance of their
// container, and are never in scope otherwise (even inside the body of the
// object / type / interface declaring them). An exception is type parameters,
// which are in scope without qualification (similar to 'locals').
return declareSymbol(container.symbol.members, container.symbol, node, symbolFlags, symbolExcludes);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 274 /* JSDocFunctionType */:
case 228 /* TypeAliasDeclaration */:
case 170 /* MappedType */:
// All the children of these container types are never visible through another
// symbol (i.e. through another symbol's 'exports' or 'members'). Instead,
// they're only accessed 'lexically' (i.e. from code that exists underneath
// their container in the tree. To accomplish this, we simply add their declared
// symbol to the 'locals' of the container. These symbols can then be found as
// the type checker walks up the containers, checking them for matching names.
return declareSymbol(container.locals, /*parent*/ undefined, node, symbolFlags, symbolExcludes);
}
}
function declareClassMember(node, symbolFlags, symbolExcludes) {
return ts.hasModifier(node, 32 /* Static */)
? declareSymbol(container.symbol.exports, container.symbol, node, symbolFlags, symbolExcludes)
: declareSymbol(container.symbol.members, container.symbol, node, symbolFlags, symbolExcludes);
}
function declareSourceFileMember(node, symbolFlags, symbolExcludes) {
return ts.isExternalModule(file)
? declareModuleMember(node, symbolFlags, symbolExcludes)
: declareSymbol(file.locals, undefined, node, symbolFlags, symbolExcludes);
}
function hasExportDeclarations(node) {
var body = node.kind === 261 /* SourceFile */ ? node : node.body;
if (body && (body.kind === 261 /* SourceFile */ || body.kind === 231 /* ModuleBlock */)) {
for (var _i = 0, _a = body.statements; _i < _a.length; _i++) {
var stat = _a[_i];
if (stat.kind === 241 /* ExportDeclaration */ || stat.kind === 240 /* ExportAssignment */) {
return true;
}
}
}
return false;
}
function setExportContextFlag(node) {
// A declaration source file or ambient module declaration that contains no export declarations (but possibly regular
// declarations with export modifiers) is an export context in which declarations are implicitly exported.
if (ts.isInAmbientContext(node) && !hasExportDeclarations(node)) {
node.flags |= 32 /* ExportContext */;
}
else {
node.flags &= ~32 /* ExportContext */;
}
}
function bindModuleDeclaration(node) {
setExportContextFlag(node);
if (ts.isAmbientModule(node)) {
if (ts.hasModifier(node, 1 /* Export */)) {
errorOnFirstToken(node, ts.Diagnostics.export_modifier_cannot_be_applied_to_ambient_modules_and_module_augmentations_since_they_are_always_visible);
}
if (ts.isExternalModuleAugmentation(node)) {
declareSymbolAndAddToSymbolTable(node, 1024 /* NamespaceModule */, 0 /* NamespaceModuleExcludes */);
}
else {
var pattern = void 0;
if (node.name.kind === 9 /* StringLiteral */) {
var text = node.name.text;
if (ts.hasZeroOrOneAsteriskCharacter(text)) {
pattern = ts.tryParsePattern(text);
}
else {
errorOnFirstToken(node.name, ts.Diagnostics.Pattern_0_can_have_at_most_one_Asterisk_character, text);
}
}
var symbol = declareSymbolAndAddToSymbolTable(node, 512 /* ValueModule */, 106639 /* ValueModuleExcludes */);
if (pattern) {
(file.patternAmbientModules || (file.patternAmbientModules = [])).push({ pattern: pattern, symbol: symbol });
}
}
}
else {
var state = getModuleInstanceState(node);
if (state === 0 /* NonInstantiated */) {
declareSymbolAndAddToSymbolTable(node, 1024 /* NamespaceModule */, 0 /* NamespaceModuleExcludes */);
}
else {
declareSymbolAndAddToSymbolTable(node, 512 /* ValueModule */, 106639 /* ValueModuleExcludes */);
if (node.symbol.flags & (16 /* Function */ | 32 /* Class */ | 256 /* RegularEnum */)) {
// if module was already merged with some function, class or non-const enum
// treat is a non-const-enum-only
node.symbol.constEnumOnlyModule = false;
}
else {
var currentModuleIsConstEnumOnly = state === 2 /* ConstEnumOnly */;
if (node.symbol.constEnumOnlyModule === undefined) {
// non-merged case - use the current state
node.symbol.constEnumOnlyModule = currentModuleIsConstEnumOnly;
}
else {
// merged case: module is const enum only if all its pieces are non-instantiated or const enum
node.symbol.constEnumOnlyModule = node.symbol.constEnumOnlyModule && currentModuleIsConstEnumOnly;
}
}
}
}
}
function bindFunctionOrConstructorType(node) {
// For a given function symbol "<...>(...) => T" we want to generate a symbol identical
// to the one we would get for: { <...>(...): T }
//
// We do that by making an anonymous type literal symbol, and then setting the function
// symbol as its sole member. To the rest of the system, this symbol will be indistinguishable
// from an actual type literal symbol you would have gotten had you used the long form.
var symbol = createSymbol(131072 /* Signature */, getDeclarationName(node));
addDeclarationToSymbol(symbol, node, 131072 /* Signature */);
var typeLiteralSymbol = createSymbol(2048 /* TypeLiteral */, "__type");
addDeclarationToSymbol(typeLiteralSymbol, node, 2048 /* TypeLiteral */);
typeLiteralSymbol.members = ts.createMap();
typeLiteralSymbol.members[symbol.name] = symbol;
}
function bindObjectLiteralExpression(node) {
var ElementKind;
(function (ElementKind) {
ElementKind[ElementKind["Property"] = 1] = "Property";
ElementKind[ElementKind["Accessor"] = 2] = "Accessor";
})(ElementKind || (ElementKind = {}));
if (inStrictMode) {
var seen = ts.createMap();
for (var _i = 0, _a = node.properties; _i < _a.length; _i++) {
var prop = _a[_i];
if (prop.kind === 259 /* SpreadAssignment */ || prop.name.kind !== 70 /* Identifier */) {
continue;
}
var identifier = prop.name;
// ECMA-262 11.1.5 Object Initializer
// If previous is not undefined then throw a SyntaxError exception if any of the following conditions are true
// a.This production is contained in strict code and IsDataDescriptor(previous) is true and
// IsDataDescriptor(propId.descriptor) is true.
// b.IsDataDescriptor(previous) is true and IsAccessorDescriptor(propId.descriptor) is true.
// c.IsAccessorDescriptor(previous) is true and IsDataDescriptor(propId.descriptor) is true.
// d.IsAccessorDescriptor(previous) is true and IsAccessorDescriptor(propId.descriptor) is true
// and either both previous and propId.descriptor have[[Get]] fields or both previous and propId.descriptor have[[Set]] fields
var currentKind = prop.kind === 257 /* PropertyAssignment */ || prop.kind === 258 /* ShorthandPropertyAssignment */ || prop.kind === 149 /* MethodDeclaration */
? 1 /* Property */
: 2 /* Accessor */;
var existingKind = seen[identifier.text];
if (!existingKind) {
seen[identifier.text] = currentKind;
continue;
}
if (currentKind === 1 /* Property */ && existingKind === 1 /* Property */) {
var span_1 = ts.getErrorSpanForNode(file, identifier);
file.bindDiagnostics.push(ts.createFileDiagnostic(file, span_1.start, span_1.length, ts.Diagnostics.An_object_literal_cannot_have_multiple_properties_with_the_same_name_in_strict_mode));
}
}
}
return bindAnonymousDeclaration(node, 4096 /* ObjectLiteral */, "__object");
}
function bindAnonymousDeclaration(node, symbolFlags, name) {
var symbol = createSymbol(symbolFlags, name);
addDeclarationToSymbol(symbol, node, symbolFlags);
}
function bindBlockScopedDeclaration(node, symbolFlags, symbolExcludes) {
switch (blockScopeContainer.kind) {
case 230 /* ModuleDeclaration */:
declareModuleMember(node, symbolFlags, symbolExcludes);
break;
case 261 /* SourceFile */:
if (ts.isExternalModule(container)) {
declareModuleMember(node, symbolFlags, symbolExcludes);
break;
}
// fall through.
default:
if (!blockScopeContainer.locals) {
blockScopeContainer.locals = ts.createMap();
addToContainerChain(blockScopeContainer);
}
declareSymbol(blockScopeContainer.locals, undefined, node, symbolFlags, symbolExcludes);
}
}
function bindBlockScopedVariableDeclaration(node) {
bindBlockScopedDeclaration(node, 2 /* BlockScopedVariable */, 107455 /* BlockScopedVariableExcludes */);
}
// The binder visits every node in the syntax tree so it is a convenient place to perform a single localized
// check for reserved words used as identifiers in strict mode code.
function checkStrictModeIdentifier(node) {
if (inStrictMode &&
node.originalKeywordKind >= 107 /* FirstFutureReservedWord */ &&
node.originalKeywordKind <= 115 /* LastFutureReservedWord */ &&
!ts.isIdentifierName(node) &&
!ts.isInAmbientContext(node)) {
// Report error only if there are no parse errors in file
if (!file.parseDiagnostics.length) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(node, getStrictModeIdentifierMessage(node), ts.declarationNameToString(node)));
}
}
}
function getStrictModeIdentifierMessage(node) {
// Provide specialized messages to help the user understand why we think they're in
// strict mode.
if (ts.getContainingClass(node)) {
return ts.Diagnostics.Identifier_expected_0_is_a_reserved_word_in_strict_mode_Class_definitions_are_automatically_in_strict_mode;
}
if (file.externalModuleIndicator) {
return ts.Diagnostics.Identifier_expected_0_is_a_reserved_word_in_strict_mode_Modules_are_automatically_in_strict_mode;
}
return ts.Diagnostics.Identifier_expected_0_is_a_reserved_word_in_strict_mode;
}
function checkStrictModeBinaryExpression(node) {
if (inStrictMode && ts.isLeftHandSideExpression(node.left) && ts.isAssignmentOperator(node.operatorToken.kind)) {
// ECMA 262 (Annex C) The identifier eval or arguments may not appear as the LeftHandSideExpression of an
// Assignment operator(11.13) or of a PostfixExpression(11.3)
checkStrictModeEvalOrArguments(node, node.left);
}
}
function checkStrictModeCatchClause(node) {
// It is a SyntaxError if a TryStatement with a Catch occurs within strict code and the Identifier of the
// Catch production is eval or arguments
if (inStrictMode && node.variableDeclaration) {
checkStrictModeEvalOrArguments(node, node.variableDeclaration.name);
}
}
function checkStrictModeDeleteExpression(node) {
// Grammar checking
if (inStrictMode && node.expression.kind === 70 /* Identifier */) {
// When a delete operator occurs within strict mode code, a SyntaxError is thrown if its
// UnaryExpression is a direct reference to a variable, function argument, or function name
var span_2 = ts.getErrorSpanForNode(file, node.expression);
file.bindDiagnostics.push(ts.createFileDiagnostic(file, span_2.start, span_2.length, ts.Diagnostics.delete_cannot_be_called_on_an_identifier_in_strict_mode));
}
}
function isEvalOrArgumentsIdentifier(node) {
return node.kind === 70 /* Identifier */ &&
(node.text === "eval" || node.text === "arguments");
}
function checkStrictModeEvalOrArguments(contextNode, name) {
if (name && name.kind === 70 /* Identifier */) {
var identifier = name;
if (isEvalOrArgumentsIdentifier(identifier)) {
// We check first if the name is inside class declaration or class expression; if so give explicit message
// otherwise report generic error message.
var span_3 = ts.getErrorSpanForNode(file, name);
file.bindDiagnostics.push(ts.createFileDiagnostic(file, span_3.start, span_3.length, getStrictModeEvalOrArgumentsMessage(contextNode), identifier.text));
}
}
}
function getStrictModeEvalOrArgumentsMessage(node) {
// Provide specialized messages to help the user understand why we think they're in
// strict mode.
if (ts.getContainingClass(node)) {
return ts.Diagnostics.Invalid_use_of_0_Class_definitions_are_automatically_in_strict_mode;
}
if (file.externalModuleIndicator) {
return ts.Diagnostics.Invalid_use_of_0_Modules_are_automatically_in_strict_mode;
}
return ts.Diagnostics.Invalid_use_of_0_in_strict_mode;
}
function checkStrictModeFunctionName(node) {
if (inStrictMode) {
// It is a SyntaxError if the identifier eval or arguments appears within a FormalParameterList of a strict mode FunctionDeclaration or FunctionExpression (13.1))
checkStrictModeEvalOrArguments(node, node.name);
}
}
function getStrictModeBlockScopeFunctionDeclarationMessage(node) {
// Provide specialized messages to help the user understand why we think they're in
// strict mode.
if (ts.getContainingClass(node)) {
return ts.Diagnostics.Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5_Class_definitions_are_automatically_in_strict_mode;
}
if (file.externalModuleIndicator) {
return ts.Diagnostics.Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5_Modules_are_automatically_in_strict_mode;
}
return ts.Diagnostics.Function_declarations_are_not_allowed_inside_blocks_in_strict_mode_when_targeting_ES3_or_ES5;
}
function checkStrictModeFunctionDeclaration(node) {
if (languageVersion < 2 /* ES2015 */) {
// Report error if function is not top level function declaration
if (blockScopeContainer.kind !== 261 /* SourceFile */ &&
blockScopeContainer.kind !== 230 /* ModuleDeclaration */ &&
!ts.isFunctionLike(blockScopeContainer)) {
// We check first if the name is inside class declaration or class expression; if so give explicit message
// otherwise report generic error message.
var errorSpan = ts.getErrorSpanForNode(file, node);
file.bindDiagnostics.push(ts.createFileDiagnostic(file, errorSpan.start, errorSpan.length, getStrictModeBlockScopeFunctionDeclarationMessage(node)));
}
}
}
function checkStrictModeNumericLiteral(node) {
if (inStrictMode && node.isOctalLiteral) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(node, ts.Diagnostics.Octal_literals_are_not_allowed_in_strict_mode));
}
}
function checkStrictModePostfixUnaryExpression(node) {
// Grammar checking
// The identifier eval or arguments may not appear as the LeftHandSideExpression of an
// Assignment operator(11.13) or of a PostfixExpression(11.3) or as the UnaryExpression
// operated upon by a Prefix Increment(11.4.4) or a Prefix Decrement(11.4.5) operator.
if (inStrictMode) {
checkStrictModeEvalOrArguments(node, node.operand);
}
}
function checkStrictModePrefixUnaryExpression(node) {
// Grammar checking
if (inStrictMode) {
if (node.operator === 42 /* PlusPlusToken */ || node.operator === 43 /* MinusMinusToken */) {
checkStrictModeEvalOrArguments(node, node.operand);
}
}
}
function checkStrictModeWithStatement(node) {
// Grammar checking for withStatement
if (inStrictMode) {
errorOnFirstToken(node, ts.Diagnostics.with_statements_are_not_allowed_in_strict_mode);
}
}
function errorOnFirstToken(node, message, arg0, arg1, arg2) {
var span = ts.getSpanOfTokenAtPosition(file, node.pos);
file.bindDiagnostics.push(ts.createFileDiagnostic(file, span.start, span.length, message, arg0, arg1, arg2));
}
function getDestructuringParameterName(node) {
return "__" + ts.indexOf(node.parent.parameters, node);
}
function bind(node) {
if (!node) {
return;
}
node.parent = parent;
var saveInStrictMode = inStrictMode;
// First we bind declaration nodes to a symbol if possible. We'll both create a symbol
// and then potentially add the symbol to an appropriate symbol table. Possible
// destination symbol tables are:
//
// 1) The 'exports' table of the current container's symbol.
// 2) The 'members' table of the current container's symbol.
// 3) The 'locals' table of the current container.
//
// However, not all symbols will end up in any of these tables. 'Anonymous' symbols
// (like TypeLiterals for example) will not be put in any table.
bindWorker(node);
// Then we recurse into the children of the node to bind them as well. For certain
// symbols we do specialized work when we recurse. For example, we'll keep track of
// the current 'container' node when it changes. This helps us know which symbol table
// a local should go into for example. Since terminal nodes are known not to have
// children, as an optimization we don't process those.
if (node.kind > 140 /* LastToken */) {
var saveParent = parent;
parent = node;
var containerFlags = getContainerFlags(node);
if (containerFlags === 0 /* None */) {
bindChildren(node);
}
else {
bindContainer(node, containerFlags);
}
parent = saveParent;
}
else if (!skipTransformFlagAggregation && (node.transformFlags & 536870912 /* HasComputedFlags */) === 0) {
subtreeTransformFlags |= computeTransformFlagsForNode(node, 0);
}
inStrictMode = saveInStrictMode;
}
function updateStrictModeStatementList(statements) {
if (!inStrictMode) {
for (var _i = 0, statements_1 = statements; _i < statements_1.length; _i++) {
var statement = statements_1[_i];
if (!ts.isPrologueDirective(statement)) {
return;
}
if (isUseStrictPrologueDirective(statement)) {
inStrictMode = true;
return;
}
}
}
}
/// Should be called only on prologue directives (isPrologueDirective(node) should be true)
function isUseStrictPrologueDirective(node) {
var nodeText = ts.getTextOfNodeFromSourceText(file.text, node.expression);
// Note: the node text must be exactly "use strict" or 'use strict'. It is not ok for the
// string to contain unicode escapes (as per ES5).
return nodeText === '"use strict"' || nodeText === "'use strict'";
}
function bindWorker(node) {
switch (node.kind) {
/* Strict mode checks */
case 70 /* Identifier */:
// for typedef type names with namespaces, bind the new jsdoc type symbol here
// because it requires all containing namespaces to be in effect, namely the
// current "blockScopeContainer" needs to be set to its immediate namespace parent.
if (node.isInJSDocNamespace) {
var parentNode = node.parent;
while (parentNode && parentNode.kind !== 284 /* JSDocTypedefTag */) {
parentNode = parentNode.parent;
}
bindBlockScopedDeclaration(parentNode, 524288 /* TypeAlias */, 793064 /* TypeAliasExcludes */);
break;
}
case 98 /* ThisKeyword */:
if (currentFlow && (ts.isExpression(node) || parent.kind === 258 /* ShorthandPropertyAssignment */)) {
node.flowNode = currentFlow;
}
return checkStrictModeIdentifier(node);
case 177 /* PropertyAccessExpression */:
if (currentFlow && isNarrowableReference(node)) {
node.flowNode = currentFlow;
}
break;
case 192 /* BinaryExpression */:
if (ts.isInJavaScriptFile(node)) {
var specialKind = ts.getSpecialPropertyAssignmentKind(node);
switch (specialKind) {
case 1 /* ExportsProperty */:
bindExportsPropertyAssignment(node);
break;
case 2 /* ModuleExports */:
bindModuleExportsAssignment(node);
break;
case 3 /* PrototypeProperty */:
bindPrototypePropertyAssignment(node);
break;
case 4 /* ThisProperty */:
bindThisPropertyAssignment(node);
break;
case 0 /* None */:
// Nothing to do
break;
default:
ts.Debug.fail("Unknown special property assignment kind");
}
}
return checkStrictModeBinaryExpression(node);
case 256 /* CatchClause */:
return checkStrictModeCatchClause(node);
case 186 /* DeleteExpression */:
return checkStrictModeDeleteExpression(node);
case 8 /* NumericLiteral */:
return checkStrictModeNumericLiteral(node);
case 191 /* PostfixUnaryExpression */:
return checkStrictModePostfixUnaryExpression(node);
case 190 /* PrefixUnaryExpression */:
return checkStrictModePrefixUnaryExpression(node);
case 217 /* WithStatement */:
return checkStrictModeWithStatement(node);
case 167 /* ThisType */:
seenThisKeyword = true;
return;
case 156 /* TypePredicate */:
return checkTypePredicate(node);
case 143 /* TypeParameter */:
return declareSymbolAndAddToSymbolTable(node, 262144 /* TypeParameter */, 530920 /* TypeParameterExcludes */);
case 144 /* Parameter */:
return bindParameter(node);
case 223 /* VariableDeclaration */:
case 174 /* BindingElement */:
if (node.dotDotDotToken && node.parent.kind === 172 /* ObjectBindingPattern */) {
emitFlags |= 32768 /* HasRestAttribute */;
}
return bindVariableDeclarationOrBindingElement(node);
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 271 /* JSDocRecordMember */:
return bindPropertyOrMethodOrAccessor(node, 4 /* Property */ | (node.questionToken ? 536870912 /* Optional */ : 0 /* None */), 0 /* PropertyExcludes */);
case 285 /* JSDocPropertyTag */:
return bindJSDocProperty(node);
case 257 /* PropertyAssignment */:
case 258 /* ShorthandPropertyAssignment */:
return bindPropertyOrMethodOrAccessor(node, 4 /* Property */, 0 /* PropertyExcludes */);
case 260 /* EnumMember */:
return bindPropertyOrMethodOrAccessor(node, 8 /* EnumMember */, 900095 /* EnumMemberExcludes */);
case 259 /* SpreadAssignment */:
case 251 /* JsxSpreadAttribute */:
var root = container;
var hasRest = false;
while (root.parent) {
if (root.kind === 176 /* ObjectLiteralExpression */ &&
root.parent.kind === 192 /* BinaryExpression */ &&
root.parent.operatorToken.kind === 57 /* EqualsToken */ &&
root.parent.left === root) {
hasRest = true;
break;
}
root = root.parent;
}
emitFlags |= hasRest ? 32768 /* HasRestAttribute */ : 16384 /* HasSpreadAttribute */;
return;
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
return declareSymbolAndAddToSymbolTable(node, 131072 /* Signature */, 0 /* None */);
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
// If this is an ObjectLiteralExpression method, then it sits in the same space
// as other properties in the object literal. So we use SymbolFlags.PropertyExcludes
// so that it will conflict with any other object literal members with the same
// name.
return bindPropertyOrMethodOrAccessor(node, 8192 /* Method */ | (node.questionToken ? 536870912 /* Optional */ : 0 /* None */), ts.isObjectLiteralMethod(node) ? 0 /* PropertyExcludes */ : 99263 /* MethodExcludes */);
case 225 /* FunctionDeclaration */:
return bindFunctionDeclaration(node);
case 150 /* Constructor */:
return declareSymbolAndAddToSymbolTable(node, 16384 /* Constructor */, /*symbolExcludes:*/ 0 /* None */);
case 151 /* GetAccessor */:
return bindPropertyOrMethodOrAccessor(node, 32768 /* GetAccessor */, 41919 /* GetAccessorExcludes */);
case 152 /* SetAccessor */:
return bindPropertyOrMethodOrAccessor(node, 65536 /* SetAccessor */, 74687 /* SetAccessorExcludes */);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 274 /* JSDocFunctionType */:
return bindFunctionOrConstructorType(node);
case 161 /* TypeLiteral */:
case 170 /* MappedType */:
case 286 /* JSDocTypeLiteral */:
case 270 /* JSDocRecordType */:
return bindAnonymousDeclaration(node, 2048 /* TypeLiteral */, "__type");
case 176 /* ObjectLiteralExpression */:
return bindObjectLiteralExpression(node);
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return bindFunctionExpression(node);
case 179 /* CallExpression */:
if (ts.isInJavaScriptFile(node)) {
bindCallExpression(node);
}
break;
// Members of classes, interfaces, and modules
case 197 /* ClassExpression */:
case 226 /* ClassDeclaration */:
// All classes are automatically in strict mode in ES6.
inStrictMode = true;
return bindClassLikeDeclaration(node);
case 227 /* InterfaceDeclaration */:
return bindBlockScopedDeclaration(node, 64 /* Interface */, 792968 /* InterfaceExcludes */);
case 284 /* JSDocTypedefTag */:
if (!node.fullName || node.fullName.kind === 70 /* Identifier */) {
return bindBlockScopedDeclaration(node, 524288 /* TypeAlias */, 793064 /* TypeAliasExcludes */);
}
break;
case 228 /* TypeAliasDeclaration */:
return bindBlockScopedDeclaration(node, 524288 /* TypeAlias */, 793064 /* TypeAliasExcludes */);
case 229 /* EnumDeclaration */:
return bindEnumDeclaration(node);
case 230 /* ModuleDeclaration */:
return bindModuleDeclaration(node);
// Imports and exports
case 234 /* ImportEqualsDeclaration */:
case 237 /* NamespaceImport */:
case 239 /* ImportSpecifier */:
case 243 /* ExportSpecifier */:
return declareSymbolAndAddToSymbolTable(node, 8388608 /* Alias */, 8388608 /* AliasExcludes */);
case 233 /* NamespaceExportDeclaration */:
return bindNamespaceExportDeclaration(node);
case 236 /* ImportClause */:
return bindImportClause(node);
case 241 /* ExportDeclaration */:
return bindExportDeclaration(node);
case 240 /* ExportAssignment */:
return bindExportAssignment(node);
case 261 /* SourceFile */:
updateStrictModeStatementList(node.statements);
return bindSourceFileIfExternalModule();
case 204 /* Block */:
if (!ts.isFunctionLike(node.parent)) {
return;
}
// Fall through
case 231 /* ModuleBlock */:
return updateStrictModeStatementList(node.statements);
}
}
function checkTypePredicate(node) {
var parameterName = node.parameterName, type = node.type;
if (parameterName && parameterName.kind === 70 /* Identifier */) {
checkStrictModeIdentifier(parameterName);
}
if (parameterName && parameterName.kind === 167 /* ThisType */) {
seenThisKeyword = true;
}
bind(type);
}
function bindSourceFileIfExternalModule() {
setExportContextFlag(file);
if (ts.isExternalModule(file)) {
bindSourceFileAsExternalModule();
}
}
function bindSourceFileAsExternalModule() {
bindAnonymousDeclaration(file, 512 /* ValueModule */, "\"" + ts.removeFileExtension(file.fileName) + "\"");
}
function bindExportAssignment(node) {
if (!container.symbol || !container.symbol.exports) {
// Export assignment in some sort of block construct
bindAnonymousDeclaration(node, 8388608 /* Alias */, getDeclarationName(node));
}
else {
// An export default clause with an expression exports a value
// We want to exclude both class and function here, this is necessary to issue an error when there are both
// default export-assignment and default export function and class declaration.
var flags = node.kind === 240 /* ExportAssignment */ && ts.exportAssignmentIsAlias(node)
? 8388608 /* Alias */
: 4 /* Property */;
declareSymbol(container.symbol.exports, container.symbol, node, flags, 4 /* Property */ | 8388608 /* AliasExcludes */ | 32 /* Class */ | 16 /* Function */);
}
}
function bindNamespaceExportDeclaration(node) {
if (node.modifiers && node.modifiers.length) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(node, ts.Diagnostics.Modifiers_cannot_appear_here));
}
if (node.parent.kind !== 261 /* SourceFile */) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(node, ts.Diagnostics.Global_module_exports_may_only_appear_at_top_level));
return;
}
else {
var parent_5 = node.parent;
if (!ts.isExternalModule(parent_5)) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(node, ts.Diagnostics.Global_module_exports_may_only_appear_in_module_files));
return;
}
if (!parent_5.isDeclarationFile) {
file.bindDiagnostics.push(ts.createDiagnosticForNode(node, ts.Diagnostics.Global_module_exports_may_only_appear_in_declaration_files));
return;
}
}
file.symbol.globalExports = file.symbol.globalExports || ts.createMap();
declareSymbol(file.symbol.globalExports, file.symbol, node, 8388608 /* Alias */, 8388608 /* AliasExcludes */);
}
function bindExportDeclaration(node) {
if (!container.symbol || !container.symbol.exports) {
// Export * in some sort of block construct
bindAnonymousDeclaration(node, 1073741824 /* ExportStar */, getDeclarationName(node));
}
else if (!node.exportClause) {
// All export * declarations are collected in an __export symbol
declareSymbol(container.symbol.exports, container.symbol, node, 1073741824 /* ExportStar */, 0 /* None */);
}
}
function bindImportClause(node) {
if (node.name) {
declareSymbolAndAddToSymbolTable(node, 8388608 /* Alias */, 8388608 /* AliasExcludes */);
}
}
function setCommonJsModuleIndicator(node) {
if (!file.commonJsModuleIndicator) {
file.commonJsModuleIndicator = node;
if (!file.externalModuleIndicator) {
bindSourceFileAsExternalModule();
}
}
}
function bindExportsPropertyAssignment(node) {
// When we create a property via 'exports.foo = bar', the 'exports.foo' property access
// expression is the declaration
setCommonJsModuleIndicator(node);
declareSymbol(file.symbol.exports, file.symbol, node.left, 4 /* Property */ | 7340032 /* Export */, 0 /* None */);
}
function bindModuleExportsAssignment(node) {
// 'module.exports = expr' assignment
setCommonJsModuleIndicator(node);
declareSymbol(file.symbol.exports, file.symbol, node, 4 /* Property */ | 7340032 /* Export */ | 512 /* ValueModule */, 0 /* None */);
}
function bindThisPropertyAssignment(node) {
ts.Debug.assert(ts.isInJavaScriptFile(node));
// Declare a 'member' if the container is an ES5 class or ES6 constructor
if (container.kind === 225 /* FunctionDeclaration */ || container.kind === 184 /* FunctionExpression */) {
container.symbol.members = container.symbol.members || ts.createMap();
// It's acceptable for multiple 'this' assignments of the same identifier to occur
declareSymbol(container.symbol.members, container.symbol, node, 4 /* Property */, 0 /* PropertyExcludes */ & ~4 /* Property */);
}
else if (container.kind === 150 /* Constructor */) {
// this.foo assignment in a JavaScript class
// Bind this property to the containing class
var saveContainer = container;
container = container.parent;
var symbol = bindPropertyOrMethodOrAccessor(node, 4 /* Property */, 0 /* None */);
if (symbol) {
// constructor-declared symbols can be overwritten by subsequent method declarations
symbol.isReplaceableByMethod = true;
}
container = saveContainer;
}
}
function bindPrototypePropertyAssignment(node) {
// We saw a node of the form 'x.prototype.y = z'. Declare a 'member' y on x if x was a function.
// Look up the function in the local scope, since prototype assignments should
// follow the function declaration
var leftSideOfAssignment = node.left;
var classPrototype = leftSideOfAssignment.expression;
var constructorFunction = classPrototype.expression;
// Fix up parent pointers since we're going to use these nodes before we bind into them
leftSideOfAssignment.parent = node;
constructorFunction.parent = classPrototype;
classPrototype.parent = leftSideOfAssignment;
var funcSymbol = container.locals[constructorFunction.text];
if (!funcSymbol || !(funcSymbol.flags & 16 /* Function */ || ts.isDeclarationOfFunctionExpression(funcSymbol))) {
return;
}
// Set up the members collection if it doesn't exist already
if (!funcSymbol.members) {
funcSymbol.members = ts.createMap();
}
// Declare the method/property
declareSymbol(funcSymbol.members, funcSymbol, leftSideOfAssignment, 4 /* Property */, 0 /* PropertyExcludes */);
}
function bindCallExpression(node) {
// We're only inspecting call expressions to detect CommonJS modules, so we can skip
// this check if we've already seen the module indicator
if (!file.commonJsModuleIndicator && ts.isRequireCall(node, /*checkArgumentIsStringLiteral*/ false)) {
setCommonJsModuleIndicator(node);
}
}
function bindClassLikeDeclaration(node) {
if (!ts.isDeclarationFile(file) && !ts.isInAmbientContext(node)) {
if (ts.getClassExtendsHeritageClauseElement(node) !== undefined) {
emitFlags |= 1024 /* HasClassExtends */;
}
if (ts.nodeIsDecorated(node)) {
emitFlags |= 2048 /* HasDecorators */;
}
}
if (node.kind === 226 /* ClassDeclaration */) {
bindBlockScopedDeclaration(node, 32 /* Class */, 899519 /* ClassExcludes */);
}
else {
var bindingName = node.name ? node.name.text : "__class";
bindAnonymousDeclaration(node, 32 /* Class */, bindingName);
// Add name of class expression into the map for semantic classifier
if (node.name) {
classifiableNames[node.name.text] = node.name.text;
}
}
var symbol = node.symbol;
// TypeScript 1.0 spec (April 2014): 8.4
// Every class automatically contains a static property member named 'prototype', the
// type of which is an instantiation of the class type with type Any supplied as a type
// argument for each type parameter. It is an error to explicitly declare a static
// property member with the name 'prototype'.
//
// Note: we check for this here because this class may be merging into a module. The
// module might have an exported variable called 'prototype'. We can't allow that as
// that would clash with the built-in 'prototype' for the class.
var prototypeSymbol = createSymbol(4 /* Property */ | 134217728 /* Prototype */, "prototype");
if (symbol.exports[prototypeSymbol.name]) {
if (node.name) {
node.name.parent = node;
}
file.bindDiagnostics.push(ts.createDiagnosticForNode(symbol.exports[prototypeSymbol.name].declarations[0], ts.Diagnostics.Duplicate_identifier_0, prototypeSymbol.name));
}
symbol.exports[prototypeSymbol.name] = prototypeSymbol;
prototypeSymbol.parent = symbol;
}
function bindEnumDeclaration(node) {
return ts.isConst(node)
? bindBlockScopedDeclaration(node, 128 /* ConstEnum */, 899967 /* ConstEnumExcludes */)
: bindBlockScopedDeclaration(node, 256 /* RegularEnum */, 899327 /* RegularEnumExcludes */);
}
function bindVariableDeclarationOrBindingElement(node) {
if (inStrictMode) {
checkStrictModeEvalOrArguments(node, node.name);
}
if (!ts.isBindingPattern(node.name)) {
if (ts.isBlockOrCatchScoped(node)) {
bindBlockScopedVariableDeclaration(node);
}
else if (ts.isParameterDeclaration(node)) {
// It is safe to walk up parent chain to find whether the node is a destructing parameter declaration
// because its parent chain has already been set up, since parents are set before descending into children.
//
// If node is a binding element in parameter declaration, we need to use ParameterExcludes.
// Using ParameterExcludes flag allows the compiler to report an error on duplicate identifiers in Parameter Declaration
// For example:
// function foo([a,a]) {} // Duplicate Identifier error
// function bar(a,a) {} // Duplicate Identifier error, parameter declaration in this case is handled in bindParameter
// // which correctly set excluded symbols
declareSymbolAndAddToSymbolTable(node, 1 /* FunctionScopedVariable */, 107455 /* ParameterExcludes */);
}
else {
declareSymbolAndAddToSymbolTable(node, 1 /* FunctionScopedVariable */, 107454 /* FunctionScopedVariableExcludes */);
}
}
}
function bindParameter(node) {
if (!ts.isDeclarationFile(file) &&
!ts.isInAmbientContext(node) &&
ts.nodeIsDecorated(node)) {
emitFlags |= (2048 /* HasDecorators */ | 4096 /* HasParamDecorators */);
}
if (inStrictMode) {
// It is a SyntaxError if the identifier eval or arguments appears within a FormalParameterList of a
// strict mode FunctionLikeDeclaration or FunctionExpression(13.1)
checkStrictModeEvalOrArguments(node, node.name);
}
if (ts.isBindingPattern(node.name)) {
bindAnonymousDeclaration(node, 1 /* FunctionScopedVariable */, getDestructuringParameterName(node));
}
else {
declareSymbolAndAddToSymbolTable(node, 1 /* FunctionScopedVariable */, 107455 /* ParameterExcludes */);
}
// If this is a property-parameter, then also declare the property symbol into the
// containing class.
if (ts.isParameterPropertyDeclaration(node)) {
var classDeclaration = node.parent.parent;
declareSymbol(classDeclaration.symbol.members, classDeclaration.symbol, node, 4 /* Property */ | (node.questionToken ? 536870912 /* Optional */ : 0 /* None */), 0 /* PropertyExcludes */);
}
}
function bindFunctionDeclaration(node) {
if (!ts.isDeclarationFile(file) && !ts.isInAmbientContext(node)) {
if (ts.isAsyncFunctionLike(node)) {
emitFlags |= 8192 /* HasAsyncFunctions */;
}
}
checkStrictModeFunctionName(node);
if (inStrictMode) {
checkStrictModeFunctionDeclaration(node);
bindBlockScopedDeclaration(node, 16 /* Function */, 106927 /* FunctionExcludes */);
}
else {
declareSymbolAndAddToSymbolTable(node, 16 /* Function */, 106927 /* FunctionExcludes */);
}
}
function bindFunctionExpression(node) {
if (!ts.isDeclarationFile(file) && !ts.isInAmbientContext(node)) {
if (ts.isAsyncFunctionLike(node)) {
emitFlags |= 8192 /* HasAsyncFunctions */;
}
}
if (currentFlow) {
node.flowNode = currentFlow;
}
checkStrictModeFunctionName(node);
var bindingName = node.name ? node.name.text : "__function";
return bindAnonymousDeclaration(node, 16 /* Function */, bindingName);
}
function bindPropertyOrMethodOrAccessor(node, symbolFlags, symbolExcludes) {
if (!ts.isDeclarationFile(file) && !ts.isInAmbientContext(node)) {
if (ts.isAsyncFunctionLike(node)) {
emitFlags |= 8192 /* HasAsyncFunctions */;
}
if (ts.nodeIsDecorated(node)) {
emitFlags |= 2048 /* HasDecorators */;
}
}
if (currentFlow && ts.isObjectLiteralOrClassExpressionMethod(node)) {
node.flowNode = currentFlow;
}
return ts.hasDynamicName(node)
? bindAnonymousDeclaration(node, symbolFlags, "__computed")
: declareSymbolAndAddToSymbolTable(node, symbolFlags, symbolExcludes);
}
function bindJSDocProperty(node) {
return declareSymbolAndAddToSymbolTable(node, 4 /* Property */, 0 /* PropertyExcludes */);
}
// reachability checks
function shouldReportErrorOnModuleDeclaration(node) {
var instanceState = getModuleInstanceState(node);
return instanceState === 1 /* Instantiated */ || (instanceState === 2 /* ConstEnumOnly */ && options.preserveConstEnums);
}
function checkUnreachable(node) {
if (!(currentFlow.flags & 1 /* Unreachable */)) {
return false;
}
if (currentFlow === unreachableFlow) {
var reportError =
// report error on all statements except empty ones
(ts.isStatementButNotDeclaration(node) && node.kind !== 206 /* EmptyStatement */) ||
// report error on class declarations
node.kind === 226 /* ClassDeclaration */ ||
// report error on instantiated modules or const-enums only modules if preserveConstEnums is set
(node.kind === 230 /* ModuleDeclaration */ && shouldReportErrorOnModuleDeclaration(node)) ||
// report error on regular enums and const enums if preserveConstEnums is set
(node.kind === 229 /* EnumDeclaration */ && (!ts.isConstEnumDeclaration(node) || options.preserveConstEnums));
if (reportError) {
currentFlow = reportedUnreachableFlow;
// unreachable code is reported if
// - user has explicitly asked about it AND
// - statement is in not ambient context (statements in ambient context is already an error
// so we should not report extras) AND
// - node is not variable statement OR
// - node is block scoped variable statement OR
// - node is not block scoped variable statement and at least one variable declaration has initializer
// Rationale: we don't want to report errors on non-initialized var's since they are hoisted
// On the other side we do want to report errors on non-initialized 'lets' because of TDZ
var reportUnreachableCode = !options.allowUnreachableCode &&
!ts.isInAmbientContext(node) &&
(node.kind !== 205 /* VariableStatement */ ||
ts.getCombinedNodeFlags(node.declarationList) & 3 /* BlockScoped */ ||
ts.forEach(node.declarationList.declarations, function (d) { return d.initializer; }));
if (reportUnreachableCode) {
errorOnFirstToken(node, ts.Diagnostics.Unreachable_code_detected);
}
}
}
return true;
}
}
/**
* Computes the transform flags for a node, given the transform flags of its subtree
*
* @param node The node to analyze
* @param subtreeFlags Transform flags computed for this node's subtree
*/
function computeTransformFlagsForNode(node, subtreeFlags) {
var kind = node.kind;
switch (kind) {
case 179 /* CallExpression */:
return computeCallExpression(node, subtreeFlags);
case 180 /* NewExpression */:
return computeNewExpression(node, subtreeFlags);
case 230 /* ModuleDeclaration */:
return computeModuleDeclaration(node, subtreeFlags);
case 183 /* ParenthesizedExpression */:
return computeParenthesizedExpression(node, subtreeFlags);
case 192 /* BinaryExpression */:
return computeBinaryExpression(node, subtreeFlags);
case 207 /* ExpressionStatement */:
return computeExpressionStatement(node, subtreeFlags);
case 144 /* Parameter */:
return computeParameter(node, subtreeFlags);
case 185 /* ArrowFunction */:
return computeArrowFunction(node, subtreeFlags);
case 184 /* FunctionExpression */:
return computeFunctionExpression(node, subtreeFlags);
case 225 /* FunctionDeclaration */:
return computeFunctionDeclaration(node, subtreeFlags);
case 223 /* VariableDeclaration */:
return computeVariableDeclaration(node, subtreeFlags);
case 224 /* VariableDeclarationList */:
return computeVariableDeclarationList(node, subtreeFlags);
case 205 /* VariableStatement */:
return computeVariableStatement(node, subtreeFlags);
case 219 /* LabeledStatement */:
return computeLabeledStatement(node, subtreeFlags);
case 226 /* ClassDeclaration */:
return computeClassDeclaration(node, subtreeFlags);
case 197 /* ClassExpression */:
return computeClassExpression(node, subtreeFlags);
case 255 /* HeritageClause */:
return computeHeritageClause(node, subtreeFlags);
case 256 /* CatchClause */:
return computeCatchClause(node, subtreeFlags);
case 199 /* ExpressionWithTypeArguments */:
return computeExpressionWithTypeArguments(node, subtreeFlags);
case 150 /* Constructor */:
return computeConstructor(node, subtreeFlags);
case 147 /* PropertyDeclaration */:
return computePropertyDeclaration(node, subtreeFlags);
case 149 /* MethodDeclaration */:
return computeMethod(node, subtreeFlags);
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return computeAccessor(node, subtreeFlags);
case 234 /* ImportEqualsDeclaration */:
return computeImportEquals(node, subtreeFlags);
case 177 /* PropertyAccessExpression */:
return computePropertyAccess(node, subtreeFlags);
default:
return computeOther(node, kind, subtreeFlags);
}
}
ts.computeTransformFlagsForNode = computeTransformFlagsForNode;
function computeCallExpression(node, subtreeFlags) {
var transformFlags = subtreeFlags;
var expression = node.expression;
var expressionKind = expression.kind;
if (node.typeArguments) {
transformFlags |= 3 /* AssertTypeScript */;
}
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */
|| isSuperOrSuperProperty(expression, expressionKind)) {
// If the this node contains a SpreadExpression, or is a super call, then it is an ES6
// node.
transformFlags |= 3072 /* AssertES2015 */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~545281365 /* ArrayLiteralOrCallOrNewExcludes */;
}
function isSuperOrSuperProperty(node, kind) {
switch (kind) {
case 96 /* SuperKeyword */:
return true;
case 177 /* PropertyAccessExpression */:
case 178 /* ElementAccessExpression */:
var expression = node.expression;
var expressionKind = expression.kind;
return expressionKind === 96 /* SuperKeyword */;
}
return false;
}
function computeNewExpression(node, subtreeFlags) {
var transformFlags = subtreeFlags;
if (node.typeArguments) {
transformFlags |= 3 /* AssertTypeScript */;
}
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
// If the this node contains a SpreadElementExpression then it is an ES6
// node.
transformFlags |= 3072 /* AssertES2015 */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~545281365 /* ArrayLiteralOrCallOrNewExcludes */;
}
function computeBinaryExpression(node, subtreeFlags) {
var transformFlags = subtreeFlags;
var operatorTokenKind = node.operatorToken.kind;
var leftKind = node.left.kind;
if (operatorTokenKind === 57 /* EqualsToken */ && leftKind === 176 /* ObjectLiteralExpression */) {
// Destructuring object assignments with are ES2015 syntax
// and possibly ESNext if they contain rest
transformFlags |= 48 /* AssertESNext */ | 3072 /* AssertES2015 */ | 49152 /* AssertDestructuringAssignment */;
}
else if (operatorTokenKind === 57 /* EqualsToken */ && leftKind === 175 /* ArrayLiteralExpression */) {
// Destructuring assignments are ES2015 syntax.
transformFlags |= 3072 /* AssertES2015 */ | 49152 /* AssertDestructuringAssignment */;
}
else if (operatorTokenKind === 39 /* AsteriskAsteriskToken */
|| operatorTokenKind === 61 /* AsteriskAsteriskEqualsToken */) {
// Exponentiation is ES2016 syntax.
transformFlags |= 768 /* AssertES2016 */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeParameter(node, subtreeFlags) {
var transformFlags = subtreeFlags;
var modifierFlags = ts.getModifierFlags(node);
var name = node.name;
var initializer = node.initializer;
var dotDotDotToken = node.dotDotDotToken;
// The '?' token, type annotations, decorators, and 'this' parameters are TypeSCript
// syntax.
if (node.questionToken
|| node.type
|| subtreeFlags & 65536 /* ContainsDecorators */
|| ts.isThisIdentifier(name)) {
transformFlags |= 3 /* AssertTypeScript */;
}
// If a parameter has an accessibility modifier, then it is TypeScript syntax.
if (modifierFlags & 92 /* ParameterPropertyModifier */) {
transformFlags |= 3 /* AssertTypeScript */ | 4194304 /* ContainsParameterPropertyAssignments */;
}
// parameters with object rest destructuring are ES Next syntax
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
transformFlags |= 48 /* AssertESNext */;
}
// If a parameter has an initializer, a binding pattern or a dotDotDot token, then
// it is ES6 syntax and its container must emit default value assignments or parameter destructuring downlevel.
if (subtreeFlags & 67108864 /* ContainsBindingPattern */ || initializer || dotDotDotToken) {
transformFlags |= 3072 /* AssertES2015 */ | 2097152 /* ContainsDefaultValueAssignments */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~604001621 /* ParameterExcludes */;
}
function computeParenthesizedExpression(node, subtreeFlags) {
var transformFlags = subtreeFlags;
var expression = node.expression;
var expressionKind = expression.kind;
var expressionTransformFlags = expression.transformFlags;
// If the node is synthesized, it means the emitter put the parentheses there,
// not the user. If we didn't want them, the emitter would not have put them
// there.
if (expressionKind === 200 /* AsExpression */
|| expressionKind === 182 /* TypeAssertionExpression */) {
transformFlags |= 3 /* AssertTypeScript */;
}
// If the expression of a ParenthesizedExpression is a destructuring assignment,
// then the ParenthesizedExpression is a destructuring assignment.
if (expressionTransformFlags & 16384 /* DestructuringAssignment */) {
transformFlags |= 16384 /* DestructuringAssignment */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeClassDeclaration(node, subtreeFlags) {
var transformFlags;
var modifierFlags = ts.getModifierFlags(node);
if (modifierFlags & 2 /* Ambient */) {
// An ambient declaration is TypeScript syntax.
transformFlags = 3 /* AssertTypeScript */;
}
else {
// A ClassDeclaration is ES6 syntax.
transformFlags = subtreeFlags | 3072 /* AssertES2015 */;
// A class with a parameter property assignment, property initializer, or decorator is
// TypeScript syntax.
// An exported declaration may be TypeScript syntax, but is handled by the visitor
// for a namespace declaration.
if ((subtreeFlags & 4390912 /* TypeScriptClassSyntaxMask */)
|| node.typeParameters) {
transformFlags |= 3 /* AssertTypeScript */;
}
if (subtreeFlags & 1048576 /* ContainsLexicalThisInComputedPropertyName */) {
// A computed property name containing `this` might need to be rewritten,
// so propagate the ContainsLexicalThis flag upward.
transformFlags |= 262144 /* ContainsLexicalThis */;
}
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~559895893 /* ClassExcludes */;
}
function computeClassExpression(node, subtreeFlags) {
// A ClassExpression is ES6 syntax.
var transformFlags = subtreeFlags | 3072 /* AssertES2015 */;
// A class with a parameter property assignment, property initializer, or decorator is
// TypeScript syntax.
if (subtreeFlags & 4390912 /* TypeScriptClassSyntaxMask */
|| node.typeParameters) {
transformFlags |= 3 /* AssertTypeScript */;
}
if (subtreeFlags & 1048576 /* ContainsLexicalThisInComputedPropertyName */) {
// A computed property name containing `this` might need to be rewritten,
// so propagate the ContainsLexicalThis flag upward.
transformFlags |= 262144 /* ContainsLexicalThis */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~559895893 /* ClassExcludes */;
}
function computeHeritageClause(node, subtreeFlags) {
var transformFlags = subtreeFlags;
switch (node.token) {
case 84 /* ExtendsKeyword */:
// An `extends` HeritageClause is ES6 syntax.
transformFlags |= 3072 /* AssertES2015 */;
break;
case 107 /* ImplementsKeyword */:
// An `implements` HeritageClause is TypeScript syntax.
transformFlags |= 3 /* AssertTypeScript */;
break;
default:
ts.Debug.fail("Unexpected token for heritage clause");
break;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeCatchClause(node, subtreeFlags) {
var transformFlags = subtreeFlags;
if (node.variableDeclaration && ts.isBindingPattern(node.variableDeclaration.name)) {
transformFlags |= 3072 /* AssertES2015 */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeExpressionWithTypeArguments(node, subtreeFlags) {
// An ExpressionWithTypeArguments is ES6 syntax, as it is used in the
// extends clause of a class.
var transformFlags = subtreeFlags | 3072 /* AssertES2015 */;
// If an ExpressionWithTypeArguments contains type arguments, then it
// is TypeScript syntax.
if (node.typeArguments) {
transformFlags |= 3 /* AssertTypeScript */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeConstructor(node, subtreeFlags) {
var transformFlags = subtreeFlags;
// TypeScript-specific modifiers and overloads are TypeScript syntax
if (ts.hasModifier(node, 2270 /* TypeScriptModifier */)
|| !node.body) {
transformFlags |= 3 /* AssertTypeScript */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~975983957 /* ConstructorExcludes */;
}
function computeMethod(node, subtreeFlags) {
// A MethodDeclaration is ES6 syntax.
var transformFlags = subtreeFlags | 3072 /* AssertES2015 */;
// Decorators, TypeScript-specific modifiers, type parameters, type annotations, and
// overloads are TypeScript syntax.
if (node.decorators
|| ts.hasModifier(node, 2270 /* TypeScriptModifier */)
|| node.typeParameters
|| node.type
|| !node.body) {
transformFlags |= 3 /* AssertTypeScript */;
}
// An async method declaration is ES2017 syntax.
if (ts.hasModifier(node, 256 /* Async */)) {
transformFlags |= 192 /* AssertES2017 */;
}
// Currently, we only support generators that were originally async function bodies.
if (node.asteriskToken && ts.getEmitFlags(node) & 2097152 /* AsyncFunctionBody */) {
transformFlags |= 12288 /* AssertGenerator */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~975983957 /* MethodOrAccessorExcludes */;
}
function computeAccessor(node, subtreeFlags) {
var transformFlags = subtreeFlags;
// Decorators, TypeScript-specific modifiers, type annotations, and overloads are
// TypeScript syntax.
if (node.decorators
|| ts.hasModifier(node, 2270 /* TypeScriptModifier */)
|| node.type
|| !node.body) {
transformFlags |= 3 /* AssertTypeScript */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~975983957 /* MethodOrAccessorExcludes */;
}
function computePropertyDeclaration(node, subtreeFlags) {
// A PropertyDeclaration is TypeScript syntax.
var transformFlags = subtreeFlags | 3 /* AssertTypeScript */;
// If the PropertyDeclaration has an initializer, we need to inform its ancestor
// so that it handle the transformation.
if (node.initializer) {
transformFlags |= 131072 /* ContainsPropertyInitializer */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeFunctionDeclaration(node, subtreeFlags) {
var transformFlags;
var modifierFlags = ts.getModifierFlags(node);
var body = node.body;
if (!body || (modifierFlags & 2 /* Ambient */)) {
// An ambient declaration is TypeScript syntax.
// A FunctionDeclaration without a body is an overload and is TypeScript syntax.
transformFlags = 3 /* AssertTypeScript */;
}
else {
transformFlags = subtreeFlags | 268435456 /* ContainsHoistedDeclarationOrCompletion */;
// TypeScript-specific modifiers, type parameters, and type annotations are TypeScript
// syntax.
if (modifierFlags & 2270 /* TypeScriptModifier */
|| node.typeParameters
|| node.type) {
transformFlags |= 3 /* AssertTypeScript */;
}
// An async function declaration is ES2017 syntax.
if (modifierFlags & 256 /* Async */) {
transformFlags |= 192 /* AssertES2017 */;
}
// function declarations with object rest destructuring are ES Next syntax
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
transformFlags |= 48 /* AssertESNext */;
}
// If a FunctionDeclaration's subtree has marked the container as needing to capture the
// lexical this, or the function contains parameters with initializers, then this node is
// ES6 syntax.
if (subtreeFlags & 2621440 /* ES2015FunctionSyntaxMask */) {
transformFlags |= 3072 /* AssertES2015 */;
}
// If a FunctionDeclaration is generator function and is the body of a
// transformed async function, then this node can be transformed to a
// down-level generator.
// Currently we do not support transforming any other generator fucntions
// down level.
if (node.asteriskToken && ts.getEmitFlags(node) & 2097152 /* AsyncFunctionBody */) {
transformFlags |= 12288 /* AssertGenerator */;
}
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~980243797 /* FunctionExcludes */;
}
function computeFunctionExpression(node, subtreeFlags) {
var transformFlags = subtreeFlags;
// TypeScript-specific modifiers, type parameters, and type annotations are TypeScript
// syntax.
if (ts.hasModifier(node, 2270 /* TypeScriptModifier */)
|| node.typeParameters
|| node.type) {
transformFlags |= 3 /* AssertTypeScript */;
}
// An async function expression is ES2017 syntax.
if (ts.hasModifier(node, 256 /* Async */)) {
transformFlags |= 192 /* AssertES2017 */;
}
// function expressions with object rest destructuring are ES Next syntax
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
transformFlags |= 48 /* AssertESNext */;
}
// If a FunctionExpression's subtree has marked the container as needing to capture the
// lexical this, or the function contains parameters with initializers, then this node is
// ES6 syntax.
if (subtreeFlags & 2621440 /* ES2015FunctionSyntaxMask */) {
transformFlags |= 3072 /* AssertES2015 */;
}
// If a FunctionExpression is generator function and is the body of a
// transformed async function, then this node can be transformed to a
// down-level generator.
// Currently we do not support transforming any other generator fucntions
// down level.
if (node.asteriskToken && ts.getEmitFlags(node) & 2097152 /* AsyncFunctionBody */) {
transformFlags |= 12288 /* AssertGenerator */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~980243797 /* FunctionExcludes */;
}
function computeArrowFunction(node, subtreeFlags) {
// An ArrowFunction is ES6 syntax, and excludes markers that should not escape the scope of an ArrowFunction.
var transformFlags = subtreeFlags | 3072 /* AssertES2015 */;
// TypeScript-specific modifiers, type parameters, and type annotations are TypeScript
// syntax.
if (ts.hasModifier(node, 2270 /* TypeScriptModifier */)
|| node.typeParameters
|| node.type) {
transformFlags |= 3 /* AssertTypeScript */;
}
// An async arrow function is ES2017 syntax.
if (ts.hasModifier(node, 256 /* Async */)) {
transformFlags |= 192 /* AssertES2017 */;
}
// arrow functions with object rest destructuring are ES Next syntax
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
transformFlags |= 48 /* AssertESNext */;
}
// If an ArrowFunction contains a lexical this, its container must capture the lexical this.
if (subtreeFlags & 262144 /* ContainsLexicalThis */) {
transformFlags |= 524288 /* ContainsCapturedLexicalThis */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~979719509 /* ArrowFunctionExcludes */;
}
function computePropertyAccess(node, subtreeFlags) {
var transformFlags = subtreeFlags;
var expression = node.expression;
var expressionKind = expression.kind;
// If a PropertyAccessExpression starts with a super keyword, then it is
// ES6 syntax, and requires a lexical `this` binding.
if (expressionKind === 96 /* SuperKeyword */) {
transformFlags |= 262144 /* ContainsLexicalThis */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeVariableDeclaration(node, subtreeFlags) {
var transformFlags = subtreeFlags;
var nameKind = node.name.kind;
// A VariableDeclaration with an object binding pattern is ES2015 syntax
// and possibly ESNext syntax if it contains an object binding pattern
if (nameKind === 172 /* ObjectBindingPattern */) {
transformFlags |= 48 /* AssertESNext */ | 3072 /* AssertES2015 */ | 67108864 /* ContainsBindingPattern */;
}
else if (nameKind === 173 /* ArrayBindingPattern */) {
transformFlags |= 3072 /* AssertES2015 */ | 67108864 /* ContainsBindingPattern */;
}
// Type annotations are TypeScript syntax.
if (node.type) {
transformFlags |= 3 /* AssertTypeScript */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeVariableStatement(node, subtreeFlags) {
var transformFlags;
var modifierFlags = ts.getModifierFlags(node);
var declarationListTransformFlags = node.declarationList.transformFlags;
// An ambient declaration is TypeScript syntax.
if (modifierFlags & 2 /* Ambient */) {
transformFlags = 3 /* AssertTypeScript */;
}
else {
transformFlags = subtreeFlags;
if (declarationListTransformFlags & 67108864 /* ContainsBindingPattern */) {
transformFlags |= 3072 /* AssertES2015 */;
}
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeLabeledStatement(node, subtreeFlags) {
var transformFlags = subtreeFlags;
// A labeled statement containing a block scoped binding *may* need to be transformed from ES6.
if (subtreeFlags & 33554432 /* ContainsBlockScopedBinding */
&& ts.isIterationStatement(node, /*lookInLabeledStatements*/ true)) {
transformFlags |= 3072 /* AssertES2015 */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeImportEquals(node, subtreeFlags) {
var transformFlags = subtreeFlags;
// An ImportEqualsDeclaration with a namespace reference is TypeScript.
if (!ts.isExternalModuleImportEqualsDeclaration(node)) {
transformFlags |= 3 /* AssertTypeScript */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeExpressionStatement(node, subtreeFlags) {
var transformFlags = subtreeFlags;
// If the expression of an expression statement is a destructuring assignment,
// then we treat the statement as ES6 so that we can indicate that we do not
// need to hold on to the right-hand side.
if (node.expression.transformFlags & 16384 /* DestructuringAssignment */) {
transformFlags |= 3072 /* AssertES2015 */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~536892757 /* NodeExcludes */;
}
function computeModuleDeclaration(node, subtreeFlags) {
var transformFlags = 3 /* AssertTypeScript */;
var modifierFlags = ts.getModifierFlags(node);
if ((modifierFlags & 2 /* Ambient */) === 0) {
transformFlags |= subtreeFlags;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~839734613 /* ModuleExcludes */;
}
function computeVariableDeclarationList(node, subtreeFlags) {
var transformFlags = subtreeFlags | 268435456 /* ContainsHoistedDeclarationOrCompletion */;
if (subtreeFlags & 67108864 /* ContainsBindingPattern */) {
transformFlags |= 3072 /* AssertES2015 */;
}
// If a VariableDeclarationList is `let` or `const`, then it is ES6 syntax.
if (node.flags & 3 /* BlockScoped */) {
transformFlags |= 3072 /* AssertES2015 */ | 33554432 /* ContainsBlockScopedBinding */;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~604001621 /* VariableDeclarationListExcludes */;
}
function computeOther(node, kind, subtreeFlags) {
// Mark transformations needed for each node
var transformFlags = subtreeFlags;
var excludeFlags = 536892757 /* NodeExcludes */;
switch (kind) {
case 119 /* AsyncKeyword */:
case 189 /* AwaitExpression */:
// async/await is ES2017 syntax
transformFlags |= 192 /* AssertES2017 */;
break;
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 116 /* AbstractKeyword */:
case 123 /* DeclareKeyword */:
case 75 /* ConstKeyword */:
case 229 /* EnumDeclaration */:
case 260 /* EnumMember */:
case 182 /* TypeAssertionExpression */:
case 200 /* AsExpression */:
case 201 /* NonNullExpression */:
case 130 /* ReadonlyKeyword */:
// These nodes are TypeScript syntax.
transformFlags |= 3 /* AssertTypeScript */;
break;
case 246 /* JsxElement */:
case 247 /* JsxSelfClosingElement */:
case 248 /* JsxOpeningElement */:
case 10 /* JsxText */:
case 249 /* JsxClosingElement */:
case 250 /* JsxAttribute */:
case 251 /* JsxSpreadAttribute */:
case 252 /* JsxExpression */:
// These nodes are Jsx syntax.
transformFlags |= 12 /* AssertJsx */;
break;
case 213 /* ForOfStatement */:
// for-of might be ESNext if it has a rest destructuring
transformFlags |= 48 /* AssertESNext */;
// FALLTHROUGH
case 12 /* NoSubstitutionTemplateLiteral */:
case 13 /* TemplateHead */:
case 14 /* TemplateMiddle */:
case 15 /* TemplateTail */:
case 194 /* TemplateExpression */:
case 181 /* TaggedTemplateExpression */:
case 258 /* ShorthandPropertyAssignment */:
case 114 /* StaticKeyword */:
// These nodes are ES6 syntax.
transformFlags |= 3072 /* AssertES2015 */;
break;
case 195 /* YieldExpression */:
// This node is ES6 syntax.
transformFlags |= 3072 /* AssertES2015 */ | 134217728 /* ContainsYield */;
break;
case 118 /* AnyKeyword */:
case 132 /* NumberKeyword */:
case 129 /* NeverKeyword */:
case 134 /* StringKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 104 /* VoidKeyword */:
case 143 /* TypeParameter */:
case 146 /* PropertySignature */:
case 148 /* MethodSignature */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 156 /* TypePredicate */:
case 157 /* TypeReference */:
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 160 /* TypeQuery */:
case 161 /* TypeLiteral */:
case 162 /* ArrayType */:
case 163 /* TupleType */:
case 164 /* UnionType */:
case 165 /* IntersectionType */:
case 166 /* ParenthesizedType */:
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 167 /* ThisType */:
case 168 /* TypeOperator */:
case 169 /* IndexedAccessType */:
case 170 /* MappedType */:
case 171 /* LiteralType */:
// Types and signatures are TypeScript syntax, and exclude all other facts.
transformFlags = 3 /* AssertTypeScript */;
excludeFlags = -3 /* TypeExcludes */;
break;
case 142 /* ComputedPropertyName */:
// Even though computed property names are ES6, we don't treat them as such.
// This is so that they can flow through PropertyName transforms unaffected.
// Instead, we mark the container as ES6, so that it can properly handle the transform.
transformFlags |= 16777216 /* ContainsComputedPropertyName */;
if (subtreeFlags & 262144 /* ContainsLexicalThis */) {
// A computed method name like `[this.getName()](x: string) { ... }` needs to
// distinguish itself from the normal case of a method body containing `this`:
// `this` inside a method doesn't need to be rewritten (the method provides `this`),
// whereas `this` inside a computed name *might* need to be rewritten if the class/object
// is inside an arrow function:
// `_this = this; () => class K { [_this.getName()]() { ... } }`
// To make this distinction, use ContainsLexicalThisInComputedPropertyName
// instead of ContainsLexicalThis for computed property names
transformFlags |= 1048576 /* ContainsLexicalThisInComputedPropertyName */;
}
break;
case 196 /* SpreadElement */:
case 259 /* SpreadAssignment */:
// This node is ES6 or ES next syntax, but is handled by a containing node.
transformFlags |= 8388608 /* ContainsSpreadExpression */;
break;
case 174 /* BindingElement */:
if (node.dotDotDotToken) {
// this node is ES2015 or ES next syntax, but is handled by a containing node.
transformFlags |= 8388608 /* ContainsSpreadExpression */;
}
case 96 /* SuperKeyword */:
// This node is ES6 syntax.
transformFlags |= 3072 /* AssertES2015 */;
break;
case 98 /* ThisKeyword */:
// Mark this node and its ancestors as containing a lexical `this` keyword.
transformFlags |= 262144 /* ContainsLexicalThis */;
break;
case 172 /* ObjectBindingPattern */:
case 173 /* ArrayBindingPattern */:
// These nodes are ES2015 or ES Next syntax.
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
transformFlags |= 48 /* AssertESNext */ | 67108864 /* ContainsBindingPattern */;
}
else {
transformFlags |= 3072 /* AssertES2015 */ | 67108864 /* ContainsBindingPattern */;
}
break;
case 145 /* Decorator */:
// This node is TypeScript syntax, and marks its container as also being TypeScript syntax.
transformFlags |= 3 /* AssertTypeScript */ | 65536 /* ContainsDecorators */;
break;
case 176 /* ObjectLiteralExpression */:
excludeFlags = 554784085 /* ObjectLiteralExcludes */;
if (subtreeFlags & 16777216 /* ContainsComputedPropertyName */) {
// If an ObjectLiteralExpression contains a ComputedPropertyName, then it
// is an ES6 node.
transformFlags |= 3072 /* AssertES2015 */;
}
if (subtreeFlags & 1048576 /* ContainsLexicalThisInComputedPropertyName */) {
// A computed property name containing `this` might need to be rewritten,
// so propagate the ContainsLexicalThis flag upward.
transformFlags |= 262144 /* ContainsLexicalThis */;
}
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
// If an ObjectLiteralExpression contains a spread element, then it
// is an ES next node.
transformFlags |= 48 /* AssertESNext */;
}
break;
case 175 /* ArrayLiteralExpression */:
case 180 /* NewExpression */:
excludeFlags = 545281365 /* ArrayLiteralOrCallOrNewExcludes */;
if (subtreeFlags & 8388608 /* ContainsSpreadExpression */) {
// If the this node contains a SpreadExpression, then it is an ES6
// node.
transformFlags |= 3072 /* AssertES2015 */;
}
break;
case 209 /* DoStatement */:
case 210 /* WhileStatement */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
// A loop containing a block scoped binding *may* need to be transformed from ES6.
if (subtreeFlags & 33554432 /* ContainsBlockScopedBinding */) {
transformFlags |= 3072 /* AssertES2015 */;
}
break;
case 261 /* SourceFile */:
if (subtreeFlags & 524288 /* ContainsCapturedLexicalThis */) {
transformFlags |= 3072 /* AssertES2015 */;
}
break;
case 216 /* ReturnStatement */:
case 214 /* ContinueStatement */:
case 215 /* BreakStatement */:
transformFlags |= 268435456 /* ContainsHoistedDeclarationOrCompletion */;
break;
}
node.transformFlags = transformFlags | 536870912 /* HasComputedFlags */;
return transformFlags & ~excludeFlags;
}
/**
* Gets the transform flags to exclude when unioning the transform flags of a subtree.
*
* NOTE: This needs to be kept up-to-date with the exclusions used in `computeTransformFlagsForNode`.
* For performance reasons, `computeTransformFlagsForNode` uses local constant values rather
* than calling this function.
*/
/* @internal */
function getTransformFlagsSubtreeExclusions(kind) {
if (kind >= 156 /* FirstTypeNode */ && kind <= 171 /* LastTypeNode */) {
return -3 /* TypeExcludes */;
}
switch (kind) {
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 175 /* ArrayLiteralExpression */:
return 545281365 /* ArrayLiteralOrCallOrNewExcludes */;
case 230 /* ModuleDeclaration */:
return 839734613 /* ModuleExcludes */;
case 144 /* Parameter */:
return 604001621 /* ParameterExcludes */;
case 185 /* ArrowFunction */:
return 979719509 /* ArrowFunctionExcludes */;
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
return 980243797 /* FunctionExcludes */;
case 224 /* VariableDeclarationList */:
return 604001621 /* VariableDeclarationListExcludes */;
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
return 559895893 /* ClassExcludes */;
case 150 /* Constructor */:
return 975983957 /* ConstructorExcludes */;
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return 975983957 /* MethodOrAccessorExcludes */;
case 118 /* AnyKeyword */:
case 132 /* NumberKeyword */:
case 129 /* NeverKeyword */:
case 134 /* StringKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 104 /* VoidKeyword */:
case 143 /* TypeParameter */:
case 146 /* PropertySignature */:
case 148 /* MethodSignature */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
return -3 /* TypeExcludes */;
case 176 /* ObjectLiteralExpression */:
return 554784085 /* ObjectLiteralExcludes */;
default:
return 536892757 /* NodeExcludes */;
}
}
ts.getTransformFlagsSubtreeExclusions = getTransformFlagsSubtreeExclusions;
})(ts || (ts = {}));
/// <reference path="core.ts" />
/// <reference path="diagnosticInformationMap.generated.ts" />
var ts;
(function (ts) {
function trace(host) {
host.trace(ts.formatMessage.apply(undefined, arguments));
}
ts.trace = trace;
/* @internal */
function isTraceEnabled(compilerOptions, host) {
return compilerOptions.traceResolution && host.trace !== undefined;
}
ts.isTraceEnabled = isTraceEnabled;
/**
* Kinds of file that we are currently looking for.
* Typically there is one pass with Extensions.TypeScript, then a second pass with Extensions.JavaScript.
*/
var Extensions;
(function (Extensions) {
Extensions[Extensions["TypeScript"] = 0] = "TypeScript";
Extensions[Extensions["JavaScript"] = 1] = "JavaScript";
Extensions[Extensions["DtsOnly"] = 2] = "DtsOnly"; /** Only '.d.ts' */
})(Extensions || (Extensions = {}));
/** Used with `Extensions.DtsOnly` to extract the path from TypeScript results. */
function resolvedTypeScriptOnly(resolved) {
if (!resolved) {
return undefined;
}
ts.Debug.assert(ts.extensionIsTypeScript(resolved.extension));
return resolved.path;
}
/** Create Resolved from a file with unknown extension. */
function resolvedFromAnyFile(path) {
return { path: path, extension: ts.extensionFromPath(path) };
}
/** Adds `isExernalLibraryImport` to a Resolved to get a ResolvedModule. */
function resolvedModuleFromResolved(_a, isExternalLibraryImport) {
var path = _a.path, extension = _a.extension;
return { resolvedFileName: path, extension: extension, isExternalLibraryImport: isExternalLibraryImport };
}
function createResolvedModuleWithFailedLookupLocations(resolved, isExternalLibraryImport, failedLookupLocations) {
return { resolvedModule: resolved && resolvedModuleFromResolved(resolved, isExternalLibraryImport), failedLookupLocations: failedLookupLocations };
}
function moduleHasNonRelativeName(moduleName) {
return !(ts.isRootedDiskPath(moduleName) || ts.isExternalModuleNameRelative(moduleName));
}
function tryReadTypesSection(extensions, packageJsonPath, baseDirectory, state) {
var jsonContent = readJson(packageJsonPath, state.host);
switch (extensions) {
case 2 /* DtsOnly */:
case 0 /* TypeScript */:
return tryReadFromField("typings") || tryReadFromField("types");
case 1 /* JavaScript */:
if (typeof jsonContent.main === "string") {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.No_types_specified_in_package_json_so_returning_main_value_of_0, jsonContent.main);
}
return ts.normalizePath(ts.combinePaths(baseDirectory, jsonContent.main));
}
return undefined;
}
function tryReadFromField(fieldName) {
if (ts.hasProperty(jsonContent, fieldName)) {
var typesFile = jsonContent[fieldName];
if (typeof typesFile === "string") {
var typesFilePath = ts.normalizePath(ts.combinePaths(baseDirectory, typesFile));
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.package_json_has_0_field_1_that_references_2, fieldName, typesFile, typesFilePath);
}
return typesFilePath;
}
else {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Expected_type_of_0_field_in_package_json_to_be_string_got_1, fieldName, typeof typesFile);
}
}
}
}
}
function readJson(path, host) {
try {
var jsonText = host.readFile(path);
return jsonText ? JSON.parse(jsonText) : {};
}
catch (e) {
// gracefully handle if readFile fails or returns not JSON
return {};
}
}
function getEffectiveTypeRoots(options, host) {
if (options.typeRoots) {
return options.typeRoots;
}
var currentDirectory;
if (options.configFilePath) {
currentDirectory = ts.getDirectoryPath(options.configFilePath);
}
else if (host.getCurrentDirectory) {
currentDirectory = host.getCurrentDirectory();
}
if (currentDirectory !== undefined) {
return getDefaultTypeRoots(currentDirectory, host);
}
}
ts.getEffectiveTypeRoots = getEffectiveTypeRoots;
/**
* Returns the path to every node_modules/@types directory from some ancestor directory.
* Returns undefined if there are none.
*/
function getDefaultTypeRoots(currentDirectory, host) {
if (!host.directoryExists) {
return [ts.combinePaths(currentDirectory, nodeModulesAtTypes)];
}
var typeRoots;
forEachAncestorDirectory(currentDirectory, function (directory) {
var atTypes = ts.combinePaths(directory, nodeModulesAtTypes);
if (host.directoryExists(atTypes)) {
(typeRoots || (typeRoots = [])).push(atTypes);
}
});
return typeRoots;
}
var nodeModulesAtTypes = ts.combinePaths("node_modules", "@types");
/**
* @param {string | undefined} containingFile - file that contains type reference directive, can be undefined if containing file is unknown.
* This is possible in case if resolution is performed for directives specified via 'types' parameter. In this case initial path for secondary lookups
* is assumed to be the same as root directory of the project.
*/
function resolveTypeReferenceDirective(typeReferenceDirectiveName, containingFile, options, host) {
var traceEnabled = isTraceEnabled(options, host);
var moduleResolutionState = {
compilerOptions: options,
host: host,
traceEnabled: traceEnabled
};
var typeRoots = getEffectiveTypeRoots(options, host);
if (traceEnabled) {
if (containingFile === undefined) {
if (typeRoots === undefined) {
trace(host, ts.Diagnostics.Resolving_type_reference_directive_0_containing_file_not_set_root_directory_not_set, typeReferenceDirectiveName);
}
else {
trace(host, ts.Diagnostics.Resolving_type_reference_directive_0_containing_file_not_set_root_directory_1, typeReferenceDirectiveName, typeRoots);
}
}
else {
if (typeRoots === undefined) {
trace(host, ts.Diagnostics.Resolving_type_reference_directive_0_containing_file_1_root_directory_not_set, typeReferenceDirectiveName, containingFile);
}
else {
trace(host, ts.Diagnostics.Resolving_type_reference_directive_0_containing_file_1_root_directory_2, typeReferenceDirectiveName, containingFile, typeRoots);
}
}
}
var failedLookupLocations = [];
var resolved = primaryLookup();
var primary = true;
if (!resolved) {
resolved = secondaryLookup();
primary = false;
}
var resolvedTypeReferenceDirective;
if (resolved) {
resolved = realpath(resolved, host, traceEnabled);
if (traceEnabled) {
trace(host, ts.Diagnostics.Type_reference_directive_0_was_successfully_resolved_to_1_primary_Colon_2, typeReferenceDirectiveName, resolved, primary);
}
resolvedTypeReferenceDirective = { primary: primary, resolvedFileName: resolved };
}
return { resolvedTypeReferenceDirective: resolvedTypeReferenceDirective, failedLookupLocations: failedLookupLocations };
function primaryLookup() {
// Check primary library paths
if (typeRoots && typeRoots.length) {
if (traceEnabled) {
trace(host, ts.Diagnostics.Resolving_with_primary_search_path_0, typeRoots.join(", "));
}
return ts.forEach(typeRoots, function (typeRoot) {
var candidate = ts.combinePaths(typeRoot, typeReferenceDirectiveName);
var candidateDirectory = ts.getDirectoryPath(candidate);
return resolvedTypeScriptOnly(loadNodeModuleFromDirectory(2 /* DtsOnly */, candidate, failedLookupLocations, !directoryProbablyExists(candidateDirectory, host), moduleResolutionState));
});
}
else {
if (traceEnabled) {
trace(host, ts.Diagnostics.Root_directory_cannot_be_determined_skipping_primary_search_paths);
}
}
}
function secondaryLookup() {
var resolvedFile;
var initialLocationForSecondaryLookup = containingFile && ts.getDirectoryPath(containingFile);
if (initialLocationForSecondaryLookup !== undefined) {
// check secondary locations
if (traceEnabled) {
trace(host, ts.Diagnostics.Looking_up_in_node_modules_folder_initial_location_0, initialLocationForSecondaryLookup);
}
resolvedFile = resolvedTypeScriptOnly(loadModuleFromNodeModules(2 /* DtsOnly */, typeReferenceDirectiveName, initialLocationForSecondaryLookup, failedLookupLocations, moduleResolutionState));
if (!resolvedFile && traceEnabled) {
trace(host, ts.Diagnostics.Type_reference_directive_0_was_not_resolved, typeReferenceDirectiveName);
}
return resolvedFile;
}
else {
if (traceEnabled) {
trace(host, ts.Diagnostics.Containing_file_is_not_specified_and_root_directory_cannot_be_determined_skipping_lookup_in_node_modules_folder);
}
}
}
}
ts.resolveTypeReferenceDirective = resolveTypeReferenceDirective;
/**
* Given a set of options, returns the set of type directive names
* that should be included for this program automatically.
* This list could either come from the config file,
* or from enumerating the types root + initial secondary types lookup location.
* More type directives might appear in the program later as a result of loading actual source files;
* this list is only the set of defaults that are implicitly included.
*/
function getAutomaticTypeDirectiveNames(options, host) {
// Use explicit type list from tsconfig.json
if (options.types) {
return options.types;
}
// Walk the primary type lookup locations
var result = [];
if (host.directoryExists && host.getDirectories) {
var typeRoots = getEffectiveTypeRoots(options, host);
if (typeRoots) {
for (var _i = 0, typeRoots_1 = typeRoots; _i < typeRoots_1.length; _i++) {
var root = typeRoots_1[_i];
if (host.directoryExists(root)) {
for (var _a = 0, _b = host.getDirectories(root); _a < _b.length; _a++) {
var typeDirectivePath = _b[_a];
var normalized = ts.normalizePath(typeDirectivePath);
var packageJsonPath = pathToPackageJson(ts.combinePaths(root, normalized));
// tslint:disable-next-line:no-null-keyword
var isNotNeededPackage = host.fileExists(packageJsonPath) && readJson(packageJsonPath, host).typings === null;
if (!isNotNeededPackage) {
// Return just the type directive names
result.push(ts.getBaseFileName(normalized));
}
}
}
}
}
}
return result;
}
ts.getAutomaticTypeDirectiveNames = getAutomaticTypeDirectiveNames;
function resolveModuleName(moduleName, containingFile, compilerOptions, host) {
var traceEnabled = isTraceEnabled(compilerOptions, host);
if (traceEnabled) {
trace(host, ts.Diagnostics.Resolving_module_0_from_1, moduleName, containingFile);
}
var moduleResolution = compilerOptions.moduleResolution;
if (moduleResolution === undefined) {
moduleResolution = ts.getEmitModuleKind(compilerOptions) === ts.ModuleKind.CommonJS ? ts.ModuleResolutionKind.NodeJs : ts.ModuleResolutionKind.Classic;
if (traceEnabled) {
trace(host, ts.Diagnostics.Module_resolution_kind_is_not_specified_using_0, ts.ModuleResolutionKind[moduleResolution]);
}
}
else {
if (traceEnabled) {
trace(host, ts.Diagnostics.Explicitly_specified_module_resolution_kind_Colon_0, ts.ModuleResolutionKind[moduleResolution]);
}
}
var result;
switch (moduleResolution) {
case ts.ModuleResolutionKind.NodeJs:
result = nodeModuleNameResolver(moduleName, containingFile, compilerOptions, host);
break;
case ts.ModuleResolutionKind.Classic:
result = classicNameResolver(moduleName, containingFile, compilerOptions, host);
break;
}
if (traceEnabled) {
if (result.resolvedModule) {
trace(host, ts.Diagnostics.Module_name_0_was_successfully_resolved_to_1, moduleName, result.resolvedModule.resolvedFileName);
}
else {
trace(host, ts.Diagnostics.Module_name_0_was_not_resolved, moduleName);
}
}
return result;
}
ts.resolveModuleName = resolveModuleName;
/**
* Any module resolution kind can be augmented with optional settings: 'baseUrl', 'paths' and 'rootDirs' - they are used to
* mitigate differences between design time structure of the project and its runtime counterpart so the same import name
* can be resolved successfully by TypeScript compiler and runtime module loader.
* If these settings are set then loading procedure will try to use them to resolve module name and it can of failure it will
* fallback to standard resolution routine.
*
* - baseUrl - this setting controls how non-relative module names are resolved. If this setting is specified then non-relative
* names will be resolved relative to baseUrl: i.e. if baseUrl is '/a/b' then candidate location to resolve module name 'c/d' will
* be '/a/b/c/d'
* - paths - this setting can only be used when baseUrl is specified. allows to tune how non-relative module names
* will be resolved based on the content of the module name.
* Structure of 'paths' compiler options
* 'paths': {
* pattern-1: [...substitutions],
* pattern-2: [...substitutions],
* ...
* pattern-n: [...substitutions]
* }
* Pattern here is a string that can contain zero or one '*' character. During module resolution module name will be matched against
* all patterns in the list. Matching for patterns that don't contain '*' means that module name must be equal to pattern respecting the case.
* If pattern contains '*' then to match pattern "<prefix>*<suffix>" module name must start with the <prefix> and end with <suffix>.
* <MatchedStar> denotes part of the module name between <prefix> and <suffix>.
* If module name can be matches with multiple patterns then pattern with the longest prefix will be picked.
* After selecting pattern we'll use list of substitutions to get candidate locations of the module and the try to load module
* from the candidate location.
* Substitution is a string that can contain zero or one '*'. To get candidate location from substitution we'll pick every
* substitution in the list and replace '*' with <MatchedStar> string. If candidate location is not rooted it
* will be converted to absolute using baseUrl.
* For example:
* baseUrl: /a/b/c
* "paths": {
* // match all module names
* "*": [
* "*", // use matched name as is,
* // <matched name> will be looked as /a/b/c/<matched name>
*
* "folder1/*" // substitution will convert matched name to 'folder1/<matched name>',
* // since it is not rooted then final candidate location will be /a/b/c/folder1/<matched name>
* ],
* // match module names that start with 'components/'
* "components/*": [ "/root/components/*" ] // substitution will convert /components/folder1/<matched name> to '/root/components/folder1/<matched name>',
* // it is rooted so it will be final candidate location
* }
*
* 'rootDirs' allows the project to be spreaded across multiple locations and resolve modules with relative names as if
* they were in the same location. For example lets say there are two files
* '/local/src/content/file1.ts'
* '/shared/components/contracts/src/content/protocols/file2.ts'
* After bundling content of '/shared/components/contracts/src' will be merged with '/local/src' so
* if file1 has the following import 'import {x} from "./protocols/file2"' it will be resolved successfully in runtime.
* 'rootDirs' provides the way to tell compiler that in order to get the whole project it should behave as if content of all
* root dirs were merged together.
* I.e. for the example above 'rootDirs' will have two entries: [ '/local/src', '/shared/components/contracts/src' ].
* Compiler will first convert './protocols/file2' into absolute path relative to the location of containing file:
* '/local/src/content/protocols/file2' and try to load it - failure.
* Then it will search 'rootDirs' looking for a longest matching prefix of this absolute path and if such prefix is found - absolute path will
* be converted to a path relative to found rootDir entry './content/protocols/file2' (*). As a last step compiler will check all remaining
* entries in 'rootDirs', use them to build absolute path out of (*) and try to resolve module from this location.
*/
function tryLoadModuleUsingOptionalResolutionSettings(extensions, moduleName, containingDirectory, loader, failedLookupLocations, state) {
if (moduleHasNonRelativeName(moduleName)) {
return tryLoadModuleUsingBaseUrl(extensions, moduleName, loader, failedLookupLocations, state);
}
else {
return tryLoadModuleUsingRootDirs(extensions, moduleName, containingDirectory, loader, failedLookupLocations, state);
}
}
function tryLoadModuleUsingRootDirs(extensions, moduleName, containingDirectory, loader, failedLookupLocations, state) {
if (!state.compilerOptions.rootDirs) {
return undefined;
}
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.rootDirs_option_is_set_using_it_to_resolve_relative_module_name_0, moduleName);
}
var candidate = ts.normalizePath(ts.combinePaths(containingDirectory, moduleName));
var matchedRootDir;
var matchedNormalizedPrefix;
for (var _i = 0, _a = state.compilerOptions.rootDirs; _i < _a.length; _i++) {
var rootDir = _a[_i];
// rootDirs are expected to be absolute
// in case of tsconfig.json this will happen automatically - compiler will expand relative names
// using location of tsconfig.json as base location
var normalizedRoot = ts.normalizePath(rootDir);
if (!ts.endsWith(normalizedRoot, ts.directorySeparator)) {
normalizedRoot += ts.directorySeparator;
}
var isLongestMatchingPrefix = ts.startsWith(candidate, normalizedRoot) &&
(matchedNormalizedPrefix === undefined || matchedNormalizedPrefix.length < normalizedRoot.length);
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Checking_if_0_is_the_longest_matching_prefix_for_1_2, normalizedRoot, candidate, isLongestMatchingPrefix);
}
if (isLongestMatchingPrefix) {
matchedNormalizedPrefix = normalizedRoot;
matchedRootDir = rootDir;
}
}
if (matchedNormalizedPrefix) {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Longest_matching_prefix_for_0_is_1, candidate, matchedNormalizedPrefix);
}
var suffix = candidate.substr(matchedNormalizedPrefix.length);
// first - try to load from a initial location
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Loading_0_from_the_root_dir_1_candidate_location_2, suffix, matchedNormalizedPrefix, candidate);
}
var resolvedFileName = loader(extensions, candidate, failedLookupLocations, !directoryProbablyExists(containingDirectory, state.host), state);
if (resolvedFileName) {
return resolvedFileName;
}
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Trying_other_entries_in_rootDirs);
}
// then try to resolve using remaining entries in rootDirs
for (var _b = 0, _c = state.compilerOptions.rootDirs; _b < _c.length; _b++) {
var rootDir = _c[_b];
if (rootDir === matchedRootDir) {
// skip the initially matched entry
continue;
}
var candidate_1 = ts.combinePaths(ts.normalizePath(rootDir), suffix);
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Loading_0_from_the_root_dir_1_candidate_location_2, suffix, rootDir, candidate_1);
}
var baseDirectory = ts.getDirectoryPath(candidate_1);
var resolvedFileName_1 = loader(extensions, candidate_1, failedLookupLocations, !directoryProbablyExists(baseDirectory, state.host), state);
if (resolvedFileName_1) {
return resolvedFileName_1;
}
}
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Module_resolution_using_rootDirs_has_failed);
}
}
return undefined;
}
function tryLoadModuleUsingBaseUrl(extensions, moduleName, loader, failedLookupLocations, state) {
if (!state.compilerOptions.baseUrl) {
return undefined;
}
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.baseUrl_option_is_set_to_0_using_this_value_to_resolve_non_relative_module_name_1, state.compilerOptions.baseUrl, moduleName);
}
// string is for exact match
var matchedPattern = undefined;
if (state.compilerOptions.paths) {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.paths_option_is_specified_looking_for_a_pattern_to_match_module_name_0, moduleName);
}
matchedPattern = ts.matchPatternOrExact(ts.getOwnKeys(state.compilerOptions.paths), moduleName);
}
if (matchedPattern) {
var matchedStar_1 = typeof matchedPattern === "string" ? undefined : ts.matchedText(matchedPattern, moduleName);
var matchedPatternText = typeof matchedPattern === "string" ? matchedPattern : ts.patternText(matchedPattern);
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Module_name_0_matched_pattern_1, moduleName, matchedPatternText);
}
return ts.forEach(state.compilerOptions.paths[matchedPatternText], function (subst) {
var path = matchedStar_1 ? subst.replace("*", matchedStar_1) : subst;
var candidate = ts.normalizePath(ts.combinePaths(state.compilerOptions.baseUrl, path));
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Trying_substitution_0_candidate_module_location_Colon_1, subst, path);
}
// A path mapping may have a ".ts" extension; in contrast to an import, which should omit it.
var tsExtension = ts.tryGetExtensionFromPath(candidate);
if (tsExtension !== undefined) {
var path_1 = tryFile(candidate, failedLookupLocations, /*onlyRecordFailures*/ false, state);
return path_1 && { path: path_1, extension: tsExtension };
}
return loader(extensions, candidate, failedLookupLocations, !directoryProbablyExists(ts.getDirectoryPath(candidate), state.host), state);
});
}
else {
var candidate = ts.normalizePath(ts.combinePaths(state.compilerOptions.baseUrl, moduleName));
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Resolving_module_name_0_relative_to_base_url_1_2, moduleName, state.compilerOptions.baseUrl, candidate);
}
return loader(extensions, candidate, failedLookupLocations, !directoryProbablyExists(ts.getDirectoryPath(candidate), state.host), state);
}
}
function nodeModuleNameResolver(moduleName, containingFile, compilerOptions, host) {
var containingDirectory = ts.getDirectoryPath(containingFile);
var traceEnabled = isTraceEnabled(compilerOptions, host);
var failedLookupLocations = [];
var state = { compilerOptions: compilerOptions, host: host, traceEnabled: traceEnabled };
var result = tryResolve(0 /* TypeScript */) || tryResolve(1 /* JavaScript */);
if (result) {
var resolved = result.resolved, isExternalLibraryImport = result.isExternalLibraryImport;
return createResolvedModuleWithFailedLookupLocations(resolved, isExternalLibraryImport, failedLookupLocations);
}
return { resolvedModule: undefined, failedLookupLocations: failedLookupLocations };
function tryResolve(extensions) {
var resolved = tryLoadModuleUsingOptionalResolutionSettings(extensions, moduleName, containingDirectory, nodeLoadModuleByRelativeName, failedLookupLocations, state);
if (resolved) {
return { resolved: resolved, isExternalLibraryImport: false };
}
if (moduleHasNonRelativeName(moduleName)) {
if (traceEnabled) {
trace(host, ts.Diagnostics.Loading_module_0_from_node_modules_folder, moduleName);
}
var resolved_1 = loadModuleFromNodeModules(extensions, moduleName, containingDirectory, failedLookupLocations, state);
// For node_modules lookups, get the real path so that multiple accesses to an `npm link`-ed module do not create duplicate files.
return resolved_1 && { resolved: { path: realpath(resolved_1.path, host, traceEnabled), extension: resolved_1.extension }, isExternalLibraryImport: true };
}
else {
var candidate = ts.normalizePath(ts.combinePaths(containingDirectory, moduleName));
var resolved_2 = nodeLoadModuleByRelativeName(extensions, candidate, failedLookupLocations, /*onlyRecordFailures*/ false, state);
return resolved_2 && { resolved: resolved_2, isExternalLibraryImport: false };
}
}
}
ts.nodeModuleNameResolver = nodeModuleNameResolver;
function realpath(path, host, traceEnabled) {
if (!host.realpath) {
return path;
}
var real = ts.normalizePath(host.realpath(path));
if (traceEnabled) {
trace(host, ts.Diagnostics.Resolving_real_path_for_0_result_1, path, real);
}
return real;
}
function nodeLoadModuleByRelativeName(extensions, candidate, failedLookupLocations, onlyRecordFailures, state) {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Loading_module_as_file_Slash_folder_candidate_module_location_0, candidate);
}
var resolvedFromFile = !ts.pathEndsWithDirectorySeparator(candidate) && loadModuleFromFile(extensions, candidate, failedLookupLocations, onlyRecordFailures, state);
return resolvedFromFile || loadNodeModuleFromDirectory(extensions, candidate, failedLookupLocations, onlyRecordFailures, state);
}
/* @internal */
function directoryProbablyExists(directoryName, host) {
// if host does not support 'directoryExists' assume that directory will exist
return !host.directoryExists || host.directoryExists(directoryName);
}
ts.directoryProbablyExists = directoryProbablyExists;
/**
* @param {boolean} onlyRecordFailures - if true then function won't try to actually load files but instead record all attempts as failures. This flag is necessary
* in cases when we know upfront that all load attempts will fail (because containing folder does not exists) however we still need to record all failed lookup locations.
*/
function loadModuleFromFile(extensions, candidate, failedLookupLocations, onlyRecordFailures, state) {
// First, try adding an extension. An import of "foo" could be matched by a file "foo.ts", or "foo.js" by "foo.js.ts"
var resolvedByAddingExtension = tryAddingExtensions(candidate, extensions, failedLookupLocations, onlyRecordFailures, state);
if (resolvedByAddingExtension) {
return resolvedByAddingExtension;
}
// If that didn't work, try stripping a ".js" or ".jsx" extension and replacing it with a TypeScript one;
// e.g. "./foo.js" can be matched by "./foo.ts" or "./foo.d.ts"
if (ts.hasJavaScriptFileExtension(candidate)) {
var extensionless = ts.removeFileExtension(candidate);
if (state.traceEnabled) {
var extension = candidate.substring(extensionless.length);
trace(state.host, ts.Diagnostics.File_name_0_has_a_1_extension_stripping_it, candidate, extension);
}
return tryAddingExtensions(extensionless, extensions, failedLookupLocations, onlyRecordFailures, state);
}
}
/** Try to return an existing file that adds one of the `extensions` to `candidate`. */
function tryAddingExtensions(candidate, extensions, failedLookupLocations, onlyRecordFailures, state) {
if (!onlyRecordFailures) {
// check if containing folder exists - if it doesn't then just record failures for all supported extensions without disk probing
var directory = ts.getDirectoryPath(candidate);
if (directory) {
onlyRecordFailures = !directoryProbablyExists(directory, state.host);
}
}
switch (extensions) {
case 2 /* DtsOnly */:
return tryExtension(".d.ts", ts.Extension.Dts);
case 0 /* TypeScript */:
return tryExtension(".ts", ts.Extension.Ts) || tryExtension(".tsx", ts.Extension.Tsx) || tryExtension(".d.ts", ts.Extension.Dts);
case 1 /* JavaScript */:
return tryExtension(".js", ts.Extension.Js) || tryExtension(".jsx", ts.Extension.Jsx);
}
function tryExtension(ext, extension) {
var path = tryFile(candidate + ext, failedLookupLocations, onlyRecordFailures, state);
return path && { path: path, extension: extension };
}
}
/** Return the file if it exists. */
function tryFile(fileName, failedLookupLocations, onlyRecordFailures, state) {
if (!onlyRecordFailures && state.host.fileExists(fileName)) {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.File_0_exist_use_it_as_a_name_resolution_result, fileName);
}
return fileName;
}
else {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.File_0_does_not_exist, fileName);
}
failedLookupLocations.push(fileName);
return undefined;
}
}
function loadNodeModuleFromDirectory(extensions, candidate, failedLookupLocations, onlyRecordFailures, state) {
var packageJsonPath = pathToPackageJson(candidate);
var directoryExists = !onlyRecordFailures && directoryProbablyExists(candidate, state.host);
if (directoryExists && state.host.fileExists(packageJsonPath)) {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.Found_package_json_at_0, packageJsonPath);
}
var typesFile = tryReadTypesSection(extensions, packageJsonPath, candidate, state);
if (typesFile) {
var onlyRecordFailures_1 = !directoryProbablyExists(ts.getDirectoryPath(typesFile), state.host);
// A package.json "typings" may specify an exact filename, or may choose to omit an extension.
var fromFile = tryFile(typesFile, failedLookupLocations, onlyRecordFailures_1, state);
if (fromFile) {
// Note: this would allow a package.json to specify a ".js" file as typings. Maybe that should be forbidden.
return resolvedFromAnyFile(fromFile);
}
var x = tryAddingExtensions(typesFile, 0 /* TypeScript */, failedLookupLocations, onlyRecordFailures_1, state);
if (x) {
return x;
}
}
else {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.package_json_does_not_have_a_types_or_main_field);
}
}
}
else {
if (state.traceEnabled) {
trace(state.host, ts.Diagnostics.File_0_does_not_exist, packageJsonPath);
}
// record package json as one of failed lookup locations - in the future if this file will appear it will invalidate resolution results
failedLookupLocations.push(packageJsonPath);
}
return loadModuleFromFile(extensions, ts.combinePaths(candidate, "index"), failedLookupLocations, !directoryExists, state);
}
function pathToPackageJson(directory) {
return ts.combinePaths(directory, "package.json");
}
function loadModuleFromNodeModulesFolder(extensions, moduleName, directory, failedLookupLocations, state) {
var nodeModulesFolder = ts.combinePaths(directory, "node_modules");
var nodeModulesFolderExists = directoryProbablyExists(nodeModulesFolder, state.host);
var candidate = ts.normalizePath(ts.combinePaths(nodeModulesFolder, moduleName));
return loadModuleFromFile(extensions, candidate, failedLookupLocations, !nodeModulesFolderExists, state) ||
loadNodeModuleFromDirectory(extensions, candidate, failedLookupLocations, !nodeModulesFolderExists, state);
}
function loadModuleFromNodeModules(extensions, moduleName, directory, failedLookupLocations, state) {
return loadModuleFromNodeModulesWorker(extensions, moduleName, directory, failedLookupLocations, state, /*typesOnly*/ false);
}
function loadModuleFromNodeModulesAtTypes(moduleName, directory, failedLookupLocations, state) {
// Extensions parameter here doesn't actually matter, because typesOnly ensures we're just doing @types lookup, which is always DtsOnly.
return loadModuleFromNodeModulesWorker(2 /* DtsOnly */, moduleName, directory, failedLookupLocations, state, /*typesOnly*/ true);
}
function loadModuleFromNodeModulesWorker(extensions, moduleName, directory, failedLookupLocations, state, typesOnly) {
return forEachAncestorDirectory(ts.normalizeSlashes(directory), function (ancestorDirectory) {
if (ts.getBaseFileName(ancestorDirectory) !== "node_modules") {
return loadModuleFromNodeModulesOneLevel(extensions, moduleName, ancestorDirectory, failedLookupLocations, state, typesOnly);
}
});
}
/** Load a module from a single node_modules directory, but not from any ancestors' node_modules directories. */
function loadModuleFromNodeModulesOneLevel(extensions, moduleName, directory, failedLookupLocations, state, typesOnly) {
if (typesOnly === void 0) { typesOnly = false; }
var packageResult = typesOnly ? undefined : loadModuleFromNodeModulesFolder(extensions, moduleName, directory, failedLookupLocations, state);
if (packageResult) {
return packageResult;
}
if (extensions !== 1 /* JavaScript */) {
return loadModuleFromNodeModulesFolder(2 /* DtsOnly */, ts.combinePaths("@types", moduleName), directory, failedLookupLocations, state);
}
}
function classicNameResolver(moduleName, containingFile, compilerOptions, host) {
var traceEnabled = isTraceEnabled(compilerOptions, host);
var state = { compilerOptions: compilerOptions, host: host, traceEnabled: traceEnabled };
var failedLookupLocations = [];
var containingDirectory = ts.getDirectoryPath(containingFile);
var resolved = tryResolve(0 /* TypeScript */) || tryResolve(1 /* JavaScript */);
return createResolvedModuleWithFailedLookupLocations(resolved, /*isExternalLibraryImport*/ false, failedLookupLocations);
function tryResolve(extensions) {
var resolvedUsingSettings = tryLoadModuleUsingOptionalResolutionSettings(extensions, moduleName, containingDirectory, loadModuleFromFile, failedLookupLocations, state);
if (resolvedUsingSettings) {
return resolvedUsingSettings;
}
if (moduleHasNonRelativeName(moduleName)) {
// Climb up parent directories looking for a module.
var resolved_3 = forEachAncestorDirectory(containingDirectory, function (directory) {
var searchName = ts.normalizePath(ts.combinePaths(directory, moduleName));
return loadModuleFromFile(extensions, searchName, failedLookupLocations, /*onlyRecordFailures*/ false, state);
});
if (resolved_3) {
return resolved_3;
}
if (extensions === 0 /* TypeScript */) {
// If we didn't find the file normally, look it up in @types.
return loadModuleFromNodeModulesAtTypes(moduleName, containingDirectory, failedLookupLocations, state);
}
}
else {
var candidate = ts.normalizePath(ts.combinePaths(containingDirectory, moduleName));
return loadModuleFromFile(extensions, candidate, failedLookupLocations, /*onlyRecordFailures*/ false, state);
}
}
}
ts.classicNameResolver = classicNameResolver;
/**
* LSHost may load a module from a global cache of typings.
* This is the minumum code needed to expose that functionality; the rest is in LSHost.
*/
/* @internal */
function loadModuleFromGlobalCache(moduleName, projectName, compilerOptions, host, globalCache) {
var traceEnabled = isTraceEnabled(compilerOptions, host);
if (traceEnabled) {
trace(host, ts.Diagnostics.Auto_discovery_for_typings_is_enabled_in_project_0_Running_extra_resolution_pass_for_module_1_using_cache_location_2, projectName, moduleName, globalCache);
}
var state = { compilerOptions: compilerOptions, host: host, traceEnabled: traceEnabled };
var failedLookupLocations = [];
var resolved = loadModuleFromNodeModulesOneLevel(2 /* DtsOnly */, moduleName, globalCache, failedLookupLocations, state);
return createResolvedModuleWithFailedLookupLocations(resolved, /*isExternalLibraryImport*/ true, failedLookupLocations);
}
ts.loadModuleFromGlobalCache = loadModuleFromGlobalCache;
/** Calls `callback` on `directory` and every ancestor directory it has, returning the first defined result. */
function forEachAncestorDirectory(directory, callback) {
while (true) {
var result = callback(directory);
if (result !== undefined) {
return result;
}
var parentPath = ts.getDirectoryPath(directory);
if (parentPath === directory) {
return undefined;
}
directory = parentPath;
}
}
})(ts || (ts = {}));
/// <reference path="moduleNameResolver.ts"/>
/// <reference path="binder.ts"/>
/* @internal */
var ts;
(function (ts) {
var ambientModuleSymbolRegex = /^".+"$/;
var nextSymbolId = 1;
var nextNodeId = 1;
var nextMergeId = 1;
var nextFlowId = 1;
function getNodeId(node) {
if (!node.id) {
node.id = nextNodeId;
nextNodeId++;
}
return node.id;
}
ts.getNodeId = getNodeId;
function getSymbolId(symbol) {
if (!symbol.id) {
symbol.id = nextSymbolId;
nextSymbolId++;
}
return symbol.id;
}
ts.getSymbolId = getSymbolId;
function createTypeChecker(host, produceDiagnostics) {
// Cancellation that controls whether or not we can cancel in the middle of type checking.
// In general cancelling is *not* safe for the type checker. We might be in the middle of
// computing something, and we will leave our internals in an inconsistent state. Callers
// who set the cancellation token should catch if a cancellation exception occurs, and
// should throw away and create a new TypeChecker.
//
// Currently we only support setting the cancellation token when getting diagnostics. This
// is because diagnostics can be quite expensive, and we want to allow hosts to bail out if
// they no longer need the information (for example, if the user started editing again).
var cancellationToken;
var Symbol = ts.objectAllocator.getSymbolConstructor();
var Type = ts.objectAllocator.getTypeConstructor();
var Signature = ts.objectAllocator.getSignatureConstructor();
var typeCount = 0;
var symbolCount = 0;
var emptyArray = [];
var emptySymbols = ts.createMap();
var compilerOptions = host.getCompilerOptions();
var languageVersion = compilerOptions.target || 0 /* ES3 */;
var modulekind = ts.getEmitModuleKind(compilerOptions);
var noUnusedIdentifiers = !!compilerOptions.noUnusedLocals || !!compilerOptions.noUnusedParameters;
var allowSyntheticDefaultImports = typeof compilerOptions.allowSyntheticDefaultImports !== "undefined" ? compilerOptions.allowSyntheticDefaultImports : modulekind === ts.ModuleKind.System;
var strictNullChecks = compilerOptions.strictNullChecks;
var emitResolver = createResolver();
var undefinedSymbol = createSymbol(4 /* Property */ | 67108864 /* Transient */, "undefined");
undefinedSymbol.declarations = [];
var argumentsSymbol = createSymbol(4 /* Property */ | 67108864 /* Transient */, "arguments");
var checker = {
getNodeCount: function () { return ts.sum(host.getSourceFiles(), "nodeCount"); },
getIdentifierCount: function () { return ts.sum(host.getSourceFiles(), "identifierCount"); },
getSymbolCount: function () { return ts.sum(host.getSourceFiles(), "symbolCount") + symbolCount; },
getTypeCount: function () { return typeCount; },
isUndefinedSymbol: function (symbol) { return symbol === undefinedSymbol; },
isArgumentsSymbol: function (symbol) { return symbol === argumentsSymbol; },
isUnknownSymbol: function (symbol) { return symbol === unknownSymbol; },
getDiagnostics: getDiagnostics,
getGlobalDiagnostics: getGlobalDiagnostics,
getTypeOfSymbolAtLocation: getTypeOfSymbolAtLocation,
getSymbolsOfParameterPropertyDeclaration: getSymbolsOfParameterPropertyDeclaration,
getDeclaredTypeOfSymbol: getDeclaredTypeOfSymbol,
getPropertiesOfType: getPropertiesOfType,
getPropertyOfType: getPropertyOfType,
getSignaturesOfType: getSignaturesOfType,
getIndexTypeOfType: getIndexTypeOfType,
getBaseTypes: getBaseTypes,
getReturnTypeOfSignature: getReturnTypeOfSignature,
getNonNullableType: getNonNullableType,
getSymbolsInScope: getSymbolsInScope,
getSymbolAtLocation: getSymbolAtLocation,
getShorthandAssignmentValueSymbol: getShorthandAssignmentValueSymbol,
getExportSpecifierLocalTargetSymbol: getExportSpecifierLocalTargetSymbol,
getTypeAtLocation: getTypeOfNode,
getPropertySymbolOfDestructuringAssignment: getPropertySymbolOfDestructuringAssignment,
typeToString: typeToString,
getSymbolDisplayBuilder: getSymbolDisplayBuilder,
symbolToString: symbolToString,
getAugmentedPropertiesOfType: getAugmentedPropertiesOfType,
getRootSymbols: getRootSymbols,
getContextualType: getContextualType,
getFullyQualifiedName: getFullyQualifiedName,
getResolvedSignature: getResolvedSignature,
getConstantValue: getConstantValue,
isValidPropertyAccess: isValidPropertyAccess,
getSignatureFromDeclaration: getSignatureFromDeclaration,
isImplementationOfOverload: isImplementationOfOverload,
getAliasedSymbol: resolveAlias,
getEmitResolver: getEmitResolver,
getExportsOfModule: getExportsOfModuleAsArray,
getAmbientModules: getAmbientModules,
getJsxElementAttributesType: getJsxElementAttributesType,
getJsxIntrinsicTagNames: getJsxIntrinsicTagNames,
isOptionalParameter: isOptionalParameter,
tryFindAmbientModuleWithoutAugmentations: function (moduleName) {
// we deliberately exclude augmentations
// since we are only interested in declarations of the module itself
return tryFindAmbientModule(moduleName, /*withAugmentations*/ false);
}
};
var tupleTypes = [];
var unionTypes = ts.createMap();
var intersectionTypes = ts.createMap();
var stringLiteralTypes = ts.createMap();
var numericLiteralTypes = ts.createMap();
var evolvingArrayTypes = [];
var unknownSymbol = createSymbol(4 /* Property */ | 67108864 /* Transient */, "unknown");
var resolvingSymbol = createSymbol(67108864 /* Transient */, "__resolving__");
var anyType = createIntrinsicType(1 /* Any */, "any");
var autoType = createIntrinsicType(1 /* Any */, "any");
var unknownType = createIntrinsicType(1 /* Any */, "unknown");
var undefinedType = createIntrinsicType(2048 /* Undefined */, "undefined");
var undefinedWideningType = strictNullChecks ? undefinedType : createIntrinsicType(2048 /* Undefined */ | 2097152 /* ContainsWideningType */, "undefined");
var nullType = createIntrinsicType(4096 /* Null */, "null");
var nullWideningType = strictNullChecks ? nullType : createIntrinsicType(4096 /* Null */ | 2097152 /* ContainsWideningType */, "null");
var stringType = createIntrinsicType(2 /* String */, "string");
var numberType = createIntrinsicType(4 /* Number */, "number");
var trueType = createIntrinsicType(128 /* BooleanLiteral */, "true");
var falseType = createIntrinsicType(128 /* BooleanLiteral */, "false");
var booleanType = createBooleanType([trueType, falseType]);
var esSymbolType = createIntrinsicType(512 /* ESSymbol */, "symbol");
var voidType = createIntrinsicType(1024 /* Void */, "void");
var neverType = createIntrinsicType(8192 /* Never */, "never");
var silentNeverType = createIntrinsicType(8192 /* Never */, "never");
var stringOrNumberType = getUnionType([stringType, numberType]);
var emptyObjectType = createAnonymousType(undefined, emptySymbols, emptyArray, emptyArray, undefined, undefined);
var emptyTypeLiteralSymbol = createSymbol(2048 /* TypeLiteral */ | 67108864 /* Transient */, "__type");
emptyTypeLiteralSymbol.members = ts.createMap();
var emptyTypeLiteralType = createAnonymousType(emptyTypeLiteralSymbol, emptySymbols, emptyArray, emptyArray, undefined, undefined);
var emptyGenericType = createAnonymousType(undefined, emptySymbols, emptyArray, emptyArray, undefined, undefined);
emptyGenericType.instantiations = ts.createMap();
var anyFunctionType = createAnonymousType(undefined, emptySymbols, emptyArray, emptyArray, undefined, undefined);
// The anyFunctionType contains the anyFunctionType by definition. The flag is further propagated
// in getPropagatingFlagsOfTypes, and it is checked in inferFromTypes.
anyFunctionType.flags |= 8388608 /* ContainsAnyFunctionType */;
var noConstraintType = createAnonymousType(undefined, emptySymbols, emptyArray, emptyArray, undefined, undefined);
var anySignature = createSignature(undefined, undefined, undefined, emptyArray, anyType, /*typePredicate*/ undefined, 0, /*hasRestParameter*/ false, /*hasLiteralTypes*/ false);
var unknownSignature = createSignature(undefined, undefined, undefined, emptyArray, unknownType, /*typePredicate*/ undefined, 0, /*hasRestParameter*/ false, /*hasLiteralTypes*/ false);
var resolvingSignature = createSignature(undefined, undefined, undefined, emptyArray, anyType, /*typePredicate*/ undefined, 0, /*hasRestParameter*/ false, /*hasLiteralTypes*/ false);
var silentNeverSignature = createSignature(undefined, undefined, undefined, emptyArray, silentNeverType, /*typePredicate*/ undefined, 0, /*hasRestParameter*/ false, /*hasLiteralTypes*/ false);
var enumNumberIndexInfo = createIndexInfo(stringType, /*isReadonly*/ true);
var globals = ts.createMap();
/**
* List of every ambient module with a "*" wildcard.
* Unlike other ambient modules, these can't be stored in `globals` because symbol tables only deal with exact matches.
* This is only used if there is no exact match.
*/
var patternAmbientModules;
var getGlobalESSymbolConstructorSymbol;
var getGlobalPromiseConstructorSymbol;
var tryGetGlobalPromiseConstructorSymbol;
var globalObjectType;
var globalFunctionType;
var globalArrayType;
var globalReadonlyArrayType;
var globalStringType;
var globalNumberType;
var globalBooleanType;
var globalRegExpType;
var anyArrayType;
var autoArrayType;
var anyReadonlyArrayType;
// The library files are only loaded when the feature is used.
// This allows users to just specify library files they want to used through --lib
// and they will not get an error from not having unrelated library files
var getGlobalTemplateStringsArrayType;
var getGlobalESSymbolType;
var getGlobalIterableType;
var getGlobalIteratorType;
var getGlobalIterableIteratorType;
var getGlobalClassDecoratorType;
var getGlobalParameterDecoratorType;
var getGlobalPropertyDecoratorType;
var getGlobalMethodDecoratorType;
var getGlobalTypedPropertyDescriptorType;
var getGlobalPromiseType;
var tryGetGlobalPromiseType;
var getGlobalPromiseLikeType;
var getInstantiatedGlobalPromiseLikeType;
var getGlobalPromiseConstructorLikeType;
var getGlobalThenableType;
var jsxElementClassType;
var deferredNodes;
var deferredUnusedIdentifierNodes;
var flowLoopStart = 0;
var flowLoopCount = 0;
var visitedFlowCount = 0;
var emptyStringType = getLiteralTypeForText(32 /* StringLiteral */, "");
var zeroType = getLiteralTypeForText(64 /* NumberLiteral */, "0");
var resolutionTargets = [];
var resolutionResults = [];
var resolutionPropertyNames = [];
var mergedSymbols = [];
var symbolLinks = [];
var nodeLinks = [];
var flowLoopCaches = [];
var flowLoopNodes = [];
var flowLoopKeys = [];
var flowLoopTypes = [];
var visitedFlowNodes = [];
var visitedFlowTypes = [];
var potentialThisCollisions = [];
var awaitedTypeStack = [];
var diagnostics = ts.createDiagnosticCollection();
var TypeFacts;
(function (TypeFacts) {
TypeFacts[TypeFacts["None"] = 0] = "None";
TypeFacts[TypeFacts["TypeofEQString"] = 1] = "TypeofEQString";
TypeFacts[TypeFacts["TypeofEQNumber"] = 2] = "TypeofEQNumber";
TypeFacts[TypeFacts["TypeofEQBoolean"] = 4] = "TypeofEQBoolean";
TypeFacts[TypeFacts["TypeofEQSymbol"] = 8] = "TypeofEQSymbol";
TypeFacts[TypeFacts["TypeofEQObject"] = 16] = "TypeofEQObject";
TypeFacts[TypeFacts["TypeofEQFunction"] = 32] = "TypeofEQFunction";
TypeFacts[TypeFacts["TypeofEQHostObject"] = 64] = "TypeofEQHostObject";
TypeFacts[TypeFacts["TypeofNEString"] = 128] = "TypeofNEString";
TypeFacts[TypeFacts["TypeofNENumber"] = 256] = "TypeofNENumber";
TypeFacts[TypeFacts["TypeofNEBoolean"] = 512] = "TypeofNEBoolean";
TypeFacts[TypeFacts["TypeofNESymbol"] = 1024] = "TypeofNESymbol";
TypeFacts[TypeFacts["TypeofNEObject"] = 2048] = "TypeofNEObject";
TypeFacts[TypeFacts["TypeofNEFunction"] = 4096] = "TypeofNEFunction";
TypeFacts[TypeFacts["TypeofNEHostObject"] = 8192] = "TypeofNEHostObject";
TypeFacts[TypeFacts["EQUndefined"] = 16384] = "EQUndefined";
TypeFacts[TypeFacts["EQNull"] = 32768] = "EQNull";
TypeFacts[TypeFacts["EQUndefinedOrNull"] = 65536] = "EQUndefinedOrNull";
TypeFacts[TypeFacts["NEUndefined"] = 131072] = "NEUndefined";
TypeFacts[TypeFacts["NENull"] = 262144] = "NENull";
TypeFacts[TypeFacts["NEUndefinedOrNull"] = 524288] = "NEUndefinedOrNull";
TypeFacts[TypeFacts["Truthy"] = 1048576] = "Truthy";
TypeFacts[TypeFacts["Falsy"] = 2097152] = "Falsy";
TypeFacts[TypeFacts["Discriminatable"] = 4194304] = "Discriminatable";
TypeFacts[TypeFacts["All"] = 8388607] = "All";
// The following members encode facts about particular kinds of types for use in the getTypeFacts function.
// The presence of a particular fact means that the given test is true for some (and possibly all) values
// of that kind of type.
TypeFacts[TypeFacts["BaseStringStrictFacts"] = 933633] = "BaseStringStrictFacts";
TypeFacts[TypeFacts["BaseStringFacts"] = 3145473] = "BaseStringFacts";
TypeFacts[TypeFacts["StringStrictFacts"] = 4079361] = "StringStrictFacts";
TypeFacts[TypeFacts["StringFacts"] = 4194049] = "StringFacts";
TypeFacts[TypeFacts["EmptyStringStrictFacts"] = 3030785] = "EmptyStringStrictFacts";
TypeFacts[TypeFacts["EmptyStringFacts"] = 3145473] = "EmptyStringFacts";
TypeFacts[TypeFacts["NonEmptyStringStrictFacts"] = 1982209] = "NonEmptyStringStrictFacts";
TypeFacts[TypeFacts["NonEmptyStringFacts"] = 4194049] = "NonEmptyStringFacts";
TypeFacts[TypeFacts["BaseNumberStrictFacts"] = 933506] = "BaseNumberStrictFacts";
TypeFacts[TypeFacts["BaseNumberFacts"] = 3145346] = "BaseNumberFacts";
TypeFacts[TypeFacts["NumberStrictFacts"] = 4079234] = "NumberStrictFacts";
TypeFacts[TypeFacts["NumberFacts"] = 4193922] = "NumberFacts";
TypeFacts[TypeFacts["ZeroStrictFacts"] = 3030658] = "ZeroStrictFacts";
TypeFacts[TypeFacts["ZeroFacts"] = 3145346] = "ZeroFacts";
TypeFacts[TypeFacts["NonZeroStrictFacts"] = 1982082] = "NonZeroStrictFacts";
TypeFacts[TypeFacts["NonZeroFacts"] = 4193922] = "NonZeroFacts";
TypeFacts[TypeFacts["BaseBooleanStrictFacts"] = 933252] = "BaseBooleanStrictFacts";
TypeFacts[TypeFacts["BaseBooleanFacts"] = 3145092] = "BaseBooleanFacts";
TypeFacts[TypeFacts["BooleanStrictFacts"] = 4078980] = "BooleanStrictFacts";
TypeFacts[TypeFacts["BooleanFacts"] = 4193668] = "BooleanFacts";
TypeFacts[TypeFacts["FalseStrictFacts"] = 3030404] = "FalseStrictFacts";
TypeFacts[TypeFacts["FalseFacts"] = 3145092] = "FalseFacts";
TypeFacts[TypeFacts["TrueStrictFacts"] = 1981828] = "TrueStrictFacts";
TypeFacts[TypeFacts["TrueFacts"] = 4193668] = "TrueFacts";
TypeFacts[TypeFacts["SymbolStrictFacts"] = 1981320] = "SymbolStrictFacts";
TypeFacts[TypeFacts["SymbolFacts"] = 4193160] = "SymbolFacts";
TypeFacts[TypeFacts["ObjectStrictFacts"] = 6166480] = "ObjectStrictFacts";
TypeFacts[TypeFacts["ObjectFacts"] = 8378320] = "ObjectFacts";
TypeFacts[TypeFacts["FunctionStrictFacts"] = 6164448] = "FunctionStrictFacts";
TypeFacts[TypeFacts["FunctionFacts"] = 8376288] = "FunctionFacts";
TypeFacts[TypeFacts["UndefinedFacts"] = 2457472] = "UndefinedFacts";
TypeFacts[TypeFacts["NullFacts"] = 2340752] = "NullFacts";
})(TypeFacts || (TypeFacts = {}));
var typeofEQFacts = ts.createMap({
"string": 1 /* TypeofEQString */,
"number": 2 /* TypeofEQNumber */,
"boolean": 4 /* TypeofEQBoolean */,
"symbol": 8 /* TypeofEQSymbol */,
"undefined": 16384 /* EQUndefined */,
"object": 16 /* TypeofEQObject */,
"function": 32 /* TypeofEQFunction */
});
var typeofNEFacts = ts.createMap({
"string": 128 /* TypeofNEString */,
"number": 256 /* TypeofNENumber */,
"boolean": 512 /* TypeofNEBoolean */,
"symbol": 1024 /* TypeofNESymbol */,
"undefined": 131072 /* NEUndefined */,
"object": 2048 /* TypeofNEObject */,
"function": 4096 /* TypeofNEFunction */
});
var typeofTypesByName = ts.createMap({
"string": stringType,
"number": numberType,
"boolean": booleanType,
"symbol": esSymbolType,
"undefined": undefinedType
});
var jsxElementType;
var _jsxNamespace;
var _jsxFactoryEntity;
/** Things we lazy load from the JSX namespace */
var jsxTypes = ts.createMap();
var JsxNames = {
JSX: "JSX",
IntrinsicElements: "IntrinsicElements",
ElementClass: "ElementClass",
ElementAttributesPropertyNameContainer: "ElementAttributesProperty",
Element: "Element",
IntrinsicAttributes: "IntrinsicAttributes",
IntrinsicClassAttributes: "IntrinsicClassAttributes"
};
var subtypeRelation = ts.createMap();
var assignableRelation = ts.createMap();
var comparableRelation = ts.createMap();
var identityRelation = ts.createMap();
var enumRelation = ts.createMap();
// This is for caching the result of getSymbolDisplayBuilder. Do not access directly.
var _displayBuilder;
var TypeSystemPropertyName;
(function (TypeSystemPropertyName) {
TypeSystemPropertyName[TypeSystemPropertyName["Type"] = 0] = "Type";
TypeSystemPropertyName[TypeSystemPropertyName["ResolvedBaseConstructorType"] = 1] = "ResolvedBaseConstructorType";
TypeSystemPropertyName[TypeSystemPropertyName["DeclaredType"] = 2] = "DeclaredType";
TypeSystemPropertyName[TypeSystemPropertyName["ResolvedReturnType"] = 3] = "ResolvedReturnType";
})(TypeSystemPropertyName || (TypeSystemPropertyName = {}));
var builtinGlobals = ts.createMap();
builtinGlobals[undefinedSymbol.name] = undefinedSymbol;
initializeTypeChecker();
return checker;
function getJsxNamespace() {
if (_jsxNamespace === undefined) {
_jsxNamespace = "React";
if (compilerOptions.jsxFactory) {
_jsxFactoryEntity = ts.parseIsolatedEntityName(compilerOptions.jsxFactory, languageVersion);
if (_jsxFactoryEntity) {
_jsxNamespace = getFirstIdentifier(_jsxFactoryEntity).text;
}
}
else if (compilerOptions.reactNamespace) {
_jsxNamespace = compilerOptions.reactNamespace;
}
}
return _jsxNamespace;
}
function getEmitResolver(sourceFile, cancellationToken) {
// Ensure we have all the type information in place for this file so that all the
// emitter questions of this resolver will return the right information.
getDiagnostics(sourceFile, cancellationToken);
return emitResolver;
}
function error(location, message, arg0, arg1, arg2) {
var diagnostic = location
? ts.createDiagnosticForNode(location, message, arg0, arg1, arg2)
: ts.createCompilerDiagnostic(message, arg0, arg1, arg2);
diagnostics.add(diagnostic);
}
function createSymbol(flags, name) {
symbolCount++;
return new Symbol(flags, name);
}
function getExcludedSymbolFlags(flags) {
var result = 0;
if (flags & 2 /* BlockScopedVariable */)
result |= 107455 /* BlockScopedVariableExcludes */;
if (flags & 1 /* FunctionScopedVariable */)
result |= 107454 /* FunctionScopedVariableExcludes */;
if (flags & 4 /* Property */)
result |= 0 /* PropertyExcludes */;
if (flags & 8 /* EnumMember */)
result |= 900095 /* EnumMemberExcludes */;
if (flags & 16 /* Function */)
result |= 106927 /* FunctionExcludes */;
if (flags & 32 /* Class */)
result |= 899519 /* ClassExcludes */;
if (flags & 64 /* Interface */)
result |= 792968 /* InterfaceExcludes */;
if (flags & 256 /* RegularEnum */)
result |= 899327 /* RegularEnumExcludes */;
if (flags & 128 /* ConstEnum */)
result |= 899967 /* ConstEnumExcludes */;
if (flags & 512 /* ValueModule */)
result |= 106639 /* ValueModuleExcludes */;
if (flags & 8192 /* Method */)
result |= 99263 /* MethodExcludes */;
if (flags & 32768 /* GetAccessor */)
result |= 41919 /* GetAccessorExcludes */;
if (flags & 65536 /* SetAccessor */)
result |= 74687 /* SetAccessorExcludes */;
if (flags & 262144 /* TypeParameter */)
result |= 530920 /* TypeParameterExcludes */;
if (flags & 524288 /* TypeAlias */)
result |= 793064 /* TypeAliasExcludes */;
if (flags & 8388608 /* Alias */)
result |= 8388608 /* AliasExcludes */;
return result;
}
function recordMergedSymbol(target, source) {
if (!source.mergeId) {
source.mergeId = nextMergeId;
nextMergeId++;
}
mergedSymbols[source.mergeId] = target;
}
function cloneSymbol(symbol) {
var result = createSymbol(symbol.flags | 33554432 /* Merged */, symbol.name);
result.declarations = symbol.declarations.slice(0);
result.parent = symbol.parent;
if (symbol.valueDeclaration)
result.valueDeclaration = symbol.valueDeclaration;
if (symbol.constEnumOnlyModule)
result.constEnumOnlyModule = true;
if (symbol.members)
result.members = ts.cloneMap(symbol.members);
if (symbol.exports)
result.exports = ts.cloneMap(symbol.exports);
recordMergedSymbol(result, symbol);
return result;
}
function mergeSymbol(target, source) {
if (!(target.flags & getExcludedSymbolFlags(source.flags))) {
if (source.flags & 512 /* ValueModule */ && target.flags & 512 /* ValueModule */ && target.constEnumOnlyModule && !source.constEnumOnlyModule) {
// reset flag when merging instantiated module into value module that has only const enums
target.constEnumOnlyModule = false;
}
target.flags |= source.flags;
if (source.valueDeclaration &&
(!target.valueDeclaration ||
(target.valueDeclaration.kind === 230 /* ModuleDeclaration */ && source.valueDeclaration.kind !== 230 /* ModuleDeclaration */))) {
// other kinds of value declarations take precedence over modules
target.valueDeclaration = source.valueDeclaration;
}
ts.forEach(source.declarations, function (node) {
target.declarations.push(node);
});
if (source.members) {
if (!target.members)
target.members = ts.createMap();
mergeSymbolTable(target.members, source.members);
}
if (source.exports) {
if (!target.exports)
target.exports = ts.createMap();
mergeSymbolTable(target.exports, source.exports);
}
recordMergedSymbol(target, source);
}
else {
var message_2 = target.flags & 2 /* BlockScopedVariable */ || source.flags & 2 /* BlockScopedVariable */
? ts.Diagnostics.Cannot_redeclare_block_scoped_variable_0 : ts.Diagnostics.Duplicate_identifier_0;
ts.forEach(source.declarations, function (node) {
error(node.name ? node.name : node, message_2, symbolToString(source));
});
ts.forEach(target.declarations, function (node) {
error(node.name ? node.name : node, message_2, symbolToString(source));
});
}
}
function mergeSymbolTable(target, source) {
for (var id in source) {
var targetSymbol = target[id];
if (!targetSymbol) {
target[id] = source[id];
}
else {
if (!(targetSymbol.flags & 33554432 /* Merged */)) {
target[id] = targetSymbol = cloneSymbol(targetSymbol);
}
mergeSymbol(targetSymbol, source[id]);
}
}
}
function mergeModuleAugmentation(moduleName) {
var moduleAugmentation = moduleName.parent;
if (moduleAugmentation.symbol.declarations[0] !== moduleAugmentation) {
// this is a combined symbol for multiple augmentations within the same file.
// its symbol already has accumulated information for all declarations
// so we need to add it just once - do the work only for first declaration
ts.Debug.assert(moduleAugmentation.symbol.declarations.length > 1);
return;
}
if (ts.isGlobalScopeAugmentation(moduleAugmentation)) {
mergeSymbolTable(globals, moduleAugmentation.symbol.exports);
}
else {
// find a module that about to be augmented
// do not validate names of augmentations that are defined in ambient context
var moduleNotFoundError = !ts.isInAmbientContext(moduleName.parent.parent)
? ts.Diagnostics.Invalid_module_name_in_augmentation_module_0_cannot_be_found
: undefined;
var mainModule = resolveExternalModuleNameWorker(moduleName, moduleName, moduleNotFoundError, /*isForAugmentation*/ true);
if (!mainModule) {
return;
}
// obtain item referenced by 'export='
mainModule = resolveExternalModuleSymbol(mainModule);
if (mainModule.flags & 1920 /* Namespace */) {
// if module symbol has already been merged - it is safe to use it.
// otherwise clone it
mainModule = mainModule.flags & 33554432 /* Merged */ ? mainModule : cloneSymbol(mainModule);
mergeSymbol(mainModule, moduleAugmentation.symbol);
}
else {
error(moduleName, ts.Diagnostics.Cannot_augment_module_0_because_it_resolves_to_a_non_module_entity, moduleName.text);
}
}
}
function addToSymbolTable(target, source, message) {
for (var id in source) {
if (target[id]) {
// Error on redeclarations
ts.forEach(target[id].declarations, addDeclarationDiagnostic(id, message));
}
else {
target[id] = source[id];
}
}
function addDeclarationDiagnostic(id, message) {
return function (declaration) { return diagnostics.add(ts.createDiagnosticForNode(declaration, message, id)); };
}
}
function getSymbolLinks(symbol) {
if (symbol.flags & 67108864 /* Transient */)
return symbol;
var id = getSymbolId(symbol);
return symbolLinks[id] || (symbolLinks[id] = {});
}
function getNodeLinks(node) {
var nodeId = getNodeId(node);
return nodeLinks[nodeId] || (nodeLinks[nodeId] = { flags: 0 });
}
function getObjectFlags(type) {
return type.flags & 32768 /* Object */ ? type.objectFlags : 0;
}
function isGlobalSourceFile(node) {
return node.kind === 261 /* SourceFile */ && !ts.isExternalOrCommonJsModule(node);
}
function getSymbol(symbols, name, meaning) {
if (meaning) {
var symbol = symbols[name];
if (symbol) {
ts.Debug.assert((symbol.flags & 16777216 /* Instantiated */) === 0, "Should never get an instantiated symbol here.");
if (symbol.flags & meaning) {
return symbol;
}
if (symbol.flags & 8388608 /* Alias */) {
var target = resolveAlias(symbol);
// Unknown symbol means an error occurred in alias resolution, treat it as positive answer to avoid cascading errors
if (target === unknownSymbol || target.flags & meaning) {
return symbol;
}
}
}
}
// return undefined if we can't find a symbol.
}
/**
* Get symbols that represent parameter-property-declaration as parameter and as property declaration
* @param parameter a parameterDeclaration node
* @param parameterName a name of the parameter to get the symbols for.
* @return a tuple of two symbols
*/
function getSymbolsOfParameterPropertyDeclaration(parameter, parameterName) {
var constructorDeclaration = parameter.parent;
var classDeclaration = parameter.parent.parent;
var parameterSymbol = getSymbol(constructorDeclaration.locals, parameterName, 107455 /* Value */);
var propertySymbol = getSymbol(classDeclaration.symbol.members, parameterName, 107455 /* Value */);
if (parameterSymbol && propertySymbol) {
return [parameterSymbol, propertySymbol];
}
ts.Debug.fail("There should exist two symbols, one as property declaration and one as parameter declaration");
}
function isBlockScopedNameDeclaredBeforeUse(declaration, usage) {
var declarationFile = ts.getSourceFileOfNode(declaration);
var useFile = ts.getSourceFileOfNode(usage);
if (declarationFile !== useFile) {
if ((modulekind && (declarationFile.externalModuleIndicator || useFile.externalModuleIndicator)) ||
(!compilerOptions.outFile && !compilerOptions.out)) {
// nodes are in different files and order cannot be determines
return true;
}
// declaration is after usage
// can be legal if usage is deferred (i.e. inside function or in initializer of instance property)
if (isUsedInFunctionOrNonStaticProperty(usage)) {
return true;
}
var sourceFiles = host.getSourceFiles();
return ts.indexOf(sourceFiles, declarationFile) <= ts.indexOf(sourceFiles, useFile);
}
if (declaration.pos <= usage.pos) {
// declaration is before usage
// still might be illegal if usage is in the initializer of the variable declaration
return declaration.kind !== 223 /* VariableDeclaration */ ||
!isImmediatelyUsedInInitializerOfBlockScopedVariable(declaration, usage);
}
// declaration is after usage
// can be legal if usage is deferred (i.e. inside function or in initializer of instance property)
var container = ts.getEnclosingBlockScopeContainer(declaration);
return isUsedInFunctionOrNonStaticProperty(usage, container);
function isImmediatelyUsedInInitializerOfBlockScopedVariable(declaration, usage) {
var container = ts.getEnclosingBlockScopeContainer(declaration);
switch (declaration.parent.parent.kind) {
case 205 /* VariableStatement */:
case 211 /* ForStatement */:
case 213 /* ForOfStatement */:
// variable statement/for/for-of statement case,
// use site should not be inside variable declaration (initializer of declaration or binding element)
if (isSameScopeDescendentOf(usage, declaration, container)) {
return true;
}
break;
}
switch (declaration.parent.parent.kind) {
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
// ForIn/ForOf case - use site should not be used in expression part
if (isSameScopeDescendentOf(usage, declaration.parent.parent.expression, container)) {
return true;
}
}
return false;
}
function isUsedInFunctionOrNonStaticProperty(usage, container) {
var current = usage;
while (current) {
if (current === container) {
return false;
}
if (ts.isFunctionLike(current)) {
return true;
}
var initializerOfNonStaticProperty = current.parent &&
current.parent.kind === 147 /* PropertyDeclaration */ &&
(ts.getModifierFlags(current.parent) & 32 /* Static */) === 0 &&
current.parent.initializer === current;
if (initializerOfNonStaticProperty) {
return true;
}
current = current.parent;
}
return false;
}
}
// Resolve a given name for a given meaning at a given location. An error is reported if the name was not found and
// the nameNotFoundMessage argument is not undefined. Returns the resolved symbol, or undefined if no symbol with
// the given name can be found.
function resolveName(location, name, meaning, nameNotFoundMessage, nameArg) {
var result;
var lastLocation;
var propertyWithInvalidInitializer;
var errorLocation = location;
var grandparent;
var isInExternalModule = false;
loop: while (location) {
// Locals of a source file are not in scope (because they get merged into the global symbol table)
if (location.locals && !isGlobalSourceFile(location)) {
if (result = getSymbol(location.locals, name, meaning)) {
var useResult = true;
if (ts.isFunctionLike(location) && lastLocation && lastLocation !== location.body) {
// symbol lookup restrictions for function-like declarations
// - Type parameters of a function are in scope in the entire function declaration, including the parameter
// list and return type. However, local types are only in scope in the function body.
// - parameters are only in the scope of function body
// This restriction does not apply to JSDoc comment types because they are parented
// at a higher level than type parameters would normally be
if (meaning & result.flags & 793064 /* Type */ && lastLocation.kind !== 278 /* JSDocComment */) {
useResult = result.flags & 262144 /* TypeParameter */
? lastLocation === location.type ||
lastLocation.kind === 144 /* Parameter */ ||
lastLocation.kind === 143 /* TypeParameter */
: false;
}
if (meaning & 107455 /* Value */ && result.flags & 1 /* FunctionScopedVariable */) {
// parameters are visible only inside function body, parameter list and return type
// technically for parameter list case here we might mix parameters and variables declared in function,
// however it is detected separately when checking initializers of parameters
// to make sure that they reference no variables declared after them.
useResult =
lastLocation.kind === 144 /* Parameter */ ||
(lastLocation === location.type &&
result.valueDeclaration.kind === 144 /* Parameter */);
}
}
if (useResult) {
break loop;
}
else {
result = undefined;
}
}
}
switch (location.kind) {
case 261 /* SourceFile */:
if (!ts.isExternalOrCommonJsModule(location))
break;
isInExternalModule = true;
case 230 /* ModuleDeclaration */:
var moduleExports = getSymbolOfNode(location).exports;
if (location.kind === 261 /* SourceFile */ || ts.isAmbientModule(location)) {
// It's an external module. First see if the module has an export default and if the local
// name of that export default matches.
if (result = moduleExports["default"]) {
var localSymbol = ts.getLocalSymbolForExportDefault(result);
if (localSymbol && (result.flags & meaning) && localSymbol.name === name) {
break loop;
}
result = undefined;
}
// Because of module/namespace merging, a module's exports are in scope,
// yet we never want to treat an export specifier as putting a member in scope.
// Therefore, if the name we find is purely an export specifier, it is not actually considered in scope.
// Two things to note about this:
// 1. We have to check this without calling getSymbol. The problem with calling getSymbol
// on an export specifier is that it might find the export specifier itself, and try to
// resolve it as an alias. This will cause the checker to consider the export specifier
// a circular alias reference when it might not be.
// 2. We check === SymbolFlags.Alias in order to check that the symbol is *purely*
// an alias. If we used &, we'd be throwing out symbols that have non alias aspects,
// which is not the desired behavior.
if (moduleExports[name] &&
moduleExports[name].flags === 8388608 /* Alias */ &&
ts.getDeclarationOfKind(moduleExports[name], 243 /* ExportSpecifier */)) {
break;
}
}
if (result = getSymbol(moduleExports, name, meaning & 8914931 /* ModuleMember */)) {
break loop;
}
break;
case 229 /* EnumDeclaration */:
if (result = getSymbol(getSymbolOfNode(location).exports, name, meaning & 8 /* EnumMember */)) {
break loop;
}
break;
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
// TypeScript 1.0 spec (April 2014): 8.4.1
// Initializer expressions for instance member variables are evaluated in the scope
// of the class constructor body but are not permitted to reference parameters or
// local variables of the constructor. This effectively means that entities from outer scopes
// by the same name as a constructor parameter or local variable are inaccessible
// in initializer expressions for instance member variables.
if (ts.isClassLike(location.parent) && !(ts.getModifierFlags(location) & 32 /* Static */)) {
var ctor = findConstructorDeclaration(location.parent);
if (ctor && ctor.locals) {
if (getSymbol(ctor.locals, name, meaning & 107455 /* Value */)) {
// Remember the property node, it will be used later to report appropriate error
propertyWithInvalidInitializer = location;
}
}
}
break;
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
if (result = getSymbol(getSymbolOfNode(location).members, name, meaning & 793064 /* Type */)) {
if (lastLocation && ts.getModifierFlags(lastLocation) & 32 /* Static */) {
// TypeScript 1.0 spec (April 2014): 3.4.1
// The scope of a type parameter extends over the entire declaration with which the type
// parameter list is associated, with the exception of static member declarations in classes.
error(errorLocation, ts.Diagnostics.Static_members_cannot_reference_class_type_parameters);
return undefined;
}
break loop;
}
if (location.kind === 197 /* ClassExpression */ && meaning & 32 /* Class */) {
var className = location.name;
if (className && name === className.text) {
result = location.symbol;
break loop;
}
}
break;
// It is not legal to reference a class's own type parameters from a computed property name that
// belongs to the class. For example:
//
// function foo<T>() { return '' }
// class C<T> { // <-- Class's own type parameter T
// [foo<T>()]() { } // <-- Reference to T from class's own computed property
// }
//
case 142 /* ComputedPropertyName */:
grandparent = location.parent.parent;
if (ts.isClassLike(grandparent) || grandparent.kind === 227 /* InterfaceDeclaration */) {
// A reference to this grandparent's type parameters would be an error
if (result = getSymbol(getSymbolOfNode(grandparent).members, name, meaning & 793064 /* Type */)) {
error(errorLocation, ts.Diagnostics.A_computed_property_name_cannot_reference_a_type_parameter_from_its_containing_type);
return undefined;
}
}
break;
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 225 /* FunctionDeclaration */:
case 185 /* ArrowFunction */:
if (meaning & 3 /* Variable */ && name === "arguments") {
result = argumentsSymbol;
break loop;
}
break;
case 184 /* FunctionExpression */:
if (meaning & 3 /* Variable */ && name === "arguments") {
result = argumentsSymbol;
break loop;
}
if (meaning & 16 /* Function */) {
var functionName = location.name;
if (functionName && name === functionName.text) {
result = location.symbol;
break loop;
}
}
break;
case 145 /* Decorator */:
// Decorators are resolved at the class declaration. Resolving at the parameter
// or member would result in looking up locals in the method.
//
// function y() {}
// class C {
// method(@y x, y) {} // <-- decorator y should be resolved at the class declaration, not the parameter.
// }
//
if (location.parent && location.parent.kind === 144 /* Parameter */) {
location = location.parent;
}
//
// function y() {}
// class C {
// @y method(x, y) {} // <-- decorator y should be resolved at the class declaration, not the method.
// }
//
if (location.parent && ts.isClassElement(location.parent)) {
location = location.parent;
}
break;
}
lastLocation = location;
location = location.parent;
}
if (result && nameNotFoundMessage && noUnusedIdentifiers) {
result.isReferenced = true;
}
if (!result) {
result = getSymbol(globals, name, meaning);
}
if (!result) {
if (nameNotFoundMessage) {
if (!errorLocation ||
!checkAndReportErrorForMissingPrefix(errorLocation, name, nameArg) &&
!checkAndReportErrorForExtendingInterface(errorLocation) &&
!checkAndReportErrorForUsingTypeAsValue(errorLocation, name, meaning)) {
error(errorLocation, nameNotFoundMessage, typeof nameArg === "string" ? nameArg : ts.declarationNameToString(nameArg));
}
}
return undefined;
}
// Perform extra checks only if error reporting was requested
if (nameNotFoundMessage) {
if (propertyWithInvalidInitializer) {
// We have a match, but the reference occurred within a property initializer and the identifier also binds
// to a local variable in the constructor where the code will be emitted.
var propertyName = propertyWithInvalidInitializer.name;
error(errorLocation, ts.Diagnostics.Initializer_of_instance_member_variable_0_cannot_reference_identifier_1_declared_in_the_constructor, ts.declarationNameToString(propertyName), typeof nameArg === "string" ? nameArg : ts.declarationNameToString(nameArg));
return undefined;
}
// Only check for block-scoped variable if we are looking for the
// name with variable meaning
// For example,
// declare module foo {
// interface bar {}
// }
// const foo/*1*/: foo/*2*/.bar;
// The foo at /*1*/ and /*2*/ will share same symbol with two meaning
// block - scope variable and namespace module. However, only when we
// try to resolve name in /*1*/ which is used in variable position,
// we want to check for block- scoped
if (meaning & 2 /* BlockScopedVariable */) {
var exportOrLocalSymbol = getExportSymbolOfValueSymbolIfExported(result);
if (exportOrLocalSymbol.flags & 2 /* BlockScopedVariable */) {
checkResolvedBlockScopedVariable(exportOrLocalSymbol, errorLocation);
}
}
// If we're in an external module, we can't reference value symbols created from UMD export declarations
if (result && isInExternalModule && (meaning & 107455 /* Value */) === 107455 /* Value */) {
var decls = result.declarations;
if (decls && decls.length === 1 && decls[0].kind === 233 /* NamespaceExportDeclaration */) {
error(errorLocation, ts.Diagnostics._0_refers_to_a_UMD_global_but_the_current_file_is_a_module_Consider_adding_an_import_instead, name);
}
}
}
return result;
}
function checkAndReportErrorForMissingPrefix(errorLocation, name, nameArg) {
if ((errorLocation.kind === 70 /* Identifier */ && (isTypeReferenceIdentifier(errorLocation)) || isInTypeQuery(errorLocation))) {
return false;
}
var container = ts.getThisContainer(errorLocation, /* includeArrowFunctions */ true);
var location = container;
while (location) {
if (ts.isClassLike(location.parent)) {
var classSymbol = getSymbolOfNode(location.parent);
if (!classSymbol) {
break;
}
// Check to see if a static member exists.
var constructorType = getTypeOfSymbol(classSymbol);
if (getPropertyOfType(constructorType, name)) {
error(errorLocation, ts.Diagnostics.Cannot_find_name_0_Did_you_mean_the_static_member_1_0, typeof nameArg === "string" ? nameArg : ts.declarationNameToString(nameArg), symbolToString(classSymbol));
return true;
}
// No static member is present.
// Check if we're in an instance method and look for a relevant instance member.
if (location === container && !(ts.getModifierFlags(location) & 32 /* Static */)) {
var instanceType = getDeclaredTypeOfSymbol(classSymbol).thisType;
if (getPropertyOfType(instanceType, name)) {
error(errorLocation, ts.Diagnostics.Cannot_find_name_0_Did_you_mean_the_instance_member_this_0, typeof nameArg === "string" ? nameArg : ts.declarationNameToString(nameArg));
return true;
}
}
}
location = location.parent;
}
return false;
}
function checkAndReportErrorForExtendingInterface(errorLocation) {
var expression = getEntityNameForExtendingInterface(errorLocation);
var isError = !!(expression && resolveEntityName(expression, 64 /* Interface */, /*ignoreErrors*/ true));
if (isError) {
error(errorLocation, ts.Diagnostics.Cannot_extend_an_interface_0_Did_you_mean_implements, ts.getTextOfNode(expression));
}
return isError;
}
/**
* Climbs up parents to an ExpressionWithTypeArguments, and returns its expression,
* but returns undefined if that expression is not an EntityNameExpression.
*/
function getEntityNameForExtendingInterface(node) {
switch (node.kind) {
case 70 /* Identifier */:
case 177 /* PropertyAccessExpression */:
return node.parent ? getEntityNameForExtendingInterface(node.parent) : undefined;
case 199 /* ExpressionWithTypeArguments */:
ts.Debug.assert(ts.isEntityNameExpression(node.expression));
return node.expression;
default:
return undefined;
}
}
function checkAndReportErrorForUsingTypeAsValue(errorLocation, name, meaning) {
if (meaning & (107455 /* Value */ & ~1024 /* NamespaceModule */)) {
var symbol = resolveSymbol(resolveName(errorLocation, name, 793064 /* Type */ & ~107455 /* Value */, /*nameNotFoundMessage*/ undefined, /*nameArg*/ undefined));
if (symbol && !(symbol.flags & 1024 /* NamespaceModule */)) {
error(errorLocation, ts.Diagnostics._0_only_refers_to_a_type_but_is_being_used_as_a_value_here, name);
return true;
}
}
return false;
}
function checkResolvedBlockScopedVariable(result, errorLocation) {
ts.Debug.assert((result.flags & 2 /* BlockScopedVariable */) !== 0);
// Block-scoped variables cannot be used before their definition
var declaration = ts.forEach(result.declarations, function (d) { return ts.isBlockOrCatchScoped(d) ? d : undefined; });
ts.Debug.assert(declaration !== undefined, "Block-scoped variable declaration is undefined");
if (!ts.isInAmbientContext(declaration) && !isBlockScopedNameDeclaredBeforeUse(ts.getAncestor(declaration, 223 /* VariableDeclaration */), errorLocation)) {
error(errorLocation, ts.Diagnostics.Block_scoped_variable_0_used_before_its_declaration, ts.declarationNameToString(declaration.name));
}
}
/* Starting from 'initial' node walk up the parent chain until 'stopAt' node is reached.
* If at any point current node is equal to 'parent' node - return true.
* Return false if 'stopAt' node is reached or isFunctionLike(current) === true.
*/
function isSameScopeDescendentOf(initial, parent, stopAt) {
if (!parent) {
return false;
}
for (var current = initial; current && current !== stopAt && !ts.isFunctionLike(current); current = current.parent) {
if (current === parent) {
return true;
}
}
return false;
}
function getAnyImportSyntax(node) {
if (ts.isAliasSymbolDeclaration(node)) {
if (node.kind === 234 /* ImportEqualsDeclaration */) {
return node;
}
while (node && node.kind !== 235 /* ImportDeclaration */) {
node = node.parent;
}
return node;
}
}
function getDeclarationOfAliasSymbol(symbol) {
return ts.forEach(symbol.declarations, function (d) { return ts.isAliasSymbolDeclaration(d) ? d : undefined; });
}
function getTargetOfImportEqualsDeclaration(node) {
if (node.moduleReference.kind === 245 /* ExternalModuleReference */) {
return resolveExternalModuleSymbol(resolveExternalModuleName(node, ts.getExternalModuleImportEqualsDeclarationExpression(node)));
}
return getSymbolOfPartOfRightHandSideOfImportEquals(node.moduleReference);
}
function getTargetOfImportClause(node) {
var moduleSymbol = resolveExternalModuleName(node, node.parent.moduleSpecifier);
if (moduleSymbol) {
var exportDefaultSymbol = ts.isShorthandAmbientModuleSymbol(moduleSymbol) ?
moduleSymbol :
moduleSymbol.exports["export="] ?
getPropertyOfType(getTypeOfSymbol(moduleSymbol.exports["export="]), "default") :
resolveSymbol(moduleSymbol.exports["default"]);
if (!exportDefaultSymbol && !allowSyntheticDefaultImports) {
error(node.name, ts.Diagnostics.Module_0_has_no_default_export, symbolToString(moduleSymbol));
}
else if (!exportDefaultSymbol && allowSyntheticDefaultImports) {
return resolveExternalModuleSymbol(moduleSymbol) || resolveSymbol(moduleSymbol);
}
return exportDefaultSymbol;
}
}
function getTargetOfNamespaceImport(node) {
var moduleSpecifier = node.parent.parent.moduleSpecifier;
return resolveESModuleSymbol(resolveExternalModuleName(node, moduleSpecifier), moduleSpecifier);
}
// This function creates a synthetic symbol that combines the value side of one symbol with the
// type/namespace side of another symbol. Consider this example:
//
// declare module graphics {
// interface Point {
// x: number;
// y: number;
// }
// }
// declare var graphics: {
// Point: new (x: number, y: number) => graphics.Point;
// }
// declare module "graphics" {
// export = graphics;
// }
//
// An 'import { Point } from "graphics"' needs to create a symbol that combines the value side 'Point'
// property with the type/namespace side interface 'Point'.
function combineValueAndTypeSymbols(valueSymbol, typeSymbol) {
if (valueSymbol.flags & (793064 /* Type */ | 1920 /* Namespace */)) {
return valueSymbol;
}
var result = createSymbol(valueSymbol.flags | typeSymbol.flags, valueSymbol.name);
result.declarations = ts.concatenate(valueSymbol.declarations, typeSymbol.declarations);
result.parent = valueSymbol.parent || typeSymbol.parent;
if (valueSymbol.valueDeclaration)
result.valueDeclaration = valueSymbol.valueDeclaration;
if (typeSymbol.members)
result.members = typeSymbol.members;
if (valueSymbol.exports)
result.exports = valueSymbol.exports;
return result;
}
function getExportOfModule(symbol, name) {
if (symbol.flags & 1536 /* Module */) {
var exportedSymbol = getExportsOfSymbol(symbol)[name];
if (exportedSymbol) {
return resolveSymbol(exportedSymbol);
}
}
}
function getPropertyOfVariable(symbol, name) {
if (symbol.flags & 3 /* Variable */) {
var typeAnnotation = symbol.valueDeclaration.type;
if (typeAnnotation) {
return resolveSymbol(getPropertyOfType(getTypeFromTypeNode(typeAnnotation), name));
}
}
}
function getExternalModuleMember(node, specifier) {
var moduleSymbol = resolveExternalModuleName(node, node.moduleSpecifier);
var targetSymbol = resolveESModuleSymbol(moduleSymbol, node.moduleSpecifier);
if (targetSymbol) {
var name_17 = specifier.propertyName || specifier.name;
if (name_17.text) {
if (ts.isShorthandAmbientModuleSymbol(moduleSymbol)) {
return moduleSymbol;
}
var symbolFromVariable = void 0;
// First check if module was specified with "export=". If so, get the member from the resolved type
if (moduleSymbol && moduleSymbol.exports && moduleSymbol.exports["export="]) {
symbolFromVariable = getPropertyOfType(getTypeOfSymbol(targetSymbol), name_17.text);
}
else {
symbolFromVariable = getPropertyOfVariable(targetSymbol, name_17.text);
}
// if symbolFromVariable is export - get its final target
symbolFromVariable = resolveSymbol(symbolFromVariable);
var symbolFromModule = getExportOfModule(targetSymbol, name_17.text);
// If the export member we're looking for is default, and there is no real default but allowSyntheticDefaultImports is on, return the entire module as the default
if (!symbolFromModule && allowSyntheticDefaultImports && name_17.text === "default") {
symbolFromModule = resolveExternalModuleSymbol(moduleSymbol) || resolveSymbol(moduleSymbol);
}
var symbol = symbolFromModule && symbolFromVariable ?
combineValueAndTypeSymbols(symbolFromVariable, symbolFromModule) :
symbolFromModule || symbolFromVariable;
if (!symbol) {
error(name_17, ts.Diagnostics.Module_0_has_no_exported_member_1, getFullyQualifiedName(moduleSymbol), ts.declarationNameToString(name_17));
}
return symbol;
}
}
}
function getTargetOfImportSpecifier(node) {
return getExternalModuleMember(node.parent.parent.parent, node);
}
function getTargetOfNamespaceExportDeclaration(node) {
return resolveExternalModuleSymbol(node.parent.symbol);
}
function getTargetOfExportSpecifier(node) {
return node.parent.parent.moduleSpecifier ?
getExternalModuleMember(node.parent.parent, node) :
resolveEntityName(node.propertyName || node.name, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */);
}
function getTargetOfExportAssignment(node) {
return resolveEntityName(node.expression, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */);
}
function getTargetOfAliasDeclaration(node) {
switch (node.kind) {
case 234 /* ImportEqualsDeclaration */:
return getTargetOfImportEqualsDeclaration(node);
case 236 /* ImportClause */:
return getTargetOfImportClause(node);
case 237 /* NamespaceImport */:
return getTargetOfNamespaceImport(node);
case 239 /* ImportSpecifier */:
return getTargetOfImportSpecifier(node);
case 243 /* ExportSpecifier */:
return getTargetOfExportSpecifier(node);
case 240 /* ExportAssignment */:
return getTargetOfExportAssignment(node);
case 233 /* NamespaceExportDeclaration */:
return getTargetOfNamespaceExportDeclaration(node);
}
}
function resolveSymbol(symbol) {
return symbol && symbol.flags & 8388608 /* Alias */ && !(symbol.flags & (107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */)) ? resolveAlias(symbol) : symbol;
}
function resolveAlias(symbol) {
ts.Debug.assert((symbol.flags & 8388608 /* Alias */) !== 0, "Should only get Alias here.");
var links = getSymbolLinks(symbol);
if (!links.target) {
links.target = resolvingSymbol;
var node = getDeclarationOfAliasSymbol(symbol);
ts.Debug.assert(!!node);
var target = getTargetOfAliasDeclaration(node);
if (links.target === resolvingSymbol) {
links.target = target || unknownSymbol;
}
else {
error(node, ts.Diagnostics.Circular_definition_of_import_alias_0, symbolToString(symbol));
}
}
else if (links.target === resolvingSymbol) {
links.target = unknownSymbol;
}
return links.target;
}
function markExportAsReferenced(node) {
var symbol = getSymbolOfNode(node);
var target = resolveAlias(symbol);
if (target) {
var markAlias = target === unknownSymbol ||
((target.flags & 107455 /* Value */) && !isConstEnumOrConstEnumOnlyModule(target));
if (markAlias) {
markAliasSymbolAsReferenced(symbol);
}
}
}
// When an alias symbol is referenced, we need to mark the entity it references as referenced and in turn repeat that until
// we reach a non-alias or an exported entity (which is always considered referenced). We do this by checking the target of
// the alias as an expression (which recursively takes us back here if the target references another alias).
function markAliasSymbolAsReferenced(symbol) {
var links = getSymbolLinks(symbol);
if (!links.referenced) {
links.referenced = true;
var node = getDeclarationOfAliasSymbol(symbol);
ts.Debug.assert(!!node);
if (node.kind === 240 /* ExportAssignment */) {
// export default <symbol>
checkExpressionCached(node.expression);
}
else if (node.kind === 243 /* ExportSpecifier */) {
// export { <symbol> } or export { <symbol> as foo }
checkExpressionCached(node.propertyName || node.name);
}
else if (ts.isInternalModuleImportEqualsDeclaration(node)) {
// import foo = <symbol>
checkExpressionCached(node.moduleReference);
}
}
}
// This function is only for imports with entity names
function getSymbolOfPartOfRightHandSideOfImportEquals(entityName, dontResolveAlias) {
// There are three things we might try to look for. In the following examples,
// the search term is enclosed in |...|:
//
// import a = |b|; // Namespace
// import a = |b.c|; // Value, type, namespace
// import a = |b.c|.d; // Namespace
if (entityName.kind === 70 /* Identifier */ && ts.isRightSideOfQualifiedNameOrPropertyAccess(entityName)) {
entityName = entityName.parent;
}
// Check for case 1 and 3 in the above example
if (entityName.kind === 70 /* Identifier */ || entityName.parent.kind === 141 /* QualifiedName */) {
return resolveEntityName(entityName, 1920 /* Namespace */, /*ignoreErrors*/ false, dontResolveAlias);
}
else {
// Case 2 in above example
// entityName.kind could be a QualifiedName or a Missing identifier
ts.Debug.assert(entityName.parent.kind === 234 /* ImportEqualsDeclaration */);
return resolveEntityName(entityName, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */, /*ignoreErrors*/ false, dontResolveAlias);
}
}
function getFullyQualifiedName(symbol) {
return symbol.parent ? getFullyQualifiedName(symbol.parent) + "." + symbolToString(symbol) : symbolToString(symbol);
}
// Resolves a qualified name and any involved aliases
function resolveEntityName(name, meaning, ignoreErrors, dontResolveAlias, location) {
if (ts.nodeIsMissing(name)) {
return undefined;
}
var symbol;
if (name.kind === 70 /* Identifier */) {
var message = meaning === 1920 /* Namespace */ ? ts.Diagnostics.Cannot_find_namespace_0 : ts.Diagnostics.Cannot_find_name_0;
symbol = resolveName(location || name, name.text, meaning, ignoreErrors ? undefined : message, name);
if (!symbol) {
return undefined;
}
}
else if (name.kind === 141 /* QualifiedName */ || name.kind === 177 /* PropertyAccessExpression */) {
var left = name.kind === 141 /* QualifiedName */ ? name.left : name.expression;
var right = name.kind === 141 /* QualifiedName */ ? name.right : name.name;
var namespace = resolveEntityName(left, 1920 /* Namespace */, ignoreErrors, /*dontResolveAlias*/ false, location);
if (!namespace || ts.nodeIsMissing(right)) {
return undefined;
}
else if (namespace === unknownSymbol) {
return namespace;
}
symbol = getSymbol(getExportsOfSymbol(namespace), right.text, meaning);
if (!symbol) {
if (!ignoreErrors) {
error(right, ts.Diagnostics.Namespace_0_has_no_exported_member_1, getFullyQualifiedName(namespace), ts.declarationNameToString(right));
}
return undefined;
}
}
else {
ts.Debug.fail("Unknown entity name kind.");
}
ts.Debug.assert((symbol.flags & 16777216 /* Instantiated */) === 0, "Should never get an instantiated symbol here.");
return (symbol.flags & meaning) || dontResolveAlias ? symbol : resolveAlias(symbol);
}
function resolveExternalModuleName(location, moduleReferenceExpression) {
return resolveExternalModuleNameWorker(location, moduleReferenceExpression, ts.Diagnostics.Cannot_find_module_0);
}
function resolveExternalModuleNameWorker(location, moduleReferenceExpression, moduleNotFoundError, isForAugmentation) {
if (isForAugmentation === void 0) { isForAugmentation = false; }
if (moduleReferenceExpression.kind !== 9 /* StringLiteral */) {
return;
}
var moduleReferenceLiteral = moduleReferenceExpression;
return resolveExternalModule(location, moduleReferenceLiteral.text, moduleNotFoundError, moduleReferenceLiteral, isForAugmentation);
}
function resolveExternalModule(location, moduleReference, moduleNotFoundError, errorNode, isForAugmentation) {
if (isForAugmentation === void 0) { isForAugmentation = false; }
// Module names are escaped in our symbol table. However, string literal values aren't.
// Escape the name in the "require(...)" clause to ensure we find the right symbol.
var moduleName = ts.escapeIdentifier(moduleReference);
if (moduleName === undefined) {
return;
}
var ambientModule = tryFindAmbientModule(moduleName, /*withAugmentations*/ true);
if (ambientModule) {
return ambientModule;
}
var isRelative = ts.isExternalModuleNameRelative(moduleName);
var resolvedModule = ts.getResolvedModule(ts.getSourceFileOfNode(location), moduleReference);
var resolutionDiagnostic = resolvedModule && ts.getResolutionDiagnostic(compilerOptions, resolvedModule);
var sourceFile = resolvedModule && !resolutionDiagnostic && host.getSourceFile(resolvedModule.resolvedFileName);
if (sourceFile) {
if (sourceFile.symbol) {
// merged symbol is module declaration symbol combined with all augmentations
return getMergedSymbol(sourceFile.symbol);
}
if (moduleNotFoundError) {
// report errors only if it was requested
error(errorNode, ts.Diagnostics.File_0_is_not_a_module, sourceFile.fileName);
}
return undefined;
}
if (patternAmbientModules) {
var pattern = ts.findBestPatternMatch(patternAmbientModules, function (_) { return _.pattern; }, moduleName);
if (pattern) {
return getMergedSymbol(pattern.symbol);
}
}
// May be an untyped module. If so, ignore resolutionDiagnostic.
if (!isRelative && resolvedModule && !ts.extensionIsTypeScript(resolvedModule.extension)) {
if (isForAugmentation) {
ts.Debug.assert(!!moduleNotFoundError);
var diag = ts.Diagnostics.Invalid_module_name_in_augmentation_Module_0_resolves_to_an_untyped_module_at_1_which_cannot_be_augmented;
error(errorNode, diag, moduleName, resolvedModule.resolvedFileName);
}
else if (compilerOptions.noImplicitAny && moduleNotFoundError) {
error(errorNode, ts.Diagnostics.Could_not_find_a_declaration_file_for_module_0_1_implicitly_has_an_any_type, moduleReference, resolvedModule.resolvedFileName);
}
// Failed imports and untyped modules are both treated in an untyped manner; only difference is whether we give a diagnostic first.
return undefined;
}
if (moduleNotFoundError) {
// report errors only if it was requested
if (resolutionDiagnostic) {
error(errorNode, resolutionDiagnostic, moduleName, resolvedModule.resolvedFileName);
}
else {
var tsExtension = ts.tryExtractTypeScriptExtension(moduleName);
if (tsExtension) {
var diag = ts.Diagnostics.An_import_path_cannot_end_with_a_0_extension_Consider_importing_1_instead;
error(errorNode, diag, tsExtension, ts.removeExtension(moduleName, tsExtension));
}
else {
error(errorNode, moduleNotFoundError, moduleName);
}
}
}
return undefined;
}
// An external module with an 'export =' declaration resolves to the target of the 'export =' declaration,
// and an external module with no 'export =' declaration resolves to the module itself.
function resolveExternalModuleSymbol(moduleSymbol) {
return moduleSymbol && getMergedSymbol(resolveSymbol(moduleSymbol.exports["export="])) || moduleSymbol;
}
// An external module with an 'export =' declaration may be referenced as an ES6 module provided the 'export ='
// references a symbol that is at least declared as a module or a variable. The target of the 'export =' may
// combine other declarations with the module or variable (e.g. a class/module, function/module, interface/variable).
function resolveESModuleSymbol(moduleSymbol, moduleReferenceExpression) {
var symbol = resolveExternalModuleSymbol(moduleSymbol);
if (symbol && !(symbol.flags & (1536 /* Module */ | 3 /* Variable */))) {
error(moduleReferenceExpression, ts.Diagnostics.Module_0_resolves_to_a_non_module_entity_and_cannot_be_imported_using_this_construct, symbolToString(moduleSymbol));
symbol = undefined;
}
return symbol;
}
function hasExportAssignmentSymbol(moduleSymbol) {
return moduleSymbol.exports["export="] !== undefined;
}
function getExportsOfModuleAsArray(moduleSymbol) {
return symbolsToArray(getExportsOfModule(moduleSymbol));
}
function getExportsOfSymbol(symbol) {
return symbol.flags & 1536 /* Module */ ? getExportsOfModule(symbol) : symbol.exports || emptySymbols;
}
function getExportsOfModule(moduleSymbol) {
var links = getSymbolLinks(moduleSymbol);
return links.resolvedExports || (links.resolvedExports = getExportsForModule(moduleSymbol));
}
/**
* Extends one symbol table with another while collecting information on name collisions for error message generation into the `lookupTable` argument
* Not passing `lookupTable` and `exportNode` disables this collection, and just extends the tables
*/
function extendExportSymbols(target, source, lookupTable, exportNode) {
for (var id in source) {
if (id !== "default" && !target[id]) {
target[id] = source[id];
if (lookupTable && exportNode) {
lookupTable[id] = {
specifierText: ts.getTextOfNode(exportNode.moduleSpecifier)
};
}
}
else if (lookupTable && exportNode && id !== "default" && target[id] && resolveSymbol(target[id]) !== resolveSymbol(source[id])) {
if (!lookupTable[id].exportsWithDuplicate) {
lookupTable[id].exportsWithDuplicate = [exportNode];
}
else {
lookupTable[id].exportsWithDuplicate.push(exportNode);
}
}
}
}
function getExportsForModule(moduleSymbol) {
var visitedSymbols = [];
// A module defined by an 'export=' consists on one export that needs to be resolved
moduleSymbol = resolveExternalModuleSymbol(moduleSymbol);
return visit(moduleSymbol) || moduleSymbol.exports;
// The ES6 spec permits export * declarations in a module to circularly reference the module itself. For example,
// module 'a' can 'export * from "b"' and 'b' can 'export * from "a"' without error.
function visit(symbol) {
if (!(symbol && symbol.flags & 1952 /* HasExports */ && !ts.contains(visitedSymbols, symbol))) {
return;
}
visitedSymbols.push(symbol);
var symbols = ts.cloneMap(symbol.exports);
// All export * declarations are collected in an __export symbol by the binder
var exportStars = symbol.exports["__export"];
if (exportStars) {
var nestedSymbols = ts.createMap();
var lookupTable = ts.createMap();
for (var _i = 0, _a = exportStars.declarations; _i < _a.length; _i++) {
var node = _a[_i];
var resolvedModule = resolveExternalModuleName(node, node.moduleSpecifier);
var exportedSymbols = visit(resolvedModule);
extendExportSymbols(nestedSymbols, exportedSymbols, lookupTable, node);
}
for (var id in lookupTable) {
var exportsWithDuplicate = lookupTable[id].exportsWithDuplicate;
// It's not an error if the file with multiple `export *`s with duplicate names exports a member with that name itself
if (id === "export=" || !(exportsWithDuplicate && exportsWithDuplicate.length) || symbols[id]) {
continue;
}
for (var _b = 0, exportsWithDuplicate_1 = exportsWithDuplicate; _b < exportsWithDuplicate_1.length; _b++) {
var node = exportsWithDuplicate_1[_b];
diagnostics.add(ts.createDiagnosticForNode(node, ts.Diagnostics.Module_0_has_already_exported_a_member_named_1_Consider_explicitly_re_exporting_to_resolve_the_ambiguity, lookupTable[id].specifierText, id));
}
}
extendExportSymbols(symbols, nestedSymbols);
}
return symbols;
}
}
function getMergedSymbol(symbol) {
var merged;
return symbol && symbol.mergeId && (merged = mergedSymbols[symbol.mergeId]) ? merged : symbol;
}
function getSymbolOfNode(node) {
return getMergedSymbol(node.symbol);
}
function getParentOfSymbol(symbol) {
return getMergedSymbol(symbol.parent);
}
function getExportSymbolOfValueSymbolIfExported(symbol) {
return symbol && (symbol.flags & 1048576 /* ExportValue */) !== 0
? getMergedSymbol(symbol.exportSymbol)
: symbol;
}
function symbolIsValue(symbol) {
// If it is an instantiated symbol, then it is a value if the symbol it is an
// instantiation of is a value.
if (symbol.flags & 16777216 /* Instantiated */) {
return symbolIsValue(getSymbolLinks(symbol).target);
}
// If the symbol has the value flag, it is trivially a value.
if (symbol.flags & 107455 /* Value */) {
return true;
}
// If it is an alias, then it is a value if the symbol it resolves to is a value.
if (symbol.flags & 8388608 /* Alias */) {
return (resolveAlias(symbol).flags & 107455 /* Value */) !== 0;
}
return false;
}
function findConstructorDeclaration(node) {
var members = node.members;
for (var _i = 0, members_1 = members; _i < members_1.length; _i++) {
var member = members_1[_i];
if (member.kind === 150 /* Constructor */ && ts.nodeIsPresent(member.body)) {
return member;
}
}
}
function createType(flags) {
var result = new Type(checker, flags);
typeCount++;
result.id = typeCount;
return result;
}
function createIntrinsicType(kind, intrinsicName) {
var type = createType(kind);
type.intrinsicName = intrinsicName;
return type;
}
function createBooleanType(trueFalseTypes) {
var type = getUnionType(trueFalseTypes);
type.flags |= 8 /* Boolean */;
type.intrinsicName = "boolean";
return type;
}
function createObjectType(objectFlags, symbol) {
var type = createType(32768 /* Object */);
type.objectFlags = objectFlags;
type.symbol = symbol;
return type;
}
// A reserved member name starts with two underscores, but the third character cannot be an underscore
// or the @ symbol. A third underscore indicates an escaped form of an identifer that started
// with at least two underscores. The @ character indicates that the name is denoted by a well known ES
// Symbol instance.
function isReservedMemberName(name) {
return name.charCodeAt(0) === 95 /* _ */ &&
name.charCodeAt(1) === 95 /* _ */ &&
name.charCodeAt(2) !== 95 /* _ */ &&
name.charCodeAt(2) !== 64 /* at */;
}
function getNamedMembers(members) {
var result;
for (var id in members) {
if (!isReservedMemberName(id)) {
if (!result)
result = [];
var symbol = members[id];
if (symbolIsValue(symbol)) {
result.push(symbol);
}
}
}
return result || emptyArray;
}
function setStructuredTypeMembers(type, members, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo) {
type.members = members;
type.properties = getNamedMembers(members);
type.callSignatures = callSignatures;
type.constructSignatures = constructSignatures;
if (stringIndexInfo)
type.stringIndexInfo = stringIndexInfo;
if (numberIndexInfo)
type.numberIndexInfo = numberIndexInfo;
return type;
}
function createAnonymousType(symbol, members, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo) {
return setStructuredTypeMembers(createObjectType(16 /* Anonymous */, symbol), members, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo);
}
function forEachSymbolTableInScope(enclosingDeclaration, callback) {
var result;
for (var location_1 = enclosingDeclaration; location_1; location_1 = location_1.parent) {
// Locals of a source file are not in scope (because they get merged into the global symbol table)
if (location_1.locals && !isGlobalSourceFile(location_1)) {
if (result = callback(location_1.locals)) {
return result;
}
}
switch (location_1.kind) {
case 261 /* SourceFile */:
if (!ts.isExternalOrCommonJsModule(location_1)) {
break;
}
case 230 /* ModuleDeclaration */:
if (result = callback(getSymbolOfNode(location_1).exports)) {
return result;
}
break;
}
}
return callback(globals);
}
function getQualifiedLeftMeaning(rightMeaning) {
// If we are looking in value space, the parent meaning is value, other wise it is namespace
return rightMeaning === 107455 /* Value */ ? 107455 /* Value */ : 1920 /* Namespace */;
}
function getAccessibleSymbolChain(symbol, enclosingDeclaration, meaning, useOnlyExternalAliasing) {
function getAccessibleSymbolChainFromSymbolTable(symbols) {
function canQualifySymbol(symbolFromSymbolTable, meaning) {
// If the symbol is equivalent and doesn't need further qualification, this symbol is accessible
if (!needsQualification(symbolFromSymbolTable, enclosingDeclaration, meaning)) {
return true;
}
// If symbol needs qualification, make sure that parent is accessible, if it is then this symbol is accessible too
var accessibleParent = getAccessibleSymbolChain(symbolFromSymbolTable.parent, enclosingDeclaration, getQualifiedLeftMeaning(meaning), useOnlyExternalAliasing);
return !!accessibleParent;
}
function isAccessible(symbolFromSymbolTable, resolvedAliasSymbol) {
if (symbol === (resolvedAliasSymbol || symbolFromSymbolTable)) {
// if the symbolFromSymbolTable is not external module (it could be if it was determined as ambient external module and would be in globals table)
// and if symbolFromSymbolTable or alias resolution matches the symbol,
// check the symbol can be qualified, it is only then this symbol is accessible
return !ts.forEach(symbolFromSymbolTable.declarations, hasExternalModuleSymbol) &&
canQualifySymbol(symbolFromSymbolTable, meaning);
}
}
// If symbol is directly available by its name in the symbol table
if (isAccessible(symbols[symbol.name])) {
return [symbol];
}
// Check if symbol is any of the alias
return ts.forEachProperty(symbols, function (symbolFromSymbolTable) {
if (symbolFromSymbolTable.flags & 8388608 /* Alias */
&& symbolFromSymbolTable.name !== "export="
&& !ts.getDeclarationOfKind(symbolFromSymbolTable, 243 /* ExportSpecifier */)) {
if (!useOnlyExternalAliasing ||
// Is this external alias, then use it to name
ts.forEach(symbolFromSymbolTable.declarations, ts.isExternalModuleImportEqualsDeclaration)) {
var resolvedImportedSymbol = resolveAlias(symbolFromSymbolTable);
if (isAccessible(symbolFromSymbolTable, resolveAlias(symbolFromSymbolTable))) {
return [symbolFromSymbolTable];
}
// Look in the exported members, if we can find accessibleSymbolChain, symbol is accessible using this chain
// but only if the symbolFromSymbolTable can be qualified
var accessibleSymbolsFromExports = resolvedImportedSymbol.exports ? getAccessibleSymbolChainFromSymbolTable(resolvedImportedSymbol.exports) : undefined;
if (accessibleSymbolsFromExports && canQualifySymbol(symbolFromSymbolTable, getQualifiedLeftMeaning(meaning))) {
return [symbolFromSymbolTable].concat(accessibleSymbolsFromExports);
}
}
}
});
}
if (symbol) {
if (!(isPropertyOrMethodDeclarationSymbol(symbol))) {
return forEachSymbolTableInScope(enclosingDeclaration, getAccessibleSymbolChainFromSymbolTable);
}
}
}
function needsQualification(symbol, enclosingDeclaration, meaning) {
var qualify = false;
forEachSymbolTableInScope(enclosingDeclaration, function (symbolTable) {
// If symbol of this name is not available in the symbol table we are ok
var symbolFromSymbolTable = symbolTable[symbol.name];
if (!symbolFromSymbolTable) {
// Continue to the next symbol table
return false;
}
// If the symbol with this name is present it should refer to the symbol
if (symbolFromSymbolTable === symbol) {
// No need to qualify
return true;
}
// Qualify if the symbol from symbol table has same meaning as expected
symbolFromSymbolTable = (symbolFromSymbolTable.flags & 8388608 /* Alias */ && !ts.getDeclarationOfKind(symbolFromSymbolTable, 243 /* ExportSpecifier */)) ? resolveAlias(symbolFromSymbolTable) : symbolFromSymbolTable;
if (symbolFromSymbolTable.flags & meaning) {
qualify = true;
return true;
}
// Continue to the next symbol table
return false;
});
return qualify;
}
function isPropertyOrMethodDeclarationSymbol(symbol) {
if (symbol.declarations && symbol.declarations.length) {
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
switch (declaration.kind) {
case 147 /* PropertyDeclaration */:
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
continue;
default:
return false;
}
}
return true;
}
return false;
}
/**
* Check if the given symbol in given enclosing declaration is accessible and mark all associated alias to be visible if requested
*
* @param symbol a Symbol to check if accessible
* @param enclosingDeclaration a Node containing reference to the symbol
* @param meaning a SymbolFlags to check if such meaning of the symbol is accessible
* @param shouldComputeAliasToMakeVisible a boolean value to indicate whether to return aliases to be mark visible in case the symbol is accessible
*/
function isSymbolAccessible(symbol, enclosingDeclaration, meaning, shouldComputeAliasesToMakeVisible) {
if (symbol && enclosingDeclaration && !(symbol.flags & 262144 /* TypeParameter */)) {
var initialSymbol = symbol;
var meaningToLook = meaning;
while (symbol) {
// Symbol is accessible if it by itself is accessible
var accessibleSymbolChain = getAccessibleSymbolChain(symbol, enclosingDeclaration, meaningToLook, /*useOnlyExternalAliasing*/ false);
if (accessibleSymbolChain) {
var hasAccessibleDeclarations = hasVisibleDeclarations(accessibleSymbolChain[0], shouldComputeAliasesToMakeVisible);
if (!hasAccessibleDeclarations) {
return {
accessibility: 1 /* NotAccessible */,
errorSymbolName: symbolToString(initialSymbol, enclosingDeclaration, meaning),
errorModuleName: symbol !== initialSymbol ? symbolToString(symbol, enclosingDeclaration, 1920 /* Namespace */) : undefined,
};
}
return hasAccessibleDeclarations;
}
// If we haven't got the accessible symbol, it doesn't mean the symbol is actually inaccessible.
// It could be a qualified symbol and hence verify the path
// e.g.:
// module m {
// export class c {
// }
// }
// const x: typeof m.c
// In the above example when we start with checking if typeof m.c symbol is accessible,
// we are going to see if c can be accessed in scope directly.
// But it can't, hence the accessible is going to be undefined, but that doesn't mean m.c is inaccessible
// It is accessible if the parent m is accessible because then m.c can be accessed through qualification
meaningToLook = getQualifiedLeftMeaning(meaning);
symbol = getParentOfSymbol(symbol);
}
// This could be a symbol that is not exported in the external module
// or it could be a symbol from different external module that is not aliased and hence cannot be named
var symbolExternalModule = ts.forEach(initialSymbol.declarations, getExternalModuleContainer);
if (symbolExternalModule) {
var enclosingExternalModule = getExternalModuleContainer(enclosingDeclaration);
if (symbolExternalModule !== enclosingExternalModule) {
// name from different external module that is not visible
return {
accessibility: 2 /* CannotBeNamed */,
errorSymbolName: symbolToString(initialSymbol, enclosingDeclaration, meaning),
errorModuleName: symbolToString(symbolExternalModule)
};
}
}
// Just a local name that is not accessible
return {
accessibility: 1 /* NotAccessible */,
errorSymbolName: symbolToString(initialSymbol, enclosingDeclaration, meaning),
};
}
return { accessibility: 0 /* Accessible */ };
function getExternalModuleContainer(declaration) {
for (; declaration; declaration = declaration.parent) {
if (hasExternalModuleSymbol(declaration)) {
return getSymbolOfNode(declaration);
}
}
}
}
function hasExternalModuleSymbol(declaration) {
return ts.isAmbientModule(declaration) || (declaration.kind === 261 /* SourceFile */ && ts.isExternalOrCommonJsModule(declaration));
}
function hasVisibleDeclarations(symbol, shouldComputeAliasToMakeVisible) {
var aliasesToMakeVisible;
if (ts.forEach(symbol.declarations, function (declaration) { return !getIsDeclarationVisible(declaration); })) {
return undefined;
}
return { accessibility: 0 /* Accessible */, aliasesToMakeVisible: aliasesToMakeVisible };
function getIsDeclarationVisible(declaration) {
if (!isDeclarationVisible(declaration)) {
// Mark the unexported alias as visible if its parent is visible
// because these kind of aliases can be used to name types in declaration file
var anyImportSyntax = getAnyImportSyntax(declaration);
if (anyImportSyntax &&
!(ts.getModifierFlags(anyImportSyntax) & 1 /* Export */) &&
isDeclarationVisible(anyImportSyntax.parent)) {
// In function "buildTypeDisplay" where we decide whether to write type-alias or serialize types,
// we want to just check if type- alias is accessible or not but we don't care about emitting those alias at that time
// since we will do the emitting later in trackSymbol.
if (shouldComputeAliasToMakeVisible) {
getNodeLinks(declaration).isVisible = true;
if (aliasesToMakeVisible) {
if (!ts.contains(aliasesToMakeVisible, anyImportSyntax)) {
aliasesToMakeVisible.push(anyImportSyntax);
}
}
else {
aliasesToMakeVisible = [anyImportSyntax];
}
}
return true;
}
// Declaration is not visible
return false;
}
return true;
}
}
function isEntityNameVisible(entityName, enclosingDeclaration) {
// get symbol of the first identifier of the entityName
var meaning;
if (entityName.parent.kind === 160 /* TypeQuery */ || ts.isExpressionWithTypeArgumentsInClassExtendsClause(entityName.parent)) {
// Typeof value
meaning = 107455 /* Value */ | 1048576 /* ExportValue */;
}
else if (entityName.kind === 141 /* QualifiedName */ || entityName.kind === 177 /* PropertyAccessExpression */ ||
entityName.parent.kind === 234 /* ImportEqualsDeclaration */) {
// Left identifier from type reference or TypeAlias
// Entity name of the import declaration
meaning = 1920 /* Namespace */;
}
else {
// Type Reference or TypeAlias entity = Identifier
meaning = 793064 /* Type */;
}
var firstIdentifier = getFirstIdentifier(entityName);
var symbol = resolveName(enclosingDeclaration, firstIdentifier.text, meaning, /*nodeNotFoundErrorMessage*/ undefined, /*nameArg*/ undefined);
// Verify if the symbol is accessible
return (symbol && hasVisibleDeclarations(symbol, /*shouldComputeAliasToMakeVisible*/ true)) || {
accessibility: 1 /* NotAccessible */,
errorSymbolName: ts.getTextOfNode(firstIdentifier),
errorNode: firstIdentifier
};
}
function writeKeyword(writer, kind) {
writer.writeKeyword(ts.tokenToString(kind));
}
function writePunctuation(writer, kind) {
writer.writePunctuation(ts.tokenToString(kind));
}
function writeSpace(writer) {
writer.writeSpace(" ");
}
function symbolToString(symbol, enclosingDeclaration, meaning) {
var writer = ts.getSingleLineStringWriter();
getSymbolDisplayBuilder().buildSymbolDisplay(symbol, writer, enclosingDeclaration, meaning);
var result = writer.string();
ts.releaseStringWriter(writer);
return result;
}
function signatureToString(signature, enclosingDeclaration, flags, kind) {
var writer = ts.getSingleLineStringWriter();
getSymbolDisplayBuilder().buildSignatureDisplay(signature, writer, enclosingDeclaration, flags, kind);
var result = writer.string();
ts.releaseStringWriter(writer);
return result;
}
function typeToString(type, enclosingDeclaration, flags) {
var writer = ts.getSingleLineStringWriter();
getSymbolDisplayBuilder().buildTypeDisplay(type, writer, enclosingDeclaration, flags);
var result = writer.string();
ts.releaseStringWriter(writer);
var maxLength = compilerOptions.noErrorTruncation || flags & 4 /* NoTruncation */ ? undefined : 100;
if (maxLength && result.length >= maxLength) {
result = result.substr(0, maxLength - "...".length) + "...";
}
return result;
}
function typePredicateToString(typePredicate, enclosingDeclaration, flags) {
var writer = ts.getSingleLineStringWriter();
getSymbolDisplayBuilder().buildTypePredicateDisplay(typePredicate, writer, enclosingDeclaration, flags);
var result = writer.string();
ts.releaseStringWriter(writer);
return result;
}
function formatUnionTypes(types) {
var result = [];
var flags = 0;
for (var i = 0; i < types.length; i++) {
var t = types[i];
flags |= t.flags;
if (!(t.flags & 6144 /* Nullable */)) {
if (t.flags & (128 /* BooleanLiteral */ | 256 /* EnumLiteral */)) {
var baseType = t.flags & 128 /* BooleanLiteral */ ? booleanType : t.baseType;
var count = baseType.types.length;
if (i + count <= types.length && types[i + count - 1] === baseType.types[count - 1]) {
result.push(baseType);
i += count - 1;
continue;
}
}
result.push(t);
}
}
if (flags & 4096 /* Null */)
result.push(nullType);
if (flags & 2048 /* Undefined */)
result.push(undefinedType);
return result || types;
}
function visibilityToString(flags) {
if (flags === 8 /* Private */) {
return "private";
}
if (flags === 16 /* Protected */) {
return "protected";
}
return "public";
}
function getTypeAliasForTypeLiteral(type) {
if (type.symbol && type.symbol.flags & 2048 /* TypeLiteral */) {
var node = type.symbol.declarations[0].parent;
while (node.kind === 166 /* ParenthesizedType */) {
node = node.parent;
}
if (node.kind === 228 /* TypeAliasDeclaration */) {
return getSymbolOfNode(node);
}
}
return undefined;
}
function isTopLevelInExternalModuleAugmentation(node) {
return node && node.parent &&
node.parent.kind === 231 /* ModuleBlock */ &&
ts.isExternalModuleAugmentation(node.parent.parent);
}
function literalTypeToString(type) {
return type.flags & 32 /* StringLiteral */ ? "\"" + ts.escapeString(type.text) + "\"" : type.text;
}
function getSymbolDisplayBuilder() {
function getNameOfSymbol(symbol) {
if (symbol.declarations && symbol.declarations.length) {
var declaration = symbol.declarations[0];
if (declaration.name) {
return ts.declarationNameToString(declaration.name);
}
switch (declaration.kind) {
case 197 /* ClassExpression */:
return "(Anonymous class)";
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return "(Anonymous function)";
}
}
return symbol.name;
}
/**
* Writes only the name of the symbol out to the writer. Uses the original source text
* for the name of the symbol if it is available to match how the user wrote the name.
*/
function appendSymbolNameOnly(symbol, writer) {
writer.writeSymbol(getNameOfSymbol(symbol), symbol);
}
/**
* Writes a property access or element access with the name of the symbol out to the writer.
* Uses the original source text for the name of the symbol if it is available to match how the user wrote the name,
* ensuring that any names written with literals use element accesses.
*/
function appendPropertyOrElementAccessForSymbol(symbol, writer) {
var symbolName = getNameOfSymbol(symbol);
var firstChar = symbolName.charCodeAt(0);
var needsElementAccess = !ts.isIdentifierStart(firstChar, languageVersion);
if (needsElementAccess) {
writePunctuation(writer, 20 /* OpenBracketToken */);
if (ts.isSingleOrDoubleQuote(firstChar)) {
writer.writeStringLiteral(symbolName);
}
else {
writer.writeSymbol(symbolName, symbol);
}
writePunctuation(writer, 21 /* CloseBracketToken */);
}
else {
writePunctuation(writer, 22 /* DotToken */);
writer.writeSymbol(symbolName, symbol);
}
}
/**
* Enclosing declaration is optional when we don't want to get qualified name in the enclosing declaration scope
* Meaning needs to be specified if the enclosing declaration is given
*/
function buildSymbolDisplay(symbol, writer, enclosingDeclaration, meaning, flags, typeFlags) {
var parentSymbol;
function appendParentTypeArgumentsAndSymbolName(symbol) {
if (parentSymbol) {
// Write type arguments of instantiated class/interface here
if (flags & 1 /* WriteTypeParametersOrArguments */) {
if (symbol.flags & 16777216 /* Instantiated */) {
buildDisplayForTypeArgumentsAndDelimiters(getTypeParametersOfClassOrInterface(parentSymbol), symbol.mapper, writer, enclosingDeclaration);
}
else {
buildTypeParameterDisplayFromSymbol(parentSymbol, writer, enclosingDeclaration);
}
}
appendPropertyOrElementAccessForSymbol(symbol, writer);
}
else {
appendSymbolNameOnly(symbol, writer);
}
parentSymbol = symbol;
}
// Let the writer know we just wrote out a symbol. The declaration emitter writer uses
// this to determine if an import it has previously seen (and not written out) needs
// to be written to the file once the walk of the tree is complete.
//
// NOTE(cyrusn): This approach feels somewhat unfortunate. A simple pass over the tree
// up front (for example, during checking) could determine if we need to emit the imports
// and we could then access that data during declaration emit.
writer.trackSymbol(symbol, enclosingDeclaration, meaning);
/** @param endOfChain Set to false for recursive calls; non-recursive calls should always output something. */
function walkSymbol(symbol, meaning, endOfChain) {
var accessibleSymbolChain = getAccessibleSymbolChain(symbol, enclosingDeclaration, meaning, !!(flags & 2 /* UseOnlyExternalAliasing */));
if (!accessibleSymbolChain ||
needsQualification(accessibleSymbolChain[0], enclosingDeclaration, accessibleSymbolChain.length === 1 ? meaning : getQualifiedLeftMeaning(meaning))) {
// Go up and add our parent.
var parent_6 = getParentOfSymbol(accessibleSymbolChain ? accessibleSymbolChain[0] : symbol);
if (parent_6) {
walkSymbol(parent_6, getQualifiedLeftMeaning(meaning), /*endOfChain*/ false);
}
}
if (accessibleSymbolChain) {
for (var _i = 0, accessibleSymbolChain_1 = accessibleSymbolChain; _i < accessibleSymbolChain_1.length; _i++) {
var accessibleSymbol = accessibleSymbolChain_1[_i];
appendParentTypeArgumentsAndSymbolName(accessibleSymbol);
}
}
else if (
// If this is the last part of outputting the symbol, always output. The cases apply only to parent symbols.
endOfChain ||
// If a parent symbol is an external module, don't write it. (We prefer just `x` vs `"foo/bar".x`.)
!(!parentSymbol && ts.forEach(symbol.declarations, hasExternalModuleSymbol)) &&
// If a parent symbol is an anonymous type, don't write it.
!(symbol.flags & (2048 /* TypeLiteral */ | 4096 /* ObjectLiteral */))) {
appendParentTypeArgumentsAndSymbolName(symbol);
}
}
// Get qualified name if the symbol is not a type parameter
// and there is an enclosing declaration or we specifically
// asked for it
var isTypeParameter = symbol.flags & 262144 /* TypeParameter */;
var typeFormatFlag = 128 /* UseFullyQualifiedType */ & typeFlags;
if (!isTypeParameter && (enclosingDeclaration || typeFormatFlag)) {
walkSymbol(symbol, meaning, /*endOfChain*/ true);
}
else {
appendParentTypeArgumentsAndSymbolName(symbol);
}
}
function buildTypeDisplay(type, writer, enclosingDeclaration, globalFlags, symbolStack) {
var globalFlagsToPass = globalFlags & 16 /* WriteOwnNameForAnyLike */;
var inObjectTypeLiteral = false;
return writeType(type, globalFlags);
function writeType(type, flags) {
var nextFlags = flags & ~512 /* InTypeAlias */;
// Write undefined/null type as any
if (type.flags & 16015 /* Intrinsic */) {
// Special handling for unknown / resolving types, they should show up as any and not unknown or __resolving
writer.writeKeyword(!(globalFlags & 16 /* WriteOwnNameForAnyLike */) && isTypeAny(type)
? "any"
: type.intrinsicName);
}
else if (type.flags & 16384 /* TypeParameter */ && type.isThisType) {
if (inObjectTypeLiteral) {
writer.reportInaccessibleThisError();
}
writer.writeKeyword("this");
}
else if (getObjectFlags(type) & 4 /* Reference */) {
writeTypeReference(type, nextFlags);
}
else if (type.flags & 256 /* EnumLiteral */) {
buildSymbolDisplay(getParentOfSymbol(type.symbol), writer, enclosingDeclaration, 793064 /* Type */, 0 /* None */, nextFlags);
writePunctuation(writer, 22 /* DotToken */);
appendSymbolNameOnly(type.symbol, writer);
}
else if (getObjectFlags(type) & 3 /* ClassOrInterface */ || type.flags & (16 /* Enum */ | 16384 /* TypeParameter */)) {
// The specified symbol flags need to be reinterpreted as type flags
buildSymbolDisplay(type.symbol, writer, enclosingDeclaration, 793064 /* Type */, 0 /* None */, nextFlags);
}
else if (!(flags & 512 /* InTypeAlias */) && type.aliasSymbol &&
isSymbolAccessible(type.aliasSymbol, enclosingDeclaration, 793064 /* Type */, /*shouldComputeAliasesToMakeVisible*/ false).accessibility === 0 /* Accessible */) {
var typeArguments = type.aliasTypeArguments;
writeSymbolTypeReference(type.aliasSymbol, typeArguments, 0, typeArguments ? typeArguments.length : 0, nextFlags);
}
else if (type.flags & 196608 /* UnionOrIntersection */) {
writeUnionOrIntersectionType(type, nextFlags);
}
else if (getObjectFlags(type) & (16 /* Anonymous */ | 32 /* Mapped */)) {
writeAnonymousType(type, nextFlags);
}
else if (type.flags & 96 /* StringOrNumberLiteral */) {
writer.writeStringLiteral(literalTypeToString(type));
}
else if (type.flags & 262144 /* Index */) {
writer.writeKeyword("keyof");
writeSpace(writer);
writeType(type.type, 64 /* InElementType */);
}
else if (type.flags & 524288 /* IndexedAccess */) {
writeType(type.objectType, 64 /* InElementType */);
writePunctuation(writer, 20 /* OpenBracketToken */);
writeType(type.indexType, 0 /* None */);
writePunctuation(writer, 21 /* CloseBracketToken */);
}
else {
// Should never get here
// { ... }
writePunctuation(writer, 16 /* OpenBraceToken */);
writeSpace(writer);
writePunctuation(writer, 23 /* DotDotDotToken */);
writeSpace(writer);
writePunctuation(writer, 17 /* CloseBraceToken */);
}
}
function writeTypeList(types, delimiter) {
for (var i = 0; i < types.length; i++) {
if (i > 0) {
if (delimiter !== 25 /* CommaToken */) {
writeSpace(writer);
}
writePunctuation(writer, delimiter);
writeSpace(writer);
}
writeType(types[i], delimiter === 25 /* CommaToken */ ? 0 /* None */ : 64 /* InElementType */);
}
}
function writeSymbolTypeReference(symbol, typeArguments, pos, end, flags) {
// Unnamed function expressions and arrow functions have reserved names that we don't want to display
if (symbol.flags & 32 /* Class */ || !isReservedMemberName(symbol.name)) {
buildSymbolDisplay(symbol, writer, enclosingDeclaration, 793064 /* Type */, 0 /* None */, flags);
}
if (pos < end) {
writePunctuation(writer, 26 /* LessThanToken */);
writeType(typeArguments[pos], 256 /* InFirstTypeArgument */);
pos++;
while (pos < end) {
writePunctuation(writer, 25 /* CommaToken */);
writeSpace(writer);
writeType(typeArguments[pos], 0 /* None */);
pos++;
}
writePunctuation(writer, 28 /* GreaterThanToken */);
}
}
function writeTypeReference(type, flags) {
var typeArguments = type.typeArguments || emptyArray;
if (type.target === globalArrayType && !(flags & 1 /* WriteArrayAsGenericType */)) {
writeType(typeArguments[0], 64 /* InElementType */);
writePunctuation(writer, 20 /* OpenBracketToken */);
writePunctuation(writer, 21 /* CloseBracketToken */);
}
else if (type.target.objectFlags & 8 /* Tuple */) {
writePunctuation(writer, 20 /* OpenBracketToken */);
writeTypeList(type.typeArguments.slice(0, getTypeReferenceArity(type)), 25 /* CommaToken */);
writePunctuation(writer, 21 /* CloseBracketToken */);
}
else {
// Write the type reference in the format f<A>.g<B>.C<X, Y> where A and B are type arguments
// for outer type parameters, and f and g are the respective declaring containers of those
// type parameters.
var outerTypeParameters = type.target.outerTypeParameters;
var i = 0;
if (outerTypeParameters) {
var length_1 = outerTypeParameters.length;
while (i < length_1) {
// Find group of type arguments for type parameters with the same declaring container.
var start = i;
var parent_7 = getParentSymbolOfTypeParameter(outerTypeParameters[i]);
do {
i++;
} while (i < length_1 && getParentSymbolOfTypeParameter(outerTypeParameters[i]) === parent_7);
// When type parameters are their own type arguments for the whole group (i.e. we have
// the default outer type arguments), we don't show the group.
if (!ts.rangeEquals(outerTypeParameters, typeArguments, start, i)) {
writeSymbolTypeReference(parent_7, typeArguments, start, i, flags);
writePunctuation(writer, 22 /* DotToken */);
}
}
}
var typeParameterCount = (type.target.typeParameters || emptyArray).length;
writeSymbolTypeReference(type.symbol, typeArguments, i, typeParameterCount, flags);
}
}
function writeUnionOrIntersectionType(type, flags) {
if (flags & 64 /* InElementType */) {
writePunctuation(writer, 18 /* OpenParenToken */);
}
if (type.flags & 65536 /* Union */) {
writeTypeList(formatUnionTypes(type.types), 48 /* BarToken */);
}
else {
writeTypeList(type.types, 47 /* AmpersandToken */);
}
if (flags & 64 /* InElementType */) {
writePunctuation(writer, 19 /* CloseParenToken */);
}
}
function writeAnonymousType(type, flags) {
var symbol = type.symbol;
if (symbol) {
// Always use 'typeof T' for type of class, enum, and module objects
if (symbol.flags & (32 /* Class */ | 384 /* Enum */ | 512 /* ValueModule */)) {
writeTypeOfSymbol(type, flags);
}
else if (shouldWriteTypeOfFunctionSymbol()) {
writeTypeOfSymbol(type, flags);
}
else if (ts.contains(symbolStack, symbol)) {
// If type is an anonymous type literal in a type alias declaration, use type alias name
var typeAlias = getTypeAliasForTypeLiteral(type);
if (typeAlias) {
// The specified symbol flags need to be reinterpreted as type flags
buildSymbolDisplay(typeAlias, writer, enclosingDeclaration, 793064 /* Type */, 0 /* None */, flags);
}
else {
// Recursive usage, use any
writeKeyword(writer, 118 /* AnyKeyword */);
}
}
else {
// Since instantiations of the same anonymous type have the same symbol, tracking symbols instead
// of types allows us to catch circular references to instantiations of the same anonymous type
if (!symbolStack) {
symbolStack = [];
}
symbolStack.push(symbol);
writeLiteralType(type, flags);
symbolStack.pop();
}
}
else {
// Anonymous types with no symbol are never circular
writeLiteralType(type, flags);
}
function shouldWriteTypeOfFunctionSymbol() {
var isStaticMethodSymbol = !!(symbol.flags & 8192 /* Method */ &&
ts.forEach(symbol.declarations, function (declaration) { return ts.getModifierFlags(declaration) & 32 /* Static */; }));
var isNonLocalFunctionSymbol = !!(symbol.flags & 16 /* Function */) &&
(symbol.parent ||
ts.forEach(symbol.declarations, function (declaration) {
return declaration.parent.kind === 261 /* SourceFile */ || declaration.parent.kind === 231 /* ModuleBlock */;
}));
if (isStaticMethodSymbol || isNonLocalFunctionSymbol) {
// typeof is allowed only for static/non local functions
return !!(flags & 2 /* UseTypeOfFunction */) ||
(ts.contains(symbolStack, symbol)); // it is type of the symbol uses itself recursively
}
}
}
function writeTypeOfSymbol(type, typeFormatFlags) {
writeKeyword(writer, 102 /* TypeOfKeyword */);
writeSpace(writer);
buildSymbolDisplay(type.symbol, writer, enclosingDeclaration, 107455 /* Value */, 0 /* None */, typeFormatFlags);
}
function writeIndexSignature(info, keyword) {
if (info) {
if (info.isReadonly) {
writeKeyword(writer, 130 /* ReadonlyKeyword */);
writeSpace(writer);
}
writePunctuation(writer, 20 /* OpenBracketToken */);
writer.writeParameter(info.declaration ? ts.declarationNameToString(info.declaration.parameters[0].name) : "x");
writePunctuation(writer, 55 /* ColonToken */);
writeSpace(writer);
writeKeyword(writer, keyword);
writePunctuation(writer, 21 /* CloseBracketToken */);
writePunctuation(writer, 55 /* ColonToken */);
writeSpace(writer);
writeType(info.type, 0 /* None */);
writePunctuation(writer, 24 /* SemicolonToken */);
writer.writeLine();
}
}
function writePropertyWithModifiers(prop) {
if (isReadonlySymbol(prop)) {
writeKeyword(writer, 130 /* ReadonlyKeyword */);
writeSpace(writer);
}
buildSymbolDisplay(prop, writer);
if (prop.flags & 536870912 /* Optional */) {
writePunctuation(writer, 54 /* QuestionToken */);
}
}
function shouldAddParenthesisAroundFunctionType(callSignature, flags) {
if (flags & 64 /* InElementType */) {
return true;
}
else if (flags & 256 /* InFirstTypeArgument */) {
// Add parenthesis around function type for the first type argument to avoid ambiguity
var typeParameters = callSignature.target && (flags & 32 /* WriteTypeArgumentsOfSignature */) ?
callSignature.target.typeParameters : callSignature.typeParameters;
return typeParameters && typeParameters.length !== 0;
}
return false;
}
function writeLiteralType(type, flags) {
if (type.objectFlags & 32 /* Mapped */) {
if (getConstraintTypeFromMappedType(type).flags & (16384 /* TypeParameter */ | 262144 /* Index */)) {
writeMappedType(type);
return;
}
}
var resolved = resolveStructuredTypeMembers(type);
if (!resolved.properties.length && !resolved.stringIndexInfo && !resolved.numberIndexInfo) {
if (!resolved.callSignatures.length && !resolved.constructSignatures.length) {
writePunctuation(writer, 16 /* OpenBraceToken */);
writePunctuation(writer, 17 /* CloseBraceToken */);
return;
}
if (resolved.callSignatures.length === 1 && !resolved.constructSignatures.length) {
var parenthesizeSignature = shouldAddParenthesisAroundFunctionType(resolved.callSignatures[0], flags);
if (parenthesizeSignature) {
writePunctuation(writer, 18 /* OpenParenToken */);
}
buildSignatureDisplay(resolved.callSignatures[0], writer, enclosingDeclaration, globalFlagsToPass | 8 /* WriteArrowStyleSignature */, /*kind*/ undefined, symbolStack);
if (parenthesizeSignature) {
writePunctuation(writer, 19 /* CloseParenToken */);
}
return;
}
if (resolved.constructSignatures.length === 1 && !resolved.callSignatures.length) {
if (flags & 64 /* InElementType */) {
writePunctuation(writer, 18 /* OpenParenToken */);
}
writeKeyword(writer, 93 /* NewKeyword */);
writeSpace(writer);
buildSignatureDisplay(resolved.constructSignatures[0], writer, enclosingDeclaration, globalFlagsToPass | 8 /* WriteArrowStyleSignature */, /*kind*/ undefined, symbolStack);
if (flags & 64 /* InElementType */) {
writePunctuation(writer, 19 /* CloseParenToken */);
}
return;
}
}
var saveInObjectTypeLiteral = inObjectTypeLiteral;
inObjectTypeLiteral = true;
writePunctuation(writer, 16 /* OpenBraceToken */);
writer.writeLine();
writer.increaseIndent();
writeObjectLiteralType(resolved);
writer.decreaseIndent();
writePunctuation(writer, 17 /* CloseBraceToken */);
inObjectTypeLiteral = saveInObjectTypeLiteral;
}
function writeObjectLiteralType(resolved) {
for (var _i = 0, _a = resolved.callSignatures; _i < _a.length; _i++) {
var signature = _a[_i];
buildSignatureDisplay(signature, writer, enclosingDeclaration, globalFlagsToPass, /*kind*/ undefined, symbolStack);
writePunctuation(writer, 24 /* SemicolonToken */);
writer.writeLine();
}
for (var _b = 0, _c = resolved.constructSignatures; _b < _c.length; _b++) {
var signature = _c[_b];
buildSignatureDisplay(signature, writer, enclosingDeclaration, globalFlagsToPass, 1 /* Construct */, symbolStack);
writePunctuation(writer, 24 /* SemicolonToken */);
writer.writeLine();
}
writeIndexSignature(resolved.stringIndexInfo, 134 /* StringKeyword */);
writeIndexSignature(resolved.numberIndexInfo, 132 /* NumberKeyword */);
for (var _d = 0, _e = resolved.properties; _d < _e.length; _d++) {
var p = _e[_d];
var t = getTypeOfSymbol(p);
if (p.flags & (16 /* Function */ | 8192 /* Method */) && !getPropertiesOfObjectType(t).length) {
var signatures = getSignaturesOfType(t, 0 /* Call */);
for (var _f = 0, signatures_1 = signatures; _f < signatures_1.length; _f++) {
var signature = signatures_1[_f];
writePropertyWithModifiers(p);
buildSignatureDisplay(signature, writer, enclosingDeclaration, globalFlagsToPass, /*kind*/ undefined, symbolStack);
writePunctuation(writer, 24 /* SemicolonToken */);
writer.writeLine();
}
}
else {
writePropertyWithModifiers(p);
writePunctuation(writer, 55 /* ColonToken */);
writeSpace(writer);
writeType(t, 0 /* None */);
writePunctuation(writer, 24 /* SemicolonToken */);
writer.writeLine();
}
}
}
function writeMappedType(type) {
writePunctuation(writer, 16 /* OpenBraceToken */);
writer.writeLine();
writer.increaseIndent();
if (type.declaration.readonlyToken) {
writeKeyword(writer, 130 /* ReadonlyKeyword */);
writeSpace(writer);
}
writePunctuation(writer, 20 /* OpenBracketToken */);
appendSymbolNameOnly(getTypeParameterFromMappedType(type).symbol, writer);
writeSpace(writer);
writeKeyword(writer, 91 /* InKeyword */);
writeSpace(writer);
writeType(getConstraintTypeFromMappedType(type), 0 /* None */);
writePunctuation(writer, 21 /* CloseBracketToken */);
if (type.declaration.questionToken) {
writePunctuation(writer, 54 /* QuestionToken */);
}
writePunctuation(writer, 55 /* ColonToken */);
writeSpace(writer);
writeType(getTemplateTypeFromMappedType(type), 0 /* None */);
writePunctuation(writer, 24 /* SemicolonToken */);
writer.writeLine();
writer.decreaseIndent();
writePunctuation(writer, 17 /* CloseBraceToken */);
}
}
function buildTypeParameterDisplayFromSymbol(symbol, writer, enclosingDeclaration, flags) {
var targetSymbol = getTargetSymbol(symbol);
if (targetSymbol.flags & 32 /* Class */ || targetSymbol.flags & 64 /* Interface */ || targetSymbol.flags & 524288 /* TypeAlias */) {
buildDisplayForTypeParametersAndDelimiters(getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol), writer, enclosingDeclaration, flags);
}
}
function buildTypeParameterDisplay(tp, writer, enclosingDeclaration, flags, symbolStack) {
appendSymbolNameOnly(tp.symbol, writer);
var constraint = getConstraintOfTypeParameter(tp);
if (constraint) {
writeSpace(writer);
writeKeyword(writer, 84 /* ExtendsKeyword */);
writeSpace(writer);
buildTypeDisplay(constraint, writer, enclosingDeclaration, flags, symbolStack);
}
}
function buildParameterDisplay(p, writer, enclosingDeclaration, flags, symbolStack) {
var parameterNode = p.valueDeclaration;
if (ts.isRestParameter(parameterNode)) {
writePunctuation(writer, 23 /* DotDotDotToken */);
}
if (ts.isBindingPattern(parameterNode.name)) {
buildBindingPatternDisplay(parameterNode.name, writer, enclosingDeclaration, flags, symbolStack);
}
else {
appendSymbolNameOnly(p, writer);
}
if (isOptionalParameter(parameterNode)) {
writePunctuation(writer, 54 /* QuestionToken */);
}
writePunctuation(writer, 55 /* ColonToken */);
writeSpace(writer);
buildTypeDisplay(getTypeOfSymbol(p), writer, enclosingDeclaration, flags, symbolStack);
}
function buildBindingPatternDisplay(bindingPattern, writer, enclosingDeclaration, flags, symbolStack) {
// We have to explicitly emit square bracket and bracket because these tokens are not stored inside the node.
if (bindingPattern.kind === 172 /* ObjectBindingPattern */) {
writePunctuation(writer, 16 /* OpenBraceToken */);
buildDisplayForCommaSeparatedList(bindingPattern.elements, writer, function (e) { return buildBindingElementDisplay(e, writer, enclosingDeclaration, flags, symbolStack); });
writePunctuation(writer, 17 /* CloseBraceToken */);
}
else if (bindingPattern.kind === 173 /* ArrayBindingPattern */) {
writePunctuation(writer, 20 /* OpenBracketToken */);
var elements = bindingPattern.elements;
buildDisplayForCommaSeparatedList(elements, writer, function (e) { return buildBindingElementDisplay(e, writer, enclosingDeclaration, flags, symbolStack); });
if (elements && elements.hasTrailingComma) {
writePunctuation(writer, 25 /* CommaToken */);
}
writePunctuation(writer, 21 /* CloseBracketToken */);
}
}
function buildBindingElementDisplay(bindingElement, writer, enclosingDeclaration, flags, symbolStack) {
if (ts.isOmittedExpression(bindingElement)) {
return;
}
ts.Debug.assert(bindingElement.kind === 174 /* BindingElement */);
if (bindingElement.propertyName) {
writer.writeSymbol(ts.getTextOfNode(bindingElement.propertyName), bindingElement.symbol);
writePunctuation(writer, 55 /* ColonToken */);
writeSpace(writer);
}
if (ts.isBindingPattern(bindingElement.name)) {
buildBindingPatternDisplay(bindingElement.name, writer, enclosingDeclaration, flags, symbolStack);
}
else {
if (bindingElement.dotDotDotToken) {
writePunctuation(writer, 23 /* DotDotDotToken */);
}
appendSymbolNameOnly(bindingElement.symbol, writer);
}
}
function buildDisplayForTypeParametersAndDelimiters(typeParameters, writer, enclosingDeclaration, flags, symbolStack) {
if (typeParameters && typeParameters.length) {
writePunctuation(writer, 26 /* LessThanToken */);
buildDisplayForCommaSeparatedList(typeParameters, writer, function (p) { return buildTypeParameterDisplay(p, writer, enclosingDeclaration, flags, symbolStack); });
writePunctuation(writer, 28 /* GreaterThanToken */);
}
}
function buildDisplayForCommaSeparatedList(list, writer, action) {
for (var i = 0; i < list.length; i++) {
if (i > 0) {
writePunctuation(writer, 25 /* CommaToken */);
writeSpace(writer);
}
action(list[i]);
}
}
function buildDisplayForTypeArgumentsAndDelimiters(typeParameters, mapper, writer, enclosingDeclaration) {
if (typeParameters && typeParameters.length) {
writePunctuation(writer, 26 /* LessThanToken */);
var flags = 256 /* InFirstTypeArgument */;
for (var i = 0; i < typeParameters.length; i++) {
if (i > 0) {
writePunctuation(writer, 25 /* CommaToken */);
writeSpace(writer);
flags = 0 /* None */;
}
buildTypeDisplay(mapper(typeParameters[i]), writer, enclosingDeclaration, flags);
}
writePunctuation(writer, 28 /* GreaterThanToken */);
}
}
function buildDisplayForParametersAndDelimiters(thisParameter, parameters, writer, enclosingDeclaration, flags, symbolStack) {
writePunctuation(writer, 18 /* OpenParenToken */);
if (thisParameter) {
buildParameterDisplay(thisParameter, writer, enclosingDeclaration, flags, symbolStack);
}
for (var i = 0; i < parameters.length; i++) {
if (i > 0 || thisParameter) {
writePunctuation(writer, 25 /* CommaToken */);
writeSpace(writer);
}
buildParameterDisplay(parameters[i], writer, enclosingDeclaration, flags, symbolStack);
}
writePunctuation(writer, 19 /* CloseParenToken */);
}
function buildTypePredicateDisplay(predicate, writer, enclosingDeclaration, flags, symbolStack) {
if (ts.isIdentifierTypePredicate(predicate)) {
writer.writeParameter(predicate.parameterName);
}
else {
writeKeyword(writer, 98 /* ThisKeyword */);
}
writeSpace(writer);
writeKeyword(writer, 125 /* IsKeyword */);
writeSpace(writer);
buildTypeDisplay(predicate.type, writer, enclosingDeclaration, flags, symbolStack);
}
function buildReturnTypeDisplay(signature, writer, enclosingDeclaration, flags, symbolStack) {
if (flags & 8 /* WriteArrowStyleSignature */) {
writeSpace(writer);
writePunctuation(writer, 35 /* EqualsGreaterThanToken */);
}
else {
writePunctuation(writer, 55 /* ColonToken */);
}
writeSpace(writer);
if (signature.typePredicate) {
buildTypePredicateDisplay(signature.typePredicate, writer, enclosingDeclaration, flags, symbolStack);
}
else {
var returnType = getReturnTypeOfSignature(signature);
buildTypeDisplay(returnType, writer, enclosingDeclaration, flags, symbolStack);
}
}
function buildSignatureDisplay(signature, writer, enclosingDeclaration, flags, kind, symbolStack) {
if (kind === 1 /* Construct */) {
writeKeyword(writer, 93 /* NewKeyword */);
writeSpace(writer);
}
if (signature.target && (flags & 32 /* WriteTypeArgumentsOfSignature */)) {
// Instantiated signature, write type arguments instead
// This is achieved by passing in the mapper separately
buildDisplayForTypeArgumentsAndDelimiters(signature.target.typeParameters, signature.mapper, writer, enclosingDeclaration);
}
else {
buildDisplayForTypeParametersAndDelimiters(signature.typeParameters, writer, enclosingDeclaration, flags, symbolStack);
}
buildDisplayForParametersAndDelimiters(signature.thisParameter, signature.parameters, writer, enclosingDeclaration, flags, symbolStack);
buildReturnTypeDisplay(signature, writer, enclosingDeclaration, flags, symbolStack);
}
return _displayBuilder || (_displayBuilder = {
buildSymbolDisplay: buildSymbolDisplay,
buildTypeDisplay: buildTypeDisplay,
buildTypeParameterDisplay: buildTypeParameterDisplay,
buildTypePredicateDisplay: buildTypePredicateDisplay,
buildParameterDisplay: buildParameterDisplay,
buildDisplayForParametersAndDelimiters: buildDisplayForParametersAndDelimiters,
buildDisplayForTypeParametersAndDelimiters: buildDisplayForTypeParametersAndDelimiters,
buildTypeParameterDisplayFromSymbol: buildTypeParameterDisplayFromSymbol,
buildSignatureDisplay: buildSignatureDisplay,
buildReturnTypeDisplay: buildReturnTypeDisplay
});
}
function isDeclarationVisible(node) {
if (node) {
var links = getNodeLinks(node);
if (links.isVisible === undefined) {
links.isVisible = !!determineIfDeclarationIsVisible();
}
return links.isVisible;
}
return false;
function determineIfDeclarationIsVisible() {
switch (node.kind) {
case 174 /* BindingElement */:
return isDeclarationVisible(node.parent.parent);
case 223 /* VariableDeclaration */:
if (ts.isBindingPattern(node.name) &&
!node.name.elements.length) {
// If the binding pattern is empty, this variable declaration is not visible
return false;
}
// Otherwise fall through
case 230 /* ModuleDeclaration */:
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 225 /* FunctionDeclaration */:
case 229 /* EnumDeclaration */:
case 234 /* ImportEqualsDeclaration */:
// external module augmentation is always visible
if (ts.isExternalModuleAugmentation(node)) {
return true;
}
var parent_8 = getDeclarationContainer(node);
// If the node is not exported or it is not ambient module element (except import declaration)
if (!(ts.getCombinedModifierFlags(node) & 1 /* Export */) &&
!(node.kind !== 234 /* ImportEqualsDeclaration */ && parent_8.kind !== 261 /* SourceFile */ && ts.isInAmbientContext(parent_8))) {
return isGlobalSourceFile(parent_8);
}
// Exported members/ambient module elements (exception import declaration) are visible if parent is visible
return isDeclarationVisible(parent_8);
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
if (ts.getModifierFlags(node) & (8 /* Private */ | 16 /* Protected */)) {
// Private/protected properties/methods are not visible
return false;
}
// Public properties/methods are visible if its parents are visible, so const it fall into next case statement
case 150 /* Constructor */:
case 154 /* ConstructSignature */:
case 153 /* CallSignature */:
case 155 /* IndexSignature */:
case 144 /* Parameter */:
case 231 /* ModuleBlock */:
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 161 /* TypeLiteral */:
case 157 /* TypeReference */:
case 162 /* ArrayType */:
case 163 /* TupleType */:
case 164 /* UnionType */:
case 165 /* IntersectionType */:
case 166 /* ParenthesizedType */:
return isDeclarationVisible(node.parent);
// Default binding, import specifier and namespace import is visible
// only on demand so by default it is not visible
case 236 /* ImportClause */:
case 237 /* NamespaceImport */:
case 239 /* ImportSpecifier */:
return false;
// Type parameters are always visible
case 143 /* TypeParameter */:
// Source file and namespace export are always visible
case 261 /* SourceFile */:
case 233 /* NamespaceExportDeclaration */:
return true;
// Export assignments do not create name bindings outside the module
case 240 /* ExportAssignment */:
return false;
default:
return false;
}
}
}
function collectLinkedAliases(node) {
var exportSymbol;
if (node.parent && node.parent.kind === 240 /* ExportAssignment */) {
exportSymbol = resolveName(node.parent, node.text, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */ | 8388608 /* Alias */, ts.Diagnostics.Cannot_find_name_0, node);
}
else if (node.parent.kind === 243 /* ExportSpecifier */) {
var exportSpecifier = node.parent;
exportSymbol = exportSpecifier.parent.parent.moduleSpecifier ?
getExternalModuleMember(exportSpecifier.parent.parent, exportSpecifier) :
resolveEntityName(exportSpecifier.propertyName || exportSpecifier.name, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */ | 8388608 /* Alias */);
}
var result = [];
if (exportSymbol) {
buildVisibleNodeList(exportSymbol.declarations);
}
return result;
function buildVisibleNodeList(declarations) {
ts.forEach(declarations, function (declaration) {
getNodeLinks(declaration).isVisible = true;
var resultNode = getAnyImportSyntax(declaration) || declaration;
if (!ts.contains(result, resultNode)) {
result.push(resultNode);
}
if (ts.isInternalModuleImportEqualsDeclaration(declaration)) {
// Add the referenced top container visible
var internalModuleReference = declaration.moduleReference;
var firstIdentifier = getFirstIdentifier(internalModuleReference);
var importSymbol = resolveName(declaration, firstIdentifier.text, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */, undefined, undefined);
if (importSymbol) {
buildVisibleNodeList(importSymbol.declarations);
}
}
});
}
}
/**
* Push an entry on the type resolution stack. If an entry with the given target and the given property name
* is already on the stack, and no entries in between already have a type, then a circularity has occurred.
* In this case, the result values of the existing entry and all entries pushed after it are changed to false,
* and the value false is returned. Otherwise, the new entry is just pushed onto the stack, and true is returned.
* In order to see if the same query has already been done before, the target object and the propertyName both
* must match the one passed in.
*
* @param target The symbol, type, or signature whose type is being queried
* @param propertyName The property name that should be used to query the target for its type
*/
function pushTypeResolution(target, propertyName) {
var resolutionCycleStartIndex = findResolutionCycleStartIndex(target, propertyName);
if (resolutionCycleStartIndex >= 0) {
// A cycle was found
var length_2 = resolutionTargets.length;
for (var i = resolutionCycleStartIndex; i < length_2; i++) {
resolutionResults[i] = false;
}
return false;
}
resolutionTargets.push(target);
resolutionResults.push(/*items*/ true);
resolutionPropertyNames.push(propertyName);
return true;
}
function findResolutionCycleStartIndex(target, propertyName) {
for (var i = resolutionTargets.length - 1; i >= 0; i--) {
if (hasType(resolutionTargets[i], resolutionPropertyNames[i])) {
return -1;
}
if (resolutionTargets[i] === target && resolutionPropertyNames[i] === propertyName) {
return i;
}
}
return -1;
}
function hasType(target, propertyName) {
if (propertyName === 0 /* Type */) {
return getSymbolLinks(target).type;
}
if (propertyName === 2 /* DeclaredType */) {
return getSymbolLinks(target).declaredType;
}
if (propertyName === 1 /* ResolvedBaseConstructorType */) {
return target.resolvedBaseConstructorType;
}
if (propertyName === 3 /* ResolvedReturnType */) {
return target.resolvedReturnType;
}
ts.Debug.fail("Unhandled TypeSystemPropertyName " + propertyName);
}
// Pop an entry from the type resolution stack and return its associated result value. The result value will
// be true if no circularities were detected, or false if a circularity was found.
function popTypeResolution() {
resolutionTargets.pop();
resolutionPropertyNames.pop();
return resolutionResults.pop();
}
function getDeclarationContainer(node) {
node = ts.getRootDeclaration(node);
while (node) {
switch (node.kind) {
case 223 /* VariableDeclaration */:
case 224 /* VariableDeclarationList */:
case 239 /* ImportSpecifier */:
case 238 /* NamedImports */:
case 237 /* NamespaceImport */:
case 236 /* ImportClause */:
node = node.parent;
break;
default:
return node.parent;
}
}
}
function getTypeOfPrototypeProperty(prototype) {
// TypeScript 1.0 spec (April 2014): 8.4
// Every class automatically contains a static property member named 'prototype',
// the type of which is an instantiation of the class type with type Any supplied as a type argument for each type parameter.
// It is an error to explicitly declare a static property member with the name 'prototype'.
var classType = getDeclaredTypeOfSymbol(getParentOfSymbol(prototype));
return classType.typeParameters ? createTypeReference(classType, ts.map(classType.typeParameters, function (_) { return anyType; })) : classType;
}
// Return the type of the given property in the given type, or undefined if no such property exists
function getTypeOfPropertyOfType(type, name) {
var prop = getPropertyOfType(type, name);
return prop ? getTypeOfSymbol(prop) : undefined;
}
function isTypeAny(type) {
return type && (type.flags & 1 /* Any */) !== 0;
}
function isTypeNever(type) {
return type && (type.flags & 8192 /* Never */) !== 0;
}
// Return the type of a binding element parent. We check SymbolLinks first to see if a type has been
// assigned by contextual typing.
function getTypeForBindingElementParent(node) {
var symbol = getSymbolOfNode(node);
return symbol && getSymbolLinks(symbol).type || getTypeForVariableLikeDeclaration(node, /*includeOptionality*/ false);
}
function isComputedNonLiteralName(name) {
return name.kind === 142 /* ComputedPropertyName */ && !ts.isStringOrNumericLiteral(name.expression.kind);
}
function getRestType(source, properties, symbol) {
ts.Debug.assert(!!(source.flags & 32768 /* Object */), "Rest types only support object types right now.");
var members = ts.createMap();
var names = ts.createMap();
for (var _i = 0, properties_2 = properties; _i < properties_2.length; _i++) {
var name_18 = properties_2[_i];
names[ts.getTextOfPropertyName(name_18)] = true;
}
for (var _a = 0, _b = getPropertiesOfType(source); _a < _b.length; _a++) {
var prop = _b[_a];
var inNamesToRemove = prop.name in names;
var isPrivate = getDeclarationModifierFlagsFromSymbol(prop) & (8 /* Private */ | 16 /* Protected */);
var isMethod = prop.flags & 8192 /* Method */;
var isSetOnlyAccessor = prop.flags & 65536 /* SetAccessor */ && !(prop.flags & 32768 /* GetAccessor */);
if (!inNamesToRemove && !isPrivate && !isMethod && !isSetOnlyAccessor) {
members[prop.name] = prop;
}
}
var stringIndexInfo = getIndexInfoOfType(source, 0 /* String */);
var numberIndexInfo = getIndexInfoOfType(source, 1 /* Number */);
return createAnonymousType(symbol, members, emptyArray, emptyArray, stringIndexInfo, numberIndexInfo);
}
/** Return the inferred type for a binding element */
function getTypeForBindingElement(declaration) {
var pattern = declaration.parent;
var parentType = getTypeForBindingElementParent(pattern.parent);
// If parent has the unknown (error) type, then so does this binding element
if (parentType === unknownType) {
return unknownType;
}
// If no type was specified or inferred for parent, or if the specified or inferred type is any,
// infer from the initializer of the binding element if one is present. Otherwise, go with the
// undefined or any type of the parent.
if (!parentType || isTypeAny(parentType)) {
if (declaration.initializer) {
return checkDeclarationInitializer(declaration);
}
return parentType;
}
var type;
if (pattern.kind === 172 /* ObjectBindingPattern */) {
if (declaration.dotDotDotToken) {
if (!(parentType.flags & 32768 /* Object */)) {
error(declaration, ts.Diagnostics.Rest_types_may_only_be_created_from_object_types);
return unknownType;
}
var literalMembers = [];
for (var _i = 0, _a = pattern.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (element.kind !== 198 /* OmittedExpression */ && !element.dotDotDotToken) {
literalMembers.push(element.propertyName || element.name);
}
}
type = getRestType(parentType, literalMembers, declaration.symbol);
}
else {
// Use explicitly specified property name ({ p: xxx } form), or otherwise the implied name ({ p } form)
var name_19 = declaration.propertyName || declaration.name;
if (isComputedNonLiteralName(name_19)) {
// computed properties with non-literal names are treated as 'any'
return anyType;
}
if (declaration.initializer) {
getContextualType(declaration.initializer);
}
// Use type of the specified property, or otherwise, for a numeric name, the type of the numeric index signature,
// or otherwise the type of the string index signature.
var text = ts.getTextOfPropertyName(name_19);
type = getTypeOfPropertyOfType(parentType, text) ||
isNumericLiteralName(text) && getIndexTypeOfType(parentType, 1 /* Number */) ||
getIndexTypeOfType(parentType, 0 /* String */);
if (!type) {
error(name_19, ts.Diagnostics.Type_0_has_no_property_1_and_no_string_index_signature, typeToString(parentType), ts.declarationNameToString(name_19));
return unknownType;
}
}
}
else {
// This elementType will be used if the specific property corresponding to this index is not
// present (aka the tuple element property). This call also checks that the parentType is in
// fact an iterable or array (depending on target language).
var elementType = checkIteratedTypeOrElementType(parentType, pattern, /*allowStringInput*/ false);
if (declaration.dotDotDotToken) {
// Rest element has an array type with the same element type as the parent type
type = createArrayType(elementType);
}
else {
// Use specific property type when parent is a tuple or numeric index type when parent is an array
var propName = "" + ts.indexOf(pattern.elements, declaration);
type = isTupleLikeType(parentType)
? getTypeOfPropertyOfType(parentType, propName)
: elementType;
if (!type) {
if (isTupleType(parentType)) {
error(declaration, ts.Diagnostics.Tuple_type_0_with_length_1_cannot_be_assigned_to_tuple_with_length_2, typeToString(parentType), getTypeReferenceArity(parentType), pattern.elements.length);
}
else {
error(declaration, ts.Diagnostics.Type_0_has_no_property_1, typeToString(parentType), propName);
}
return unknownType;
}
}
}
// In strict null checking mode, if a default value of a non-undefined type is specified, remove
// undefined from the final type.
if (strictNullChecks && declaration.initializer && !(getFalsyFlags(checkExpressionCached(declaration.initializer)) & 2048 /* Undefined */)) {
type = getTypeWithFacts(type, 131072 /* NEUndefined */);
}
return declaration.initializer ?
getUnionType([type, checkExpressionCached(declaration.initializer)], /*subtypeReduction*/ true) :
type;
}
function getTypeForVariableLikeDeclarationFromJSDocComment(declaration) {
var jsDocType = getJSDocTypeForVariableLikeDeclarationFromJSDocComment(declaration);
if (jsDocType) {
return getTypeFromTypeNode(jsDocType);
}
}
function getJSDocTypeForVariableLikeDeclarationFromJSDocComment(declaration) {
// First, see if this node has an @type annotation on it directly.
var typeTag = ts.getJSDocTypeTag(declaration);
if (typeTag && typeTag.typeExpression) {
return typeTag.typeExpression.type;
}
if (declaration.kind === 223 /* VariableDeclaration */ &&
declaration.parent.kind === 224 /* VariableDeclarationList */ &&
declaration.parent.parent.kind === 205 /* VariableStatement */) {
// @type annotation might have been on the variable statement, try that instead.
var annotation = ts.getJSDocTypeTag(declaration.parent.parent);
if (annotation && annotation.typeExpression) {
return annotation.typeExpression.type;
}
}
else if (declaration.kind === 144 /* Parameter */) {
// If it's a parameter, see if the parent has a jsdoc comment with an @param
// annotation.
var paramTag = ts.getCorrespondingJSDocParameterTag(declaration);
if (paramTag && paramTag.typeExpression) {
return paramTag.typeExpression.type;
}
}
return undefined;
}
function isNullOrUndefined(node) {
var expr = ts.skipParentheses(node);
return expr.kind === 94 /* NullKeyword */ || expr.kind === 70 /* Identifier */ && getResolvedSymbol(expr) === undefinedSymbol;
}
function isEmptyArrayLiteral(node) {
var expr = ts.skipParentheses(node);
return expr.kind === 175 /* ArrayLiteralExpression */ && expr.elements.length === 0;
}
function addOptionality(type, optional) {
return strictNullChecks && optional ? includeFalsyTypes(type, 2048 /* Undefined */) : type;
}
// Return the inferred type for a variable, parameter, or property declaration
function getTypeForVariableLikeDeclaration(declaration, includeOptionality) {
if (declaration.flags & 2097152 /* JavaScriptFile */) {
// If this is a variable in a JavaScript file, then use the JSDoc type (if it has
// one as its type), otherwise fallback to the below standard TS codepaths to
// try to figure it out.
var type = getTypeForVariableLikeDeclarationFromJSDocComment(declaration);
if (type && type !== unknownType) {
return type;
}
}
// A variable declared in a for..in statement is always of type string
if (declaration.parent.parent.kind === 212 /* ForInStatement */) {
return stringType;
}
if (declaration.parent.parent.kind === 213 /* ForOfStatement */) {
// checkRightHandSideOfForOf will return undefined if the for-of expression type was
// missing properties/signatures required to get its iteratedType (like
// [Symbol.iterator] or next). This may be because we accessed properties from anyType,
// or it may have led to an error inside getElementTypeOfIterable.
return checkRightHandSideOfForOf(declaration.parent.parent.expression) || anyType;
}
if (ts.isBindingPattern(declaration.parent)) {
return getTypeForBindingElement(declaration);
}
// Use type from type annotation if one is present
if (declaration.type) {
return addOptionality(getTypeFromTypeNode(declaration.type), /*optional*/ declaration.questionToken && includeOptionality);
}
if (declaration.kind === 223 /* VariableDeclaration */ && !ts.isBindingPattern(declaration.name) &&
!(ts.getCombinedModifierFlags(declaration) & 1 /* Export */) && !ts.isInAmbientContext(declaration)) {
// Use control flow tracked 'any' type for non-ambient, non-exported var or let variables with no
// initializer or a 'null' or 'undefined' initializer.
if (!(ts.getCombinedNodeFlags(declaration) & 2 /* Const */) && (!declaration.initializer || isNullOrUndefined(declaration.initializer))) {
return autoType;
}
// Use control flow tracked 'any[]' type for non-ambient, non-exported variables with an empty array
// literal initializer.
if (declaration.initializer && isEmptyArrayLiteral(declaration.initializer)) {
return autoArrayType;
}
}
if (declaration.kind === 144 /* Parameter */) {
var func = declaration.parent;
// For a parameter of a set accessor, use the type of the get accessor if one is present
if (func.kind === 152 /* SetAccessor */ && !ts.hasDynamicName(func)) {
var getter = ts.getDeclarationOfKind(declaration.parent.symbol, 151 /* GetAccessor */);
if (getter) {
var getterSignature = getSignatureFromDeclaration(getter);
var thisParameter = getAccessorThisParameter(func);
if (thisParameter && declaration === thisParameter) {
// Use the type from the *getter*
ts.Debug.assert(!thisParameter.type);
return getTypeOfSymbol(getterSignature.thisParameter);
}
return getReturnTypeOfSignature(getterSignature);
}
}
// Use contextual parameter type if one is available
var type = void 0;
if (declaration.symbol.name === "this") {
type = getContextualThisParameterType(func);
}
else {
type = getContextuallyTypedParameterType(declaration);
}
if (type) {
return addOptionality(type, /*optional*/ declaration.questionToken && includeOptionality);
}
}
// Use the type of the initializer expression if one is present
if (declaration.initializer) {
var type = checkDeclarationInitializer(declaration);
return addOptionality(type, /*optional*/ declaration.questionToken && includeOptionality);
}
// If it is a short-hand property assignment, use the type of the identifier
if (declaration.kind === 258 /* ShorthandPropertyAssignment */) {
return checkIdentifier(declaration.name);
}
// If the declaration specifies a binding pattern, use the type implied by the binding pattern
if (ts.isBindingPattern(declaration.name)) {
return getTypeFromBindingPattern(declaration.name, /*includePatternInType*/ false, /*reportErrors*/ true);
}
// No type specified and nothing can be inferred
return undefined;
}
// Return the type implied by a binding pattern element. This is the type of the initializer of the element if
// one is present. Otherwise, if the element is itself a binding pattern, it is the type implied by the binding
// pattern. Otherwise, it is the type any.
function getTypeFromBindingElement(element, includePatternInType, reportErrors) {
if (element.initializer) {
return checkDeclarationInitializer(element);
}
if (ts.isBindingPattern(element.name)) {
return getTypeFromBindingPattern(element.name, includePatternInType, reportErrors);
}
if (reportErrors && compilerOptions.noImplicitAny && !declarationBelongsToPrivateAmbientMember(element)) {
reportImplicitAnyError(element, anyType);
}
return anyType;
}
// Return the type implied by an object binding pattern
function getTypeFromObjectBindingPattern(pattern, includePatternInType, reportErrors) {
var members = ts.createMap();
var hasComputedProperties = false;
ts.forEach(pattern.elements, function (e) {
var name = e.propertyName || e.name;
if (isComputedNonLiteralName(name) || e.dotDotDotToken) {
// do not include computed properties or rests in the implied type
hasComputedProperties = true;
return;
}
var text = ts.getTextOfPropertyName(name);
var flags = 4 /* Property */ | 67108864 /* Transient */ | (e.initializer ? 536870912 /* Optional */ : 0);
var symbol = createSymbol(flags, text);
symbol.type = getTypeFromBindingElement(e, includePatternInType, reportErrors);
symbol.bindingElement = e;
members[symbol.name] = symbol;
});
var result = createAnonymousType(undefined, members, emptyArray, emptyArray, undefined, undefined);
if (includePatternInType) {
result.pattern = pattern;
}
if (hasComputedProperties) {
result.objectFlags |= 512 /* ObjectLiteralPatternWithComputedProperties */;
}
return result;
}
// Return the type implied by an array binding pattern
function getTypeFromArrayBindingPattern(pattern, includePatternInType, reportErrors) {
var elements = pattern.elements;
var lastElement = ts.lastOrUndefined(elements);
if (elements.length === 0 || (!ts.isOmittedExpression(lastElement) && lastElement.dotDotDotToken)) {
return languageVersion >= 2 /* ES2015 */ ? createIterableType(anyType) : anyArrayType;
}
// If the pattern has at least one element, and no rest element, then it should imply a tuple type.
var elementTypes = ts.map(elements, function (e) { return ts.isOmittedExpression(e) ? anyType : getTypeFromBindingElement(e, includePatternInType, reportErrors); });
var result = createTupleType(elementTypes);
if (includePatternInType) {
result = cloneTypeReference(result);
result.pattern = pattern;
}
return result;
}
// Return the type implied by a binding pattern. This is the type implied purely by the binding pattern itself
// and without regard to its context (i.e. without regard any type annotation or initializer associated with the
// declaration in which the binding pattern is contained). For example, the implied type of [x, y] is [any, any]
// and the implied type of { x, y: z = 1 } is { x: any; y: number; }. The type implied by a binding pattern is
// used as the contextual type of an initializer associated with the binding pattern. Also, for a destructuring
// parameter with no type annotation or initializer, the type implied by the binding pattern becomes the type of
// the parameter.
function getTypeFromBindingPattern(pattern, includePatternInType, reportErrors) {
return pattern.kind === 172 /* ObjectBindingPattern */
? getTypeFromObjectBindingPattern(pattern, includePatternInType, reportErrors)
: getTypeFromArrayBindingPattern(pattern, includePatternInType, reportErrors);
}
// Return the type associated with a variable, parameter, or property declaration. In the simple case this is the type
// specified in a type annotation or inferred from an initializer. However, in the case of a destructuring declaration it
// is a bit more involved. For example:
//
// var [x, s = ""] = [1, "one"];
//
// Here, the array literal [1, "one"] is contextually typed by the type [any, string], which is the implied type of the
// binding pattern [x, s = ""]. Because the contextual type is a tuple type, the resulting type of [1, "one"] is the
// tuple type [number, string]. Thus, the type inferred for 'x' is number and the type inferred for 's' is string.
function getWidenedTypeForVariableLikeDeclaration(declaration, reportErrors) {
var type = getTypeForVariableLikeDeclaration(declaration, /*includeOptionality*/ true);
if (type) {
if (reportErrors) {
reportErrorsFromWidening(declaration, type);
}
// During a normal type check we'll never get to here with a property assignment (the check of the containing
// object literal uses a different path). We exclude widening only so that language services and type verification
// tools see the actual type.
if (declaration.kind === 257 /* PropertyAssignment */) {
return type;
}
return getWidenedType(type);
}
// Rest parameters default to type any[], other parameters default to type any
type = declaration.dotDotDotToken ? anyArrayType : anyType;
// Report implicit any errors unless this is a private property within an ambient declaration
if (reportErrors && compilerOptions.noImplicitAny) {
if (!declarationBelongsToPrivateAmbientMember(declaration)) {
reportImplicitAnyError(declaration, type);
}
}
return type;
}
function declarationBelongsToPrivateAmbientMember(declaration) {
var root = ts.getRootDeclaration(declaration);
var memberDeclaration = root.kind === 144 /* Parameter */ ? root.parent : root;
return isPrivateWithinAmbient(memberDeclaration);
}
function getTypeOfVariableOrParameterOrProperty(symbol) {
var links = getSymbolLinks(symbol);
if (!links.type) {
// Handle prototype property
if (symbol.flags & 134217728 /* Prototype */) {
return links.type = getTypeOfPrototypeProperty(symbol);
}
// Handle catch clause variables
var declaration = symbol.valueDeclaration;
if (ts.isCatchClauseVariableDeclarationOrBindingElement(declaration)) {
return links.type = anyType;
}
// Handle export default expressions
if (declaration.kind === 240 /* ExportAssignment */) {
return links.type = checkExpression(declaration.expression);
}
if (declaration.flags & 2097152 /* JavaScriptFile */ && declaration.kind === 285 /* JSDocPropertyTag */ && declaration.typeExpression) {
return links.type = getTypeFromTypeNode(declaration.typeExpression.type);
}
// Handle variable, parameter or property
if (!pushTypeResolution(symbol, 0 /* Type */)) {
return unknownType;
}
var type = void 0;
// Handle certain special assignment kinds, which happen to union across multiple declarations:
// * module.exports = expr
// * exports.p = expr
// * this.p = expr
// * className.prototype.method = expr
if (declaration.kind === 192 /* BinaryExpression */ ||
declaration.kind === 177 /* PropertyAccessExpression */ && declaration.parent.kind === 192 /* BinaryExpression */) {
// Use JS Doc type if present on parent expression statement
if (declaration.flags & 2097152 /* JavaScriptFile */) {
var typeTag = ts.getJSDocTypeTag(declaration.parent);
if (typeTag && typeTag.typeExpression) {
return links.type = getTypeFromTypeNode(typeTag.typeExpression.type);
}
}
var declaredTypes = ts.map(symbol.declarations, function (decl) { return decl.kind === 192 /* BinaryExpression */ ?
checkExpressionCached(decl.right) :
checkExpressionCached(decl.parent.right); });
type = getUnionType(declaredTypes, /*subtypeReduction*/ true);
}
else {
type = getWidenedTypeForVariableLikeDeclaration(declaration, /*reportErrors*/ true);
}
if (!popTypeResolution()) {
if (symbol.valueDeclaration.type) {
// Variable has type annotation that circularly references the variable itself
type = unknownType;
error(symbol.valueDeclaration, ts.Diagnostics._0_is_referenced_directly_or_indirectly_in_its_own_type_annotation, symbolToString(symbol));
}
else {
// Variable has initializer that circularly references the variable itself
type = anyType;
if (compilerOptions.noImplicitAny) {
error(symbol.valueDeclaration, ts.Diagnostics._0_implicitly_has_type_any_because_it_does_not_have_a_type_annotation_and_is_referenced_directly_or_indirectly_in_its_own_initializer, symbolToString(symbol));
}
}
}
links.type = type;
}
return links.type;
}
function getAnnotatedAccessorType(accessor) {
if (accessor) {
if (accessor.kind === 151 /* GetAccessor */) {
return accessor.type && getTypeFromTypeNode(accessor.type);
}
else {
var setterTypeAnnotation = ts.getSetAccessorTypeAnnotationNode(accessor);
return setterTypeAnnotation && getTypeFromTypeNode(setterTypeAnnotation);
}
}
return undefined;
}
function getAnnotatedAccessorThisParameter(accessor) {
var parameter = getAccessorThisParameter(accessor);
return parameter && parameter.symbol;
}
function getThisTypeOfDeclaration(declaration) {
return getThisTypeOfSignature(getSignatureFromDeclaration(declaration));
}
function getTypeOfAccessors(symbol) {
var links = getSymbolLinks(symbol);
if (!links.type) {
var getter = ts.getDeclarationOfKind(symbol, 151 /* GetAccessor */);
var setter = ts.getDeclarationOfKind(symbol, 152 /* SetAccessor */);
if (getter && getter.flags & 2097152 /* JavaScriptFile */) {
var jsDocType = getTypeForVariableLikeDeclarationFromJSDocComment(getter);
if (jsDocType) {
return links.type = jsDocType;
}
}
if (!pushTypeResolution(symbol, 0 /* Type */)) {
return unknownType;
}
var type = void 0;
// First try to see if the user specified a return type on the get-accessor.
var getterReturnType = getAnnotatedAccessorType(getter);
if (getterReturnType) {
type = getterReturnType;
}
else {
// If the user didn't specify a return type, try to use the set-accessor's parameter type.
var setterParameterType = getAnnotatedAccessorType(setter);
if (setterParameterType) {
type = setterParameterType;
}
else {
// If there are no specified types, try to infer it from the body of the get accessor if it exists.
if (getter && getter.body) {
type = getReturnTypeFromBody(getter);
}
else {
if (compilerOptions.noImplicitAny) {
if (setter) {
error(setter, ts.Diagnostics.Property_0_implicitly_has_type_any_because_its_set_accessor_lacks_a_parameter_type_annotation, symbolToString(symbol));
}
else {
ts.Debug.assert(!!getter, "there must existed getter as we are current checking either setter or getter in this function");
error(getter, ts.Diagnostics.Property_0_implicitly_has_type_any_because_its_get_accessor_lacks_a_return_type_annotation, symbolToString(symbol));
}
}
type = anyType;
}
}
}
if (!popTypeResolution()) {
type = anyType;
if (compilerOptions.noImplicitAny) {
var getter_1 = ts.getDeclarationOfKind(symbol, 151 /* GetAccessor */);
error(getter_1, ts.Diagnostics._0_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions, symbolToString(symbol));
}
}
links.type = type;
}
return links.type;
}
function getTypeOfFuncClassEnumModule(symbol) {
var links = getSymbolLinks(symbol);
if (!links.type) {
if (symbol.flags & 1536 /* Module */ && ts.isShorthandAmbientModuleSymbol(symbol)) {
links.type = anyType;
}
else {
var type = createObjectType(16 /* Anonymous */, symbol);
links.type = strictNullChecks && symbol.flags & 536870912 /* Optional */ ?
includeFalsyTypes(type, 2048 /* Undefined */) : type;
}
}
return links.type;
}
function getTypeOfEnumMember(symbol) {
var links = getSymbolLinks(symbol);
if (!links.type) {
links.type = getDeclaredTypeOfEnumMember(symbol);
}
return links.type;
}
function getTypeOfAlias(symbol) {
var links = getSymbolLinks(symbol);
if (!links.type) {
var targetSymbol = resolveAlias(symbol);
// It only makes sense to get the type of a value symbol. If the result of resolving
// the alias is not a value, then it has no type. To get the type associated with a
// type symbol, call getDeclaredTypeOfSymbol.
// This check is important because without it, a call to getTypeOfSymbol could end
// up recursively calling getTypeOfAlias, causing a stack overflow.
links.type = targetSymbol.flags & 107455 /* Value */
? getTypeOfSymbol(targetSymbol)
: unknownType;
}
return links.type;
}
function getTypeOfInstantiatedSymbol(symbol) {
var links = getSymbolLinks(symbol);
if (!links.type) {
links.type = instantiateType(getTypeOfSymbol(links.target), links.mapper);
}
return links.type;
}
function getTypeOfSymbol(symbol) {
if (symbol.flags & 16777216 /* Instantiated */) {
return getTypeOfInstantiatedSymbol(symbol);
}
if (symbol.flags & (3 /* Variable */ | 4 /* Property */)) {
return getTypeOfVariableOrParameterOrProperty(symbol);
}
if (symbol.flags & (16 /* Function */ | 8192 /* Method */ | 32 /* Class */ | 384 /* Enum */ | 512 /* ValueModule */)) {
return getTypeOfFuncClassEnumModule(symbol);
}
if (symbol.flags & 8 /* EnumMember */) {
return getTypeOfEnumMember(symbol);
}
if (symbol.flags & 98304 /* Accessor */) {
return getTypeOfAccessors(symbol);
}
if (symbol.flags & 8388608 /* Alias */) {
return getTypeOfAlias(symbol);
}
return unknownType;
}
function getTargetType(type) {
return getObjectFlags(type) & 4 /* Reference */ ? type.target : type;
}
function hasBaseType(type, checkBase) {
return check(type);
function check(type) {
var target = getTargetType(type);
return target === checkBase || ts.forEach(getBaseTypes(target), check);
}
}
// Appends the type parameters given by a list of declarations to a set of type parameters and returns the resulting set.
// The function allocates a new array if the input type parameter set is undefined, but otherwise it modifies the set
// in-place and returns the same array.
function appendTypeParameters(typeParameters, declarations) {
for (var _i = 0, declarations_2 = declarations; _i < declarations_2.length; _i++) {
var declaration = declarations_2[_i];
var tp = getDeclaredTypeOfTypeParameter(getSymbolOfNode(declaration));
if (!typeParameters) {
typeParameters = [tp];
}
else if (!ts.contains(typeParameters, tp)) {
typeParameters.push(tp);
}
}
return typeParameters;
}
// Appends the outer type parameters of a node to a set of type parameters and returns the resulting set. The function
// allocates a new array if the input type parameter set is undefined, but otherwise it modifies the set in-place and
// returns the same array.
function appendOuterTypeParameters(typeParameters, node) {
while (true) {
node = node.parent;
if (!node) {
return typeParameters;
}
if (node.kind === 226 /* ClassDeclaration */ || node.kind === 197 /* ClassExpression */ ||
node.kind === 225 /* FunctionDeclaration */ || node.kind === 184 /* FunctionExpression */ ||
node.kind === 149 /* MethodDeclaration */ || node.kind === 185 /* ArrowFunction */) {
var declarations = node.typeParameters;
if (declarations) {
return appendTypeParameters(appendOuterTypeParameters(typeParameters, node), declarations);
}
}
}
}
// The outer type parameters are those defined by enclosing generic classes, methods, or functions.
function getOuterTypeParametersOfClassOrInterface(symbol) {
var declaration = symbol.flags & 32 /* Class */ ? symbol.valueDeclaration : ts.getDeclarationOfKind(symbol, 227 /* InterfaceDeclaration */);
return appendOuterTypeParameters(undefined, declaration);
}
// The local type parameters are the combined set of type parameters from all declarations of the class,
// interface, or type alias.
function getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol) {
var result;
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var node = _a[_i];
if (node.kind === 227 /* InterfaceDeclaration */ || node.kind === 226 /* ClassDeclaration */ ||
node.kind === 197 /* ClassExpression */ || node.kind === 228 /* TypeAliasDeclaration */) {
var declaration = node;
if (declaration.typeParameters) {
result = appendTypeParameters(result, declaration.typeParameters);
}
}
}
return result;
}
// The full set of type parameters for a generic class or interface type consists of its outer type parameters plus
// its locally declared type parameters.
function getTypeParametersOfClassOrInterface(symbol) {
return ts.concatenate(getOuterTypeParametersOfClassOrInterface(symbol), getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol));
}
function isConstructorType(type) {
return type.flags & 32768 /* Object */ && getSignaturesOfType(type, 1 /* Construct */).length > 0;
}
function getBaseTypeNodeOfClass(type) {
return ts.getClassExtendsHeritageClauseElement(type.symbol.valueDeclaration);
}
function getConstructorsForTypeArguments(type, typeArgumentNodes) {
var typeArgCount = typeArgumentNodes ? typeArgumentNodes.length : 0;
return ts.filter(getSignaturesOfType(type, 1 /* Construct */), function (sig) { return (sig.typeParameters ? sig.typeParameters.length : 0) === typeArgCount; });
}
function getInstantiatedConstructorsForTypeArguments(type, typeArgumentNodes) {
var signatures = getConstructorsForTypeArguments(type, typeArgumentNodes);
if (typeArgumentNodes) {
var typeArguments_1 = ts.map(typeArgumentNodes, getTypeFromTypeNode);
signatures = ts.map(signatures, function (sig) { return getSignatureInstantiation(sig, typeArguments_1); });
}
return signatures;
}
// The base constructor of a class can resolve to
// undefinedType if the class has no extends clause,
// unknownType if an error occurred during resolution of the extends expression,
// nullType if the extends expression is the null value, or
// an object type with at least one construct signature.
function getBaseConstructorTypeOfClass(type) {
if (!type.resolvedBaseConstructorType) {
var baseTypeNode = getBaseTypeNodeOfClass(type);
if (!baseTypeNode) {
return type.resolvedBaseConstructorType = undefinedType;
}
if (!pushTypeResolution(type, 1 /* ResolvedBaseConstructorType */)) {
return unknownType;
}
var baseConstructorType = checkExpression(baseTypeNode.expression);
if (baseConstructorType.flags & 32768 /* Object */) {
// Resolving the members of a class requires us to resolve the base class of that class.
// We force resolution here such that we catch circularities now.
resolveStructuredTypeMembers(baseConstructorType);
}
if (!popTypeResolution()) {
error(type.symbol.valueDeclaration, ts.Diagnostics._0_is_referenced_directly_or_indirectly_in_its_own_base_expression, symbolToString(type.symbol));
return type.resolvedBaseConstructorType = unknownType;
}
if (baseConstructorType !== unknownType && baseConstructorType !== nullWideningType && !isConstructorType(baseConstructorType)) {
error(baseTypeNode.expression, ts.Diagnostics.Type_0_is_not_a_constructor_function_type, typeToString(baseConstructorType));
return type.resolvedBaseConstructorType = unknownType;
}
type.resolvedBaseConstructorType = baseConstructorType;
}
return type.resolvedBaseConstructorType;
}
function getBaseTypes(type) {
if (!type.resolvedBaseTypes) {
if (type.objectFlags & 8 /* Tuple */) {
type.resolvedBaseTypes = [createArrayType(getUnionType(type.typeParameters))];
}
else if (type.symbol.flags & (32 /* Class */ | 64 /* Interface */)) {
if (type.symbol.flags & 32 /* Class */) {
resolveBaseTypesOfClass(type);
}
if (type.symbol.flags & 64 /* Interface */) {
resolveBaseTypesOfInterface(type);
}
}
else {
ts.Debug.fail("type must be class or interface");
}
}
return type.resolvedBaseTypes;
}
function resolveBaseTypesOfClass(type) {
type.resolvedBaseTypes = type.resolvedBaseTypes || emptyArray;
var baseConstructorType = getBaseConstructorTypeOfClass(type);
if (!(baseConstructorType.flags & 32768 /* Object */)) {
return;
}
var baseTypeNode = getBaseTypeNodeOfClass(type);
var baseType;
var originalBaseType = baseConstructorType && baseConstructorType.symbol ? getDeclaredTypeOfSymbol(baseConstructorType.symbol) : undefined;
if (baseConstructorType.symbol && baseConstructorType.symbol.flags & 32 /* Class */ &&
areAllOuterTypeParametersApplied(originalBaseType)) {
// When base constructor type is a class with no captured type arguments we know that the constructors all have the same type parameters as the
// class and all return the instance type of the class. There is no need for further checks and we can apply the
// type arguments in the same manner as a type reference to get the same error reporting experience.
baseType = getTypeFromClassOrInterfaceReference(baseTypeNode, baseConstructorType.symbol);
}
else {
// The class derives from a "class-like" constructor function, check that we have at least one construct signature
// with a matching number of type parameters and use the return type of the first instantiated signature. Elsewhere
// we check that all instantiated signatures return the same type.
var constructors = getInstantiatedConstructorsForTypeArguments(baseConstructorType, baseTypeNode.typeArguments);
if (!constructors.length) {
error(baseTypeNode.expression, ts.Diagnostics.No_base_constructor_has_the_specified_number_of_type_arguments);
return;
}
baseType = getReturnTypeOfSignature(constructors[0]);
}
if (baseType === unknownType) {
return;
}
if (!(getObjectFlags(getTargetType(baseType)) & 3 /* ClassOrInterface */)) {
error(baseTypeNode.expression, ts.Diagnostics.Base_constructor_return_type_0_is_not_a_class_or_interface_type, typeToString(baseType));
return;
}
if (type === baseType || hasBaseType(baseType, type)) {
error(type.symbol.valueDeclaration, ts.Diagnostics.Type_0_recursively_references_itself_as_a_base_type, typeToString(type, /*enclosingDeclaration*/ undefined, 1 /* WriteArrayAsGenericType */));
return;
}
if (type.resolvedBaseTypes === emptyArray) {
type.resolvedBaseTypes = [baseType];
}
else {
type.resolvedBaseTypes.push(baseType);
}
}
function areAllOuterTypeParametersApplied(type) {
// An unapplied type parameter has its symbol still the same as the matching argument symbol.
// Since parameters are applied outer-to-inner, only the last outer parameter needs to be checked.
var outerTypeParameters = type.outerTypeParameters;
if (outerTypeParameters) {
var last = outerTypeParameters.length - 1;
var typeArguments = type.typeArguments;
return outerTypeParameters[last].symbol !== typeArguments[last].symbol;
}
return true;
}
function resolveBaseTypesOfInterface(type) {
type.resolvedBaseTypes = type.resolvedBaseTypes || emptyArray;
for (var _i = 0, _a = type.symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (declaration.kind === 227 /* InterfaceDeclaration */ && ts.getInterfaceBaseTypeNodes(declaration)) {
for (var _b = 0, _c = ts.getInterfaceBaseTypeNodes(declaration); _b < _c.length; _b++) {
var node = _c[_b];
var baseType = getTypeFromTypeNode(node);
if (baseType !== unknownType) {
if (getObjectFlags(getTargetType(baseType)) & 3 /* ClassOrInterface */) {
if (type !== baseType && !hasBaseType(baseType, type)) {
if (type.resolvedBaseTypes === emptyArray) {
type.resolvedBaseTypes = [baseType];
}
else {
type.resolvedBaseTypes.push(baseType);
}
}
else {
error(declaration, ts.Diagnostics.Type_0_recursively_references_itself_as_a_base_type, typeToString(type, /*enclosingDeclaration*/ undefined, 1 /* WriteArrayAsGenericType */));
}
}
else {
error(node, ts.Diagnostics.An_interface_may_only_extend_a_class_or_another_interface);
}
}
}
}
}
}
// Returns true if the interface given by the symbol is free of "this" references. Specifically, the result is
// true if the interface itself contains no references to "this" in its body, if all base types are interfaces,
// and if none of the base interfaces have a "this" type.
function isIndependentInterface(symbol) {
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (declaration.kind === 227 /* InterfaceDeclaration */) {
if (declaration.flags & 64 /* ContainsThis */) {
return false;
}
var baseTypeNodes = ts.getInterfaceBaseTypeNodes(declaration);
if (baseTypeNodes) {
for (var _b = 0, baseTypeNodes_1 = baseTypeNodes; _b < baseTypeNodes_1.length; _b++) {
var node = baseTypeNodes_1[_b];
if (ts.isEntityNameExpression(node.expression)) {
var baseSymbol = resolveEntityName(node.expression, 793064 /* Type */, /*ignoreErrors*/ true);
if (!baseSymbol || !(baseSymbol.flags & 64 /* Interface */) || getDeclaredTypeOfClassOrInterface(baseSymbol).thisType) {
return false;
}
}
}
}
}
}
return true;
}
function getDeclaredTypeOfClassOrInterface(symbol) {
var links = getSymbolLinks(symbol);
if (!links.declaredType) {
var kind = symbol.flags & 32 /* Class */ ? 1 /* Class */ : 2 /* Interface */;
var type = links.declaredType = createObjectType(kind, symbol);
var outerTypeParameters = getOuterTypeParametersOfClassOrInterface(symbol);
var localTypeParameters = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol);
// A class or interface is generic if it has type parameters or a "this" type. We always give classes a "this" type
// because it is not feasible to analyze all members to determine if the "this" type escapes the class (in particular,
// property types inferred from initializers and method return types inferred from return statements are very hard
// to exhaustively analyze). We give interfaces a "this" type if we can't definitely determine that they are free of
// "this" references.
if (outerTypeParameters || localTypeParameters || kind === 1 /* Class */ || !isIndependentInterface(symbol)) {
type.objectFlags |= 4 /* Reference */;
type.typeParameters = ts.concatenate(outerTypeParameters, localTypeParameters);
type.outerTypeParameters = outerTypeParameters;
type.localTypeParameters = localTypeParameters;
type.instantiations = ts.createMap();
type.instantiations[getTypeListId(type.typeParameters)] = type;
type.target = type;
type.typeArguments = type.typeParameters;
type.thisType = createType(16384 /* TypeParameter */);
type.thisType.isThisType = true;
type.thisType.symbol = symbol;
type.thisType.constraint = type;
}
}
return links.declaredType;
}
function getDeclaredTypeOfTypeAlias(symbol) {
var links = getSymbolLinks(symbol);
if (!links.declaredType) {
// Note that we use the links object as the target here because the symbol object is used as the unique
// identity for resolution of the 'type' property in SymbolLinks.
if (!pushTypeResolution(symbol, 2 /* DeclaredType */)) {
return unknownType;
}
var declaration = ts.getDeclarationOfKind(symbol, 284 /* JSDocTypedefTag */);
var type = void 0;
if (declaration) {
if (declaration.jsDocTypeLiteral) {
type = getTypeFromTypeNode(declaration.jsDocTypeLiteral);
}
else {
type = getTypeFromTypeNode(declaration.typeExpression.type);
}
}
else {
declaration = ts.getDeclarationOfKind(symbol, 228 /* TypeAliasDeclaration */);
type = getTypeFromTypeNode(declaration.type);
}
if (popTypeResolution()) {
var typeParameters = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol);
if (typeParameters) {
// Initialize the instantiation cache for generic type aliases. The declared type corresponds to
// an instantiation of the type alias with the type parameters supplied as type arguments.
links.typeParameters = typeParameters;
links.instantiations = ts.createMap();
links.instantiations[getTypeListId(typeParameters)] = type;
}
}
else {
type = unknownType;
error(declaration.name, ts.Diagnostics.Type_alias_0_circularly_references_itself, symbolToString(symbol));
}
links.declaredType = type;
}
return links.declaredType;
}
function isLiteralEnumMember(symbol, member) {
var expr = member.initializer;
if (!expr) {
return !ts.isInAmbientContext(member);
}
return expr.kind === 8 /* NumericLiteral */ ||
expr.kind === 190 /* PrefixUnaryExpression */ && expr.operator === 37 /* MinusToken */ &&
expr.operand.kind === 8 /* NumericLiteral */ ||
expr.kind === 70 /* Identifier */ && !!symbol.exports[expr.text];
}
function enumHasLiteralMembers(symbol) {
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (declaration.kind === 229 /* EnumDeclaration */) {
for (var _b = 0, _c = declaration.members; _b < _c.length; _b++) {
var member = _c[_b];
if (!isLiteralEnumMember(symbol, member)) {
return false;
}
}
}
}
return true;
}
function createEnumLiteralType(symbol, baseType, text) {
var type = createType(256 /* EnumLiteral */);
type.symbol = symbol;
type.baseType = baseType;
type.text = text;
return type;
}
function getDeclaredTypeOfEnum(symbol) {
var links = getSymbolLinks(symbol);
if (!links.declaredType) {
var enumType = links.declaredType = createType(16 /* Enum */);
enumType.symbol = symbol;
if (enumHasLiteralMembers(symbol)) {
var memberTypeList = [];
var memberTypes = ts.createMap();
for (var _i = 0, _a = enumType.symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (declaration.kind === 229 /* EnumDeclaration */) {
computeEnumMemberValues(declaration);
for (var _b = 0, _c = declaration.members; _b < _c.length; _b++) {
var member = _c[_b];
var memberSymbol = getSymbolOfNode(member);
var value = getEnumMemberValue(member);
if (!memberTypes[value]) {
var memberType = memberTypes[value] = createEnumLiteralType(memberSymbol, enumType, "" + value);
memberTypeList.push(memberType);
}
}
}
}
enumType.memberTypes = memberTypes;
if (memberTypeList.length > 1) {
enumType.flags |= 65536 /* Union */;
enumType.types = memberTypeList;
unionTypes[getTypeListId(memberTypeList)] = enumType;
}
}
}
return links.declaredType;
}
function getDeclaredTypeOfEnumMember(symbol) {
var links = getSymbolLinks(symbol);
if (!links.declaredType) {
var enumType = getDeclaredTypeOfEnum(getParentOfSymbol(symbol));
links.declaredType = enumType.flags & 65536 /* Union */ ?
enumType.memberTypes[getEnumMemberValue(symbol.valueDeclaration)] :
enumType;
}
return links.declaredType;
}
function getDeclaredTypeOfTypeParameter(symbol) {
var links = getSymbolLinks(symbol);
if (!links.declaredType) {
var type = createType(16384 /* TypeParameter */);
type.symbol = symbol;
if (!ts.getDeclarationOfKind(symbol, 143 /* TypeParameter */).constraint) {
type.constraint = noConstraintType;
}
links.declaredType = type;
}
return links.declaredType;
}
function getDeclaredTypeOfAlias(symbol) {
var links = getSymbolLinks(symbol);
if (!links.declaredType) {
links.declaredType = getDeclaredTypeOfSymbol(resolveAlias(symbol));
}
return links.declaredType;
}
function getDeclaredTypeOfSymbol(symbol) {
ts.Debug.assert((symbol.flags & 16777216 /* Instantiated */) === 0);
if (symbol.flags & (32 /* Class */ | 64 /* Interface */)) {
return getDeclaredTypeOfClassOrInterface(symbol);
}
if (symbol.flags & 524288 /* TypeAlias */) {
return getDeclaredTypeOfTypeAlias(symbol);
}
if (symbol.flags & 262144 /* TypeParameter */) {
return getDeclaredTypeOfTypeParameter(symbol);
}
if (symbol.flags & 384 /* Enum */) {
return getDeclaredTypeOfEnum(symbol);
}
if (symbol.flags & 8 /* EnumMember */) {
return getDeclaredTypeOfEnumMember(symbol);
}
if (symbol.flags & 8388608 /* Alias */) {
return getDeclaredTypeOfAlias(symbol);
}
return unknownType;
}
// A type reference is considered independent if each type argument is considered independent.
function isIndependentTypeReference(node) {
if (node.typeArguments) {
for (var _i = 0, _a = node.typeArguments; _i < _a.length; _i++) {
var typeNode = _a[_i];
if (!isIndependentType(typeNode)) {
return false;
}
}
}
return true;
}
// A type is considered independent if it the any, string, number, boolean, symbol, or void keyword, a string
// literal type, an array with an element type that is considered independent, or a type reference that is
// considered independent.
function isIndependentType(node) {
switch (node.kind) {
case 118 /* AnyKeyword */:
case 134 /* StringKeyword */:
case 132 /* NumberKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 104 /* VoidKeyword */:
case 137 /* UndefinedKeyword */:
case 94 /* NullKeyword */:
case 129 /* NeverKeyword */:
case 171 /* LiteralType */:
return true;
case 162 /* ArrayType */:
return isIndependentType(node.elementType);
case 157 /* TypeReference */:
return isIndependentTypeReference(node);
}
return false;
}
// A variable-like declaration is considered independent (free of this references) if it has a type annotation
// that specifies an independent type, or if it has no type annotation and no initializer (and thus of type any).
function isIndependentVariableLikeDeclaration(node) {
return node.type && isIndependentType(node.type) || !node.type && !node.initializer;
}
// A function-like declaration is considered independent (free of this references) if it has a return type
// annotation that is considered independent and if each parameter is considered independent.
function isIndependentFunctionLikeDeclaration(node) {
if (node.kind !== 150 /* Constructor */ && (!node.type || !isIndependentType(node.type))) {
return false;
}
for (var _i = 0, _a = node.parameters; _i < _a.length; _i++) {
var parameter = _a[_i];
if (!isIndependentVariableLikeDeclaration(parameter)) {
return false;
}
}
return true;
}
// Returns true if the class or interface member given by the symbol is free of "this" references. The
// function may return false for symbols that are actually free of "this" references because it is not
// feasible to perform a complete analysis in all cases. In particular, property members with types
// inferred from their initializers and function members with inferred return types are conservatively
// assumed not to be free of "this" references.
function isIndependentMember(symbol) {
if (symbol.declarations && symbol.declarations.length === 1) {
var declaration = symbol.declarations[0];
if (declaration) {
switch (declaration.kind) {
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
return isIndependentVariableLikeDeclaration(declaration);
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
return isIndependentFunctionLikeDeclaration(declaration);
}
}
}
return false;
}
function createSymbolTable(symbols) {
var result = ts.createMap();
for (var _i = 0, symbols_1 = symbols; _i < symbols_1.length; _i++) {
var symbol = symbols_1[_i];
result[symbol.name] = symbol;
}
return result;
}
// The mappingThisOnly flag indicates that the only type parameter being mapped is "this". When the flag is true,
// we check symbols to see if we can quickly conclude they are free of "this" references, thus needing no instantiation.
function createInstantiatedSymbolTable(symbols, mapper, mappingThisOnly) {
var result = ts.createMap();
for (var _i = 0, symbols_2 = symbols; _i < symbols_2.length; _i++) {
var symbol = symbols_2[_i];
result[symbol.name] = mappingThisOnly && isIndependentMember(symbol) ? symbol : instantiateSymbol(symbol, mapper);
}
return result;
}
function addInheritedMembers(symbols, baseSymbols) {
for (var _i = 0, baseSymbols_1 = baseSymbols; _i < baseSymbols_1.length; _i++) {
var s = baseSymbols_1[_i];
if (!symbols[s.name]) {
symbols[s.name] = s;
}
}
}
function resolveDeclaredMembers(type) {
if (!type.declaredProperties) {
var symbol = type.symbol;
type.declaredProperties = getNamedMembers(symbol.members);
type.declaredCallSignatures = getSignaturesOfSymbol(symbol.members["__call"]);
type.declaredConstructSignatures = getSignaturesOfSymbol(symbol.members["__new"]);
type.declaredStringIndexInfo = getIndexInfoOfSymbol(symbol, 0 /* String */);
type.declaredNumberIndexInfo = getIndexInfoOfSymbol(symbol, 1 /* Number */);
}
return type;
}
function getTypeWithThisArgument(type, thisArgument) {
if (getObjectFlags(type) & 4 /* Reference */) {
return createTypeReference(type.target, ts.concatenate(type.typeArguments, [thisArgument || type.target.thisType]));
}
return type;
}
function resolveObjectTypeMembers(type, source, typeParameters, typeArguments) {
var mapper;
var members;
var callSignatures;
var constructSignatures;
var stringIndexInfo;
var numberIndexInfo;
if (ts.rangeEquals(typeParameters, typeArguments, 0, typeParameters.length)) {
mapper = identityMapper;
members = source.symbol ? source.symbol.members : createSymbolTable(source.declaredProperties);
callSignatures = source.declaredCallSignatures;
constructSignatures = source.declaredConstructSignatures;
stringIndexInfo = source.declaredStringIndexInfo;
numberIndexInfo = source.declaredNumberIndexInfo;
}
else {
mapper = createTypeMapper(typeParameters, typeArguments);
members = createInstantiatedSymbolTable(source.declaredProperties, mapper, /*mappingThisOnly*/ typeParameters.length === 1);
callSignatures = instantiateSignatures(source.declaredCallSignatures, mapper);
constructSignatures = instantiateSignatures(source.declaredConstructSignatures, mapper);
stringIndexInfo = instantiateIndexInfo(source.declaredStringIndexInfo, mapper);
numberIndexInfo = instantiateIndexInfo(source.declaredNumberIndexInfo, mapper);
}
var baseTypes = getBaseTypes(source);
if (baseTypes.length) {
if (source.symbol && members === source.symbol.members) {
members = createSymbolTable(source.declaredProperties);
}
var thisArgument = ts.lastOrUndefined(typeArguments);
for (var _i = 0, baseTypes_1 = baseTypes; _i < baseTypes_1.length; _i++) {
var baseType = baseTypes_1[_i];
var instantiatedBaseType = thisArgument ? getTypeWithThisArgument(instantiateType(baseType, mapper), thisArgument) : baseType;
addInheritedMembers(members, getPropertiesOfObjectType(instantiatedBaseType));
callSignatures = ts.concatenate(callSignatures, getSignaturesOfType(instantiatedBaseType, 0 /* Call */));
constructSignatures = ts.concatenate(constructSignatures, getSignaturesOfType(instantiatedBaseType, 1 /* Construct */));
stringIndexInfo = stringIndexInfo || getIndexInfoOfType(instantiatedBaseType, 0 /* String */);
numberIndexInfo = numberIndexInfo || getIndexInfoOfType(instantiatedBaseType, 1 /* Number */);
}
}
setStructuredTypeMembers(type, members, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo);
}
function resolveClassOrInterfaceMembers(type) {
resolveObjectTypeMembers(type, resolveDeclaredMembers(type), emptyArray, emptyArray);
}
function resolveTypeReferenceMembers(type) {
var source = resolveDeclaredMembers(type.target);
var typeParameters = ts.concatenate(source.typeParameters, [source.thisType]);
var typeArguments = type.typeArguments && type.typeArguments.length === typeParameters.length ?
type.typeArguments : ts.concatenate(type.typeArguments, [type]);
resolveObjectTypeMembers(type, source, typeParameters, typeArguments);
}
function createSignature(declaration, typeParameters, thisParameter, parameters, resolvedReturnType, typePredicate, minArgumentCount, hasRestParameter, hasLiteralTypes) {
var sig = new Signature(checker);
sig.declaration = declaration;
sig.typeParameters = typeParameters;
sig.parameters = parameters;
sig.thisParameter = thisParameter;
sig.resolvedReturnType = resolvedReturnType;
sig.typePredicate = typePredicate;
sig.minArgumentCount = minArgumentCount;
sig.hasRestParameter = hasRestParameter;
sig.hasLiteralTypes = hasLiteralTypes;
return sig;
}
function cloneSignature(sig) {
return createSignature(sig.declaration, sig.typeParameters, sig.thisParameter, sig.parameters, sig.resolvedReturnType, sig.typePredicate, sig.minArgumentCount, sig.hasRestParameter, sig.hasLiteralTypes);
}
function getDefaultConstructSignatures(classType) {
var baseConstructorType = getBaseConstructorTypeOfClass(classType);
var baseSignatures = getSignaturesOfType(baseConstructorType, 1 /* Construct */);
if (baseSignatures.length === 0) {
return [createSignature(undefined, classType.localTypeParameters, undefined, emptyArray, classType, /*typePredicate*/ undefined, 0, /*hasRestParameter*/ false, /*hasLiteralTypes*/ false)];
}
var baseTypeNode = getBaseTypeNodeOfClass(classType);
var typeArguments = ts.map(baseTypeNode.typeArguments, getTypeFromTypeNode);
var typeArgCount = typeArguments ? typeArguments.length : 0;
var result = [];
for (var _i = 0, baseSignatures_1 = baseSignatures; _i < baseSignatures_1.length; _i++) {
var baseSig = baseSignatures_1[_i];
var typeParamCount = baseSig.typeParameters ? baseSig.typeParameters.length : 0;
if (typeParamCount === typeArgCount) {
var sig = typeParamCount ? createSignatureInstantiation(baseSig, typeArguments) : cloneSignature(baseSig);
sig.typeParameters = classType.localTypeParameters;
sig.resolvedReturnType = classType;
result.push(sig);
}
}
return result;
}
function findMatchingSignature(signatureList, signature, partialMatch, ignoreThisTypes, ignoreReturnTypes) {
for (var _i = 0, signatureList_1 = signatureList; _i < signatureList_1.length; _i++) {
var s = signatureList_1[_i];
if (compareSignaturesIdentical(s, signature, partialMatch, ignoreThisTypes, ignoreReturnTypes, compareTypesIdentical)) {
return s;
}
}
}
function findMatchingSignatures(signatureLists, signature, listIndex) {
if (signature.typeParameters) {
// We require an exact match for generic signatures, so we only return signatures from the first
// signature list and only if they have exact matches in the other signature lists.
if (listIndex > 0) {
return undefined;
}
for (var i = 1; i < signatureLists.length; i++) {
if (!findMatchingSignature(signatureLists[i], signature, /*partialMatch*/ false, /*ignoreThisTypes*/ false, /*ignoreReturnTypes*/ false)) {
return undefined;
}
}
return [signature];
}
var result = undefined;
for (var i = 0; i < signatureLists.length; i++) {
// Allow matching non-generic signatures to have excess parameters and different return types
var match = i === listIndex ? signature : findMatchingSignature(signatureLists[i], signature, /*partialMatch*/ true, /*ignoreThisTypes*/ true, /*ignoreReturnTypes*/ true);
if (!match) {
return undefined;
}
if (!ts.contains(result, match)) {
(result || (result = [])).push(match);
}
}
return result;
}
// The signatures of a union type are those signatures that are present in each of the constituent types.
// Generic signatures must match exactly, but non-generic signatures are allowed to have extra optional
// parameters and may differ in return types. When signatures differ in return types, the resulting return
// type is the union of the constituent return types.
function getUnionSignatures(types, kind) {
var signatureLists = ts.map(types, function (t) { return getSignaturesOfType(t, kind); });
var result = undefined;
for (var i = 0; i < signatureLists.length; i++) {
for (var _i = 0, _a = signatureLists[i]; _i < _a.length; _i++) {
var signature = _a[_i];
// Only process signatures with parameter lists that aren't already in the result list
if (!result || !findMatchingSignature(result, signature, /*partialMatch*/ false, /*ignoreThisTypes*/ true, /*ignoreReturnTypes*/ true)) {
var unionSignatures = findMatchingSignatures(signatureLists, signature, i);
if (unionSignatures) {
var s = signature;
// Union the result types when more than one signature matches
if (unionSignatures.length > 1) {
s = cloneSignature(signature);
if (ts.forEach(unionSignatures, function (sig) { return sig.thisParameter; })) {
var thisType = getUnionType(ts.map(unionSignatures, function (sig) { return getTypeOfSymbol(sig.thisParameter) || anyType; }), /*subtypeReduction*/ true);
s.thisParameter = createTransientSymbol(signature.thisParameter, thisType);
}
// Clear resolved return type we possibly got from cloneSignature
s.resolvedReturnType = undefined;
s.unionSignatures = unionSignatures;
}
(result || (result = [])).push(s);
}
}
}
}
return result || emptyArray;
}
function getUnionIndexInfo(types, kind) {
var indexTypes = [];
var isAnyReadonly = false;
for (var _i = 0, types_1 = types; _i < types_1.length; _i++) {
var type = types_1[_i];
var indexInfo = getIndexInfoOfType(type, kind);
if (!indexInfo) {
return undefined;
}
indexTypes.push(indexInfo.type);
isAnyReadonly = isAnyReadonly || indexInfo.isReadonly;
}
return createIndexInfo(getUnionType(indexTypes, /*subtypeReduction*/ true), isAnyReadonly);
}
function resolveUnionTypeMembers(type) {
// The members and properties collections are empty for union types. To get all properties of a union
// type use getPropertiesOfType (only the language service uses this).
var callSignatures = getUnionSignatures(type.types, 0 /* Call */);
var constructSignatures = getUnionSignatures(type.types, 1 /* Construct */);
var stringIndexInfo = getUnionIndexInfo(type.types, 0 /* String */);
var numberIndexInfo = getUnionIndexInfo(type.types, 1 /* Number */);
setStructuredTypeMembers(type, emptySymbols, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo);
}
function intersectTypes(type1, type2) {
return !type1 ? type2 : !type2 ? type1 : getIntersectionType([type1, type2]);
}
function intersectIndexInfos(info1, info2) {
return !info1 ? info2 : !info2 ? info1 : createIndexInfo(getIntersectionType([info1.type, info2.type]), info1.isReadonly && info2.isReadonly);
}
function unionSpreadIndexInfos(info1, info2) {
return info1 && info2 && createIndexInfo(getUnionType([info1.type, info2.type]), info1.isReadonly || info2.isReadonly);
}
function resolveIntersectionTypeMembers(type) {
// The members and properties collections are empty for intersection types. To get all properties of an
// intersection type use getPropertiesOfType (only the language service uses this).
var callSignatures = emptyArray;
var constructSignatures = emptyArray;
var stringIndexInfo = undefined;
var numberIndexInfo = undefined;
for (var _i = 0, _a = type.types; _i < _a.length; _i++) {
var t = _a[_i];
callSignatures = ts.concatenate(callSignatures, getSignaturesOfType(t, 0 /* Call */));
constructSignatures = ts.concatenate(constructSignatures, getSignaturesOfType(t, 1 /* Construct */));
stringIndexInfo = intersectIndexInfos(stringIndexInfo, getIndexInfoOfType(t, 0 /* String */));
numberIndexInfo = intersectIndexInfos(numberIndexInfo, getIndexInfoOfType(t, 1 /* Number */));
}
setStructuredTypeMembers(type, emptySymbols, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo);
}
function resolveAnonymousTypeMembers(type) {
var symbol = type.symbol;
if (type.target) {
var members = createInstantiatedSymbolTable(getPropertiesOfObjectType(type.target), type.mapper, /*mappingThisOnly*/ false);
var callSignatures = instantiateSignatures(getSignaturesOfType(type.target, 0 /* Call */), type.mapper);
var constructSignatures = instantiateSignatures(getSignaturesOfType(type.target, 1 /* Construct */), type.mapper);
var stringIndexInfo = instantiateIndexInfo(getIndexInfoOfType(type.target, 0 /* String */), type.mapper);
var numberIndexInfo = instantiateIndexInfo(getIndexInfoOfType(type.target, 1 /* Number */), type.mapper);
setStructuredTypeMembers(type, members, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo);
}
else if (symbol.flags & 2048 /* TypeLiteral */) {
var members = symbol.members;
var callSignatures = getSignaturesOfSymbol(members["__call"]);
var constructSignatures = getSignaturesOfSymbol(members["__new"]);
var stringIndexInfo = getIndexInfoOfSymbol(symbol, 0 /* String */);
var numberIndexInfo = getIndexInfoOfSymbol(symbol, 1 /* Number */);
setStructuredTypeMembers(type, members, callSignatures, constructSignatures, stringIndexInfo, numberIndexInfo);
}
else {
// Combinations of function, class, enum and module
var members = emptySymbols;
var constructSignatures = emptyArray;
if (symbol.flags & 1952 /* HasExports */) {
members = getExportsOfSymbol(symbol);
}
if (symbol.flags & 32 /* Class */) {
var classType = getDeclaredTypeOfClassOrInterface(symbol);
constructSignatures = getSignaturesOfSymbol(symbol.members["__constructor"]);
if (!constructSignatures.length) {
constructSignatures = getDefaultConstructSignatures(classType);
}
var baseConstructorType = getBaseConstructorTypeOfClass(classType);
if (baseConstructorType.flags & 32768 /* Object */) {
members = createSymbolTable(getNamedMembers(members));
addInheritedMembers(members, getPropertiesOfObjectType(baseConstructorType));
}
}
var numberIndexInfo = symbol.flags & 384 /* Enum */ ? enumNumberIndexInfo : undefined;
setStructuredTypeMembers(type, members, emptyArray, constructSignatures, undefined, numberIndexInfo);
// We resolve the members before computing the signatures because a signature may use
// typeof with a qualified name expression that circularly references the type we are
// in the process of resolving (see issue #6072). The temporarily empty signature list
// will never be observed because a qualified name can't reference signatures.
if (symbol.flags & (16 /* Function */ | 8192 /* Method */)) {
type.callSignatures = getSignaturesOfSymbol(symbol);
}
}
}
/** Resolve the members of a mapped type { [P in K]: T } */
function resolveMappedTypeMembers(type) {
var members = ts.createMap();
var stringIndexInfo;
var numberIndexInfo;
// In { [P in K]: T }, we refer to P as the type parameter type, K as the constraint type,
// and T as the template type.
var typeParameter = getTypeParameterFromMappedType(type);
var constraintType = getConstraintTypeFromMappedType(type);
var templateType = getTemplateTypeFromMappedType(type);
var isReadonly = !!type.declaration.readonlyToken;
var isOptional = !!type.declaration.questionToken;
// First, if the constraint type is a type parameter, obtain the base constraint. Then,
// if the key type is a 'keyof X', obtain 'keyof C' where C is the base constraint of X.
// Finally, iterate over the constituents of the resulting iteration type.
var keyType = constraintType.flags & 16384 /* TypeParameter */ ? getApparentType(constraintType) : constraintType;
var iterationType = keyType.flags & 262144 /* Index */ ? getIndexType(getApparentType(keyType.type)) : keyType;
forEachType(iterationType, function (t) {
// Create a mapper from T to the current iteration type constituent. Then, if the
// mapped type is itself an instantiated type, combine the iteration mapper with the
// instantiation mapper.
var iterationMapper = createUnaryTypeMapper(typeParameter, t);
var templateMapper = type.mapper ? combineTypeMappers(type.mapper, iterationMapper) : iterationMapper;
var propType = instantiateType(templateType, templateMapper);
// If the current iteration type constituent is a literal type, create a property.
// Otherwise, for type string create a string index signature and for type number
// create a numeric index signature.
if (t.flags & (32 /* StringLiteral */ | 64 /* NumberLiteral */ | 256 /* EnumLiteral */)) {
var propName = t.text;
var prop = createSymbol(4 /* Property */ | 67108864 /* Transient */ | (isOptional ? 536870912 /* Optional */ : 0), propName);
prop.type = addOptionality(propType, isOptional);
prop.isReadonly = isReadonly;
members[propName] = prop;
}
else if (t.flags & 2 /* String */) {
stringIndexInfo = createIndexInfo(propType, isReadonly);
}
else if (t.flags & 4 /* Number */) {
numberIndexInfo = createIndexInfo(propType, isReadonly);
}
});
// If we created both a string and a numeric string index signature, and if the two index
// signatures have identical types, discard the redundant numeric index signature.
if (stringIndexInfo && numberIndexInfo && isTypeIdenticalTo(stringIndexInfo.type, numberIndexInfo.type)) {
numberIndexInfo = undefined;
}
setStructuredTypeMembers(type, members, emptyArray, emptyArray, stringIndexInfo, numberIndexInfo);
}
function getTypeParameterFromMappedType(type) {
return type.typeParameter ||
(type.typeParameter = getDeclaredTypeOfTypeParameter(getSymbolOfNode(type.declaration.typeParameter)));
}
function getConstraintTypeFromMappedType(type) {
return type.constraintType ||
(type.constraintType = instantiateType(getConstraintOfTypeParameter(getTypeParameterFromMappedType(type)), type.mapper || identityMapper) || unknownType);
}
function getTemplateTypeFromMappedType(type) {
return type.templateType ||
(type.templateType = type.declaration.type ?
instantiateType(getTypeFromTypeNode(type.declaration.type), type.mapper || identityMapper) :
unknownType);
}
function isGenericMappedType(type) {
if (getObjectFlags(type) & 32 /* Mapped */) {
var constraintType = getConstraintTypeFromMappedType(type);
return !!(constraintType.flags & (16384 /* TypeParameter */ | 262144 /* Index */));
}
return false;
}
function resolveStructuredTypeMembers(type) {
if (!type.members) {
if (type.flags & 32768 /* Object */) {
if (type.objectFlags & 4 /* Reference */) {
resolveTypeReferenceMembers(type);
}
else if (type.objectFlags & 3 /* ClassOrInterface */) {
resolveClassOrInterfaceMembers(type);
}
else if (type.objectFlags & 16 /* Anonymous */) {
resolveAnonymousTypeMembers(type);
}
else if (type.objectFlags & 32 /* Mapped */) {
resolveMappedTypeMembers(type);
}
}
else if (type.flags & 65536 /* Union */) {
resolveUnionTypeMembers(type);
}
else if (type.flags & 131072 /* Intersection */) {
resolveIntersectionTypeMembers(type);
}
}
return type;
}
/** Return properties of an object type or an empty array for other types */
function getPropertiesOfObjectType(type) {
if (type.flags & 32768 /* Object */) {
return resolveStructuredTypeMembers(type).properties;
}
return emptyArray;
}
/** If the given type is an object type and that type has a property by the given name,
* return the symbol for that property. Otherwise return undefined. */
function getPropertyOfObjectType(type, name) {
if (type.flags & 32768 /* Object */) {
var resolved = resolveStructuredTypeMembers(type);
var symbol = resolved.members[name];
if (symbol && symbolIsValue(symbol)) {
return symbol;
}
}
}
function getPropertiesOfUnionOrIntersectionType(type) {
for (var _i = 0, _a = type.types; _i < _a.length; _i++) {
var current = _a[_i];
for (var _b = 0, _c = getPropertiesOfType(current); _b < _c.length; _b++) {
var prop = _c[_b];
getUnionOrIntersectionProperty(type, prop.name);
}
// The properties of a union type are those that are present in all constituent types, so
// we only need to check the properties of the first type
if (type.flags & 65536 /* Union */) {
break;
}
}
var props = type.resolvedProperties;
if (props) {
var result = [];
for (var key in props) {
var prop = props[key];
// We need to filter out partial properties in union types
if (!(prop.flags & 268435456 /* SyntheticProperty */ && prop.isPartial)) {
result.push(prop);
}
}
return result;
}
return emptyArray;
}
function getPropertiesOfType(type) {
type = getApparentType(type);
return type.flags & 196608 /* UnionOrIntersection */ ?
getPropertiesOfUnionOrIntersectionType(type) :
getPropertiesOfObjectType(type);
}
/**
* The apparent type of a type parameter is the base constraint instantiated with the type parameter
* as the type argument for the 'this' type.
*/
function getApparentTypeOfTypeParameter(type) {
if (!type.resolvedApparentType) {
var constraintType = getConstraintOfTypeParameter(type);
while (constraintType && constraintType.flags & 16384 /* TypeParameter */) {
constraintType = getConstraintOfTypeParameter(constraintType);
}
type.resolvedApparentType = getTypeWithThisArgument(constraintType || emptyObjectType, type);
}
return type.resolvedApparentType;
}
/**
* For a type parameter, return the base constraint of the type parameter. For the string, number,
* boolean, and symbol primitive types, return the corresponding object types. Otherwise return the
* type itself. Note that the apparent type of a union type is the union type itself.
*/
function getApparentType(type) {
var t = type.flags & 16384 /* TypeParameter */ ? getApparentTypeOfTypeParameter(type) : type;
return t.flags & 34 /* StringLike */ ? globalStringType :
t.flags & 340 /* NumberLike */ ? globalNumberType :
t.flags & 136 /* BooleanLike */ ? globalBooleanType :
t.flags & 512 /* ESSymbol */ ? getGlobalESSymbolType() :
t.flags & 262144 /* Index */ ? stringOrNumberType :
t;
}
function createUnionOrIntersectionProperty(containingType, name) {
var types = containingType.types;
var props;
// Flags we want to propagate to the result if they exist in all source symbols
var commonFlags = (containingType.flags & 131072 /* Intersection */) ? 536870912 /* Optional */ : 0 /* None */;
var isReadonly = false;
var isPartial = false;
for (var _i = 0, types_2 = types; _i < types_2.length; _i++) {
var current = types_2[_i];
var type = getApparentType(current);
if (type !== unknownType) {
var prop = getPropertyOfType(type, name);
if (prop && !(getDeclarationModifierFlagsFromSymbol(prop) & (8 /* Private */ | 16 /* Protected */))) {
commonFlags &= prop.flags;
if (!props) {
props = [prop];
}
else if (!ts.contains(props, prop)) {
props.push(prop);
}
if (isReadonlySymbol(prop)) {
isReadonly = true;
}
}
else if (containingType.flags & 65536 /* Union */) {
isPartial = true;
}
}
}
if (!props) {
return undefined;
}
if (props.length === 1 && !isPartial) {
return props[0];
}
var propTypes = [];
var declarations = [];
var commonType = undefined;
var hasNonUniformType = false;
for (var _a = 0, props_1 = props; _a < props_1.length; _a++) {
var prop = props_1[_a];
if (prop.declarations) {
ts.addRange(declarations, prop.declarations);
}
var type = getTypeOfSymbol(prop);
if (!commonType) {
commonType = type;
}
else if (type !== commonType) {
hasNonUniformType = true;
}
propTypes.push(type);
}
var result = createSymbol(4 /* Property */ | 67108864 /* Transient */ | 268435456 /* SyntheticProperty */ | commonFlags, name);
result.containingType = containingType;
result.hasNonUniformType = hasNonUniformType;
result.isPartial = isPartial;
result.declarations = declarations;
result.isReadonly = isReadonly;
result.type = containingType.flags & 65536 /* Union */ ? getUnionType(propTypes) : getIntersectionType(propTypes);
return result;
}
// Return the symbol for a given property in a union or intersection type, or undefined if the property
// does not exist in any constituent type. Note that the returned property may only be present in some
// constituents, in which case the isPartial flag is set when the containing type is union type. We need
// these partial properties when identifying discriminant properties, but otherwise they are filtered out
// and do not appear to be present in the union type.
function getUnionOrIntersectionProperty(type, name) {
var properties = type.resolvedProperties || (type.resolvedProperties = ts.createMap());
var property = properties[name];
if (!property) {
property = createUnionOrIntersectionProperty(type, name);
if (property) {
properties[name] = property;
}
}
return property;
}
function getPropertyOfUnionOrIntersectionType(type, name) {
var property = getUnionOrIntersectionProperty(type, name);
// We need to filter out partial properties in union types
return property && !(property.flags & 268435456 /* SyntheticProperty */ && property.isPartial) ? property : undefined;
}
/**
* Return the symbol for the property with the given name in the given type. Creates synthetic union properties when
* necessary, maps primitive types and type parameters are to their apparent types, and augments with properties from
* Object and Function as appropriate.
*
* @param type a type to look up property from
* @param name a name of property to look up in a given type
*/
function getPropertyOfType(type, name) {
type = getApparentType(type);
if (type.flags & 32768 /* Object */) {
var resolved = resolveStructuredTypeMembers(type);
var symbol = resolved.members[name];
if (symbol && symbolIsValue(symbol)) {
return symbol;
}
if (resolved === anyFunctionType || resolved.callSignatures.length || resolved.constructSignatures.length) {
var symbol_1 = getPropertyOfObjectType(globalFunctionType, name);
if (symbol_1) {
return symbol_1;
}
}
return getPropertyOfObjectType(globalObjectType, name);
}
if (type.flags & 196608 /* UnionOrIntersection */) {
return getPropertyOfUnionOrIntersectionType(type, name);
}
return undefined;
}
function getSignaturesOfStructuredType(type, kind) {
if (type.flags & 229376 /* StructuredType */) {
var resolved = resolveStructuredTypeMembers(type);
return kind === 0 /* Call */ ? resolved.callSignatures : resolved.constructSignatures;
}
return emptyArray;
}
/**
* Return the signatures of the given kind in the given type. Creates synthetic union signatures when necessary and
* maps primitive types and type parameters are to their apparent types.
*/
function getSignaturesOfType(type, kind) {
return getSignaturesOfStructuredType(getApparentType(type), kind);
}
function getIndexInfoOfStructuredType(type, kind) {
if (type.flags & 229376 /* StructuredType */) {
var resolved = resolveStructuredTypeMembers(type);
return kind === 0 /* String */ ? resolved.stringIndexInfo : resolved.numberIndexInfo;
}
}
function getIndexTypeOfStructuredType(type, kind) {
var info = getIndexInfoOfStructuredType(type, kind);
return info && info.type;
}
// Return the indexing info of the given kind in the given type. Creates synthetic union index types when necessary and
// maps primitive types and type parameters are to their apparent types.
function getIndexInfoOfType(type, kind) {
return getIndexInfoOfStructuredType(getApparentType(type), kind);
}
// Return the index type of the given kind in the given type. Creates synthetic union index types when necessary and
// maps primitive types and type parameters are to their apparent types.
function getIndexTypeOfType(type, kind) {
return getIndexTypeOfStructuredType(getApparentType(type), kind);
}
function getImplicitIndexTypeOfType(type, kind) {
if (isObjectLiteralType(type)) {
var propTypes = [];
for (var _i = 0, _a = getPropertiesOfType(type); _i < _a.length; _i++) {
var prop = _a[_i];
if (kind === 0 /* String */ || isNumericLiteralName(prop.name)) {
propTypes.push(getTypeOfSymbol(prop));
}
}
if (propTypes.length) {
return getUnionType(propTypes, /*subtypeReduction*/ true);
}
}
return undefined;
}
function getTypeParametersFromJSDocTemplate(declaration) {
if (declaration.flags & 2097152 /* JavaScriptFile */) {
var templateTag = ts.getJSDocTemplateTag(declaration);
if (templateTag) {
return getTypeParametersFromDeclaration(templateTag.typeParameters);
}
}
return undefined;
}
// Return list of type parameters with duplicates removed (duplicate identifier errors are generated in the actual
// type checking functions).
function getTypeParametersFromDeclaration(typeParameterDeclarations) {
var result = [];
ts.forEach(typeParameterDeclarations, function (node) {
var tp = getDeclaredTypeOfTypeParameter(node.symbol);
if (!ts.contains(result, tp)) {
result.push(tp);
}
});
return result;
}
function symbolsToArray(symbols) {
var result = [];
for (var id in symbols) {
if (!isReservedMemberName(id)) {
result.push(symbols[id]);
}
}
return result;
}
function isJSDocOptionalParameter(node) {
if (node.flags & 2097152 /* JavaScriptFile */) {
if (node.type && node.type.kind === 273 /* JSDocOptionalType */) {
return true;
}
var paramTag = ts.getCorrespondingJSDocParameterTag(node);
if (paramTag) {
if (paramTag.isBracketed) {
return true;
}
if (paramTag.typeExpression) {
return paramTag.typeExpression.type.kind === 273 /* JSDocOptionalType */;
}
}
}
}
function tryFindAmbientModule(moduleName, withAugmentations) {
if (ts.isExternalModuleNameRelative(moduleName)) {
return undefined;
}
var symbol = getSymbol(globals, "\"" + moduleName + "\"", 512 /* ValueModule */);
// merged symbol is module declaration symbol combined with all augmentations
return symbol && withAugmentations ? getMergedSymbol(symbol) : symbol;
}
function isOptionalParameter(node) {
if (ts.hasQuestionToken(node) || isJSDocOptionalParameter(node)) {
return true;
}
if (node.initializer) {
var signatureDeclaration = node.parent;
var signature = getSignatureFromDeclaration(signatureDeclaration);
var parameterIndex = ts.indexOf(signatureDeclaration.parameters, node);
ts.Debug.assert(parameterIndex >= 0);
return parameterIndex >= signature.minArgumentCount;
}
return false;
}
function createTypePredicateFromTypePredicateNode(node) {
if (node.parameterName.kind === 70 /* Identifier */) {
var parameterName = node.parameterName;
return {
kind: 1 /* Identifier */,
parameterName: parameterName ? parameterName.text : undefined,
parameterIndex: parameterName ? getTypePredicateParameterIndex(node.parent.parameters, parameterName) : undefined,
type: getTypeFromTypeNode(node.type)
};
}
else {
return {
kind: 0 /* This */,
type: getTypeFromTypeNode(node.type)
};
}
}
function getSignatureFromDeclaration(declaration) {
var links = getNodeLinks(declaration);
if (!links.resolvedSignature) {
var parameters = [];
var hasLiteralTypes = false;
var minArgumentCount = -1;
var thisParameter = undefined;
var hasThisParameter = void 0;
var isJSConstructSignature = ts.isJSDocConstructSignature(declaration);
// If this is a JSDoc construct signature, then skip the first parameter in the
// parameter list. The first parameter represents the return type of the construct
// signature.
for (var i = isJSConstructSignature ? 1 : 0, n = declaration.parameters.length; i < n; i++) {
var param = declaration.parameters[i];
var paramSymbol = param.symbol;
// Include parameter symbol instead of property symbol in the signature
if (paramSymbol && !!(paramSymbol.flags & 4 /* Property */) && !ts.isBindingPattern(param.name)) {
var resolvedSymbol = resolveName(param, paramSymbol.name, 107455 /* Value */, undefined, undefined);
paramSymbol = resolvedSymbol;
}
if (i === 0 && paramSymbol.name === "this") {
hasThisParameter = true;
thisParameter = param.symbol;
}
else {
parameters.push(paramSymbol);
}
if (param.type && param.type.kind === 171 /* LiteralType */) {
hasLiteralTypes = true;
}
if (param.initializer || param.questionToken || param.dotDotDotToken || isJSDocOptionalParameter(param)) {
if (minArgumentCount < 0) {
minArgumentCount = i - (hasThisParameter ? 1 : 0);
}
}
else {
// If we see any required parameters, it means the prior ones were not in fact optional.
minArgumentCount = -1;
}
}
// If only one accessor includes a this-type annotation, the other behaves as if it had the same type annotation
if ((declaration.kind === 151 /* GetAccessor */ || declaration.kind === 152 /* SetAccessor */) &&
!ts.hasDynamicName(declaration) &&
(!hasThisParameter || !thisParameter)) {
var otherKind = declaration.kind === 151 /* GetAccessor */ ? 152 /* SetAccessor */ : 151 /* GetAccessor */;
var other = ts.getDeclarationOfKind(declaration.symbol, otherKind);
if (other) {
thisParameter = getAnnotatedAccessorThisParameter(other);
}
}
if (minArgumentCount < 0) {
minArgumentCount = declaration.parameters.length - (hasThisParameter ? 1 : 0);
}
if (isJSConstructSignature) {
minArgumentCount--;
}
var classType = declaration.kind === 150 /* Constructor */ ?
getDeclaredTypeOfClassOrInterface(getMergedSymbol(declaration.parent.symbol))
: undefined;
var typeParameters = classType ? classType.localTypeParameters :
declaration.typeParameters ? getTypeParametersFromDeclaration(declaration.typeParameters) :
getTypeParametersFromJSDocTemplate(declaration);
var returnType = getSignatureReturnTypeFromDeclaration(declaration, isJSConstructSignature, classType);
var typePredicate = declaration.type && declaration.type.kind === 156 /* TypePredicate */ ?
createTypePredicateFromTypePredicateNode(declaration.type) :
undefined;
links.resolvedSignature = createSignature(declaration, typeParameters, thisParameter, parameters, returnType, typePredicate, minArgumentCount, ts.hasRestParameter(declaration), hasLiteralTypes);
}
return links.resolvedSignature;
}
function getSignatureReturnTypeFromDeclaration(declaration, isJSConstructSignature, classType) {
if (isJSConstructSignature) {
return getTypeFromTypeNode(declaration.parameters[0].type);
}
else if (classType) {
return classType;
}
else if (declaration.type) {
return getTypeFromTypeNode(declaration.type);
}
if (declaration.flags & 2097152 /* JavaScriptFile */) {
var type = getReturnTypeFromJSDocComment(declaration);
if (type && type !== unknownType) {
return type;
}
}
// TypeScript 1.0 spec (April 2014):
// If only one accessor includes a type annotation, the other behaves as if it had the same type annotation.
if (declaration.kind === 151 /* GetAccessor */ && !ts.hasDynamicName(declaration)) {
var setter = ts.getDeclarationOfKind(declaration.symbol, 152 /* SetAccessor */);
return getAnnotatedAccessorType(setter);
}
if (ts.nodeIsMissing(declaration.body)) {
return anyType;
}
}
function getSignaturesOfSymbol(symbol) {
if (!symbol)
return emptyArray;
var result = [];
for (var i = 0, len = symbol.declarations.length; i < len; i++) {
var node = symbol.declarations[i];
switch (node.kind) {
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 225 /* FunctionDeclaration */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 274 /* JSDocFunctionType */:
// Don't include signature if node is the implementation of an overloaded function. A node is considered
// an implementation node if it has a body and the previous node is of the same kind and immediately
// precedes the implementation node (i.e. has the same parent and ends where the implementation starts).
if (i > 0 && node.body) {
var previous = symbol.declarations[i - 1];
if (node.parent === previous.parent && node.kind === previous.kind && node.pos === previous.end) {
break;
}
}
result.push(getSignatureFromDeclaration(node));
}
}
return result;
}
function resolveExternalModuleTypeByLiteral(name) {
var moduleSym = resolveExternalModuleName(name, name);
if (moduleSym) {
var resolvedModuleSymbol = resolveExternalModuleSymbol(moduleSym);
if (resolvedModuleSymbol) {
return getTypeOfSymbol(resolvedModuleSymbol);
}
}
return anyType;
}
function getThisTypeOfSignature(signature) {
if (signature.thisParameter) {
return getTypeOfSymbol(signature.thisParameter);
}
}
function getReturnTypeOfSignature(signature) {
if (!signature.resolvedReturnType) {
if (!pushTypeResolution(signature, 3 /* ResolvedReturnType */)) {
return unknownType;
}
var type = void 0;
if (signature.target) {
type = instantiateType(getReturnTypeOfSignature(signature.target), signature.mapper);
}
else if (signature.unionSignatures) {
type = getUnionType(ts.map(signature.unionSignatures, getReturnTypeOfSignature), /*subtypeReduction*/ true);
}
else {
type = getReturnTypeFromBody(signature.declaration);
}
if (!popTypeResolution()) {
type = anyType;
if (compilerOptions.noImplicitAny) {
var declaration = signature.declaration;
if (declaration.name) {
error(declaration.name, ts.Diagnostics._0_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions, ts.declarationNameToString(declaration.name));
}
else {
error(declaration, ts.Diagnostics.Function_implicitly_has_return_type_any_because_it_does_not_have_a_return_type_annotation_and_is_referenced_directly_or_indirectly_in_one_of_its_return_expressions);
}
}
}
signature.resolvedReturnType = type;
}
return signature.resolvedReturnType;
}
function getRestTypeOfSignature(signature) {
if (signature.hasRestParameter) {
var type = getTypeOfSymbol(ts.lastOrUndefined(signature.parameters));
if (getObjectFlags(type) & 4 /* Reference */ && type.target === globalArrayType) {
return type.typeArguments[0];
}
}
return anyType;
}
function getSignatureInstantiation(signature, typeArguments) {
var instantiations = signature.instantiations || (signature.instantiations = ts.createMap());
var id = getTypeListId(typeArguments);
return instantiations[id] || (instantiations[id] = createSignatureInstantiation(signature, typeArguments));
}
function createSignatureInstantiation(signature, typeArguments) {
return instantiateSignature(signature, createTypeMapper(signature.typeParameters, typeArguments), /*eraseTypeParameters*/ true);
}
function getErasedSignature(signature) {
if (!signature.typeParameters)
return signature;
if (!signature.erasedSignatureCache) {
signature.erasedSignatureCache = instantiateSignature(signature, createTypeEraser(signature.typeParameters), /*eraseTypeParameters*/ true);
}
return signature.erasedSignatureCache;
}
function getOrCreateTypeFromSignature(signature) {
// There are two ways to declare a construct signature, one is by declaring a class constructor
// using the constructor keyword, and the other is declaring a bare construct signature in an
// object type literal or interface (using the new keyword). Each way of declaring a constructor
// will result in a different declaration kind.
if (!signature.isolatedSignatureType) {
var isConstructor = signature.declaration.kind === 150 /* Constructor */ || signature.declaration.kind === 154 /* ConstructSignature */;
var type = createObjectType(16 /* Anonymous */);
type.members = emptySymbols;
type.properties = emptyArray;
type.callSignatures = !isConstructor ? [signature] : emptyArray;
type.constructSignatures = isConstructor ? [signature] : emptyArray;
signature.isolatedSignatureType = type;
}
return signature.isolatedSignatureType;
}
function getIndexSymbol(symbol) {
return symbol.members["__index"];
}
function getIndexDeclarationOfSymbol(symbol, kind) {
var syntaxKind = kind === 1 /* Number */ ? 132 /* NumberKeyword */ : 134 /* StringKeyword */;
var indexSymbol = getIndexSymbol(symbol);
if (indexSymbol) {
for (var _i = 0, _a = indexSymbol.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
var node = decl;
if (node.parameters.length === 1) {
var parameter = node.parameters[0];
if (parameter && parameter.type && parameter.type.kind === syntaxKind) {
return node;
}
}
}
}
return undefined;
}
function createIndexInfo(type, isReadonly, declaration) {
return { type: type, isReadonly: isReadonly, declaration: declaration };
}
function getIndexInfoOfSymbol(symbol, kind) {
var declaration = getIndexDeclarationOfSymbol(symbol, kind);
if (declaration) {
return createIndexInfo(declaration.type ? getTypeFromTypeNode(declaration.type) : anyType, (ts.getModifierFlags(declaration) & 64 /* Readonly */) !== 0, declaration);
}
return undefined;
}
function getConstraintDeclaration(type) {
return ts.getDeclarationOfKind(type.symbol, 143 /* TypeParameter */).constraint;
}
function hasConstraintReferenceTo(type, target) {
var checked;
while (type && type.flags & 16384 /* TypeParameter */ && !(type.isThisType) && !ts.contains(checked, type)) {
if (type === target) {
return true;
}
(checked || (checked = [])).push(type);
var constraintDeclaration = getConstraintDeclaration(type);
type = constraintDeclaration && getTypeFromTypeNode(constraintDeclaration);
}
return false;
}
function getConstraintOfTypeParameter(typeParameter) {
if (!typeParameter.constraint) {
if (typeParameter.target) {
var targetConstraint = getConstraintOfTypeParameter(typeParameter.target);
typeParameter.constraint = targetConstraint ? instantiateType(targetConstraint, typeParameter.mapper) : noConstraintType;
}
else {
var constraintDeclaration = getConstraintDeclaration(typeParameter);
var constraint = getTypeFromTypeNode(constraintDeclaration);
if (hasConstraintReferenceTo(constraint, typeParameter)) {
error(constraintDeclaration, ts.Diagnostics.Type_parameter_0_has_a_circular_constraint, typeToString(typeParameter));
constraint = unknownType;
}
typeParameter.constraint = constraint;
}
}
return typeParameter.constraint === noConstraintType ? undefined : typeParameter.constraint;
}
function getParentSymbolOfTypeParameter(typeParameter) {
return getSymbolOfNode(ts.getDeclarationOfKind(typeParameter.symbol, 143 /* TypeParameter */).parent);
}
function getTypeListId(types) {
var result = "";
if (types) {
var length_3 = types.length;
var i = 0;
while (i < length_3) {
var startId = types[i].id;
var count = 1;
while (i + count < length_3 && types[i + count].id === startId + count) {
count++;
}
if (result.length) {
result += ",";
}
result += startId;
if (count > 1) {
result += ":" + count;
}
i += count;
}
}
return result;
}
// This function is used to propagate certain flags when creating new object type references and union types.
// It is only necessary to do so if a constituent type might be the undefined type, the null type, the type
// of an object literal or the anyFunctionType. This is because there are operations in the type checker
// that care about the presence of such types at arbitrary depth in a containing type.
function getPropagatingFlagsOfTypes(types, excludeKinds) {
var result = 0;
for (var _i = 0, types_3 = types; _i < types_3.length; _i++) {
var type = types_3[_i];
if (!(type.flags & excludeKinds)) {
result |= type.flags;
}
}
return result & 14680064 /* PropagatingFlags */;
}
function createTypeReference(target, typeArguments) {
var id = getTypeListId(typeArguments);
var type = target.instantiations[id];
if (!type) {
type = target.instantiations[id] = createObjectType(4 /* Reference */, target.symbol);
type.flags |= typeArguments ? getPropagatingFlagsOfTypes(typeArguments, /*excludeKinds*/ 0) : 0;
type.target = target;
type.typeArguments = typeArguments;
}
return type;
}
function cloneTypeReference(source) {
var type = createType(source.flags);
type.symbol = source.symbol;
type.objectFlags = source.objectFlags;
type.target = source.target;
type.typeArguments = source.typeArguments;
return type;
}
function getTypeReferenceArity(type) {
return type.target.typeParameters ? type.target.typeParameters.length : 0;
}
// Get type from reference to class or interface
function getTypeFromClassOrInterfaceReference(node, symbol) {
var type = getDeclaredTypeOfSymbol(getMergedSymbol(symbol));
var typeParameters = type.localTypeParameters;
if (typeParameters) {
if (!node.typeArguments || node.typeArguments.length !== typeParameters.length) {
error(node, ts.Diagnostics.Generic_type_0_requires_1_type_argument_s, typeToString(type, /*enclosingDeclaration*/ undefined, 1 /* WriteArrayAsGenericType */), typeParameters.length);
return unknownType;
}
// In a type reference, the outer type parameters of the referenced class or interface are automatically
// supplied as type arguments and the type reference only specifies arguments for the local type parameters
// of the class or interface.
return createTypeReference(type, ts.concatenate(type.outerTypeParameters, ts.map(node.typeArguments, getTypeFromTypeNode)));
}
if (node.typeArguments) {
error(node, ts.Diagnostics.Type_0_is_not_generic, typeToString(type));
return unknownType;
}
return type;
}
function getTypeAliasInstantiation(symbol, typeArguments) {
var type = getDeclaredTypeOfSymbol(symbol);
var links = getSymbolLinks(symbol);
var typeParameters = links.typeParameters;
var id = getTypeListId(typeArguments);
return links.instantiations[id] || (links.instantiations[id] = instantiateTypeNoAlias(type, createTypeMapper(typeParameters, typeArguments)));
}
// Get type from reference to type alias. When a type alias is generic, the declared type of the type alias may include
// references to the type parameters of the alias. We replace those with the actual type arguments by instantiating the
// declared type. Instantiations are cached using the type identities of the type arguments as the key.
function getTypeFromTypeAliasReference(node, symbol) {
var type = getDeclaredTypeOfSymbol(symbol);
var typeParameters = getSymbolLinks(symbol).typeParameters;
if (typeParameters) {
if (!node.typeArguments || node.typeArguments.length !== typeParameters.length) {
error(node, ts.Diagnostics.Generic_type_0_requires_1_type_argument_s, symbolToString(symbol), typeParameters.length);
return unknownType;
}
var typeArguments = ts.map(node.typeArguments, getTypeFromTypeNode);
return getTypeAliasInstantiation(symbol, typeArguments);
}
if (node.typeArguments) {
error(node, ts.Diagnostics.Type_0_is_not_generic, symbolToString(symbol));
return unknownType;
}
return type;
}
// Get type from reference to named type that cannot be generic (enum or type parameter)
function getTypeFromNonGenericTypeReference(node, symbol) {
if (node.typeArguments) {
error(node, ts.Diagnostics.Type_0_is_not_generic, symbolToString(symbol));
return unknownType;
}
return getDeclaredTypeOfSymbol(symbol);
}
function getTypeReferenceName(node) {
switch (node.kind) {
case 157 /* TypeReference */:
return node.typeName;
case 272 /* JSDocTypeReference */:
return node.name;
case 199 /* ExpressionWithTypeArguments */:
// We only support expressions that are simple qualified names. For other
// expressions this produces undefined.
var expr = node.expression;
if (ts.isEntityNameExpression(expr)) {
return expr;
}
}
return undefined;
}
function resolveTypeReferenceName(typeReferenceName) {
if (!typeReferenceName) {
return unknownSymbol;
}
return resolveEntityName(typeReferenceName, 793064 /* Type */) || unknownSymbol;
}
function getTypeReferenceType(node, symbol) {
if (symbol === unknownSymbol) {
return unknownType;
}
if (symbol.flags & (32 /* Class */ | 64 /* Interface */)) {
return getTypeFromClassOrInterfaceReference(node, symbol);
}
if (symbol.flags & 524288 /* TypeAlias */) {
return getTypeFromTypeAliasReference(node, symbol);
}
if (symbol.flags & 107455 /* Value */ && node.kind === 272 /* JSDocTypeReference */) {
// A JSDocTypeReference may have resolved to a value (as opposed to a type). In
// that case, the type of this reference is just the type of the value we resolved
// to.
return getTypeOfSymbol(symbol);
}
return getTypeFromNonGenericTypeReference(node, symbol);
}
function getTypeFromTypeReference(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
var symbol = void 0;
var type = void 0;
if (node.kind === 272 /* JSDocTypeReference */) {
var typeReferenceName = getTypeReferenceName(node);
symbol = resolveTypeReferenceName(typeReferenceName);
type = getTypeReferenceType(node, symbol);
}
else {
// We only support expressions that are simple qualified names. For other expressions this produces undefined.
var typeNameOrExpression = node.kind === 157 /* TypeReference */
? node.typeName
: ts.isEntityNameExpression(node.expression)
? node.expression
: undefined;
symbol = typeNameOrExpression && resolveEntityName(typeNameOrExpression, 793064 /* Type */) || unknownSymbol;
type = symbol === unknownSymbol ? unknownType :
symbol.flags & (32 /* Class */ | 64 /* Interface */) ? getTypeFromClassOrInterfaceReference(node, symbol) :
symbol.flags & 524288 /* TypeAlias */ ? getTypeFromTypeAliasReference(node, symbol) :
getTypeFromNonGenericTypeReference(node, symbol);
}
// Cache both the resolved symbol and the resolved type. The resolved symbol is needed in when we check the
// type reference in checkTypeReferenceOrExpressionWithTypeArguments.
links.resolvedSymbol = symbol;
links.resolvedType = type;
}
return links.resolvedType;
}
function getTypeFromTypeQueryNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
// TypeScript 1.0 spec (April 2014): 3.6.3
// The expression is processed as an identifier expression (section 4.3)
// or property access expression(section 4.10),
// the widened type(section 3.9) of which becomes the result.
links.resolvedType = getWidenedType(checkExpression(node.exprName));
}
return links.resolvedType;
}
function getTypeOfGlobalSymbol(symbol, arity) {
function getTypeDeclaration(symbol) {
var declarations = symbol.declarations;
for (var _i = 0, declarations_3 = declarations; _i < declarations_3.length; _i++) {
var declaration = declarations_3[_i];
switch (declaration.kind) {
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 229 /* EnumDeclaration */:
return declaration;
}
}
}
if (!symbol) {
return arity ? emptyGenericType : emptyObjectType;
}
var type = getDeclaredTypeOfSymbol(symbol);
if (!(type.flags & 32768 /* Object */)) {
error(getTypeDeclaration(symbol), ts.Diagnostics.Global_type_0_must_be_a_class_or_interface_type, symbol.name);
return arity ? emptyGenericType : emptyObjectType;
}
if ((type.typeParameters ? type.typeParameters.length : 0) !== arity) {
error(getTypeDeclaration(symbol), ts.Diagnostics.Global_type_0_must_have_1_type_parameter_s, symbol.name, arity);
return arity ? emptyGenericType : emptyObjectType;
}
return type;
}
function getGlobalValueSymbol(name) {
return getGlobalSymbol(name, 107455 /* Value */, ts.Diagnostics.Cannot_find_global_value_0);
}
function getGlobalTypeSymbol(name) {
return getGlobalSymbol(name, 793064 /* Type */, ts.Diagnostics.Cannot_find_global_type_0);
}
function getGlobalSymbol(name, meaning, diagnostic) {
return resolveName(undefined, name, meaning, diagnostic, name);
}
function getGlobalType(name, arity) {
if (arity === void 0) { arity = 0; }
return getTypeOfGlobalSymbol(getGlobalTypeSymbol(name), arity);
}
/**
* Returns a type that is inside a namespace at the global scope, e.g.
* getExportedTypeFromNamespace('JSX', 'Element') returns the JSX.Element type
*/
function getExportedTypeFromNamespace(namespace, name) {
var namespaceSymbol = getGlobalSymbol(namespace, 1920 /* Namespace */, /*diagnosticMessage*/ undefined);
var typeSymbol = namespaceSymbol && getSymbol(namespaceSymbol.exports, name, 793064 /* Type */);
return typeSymbol && getDeclaredTypeOfSymbol(typeSymbol);
}
/**
* Creates a TypeReference for a generic `TypedPropertyDescriptor<T>`.
*/
function createTypedPropertyDescriptorType(propertyType) {
var globalTypedPropertyDescriptorType = getGlobalTypedPropertyDescriptorType();
return globalTypedPropertyDescriptorType !== emptyGenericType
? createTypeReference(globalTypedPropertyDescriptorType, [propertyType])
: emptyObjectType;
}
/**
* Instantiates a global type that is generic with some element type, and returns that instantiation.
*/
function createTypeFromGenericGlobalType(genericGlobalType, typeArguments) {
return genericGlobalType !== emptyGenericType ? createTypeReference(genericGlobalType, typeArguments) : emptyObjectType;
}
function createIterableType(elementType) {
return createTypeFromGenericGlobalType(getGlobalIterableType(), [elementType]);
}
function createIterableIteratorType(elementType) {
return createTypeFromGenericGlobalType(getGlobalIterableIteratorType(), [elementType]);
}
function createArrayType(elementType) {
return createTypeFromGenericGlobalType(globalArrayType, [elementType]);
}
function getTypeFromArrayTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = createArrayType(getTypeFromTypeNode(node.elementType));
}
return links.resolvedType;
}
// We represent tuple types as type references to synthesized generic interface types created by
// this function. The types are of the form:
//
// interface Tuple<T0, T1, T2, ...> extends Array<T0 | T1 | T2 | ...> { 0: T0, 1: T1, 2: T2, ... }
//
// Note that the generic type created by this function has no symbol associated with it. The same
// is true for each of the synthesized type parameters.
function createTupleTypeOfArity(arity) {
var typeParameters = [];
var properties = [];
for (var i = 0; i < arity; i++) {
var typeParameter = createType(16384 /* TypeParameter */);
typeParameters.push(typeParameter);
var property = createSymbol(4 /* Property */ | 67108864 /* Transient */, "" + i);
property.type = typeParameter;
properties.push(property);
}
var type = createObjectType(8 /* Tuple */ | 4 /* Reference */);
type.typeParameters = typeParameters;
type.outerTypeParameters = undefined;
type.localTypeParameters = typeParameters;
type.instantiations = ts.createMap();
type.instantiations[getTypeListId(type.typeParameters)] = type;
type.target = type;
type.typeArguments = type.typeParameters;
type.thisType = createType(16384 /* TypeParameter */);
type.thisType.isThisType = true;
type.thisType.constraint = type;
type.declaredProperties = properties;
type.declaredCallSignatures = emptyArray;
type.declaredConstructSignatures = emptyArray;
type.declaredStringIndexInfo = undefined;
type.declaredNumberIndexInfo = undefined;
return type;
}
function getTupleTypeOfArity(arity) {
return tupleTypes[arity] || (tupleTypes[arity] = createTupleTypeOfArity(arity));
}
function createTupleType(elementTypes) {
return createTypeReference(getTupleTypeOfArity(elementTypes.length), elementTypes);
}
function getTypeFromTupleTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = createTupleType(ts.map(node.elementTypes, getTypeFromTypeNode));
}
return links.resolvedType;
}
function binarySearchTypes(types, type) {
var low = 0;
var high = types.length - 1;
var typeId = type.id;
while (low <= high) {
var middle = low + ((high - low) >> 1);
var id = types[middle].id;
if (id === typeId) {
return middle;
}
else if (id > typeId) {
high = middle - 1;
}
else {
low = middle + 1;
}
}
return ~low;
}
function containsType(types, type) {
return binarySearchTypes(types, type) >= 0;
}
function addTypeToUnion(typeSet, type) {
var flags = type.flags;
if (flags & 65536 /* Union */) {
addTypesToUnion(typeSet, type.types);
}
else if (flags & 1 /* Any */) {
typeSet.containsAny = true;
}
else if (!strictNullChecks && flags & 6144 /* Nullable */) {
if (flags & 2048 /* Undefined */)
typeSet.containsUndefined = true;
if (flags & 4096 /* Null */)
typeSet.containsNull = true;
if (!(flags & 2097152 /* ContainsWideningType */))
typeSet.containsNonWideningType = true;
}
else if (!(flags & 8192 /* Never */)) {
if (flags & 2 /* String */)
typeSet.containsString = true;
if (flags & 4 /* Number */)
typeSet.containsNumber = true;
if (flags & 96 /* StringOrNumberLiteral */)
typeSet.containsStringOrNumberLiteral = true;
var len = typeSet.length;
var index = len && type.id > typeSet[len - 1].id ? ~len : binarySearchTypes(typeSet, type);
if (index < 0) {
if (!(flags & 32768 /* Object */ && type.objectFlags & 16 /* Anonymous */ &&
type.symbol && type.symbol.flags & (16 /* Function */ | 8192 /* Method */) && containsIdenticalType(typeSet, type))) {
typeSet.splice(~index, 0, type);
}
}
}
}
// Add the given types to the given type set. Order is preserved, duplicates are removed,
// and nested types of the given kind are flattened into the set.
function addTypesToUnion(typeSet, types) {
for (var _i = 0, types_4 = types; _i < types_4.length; _i++) {
var type = types_4[_i];
addTypeToUnion(typeSet, type);
}
}
function containsIdenticalType(types, type) {
for (var _i = 0, types_5 = types; _i < types_5.length; _i++) {
var t = types_5[_i];
if (isTypeIdenticalTo(t, type)) {
return true;
}
}
return false;
}
function isSubtypeOfAny(candidate, types) {
for (var i = 0, len = types.length; i < len; i++) {
if (candidate !== types[i] && isTypeSubtypeOf(candidate, types[i])) {
return true;
}
}
return false;
}
function isSetOfLiteralsFromSameEnum(types) {
var first = types[0];
if (first.flags & 256 /* EnumLiteral */) {
var firstEnum = getParentOfSymbol(first.symbol);
for (var i = 1; i < types.length; i++) {
var other = types[i];
if (!(other.flags & 256 /* EnumLiteral */) || (firstEnum !== getParentOfSymbol(other.symbol))) {
return false;
}
}
return true;
}
return false;
}
function removeSubtypes(types) {
if (types.length === 0 || isSetOfLiteralsFromSameEnum(types)) {
return;
}
var i = types.length;
while (i > 0) {
i--;
if (isSubtypeOfAny(types[i], types)) {
ts.orderedRemoveItemAt(types, i);
}
}
}
function removeRedundantLiteralTypes(types) {
var i = types.length;
while (i > 0) {
i--;
var t = types[i];
var remove = t.flags & 32 /* StringLiteral */ && types.containsString ||
t.flags & 64 /* NumberLiteral */ && types.containsNumber ||
t.flags & 96 /* StringOrNumberLiteral */ && t.flags & 1048576 /* FreshLiteral */ && containsType(types, t.regularType);
if (remove) {
ts.orderedRemoveItemAt(types, i);
}
}
}
// We sort and deduplicate the constituent types based on object identity. If the subtypeReduction
// flag is specified we also reduce the constituent type set to only include types that aren't subtypes
// of other types. Subtype reduction is expensive for large union types and is possible only when union
// types are known not to circularly reference themselves (as is the case with union types created by
// expression constructs such as array literals and the || and ?: operators). Named types can
// circularly reference themselves and therefore cannot be subtype reduced during their declaration.
// For example, "type Item = string | (() => Item" is a named type that circularly references itself.
function getUnionType(types, subtypeReduction, aliasSymbol, aliasTypeArguments) {
if (types.length === 0) {
return neverType;
}
if (types.length === 1) {
return types[0];
}
var typeSet = [];
addTypesToUnion(typeSet, types);
if (typeSet.containsAny) {
return anyType;
}
if (subtypeReduction) {
removeSubtypes(typeSet);
}
else if (typeSet.containsStringOrNumberLiteral) {
removeRedundantLiteralTypes(typeSet);
}
if (typeSet.length === 0) {
return typeSet.containsNull ? typeSet.containsNonWideningType ? nullType : nullWideningType :
typeSet.containsUndefined ? typeSet.containsNonWideningType ? undefinedType : undefinedWideningType :
neverType;
}
return getUnionTypeFromSortedList(typeSet, aliasSymbol, aliasTypeArguments);
}
// This function assumes the constituent type list is sorted and deduplicated.
function getUnionTypeFromSortedList(types, aliasSymbol, aliasTypeArguments) {
if (types.length === 0) {
return neverType;
}
if (types.length === 1) {
return types[0];
}
var id = getTypeListId(types);
var type = unionTypes[id];
if (!type) {
var propagatedFlags = getPropagatingFlagsOfTypes(types, /*excludeKinds*/ 6144 /* Nullable */);
type = unionTypes[id] = createType(65536 /* Union */ | propagatedFlags);
type.types = types;
type.aliasSymbol = aliasSymbol;
type.aliasTypeArguments = aliasTypeArguments;
}
return type;
}
function getTypeFromUnionTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = getUnionType(ts.map(node.types, getTypeFromTypeNode), /*subtypeReduction*/ false, getAliasSymbolForTypeNode(node), getAliasTypeArgumentsForTypeNode(node));
}
return links.resolvedType;
}
function addTypeToIntersection(typeSet, type) {
if (type.flags & 131072 /* Intersection */) {
addTypesToIntersection(typeSet, type.types);
}
else if (type.flags & 1 /* Any */) {
typeSet.containsAny = true;
}
else if (!(type.flags & 8192 /* Never */) && (strictNullChecks || !(type.flags & 6144 /* Nullable */)) && !ts.contains(typeSet, type)) {
typeSet.push(type);
}
}
// Add the given types to the given type set. Order is preserved, duplicates are removed,
// and nested types of the given kind are flattened into the set.
function addTypesToIntersection(typeSet, types) {
for (var _i = 0, types_6 = types; _i < types_6.length; _i++) {
var type = types_6[_i];
addTypeToIntersection(typeSet, type);
}
}
// We normalize combinations of intersection and union types based on the distributive property of the '&'
// operator. Specifically, because X & (A | B) is equivalent to X & A | X & B, we can transform intersection
// types with union type constituents into equivalent union types with intersection type constituents and
// effectively ensure that union types are always at the top level in type representations.
//
// We do not perform structural deduplication on intersection types. Intersection types are created only by the &
// type operator and we can't reduce those because we want to support recursive intersection types. For example,
// a type alias of the form "type List<T> = T & { next: List<T> }" cannot be reduced during its declaration.
// Also, unlike union types, the order of the constituent types is preserved in order that overload resolution
// for intersections of types with signatures can be deterministic.
function getIntersectionType(types, aliasSymbol, aliasTypeArguments) {
if (types.length === 0) {
return emptyObjectType;
}
var _loop_2 = function (i) {
var type_1 = types[i];
if (type_1.flags & 65536 /* Union */) {
return { value: getUnionType(ts.map(type_1.types, function (t) { return getIntersectionType(ts.replaceElement(types, i, t)); }),
/*subtypeReduction*/ false, aliasSymbol, aliasTypeArguments) };
}
};
for (var i = 0; i < types.length; i++) {
var state_2 = _loop_2(i);
if (typeof state_2 === "object")
return state_2.value;
}
var typeSet = [];
addTypesToIntersection(typeSet, types);
if (typeSet.containsAny) {
return anyType;
}
if (typeSet.length === 1) {
return typeSet[0];
}
var id = getTypeListId(typeSet);
var type = intersectionTypes[id];
if (!type) {
var propagatedFlags = getPropagatingFlagsOfTypes(typeSet, /*excludeKinds*/ 6144 /* Nullable */);
type = intersectionTypes[id] = createType(131072 /* Intersection */ | propagatedFlags);
type.types = typeSet;
type.aliasSymbol = aliasSymbol;
type.aliasTypeArguments = aliasTypeArguments;
}
return type;
}
function getTypeFromIntersectionTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = getIntersectionType(ts.map(node.types, getTypeFromTypeNode), getAliasSymbolForTypeNode(node), getAliasTypeArgumentsForTypeNode(node));
}
return links.resolvedType;
}
function getIndexTypeForTypeParameter(type) {
if (!type.resolvedIndexType) {
type.resolvedIndexType = createType(262144 /* Index */);
type.resolvedIndexType.type = type;
}
return type.resolvedIndexType;
}
function getLiteralTypeFromPropertyName(prop) {
return getDeclarationModifierFlagsFromSymbol(prop) & 24 /* NonPublicAccessibilityModifier */ || ts.startsWith(prop.name, "__@") ?
neverType :
getLiteralTypeForText(32 /* StringLiteral */, ts.unescapeIdentifier(prop.name));
}
function getLiteralTypeFromPropertyNames(type) {
return getUnionType(ts.map(getPropertiesOfType(type), getLiteralTypeFromPropertyName));
}
function getIndexType(type) {
return type.flags & 16384 /* TypeParameter */ ? getIndexTypeForTypeParameter(type) :
type.flags & 1 /* Any */ || getIndexInfoOfType(type, 0 /* String */) ? stringOrNumberType :
getIndexInfoOfType(type, 1 /* Number */) ? getUnionType([numberType, getLiteralTypeFromPropertyNames(type)]) :
getLiteralTypeFromPropertyNames(type);
}
function getTypeFromTypeOperatorNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = getIndexType(getTypeFromTypeNode(node.type));
}
return links.resolvedType;
}
function createIndexedAccessType(objectType, indexType) {
var type = createType(524288 /* IndexedAccess */);
type.objectType = objectType;
type.indexType = indexType;
return type;
}
function getIndexedAccessTypeForTypeParameter(objectType, indexType) {
var indexedAccessTypes = indexType.resolvedIndexedAccessTypes || (indexType.resolvedIndexedAccessTypes = []);
return indexedAccessTypes[objectType.id] || (indexedAccessTypes[objectType.id] = createIndexedAccessType(objectType, indexType));
}
function getPropertyTypeForIndexType(objectType, indexType, accessNode, cacheSymbol) {
var accessExpression = accessNode && accessNode.kind === 178 /* ElementAccessExpression */ ? accessNode : undefined;
var propName = indexType.flags & (32 /* StringLiteral */ | 64 /* NumberLiteral */ | 256 /* EnumLiteral */) ?
indexType.text :
accessExpression && checkThatExpressionIsProperSymbolReference(accessExpression.argumentExpression, indexType, /*reportError*/ false) ?
ts.getPropertyNameForKnownSymbolName(accessExpression.argumentExpression.name.text) :
undefined;
if (propName) {
var prop = getPropertyOfType(objectType, propName);
if (prop) {
if (accessExpression) {
if (ts.isAssignmentTarget(accessExpression) && (isReferenceToReadonlyEntity(accessExpression, prop) || isReferenceThroughNamespaceImport(accessExpression))) {
error(accessExpression.argumentExpression, ts.Diagnostics.Cannot_assign_to_0_because_it_is_a_constant_or_a_read_only_property, symbolToString(prop));
return unknownType;
}
if (cacheSymbol) {
getNodeLinks(accessNode).resolvedSymbol = prop;
}
}
return getTypeOfSymbol(prop);
}
}
if (isTypeAnyOrAllConstituentTypesHaveKind(indexType, 34 /* StringLike */ | 340 /* NumberLike */ | 512 /* ESSymbol */)) {
if (isTypeAny(objectType)) {
return anyType;
}
var indexInfo = isTypeAnyOrAllConstituentTypesHaveKind(indexType, 340 /* NumberLike */) && getIndexInfoOfType(objectType, 1 /* Number */) ||
getIndexInfoOfType(objectType, 0 /* String */) ||
undefined;
if (indexInfo) {
if (accessExpression && ts.isAssignmentTarget(accessExpression) && indexInfo.isReadonly) {
error(accessExpression, ts.Diagnostics.Index_signature_in_type_0_only_permits_reading, typeToString(objectType));
return unknownType;
}
return indexInfo.type;
}
if (accessExpression && !isConstEnumObjectType(objectType)) {
if (compilerOptions.noImplicitAny && !compilerOptions.suppressImplicitAnyIndexErrors) {
if (getIndexTypeOfType(objectType, 1 /* Number */)) {
error(accessExpression.argumentExpression, ts.Diagnostics.Element_implicitly_has_an_any_type_because_index_expression_is_not_of_type_number);
}
else {
error(accessExpression, ts.Diagnostics.Element_implicitly_has_an_any_type_because_type_0_has_no_index_signature, typeToString(objectType));
}
}
return anyType;
}
}
if (accessNode) {
var indexNode = accessNode.kind === 178 /* ElementAccessExpression */ ? accessNode.argumentExpression : accessNode.indexType;
if (indexType.flags & (32 /* StringLiteral */ | 64 /* NumberLiteral */)) {
error(indexNode, ts.Diagnostics.Property_0_does_not_exist_on_type_1, indexType.text, typeToString(objectType));
}
else if (indexType.flags & (2 /* String */ | 4 /* Number */)) {
error(indexNode, ts.Diagnostics.Type_0_has_no_matching_index_signature_for_type_1, typeToString(objectType), typeToString(indexType));
}
else {
error(indexNode, ts.Diagnostics.Type_0_cannot_be_used_as_an_index_type, typeToString(indexType));
}
}
return unknownType;
}
function getIndexedAccessType(objectType, indexType, accessNode) {
if (indexType.flags & 16384 /* TypeParameter */) {
if (accessNode && !isTypeAssignableTo(getConstraintOfTypeParameter(indexType) || emptyObjectType, getIndexType(objectType))) {
error(accessNode, ts.Diagnostics.Type_0_is_not_constrained_to_keyof_1, typeToString(indexType), typeToString(objectType));
return unknownType;
}
return getIndexedAccessTypeForTypeParameter(objectType, indexType);
}
var apparentType = getApparentType(objectType);
if (indexType.flags & 65536 /* Union */ && !(indexType.flags & 8190 /* Primitive */)) {
var propTypes = [];
for (var _i = 0, _a = indexType.types; _i < _a.length; _i++) {
var t = _a[_i];
var propType = getPropertyTypeForIndexType(apparentType, t, accessNode, /*cacheSymbol*/ false);
if (propType === unknownType) {
return unknownType;
}
propTypes.push(propType);
}
return getUnionType(propTypes);
}
return getPropertyTypeForIndexType(apparentType, indexType, accessNode, /*cacheSymbol*/ true);
}
function getTypeFromIndexedAccessTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = getIndexedAccessType(getTypeFromTypeNode(node.objectType), getTypeFromTypeNode(node.indexType), node);
}
return links.resolvedType;
}
function getTypeFromMappedTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
var type = createObjectType(32 /* Mapped */, node.symbol);
type.declaration = node;
type.aliasSymbol = getAliasSymbolForTypeNode(node);
type.aliasTypeArguments = getAliasTypeArgumentsForTypeNode(node);
links.resolvedType = type;
}
return links.resolvedType;
}
function getTypeFromTypeLiteralOrFunctionOrConstructorTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
// Deferred resolution of members is handled by resolveObjectTypeMembers
var aliasSymbol = getAliasSymbolForTypeNode(node);
if (ts.isEmpty(node.symbol.members) && !aliasSymbol) {
links.resolvedType = emptyTypeLiteralType;
}
else {
var type = createObjectType(16 /* Anonymous */, node.symbol);
type.aliasSymbol = aliasSymbol;
type.aliasTypeArguments = getAliasTypeArgumentsForTypeNode(node);
links.resolvedType = type;
}
}
return links.resolvedType;
}
function getAliasSymbolForTypeNode(node) {
return node.parent.kind === 228 /* TypeAliasDeclaration */ ? getSymbolOfNode(node.parent) : undefined;
}
function getAliasTypeArgumentsForTypeNode(node) {
var symbol = getAliasSymbolForTypeNode(node);
return symbol ? getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(symbol) : undefined;
}
/**
* Since the source of spread types are object literals, which are not binary,
* this function should be called in a left folding style, with left = previous result of getSpreadType
* and right = the new element to be spread.
*/
function getSpreadType(left, right, isFromObjectLiteral) {
ts.Debug.assert(!!(left.flags & (32768 /* Object */ | 1 /* Any */)) && !!(right.flags & (32768 /* Object */ | 1 /* Any */)), "Only object types may be spread.");
if (left.flags & 1 /* Any */ || right.flags & 1 /* Any */) {
return anyType;
}
var members = ts.createMap();
var skippedPrivateMembers = ts.createMap();
var stringIndexInfo;
var numberIndexInfo;
if (left === emptyObjectType) {
// for the first spread element, left === emptyObjectType, so take the right's string indexer
stringIndexInfo = getIndexInfoOfType(right, 0 /* String */);
numberIndexInfo = getIndexInfoOfType(right, 1 /* Number */);
}
else {
stringIndexInfo = unionSpreadIndexInfos(getIndexInfoOfType(left, 0 /* String */), getIndexInfoOfType(right, 0 /* String */));
numberIndexInfo = unionSpreadIndexInfos(getIndexInfoOfType(left, 1 /* Number */), getIndexInfoOfType(right, 1 /* Number */));
}
for (var _i = 0, _a = getPropertiesOfType(right); _i < _a.length; _i++) {
var rightProp = _a[_i];
// we approximate own properties as non-methods plus methods that are inside the object literal
var isOwnProperty = !(rightProp.flags & 8192 /* Method */) || isFromObjectLiteral;
var isSetterWithoutGetter = rightProp.flags & 65536 /* SetAccessor */ && !(rightProp.flags & 32768 /* GetAccessor */);
if (getDeclarationModifierFlagsFromSymbol(rightProp) & (8 /* Private */ | 16 /* Protected */)) {
skippedPrivateMembers[rightProp.name] = true;
}
else if (isOwnProperty && !isSetterWithoutGetter) {
members[rightProp.name] = rightProp;
}
}
for (var _b = 0, _c = getPropertiesOfType(left); _b < _c.length; _b++) {
var leftProp = _c[_b];
if (leftProp.flags & 65536 /* SetAccessor */ && !(leftProp.flags & 32768 /* GetAccessor */)
|| leftProp.name in skippedPrivateMembers) {
continue;
}
if (leftProp.name in members) {
var rightProp = members[leftProp.name];
var rightType = getTypeOfSymbol(rightProp);
if (maybeTypeOfKind(rightType, 2048 /* Undefined */) || rightProp.flags & 536870912 /* Optional */) {
var declarations = ts.concatenate(leftProp.declarations, rightProp.declarations);
var flags = 4 /* Property */ | 67108864 /* Transient */ | (leftProp.flags & 536870912 /* Optional */);
var result = createSymbol(flags, leftProp.name);
result.type = getUnionType([getTypeOfSymbol(leftProp), getTypeWithFacts(rightType, 131072 /* NEUndefined */)]);
result.leftSpread = leftProp;
result.rightSpread = rightProp;
result.declarations = declarations;
result.isReadonly = isReadonlySymbol(leftProp) || isReadonlySymbol(rightProp);
members[leftProp.name] = result;
}
}
else {
members[leftProp.name] = leftProp;
}
}
return createAnonymousType(undefined, members, emptyArray, emptyArray, stringIndexInfo, numberIndexInfo);
}
function createLiteralType(flags, text) {
var type = createType(flags);
type.text = text;
return type;
}
function getFreshTypeOfLiteralType(type) {
if (type.flags & 96 /* StringOrNumberLiteral */ && !(type.flags & 1048576 /* FreshLiteral */)) {
if (!type.freshType) {
var freshType = createLiteralType(type.flags | 1048576 /* FreshLiteral */, type.text);
freshType.regularType = type;
type.freshType = freshType;
}
return type.freshType;
}
return type;
}
function getRegularTypeOfLiteralType(type) {
return type.flags & 96 /* StringOrNumberLiteral */ && type.flags & 1048576 /* FreshLiteral */ ? type.regularType : type;
}
function getLiteralTypeForText(flags, text) {
var map = flags & 32 /* StringLiteral */ ? stringLiteralTypes : numericLiteralTypes;
return map[text] || (map[text] = createLiteralType(flags, text));
}
function getTypeFromLiteralTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = getRegularTypeOfLiteralType(checkExpression(node.literal));
}
return links.resolvedType;
}
function getTypeFromJSDocVariadicType(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
var type = getTypeFromTypeNode(node.type);
links.resolvedType = type ? createArrayType(type) : unknownType;
}
return links.resolvedType;
}
function getTypeFromJSDocTupleType(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
var types = ts.map(node.types, getTypeFromTypeNode);
links.resolvedType = createTupleType(types);
}
return links.resolvedType;
}
function getThisType(node) {
var container = ts.getThisContainer(node, /*includeArrowFunctions*/ false);
var parent = container && container.parent;
if (parent && (ts.isClassLike(parent) || parent.kind === 227 /* InterfaceDeclaration */)) {
if (!(ts.getModifierFlags(container) & 32 /* Static */) &&
(container.kind !== 150 /* Constructor */ || ts.isNodeDescendantOf(node, container.body))) {
return getDeclaredTypeOfClassOrInterface(getSymbolOfNode(parent)).thisType;
}
}
error(node, ts.Diagnostics.A_this_type_is_available_only_in_a_non_static_member_of_a_class_or_interface);
return unknownType;
}
function getTypeFromThisTypeNode(node) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
links.resolvedType = getThisType(node);
}
return links.resolvedType;
}
function getTypeFromTypeNode(node) {
switch (node.kind) {
case 118 /* AnyKeyword */:
case 263 /* JSDocAllType */:
case 264 /* JSDocUnknownType */:
return anyType;
case 134 /* StringKeyword */:
return stringType;
case 132 /* NumberKeyword */:
return numberType;
case 121 /* BooleanKeyword */:
return booleanType;
case 135 /* SymbolKeyword */:
return esSymbolType;
case 104 /* VoidKeyword */:
return voidType;
case 137 /* UndefinedKeyword */:
return undefinedType;
case 94 /* NullKeyword */:
return nullType;
case 129 /* NeverKeyword */:
return neverType;
case 288 /* JSDocNullKeyword */:
return nullType;
case 289 /* JSDocUndefinedKeyword */:
return undefinedType;
case 290 /* JSDocNeverKeyword */:
return neverType;
case 167 /* ThisType */:
case 98 /* ThisKeyword */:
return getTypeFromThisTypeNode(node);
case 171 /* LiteralType */:
return getTypeFromLiteralTypeNode(node);
case 287 /* JSDocLiteralType */:
return getTypeFromLiteralTypeNode(node.literal);
case 157 /* TypeReference */:
case 272 /* JSDocTypeReference */:
return getTypeFromTypeReference(node);
case 156 /* TypePredicate */:
return booleanType;
case 199 /* ExpressionWithTypeArguments */:
return getTypeFromTypeReference(node);
case 160 /* TypeQuery */:
return getTypeFromTypeQueryNode(node);
case 162 /* ArrayType */:
case 265 /* JSDocArrayType */:
return getTypeFromArrayTypeNode(node);
case 163 /* TupleType */:
return getTypeFromTupleTypeNode(node);
case 164 /* UnionType */:
case 266 /* JSDocUnionType */:
return getTypeFromUnionTypeNode(node);
case 165 /* IntersectionType */:
return getTypeFromIntersectionTypeNode(node);
case 166 /* ParenthesizedType */:
case 268 /* JSDocNullableType */:
case 269 /* JSDocNonNullableType */:
case 276 /* JSDocConstructorType */:
case 277 /* JSDocThisType */:
case 273 /* JSDocOptionalType */:
return getTypeFromTypeNode(node.type);
case 270 /* JSDocRecordType */:
return getTypeFromTypeNode(node.literal);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 161 /* TypeLiteral */:
case 286 /* JSDocTypeLiteral */:
case 274 /* JSDocFunctionType */:
return getTypeFromTypeLiteralOrFunctionOrConstructorTypeNode(node);
case 168 /* TypeOperator */:
return getTypeFromTypeOperatorNode(node);
case 169 /* IndexedAccessType */:
return getTypeFromIndexedAccessTypeNode(node);
case 170 /* MappedType */:
return getTypeFromMappedTypeNode(node);
// This function assumes that an identifier or qualified name is a type expression
// Callers should first ensure this by calling isTypeNode
case 70 /* Identifier */:
case 141 /* QualifiedName */:
var symbol = getSymbolAtLocation(node);
return symbol && getDeclaredTypeOfSymbol(symbol);
case 267 /* JSDocTupleType */:
return getTypeFromJSDocTupleType(node);
case 275 /* JSDocVariadicType */:
return getTypeFromJSDocVariadicType(node);
default:
return unknownType;
}
}
function instantiateList(items, mapper, instantiator) {
if (items && items.length) {
var result = [];
for (var _i = 0, items_1 = items; _i < items_1.length; _i++) {
var v = items_1[_i];
result.push(instantiator(v, mapper));
}
return result;
}
return items;
}
function instantiateTypes(types, mapper) {
return instantiateList(types, mapper, instantiateType);
}
function instantiateSignatures(signatures, mapper) {
return instantiateList(signatures, mapper, instantiateSignature);
}
function instantiateCached(type, mapper, instantiator) {
var instantiations = mapper.instantiations || (mapper.instantiations = []);
return instantiations[type.id] || (instantiations[type.id] = instantiator(type, mapper));
}
function createUnaryTypeMapper(source, target) {
return function (t) { return t === source ? target : t; };
}
function createBinaryTypeMapper(source1, target1, source2, target2) {
return function (t) { return t === source1 ? target1 : t === source2 ? target2 : t; };
}
function createArrayTypeMapper(sources, targets) {
return function (t) {
for (var i = 0; i < sources.length; i++) {
if (t === sources[i]) {
return targets ? targets[i] : anyType;
}
}
return t;
};
}
function createTypeMapper(sources, targets) {
var count = sources.length;
var mapper = count == 1 ? createUnaryTypeMapper(sources[0], targets ? targets[0] : anyType) :
count == 2 ? createBinaryTypeMapper(sources[0], targets ? targets[0] : anyType, sources[1], targets ? targets[1] : anyType) :
createArrayTypeMapper(sources, targets);
mapper.mappedTypes = sources;
return mapper;
}
function createTypeEraser(sources) {
return createTypeMapper(sources, undefined);
}
function getInferenceMapper(context) {
if (!context.mapper) {
var mapper = function (t) {
var typeParameters = context.signature.typeParameters;
for (var i = 0; i < typeParameters.length; i++) {
if (t === typeParameters[i]) {
context.inferences[i].isFixed = true;
return getInferredType(context, i);
}
}
return t;
};
mapper.mappedTypes = context.signature.typeParameters;
mapper.context = context;
context.mapper = mapper;
}
return context.mapper;
}
function identityMapper(type) {
return type;
}
function combineTypeMappers(mapper1, mapper2) {
var mapper = function (t) { return instantiateType(mapper1(t), mapper2); };
mapper.mappedTypes = mapper1.mappedTypes;
return mapper;
}
function cloneTypeParameter(typeParameter) {
var result = createType(16384 /* TypeParameter */);
result.symbol = typeParameter.symbol;
result.target = typeParameter;
return result;
}
function cloneTypePredicate(predicate, mapper) {
if (ts.isIdentifierTypePredicate(predicate)) {
return {
kind: 1 /* Identifier */,
parameterName: predicate.parameterName,
parameterIndex: predicate.parameterIndex,
type: instantiateType(predicate.type, mapper)
};
}
else {
return {
kind: 0 /* This */,
type: instantiateType(predicate.type, mapper)
};
}
}
function instantiateSignature(signature, mapper, eraseTypeParameters) {
var freshTypeParameters;
var freshTypePredicate;
if (signature.typeParameters && !eraseTypeParameters) {
// First create a fresh set of type parameters, then include a mapping from the old to the
// new type parameters in the mapper function. Finally store this mapper in the new type
// parameters such that we can use it when instantiating constraints.
freshTypeParameters = ts.map(signature.typeParameters, cloneTypeParameter);
mapper = combineTypeMappers(createTypeMapper(signature.typeParameters, freshTypeParameters), mapper);
for (var _i = 0, freshTypeParameters_1 = freshTypeParameters; _i < freshTypeParameters_1.length; _i++) {
var tp = freshTypeParameters_1[_i];
tp.mapper = mapper;
}
}
if (signature.typePredicate) {
freshTypePredicate = cloneTypePredicate(signature.typePredicate, mapper);
}
var result = createSignature(signature.declaration, freshTypeParameters, signature.thisParameter && instantiateSymbol(signature.thisParameter, mapper), instantiateList(signature.parameters, mapper, instantiateSymbol), instantiateType(signature.resolvedReturnType, mapper), freshTypePredicate, signature.minArgumentCount, signature.hasRestParameter, signature.hasLiteralTypes);
result.target = signature;
result.mapper = mapper;
return result;
}
function instantiateSymbol(symbol, mapper) {
if (symbol.flags & 16777216 /* Instantiated */) {
var links = getSymbolLinks(symbol);
// If symbol being instantiated is itself a instantiation, fetch the original target and combine the
// type mappers. This ensures that original type identities are properly preserved and that aliases
// always reference a non-aliases.
symbol = links.target;
mapper = combineTypeMappers(links.mapper, mapper);
}
// Keep the flags from the symbol we're instantiating. Mark that is instantiated, and
// also transient so that we can just store data on it directly.
var result = createSymbol(16777216 /* Instantiated */ | 67108864 /* Transient */ | symbol.flags, symbol.name);
result.declarations = symbol.declarations;
result.parent = symbol.parent;
result.target = symbol;
result.mapper = mapper;
if (symbol.valueDeclaration) {
result.valueDeclaration = symbol.valueDeclaration;
}
return result;
}
function instantiateAnonymousType(type, mapper) {
var result = createObjectType(16 /* Anonymous */ | 64 /* Instantiated */, type.symbol);
result.target = type.objectFlags & 64 /* Instantiated */ ? type.target : type;
result.mapper = type.objectFlags & 64 /* Instantiated */ ? combineTypeMappers(type.mapper, mapper) : mapper;
result.aliasSymbol = type.aliasSymbol;
result.aliasTypeArguments = instantiateTypes(type.aliasTypeArguments, mapper);
return result;
}
function instantiateMappedType(type, mapper) {
var result = createObjectType(32 /* Mapped */ | 64 /* Instantiated */, type.symbol);
result.declaration = type.declaration;
result.mapper = type.mapper ? combineTypeMappers(type.mapper, mapper) : mapper;
result.aliasSymbol = type.aliasSymbol;
result.aliasTypeArguments = instantiateTypes(type.aliasTypeArguments, mapper);
return result;
}
function isSymbolInScopeOfMappedTypeParameter(symbol, mapper) {
if (!(symbol.declarations && symbol.declarations.length)) {
return false;
}
var mappedTypes = mapper.mappedTypes;
// Starting with the parent of the symbol's declaration, check if the mapper maps any of
// the type parameters introduced by enclosing declarations. We just pick the first
// declaration since multiple declarations will all have the same parent anyway.
var node = symbol.declarations[0].parent;
while (node) {
switch (node.kind) {
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 225 /* FunctionDeclaration */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
var declaration = node;
if (declaration.typeParameters) {
for (var _i = 0, _a = declaration.typeParameters; _i < _a.length; _i++) {
var d = _a[_i];
if (ts.contains(mappedTypes, getDeclaredTypeOfTypeParameter(getSymbolOfNode(d)))) {
return true;
}
}
}
if (ts.isClassLike(node) || node.kind === 227 /* InterfaceDeclaration */) {
var thisType = getDeclaredTypeOfClassOrInterface(getSymbolOfNode(node)).thisType;
if (thisType && ts.contains(mappedTypes, thisType)) {
return true;
}
}
break;
case 230 /* ModuleDeclaration */:
case 261 /* SourceFile */:
return false;
}
node = node.parent;
}
return false;
}
function isTopLevelTypeAlias(symbol) {
if (symbol.declarations && symbol.declarations.length) {
var parentKind = symbol.declarations[0].parent.kind;
return parentKind === 261 /* SourceFile */ || parentKind === 231 /* ModuleBlock */;
}
return false;
}
function instantiateType(type, mapper) {
if (type && mapper !== identityMapper) {
// If we are instantiating a type that has a top-level type alias, obtain the instantiation through
// the type alias instead in order to share instantiations for the same type arguments. This can
// dramatically reduce the number of structurally identical types we generate. Note that we can only
// perform this optimization for top-level type aliases. Consider:
//
// function f1<T>(x: T) {
// type Foo<X> = { x: X, t: T };
// let obj: Foo<T> = { x: x };
// return obj;
// }
// function f2<U>(x: U) { return f1(x); }
// let z = f2(42);
//
// Above, the declaration of f2 has an inferred return type that is an instantiation of f1's Foo<X>
// equivalent to { x: U, t: U }. When instantiating this return type, we can't go back to Foo<X>'s
// cache because all cached instantiations are of the form { x: ???, t: T }, i.e. they have not been
// instantiated for T. Instead, we need to further instantiate the { x: U, t: U } form.
if (type.aliasSymbol && isTopLevelTypeAlias(type.aliasSymbol)) {
if (type.aliasTypeArguments) {
return getTypeAliasInstantiation(type.aliasSymbol, instantiateTypes(type.aliasTypeArguments, mapper));
}
return type;
}
return instantiateTypeNoAlias(type, mapper);
}
return type;
}
function instantiateTypeNoAlias(type, mapper) {
if (type.flags & 16384 /* TypeParameter */) {
return mapper(type);
}
if (type.flags & 32768 /* Object */) {
if (type.objectFlags & 16 /* Anonymous */) {
// If the anonymous type originates in a declaration of a function, method, class, or
// interface, in an object type literal, or in an object literal expression, we may need
// to instantiate the type because it might reference a type parameter. We skip instantiation
// if none of the type parameters that are in scope in the type's declaration are mapped by
// the given mapper, however we can only do that analysis if the type isn't itself an
// instantiation.
return type.symbol &&
type.symbol.flags & (16 /* Function */ | 8192 /* Method */ | 32 /* Class */ | 2048 /* TypeLiteral */ | 4096 /* ObjectLiteral */) &&
(type.objectFlags & 64 /* Instantiated */ || isSymbolInScopeOfMappedTypeParameter(type.symbol, mapper)) ?
instantiateCached(type, mapper, instantiateAnonymousType) : type;
}
if (type.objectFlags & 32 /* Mapped */) {
return instantiateCached(type, mapper, instantiateMappedType);
}
if (type.objectFlags & 4 /* Reference */) {
return createTypeReference(type.target, instantiateTypes(type.typeArguments, mapper));
}
}
if (type.flags & 65536 /* Union */ && !(type.flags & 8190 /* Primitive */)) {
return getUnionType(instantiateTypes(type.types, mapper), /*subtypeReduction*/ false, type.aliasSymbol, instantiateTypes(type.aliasTypeArguments, mapper));
}
if (type.flags & 131072 /* Intersection */) {
return getIntersectionType(instantiateTypes(type.types, mapper), type.aliasSymbol, instantiateTypes(type.aliasTypeArguments, mapper));
}
if (type.flags & 262144 /* Index */) {
return getIndexType(instantiateType(type.type, mapper));
}
if (type.flags & 524288 /* IndexedAccess */) {
return getIndexedAccessType(instantiateType(type.objectType, mapper), instantiateType(type.indexType, mapper));
}
return type;
}
function instantiateIndexInfo(info, mapper) {
return info && createIndexInfo(instantiateType(info.type, mapper), info.isReadonly, info.declaration);
}
// Returns true if the given expression contains (at any level of nesting) a function or arrow expression
// that is subject to contextual typing.
function isContextSensitive(node) {
ts.Debug.assert(node.kind !== 149 /* MethodDeclaration */ || ts.isObjectLiteralMethod(node));
switch (node.kind) {
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return isContextSensitiveFunctionLikeDeclaration(node);
case 176 /* ObjectLiteralExpression */:
return ts.forEach(node.properties, isContextSensitive);
case 175 /* ArrayLiteralExpression */:
return ts.forEach(node.elements, isContextSensitive);
case 193 /* ConditionalExpression */:
return isContextSensitive(node.whenTrue) ||
isContextSensitive(node.whenFalse);
case 192 /* BinaryExpression */:
return node.operatorToken.kind === 53 /* BarBarToken */ &&
(isContextSensitive(node.left) || isContextSensitive(node.right));
case 257 /* PropertyAssignment */:
return isContextSensitive(node.initializer);
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
return isContextSensitiveFunctionLikeDeclaration(node);
case 183 /* ParenthesizedExpression */:
return isContextSensitive(node.expression);
}
return false;
}
function isContextSensitiveFunctionLikeDeclaration(node) {
// Functions with type parameters are not context sensitive.
if (node.typeParameters) {
return false;
}
// Functions with any parameters that lack type annotations are context sensitive.
if (ts.forEach(node.parameters, function (p) { return !p.type; })) {
return true;
}
// For arrow functions we now know we're not context sensitive.
if (node.kind === 185 /* ArrowFunction */) {
return false;
}
// If the first parameter is not an explicit 'this' parameter, then the function has
// an implicit 'this' parameter which is subject to contextual typing. Otherwise we
// know that all parameters (including 'this') have type annotations and nothing is
// subject to contextual typing.
var parameter = ts.firstOrUndefined(node.parameters);
return !(parameter && ts.parameterIsThisKeyword(parameter));
}
function isContextSensitiveFunctionOrObjectLiteralMethod(func) {
return (isFunctionExpressionOrArrowFunction(func) || ts.isObjectLiteralMethod(func)) && isContextSensitiveFunctionLikeDeclaration(func);
}
function getTypeWithoutSignatures(type) {
if (type.flags & 32768 /* Object */) {
var resolved = resolveStructuredTypeMembers(type);
if (resolved.constructSignatures.length) {
var result = createObjectType(16 /* Anonymous */, type.symbol);
result.members = resolved.members;
result.properties = resolved.properties;
result.callSignatures = emptyArray;
result.constructSignatures = emptyArray;
type = result;
}
}
return type;
}
// TYPE CHECKING
function isTypeIdenticalTo(source, target) {
return isTypeRelatedTo(source, target, identityRelation);
}
function compareTypesIdentical(source, target) {
return isTypeRelatedTo(source, target, identityRelation) ? -1 /* True */ : 0 /* False */;
}
function compareTypesAssignable(source, target) {
return isTypeRelatedTo(source, target, assignableRelation) ? -1 /* True */ : 0 /* False */;
}
function isTypeSubtypeOf(source, target) {
return isTypeRelatedTo(source, target, subtypeRelation);
}
function isTypeAssignableTo(source, target) {
return isTypeRelatedTo(source, target, assignableRelation);
}
// A type S is considered to be an instance of a type T if S and T are the same type or if S is a
// subtype of T but not structurally identical to T. This specifically means that two distinct but
// structurally identical types (such as two classes) are not considered instances of each other.
function isTypeInstanceOf(source, target) {
return source === target || isTypeSubtypeOf(source, target) && !isTypeIdenticalTo(source, target);
}
/**
* This is *not* a bi-directional relationship.
* If one needs to check both directions for comparability, use a second call to this function or 'checkTypeComparableTo'.
*/
function isTypeComparableTo(source, target) {
return isTypeRelatedTo(source, target, comparableRelation);
}
function areTypesComparable(type1, type2) {
return isTypeComparableTo(type1, type2) || isTypeComparableTo(type2, type1);
}
function checkTypeSubtypeOf(source, target, errorNode, headMessage, containingMessageChain) {
return checkTypeRelatedTo(source, target, subtypeRelation, errorNode, headMessage, containingMessageChain);
}
function checkTypeAssignableTo(source, target, errorNode, headMessage, containingMessageChain) {
return checkTypeRelatedTo(source, target, assignableRelation, errorNode, headMessage, containingMessageChain);
}
/**
* This is *not* a bi-directional relationship.
* If one needs to check both directions for comparability, use a second call to this function or 'isTypeComparableTo'.
*/
function checkTypeComparableTo(source, target, errorNode, headMessage, containingMessageChain) {
return checkTypeRelatedTo(source, target, comparableRelation, errorNode, headMessage, containingMessageChain);
}
function isSignatureAssignableTo(source, target, ignoreReturnTypes) {
return compareSignaturesRelated(source, target, ignoreReturnTypes, /*reportErrors*/ false, /*errorReporter*/ undefined, compareTypesAssignable) !== 0 /* False */;
}
/**
* See signatureRelatedTo, compareSignaturesIdentical
*/
function compareSignaturesRelated(source, target, ignoreReturnTypes, reportErrors, errorReporter, compareTypes) {
// TODO (drosen): De-duplicate code between related functions.
if (source === target) {
return -1 /* True */;
}
if (!target.hasRestParameter && source.minArgumentCount > target.parameters.length) {
return 0 /* False */;
}
// Spec 1.0 Section 3.8.3 & 3.8.4:
// M and N (the signatures) are instantiated using type Any as the type argument for all type parameters declared by M and N
source = getErasedSignature(source);
target = getErasedSignature(target);
var result = -1 /* True */;
var sourceThisType = getThisTypeOfSignature(source);
if (sourceThisType && sourceThisType !== voidType) {
var targetThisType = getThisTypeOfSignature(target);
if (targetThisType) {
// void sources are assignable to anything.
var related = compareTypes(sourceThisType, targetThisType, /*reportErrors*/ false)
|| compareTypes(targetThisType, sourceThisType, reportErrors);
if (!related) {
if (reportErrors) {
errorReporter(ts.Diagnostics.The_this_types_of_each_signature_are_incompatible);
}
return 0 /* False */;
}
result &= related;
}
}
var sourceMax = getNumNonRestParameters(source);
var targetMax = getNumNonRestParameters(target);
var checkCount = getNumParametersToCheckForSignatureRelatability(source, sourceMax, target, targetMax);
var sourceParams = source.parameters;
var targetParams = target.parameters;
for (var i = 0; i < checkCount; i++) {
var s = i < sourceMax ? getTypeOfParameter(sourceParams[i]) : getRestTypeOfSignature(source);
var t = i < targetMax ? getTypeOfParameter(targetParams[i]) : getRestTypeOfSignature(target);
var related = compareTypes(s, t, /*reportErrors*/ false) || compareTypes(t, s, reportErrors);
if (!related) {
if (reportErrors) {
errorReporter(ts.Diagnostics.Types_of_parameters_0_and_1_are_incompatible, sourceParams[i < sourceMax ? i : sourceMax].name, targetParams[i < targetMax ? i : targetMax].name);
}
return 0 /* False */;
}
result &= related;
}
if (!ignoreReturnTypes) {
var targetReturnType = getReturnTypeOfSignature(target);
if (targetReturnType === voidType) {
return result;
}
var sourceReturnType = getReturnTypeOfSignature(source);
// The following block preserves behavior forbidding boolean returning functions from being assignable to type guard returning functions
if (target.typePredicate) {
if (source.typePredicate) {
result &= compareTypePredicateRelatedTo(source.typePredicate, target.typePredicate, reportErrors, errorReporter, compareTypes);
}
else if (ts.isIdentifierTypePredicate(target.typePredicate)) {
if (reportErrors) {
errorReporter(ts.Diagnostics.Signature_0_must_have_a_type_predicate, signatureToString(source));
}
return 0 /* False */;
}
}
else {
result &= compareTypes(sourceReturnType, targetReturnType, reportErrors);
}
}
return result;
}
function compareTypePredicateRelatedTo(source, target, reportErrors, errorReporter, compareTypes) {
if (source.kind !== target.kind) {
if (reportErrors) {
errorReporter(ts.Diagnostics.A_this_based_type_guard_is_not_compatible_with_a_parameter_based_type_guard);
errorReporter(ts.Diagnostics.Type_predicate_0_is_not_assignable_to_1, typePredicateToString(source), typePredicateToString(target));
}
return 0 /* False */;
}
if (source.kind === 1 /* Identifier */) {
var sourceIdentifierPredicate = source;
var targetIdentifierPredicate = target;
if (sourceIdentifierPredicate.parameterIndex !== targetIdentifierPredicate.parameterIndex) {
if (reportErrors) {
errorReporter(ts.Diagnostics.Parameter_0_is_not_in_the_same_position_as_parameter_1, sourceIdentifierPredicate.parameterName, targetIdentifierPredicate.parameterName);
errorReporter(ts.Diagnostics.Type_predicate_0_is_not_assignable_to_1, typePredicateToString(source), typePredicateToString(target));
}
return 0 /* False */;
}
}
var related = compareTypes(source.type, target.type, reportErrors);
if (related === 0 /* False */ && reportErrors) {
errorReporter(ts.Diagnostics.Type_predicate_0_is_not_assignable_to_1, typePredicateToString(source), typePredicateToString(target));
}
return related;
}
function isImplementationCompatibleWithOverload(implementation, overload) {
var erasedSource = getErasedSignature(implementation);
var erasedTarget = getErasedSignature(overload);
// First see if the return types are compatible in either direction.
var sourceReturnType = getReturnTypeOfSignature(erasedSource);
var targetReturnType = getReturnTypeOfSignature(erasedTarget);
if (targetReturnType === voidType
|| isTypeRelatedTo(targetReturnType, sourceReturnType, assignableRelation)
|| isTypeRelatedTo(sourceReturnType, targetReturnType, assignableRelation)) {
return isSignatureAssignableTo(erasedSource, erasedTarget, /*ignoreReturnTypes*/ true);
}
return false;
}
function getNumNonRestParameters(signature) {
var numParams = signature.parameters.length;
return signature.hasRestParameter ?
numParams - 1 :
numParams;
}
function getNumParametersToCheckForSignatureRelatability(source, sourceNonRestParamCount, target, targetNonRestParamCount) {
if (source.hasRestParameter === target.hasRestParameter) {
if (source.hasRestParameter) {
// If both have rest parameters, get the max and add 1 to
// compensate for the rest parameter.
return Math.max(sourceNonRestParamCount, targetNonRestParamCount) + 1;
}
else {
return Math.min(sourceNonRestParamCount, targetNonRestParamCount);
}
}
else {
// Return the count for whichever signature doesn't have rest parameters.
return source.hasRestParameter ?
targetNonRestParamCount :
sourceNonRestParamCount;
}
}
function isEnumTypeRelatedTo(source, target, errorReporter) {
if (source === target) {
return true;
}
var id = source.id + "," + target.id;
if (enumRelation[id] !== undefined) {
return enumRelation[id];
}
if (source.symbol.name !== target.symbol.name ||
!(source.symbol.flags & 256 /* RegularEnum */) || !(target.symbol.flags & 256 /* RegularEnum */) ||
(source.flags & 65536 /* Union */) !== (target.flags & 65536 /* Union */)) {
return enumRelation[id] = false;
}
var targetEnumType = getTypeOfSymbol(target.symbol);
for (var _i = 0, _a = getPropertiesOfType(getTypeOfSymbol(source.symbol)); _i < _a.length; _i++) {
var property = _a[_i];
if (property.flags & 8 /* EnumMember */) {
var targetProperty = getPropertyOfType(targetEnumType, property.name);
if (!targetProperty || !(targetProperty.flags & 8 /* EnumMember */)) {
if (errorReporter) {
errorReporter(ts.Diagnostics.Property_0_is_missing_in_type_1, property.name, typeToString(target, /*enclosingDeclaration*/ undefined, 128 /* UseFullyQualifiedType */));
}
return enumRelation[id] = false;
}
}
}
return enumRelation[id] = true;
}
function isSimpleTypeRelatedTo(source, target, relation, errorReporter) {
if (target.flags & 8192 /* Never */)
return false;
if (target.flags & 1 /* Any */ || source.flags & 8192 /* Never */)
return true;
if (source.flags & 34 /* StringLike */ && target.flags & 2 /* String */)
return true;
if (source.flags & 340 /* NumberLike */ && target.flags & 4 /* Number */)
return true;
if (source.flags & 136 /* BooleanLike */ && target.flags & 8 /* Boolean */)
return true;
if (source.flags & 256 /* EnumLiteral */ && target.flags & 16 /* Enum */ && source.baseType === target)
return true;
if (source.flags & 16 /* Enum */ && target.flags & 16 /* Enum */ && isEnumTypeRelatedTo(source, target, errorReporter))
return true;
if (source.flags & 2048 /* Undefined */ && (!strictNullChecks || target.flags & (2048 /* Undefined */ | 1024 /* Void */)))
return true;
if (source.flags & 4096 /* Null */ && (!strictNullChecks || target.flags & 4096 /* Null */))
return true;
if (relation === assignableRelation || relation === comparableRelation) {
if (source.flags & 1 /* Any */)
return true;
if ((source.flags & 4 /* Number */ | source.flags & 64 /* NumberLiteral */) && target.flags & 272 /* EnumLike */)
return true;
if (source.flags & 256 /* EnumLiteral */ &&
target.flags & 256 /* EnumLiteral */ &&
source.text === target.text &&
isEnumTypeRelatedTo(source.baseType, target.baseType, errorReporter)) {
return true;
}
if (source.flags & 256 /* EnumLiteral */ &&
target.flags & 16 /* Enum */ &&
isEnumTypeRelatedTo(target, source.baseType, errorReporter)) {
return true;
}
}
return false;
}
function isTypeRelatedTo(source, target, relation) {
if (source.flags & 96 /* StringOrNumberLiteral */ && source.flags & 1048576 /* FreshLiteral */) {
source = source.regularType;
}
if (target.flags & 96 /* StringOrNumberLiteral */ && target.flags & 1048576 /* FreshLiteral */) {
target = target.regularType;
}
if (source === target || relation !== identityRelation && isSimpleTypeRelatedTo(source, target, relation)) {
return true;
}
if (source.flags & 32768 /* Object */ && target.flags & 32768 /* Object */) {
var id = relation !== identityRelation || source.id < target.id ? source.id + "," + target.id : target.id + "," + source.id;
var related = relation[id];
if (related !== undefined) {
return related === 1 /* Succeeded */;
}
}
if (source.flags & 507904 /* StructuredOrTypeParameter */ || target.flags & 507904 /* StructuredOrTypeParameter */) {
return checkTypeRelatedTo(source, target, relation, undefined, undefined, undefined);
}
return false;
}
/**
* Checks if 'source' is related to 'target' (e.g.: is a assignable to).
* @param source The left-hand-side of the relation.
* @param target The right-hand-side of the relation.
* @param relation The relation considered. One of 'identityRelation', 'subtypeRelation', 'assignableRelation', or 'comparableRelation'.
* Used as both to determine which checks are performed and as a cache of previously computed results.
* @param errorNode The suggested node upon which all errors will be reported, if defined. This may or may not be the actual node used.
* @param headMessage If the error chain should be prepended by a head message, then headMessage will be used.
* @param containingMessageChain A chain of errors to prepend any new errors found.
*/
function checkTypeRelatedTo(source, target, relation, errorNode, headMessage, containingMessageChain) {
var errorInfo;
var sourceStack;
var targetStack;
var maybeStack;
var expandingFlags;
var depth = 0;
var overflow = false;
ts.Debug.assert(relation !== identityRelation || !errorNode, "no error reporting in identity checking");
var result = isRelatedTo(source, target, /*reportErrors*/ !!errorNode, headMessage);
if (overflow) {
error(errorNode, ts.Diagnostics.Excessive_stack_depth_comparing_types_0_and_1, typeToString(source), typeToString(target));
}
else if (errorInfo) {
if (containingMessageChain) {
errorInfo = ts.concatenateDiagnosticMessageChains(containingMessageChain, errorInfo);
}
diagnostics.add(ts.createDiagnosticForNodeFromMessageChain(errorNode, errorInfo));
}
return result !== 0 /* False */;
function reportError(message, arg0, arg1, arg2) {
ts.Debug.assert(!!errorNode);
errorInfo = ts.chainDiagnosticMessages(errorInfo, message, arg0, arg1, arg2);
}
function reportRelationError(message, source, target) {
var sourceType = typeToString(source);
var targetType = typeToString(target);
if (sourceType === targetType) {
sourceType = typeToString(source, /*enclosingDeclaration*/ undefined, 128 /* UseFullyQualifiedType */);
targetType = typeToString(target, /*enclosingDeclaration*/ undefined, 128 /* UseFullyQualifiedType */);
}
if (!message) {
if (relation === comparableRelation) {
message = ts.Diagnostics.Type_0_is_not_comparable_to_type_1;
}
else if (sourceType === targetType) {
message = ts.Diagnostics.Type_0_is_not_assignable_to_type_1_Two_different_types_with_this_name_exist_but_they_are_unrelated;
}
else {
message = ts.Diagnostics.Type_0_is_not_assignable_to_type_1;
}
}
reportError(message, sourceType, targetType);
}
function tryElaborateErrorsForPrimitivesAndObjects(source, target) {
var sourceType = typeToString(source);
var targetType = typeToString(target);
if ((globalStringType === source && stringType === target) ||
(globalNumberType === source && numberType === target) ||
(globalBooleanType === source && booleanType === target) ||
(getGlobalESSymbolType() === source && esSymbolType === target)) {
reportError(ts.Diagnostics._0_is_a_primitive_but_1_is_a_wrapper_object_Prefer_using_0_when_possible, targetType, sourceType);
}
}
// Compare two types and return
// Ternary.True if they are related with no assumptions,
// Ternary.Maybe if they are related with assumptions of other relationships, or
// Ternary.False if they are not related.
function isRelatedTo(source, target, reportErrors, headMessage) {
var result;
if (source.flags & 96 /* StringOrNumberLiteral */ && source.flags & 1048576 /* FreshLiteral */) {
source = source.regularType;
}
if (target.flags & 96 /* StringOrNumberLiteral */ && target.flags & 1048576 /* FreshLiteral */) {
target = target.regularType;
}
// both types are the same - covers 'they are the same primitive type or both are Any' or the same type parameter cases
if (source === target)
return -1 /* True */;
if (relation === identityRelation) {
return isIdenticalTo(source, target);
}
if (isSimpleTypeRelatedTo(source, target, relation, reportErrors ? reportError : undefined))
return -1 /* True */;
if (source.flags & 262144 /* Index */) {
// A keyof T is related to a union type containing both string and number
if (maybeTypeOfKind(target, 2 /* String */) && maybeTypeOfKind(target, 4 /* Number */)) {
return -1 /* True */;
}
}
if (getObjectFlags(source) & 128 /* ObjectLiteral */ && source.flags & 1048576 /* FreshLiteral */) {
if (hasExcessProperties(source, target, reportErrors)) {
if (reportErrors) {
reportRelationError(headMessage, source, target);
}
return 0 /* False */;
}
// Above we check for excess properties with respect to the entire target type. When union
// and intersection types are further deconstructed on the target side, we don't want to
// make the check again (as it might fail for a partial target type). Therefore we obtain
// the regular source type and proceed with that.
if (target.flags & 196608 /* UnionOrIntersection */) {
source = getRegularTypeOfObjectLiteral(source);
}
}
var saveErrorInfo = errorInfo;
// Note that these checks are specifically ordered to produce correct results. In particular,
// we need to deconstruct unions before intersections (because unions are always at the top),
// and we need to handle "each" relations before "some" relations for the same kind of type.
if (source.flags & 65536 /* Union */) {
if (relation === comparableRelation) {
result = someTypeRelatedToType(source, target, reportErrors && !(source.flags & 8190 /* Primitive */));
}
else {
result = eachTypeRelatedToType(source, target, reportErrors && !(source.flags & 8190 /* Primitive */));
}
if (result) {
return result;
}
}
else if (target.flags & 65536 /* Union */) {
if (result = typeRelatedToSomeType(source, target, reportErrors && !(source.flags & 8190 /* Primitive */) && !(target.flags & 8190 /* Primitive */))) {
return result;
}
}
else if (target.flags & 131072 /* Intersection */) {
if (result = typeRelatedToEachType(source, target, reportErrors)) {
return result;
}
}
else if (source.flags & 131072 /* Intersection */) {
// Check to see if any constituents of the intersection are immediately related to the target.
//
// Don't report errors though. Checking whether a constituent is related to the source is not actually
// useful and leads to some confusing error messages. Instead it is better to let the below checks
// take care of this, or to not elaborate at all. For instance,
//
// - For an object type (such as 'C = A & B'), users are usually more interested in structural errors.
//
// - For a union type (such as '(A | B) = (C & D)'), it's better to hold onto the whole intersection
// than to report that 'D' is not assignable to 'A' or 'B'.
//
// - For a primitive type or type parameter (such as 'number = A & B') there is no point in
// breaking the intersection apart.
if (result = someTypeRelatedToType(source, target, /*reportErrors*/ false)) {
return result;
}
}
if (target.flags & 16384 /* TypeParameter */) {
// Given a type parameter K with a constraint keyof T, a type S is
// assignable to K if S is assignable to keyof T.
var constraint = getConstraintOfTypeParameter(target);
if (constraint && constraint.flags & 262144 /* Index */) {
if (result = isRelatedTo(source, constraint, reportErrors)) {
return result;
}
}
}
else if (target.flags & 262144 /* Index */) {
// A keyof S is related to a keyof T if T is related to S.
if (source.flags & 262144 /* Index */) {
if (result = isRelatedTo(target.type, source.type, /*reportErrors*/ false)) {
return result;
}
}
// Given a type parameter T with a constraint C, a type S is assignable to
// keyof T if S is assignable to keyof C.
var constraint = getConstraintOfTypeParameter(target.type);
if (constraint) {
if (result = isRelatedTo(source, getIndexType(constraint), reportErrors)) {
return result;
}
}
}
if (source.flags & 16384 /* TypeParameter */) {
var constraint = getConstraintOfTypeParameter(source);
if (!constraint || constraint.flags & 1 /* Any */) {
constraint = emptyObjectType;
}
// The constraint may need to be further instantiated with its 'this' type.
constraint = getTypeWithThisArgument(constraint, source);
// Report constraint errors only if the constraint is not the empty object type
var reportConstraintErrors = reportErrors && constraint !== emptyObjectType;
if (result = isRelatedTo(constraint, target, reportConstraintErrors)) {
errorInfo = saveErrorInfo;
return result;
}
}
else {
if (getObjectFlags(source) & 4 /* Reference */ && getObjectFlags(target) & 4 /* Reference */ && source.target === target.target) {
// We have type references to same target type, see if relationship holds for all type arguments
if (result = typeArgumentsRelatedTo(source, target, reportErrors)) {
return result;
}
}
if (isGenericMappedType(target)) {
// A type [P in S]: X is related to a type [P in T]: Y if T is related to S and X is related to Y.
if (isGenericMappedType(source)) {
if ((result = isRelatedTo(getConstraintTypeFromMappedType(target), getConstraintTypeFromMappedType(source), reportErrors)) &&
(result = isRelatedTo(getTemplateTypeFromMappedType(source), getTemplateTypeFromMappedType(target), reportErrors))) {
return result;
}
}
}
else {
// Even if relationship doesn't hold for unions, intersections, or generic type references,
// it may hold in a structural comparison.
var apparentSource = getApparentType(source);
// In a check of the form X = A & B, we will have previously checked if A relates to X or B relates
// to X. Failing both of those we want to check if the aggregation of A and B's members structurally
// relates to X. Thus, we include intersection types on the source side here.
if (apparentSource.flags & (32768 /* Object */ | 131072 /* Intersection */) && target.flags & 32768 /* Object */) {
// Report structural errors only if we haven't reported any errors yet
var reportStructuralErrors = reportErrors && errorInfo === saveErrorInfo && !(source.flags & 8190 /* Primitive */);
if (result = objectTypeRelatedTo(apparentSource, source, target, reportStructuralErrors)) {
errorInfo = saveErrorInfo;
return result;
}
}
}
}
if (reportErrors) {
if (source.flags & 32768 /* Object */ && target.flags & 8190 /* Primitive */) {
tryElaborateErrorsForPrimitivesAndObjects(source, target);
}
else if (source.symbol && source.flags & 32768 /* Object */ && globalObjectType === source) {
reportError(ts.Diagnostics.The_Object_type_is_assignable_to_very_few_other_types_Did_you_mean_to_use_the_any_type_instead);
}
reportRelationError(headMessage, source, target);
}
return 0 /* False */;
}
function isIdenticalTo(source, target) {
var result;
if (source.flags & 32768 /* Object */ && target.flags & 32768 /* Object */) {
if (getObjectFlags(source) & 4 /* Reference */ && getObjectFlags(target) & 4 /* Reference */ && source.target === target.target) {
// We have type references to same target type, see if all type arguments are identical
if (result = typeArgumentsRelatedTo(source, target, /*reportErrors*/ false)) {
return result;
}
}
return objectTypeRelatedTo(source, source, target, /*reportErrors*/ false);
}
if (source.flags & 65536 /* Union */ && target.flags & 65536 /* Union */ ||
source.flags & 131072 /* Intersection */ && target.flags & 131072 /* Intersection */) {
if (result = eachTypeRelatedToSomeType(source, target)) {
if (result &= eachTypeRelatedToSomeType(target, source)) {
return result;
}
}
}
return 0 /* False */;
}
// Check if a property with the given name is known anywhere in the given type. In an object type, a property
// is considered known if the object type is empty and the check is for assignability, if the object type has
// index signatures, or if the property is actually declared in the object type. In a union or intersection
// type, a property is considered known if it is known in any constituent type.
function isKnownProperty(type, name) {
if (type.flags & 32768 /* Object */) {
var resolved = resolveStructuredTypeMembers(type);
if ((relation === assignableRelation || relation === comparableRelation) && (type === globalObjectType || isEmptyObjectType(resolved)) ||
resolved.stringIndexInfo ||
(resolved.numberIndexInfo && isNumericLiteralName(name)) ||
getPropertyOfType(type, name)) {
return true;
}
}
else if (type.flags & 196608 /* UnionOrIntersection */) {
for (var _i = 0, _a = type.types; _i < _a.length; _i++) {
var t = _a[_i];
if (isKnownProperty(t, name)) {
return true;
}
}
}
return false;
}
function isEmptyObjectType(t) {
return t.properties.length === 0 &&
t.callSignatures.length === 0 &&
t.constructSignatures.length === 0 &&
!t.stringIndexInfo &&
!t.numberIndexInfo;
}
function hasExcessProperties(source, target, reportErrors) {
if (maybeTypeOfKind(target, 32768 /* Object */) && !(getObjectFlags(target) & 512 /* ObjectLiteralPatternWithComputedProperties */)) {
for (var _i = 0, _a = getPropertiesOfObjectType(source); _i < _a.length; _i++) {
var prop = _a[_i];
if (!isKnownProperty(target, prop.name)) {
if (reportErrors) {
// We know *exactly* where things went wrong when comparing the types.
// Use this property as the error node as this will be more helpful in
// reasoning about what went wrong.
ts.Debug.assert(!!errorNode);
errorNode = prop.valueDeclaration;
reportError(ts.Diagnostics.Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1, symbolToString(prop), typeToString(target));
}
return true;
}
}
}
return false;
}
function eachTypeRelatedToSomeType(source, target) {
var result = -1 /* True */;
var sourceTypes = source.types;
for (var _i = 0, sourceTypes_1 = sourceTypes; _i < sourceTypes_1.length; _i++) {
var sourceType = sourceTypes_1[_i];
var related = typeRelatedToSomeType(sourceType, target, /*reportErrors*/ false);
if (!related) {
return 0 /* False */;
}
result &= related;
}
return result;
}
function typeRelatedToSomeType(source, target, reportErrors) {
var targetTypes = target.types;
if (target.flags & 65536 /* Union */ && containsType(targetTypes, source)) {
return -1 /* True */;
}
var len = targetTypes.length;
for (var i = 0; i < len; i++) {
var related = isRelatedTo(source, targetTypes[i], reportErrors && i === len - 1);
if (related) {
return related;
}
}
return 0 /* False */;
}
function typeRelatedToEachType(source, target, reportErrors) {
var result = -1 /* True */;
var targetTypes = target.types;
for (var _i = 0, targetTypes_1 = targetTypes; _i < targetTypes_1.length; _i++) {
var targetType = targetTypes_1[_i];
var related = isRelatedTo(source, targetType, reportErrors);
if (!related) {
return 0 /* False */;
}
result &= related;
}
return result;
}
function someTypeRelatedToType(source, target, reportErrors) {
var sourceTypes = source.types;
if (source.flags & 65536 /* Union */ && containsType(sourceTypes, target)) {
return -1 /* True */;
}
var len = sourceTypes.length;
for (var i = 0; i < len; i++) {
var related = isRelatedTo(sourceTypes[i], target, reportErrors && i === len - 1);
if (related) {
return related;
}
}
return 0 /* False */;
}
function eachTypeRelatedToType(source, target, reportErrors) {
var result = -1 /* True */;
var sourceTypes = source.types;
for (var _i = 0, sourceTypes_2 = sourceTypes; _i < sourceTypes_2.length; _i++) {
var sourceType = sourceTypes_2[_i];
var related = isRelatedTo(sourceType, target, reportErrors);
if (!related) {
return 0 /* False */;
}
result &= related;
}
return result;
}
function typeArgumentsRelatedTo(source, target, reportErrors) {
var sources = source.typeArguments || emptyArray;
var targets = target.typeArguments || emptyArray;
if (sources.length !== targets.length && relation === identityRelation) {
return 0 /* False */;
}
var length = sources.length <= targets.length ? sources.length : targets.length;
var result = -1 /* True */;
for (var i = 0; i < length; i++) {
var related = isRelatedTo(sources[i], targets[i], reportErrors);
if (!related) {
return 0 /* False */;
}
result &= related;
}
return result;
}
// Determine if two object types are related by structure. First, check if the result is already available in the global cache.
// Second, check if we have already started a comparison of the given two types in which case we assume the result to be true.
// Third, check if both types are part of deeply nested chains of generic type instantiations and if so assume the types are
// equal and infinitely expanding. Fourth, if we have reached a depth of 100 nested comparisons, assume we have runaway recursion
// and issue an error. Otherwise, actually compare the structure of the two types.
function objectTypeRelatedTo(source, originalSource, target, reportErrors) {
if (overflow) {
return 0 /* False */;
}
var id = relation !== identityRelation || source.id < target.id ? source.id + "," + target.id : target.id + "," + source.id;
var related = relation[id];
if (related !== undefined) {
if (reportErrors && related === 2 /* Failed */) {
// We are elaborating errors and the cached result is an unreported failure. Record the result as a reported
// failure and continue computing the relation such that errors get reported.
relation[id] = 3 /* FailedAndReported */;
}
else {
return related === 1 /* Succeeded */ ? -1 /* True */ : 0 /* False */;
}
}
if (depth > 0) {
for (var i = 0; i < depth; i++) {
// If source and target are already being compared, consider them related with assumptions
if (maybeStack[i][id]) {
return 1 /* Maybe */;
}
}
if (depth === 100) {
overflow = true;
return 0 /* False */;
}
}
else {
sourceStack = [];
targetStack = [];
maybeStack = [];
expandingFlags = 0;
}
sourceStack[depth] = source;
targetStack[depth] = target;
maybeStack[depth] = ts.createMap();
maybeStack[depth][id] = 1 /* Succeeded */;
depth++;
var saveExpandingFlags = expandingFlags;
if (!(expandingFlags & 1) && isDeeplyNestedGeneric(source, sourceStack, depth))
expandingFlags |= 1;
if (!(expandingFlags & 2) && isDeeplyNestedGeneric(target, targetStack, depth))
expandingFlags |= 2;
var result;
if (expandingFlags === 3) {
result = 1 /* Maybe */;
}
else {
result = propertiesRelatedTo(source, target, reportErrors);
if (result) {
result &= signaturesRelatedTo(source, target, 0 /* Call */, reportErrors);
if (result) {
result &= signaturesRelatedTo(source, target, 1 /* Construct */, reportErrors);
if (result) {
result &= indexTypesRelatedTo(source, originalSource, target, 0 /* String */, reportErrors);
if (result) {
result &= indexTypesRelatedTo(source, originalSource, target, 1 /* Number */, reportErrors);
}
}
}
}
}
expandingFlags = saveExpandingFlags;
depth--;
if (result) {
var maybeCache = maybeStack[depth];
// If result is definitely true, copy assumptions to global cache, else copy to next level up
var destinationCache = (result === -1 /* True */ || depth === 0) ? relation : maybeStack[depth - 1];
ts.copyProperties(maybeCache, destinationCache);
}
else {
// A false result goes straight into global cache (when something is false under assumptions it
// will also be false without assumptions)
relation[id] = reportErrors ? 3 /* FailedAndReported */ : 2 /* Failed */;
}
return result;
}
function propertiesRelatedTo(source, target, reportErrors) {
if (relation === identityRelation) {
return propertiesIdenticalTo(source, target);
}
var result = -1 /* True */;
var properties = getPropertiesOfObjectType(target);
var requireOptionalProperties = relation === subtypeRelation && !(getObjectFlags(source) & 128 /* ObjectLiteral */);
for (var _i = 0, properties_3 = properties; _i < properties_3.length; _i++) {
var targetProp = properties_3[_i];
var sourceProp = getPropertyOfType(source, targetProp.name);
if (sourceProp !== targetProp) {
if (!sourceProp) {
if (!(targetProp.flags & 536870912 /* Optional */) || requireOptionalProperties) {
if (reportErrors) {
reportError(ts.Diagnostics.Property_0_is_missing_in_type_1, symbolToString(targetProp), typeToString(source));
}
return 0 /* False */;
}
}
else if (!(targetProp.flags & 134217728 /* Prototype */)) {
var sourcePropFlags = getDeclarationModifierFlagsFromSymbol(sourceProp);
var targetPropFlags = getDeclarationModifierFlagsFromSymbol(targetProp);
if (sourcePropFlags & 8 /* Private */ || targetPropFlags & 8 /* Private */) {
if (sourceProp.valueDeclaration !== targetProp.valueDeclaration) {
if (reportErrors) {
if (sourcePropFlags & 8 /* Private */ && targetPropFlags & 8 /* Private */) {
reportError(ts.Diagnostics.Types_have_separate_declarations_of_a_private_property_0, symbolToString(targetProp));
}
else {
reportError(ts.Diagnostics.Property_0_is_private_in_type_1_but_not_in_type_2, symbolToString(targetProp), typeToString(sourcePropFlags & 8 /* Private */ ? source : target), typeToString(sourcePropFlags & 8 /* Private */ ? target : source));
}
}
return 0 /* False */;
}
}
else if (targetPropFlags & 16 /* Protected */) {
var sourceDeclaredInClass = sourceProp.parent && sourceProp.parent.flags & 32 /* Class */;
var sourceClass = sourceDeclaredInClass ? getDeclaredTypeOfSymbol(getParentOfSymbol(sourceProp)) : undefined;
var targetClass = getDeclaredTypeOfSymbol(getParentOfSymbol(targetProp));
if (!sourceClass || !hasBaseType(sourceClass, targetClass)) {
if (reportErrors) {
reportError(ts.Diagnostics.Property_0_is_protected_but_type_1_is_not_a_class_derived_from_2, symbolToString(targetProp), typeToString(sourceClass || source), typeToString(targetClass));
}
return 0 /* False */;
}
}
else if (sourcePropFlags & 16 /* Protected */) {
if (reportErrors) {
reportError(ts.Diagnostics.Property_0_is_protected_in_type_1_but_public_in_type_2, symbolToString(targetProp), typeToString(source), typeToString(target));
}
return 0 /* False */;
}
var related = isRelatedTo(getTypeOfSymbol(sourceProp), getTypeOfSymbol(targetProp), reportErrors);
if (!related) {
if (reportErrors) {
reportError(ts.Diagnostics.Types_of_property_0_are_incompatible, symbolToString(targetProp));
}
return 0 /* False */;
}
result &= related;
// When checking for comparability, be more lenient with optional properties.
if (relation !== comparableRelation && sourceProp.flags & 536870912 /* Optional */ && !(targetProp.flags & 536870912 /* Optional */)) {
// TypeScript 1.0 spec (April 2014): 3.8.3
// S is a subtype of a type T, and T is a supertype of S if ...
// S' and T are object types and, for each member M in T..
// M is a property and S' contains a property N where
// if M is a required property, N is also a required property
// (M - property in T)
// (N - property in S)
if (reportErrors) {
reportError(ts.Diagnostics.Property_0_is_optional_in_type_1_but_required_in_type_2, symbolToString(targetProp), typeToString(source), typeToString(target));
}
return 0 /* False */;
}
}
}
}
return result;
}
function propertiesIdenticalTo(source, target) {
if (!(source.flags & 32768 /* Object */ && target.flags & 32768 /* Object */)) {
return 0 /* False */;
}
var sourceProperties = getPropertiesOfObjectType(source);
var targetProperties = getPropertiesOfObjectType(target);
if (sourceProperties.length !== targetProperties.length) {
return 0 /* False */;
}
var result = -1 /* True */;
for (var _i = 0, sourceProperties_1 = sourceProperties; _i < sourceProperties_1.length; _i++) {
var sourceProp = sourceProperties_1[_i];
var targetProp = getPropertyOfObjectType(target, sourceProp.name);
if (!targetProp) {
return 0 /* False */;
}
var related = compareProperties(sourceProp, targetProp, isRelatedTo);
if (!related) {
return 0 /* False */;
}
result &= related;
}
return result;
}
function signaturesRelatedTo(source, target, kind, reportErrors) {
if (relation === identityRelation) {
return signaturesIdenticalTo(source, target, kind);
}
if (target === anyFunctionType || source === anyFunctionType) {
return -1 /* True */;
}
var sourceSignatures = getSignaturesOfType(source, kind);
var targetSignatures = getSignaturesOfType(target, kind);
if (kind === 1 /* Construct */ && sourceSignatures.length && targetSignatures.length) {
if (isAbstractConstructorType(source) && !isAbstractConstructorType(target)) {
// An abstract constructor type is not assignable to a non-abstract constructor type
// as it would otherwise be possible to new an abstract class. Note that the assignability
// check we perform for an extends clause excludes construct signatures from the target,
// so this check never proceeds.
if (reportErrors) {
reportError(ts.Diagnostics.Cannot_assign_an_abstract_constructor_type_to_a_non_abstract_constructor_type);
}
return 0 /* False */;
}
if (!constructorVisibilitiesAreCompatible(sourceSignatures[0], targetSignatures[0], reportErrors)) {
return 0 /* False */;
}
}
var result = -1 /* True */;
var saveErrorInfo = errorInfo;
outer: for (var _i = 0, targetSignatures_1 = targetSignatures; _i < targetSignatures_1.length; _i++) {
var t = targetSignatures_1[_i];
// Only elaborate errors from the first failure
var shouldElaborateErrors = reportErrors;
for (var _a = 0, sourceSignatures_1 = sourceSignatures; _a < sourceSignatures_1.length; _a++) {
var s = sourceSignatures_1[_a];
var related = signatureRelatedTo(s, t, shouldElaborateErrors);
if (related) {
result &= related;
errorInfo = saveErrorInfo;
continue outer;
}
shouldElaborateErrors = false;
}
if (shouldElaborateErrors) {
reportError(ts.Diagnostics.Type_0_provides_no_match_for_the_signature_1, typeToString(source), signatureToString(t, /*enclosingDeclaration*/ undefined, /*flags*/ undefined, kind));
}
return 0 /* False */;
}
return result;
}
/**
* See signatureAssignableTo, compareSignaturesIdentical
*/
function signatureRelatedTo(source, target, reportErrors) {
return compareSignaturesRelated(source, target, /*ignoreReturnTypes*/ false, reportErrors, reportError, isRelatedTo);
}
function signaturesIdenticalTo(source, target, kind) {
var sourceSignatures = getSignaturesOfType(source, kind);
var targetSignatures = getSignaturesOfType(target, kind);
if (sourceSignatures.length !== targetSignatures.length) {
return 0 /* False */;
}
var result = -1 /* True */;
for (var i = 0, len = sourceSignatures.length; i < len; i++) {
var related = compareSignaturesIdentical(sourceSignatures[i], targetSignatures[i], /*partialMatch*/ false, /*ignoreThisTypes*/ false, /*ignoreReturnTypes*/ false, isRelatedTo);
if (!related) {
return 0 /* False */;
}
result &= related;
}
return result;
}
function eachPropertyRelatedTo(source, target, kind, reportErrors) {
var result = -1 /* True */;
for (var _i = 0, _a = getPropertiesOfObjectType(source); _i < _a.length; _i++) {
var prop = _a[_i];
if (kind === 0 /* String */ || isNumericLiteralName(prop.name)) {
var related = isRelatedTo(getTypeOfSymbol(prop), target, reportErrors);
if (!related) {
if (reportErrors) {
reportError(ts.Diagnostics.Property_0_is_incompatible_with_index_signature, symbolToString(prop));
}
return 0 /* False */;
}
result &= related;
}
}
return result;
}
function indexInfoRelatedTo(sourceInfo, targetInfo, reportErrors) {
var related = isRelatedTo(sourceInfo.type, targetInfo.type, reportErrors);
if (!related && reportErrors) {
reportError(ts.Diagnostics.Index_signatures_are_incompatible);
}
return related;
}
function indexTypesRelatedTo(source, originalSource, target, kind, reportErrors) {
if (relation === identityRelation) {
return indexTypesIdenticalTo(source, target, kind);
}
var targetInfo = getIndexInfoOfType(target, kind);
if (!targetInfo || ((targetInfo.type.flags & 1 /* Any */) && !(originalSource.flags & 8190 /* Primitive */))) {
// Index signature of type any permits assignment from everything but primitives
return -1 /* True */;
}
var sourceInfo = getIndexInfoOfType(source, kind) ||
kind === 1 /* Number */ && getIndexInfoOfType(source, 0 /* String */);
if (sourceInfo) {
return indexInfoRelatedTo(sourceInfo, targetInfo, reportErrors);
}
if (isObjectLiteralType(source)) {
var related = -1 /* True */;
if (kind === 0 /* String */) {
var sourceNumberInfo = getIndexInfoOfType(source, 1 /* Number */);
if (sourceNumberInfo) {
related = indexInfoRelatedTo(sourceNumberInfo, targetInfo, reportErrors);
}
}
if (related) {
related &= eachPropertyRelatedTo(source, targetInfo.type, kind, reportErrors);
}
return related;
}
if (reportErrors) {
reportError(ts.Diagnostics.Index_signature_is_missing_in_type_0, typeToString(source));
}
return 0 /* False */;
}
function indexTypesIdenticalTo(source, target, indexKind) {
var targetInfo = getIndexInfoOfType(target, indexKind);
var sourceInfo = getIndexInfoOfType(source, indexKind);
if (!sourceInfo && !targetInfo) {
return -1 /* True */;
}
if (sourceInfo && targetInfo && sourceInfo.isReadonly === targetInfo.isReadonly) {
return isRelatedTo(sourceInfo.type, targetInfo.type);
}
return 0 /* False */;
}
function constructorVisibilitiesAreCompatible(sourceSignature, targetSignature, reportErrors) {
if (!sourceSignature.declaration || !targetSignature.declaration) {
return true;
}
var sourceAccessibility = ts.getModifierFlags(sourceSignature.declaration) & 24 /* NonPublicAccessibilityModifier */;
var targetAccessibility = ts.getModifierFlags(targetSignature.declaration) & 24 /* NonPublicAccessibilityModifier */;
// A public, protected and private signature is assignable to a private signature.
if (targetAccessibility === 8 /* Private */) {
return true;
}
// A public and protected signature is assignable to a protected signature.
if (targetAccessibility === 16 /* Protected */ && sourceAccessibility !== 8 /* Private */) {
return true;
}
// Only a public signature is assignable to public signature.
if (targetAccessibility !== 16 /* Protected */ && !sourceAccessibility) {
return true;
}
if (reportErrors) {
reportError(ts.Diagnostics.Cannot_assign_a_0_constructor_type_to_a_1_constructor_type, visibilityToString(sourceAccessibility), visibilityToString(targetAccessibility));
}
return false;
}
}
// Return true if the given type is the constructor type for an abstract class
function isAbstractConstructorType(type) {
if (getObjectFlags(type) & 16 /* Anonymous */) {
var symbol = type.symbol;
if (symbol && symbol.flags & 32 /* Class */) {
var declaration = getClassLikeDeclarationOfSymbol(symbol);
if (declaration && ts.getModifierFlags(declaration) & 128 /* Abstract */) {
return true;
}
}
}
return false;
}
// Return true if the given type is part of a deeply nested chain of generic instantiations. We consider this to be the case
// when structural type comparisons have been started for 10 or more instantiations of the same generic type. It is possible,
// though highly unlikely, for this test to be true in a situation where a chain of instantiations is not infinitely expanding.
// Effectively, we will generate a false positive when two types are structurally equal to at least 10 levels, but unequal at
// some level beyond that.
function isDeeplyNestedGeneric(type, stack, depth) {
// We track type references (created by createTypeReference) and instantiated types (created by instantiateType)
if (getObjectFlags(type) & (4 /* Reference */ | 64 /* Instantiated */) && depth >= 5) {
var symbol = type.symbol;
var count = 0;
for (var i = 0; i < depth; i++) {
var t = stack[i];
if (getObjectFlags(t) & (4 /* Reference */ | 64 /* Instantiated */) && t.symbol === symbol) {
count++;
if (count >= 5)
return true;
}
}
}
return false;
}
function isPropertyIdenticalTo(sourceProp, targetProp) {
return compareProperties(sourceProp, targetProp, compareTypesIdentical) !== 0 /* False */;
}
function compareProperties(sourceProp, targetProp, compareTypes) {
// Two members are considered identical when
// - they are public properties with identical names, optionality, and types,
// - they are private or protected properties originating in the same declaration and having identical types
if (sourceProp === targetProp) {
return -1 /* True */;
}
var sourcePropAccessibility = getDeclarationModifierFlagsFromSymbol(sourceProp) & 24 /* NonPublicAccessibilityModifier */;
var targetPropAccessibility = getDeclarationModifierFlagsFromSymbol(targetProp) & 24 /* NonPublicAccessibilityModifier */;
if (sourcePropAccessibility !== targetPropAccessibility) {
return 0 /* False */;
}
if (sourcePropAccessibility) {
if (getTargetSymbol(sourceProp) !== getTargetSymbol(targetProp)) {
return 0 /* False */;
}
}
else {
if ((sourceProp.flags & 536870912 /* Optional */) !== (targetProp.flags & 536870912 /* Optional */)) {
return 0 /* False */;
}
}
if (isReadonlySymbol(sourceProp) !== isReadonlySymbol(targetProp)) {
return 0 /* False */;
}
return compareTypes(getTypeOfSymbol(sourceProp), getTypeOfSymbol(targetProp));
}
function isMatchingSignature(source, target, partialMatch) {
// A source signature matches a target signature if the two signatures have the same number of required,
// optional, and rest parameters.
if (source.parameters.length === target.parameters.length &&
source.minArgumentCount === target.minArgumentCount &&
source.hasRestParameter === target.hasRestParameter) {
return true;
}
// A source signature partially matches a target signature if the target signature has no fewer required
// parameters and no more overall parameters than the source signature (where a signature with a rest
// parameter is always considered to have more overall parameters than one without).
var sourceRestCount = source.hasRestParameter ? 1 : 0;
var targetRestCount = target.hasRestParameter ? 1 : 0;
if (partialMatch && source.minArgumentCount <= target.minArgumentCount && (sourceRestCount > targetRestCount ||
sourceRestCount === targetRestCount && source.parameters.length >= target.parameters.length)) {
return true;
}
return false;
}
/**
* See signatureRelatedTo, compareSignaturesIdentical
*/
function compareSignaturesIdentical(source, target, partialMatch, ignoreThisTypes, ignoreReturnTypes, compareTypes) {
// TODO (drosen): De-duplicate code between related functions.
if (source === target) {
return -1 /* True */;
}
if (!(isMatchingSignature(source, target, partialMatch))) {
return 0 /* False */;
}
// Check that the two signatures have the same number of type parameters. We might consider
// also checking that any type parameter constraints match, but that would require instantiating
// the constraints with a common set of type arguments to get relatable entities in places where
// type parameters occur in the constraints. The complexity of doing that doesn't seem worthwhile,
// particularly as we're comparing erased versions of the signatures below.
if ((source.typeParameters ? source.typeParameters.length : 0) !== (target.typeParameters ? target.typeParameters.length : 0)) {
return 0 /* False */;
}
// Spec 1.0 Section 3.8.3 & 3.8.4:
// M and N (the signatures) are instantiated using type Any as the type argument for all type parameters declared by M and N
source = getErasedSignature(source);
target = getErasedSignature(target);
var result = -1 /* True */;
if (!ignoreThisTypes) {
var sourceThisType = getThisTypeOfSignature(source);
if (sourceThisType) {
var targetThisType = getThisTypeOfSignature(target);
if (targetThisType) {
var related = compareTypes(sourceThisType, targetThisType);
if (!related) {
return 0 /* False */;
}
result &= related;
}
}
}
var targetLen = target.parameters.length;
for (var i = 0; i < targetLen; i++) {
var s = isRestParameterIndex(source, i) ? getRestTypeOfSignature(source) : getTypeOfParameter(source.parameters[i]);
var t = isRestParameterIndex(target, i) ? getRestTypeOfSignature(target) : getTypeOfParameter(target.parameters[i]);
var related = compareTypes(s, t);
if (!related) {
return 0 /* False */;
}
result &= related;
}
if (!ignoreReturnTypes) {
result &= compareTypes(getReturnTypeOfSignature(source), getReturnTypeOfSignature(target));
}
return result;
}
function isRestParameterIndex(signature, parameterIndex) {
return signature.hasRestParameter && parameterIndex >= signature.parameters.length - 1;
}
function isSupertypeOfEach(candidate, types) {
for (var _i = 0, types_7 = types; _i < types_7.length; _i++) {
var t = types_7[_i];
if (candidate !== t && !isTypeSubtypeOf(t, candidate))
return false;
}
return true;
}
function literalTypesWithSameBaseType(types) {
var commonBaseType;
for (var _i = 0, types_8 = types; _i < types_8.length; _i++) {
var t = types_8[_i];
var baseType = getBaseTypeOfLiteralType(t);
if (!commonBaseType) {
commonBaseType = baseType;
}
if (baseType === t || baseType !== commonBaseType) {
return false;
}
}
return true;
}
// When the candidate types are all literal types with the same base type, the common
// supertype is a union of those literal types. Otherwise, the common supertype is the
// first type that is a supertype of each of the other types.
function getSupertypeOrUnion(types) {
return literalTypesWithSameBaseType(types) ? getUnionType(types) : ts.forEach(types, function (t) { return isSupertypeOfEach(t, types) ? t : undefined; });
}
function getCommonSupertype(types) {
if (!strictNullChecks) {
return getSupertypeOrUnion(types);
}
var primaryTypes = ts.filter(types, function (t) { return !(t.flags & 6144 /* Nullable */); });
if (!primaryTypes.length) {
return getUnionType(types, /*subtypeReduction*/ true);
}
var supertype = getSupertypeOrUnion(primaryTypes);
return supertype && includeFalsyTypes(supertype, getFalsyFlagsOfTypes(types) & 6144 /* Nullable */);
}
function reportNoCommonSupertypeError(types, errorLocation, errorMessageChainHead) {
// The downfallType/bestSupertypeDownfallType is the first type that caused a particular candidate
// to not be the common supertype. So if it weren't for this one downfallType (and possibly others),
// the type in question could have been the common supertype.
var bestSupertype;
var bestSupertypeDownfallType;
var bestSupertypeScore = 0;
for (var i = 0; i < types.length; i++) {
var score = 0;
var downfallType = undefined;
for (var j = 0; j < types.length; j++) {
if (isTypeSubtypeOf(types[j], types[i])) {
score++;
}
else if (!downfallType) {
downfallType = types[j];
}
}
ts.Debug.assert(!!downfallType, "If there is no common supertype, each type should have a downfallType");
if (score > bestSupertypeScore) {
bestSupertype = types[i];
bestSupertypeDownfallType = downfallType;
bestSupertypeScore = score;
}
// types.length - 1 is the maximum score, given that getCommonSupertype returned false
if (bestSupertypeScore === types.length - 1) {
break;
}
}
// In the following errors, the {1} slot is before the {0} slot because checkTypeSubtypeOf supplies the
// subtype as the first argument to the error
checkTypeSubtypeOf(bestSupertypeDownfallType, bestSupertype, errorLocation, ts.Diagnostics.Type_argument_candidate_1_is_not_a_valid_type_argument_because_it_is_not_a_supertype_of_candidate_0, errorMessageChainHead);
}
function isArrayType(type) {
return getObjectFlags(type) & 4 /* Reference */ && type.target === globalArrayType;
}
function isArrayLikeType(type) {
// A type is array-like if it is a reference to the global Array or global ReadonlyArray type,
// or if it is not the undefined or null type and if it is assignable to ReadonlyArray<any>
return getObjectFlags(type) & 4 /* Reference */ && (type.target === globalArrayType || type.target === globalReadonlyArrayType) ||
!(type.flags & 6144 /* Nullable */) && isTypeAssignableTo(type, anyReadonlyArrayType);
}
function isTupleLikeType(type) {
return !!getPropertyOfType(type, "0");
}
function isUnitType(type) {
return (type.flags & (480 /* Literal */ | 2048 /* Undefined */ | 4096 /* Null */)) !== 0;
}
function isLiteralType(type) {
return type.flags & 8 /* Boolean */ ? true :
type.flags & 65536 /* Union */ ? type.flags & 16 /* Enum */ ? true : !ts.forEach(type.types, function (t) { return !isUnitType(t); }) :
isUnitType(type);
}
function getBaseTypeOfLiteralType(type) {
return type.flags & 32 /* StringLiteral */ ? stringType :
type.flags & 64 /* NumberLiteral */ ? numberType :
type.flags & 128 /* BooleanLiteral */ ? booleanType :
type.flags & 256 /* EnumLiteral */ ? type.baseType :
type.flags & 65536 /* Union */ && !(type.flags & 16 /* Enum */) ? getUnionType(ts.sameMap(type.types, getBaseTypeOfLiteralType)) :
type;
}
function getWidenedLiteralType(type) {
return type.flags & 32 /* StringLiteral */ && type.flags & 1048576 /* FreshLiteral */ ? stringType :
type.flags & 64 /* NumberLiteral */ && type.flags & 1048576 /* FreshLiteral */ ? numberType :
type.flags & 128 /* BooleanLiteral */ ? booleanType :
type.flags & 256 /* EnumLiteral */ ? type.baseType :
type.flags & 65536 /* Union */ && !(type.flags & 16 /* Enum */) ? getUnionType(ts.sameMap(type.types, getWidenedLiteralType)) :
type;
}
/**
* Check if a Type was written as a tuple type literal.
* Prefer using isTupleLikeType() unless the use of `elementTypes` is required.
*/
function isTupleType(type) {
return !!(getObjectFlags(type) & 4 /* Reference */ && type.target.objectFlags & 8 /* Tuple */);
}
function getFalsyFlagsOfTypes(types) {
var result = 0;
for (var _i = 0, types_9 = types; _i < types_9.length; _i++) {
var t = types_9[_i];
result |= getFalsyFlags(t);
}
return result;
}
// Returns the String, Number, Boolean, StringLiteral, NumberLiteral, BooleanLiteral, Void, Undefined, or Null
// flags for the string, number, boolean, "", 0, false, void, undefined, or null types respectively. Returns
// no flags for all other types (including non-falsy literal types).
function getFalsyFlags(type) {
return type.flags & 65536 /* Union */ ? getFalsyFlagsOfTypes(type.types) :
type.flags & 32 /* StringLiteral */ ? type.text === "" ? 32 /* StringLiteral */ : 0 :
type.flags & 64 /* NumberLiteral */ ? type.text === "0" ? 64 /* NumberLiteral */ : 0 :
type.flags & 128 /* BooleanLiteral */ ? type === falseType ? 128 /* BooleanLiteral */ : 0 :
type.flags & 7406 /* PossiblyFalsy */;
}
function includeFalsyTypes(type, flags) {
if ((getFalsyFlags(type) & flags) === flags) {
return type;
}
var types = [type];
if (flags & 34 /* StringLike */)
types.push(emptyStringType);
if (flags & 340 /* NumberLike */)
types.push(zeroType);
if (flags & 136 /* BooleanLike */)
types.push(falseType);
if (flags & 1024 /* Void */)
types.push(voidType);
if (flags & 2048 /* Undefined */)
types.push(undefinedType);
if (flags & 4096 /* Null */)
types.push(nullType);
return getUnionType(types, /*subtypeReduction*/ true);
}
function removeDefinitelyFalsyTypes(type) {
return getFalsyFlags(type) & 7392 /* DefinitelyFalsy */ ?
filterType(type, function (t) { return !(getFalsyFlags(t) & 7392 /* DefinitelyFalsy */); }) :
type;
}
function getNonNullableType(type) {
return strictNullChecks ? getTypeWithFacts(type, 524288 /* NEUndefinedOrNull */) : type;
}
/**
* Return true if type was inferred from an object literal or written as an object type literal
* with no call or construct signatures.
*/
function isObjectLiteralType(type) {
return type.symbol && (type.symbol.flags & (4096 /* ObjectLiteral */ | 2048 /* TypeLiteral */)) !== 0 &&
getSignaturesOfType(type, 0 /* Call */).length === 0 &&
getSignaturesOfType(type, 1 /* Construct */).length === 0;
}
function createTransientSymbol(source, type) {
var symbol = createSymbol(source.flags | 67108864 /* Transient */, source.name);
symbol.declarations = source.declarations;
symbol.parent = source.parent;
symbol.type = type;
symbol.target = source;
if (source.valueDeclaration) {
symbol.valueDeclaration = source.valueDeclaration;
}
return symbol;
}
function transformTypeOfMembers(type, f) {
var members = ts.createMap();
for (var _i = 0, _a = getPropertiesOfObjectType(type); _i < _a.length; _i++) {
var property = _a[_i];
var original = getTypeOfSymbol(property);
var updated = f(original);
members[property.name] = updated === original ? property : createTransientSymbol(property, updated);
}
;
return members;
}
/**
* If the the provided object literal is subject to the excess properties check,
* create a new that is exempt. Recursively mark object literal members as exempt.
* Leave signatures alone since they are not subject to the check.
*/
function getRegularTypeOfObjectLiteral(type) {
if (!(getObjectFlags(type) & 128 /* ObjectLiteral */ && type.flags & 1048576 /* FreshLiteral */)) {
return type;
}
var regularType = type.regularType;
if (regularType) {
return regularType;
}
var resolved = type;
var members = transformTypeOfMembers(type, getRegularTypeOfObjectLiteral);
var regularNew = createAnonymousType(resolved.symbol, members, resolved.callSignatures, resolved.constructSignatures, resolved.stringIndexInfo, resolved.numberIndexInfo);
regularNew.flags = resolved.flags & ~1048576 /* FreshLiteral */;
regularNew.objectFlags |= 128 /* ObjectLiteral */;
type.regularType = regularNew;
return regularNew;
}
function getWidenedTypeOfObjectLiteral(type) {
var members = transformTypeOfMembers(type, function (prop) {
var widened = getWidenedType(prop);
return prop === widened ? prop : widened;
});
var stringIndexInfo = getIndexInfoOfType(type, 0 /* String */);
var numberIndexInfo = getIndexInfoOfType(type, 1 /* Number */);
return createAnonymousType(type.symbol, members, emptyArray, emptyArray, stringIndexInfo && createIndexInfo(getWidenedType(stringIndexInfo.type), stringIndexInfo.isReadonly), numberIndexInfo && createIndexInfo(getWidenedType(numberIndexInfo.type), numberIndexInfo.isReadonly));
}
function getWidenedConstituentType(type) {
return type.flags & 6144 /* Nullable */ ? type : getWidenedType(type);
}
function getWidenedType(type) {
if (type.flags & 6291456 /* RequiresWidening */) {
if (type.flags & 6144 /* Nullable */) {
return anyType;
}
if (getObjectFlags(type) & 128 /* ObjectLiteral */) {
return getWidenedTypeOfObjectLiteral(type);
}
if (type.flags & 65536 /* Union */) {
return getUnionType(ts.sameMap(type.types, getWidenedConstituentType));
}
if (isArrayType(type) || isTupleType(type)) {
return createTypeReference(type.target, ts.sameMap(type.typeArguments, getWidenedType));
}
}
return type;
}
/**
* Reports implicit any errors that occur as a result of widening 'null' and 'undefined'
* to 'any'. A call to reportWideningErrorsInType is normally accompanied by a call to
* getWidenedType. But in some cases getWidenedType is called without reporting errors
* (type argument inference is an example).
*
* The return value indicates whether an error was in fact reported. The particular circumstances
* are on a best effort basis. Currently, if the null or undefined that causes widening is inside
* an object literal property (arbitrarily deeply), this function reports an error. If no error is
* reported, reportImplicitAnyError is a suitable fallback to report a general error.
*/
function reportWideningErrorsInType(type) {
var errorReported = false;
if (type.flags & 65536 /* Union */) {
for (var _i = 0, _a = type.types; _i < _a.length; _i++) {
var t = _a[_i];
if (reportWideningErrorsInType(t)) {
errorReported = true;
}
}
}
if (isArrayType(type) || isTupleType(type)) {
for (var _b = 0, _c = type.typeArguments; _b < _c.length; _b++) {
var t = _c[_b];
if (reportWideningErrorsInType(t)) {
errorReported = true;
}
}
}
if (getObjectFlags(type) & 128 /* ObjectLiteral */) {
for (var _d = 0, _e = getPropertiesOfObjectType(type); _d < _e.length; _d++) {
var p = _e[_d];
var t = getTypeOfSymbol(p);
if (t.flags & 2097152 /* ContainsWideningType */) {
if (!reportWideningErrorsInType(t)) {
error(p.valueDeclaration, ts.Diagnostics.Object_literal_s_property_0_implicitly_has_an_1_type, p.name, typeToString(getWidenedType(t)));
}
errorReported = true;
}
}
}
return errorReported;
}
function reportImplicitAnyError(declaration, type) {
var typeAsString = typeToString(getWidenedType(type));
var diagnostic;
switch (declaration.kind) {
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
diagnostic = ts.Diagnostics.Member_0_implicitly_has_an_1_type;
break;
case 144 /* Parameter */:
diagnostic = declaration.dotDotDotToken ?
ts.Diagnostics.Rest_parameter_0_implicitly_has_an_any_type :
ts.Diagnostics.Parameter_0_implicitly_has_an_1_type;
break;
case 174 /* BindingElement */:
diagnostic = ts.Diagnostics.Binding_element_0_implicitly_has_an_1_type;
break;
case 225 /* FunctionDeclaration */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
if (!declaration.name) {
error(declaration, ts.Diagnostics.Function_expression_which_lacks_return_type_annotation_implicitly_has_an_0_return_type, typeAsString);
return;
}
diagnostic = ts.Diagnostics._0_which_lacks_return_type_annotation_implicitly_has_an_1_return_type;
break;
default:
diagnostic = ts.Diagnostics.Variable_0_implicitly_has_an_1_type;
}
error(declaration, diagnostic, ts.declarationNameToString(declaration.name), typeAsString);
}
function reportErrorsFromWidening(declaration, type) {
if (produceDiagnostics && compilerOptions.noImplicitAny && type.flags & 2097152 /* ContainsWideningType */) {
// Report implicit any error within type if possible, otherwise report error on declaration
if (!reportWideningErrorsInType(type)) {
reportImplicitAnyError(declaration, type);
}
}
}
function forEachMatchingParameterType(source, target, callback) {
var sourceMax = source.parameters.length;
var targetMax = target.parameters.length;
var count;
if (source.hasRestParameter && target.hasRestParameter) {
count = Math.max(sourceMax, targetMax);
}
else if (source.hasRestParameter) {
count = targetMax;
}
else if (target.hasRestParameter) {
count = sourceMax;
}
else {
count = Math.min(sourceMax, targetMax);
}
for (var i = 0; i < count; i++) {
callback(getTypeAtPosition(source, i), getTypeAtPosition(target, i));
}
}
function createInferenceContext(signature, inferUnionTypes) {
var inferences = ts.map(signature.typeParameters, createTypeInferencesObject);
return {
signature: signature,
inferUnionTypes: inferUnionTypes,
inferences: inferences,
inferredTypes: new Array(signature.typeParameters.length),
};
}
function createTypeInferencesObject() {
return {
primary: undefined,
secondary: undefined,
topLevel: true,
isFixed: false,
};
}
// Return true if the given type could possibly reference a type parameter for which
// we perform type inference (i.e. a type parameter of a generic function). We cache
// results for union and intersection types for performance reasons.
function couldContainTypeParameters(type) {
var objectFlags = getObjectFlags(type);
return !!(type.flags & 16384 /* TypeParameter */ ||
objectFlags & 4 /* Reference */ && ts.forEach(type.typeArguments, couldContainTypeParameters) ||
objectFlags & 16 /* Anonymous */ && type.symbol && type.symbol.flags & (8192 /* Method */ | 2048 /* TypeLiteral */ | 32 /* Class */) ||
objectFlags & 32 /* Mapped */ ||
type.flags & 196608 /* UnionOrIntersection */ && couldUnionOrIntersectionContainTypeParameters(type));
}
function couldUnionOrIntersectionContainTypeParameters(type) {
if (type.couldContainTypeParameters === undefined) {
type.couldContainTypeParameters = ts.forEach(type.types, couldContainTypeParameters);
}
return type.couldContainTypeParameters;
}
function isTypeParameterAtTopLevel(type, typeParameter) {
return type === typeParameter || type.flags & 196608 /* UnionOrIntersection */ && ts.forEach(type.types, function (t) { return isTypeParameterAtTopLevel(t, typeParameter); });
}
function inferTypes(context, originalSource, originalTarget) {
var typeParameters = context.signature.typeParameters;
var sourceStack;
var targetStack;
var depth = 0;
var inferiority = 0;
var visited = ts.createMap();
inferFromTypes(originalSource, originalTarget);
function isInProcess(source, target) {
for (var i = 0; i < depth; i++) {
if (source === sourceStack[i] && target === targetStack[i]) {
return true;
}
}
return false;
}
function inferFromTypes(source, target) {
if (!couldContainTypeParameters(target)) {
return;
}
if (source.aliasSymbol && source.aliasTypeArguments && source.aliasSymbol === target.aliasSymbol) {
// Source and target are types originating in the same generic type alias declaration.
// Simply infer from source type arguments to target type arguments.
var sourceTypes = source.aliasTypeArguments;
var targetTypes = target.aliasTypeArguments;
for (var i = 0; i < sourceTypes.length; i++) {
inferFromTypes(sourceTypes[i], targetTypes[i]);
}
return;
}
if (source.flags & 65536 /* Union */ && target.flags & 65536 /* Union */ && !(source.flags & 16 /* Enum */ && target.flags & 16 /* Enum */) ||
source.flags & 131072 /* Intersection */ && target.flags & 131072 /* Intersection */) {
// Source and target are both unions or both intersections. If source and target
// are the same type, just relate each constituent type to itself.
if (source === target) {
for (var _i = 0, _a = source.types; _i < _a.length; _i++) {
var t = _a[_i];
inferFromTypes(t, t);
}
return;
}
// Find each source constituent type that has an identically matching target constituent
// type, and for each such type infer from the type to itself. When inferring from a
// type to itself we effectively find all type parameter occurrences within that type
// and infer themselves as their type arguments. We have special handling for numeric
// and string literals because the number and string types are not represented as unions
// of all their possible values.
var matchingTypes = void 0;
for (var _b = 0, _c = source.types; _b < _c.length; _b++) {
var t = _c[_b];
if (typeIdenticalToSomeType(t, target.types)) {
(matchingTypes || (matchingTypes = [])).push(t);
inferFromTypes(t, t);
}
else if (t.flags & (64 /* NumberLiteral */ | 32 /* StringLiteral */)) {
var b = getBaseTypeOfLiteralType(t);
if (typeIdenticalToSomeType(b, target.types)) {
(matchingTypes || (matchingTypes = [])).push(t, b);
}
}
}
// Next, to improve the quality of inferences, reduce the source and target types by
// removing the identically matched constituents. For example, when inferring from
// 'string | string[]' to 'string | T' we reduce the types to 'string[]' and 'T'.
if (matchingTypes) {
source = removeTypesFromUnionOrIntersection(source, matchingTypes);
target = removeTypesFromUnionOrIntersection(target, matchingTypes);
}
}
if (target.flags & 16384 /* TypeParameter */) {
// If target is a type parameter, make an inference, unless the source type contains
// the anyFunctionType (the wildcard type that's used to avoid contextually typing functions).
// Because the anyFunctionType is internal, it should not be exposed to the user by adding
// it as an inference candidate. Hopefully, a better candidate will come along that does
// not contain anyFunctionType when we come back to this argument for its second round
// of inference.
if (source.flags & 8388608 /* ContainsAnyFunctionType */) {
return;
}
for (var i = 0; i < typeParameters.length; i++) {
if (target === typeParameters[i]) {
var inferences = context.inferences[i];
if (!inferences.isFixed) {
// Any inferences that are made to a type parameter in a union type are inferior
// to inferences made to a flat (non-union) type. This is because if we infer to
// T | string[], we really don't know if we should be inferring to T or not (because
// the correct constituent on the target side could be string[]). Therefore, we put
// such inferior inferences into a secondary bucket, and only use them if the primary
// bucket is empty.
var candidates = inferiority ?
inferences.secondary || (inferences.secondary = []) :
inferences.primary || (inferences.primary = []);
if (!ts.contains(candidates, source)) {
candidates.push(source);
}
if (!isTypeParameterAtTopLevel(originalTarget, target)) {
inferences.topLevel = false;
}
}
return;
}
}
}
else if (getObjectFlags(source) & 4 /* Reference */ && getObjectFlags(target) & 4 /* Reference */ && source.target === target.target) {
// If source and target are references to the same generic type, infer from type arguments
var sourceTypes = source.typeArguments || emptyArray;
var targetTypes = target.typeArguments || emptyArray;
var count = sourceTypes.length < targetTypes.length ? sourceTypes.length : targetTypes.length;
for (var i = 0; i < count; i++) {
inferFromTypes(sourceTypes[i], targetTypes[i]);
}
}
else if (target.flags & 196608 /* UnionOrIntersection */) {
var targetTypes = target.types;
var typeParameterCount = 0;
var typeParameter = void 0;
// First infer to each type in union or intersection that isn't a type parameter
for (var _d = 0, targetTypes_2 = targetTypes; _d < targetTypes_2.length; _d++) {
var t = targetTypes_2[_d];
if (t.flags & 16384 /* TypeParameter */ && ts.contains(typeParameters, t)) {
typeParameter = t;
typeParameterCount++;
}
else {
inferFromTypes(source, t);
}
}
// Next, if target containings a single naked type parameter, make a secondary inference to that type
// parameter. This gives meaningful results for union types in co-variant positions and intersection
// types in contra-variant positions (such as callback parameters).
if (typeParameterCount === 1) {
inferiority++;
inferFromTypes(source, typeParameter);
inferiority--;
}
}
else if (source.flags & 196608 /* UnionOrIntersection */) {
// Source is a union or intersection type, infer from each constituent type
var sourceTypes = source.types;
for (var _e = 0, sourceTypes_3 = sourceTypes; _e < sourceTypes_3.length; _e++) {
var sourceType = sourceTypes_3[_e];
inferFromTypes(sourceType, target);
}
}
else {
if (getObjectFlags(target) & 32 /* Mapped */) {
var constraintType = getConstraintTypeFromMappedType(target);
if (getObjectFlags(source) & 32 /* Mapped */) {
inferFromTypes(getConstraintTypeFromMappedType(source), constraintType);
inferFromTypes(getTemplateTypeFromMappedType(source), getTemplateTypeFromMappedType(target));
return;
}
if (constraintType.flags & 16384 /* TypeParameter */) {
inferFromTypes(getIndexType(source), constraintType);
inferFromTypes(getUnionType(ts.map(getPropertiesOfType(source), getTypeOfSymbol)), getTemplateTypeFromMappedType(target));
return;
}
}
source = getApparentType(source);
if (source.flags & 32768 /* Object */) {
if (isInProcess(source, target)) {
return;
}
if (isDeeplyNestedGeneric(source, sourceStack, depth) && isDeeplyNestedGeneric(target, targetStack, depth)) {
return;
}
var key = source.id + "," + target.id;
if (visited[key]) {
return;
}
visited[key] = true;
if (depth === 0) {
sourceStack = [];
targetStack = [];
}
sourceStack[depth] = source;
targetStack[depth] = target;
depth++;
inferFromProperties(source, target);
inferFromSignatures(source, target, 0 /* Call */);
inferFromSignatures(source, target, 1 /* Construct */);
inferFromIndexTypes(source, target);
depth--;
}
}
}
function inferFromProperties(source, target) {
var properties = getPropertiesOfObjectType(target);
for (var _i = 0, properties_4 = properties; _i < properties_4.length; _i++) {
var targetProp = properties_4[_i];
var sourceProp = getPropertyOfObjectType(source, targetProp.name);
if (sourceProp) {
inferFromTypes(getTypeOfSymbol(sourceProp), getTypeOfSymbol(targetProp));
}
}
}
function inferFromSignatures(source, target, kind) {
var sourceSignatures = getSignaturesOfType(source, kind);
var targetSignatures = getSignaturesOfType(target, kind);
var sourceLen = sourceSignatures.length;
var targetLen = targetSignatures.length;
var len = sourceLen < targetLen ? sourceLen : targetLen;
for (var i = 0; i < len; i++) {
inferFromSignature(getErasedSignature(sourceSignatures[sourceLen - len + i]), getErasedSignature(targetSignatures[targetLen - len + i]));
}
}
function inferFromParameterTypes(source, target) {
return inferFromTypes(source, target);
}
function inferFromSignature(source, target) {
forEachMatchingParameterType(source, target, inferFromParameterTypes);
if (source.typePredicate && target.typePredicate && source.typePredicate.kind === target.typePredicate.kind) {
inferFromTypes(source.typePredicate.type, target.typePredicate.type);
}
else {
inferFromTypes(getReturnTypeOfSignature(source), getReturnTypeOfSignature(target));
}
}
function inferFromIndexTypes(source, target) {
var targetStringIndexType = getIndexTypeOfType(target, 0 /* String */);
if (targetStringIndexType) {
var sourceIndexType = getIndexTypeOfType(source, 0 /* String */) ||
getImplicitIndexTypeOfType(source, 0 /* String */);
if (sourceIndexType) {
inferFromTypes(sourceIndexType, targetStringIndexType);
}
}
var targetNumberIndexType = getIndexTypeOfType(target, 1 /* Number */);
if (targetNumberIndexType) {
var sourceIndexType = getIndexTypeOfType(source, 1 /* Number */) ||
getIndexTypeOfType(source, 0 /* String */) ||
getImplicitIndexTypeOfType(source, 1 /* Number */);
if (sourceIndexType) {
inferFromTypes(sourceIndexType, targetNumberIndexType);
}
}
}
}
function typeIdenticalToSomeType(type, types) {
for (var _i = 0, types_10 = types; _i < types_10.length; _i++) {
var t = types_10[_i];
if (isTypeIdenticalTo(t, type)) {
return true;
}
}
return false;
}
/**
* Return a new union or intersection type computed by removing a given set of types
* from a given union or intersection type.
*/
function removeTypesFromUnionOrIntersection(type, typesToRemove) {
var reducedTypes = [];
for (var _i = 0, _a = type.types; _i < _a.length; _i++) {
var t = _a[_i];
if (!typeIdenticalToSomeType(t, typesToRemove)) {
reducedTypes.push(t);
}
}
return type.flags & 65536 /* Union */ ? getUnionType(reducedTypes) : getIntersectionType(reducedTypes);
}
function getInferenceCandidates(context, index) {
var inferences = context.inferences[index];
return inferences.primary || inferences.secondary || emptyArray;
}
function hasPrimitiveConstraint(type) {
var constraint = getConstraintOfTypeParameter(type);
return constraint && maybeTypeOfKind(constraint, 8190 /* Primitive */ | 262144 /* Index */);
}
function getInferredType(context, index) {
var inferredType = context.inferredTypes[index];
var inferenceSucceeded;
if (!inferredType) {
var inferences = getInferenceCandidates(context, index);
if (inferences.length) {
// We widen inferred literal types if
// all inferences were made to top-level ocurrences of the type parameter, and
// the type parameter has no constraint or its constraint includes no primitive or literal types, and
// the type parameter was fixed during inference or does not occur at top-level in the return type.
var signature = context.signature;
var widenLiteralTypes = context.inferences[index].topLevel &&
!hasPrimitiveConstraint(signature.typeParameters[index]) &&
(context.inferences[index].isFixed || !isTypeParameterAtTopLevel(getReturnTypeOfSignature(signature), signature.typeParameters[index]));
var baseInferences = widenLiteralTypes ? ts.sameMap(inferences, getWidenedLiteralType) : inferences;
// Infer widened union or supertype, or the unknown type for no common supertype
var unionOrSuperType = context.inferUnionTypes ? getUnionType(baseInferences, /*subtypeReduction*/ true) : getCommonSupertype(baseInferences);
inferredType = unionOrSuperType ? getWidenedType(unionOrSuperType) : unknownType;
inferenceSucceeded = !!unionOrSuperType;
}
else {
// Infer the empty object type when no inferences were made. It is important to remember that
// in this case, inference still succeeds, meaning there is no error for not having inference
// candidates. An inference error only occurs when there are *conflicting* candidates, i.e.
// candidates with no common supertype.
inferredType = emptyObjectType;
inferenceSucceeded = true;
}
context.inferredTypes[index] = inferredType;
// Only do the constraint check if inference succeeded (to prevent cascading errors)
if (inferenceSucceeded) {
var constraint = getConstraintOfTypeParameter(context.signature.typeParameters[index]);
if (constraint) {
var instantiatedConstraint = instantiateType(constraint, getInferenceMapper(context));
if (!isTypeAssignableTo(inferredType, getTypeWithThisArgument(instantiatedConstraint, inferredType))) {
context.inferredTypes[index] = inferredType = instantiatedConstraint;
}
}
}
else if (context.failedTypeParameterIndex === undefined || context.failedTypeParameterIndex > index) {
// If inference failed, it is necessary to record the index of the failed type parameter (the one we are on).
// It might be that inference has already failed on a later type parameter on a previous call to inferTypeArguments.
// So if this failure is on preceding type parameter, this type parameter is the new failure index.
context.failedTypeParameterIndex = index;
}
}
return inferredType;
}
function getInferredTypes(context) {
for (var i = 0; i < context.inferredTypes.length; i++) {
getInferredType(context, i);
}
return context.inferredTypes;
}
// EXPRESSION TYPE CHECKING
function getResolvedSymbol(node) {
var links = getNodeLinks(node);
if (!links.resolvedSymbol) {
links.resolvedSymbol = !ts.nodeIsMissing(node) && resolveName(node, node.text, 107455 /* Value */ | 1048576 /* ExportValue */, ts.Diagnostics.Cannot_find_name_0, node) || unknownSymbol;
}
return links.resolvedSymbol;
}
function isInTypeQuery(node) {
// TypeScript 1.0 spec (April 2014): 3.6.3
// A type query consists of the keyword typeof followed by an expression.
// The expression is restricted to a single identifier or a sequence of identifiers separated by periods
while (node) {
switch (node.kind) {
case 160 /* TypeQuery */:
return true;
case 70 /* Identifier */:
case 141 /* QualifiedName */:
node = node.parent;
continue;
default:
return false;
}
}
ts.Debug.fail("should not get here");
}
// Return the flow cache key for a "dotted name" (i.e. a sequence of identifiers
// separated by dots). The key consists of the id of the symbol referenced by the
// leftmost identifier followed by zero or more property names separated by dots.
// The result is undefined if the reference isn't a dotted name.
function getFlowCacheKey(node) {
if (node.kind === 70 /* Identifier */) {
var symbol = getResolvedSymbol(node);
return symbol !== unknownSymbol ? "" + getSymbolId(symbol) : undefined;
}
if (node.kind === 98 /* ThisKeyword */) {
return "0";
}
if (node.kind === 177 /* PropertyAccessExpression */) {
var key = getFlowCacheKey(node.expression);
return key && key + "." + node.name.text;
}
return undefined;
}
function getLeftmostIdentifierOrThis(node) {
switch (node.kind) {
case 70 /* Identifier */:
case 98 /* ThisKeyword */:
return node;
case 177 /* PropertyAccessExpression */:
return getLeftmostIdentifierOrThis(node.expression);
}
return undefined;
}
function isMatchingReference(source, target) {
switch (source.kind) {
case 70 /* Identifier */:
return target.kind === 70 /* Identifier */ && getResolvedSymbol(source) === getResolvedSymbol(target) ||
(target.kind === 223 /* VariableDeclaration */ || target.kind === 174 /* BindingElement */) &&
getExportSymbolOfValueSymbolIfExported(getResolvedSymbol(source)) === getSymbolOfNode(target);
case 98 /* ThisKeyword */:
return target.kind === 98 /* ThisKeyword */;
case 177 /* PropertyAccessExpression */:
return target.kind === 177 /* PropertyAccessExpression */ &&
source.name.text === target.name.text &&
isMatchingReference(source.expression, target.expression);
}
return false;
}
function containsMatchingReference(source, target) {
while (source.kind === 177 /* PropertyAccessExpression */) {
source = source.expression;
if (isMatchingReference(source, target)) {
return true;
}
}
return false;
}
// Return true if target is a property access xxx.yyy, source is a property access xxx.zzz, the declared
// type of xxx is a union type, and yyy is a property that is possibly a discriminant. We consider a property
// a possible discriminant if its type differs in the constituents of containing union type, and if every
// choice is a unit type or a union of unit types.
function containsMatchingReferenceDiscriminant(source, target) {
return target.kind === 177 /* PropertyAccessExpression */ &&
containsMatchingReference(source, target.expression) &&
isDiscriminantProperty(getDeclaredTypeOfReference(target.expression), target.name.text);
}
function getDeclaredTypeOfReference(expr) {
if (expr.kind === 70 /* Identifier */) {
return getTypeOfSymbol(getResolvedSymbol(expr));
}
if (expr.kind === 177 /* PropertyAccessExpression */) {
var type = getDeclaredTypeOfReference(expr.expression);
return type && getTypeOfPropertyOfType(type, expr.name.text);
}
return undefined;
}
function isDiscriminantProperty(type, name) {
if (type && type.flags & 65536 /* Union */) {
var prop = getUnionOrIntersectionProperty(type, name);
if (prop && prop.flags & 268435456 /* SyntheticProperty */) {
if (prop.isDiscriminantProperty === undefined) {
prop.isDiscriminantProperty = prop.hasNonUniformType && isLiteralType(getTypeOfSymbol(prop));
}
return prop.isDiscriminantProperty;
}
}
return false;
}
function isOrContainsMatchingReference(source, target) {
return isMatchingReference(source, target) || containsMatchingReference(source, target);
}
function hasMatchingArgument(callExpression, reference) {
if (callExpression.arguments) {
for (var _i = 0, _a = callExpression.arguments; _i < _a.length; _i++) {
var argument = _a[_i];
if (isOrContainsMatchingReference(reference, argument)) {
return true;
}
}
}
if (callExpression.expression.kind === 177 /* PropertyAccessExpression */ &&
isOrContainsMatchingReference(reference, callExpression.expression.expression)) {
return true;
}
return false;
}
function getFlowNodeId(flow) {
if (!flow.id) {
flow.id = nextFlowId;
nextFlowId++;
}
return flow.id;
}
function typeMaybeAssignableTo(source, target) {
if (!(source.flags & 65536 /* Union */)) {
return isTypeAssignableTo(source, target);
}
for (var _i = 0, _a = source.types; _i < _a.length; _i++) {
var t = _a[_i];
if (isTypeAssignableTo(t, target)) {
return true;
}
}
return false;
}
// Remove those constituent types of declaredType to which no constituent type of assignedType is assignable.
// For example, when a variable of type number | string | boolean is assigned a value of type number | boolean,
// we remove type string.
function getAssignmentReducedType(declaredType, assignedType) {
if (declaredType !== assignedType) {
if (assignedType.flags & 8192 /* Never */) {
return assignedType;
}
var reducedType = filterType(declaredType, function (t) { return typeMaybeAssignableTo(assignedType, t); });
if (!(reducedType.flags & 8192 /* Never */)) {
return reducedType;
}
}
return declaredType;
}
function getTypeFactsOfTypes(types) {
var result = 0 /* None */;
for (var _i = 0, types_11 = types; _i < types_11.length; _i++) {
var t = types_11[_i];
result |= getTypeFacts(t);
}
return result;
}
function isFunctionObjectType(type) {
// We do a quick check for a "bind" property before performing the more expensive subtype
// check. This gives us a quicker out in the common case where an object type is not a function.
var resolved = resolveStructuredTypeMembers(type);
return !!(resolved.callSignatures.length || resolved.constructSignatures.length ||
resolved.members["bind"] && isTypeSubtypeOf(type, globalFunctionType));
}
function getTypeFacts(type) {
var flags = type.flags;
if (flags & 2 /* String */) {
return strictNullChecks ? 4079361 /* StringStrictFacts */ : 4194049 /* StringFacts */;
}
if (flags & 32 /* StringLiteral */) {
return strictNullChecks ?
type.text === "" ? 3030785 /* EmptyStringStrictFacts */ : 1982209 /* NonEmptyStringStrictFacts */ :
type.text === "" ? 3145473 /* EmptyStringFacts */ : 4194049 /* NonEmptyStringFacts */;
}
if (flags & (4 /* Number */ | 16 /* Enum */)) {
return strictNullChecks ? 4079234 /* NumberStrictFacts */ : 4193922 /* NumberFacts */;
}
if (flags & (64 /* NumberLiteral */ | 256 /* EnumLiteral */)) {
var isZero = type.text === "0";
return strictNullChecks ?
isZero ? 3030658 /* ZeroStrictFacts */ : 1982082 /* NonZeroStrictFacts */ :
isZero ? 3145346 /* ZeroFacts */ : 4193922 /* NonZeroFacts */;
}
if (flags & 8 /* Boolean */) {
return strictNullChecks ? 4078980 /* BooleanStrictFacts */ : 4193668 /* BooleanFacts */;
}
if (flags & 136 /* BooleanLike */) {
return strictNullChecks ?
type === falseType ? 3030404 /* FalseStrictFacts */ : 1981828 /* TrueStrictFacts */ :
type === falseType ? 3145092 /* FalseFacts */ : 4193668 /* TrueFacts */;
}
if (flags & 32768 /* Object */) {
return isFunctionObjectType(type) ?
strictNullChecks ? 6164448 /* FunctionStrictFacts */ : 8376288 /* FunctionFacts */ :
strictNullChecks ? 6166480 /* ObjectStrictFacts */ : 8378320 /* ObjectFacts */;
}
if (flags & (1024 /* Void */ | 2048 /* Undefined */)) {
return 2457472 /* UndefinedFacts */;
}
if (flags & 4096 /* Null */) {
return 2340752 /* NullFacts */;
}
if (flags & 512 /* ESSymbol */) {
return strictNullChecks ? 1981320 /* SymbolStrictFacts */ : 4193160 /* SymbolFacts */;
}
if (flags & 16384 /* TypeParameter */) {
var constraint = getConstraintOfTypeParameter(type);
return getTypeFacts(constraint || emptyObjectType);
}
if (flags & 196608 /* UnionOrIntersection */) {
return getTypeFactsOfTypes(type.types);
}
return 8388607 /* All */;
}
function getTypeWithFacts(type, include) {
return filterType(type, function (t) { return (getTypeFacts(t) & include) !== 0; });
}
function getTypeWithDefault(type, defaultExpression) {
if (defaultExpression) {
var defaultType = checkExpression(defaultExpression);
return getUnionType([getTypeWithFacts(type, 131072 /* NEUndefined */), defaultType]);
}
return type;
}
function getTypeOfDestructuredProperty(type, name) {
var text = ts.getTextOfPropertyName(name);
return getTypeOfPropertyOfType(type, text) ||
isNumericLiteralName(text) && getIndexTypeOfType(type, 1 /* Number */) ||
getIndexTypeOfType(type, 0 /* String */) ||
unknownType;
}
function getTypeOfDestructuredArrayElement(type, index) {
return isTupleLikeType(type) && getTypeOfPropertyOfType(type, "" + index) ||
checkIteratedTypeOrElementType(type, /*errorNode*/ undefined, /*allowStringInput*/ false) ||
unknownType;
}
function getTypeOfDestructuredSpreadExpression(type) {
return createArrayType(checkIteratedTypeOrElementType(type, /*errorNode*/ undefined, /*allowStringInput*/ false) || unknownType);
}
function getAssignedTypeOfBinaryExpression(node) {
return node.parent.kind === 175 /* ArrayLiteralExpression */ || node.parent.kind === 257 /* PropertyAssignment */ ?
getTypeWithDefault(getAssignedType(node), node.right) :
checkExpression(node.right);
}
function getAssignedTypeOfArrayLiteralElement(node, element) {
return getTypeOfDestructuredArrayElement(getAssignedType(node), ts.indexOf(node.elements, element));
}
function getAssignedTypeOfSpreadExpression(node) {
return getTypeOfDestructuredSpreadExpression(getAssignedType(node.parent));
}
function getAssignedTypeOfPropertyAssignment(node) {
return getTypeOfDestructuredProperty(getAssignedType(node.parent), node.name);
}
function getAssignedTypeOfShorthandPropertyAssignment(node) {
return getTypeWithDefault(getAssignedTypeOfPropertyAssignment(node), node.objectAssignmentInitializer);
}
function getAssignedType(node) {
var parent = node.parent;
switch (parent.kind) {
case 212 /* ForInStatement */:
return stringType;
case 213 /* ForOfStatement */:
return checkRightHandSideOfForOf(parent.expression) || unknownType;
case 192 /* BinaryExpression */:
return getAssignedTypeOfBinaryExpression(parent);
case 186 /* DeleteExpression */:
return undefinedType;
case 175 /* ArrayLiteralExpression */:
return getAssignedTypeOfArrayLiteralElement(parent, node);
case 196 /* SpreadElement */:
return getAssignedTypeOfSpreadExpression(parent);
case 257 /* PropertyAssignment */:
return getAssignedTypeOfPropertyAssignment(parent);
case 258 /* ShorthandPropertyAssignment */:
return getAssignedTypeOfShorthandPropertyAssignment(parent);
}
return unknownType;
}
function getInitialTypeOfBindingElement(node) {
var pattern = node.parent;
var parentType = getInitialType(pattern.parent);
var type = pattern.kind === 172 /* ObjectBindingPattern */ ?
getTypeOfDestructuredProperty(parentType, node.propertyName || node.name) :
!node.dotDotDotToken ?
getTypeOfDestructuredArrayElement(parentType, ts.indexOf(pattern.elements, node)) :
getTypeOfDestructuredSpreadExpression(parentType);
return getTypeWithDefault(type, node.initializer);
}
function getTypeOfInitializer(node) {
// Return the cached type if one is available. If the type of the variable was inferred
// from its initializer, we'll already have cached the type. Otherwise we compute it now
// without caching such that transient types are reflected.
var links = getNodeLinks(node);
return links.resolvedType || checkExpression(node);
}
function getInitialTypeOfVariableDeclaration(node) {
if (node.initializer) {
return getTypeOfInitializer(node.initializer);
}
if (node.parent.parent.kind === 212 /* ForInStatement */) {
return stringType;
}
if (node.parent.parent.kind === 213 /* ForOfStatement */) {
return checkRightHandSideOfForOf(node.parent.parent.expression) || unknownType;
}
return unknownType;
}
function getInitialType(node) {
return node.kind === 223 /* VariableDeclaration */ ?
getInitialTypeOfVariableDeclaration(node) :
getInitialTypeOfBindingElement(node);
}
function getInitialOrAssignedType(node) {
return node.kind === 223 /* VariableDeclaration */ || node.kind === 174 /* BindingElement */ ?
getInitialType(node) :
getAssignedType(node);
}
function isEmptyArrayAssignment(node) {
return node.kind === 223 /* VariableDeclaration */ && node.initializer &&
isEmptyArrayLiteral(node.initializer) ||
node.kind !== 174 /* BindingElement */ && node.parent.kind === 192 /* BinaryExpression */ &&
isEmptyArrayLiteral(node.parent.right);
}
function getReferenceCandidate(node) {
switch (node.kind) {
case 183 /* ParenthesizedExpression */:
return getReferenceCandidate(node.expression);
case 192 /* BinaryExpression */:
switch (node.operatorToken.kind) {
case 57 /* EqualsToken */:
return getReferenceCandidate(node.left);
case 25 /* CommaToken */:
return getReferenceCandidate(node.right);
}
}
return node;
}
function getReferenceRoot(node) {
var parent = node.parent;
return parent.kind === 183 /* ParenthesizedExpression */ ||
parent.kind === 192 /* BinaryExpression */ && parent.operatorToken.kind === 57 /* EqualsToken */ && parent.left === node ||
parent.kind === 192 /* BinaryExpression */ && parent.operatorToken.kind === 25 /* CommaToken */ && parent.right === node ?
getReferenceRoot(parent) : node;
}
function getTypeOfSwitchClause(clause) {
if (clause.kind === 253 /* CaseClause */) {
var caseType = getRegularTypeOfLiteralType(checkExpression(clause.expression));
return isUnitType(caseType) ? caseType : undefined;
}
return neverType;
}
function getSwitchClauseTypes(switchStatement) {
var links = getNodeLinks(switchStatement);
if (!links.switchTypes) {
// If all case clauses specify expressions that have unit types, we return an array
// of those unit types. Otherwise we return an empty array.
var types = ts.map(switchStatement.caseBlock.clauses, getTypeOfSwitchClause);
links.switchTypes = !ts.contains(types, undefined) ? types : emptyArray;
}
return links.switchTypes;
}
function eachTypeContainedIn(source, types) {
return source.flags & 65536 /* Union */ ? !ts.forEach(source.types, function (t) { return !ts.contains(types, t); }) : ts.contains(types, source);
}
function isTypeSubsetOf(source, target) {
return source === target || target.flags & 65536 /* Union */ && isTypeSubsetOfUnion(source, target);
}
function isTypeSubsetOfUnion(source, target) {
if (source.flags & 65536 /* Union */) {
for (var _i = 0, _a = source.types; _i < _a.length; _i++) {
var t = _a[_i];
if (!containsType(target.types, t)) {
return false;
}
}
return true;
}
if (source.flags & 256 /* EnumLiteral */ && target.flags & 16 /* Enum */ && source.baseType === target) {
return true;
}
return containsType(target.types, source);
}
function forEachType(type, f) {
return type.flags & 65536 /* Union */ ? ts.forEach(type.types, f) : f(type);
}
function filterType(type, f) {
if (type.flags & 65536 /* Union */) {
var types = type.types;
var filtered = ts.filter(types, f);
return filtered === types ? type : getUnionTypeFromSortedList(filtered);
}
return f(type) ? type : neverType;
}
function mapType(type, f) {
return type.flags & 65536 /* Union */ ? getUnionType(ts.map(type.types, f)) : f(type);
}
function extractTypesOfKind(type, kind) {
return filterType(type, function (t) { return (t.flags & kind) !== 0; });
}
// Return a new type in which occurrences of the string and number primitive types in
// typeWithPrimitives have been replaced with occurrences of string literals and numeric
// literals in typeWithLiterals, respectively.
function replacePrimitivesWithLiterals(typeWithPrimitives, typeWithLiterals) {
if (isTypeSubsetOf(stringType, typeWithPrimitives) && maybeTypeOfKind(typeWithLiterals, 32 /* StringLiteral */) ||
isTypeSubsetOf(numberType, typeWithPrimitives) && maybeTypeOfKind(typeWithLiterals, 64 /* NumberLiteral */)) {
return mapType(typeWithPrimitives, function (t) {
return t.flags & 2 /* String */ ? extractTypesOfKind(typeWithLiterals, 2 /* String */ | 32 /* StringLiteral */) :
t.flags & 4 /* Number */ ? extractTypesOfKind(typeWithLiterals, 4 /* Number */ | 64 /* NumberLiteral */) :
t;
});
}
return typeWithPrimitives;
}
function isIncomplete(flowType) {
return flowType.flags === 0;
}
function getTypeFromFlowType(flowType) {
return flowType.flags === 0 ? flowType.type : flowType;
}
function createFlowType(type, incomplete) {
return incomplete ? { flags: 0, type: type } : type;
}
// An evolving array type tracks the element types that have so far been seen in an
// 'x.push(value)' or 'x[n] = value' operation along the control flow graph. Evolving
// array types are ultimately converted into manifest array types (using getFinalArrayType)
// and never escape the getFlowTypeOfReference function.
function createEvolvingArrayType(elementType) {
var result = createObjectType(256 /* EvolvingArray */);
result.elementType = elementType;
return result;
}
function getEvolvingArrayType(elementType) {
return evolvingArrayTypes[elementType.id] || (evolvingArrayTypes[elementType.id] = createEvolvingArrayType(elementType));
}
// When adding evolving array element types we do not perform subtype reduction. Instead,
// we defer subtype reduction until the evolving array type is finalized into a manifest
// array type.
function addEvolvingArrayElementType(evolvingArrayType, node) {
var elementType = getBaseTypeOfLiteralType(checkExpression(node));
return isTypeSubsetOf(elementType, evolvingArrayType.elementType) ? evolvingArrayType : getEvolvingArrayType(getUnionType([evolvingArrayType.elementType, elementType]));
}
function createFinalArrayType(elementType) {
return elementType.flags & 8192 /* Never */ ?
autoArrayType :
createArrayType(elementType.flags & 65536 /* Union */ ?
getUnionType(elementType.types, /*subtypeReduction*/ true) :
elementType);
}
// We perform subtype reduction upon obtaining the final array type from an evolving array type.
function getFinalArrayType(evolvingArrayType) {
return evolvingArrayType.finalArrayType || (evolvingArrayType.finalArrayType = createFinalArrayType(evolvingArrayType.elementType));
}
function finalizeEvolvingArrayType(type) {
return getObjectFlags(type) & 256 /* EvolvingArray */ ? getFinalArrayType(type) : type;
}
function getElementTypeOfEvolvingArrayType(type) {
return getObjectFlags(type) & 256 /* EvolvingArray */ ? type.elementType : neverType;
}
function isEvolvingArrayTypeList(types) {
var hasEvolvingArrayType = false;
for (var _i = 0, types_12 = types; _i < types_12.length; _i++) {
var t = types_12[_i];
if (!(t.flags & 8192 /* Never */)) {
if (!(getObjectFlags(t) & 256 /* EvolvingArray */)) {
return false;
}
hasEvolvingArrayType = true;
}
}
return hasEvolvingArrayType;
}
// At flow control branch or loop junctions, if the type along every antecedent code path
// is an evolving array type, we construct a combined evolving array type. Otherwise we
// finalize all evolving array types.
function getUnionOrEvolvingArrayType(types, subtypeReduction) {
return isEvolvingArrayTypeList(types) ?
getEvolvingArrayType(getUnionType(ts.map(types, getElementTypeOfEvolvingArrayType))) :
getUnionType(ts.sameMap(types, finalizeEvolvingArrayType), subtypeReduction);
}
// Return true if the given node is 'x' in an 'x.length', x.push(value)', 'x.unshift(value)' or
// 'x[n] = value' operation, where 'n' is an expression of type any, undefined, or a number-like type.
function isEvolvingArrayOperationTarget(node) {
var root = getReferenceRoot(node);
var parent = root.parent;
var isLengthPushOrUnshift = parent.kind === 177 /* PropertyAccessExpression */ && (parent.name.text === "length" ||
parent.parent.kind === 179 /* CallExpression */ && ts.isPushOrUnshiftIdentifier(parent.name));
var isElementAssignment = parent.kind === 178 /* ElementAccessExpression */ &&
parent.expression === root &&
parent.parent.kind === 192 /* BinaryExpression */ &&
parent.parent.operatorToken.kind === 57 /* EqualsToken */ &&
parent.parent.left === parent &&
!ts.isAssignmentTarget(parent.parent) &&
isTypeAnyOrAllConstituentTypesHaveKind(checkExpression(parent.argumentExpression), 340 /* NumberLike */ | 2048 /* Undefined */);
return isLengthPushOrUnshift || isElementAssignment;
}
function maybeTypePredicateCall(node) {
var links = getNodeLinks(node);
if (links.maybeTypePredicate === undefined) {
links.maybeTypePredicate = getMaybeTypePredicate(node);
}
return links.maybeTypePredicate;
}
function getMaybeTypePredicate(node) {
if (node.expression.kind !== 96 /* SuperKeyword */) {
var funcType = checkNonNullExpression(node.expression);
if (funcType !== silentNeverType) {
var apparentType = getApparentType(funcType);
if (apparentType !== unknownType) {
var callSignatures = getSignaturesOfType(apparentType, 0 /* Call */);
return !!ts.forEach(callSignatures, function (sig) { return sig.typePredicate; });
}
}
}
return false;
}
function getFlowTypeOfReference(reference, declaredType, assumeInitialized, flowContainer) {
var key;
if (!reference.flowNode || assumeInitialized && !(declaredType.flags & 1033215 /* Narrowable */)) {
return declaredType;
}
var initialType = assumeInitialized ? declaredType :
declaredType === autoType || declaredType === autoArrayType ? undefinedType :
includeFalsyTypes(declaredType, 2048 /* Undefined */);
var visitedFlowStart = visitedFlowCount;
var evolvedType = getTypeFromFlowType(getTypeAtFlowNode(reference.flowNode));
visitedFlowCount = visitedFlowStart;
// When the reference is 'x' in an 'x.length', 'x.push(value)', 'x.unshift(value)' or x[n] = value' operation,
// we give type 'any[]' to 'x' instead of using the type determined by control flow analysis such that operations
// on empty arrays are possible without implicit any errors and new element types can be inferred without
// type mismatch errors.
var resultType = getObjectFlags(evolvedType) & 256 /* EvolvingArray */ && isEvolvingArrayOperationTarget(reference) ? anyArrayType : finalizeEvolvingArrayType(evolvedType);
if (reference.parent.kind === 201 /* NonNullExpression */ && getTypeWithFacts(resultType, 524288 /* NEUndefinedOrNull */).flags & 8192 /* Never */) {
return declaredType;
}
return resultType;
function getTypeAtFlowNode(flow) {
while (true) {
if (flow.flags & 1024 /* Shared */) {
// We cache results of flow type resolution for shared nodes that were previously visited in
// the same getFlowTypeOfReference invocation. A node is considered shared when it is the
// antecedent of more than one node.
for (var i = visitedFlowStart; i < visitedFlowCount; i++) {
if (visitedFlowNodes[i] === flow) {
return visitedFlowTypes[i];
}
}
}
var type = void 0;
if (flow.flags & 16 /* Assignment */) {
type = getTypeAtFlowAssignment(flow);
if (!type) {
flow = flow.antecedent;
continue;
}
}
else if (flow.flags & 96 /* Condition */) {
type = getTypeAtFlowCondition(flow);
}
else if (flow.flags & 128 /* SwitchClause */) {
type = getTypeAtSwitchClause(flow);
}
else if (flow.flags & 12 /* Label */) {
if (flow.antecedents.length === 1) {
flow = flow.antecedents[0];
continue;
}
type = flow.flags & 4 /* BranchLabel */ ?
getTypeAtFlowBranchLabel(flow) :
getTypeAtFlowLoopLabel(flow);
}
else if (flow.flags & 256 /* ArrayMutation */) {
type = getTypeAtFlowArrayMutation(flow);
if (!type) {
flow = flow.antecedent;
continue;
}
}
else if (flow.flags & 2 /* Start */) {
// Check if we should continue with the control flow of the containing function.
var container = flow.container;
if (container && container !== flowContainer && reference.kind !== 177 /* PropertyAccessExpression */) {
flow = container.flowNode;
continue;
}
// At the top of the flow we have the initial type.
type = initialType;
}
else {
// Unreachable code errors are reported in the binding phase. Here we
// simply return the non-auto declared type to reduce follow-on errors.
type = convertAutoToAny(declaredType);
}
if (flow.flags & 1024 /* Shared */) {
// Record visited node and the associated type in the cache.
visitedFlowNodes[visitedFlowCount] = flow;
visitedFlowTypes[visitedFlowCount] = type;
visitedFlowCount++;
}
return type;
}
}
function getTypeAtFlowAssignment(flow) {
var node = flow.node;
// Assignments only narrow the computed type if the declared type is a union type. Thus, we
// only need to evaluate the assigned type if the declared type is a union type.
if (isMatchingReference(reference, node)) {
if (ts.getAssignmentTargetKind(node) === 2 /* Compound */) {
var flowType = getTypeAtFlowNode(flow.antecedent);
return createFlowType(getBaseTypeOfLiteralType(getTypeFromFlowType(flowType)), isIncomplete(flowType));
}
if (declaredType === autoType || declaredType === autoArrayType) {
if (isEmptyArrayAssignment(node)) {
return getEvolvingArrayType(neverType);
}
var assignedType = getBaseTypeOfLiteralType(getInitialOrAssignedType(node));
return isTypeAssignableTo(assignedType, declaredType) ? assignedType : anyArrayType;
}
if (declaredType.flags & 65536 /* Union */) {
return getAssignmentReducedType(declaredType, getInitialOrAssignedType(node));
}
return declaredType;
}
// We didn't have a direct match. However, if the reference is a dotted name, this
// may be an assignment to a left hand part of the reference. For example, for a
// reference 'x.y.z', we may be at an assignment to 'x.y' or 'x'. In that case,
// return the declared type.
if (containsMatchingReference(reference, node)) {
return declaredType;
}
// Assignment doesn't affect reference
return undefined;
}
function getTypeAtFlowArrayMutation(flow) {
var node = flow.node;
var expr = node.kind === 179 /* CallExpression */ ?
node.expression.expression :
node.left.expression;
if (isMatchingReference(reference, getReferenceCandidate(expr))) {
var flowType = getTypeAtFlowNode(flow.antecedent);
var type = getTypeFromFlowType(flowType);
if (getObjectFlags(type) & 256 /* EvolvingArray */) {
var evolvedType_1 = type;
if (node.kind === 179 /* CallExpression */) {
for (var _i = 0, _a = node.arguments; _i < _a.length; _i++) {
var arg = _a[_i];
evolvedType_1 = addEvolvingArrayElementType(evolvedType_1, arg);
}
}
else {
var indexType = checkExpression(node.left.argumentExpression);
if (isTypeAnyOrAllConstituentTypesHaveKind(indexType, 340 /* NumberLike */ | 2048 /* Undefined */)) {
evolvedType_1 = addEvolvingArrayElementType(evolvedType_1, node.right);
}
}
return evolvedType_1 === type ? flowType : createFlowType(evolvedType_1, isIncomplete(flowType));
}
return flowType;
}
return undefined;
}
function getTypeAtFlowCondition(flow) {
var flowType = getTypeAtFlowNode(flow.antecedent);
var type = getTypeFromFlowType(flowType);
if (type.flags & 8192 /* Never */) {
return flowType;
}
// If we have an antecedent type (meaning we're reachable in some way), we first
// attempt to narrow the antecedent type. If that produces the never type, and if
// the antecedent type is incomplete (i.e. a transient type in a loop), then we
// take the type guard as an indication that control *could* reach here once we
// have the complete type. We proceed by switching to the silent never type which
// doesn't report errors when operators are applied to it. Note that this is the
// *only* place a silent never type is ever generated.
var assumeTrue = (flow.flags & 32 /* TrueCondition */) !== 0;
var nonEvolvingType = finalizeEvolvingArrayType(type);
var narrowedType = narrowType(nonEvolvingType, flow.expression, assumeTrue);
if (narrowedType === nonEvolvingType) {
return flowType;
}
var incomplete = isIncomplete(flowType);
var resultType = incomplete && narrowedType.flags & 8192 /* Never */ ? silentNeverType : narrowedType;
return createFlowType(resultType, incomplete);
}
function getTypeAtSwitchClause(flow) {
var flowType = getTypeAtFlowNode(flow.antecedent);
var type = getTypeFromFlowType(flowType);
var expr = flow.switchStatement.expression;
if (isMatchingReference(reference, expr)) {
type = narrowTypeBySwitchOnDiscriminant(type, flow.switchStatement, flow.clauseStart, flow.clauseEnd);
}
else if (isMatchingReferenceDiscriminant(expr)) {
type = narrowTypeByDiscriminant(type, expr, function (t) { return narrowTypeBySwitchOnDiscriminant(t, flow.switchStatement, flow.clauseStart, flow.clauseEnd); });
}
return createFlowType(type, isIncomplete(flowType));
}
function getTypeAtFlowBranchLabel(flow) {
var antecedentTypes = [];
var subtypeReduction = false;
var seenIncomplete = false;
for (var _i = 0, _a = flow.antecedents; _i < _a.length; _i++) {
var antecedent = _a[_i];
var flowType = getTypeAtFlowNode(antecedent);
var type = getTypeFromFlowType(flowType);
// If the type at a particular antecedent path is the declared type and the
// reference is known to always be assigned (i.e. when declared and initial types
// are the same), there is no reason to process more antecedents since the only
// possible outcome is subtypes that will be removed in the final union type anyway.
if (type === declaredType && declaredType === initialType) {
return type;
}
if (!ts.contains(antecedentTypes, type)) {
antecedentTypes.push(type);
}
// If an antecedent type is not a subset of the declared type, we need to perform
// subtype reduction. This happens when a "foreign" type is injected into the control
// flow using the instanceof operator or a user defined type predicate.
if (!isTypeSubsetOf(type, declaredType)) {
subtypeReduction = true;
}
if (isIncomplete(flowType)) {
seenIncomplete = true;
}
}
return createFlowType(getUnionOrEvolvingArrayType(antecedentTypes, subtypeReduction), seenIncomplete);
}
function getTypeAtFlowLoopLabel(flow) {
// If we have previously computed the control flow type for the reference at
// this flow loop junction, return the cached type.
var id = getFlowNodeId(flow);
var cache = flowLoopCaches[id] || (flowLoopCaches[id] = ts.createMap());
if (!key) {
key = getFlowCacheKey(reference);
}
if (cache[key]) {
return cache[key];
}
// If this flow loop junction and reference are already being processed, return
// the union of the types computed for each branch so far, marked as incomplete.
// It is possible to see an empty array in cases where loops are nested and the
// back edge of the outer loop reaches an inner loop that is already being analyzed.
// In such cases we restart the analysis of the inner loop, which will then see
// a non-empty in-process array for the outer loop and eventually terminate because
// the first antecedent of a loop junction is always the non-looping control flow
// path that leads to the top.
for (var i = flowLoopStart; i < flowLoopCount; i++) {
if (flowLoopNodes[i] === flow && flowLoopKeys[i] === key && flowLoopTypes[i].length) {
return createFlowType(getUnionOrEvolvingArrayType(flowLoopTypes[i], /*subtypeReduction*/ false), /*incomplete*/ true);
}
}
// Add the flow loop junction and reference to the in-process stack and analyze
// each antecedent code path.
var antecedentTypes = [];
var subtypeReduction = false;
var firstAntecedentType;
flowLoopNodes[flowLoopCount] = flow;
flowLoopKeys[flowLoopCount] = key;
flowLoopTypes[flowLoopCount] = antecedentTypes;
for (var _i = 0, _a = flow.antecedents; _i < _a.length; _i++) {
var antecedent = _a[_i];
flowLoopCount++;
var flowType = getTypeAtFlowNode(antecedent);
flowLoopCount--;
if (!firstAntecedentType) {
firstAntecedentType = flowType;
}
var type = getTypeFromFlowType(flowType);
// If we see a value appear in the cache it is a sign that control flow analysis
// was restarted and completed by checkExpressionCached. We can simply pick up
// the resulting type and bail out.
if (cache[key]) {
return cache[key];
}
if (!ts.contains(antecedentTypes, type)) {
antecedentTypes.push(type);
}
// If an antecedent type is not a subset of the declared type, we need to perform
// subtype reduction. This happens when a "foreign" type is injected into the control
// flow using the instanceof operator or a user defined type predicate.
if (!isTypeSubsetOf(type, declaredType)) {
subtypeReduction = true;
}
// If the type at a particular antecedent path is the declared type there is no
// reason to process more antecedents since the only possible outcome is subtypes
// that will be removed in the final union type anyway.
if (type === declaredType) {
break;
}
}
// The result is incomplete if the first antecedent (the non-looping control flow path)
// is incomplete.
var result = getUnionOrEvolvingArrayType(antecedentTypes, subtypeReduction);
if (isIncomplete(firstAntecedentType)) {
return createFlowType(result, /*incomplete*/ true);
}
return cache[key] = result;
}
function isMatchingReferenceDiscriminant(expr) {
return expr.kind === 177 /* PropertyAccessExpression */ &&
declaredType.flags & 65536 /* Union */ &&
isMatchingReference(reference, expr.expression) &&
isDiscriminantProperty(declaredType, expr.name.text);
}
function narrowTypeByDiscriminant(type, propAccess, narrowType) {
var propName = propAccess.name.text;
var propType = getTypeOfPropertyOfType(type, propName);
var narrowedPropType = propType && narrowType(propType);
return propType === narrowedPropType ? type : filterType(type, function (t) { return isTypeComparableTo(getTypeOfPropertyOfType(t, propName), narrowedPropType); });
}
function narrowTypeByTruthiness(type, expr, assumeTrue) {
if (isMatchingReference(reference, expr)) {
return getTypeWithFacts(type, assumeTrue ? 1048576 /* Truthy */ : 2097152 /* Falsy */);
}
if (isMatchingReferenceDiscriminant(expr)) {
return narrowTypeByDiscriminant(type, expr, function (t) { return getTypeWithFacts(t, assumeTrue ? 1048576 /* Truthy */ : 2097152 /* Falsy */); });
}
if (containsMatchingReferenceDiscriminant(reference, expr)) {
return declaredType;
}
return type;
}
function narrowTypeByBinaryExpression(type, expr, assumeTrue) {
switch (expr.operatorToken.kind) {
case 57 /* EqualsToken */:
return narrowTypeByTruthiness(type, expr.left, assumeTrue);
case 31 /* EqualsEqualsToken */:
case 32 /* ExclamationEqualsToken */:
case 33 /* EqualsEqualsEqualsToken */:
case 34 /* ExclamationEqualsEqualsToken */:
var operator_1 = expr.operatorToken.kind;
var left_1 = getReferenceCandidate(expr.left);
var right_1 = getReferenceCandidate(expr.right);
if (left_1.kind === 187 /* TypeOfExpression */ && right_1.kind === 9 /* StringLiteral */) {
return narrowTypeByTypeof(type, left_1, operator_1, right_1, assumeTrue);
}
if (right_1.kind === 187 /* TypeOfExpression */ && left_1.kind === 9 /* StringLiteral */) {
return narrowTypeByTypeof(type, right_1, operator_1, left_1, assumeTrue);
}
if (isMatchingReference(reference, left_1)) {
return narrowTypeByEquality(type, operator_1, right_1, assumeTrue);
}
if (isMatchingReference(reference, right_1)) {
return narrowTypeByEquality(type, operator_1, left_1, assumeTrue);
}
if (isMatchingReferenceDiscriminant(left_1)) {
return narrowTypeByDiscriminant(type, left_1, function (t) { return narrowTypeByEquality(t, operator_1, right_1, assumeTrue); });
}
if (isMatchingReferenceDiscriminant(right_1)) {
return narrowTypeByDiscriminant(type, right_1, function (t) { return narrowTypeByEquality(t, operator_1, left_1, assumeTrue); });
}
if (containsMatchingReferenceDiscriminant(reference, left_1) || containsMatchingReferenceDiscriminant(reference, right_1)) {
return declaredType;
}
break;
case 92 /* InstanceOfKeyword */:
return narrowTypeByInstanceof(type, expr, assumeTrue);
case 25 /* CommaToken */:
return narrowType(type, expr.right, assumeTrue);
}
return type;
}
function narrowTypeByEquality(type, operator, value, assumeTrue) {
if (type.flags & 1 /* Any */) {
return type;
}
if (operator === 32 /* ExclamationEqualsToken */ || operator === 34 /* ExclamationEqualsEqualsToken */) {
assumeTrue = !assumeTrue;
}
var valueType = checkExpression(value);
if (valueType.flags & 6144 /* Nullable */) {
if (!strictNullChecks) {
return type;
}
var doubleEquals = operator === 31 /* EqualsEqualsToken */ || operator === 32 /* ExclamationEqualsToken */;
var facts = doubleEquals ?
assumeTrue ? 65536 /* EQUndefinedOrNull */ : 524288 /* NEUndefinedOrNull */ :
value.kind === 94 /* NullKeyword */ ?
assumeTrue ? 32768 /* EQNull */ : 262144 /* NENull */ :
assumeTrue ? 16384 /* EQUndefined */ : 131072 /* NEUndefined */;
return getTypeWithFacts(type, facts);
}
if (type.flags & 33281 /* NotUnionOrUnit */) {
return type;
}
if (assumeTrue) {
var narrowedType = filterType(type, function (t) { return areTypesComparable(t, valueType); });
return narrowedType.flags & 8192 /* Never */ ? type : replacePrimitivesWithLiterals(narrowedType, valueType);
}
if (isUnitType(valueType)) {
var regularType_1 = getRegularTypeOfLiteralType(valueType);
return filterType(type, function (t) { return getRegularTypeOfLiteralType(t) !== regularType_1; });
}
return type;
}
function narrowTypeByTypeof(type, typeOfExpr, operator, literal, assumeTrue) {
// We have '==', '!=', '====', or !==' operator with 'typeof xxx' and string literal operands
var target = getReferenceCandidate(typeOfExpr.expression);
if (!isMatchingReference(reference, target)) {
// For a reference of the form 'x.y', a 'typeof x === ...' type guard resets the
// narrowed type of 'y' to its declared type.
if (containsMatchingReference(reference, target)) {
return declaredType;
}
return type;
}
if (operator === 32 /* ExclamationEqualsToken */ || operator === 34 /* ExclamationEqualsEqualsToken */) {
assumeTrue = !assumeTrue;
}
if (assumeTrue && !(type.flags & 65536 /* Union */)) {
// We narrow a non-union type to an exact primitive type if the non-union type
// is a supertype of that primitive type. For example, type 'any' can be narrowed
// to one of the primitive types.
var targetType = typeofTypesByName[literal.text];
if (targetType && isTypeSubtypeOf(targetType, type)) {
return targetType;
}
}
var facts = assumeTrue ?
typeofEQFacts[literal.text] || 64 /* TypeofEQHostObject */ :
typeofNEFacts[literal.text] || 8192 /* TypeofNEHostObject */;
return getTypeWithFacts(type, facts);
}
function narrowTypeBySwitchOnDiscriminant(type, switchStatement, clauseStart, clauseEnd) {
// We only narrow if all case expressions specify values with unit types
var switchTypes = getSwitchClauseTypes(switchStatement);
if (!switchTypes.length) {
return type;
}
var clauseTypes = switchTypes.slice(clauseStart, clauseEnd);
var hasDefaultClause = clauseStart === clauseEnd || ts.contains(clauseTypes, neverType);
var discriminantType = getUnionType(clauseTypes);
var caseType = discriminantType.flags & 8192 /* Never */ ? neverType :
replacePrimitivesWithLiterals(filterType(type, function (t) { return isTypeComparableTo(discriminantType, t); }), discriminantType);
if (!hasDefaultClause) {
return caseType;
}
var defaultType = filterType(type, function (t) { return !(isUnitType(t) && ts.contains(switchTypes, getRegularTypeOfLiteralType(t))); });
return caseType.flags & 8192 /* Never */ ? defaultType : getUnionType([caseType, defaultType]);
}
function narrowTypeByInstanceof(type, expr, assumeTrue) {
var left = getReferenceCandidate(expr.left);
if (!isMatchingReference(reference, left)) {
// For a reference of the form 'x.y', an 'x instanceof T' type guard resets the
// narrowed type of 'y' to its declared type.
if (containsMatchingReference(reference, left)) {
return declaredType;
}
return type;
}
// Check that right operand is a function type with a prototype property
var rightType = checkExpression(expr.right);
if (!isTypeSubtypeOf(rightType, globalFunctionType)) {
return type;
}
var targetType;
var prototypeProperty = getPropertyOfType(rightType, "prototype");
if (prototypeProperty) {
// Target type is type of the prototype property
var prototypePropertyType = getTypeOfSymbol(prototypeProperty);
if (!isTypeAny(prototypePropertyType)) {
targetType = prototypePropertyType;
}
}
// Don't narrow from 'any' if the target type is exactly 'Object' or 'Function'
if (isTypeAny(type) && (targetType === globalObjectType || targetType === globalFunctionType)) {
return type;
}
if (!targetType) {
// Target type is type of construct signature
var constructSignatures = void 0;
if (getObjectFlags(rightType) & 2 /* Interface */) {
constructSignatures = resolveDeclaredMembers(rightType).declaredConstructSignatures;
}
else if (getObjectFlags(rightType) & 16 /* Anonymous */) {
constructSignatures = getSignaturesOfType(rightType, 1 /* Construct */);
}
if (constructSignatures && constructSignatures.length) {
targetType = getUnionType(ts.map(constructSignatures, function (signature) { return getReturnTypeOfSignature(getErasedSignature(signature)); }));
}
}
if (targetType) {
return getNarrowedType(type, targetType, assumeTrue);
}
return type;
}
function getNarrowedType(type, candidate, assumeTrue) {
if (!assumeTrue) {
return filterType(type, function (t) { return !isTypeInstanceOf(t, candidate); });
}
// If the current type is a union type, remove all constituents that couldn't be instances of
// the candidate type. If one or more constituents remain, return a union of those.
if (type.flags & 65536 /* Union */) {
var assignableType = filterType(type, function (t) { return isTypeInstanceOf(t, candidate); });
if (!(assignableType.flags & 8192 /* Never */)) {
return assignableType;
}
}
// If the candidate type is a subtype of the target type, narrow to the candidate type.
// Otherwise, if the target type is assignable to the candidate type, keep the target type.
// Otherwise, if the candidate type is assignable to the target type, narrow to the candidate
// type. Otherwise, the types are completely unrelated, so narrow to an intersection of the
// two types.
var targetType = type.flags & 16384 /* TypeParameter */ ? getApparentType(type) : type;
return isTypeSubtypeOf(candidate, type) ? candidate :
isTypeAssignableTo(type, candidate) ? type :
isTypeAssignableTo(candidate, targetType) ? candidate :
getIntersectionType([type, candidate]);
}
function narrowTypeByTypePredicate(type, callExpression, assumeTrue) {
if (!hasMatchingArgument(callExpression, reference) || !maybeTypePredicateCall(callExpression)) {
return type;
}
var signature = getResolvedSignature(callExpression);
var predicate = signature.typePredicate;
if (!predicate) {
return type;
}
// Don't narrow from 'any' if the predicate type is exactly 'Object' or 'Function'
if (isTypeAny(type) && (predicate.type === globalObjectType || predicate.type === globalFunctionType)) {
return type;
}
if (ts.isIdentifierTypePredicate(predicate)) {
var predicateArgument = callExpression.arguments[predicate.parameterIndex];
if (predicateArgument) {
if (isMatchingReference(reference, predicateArgument)) {
return getNarrowedType(type, predicate.type, assumeTrue);
}
if (containsMatchingReference(reference, predicateArgument)) {
return declaredType;
}
}
}
else {
var invokedExpression = ts.skipParentheses(callExpression.expression);
if (invokedExpression.kind === 178 /* ElementAccessExpression */ || invokedExpression.kind === 177 /* PropertyAccessExpression */) {
var accessExpression = invokedExpression;
var possibleReference = ts.skipParentheses(accessExpression.expression);
if (isMatchingReference(reference, possibleReference)) {
return getNarrowedType(type, predicate.type, assumeTrue);
}
if (containsMatchingReference(reference, possibleReference)) {
return declaredType;
}
}
}
return type;
}
// Narrow the given type based on the given expression having the assumed boolean value. The returned type
// will be a subtype or the same type as the argument.
function narrowType(type, expr, assumeTrue) {
switch (expr.kind) {
case 70 /* Identifier */:
case 98 /* ThisKeyword */:
case 177 /* PropertyAccessExpression */:
return narrowTypeByTruthiness(type, expr, assumeTrue);
case 179 /* CallExpression */:
return narrowTypeByTypePredicate(type, expr, assumeTrue);
case 183 /* ParenthesizedExpression */:
return narrowType(type, expr.expression, assumeTrue);
case 192 /* BinaryExpression */:
return narrowTypeByBinaryExpression(type, expr, assumeTrue);
case 190 /* PrefixUnaryExpression */:
if (expr.operator === 50 /* ExclamationToken */) {
return narrowType(type, expr.operand, !assumeTrue);
}
break;
}
return type;
}
}
function getTypeOfSymbolAtLocation(symbol, location) {
// If we have an identifier or a property access at the given location, if the location is
// an dotted name expression, and if the location is not an assignment target, obtain the type
// of the expression (which will reflect control flow analysis). If the expression indeed
// resolved to the given symbol, return the narrowed type.
if (location.kind === 70 /* Identifier */) {
if (ts.isRightSideOfQualifiedNameOrPropertyAccess(location)) {
location = location.parent;
}
if (ts.isPartOfExpression(location) && !ts.isAssignmentTarget(location)) {
var type = checkExpression(location);
if (getExportSymbolOfValueSymbolIfExported(getNodeLinks(location).resolvedSymbol) === symbol) {
return type;
}
}
}
// The location isn't a reference to the given symbol, meaning we're being asked
// a hypothetical question of what type the symbol would have if there was a reference
// to it at the given location. Since we have no control flow information for the
// hypothetical reference (control flow information is created and attached by the
// binder), we simply return the declared type of the symbol.
return getTypeOfSymbol(symbol);
}
function getControlFlowContainer(node) {
while (true) {
node = node.parent;
if (ts.isFunctionLike(node) && !ts.getImmediatelyInvokedFunctionExpression(node) ||
node.kind === 231 /* ModuleBlock */ ||
node.kind === 261 /* SourceFile */ ||
node.kind === 147 /* PropertyDeclaration */) {
return node;
}
}
}
// Check if a parameter is assigned anywhere within its declaring function.
function isParameterAssigned(symbol) {
var func = ts.getRootDeclaration(symbol.valueDeclaration).parent;
var links = getNodeLinks(func);
if (!(links.flags & 4194304 /* AssignmentsMarked */)) {
links.flags |= 4194304 /* AssignmentsMarked */;
if (!hasParentWithAssignmentsMarked(func)) {
markParameterAssignments(func);
}
}
return symbol.isAssigned || false;
}
function hasParentWithAssignmentsMarked(node) {
while (true) {
node = node.parent;
if (!node) {
return false;
}
if (ts.isFunctionLike(node) && getNodeLinks(node).flags & 4194304 /* AssignmentsMarked */) {
return true;
}
}
}
function markParameterAssignments(node) {
if (node.kind === 70 /* Identifier */) {
if (ts.isAssignmentTarget(node)) {
var symbol = getResolvedSymbol(node);
if (symbol.valueDeclaration && ts.getRootDeclaration(symbol.valueDeclaration).kind === 144 /* Parameter */) {
symbol.isAssigned = true;
}
}
}
else {
ts.forEachChild(node, markParameterAssignments);
}
}
function isConstVariable(symbol) {
return symbol.flags & 3 /* Variable */ && (getDeclarationNodeFlagsFromSymbol(symbol) & 2 /* Const */) !== 0 && getTypeOfSymbol(symbol) !== autoArrayType;
}
function checkIdentifier(node) {
var symbol = getResolvedSymbol(node);
if (symbol === unknownSymbol) {
return unknownType;
}
// As noted in ECMAScript 6 language spec, arrow functions never have an arguments objects.
// Although in down-level emit of arrow function, we emit it using function expression which means that
// arguments objects will be bound to the inner object; emitting arrow function natively in ES6, arguments objects
// will be bound to non-arrow function that contain this arrow function. This results in inconsistent behavior.
// To avoid that we will give an error to users if they use arguments objects in arrow function so that they
// can explicitly bound arguments objects
if (symbol === argumentsSymbol) {
var container = ts.getContainingFunction(node);
if (languageVersion < 2 /* ES2015 */) {
if (container.kind === 185 /* ArrowFunction */) {
error(node, ts.Diagnostics.The_arguments_object_cannot_be_referenced_in_an_arrow_function_in_ES3_and_ES5_Consider_using_a_standard_function_expression);
}
else if (ts.hasModifier(container, 256 /* Async */)) {
error(node, ts.Diagnostics.The_arguments_object_cannot_be_referenced_in_an_async_function_or_method_in_ES3_and_ES5_Consider_using_a_standard_function_or_method);
}
}
if (node.flags & 524288 /* AwaitContext */) {
getNodeLinks(container).flags |= 8192 /* CaptureArguments */;
}
return getTypeOfSymbol(symbol);
}
if (symbol.flags & 8388608 /* Alias */ && !isInTypeQuery(node) && !isConstEnumOrConstEnumOnlyModule(resolveAlias(symbol))) {
markAliasSymbolAsReferenced(symbol);
}
var localOrExportSymbol = getExportSymbolOfValueSymbolIfExported(symbol);
if (localOrExportSymbol.flags & 32 /* Class */) {
var declaration_1 = localOrExportSymbol.valueDeclaration;
// Due to the emit for class decorators, any reference to the class from inside of the class body
// must instead be rewritten to point to a temporary variable to avoid issues with the double-bind
// behavior of class names in ES6.
if (languageVersion === 2 /* ES2015 */
&& declaration_1.kind === 226 /* ClassDeclaration */
&& ts.nodeIsDecorated(declaration_1)) {
var container = ts.getContainingClass(node);
while (container !== undefined) {
if (container === declaration_1 && container.name !== node) {
getNodeLinks(declaration_1).flags |= 8388608 /* ClassWithConstructorReference */;
getNodeLinks(node).flags |= 16777216 /* ConstructorReferenceInClass */;
break;
}
container = ts.getContainingClass(container);
}
}
else if (declaration_1.kind === 197 /* ClassExpression */) {
// When we emit a class expression with static members that contain a reference
// to the constructor in the initializer, we will need to substitute that
// binding with an alias as the class name is not in scope.
var container = ts.getThisContainer(node, /*includeArrowFunctions*/ false);
while (container !== undefined) {
if (container.parent === declaration_1) {
if (container.kind === 147 /* PropertyDeclaration */ && ts.hasModifier(container, 32 /* Static */)) {
getNodeLinks(declaration_1).flags |= 8388608 /* ClassWithConstructorReference */;
getNodeLinks(node).flags |= 16777216 /* ConstructorReferenceInClass */;
}
break;
}
container = ts.getThisContainer(container, /*includeArrowFunctions*/ false);
}
}
}
checkCollisionWithCapturedSuperVariable(node, node);
checkCollisionWithCapturedThisVariable(node, node);
checkNestedBlockScopedBinding(node, symbol);
var type = getTypeOfSymbol(localOrExportSymbol);
var declaration = localOrExportSymbol.valueDeclaration;
var assignmentKind = ts.getAssignmentTargetKind(node);
if (assignmentKind) {
if (!(localOrExportSymbol.flags & 3 /* Variable */)) {
error(node, ts.Diagnostics.Cannot_assign_to_0_because_it_is_not_a_variable, symbolToString(symbol));
return unknownType;
}
if (isReadonlySymbol(localOrExportSymbol)) {
error(node, ts.Diagnostics.Cannot_assign_to_0_because_it_is_a_constant_or_a_read_only_property, symbolToString(symbol));
return unknownType;
}
}
// We only narrow variables and parameters occurring in a non-assignment position. For all other
// entities we simply return the declared type.
if (!(localOrExportSymbol.flags & 3 /* Variable */) || assignmentKind === 1 /* Definite */ || !declaration) {
return type;
}
// The declaration container is the innermost function that encloses the declaration of the variable
// or parameter. The flow container is the innermost function starting with which we analyze the control
// flow graph to determine the control flow based type.
var isParameter = ts.getRootDeclaration(declaration).kind === 144 /* Parameter */;
var declarationContainer = getControlFlowContainer(declaration);
var flowContainer = getControlFlowContainer(node);
var isOuterVariable = flowContainer !== declarationContainer;
// When the control flow originates in a function expression or arrow function and we are referencing
// a const variable or parameter from an outer function, we extend the origin of the control flow
// analysis to include the immediately enclosing function.
while (flowContainer !== declarationContainer && (flowContainer.kind === 184 /* FunctionExpression */ ||
flowContainer.kind === 185 /* ArrowFunction */ || ts.isObjectLiteralOrClassExpressionMethod(flowContainer)) &&
(isConstVariable(localOrExportSymbol) || isParameter && !isParameterAssigned(localOrExportSymbol))) {
flowContainer = getControlFlowContainer(flowContainer);
}
// We only look for uninitialized variables in strict null checking mode, and only when we can analyze
// the entire control flow graph from the variable's declaration (i.e. when the flow container and
// declaration container are the same).
var assumeInitialized = isParameter || isOuterVariable ||
type !== autoType && type !== autoArrayType && (!strictNullChecks || (type.flags & 1 /* Any */) !== 0) ||
ts.isInAmbientContext(declaration);
var flowType = getFlowTypeOfReference(node, type, assumeInitialized, flowContainer);
// A variable is considered uninitialized when it is possible to analyze the entire control flow graph
// from declaration to use, and when the variable's declared type doesn't include undefined but the
// control flow based type does include undefined.
if (type === autoType || type === autoArrayType) {
if (flowType === autoType || flowType === autoArrayType) {
if (compilerOptions.noImplicitAny) {
error(declaration.name, ts.Diagnostics.Variable_0_implicitly_has_type_1_in_some_locations_where_its_type_cannot_be_determined, symbolToString(symbol), typeToString(flowType));
error(node, ts.Diagnostics.Variable_0_implicitly_has_an_1_type, symbolToString(symbol), typeToString(flowType));
}
return convertAutoToAny(flowType);
}
}
else if (!assumeInitialized && !(getFalsyFlags(type) & 2048 /* Undefined */) && getFalsyFlags(flowType) & 2048 /* Undefined */) {
error(node, ts.Diagnostics.Variable_0_is_used_before_being_assigned, symbolToString(symbol));
// Return the declared type to reduce follow-on errors
return type;
}
return assignmentKind ? getBaseTypeOfLiteralType(flowType) : flowType;
}
function isInsideFunction(node, threshold) {
var current = node;
while (current && current !== threshold) {
if (ts.isFunctionLike(current)) {
return true;
}
current = current.parent;
}
return false;
}
function checkNestedBlockScopedBinding(node, symbol) {
if (languageVersion >= 2 /* ES2015 */ ||
(symbol.flags & (2 /* BlockScopedVariable */ | 32 /* Class */)) === 0 ||
symbol.valueDeclaration.parent.kind === 256 /* CatchClause */) {
return;
}
// 1. walk from the use site up to the declaration and check
// if there is anything function like between declaration and use-site (is binding/class is captured in function).
// 2. walk from the declaration up to the boundary of lexical environment and check
// if there is an iteration statement in between declaration and boundary (is binding/class declared inside iteration statement)
var container = ts.getEnclosingBlockScopeContainer(symbol.valueDeclaration);
var usedInFunction = isInsideFunction(node.parent, container);
var current = container;
var containedInIterationStatement = false;
while (current && !ts.nodeStartsNewLexicalEnvironment(current)) {
if (ts.isIterationStatement(current, /*lookInLabeledStatements*/ false)) {
containedInIterationStatement = true;
break;
}
current = current.parent;
}
if (containedInIterationStatement) {
if (usedInFunction) {
// mark iteration statement as containing block-scoped binding captured in some function
getNodeLinks(current).flags |= 65536 /* LoopWithCapturedBlockScopedBinding */;
}
// mark variables that are declared in loop initializer and reassigned inside the body of ForStatement.
// if body of ForStatement will be converted to function then we'll need a extra machinery to propagate reassigned values back.
if (container.kind === 211 /* ForStatement */ &&
ts.getAncestor(symbol.valueDeclaration, 224 /* VariableDeclarationList */).parent === container &&
isAssignedInBodyOfForStatement(node, container)) {
getNodeLinks(symbol.valueDeclaration).flags |= 2097152 /* NeedsLoopOutParameter */;
}
// set 'declared inside loop' bit on the block-scoped binding
getNodeLinks(symbol.valueDeclaration).flags |= 262144 /* BlockScopedBindingInLoop */;
}
if (usedInFunction) {
getNodeLinks(symbol.valueDeclaration).flags |= 131072 /* CapturedBlockScopedBinding */;
}
}
function isAssignedInBodyOfForStatement(node, container) {
var current = node;
// skip parenthesized nodes
while (current.parent.kind === 183 /* ParenthesizedExpression */) {
current = current.parent;
}
// check if node is used as LHS in some assignment expression
var isAssigned = false;
if (ts.isAssignmentTarget(current)) {
isAssigned = true;
}
else if ((current.parent.kind === 190 /* PrefixUnaryExpression */ || current.parent.kind === 191 /* PostfixUnaryExpression */)) {
var expr = current.parent;
isAssigned = expr.operator === 42 /* PlusPlusToken */ || expr.operator === 43 /* MinusMinusToken */;
}
if (!isAssigned) {
return false;
}
// at this point we know that node is the target of assignment
// now check that modification happens inside the statement part of the ForStatement
while (current !== container) {
if (current === container.statement) {
return true;
}
else {
current = current.parent;
}
}
return false;
}
function captureLexicalThis(node, container) {
getNodeLinks(node).flags |= 2 /* LexicalThis */;
if (container.kind === 147 /* PropertyDeclaration */ || container.kind === 150 /* Constructor */) {
var classNode = container.parent;
getNodeLinks(classNode).flags |= 4 /* CaptureThis */;
}
else {
getNodeLinks(container).flags |= 4 /* CaptureThis */;
}
}
function findFirstSuperCall(n) {
if (ts.isSuperCall(n)) {
return n;
}
else if (ts.isFunctionLike(n)) {
return undefined;
}
return ts.forEachChild(n, findFirstSuperCall);
}
/**
* Return a cached result if super-statement is already found.
* Otherwise, find a super statement in a given constructor function and cache the result in the node-links of the constructor
*
* @param constructor constructor-function to look for super statement
*/
function getSuperCallInConstructor(constructor) {
var links = getNodeLinks(constructor);
// Only trying to find super-call if we haven't yet tried to find one. Once we try, we will record the result
if (links.hasSuperCall === undefined) {
links.superCall = findFirstSuperCall(constructor.body);
links.hasSuperCall = links.superCall ? true : false;
}
return links.superCall;
}
/**
* Check if the given class-declaration extends null then return true.
* Otherwise, return false
* @param classDecl a class declaration to check if it extends null
*/
function classDeclarationExtendsNull(classDecl) {
var classSymbol = getSymbolOfNode(classDecl);
var classInstanceType = getDeclaredTypeOfSymbol(classSymbol);
var baseConstructorType = getBaseConstructorTypeOfClass(classInstanceType);
return baseConstructorType === nullWideningType;
}
function checkThisExpression(node) {
// Stop at the first arrow function so that we can
// tell whether 'this' needs to be captured.
var container = ts.getThisContainer(node, /* includeArrowFunctions */ true);
var needToCaptureLexicalThis = false;
if (container.kind === 150 /* Constructor */) {
var containingClassDecl = container.parent;
var baseTypeNode = ts.getClassExtendsHeritageClauseElement(containingClassDecl);
// If a containing class does not have extends clause or the class extends null
// skip checking whether super statement is called before "this" accessing.
if (baseTypeNode && !classDeclarationExtendsNull(containingClassDecl)) {
var superCall = getSuperCallInConstructor(container);
// We should give an error in the following cases:
// - No super-call
// - "this" is accessing before super-call.
// i.e super(this)
// this.x; super();
// We want to make sure that super-call is done before accessing "this" so that
// "this" is not accessed as a parameter of the super-call.
if (!superCall || superCall.end > node.pos) {
// In ES6, super inside constructor of class-declaration has to precede "this" accessing
error(node, ts.Diagnostics.super_must_be_called_before_accessing_this_in_the_constructor_of_a_derived_class);
}
}
}
// Now skip arrow functions to get the "real" owner of 'this'.
if (container.kind === 185 /* ArrowFunction */) {
container = ts.getThisContainer(container, /* includeArrowFunctions */ false);
// When targeting es6, arrow function lexically bind "this" so we do not need to do the work of binding "this" in emitted code
needToCaptureLexicalThis = (languageVersion < 2 /* ES2015 */);
}
switch (container.kind) {
case 230 /* ModuleDeclaration */:
error(node, ts.Diagnostics.this_cannot_be_referenced_in_a_module_or_namespace_body);
// do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks
break;
case 229 /* EnumDeclaration */:
error(node, ts.Diagnostics.this_cannot_be_referenced_in_current_location);
// do not return here so in case if lexical this is captured - it will be reflected in flags on NodeLinks
break;
case 150 /* Constructor */:
if (isInConstructorArgumentInitializer(node, container)) {
error(node, ts.Diagnostics.this_cannot_be_referenced_in_constructor_arguments);
}
break;
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
if (ts.getModifierFlags(container) & 32 /* Static */) {
error(node, ts.Diagnostics.this_cannot_be_referenced_in_a_static_property_initializer);
}
break;
case 142 /* ComputedPropertyName */:
error(node, ts.Diagnostics.this_cannot_be_referenced_in_a_computed_property_name);
break;
}
if (needToCaptureLexicalThis) {
captureLexicalThis(node, container);
}
if (ts.isFunctionLike(container) &&
(!isInParameterInitializerBeforeContainingFunction(node) || ts.getThisParameter(container))) {
// Note: a parameter initializer should refer to class-this unless function-this is explicitly annotated.
// If this is a function in a JS file, it might be a class method. Check if it's the RHS
// of a x.prototype.y = function [name]() { .... }
if (container.kind === 184 /* FunctionExpression */ &&
ts.isInJavaScriptFile(container.parent) &&
ts.getSpecialPropertyAssignmentKind(container.parent) === 3 /* PrototypeProperty */) {
// Get the 'x' of 'x.prototype.y = f' (here, 'f' is 'container')
var className = container.parent // x.prototype.y = f
.left // x.prototype.y
.expression // x.prototype
.expression; // x
var classSymbol = checkExpression(className).symbol;
if (classSymbol && classSymbol.members && (classSymbol.flags & 16 /* Function */)) {
return getInferredClassType(classSymbol);
}
}
var thisType = getThisTypeOfDeclaration(container) || getContextualThisParameterType(container);
if (thisType) {
return thisType;
}
}
if (ts.isClassLike(container.parent)) {
var symbol = getSymbolOfNode(container.parent);
var type = ts.hasModifier(container, 32 /* Static */) ? getTypeOfSymbol(symbol) : getDeclaredTypeOfSymbol(symbol).thisType;
return getFlowTypeOfReference(node, type, /*assumeInitialized*/ true, /*flowContainer*/ undefined);
}
if (ts.isInJavaScriptFile(node)) {
var type = getTypeForThisExpressionFromJSDoc(container);
if (type && type !== unknownType) {
return type;
}
}
if (compilerOptions.noImplicitThis) {
// With noImplicitThis, functions may not reference 'this' if it has type 'any'
error(node, ts.Diagnostics.this_implicitly_has_type_any_because_it_does_not_have_a_type_annotation);
}
return anyType;
}
function getTypeForThisExpressionFromJSDoc(node) {
var typeTag = ts.getJSDocTypeTag(node);
if (typeTag && typeTag.typeExpression && typeTag.typeExpression.type && typeTag.typeExpression.type.kind === 274 /* JSDocFunctionType */) {
var jsDocFunctionType = typeTag.typeExpression.type;
if (jsDocFunctionType.parameters.length > 0 && jsDocFunctionType.parameters[0].type.kind === 277 /* JSDocThisType */) {
return getTypeFromTypeNode(jsDocFunctionType.parameters[0].type);
}
}
}
function isInConstructorArgumentInitializer(node, constructorDecl) {
for (var n = node; n && n !== constructorDecl; n = n.parent) {
if (n.kind === 144 /* Parameter */) {
return true;
}
}
return false;
}
function checkSuperExpression(node) {
var isCallExpression = node.parent.kind === 179 /* CallExpression */ && node.parent.expression === node;
var container = ts.getSuperContainer(node, /*stopOnFunctions*/ true);
var needToCaptureLexicalThis = false;
// adjust the container reference in case if super is used inside arrow functions with arbitrarily deep nesting
if (!isCallExpression) {
while (container && container.kind === 185 /* ArrowFunction */) {
container = ts.getSuperContainer(container, /*stopOnFunctions*/ true);
needToCaptureLexicalThis = languageVersion < 2 /* ES2015 */;
}
}
var canUseSuperExpression = isLegalUsageOfSuperExpression(container);
var nodeCheckFlag = 0;
if (!canUseSuperExpression) {
// issue more specific error if super is used in computed property name
// class A { foo() { return "1" }}
// class B {
// [super.foo()]() {}
// }
var current = node;
while (current && current !== container && current.kind !== 142 /* ComputedPropertyName */) {
current = current.parent;
}
if (current && current.kind === 142 /* ComputedPropertyName */) {
error(node, ts.Diagnostics.super_cannot_be_referenced_in_a_computed_property_name);
}
else if (isCallExpression) {
error(node, ts.Diagnostics.Super_calls_are_not_permitted_outside_constructors_or_in_nested_functions_inside_constructors);
}
else if (!container || !container.parent || !(ts.isClassLike(container.parent) || container.parent.kind === 176 /* ObjectLiteralExpression */)) {
error(node, ts.Diagnostics.super_can_only_be_referenced_in_members_of_derived_classes_or_object_literal_expressions);
}
else {
error(node, ts.Diagnostics.super_property_access_is_permitted_only_in_a_constructor_member_function_or_member_accessor_of_a_derived_class);
}
return unknownType;
}
if ((ts.getModifierFlags(container) & 32 /* Static */) || isCallExpression) {
nodeCheckFlag = 512 /* SuperStatic */;
}
else {
nodeCheckFlag = 256 /* SuperInstance */;
}
getNodeLinks(node).flags |= nodeCheckFlag;
// Due to how we emit async functions, we need to specialize the emit for an async method that contains a `super` reference.
// This is due to the fact that we emit the body of an async function inside of a generator function. As generator
// functions cannot reference `super`, we emit a helper inside of the method body, but outside of the generator. This helper
// uses an arrow function, which is permitted to reference `super`.
//
// There are two primary ways we can access `super` from within an async method. The first is getting the value of a property
// or indexed access on super, either as part of a right-hand-side expression or call expression. The second is when setting the value
// of a property or indexed access, either as part of an assignment expression or destructuring assignment.
//
// The simplest case is reading a value, in which case we will emit something like the following:
//
// // ts
// ...
// async asyncMethod() {
// let x = await super.asyncMethod();
// return x;
// }
// ...
//
// // js
// ...
// asyncMethod() {
// const _super = name => super[name];
// return __awaiter(this, arguments, Promise, function *() {
// let x = yield _super("asyncMethod").call(this);
// return x;
// });
// }
// ...
//
// The more complex case is when we wish to assign a value, especially as part of a destructuring assignment. As both cases
// are legal in ES6, but also likely less frequent, we emit the same more complex helper for both scenarios:
//
// // ts
// ...
// async asyncMethod(ar: Promise<any[]>) {
// [super.a, super.b] = await ar;
// }
// ...
//
// // js
// ...
// asyncMethod(ar) {
// const _super = (function (geti, seti) {
// const cache = Object.create(null);
// return name => cache[name] || (cache[name] = { get value() { return geti(name); }, set value(v) { seti(name, v); } });
// })(name => super[name], (name, value) => super[name] = value);
// return __awaiter(this, arguments, Promise, function *() {
// [_super("a").value, _super("b").value] = yield ar;
// });
// }
// ...
//
// This helper creates an object with a "value" property that wraps the `super` property or indexed access for both get and set.
// This is required for destructuring assignments, as a call expression cannot be used as the target of a destructuring assignment
// while a property access can.
if (container.kind === 149 /* MethodDeclaration */ && ts.getModifierFlags(container) & 256 /* Async */) {
if (ts.isSuperProperty(node.parent) && ts.isAssignmentTarget(node.parent)) {
getNodeLinks(container).flags |= 4096 /* AsyncMethodWithSuperBinding */;
}
else {
getNodeLinks(container).flags |= 2048 /* AsyncMethodWithSuper */;
}
}
if (needToCaptureLexicalThis) {
// call expressions are allowed only in constructors so they should always capture correct 'this'
// super property access expressions can also appear in arrow functions -
// in this case they should also use correct lexical this
captureLexicalThis(node.parent, container);
}
if (container.parent.kind === 176 /* ObjectLiteralExpression */) {
if (languageVersion < 2 /* ES2015 */) {
error(node, ts.Diagnostics.super_is_only_allowed_in_members_of_object_literal_expressions_when_option_target_is_ES2015_or_higher);
return unknownType;
}
else {
// for object literal assume that type of 'super' is 'any'
return anyType;
}
}
// at this point the only legal case for parent is ClassLikeDeclaration
var classLikeDeclaration = container.parent;
var classType = getDeclaredTypeOfSymbol(getSymbolOfNode(classLikeDeclaration));
var baseClassType = classType && getBaseTypes(classType)[0];
if (!baseClassType) {
if (!ts.getClassExtendsHeritageClauseElement(classLikeDeclaration)) {
error(node, ts.Diagnostics.super_can_only_be_referenced_in_a_derived_class);
}
return unknownType;
}
if (container.kind === 150 /* Constructor */ && isInConstructorArgumentInitializer(node, container)) {
// issue custom error message for super property access in constructor arguments (to be aligned with old compiler)
error(node, ts.Diagnostics.super_cannot_be_referenced_in_constructor_arguments);
return unknownType;
}
return nodeCheckFlag === 512 /* SuperStatic */
? getBaseConstructorTypeOfClass(classType)
: getTypeWithThisArgument(baseClassType, classType.thisType);
function isLegalUsageOfSuperExpression(container) {
if (!container) {
return false;
}
if (isCallExpression) {
// TS 1.0 SPEC (April 2014): 4.8.1
// Super calls are only permitted in constructors of derived classes
return container.kind === 150 /* Constructor */;
}
else {
// TS 1.0 SPEC (April 2014)
// 'super' property access is allowed
// - In a constructor, instance member function, instance member accessor, or instance member variable initializer where this references a derived class instance
// - In a static member function or static member accessor
// topmost container must be something that is directly nested in the class declaration\object literal expression
if (ts.isClassLike(container.parent) || container.parent.kind === 176 /* ObjectLiteralExpression */) {
if (ts.getModifierFlags(container) & 32 /* Static */) {
return container.kind === 149 /* MethodDeclaration */ ||
container.kind === 148 /* MethodSignature */ ||
container.kind === 151 /* GetAccessor */ ||
container.kind === 152 /* SetAccessor */;
}
else {
return container.kind === 149 /* MethodDeclaration */ ||
container.kind === 148 /* MethodSignature */ ||
container.kind === 151 /* GetAccessor */ ||
container.kind === 152 /* SetAccessor */ ||
container.kind === 147 /* PropertyDeclaration */ ||
container.kind === 146 /* PropertySignature */ ||
container.kind === 150 /* Constructor */;
}
}
}
return false;
}
}
function getContextualThisParameterType(func) {
if (isContextSensitiveFunctionOrObjectLiteralMethod(func) && func.kind !== 185 /* ArrowFunction */) {
var contextualSignature = getContextualSignature(func);
if (contextualSignature) {
var thisParameter = contextualSignature.thisParameter;
if (thisParameter) {
return getTypeOfSymbol(thisParameter);
}
}
}
return undefined;
}
// Return contextual type of parameter or undefined if no contextual type is available
function getContextuallyTypedParameterType(parameter) {
var func = parameter.parent;
if (isContextSensitiveFunctionOrObjectLiteralMethod(func)) {
var iife = ts.getImmediatelyInvokedFunctionExpression(func);
if (iife) {
var indexOfParameter = ts.indexOf(func.parameters, parameter);
if (iife.arguments && indexOfParameter < iife.arguments.length) {
if (parameter.dotDotDotToken) {
var restTypes = [];
for (var i = indexOfParameter; i < iife.arguments.length; i++) {
restTypes.push(getWidenedLiteralType(checkExpression(iife.arguments[i])));
}
return createArrayType(getUnionType(restTypes));
}
var links = getNodeLinks(iife);
var cached = links.resolvedSignature;
links.resolvedSignature = anySignature;
var type = getWidenedLiteralType(checkExpression(iife.arguments[indexOfParameter]));
links.resolvedSignature = cached;
return type;
}
}
var contextualSignature = getContextualSignature(func);
if (contextualSignature) {
var funcHasRestParameters = ts.hasRestParameter(func);
var len = func.parameters.length - (funcHasRestParameters ? 1 : 0);
var indexOfParameter = ts.indexOf(func.parameters, parameter);
if (indexOfParameter < len) {
return getTypeAtPosition(contextualSignature, indexOfParameter);
}
// If last parameter is contextually rest parameter get its type
if (funcHasRestParameters &&
indexOfParameter === (func.parameters.length - 1) &&
isRestParameterIndex(contextualSignature, func.parameters.length - 1)) {
return getTypeOfSymbol(ts.lastOrUndefined(contextualSignature.parameters));
}
}
}
return undefined;
}
// In a variable, parameter or property declaration with a type annotation,
// the contextual type of an initializer expression is the type of the variable, parameter or property.
// Otherwise, in a parameter declaration of a contextually typed function expression,
// the contextual type of an initializer expression is the contextual type of the parameter.
// Otherwise, in a variable or parameter declaration with a binding pattern name,
// the contextual type of an initializer expression is the type implied by the binding pattern.
// Otherwise, in a binding pattern inside a variable or parameter declaration,
// the contextual type of an initializer expression is the type annotation of the containing declaration, if present.
function getContextualTypeForInitializerExpression(node) {
var declaration = node.parent;
if (node === declaration.initializer) {
if (declaration.type) {
return getTypeFromTypeNode(declaration.type);
}
if (declaration.kind === 144 /* Parameter */) {
var type = getContextuallyTypedParameterType(declaration);
if (type) {
return type;
}
}
if (ts.isBindingPattern(declaration.name)) {
return getTypeFromBindingPattern(declaration.name, /*includePatternInType*/ true, /*reportErrors*/ false);
}
if (ts.isBindingPattern(declaration.parent)) {
var parentDeclaration = declaration.parent.parent;
var name_20 = declaration.propertyName || declaration.name;
if (ts.isVariableLike(parentDeclaration) &&
parentDeclaration.type &&
!ts.isBindingPattern(name_20)) {
var text = ts.getTextOfPropertyName(name_20);
if (text) {
return getTypeOfPropertyOfType(getTypeFromTypeNode(parentDeclaration.type), text);
}
}
}
}
return undefined;
}
function getContextualTypeForReturnExpression(node) {
var func = ts.getContainingFunction(node);
if (ts.isAsyncFunctionLike(func)) {
var contextualReturnType = getContextualReturnType(func);
if (contextualReturnType) {
return getPromisedType(contextualReturnType);
}
return undefined;
}
if (func && !func.asteriskToken) {
return getContextualReturnType(func);
}
return undefined;
}
function getContextualTypeForYieldOperand(node) {
var func = ts.getContainingFunction(node);
if (func) {
var contextualReturnType = getContextualReturnType(func);
if (contextualReturnType) {
return node.asteriskToken
? contextualReturnType
: getElementTypeOfIterableIterator(contextualReturnType);
}
}
return undefined;
}
function isInParameterInitializerBeforeContainingFunction(node) {
while (node.parent && !ts.isFunctionLike(node.parent)) {
if (node.parent.kind === 144 /* Parameter */ && node.parent.initializer === node) {
return true;
}
node = node.parent;
}
return false;
}
function getContextualReturnType(functionDecl) {
// If the containing function has a return type annotation, is a constructor, or is a get accessor whose
// corresponding set accessor has a type annotation, return statements in the function are contextually typed
if (functionDecl.type ||
functionDecl.kind === 150 /* Constructor */ ||
functionDecl.kind === 151 /* GetAccessor */ && ts.getSetAccessorTypeAnnotationNode(ts.getDeclarationOfKind(functionDecl.symbol, 152 /* SetAccessor */))) {
return getReturnTypeOfSignature(getSignatureFromDeclaration(functionDecl));
}
// Otherwise, if the containing function is contextually typed by a function type with exactly one call signature
// and that call signature is non-generic, return statements are contextually typed by the return type of the signature
var signature = getContextualSignatureForFunctionLikeDeclaration(functionDecl);
if (signature) {
return getReturnTypeOfSignature(signature);
}
return undefined;
}
// In a typed function call, an argument or substitution expression is contextually typed by the type of the corresponding parameter.
function getContextualTypeForArgument(callTarget, arg) {
var args = getEffectiveCallArguments(callTarget);
var argIndex = ts.indexOf(args, arg);
if (argIndex >= 0) {
var signature = getResolvedOrAnySignature(callTarget);
return getTypeAtPosition(signature, argIndex);
}
return undefined;
}
function getContextualTypeForSubstitutionExpression(template, substitutionExpression) {
if (template.parent.kind === 181 /* TaggedTemplateExpression */) {
return getContextualTypeForArgument(template.parent, substitutionExpression);
}
return undefined;
}
function getContextualTypeForBinaryOperand(node) {
var binaryExpression = node.parent;
var operator = binaryExpression.operatorToken.kind;
if (operator >= 57 /* FirstAssignment */ && operator <= 69 /* LastAssignment */) {
// Don't do this for special property assignments to avoid circularity
if (ts.getSpecialPropertyAssignmentKind(binaryExpression) !== 0 /* None */) {
return undefined;
}
// In an assignment expression, the right operand is contextually typed by the type of the left operand.
if (node === binaryExpression.right) {
return checkExpression(binaryExpression.left);
}
}
else if (operator === 53 /* BarBarToken */) {
// When an || expression has a contextual type, the operands are contextually typed by that type. When an ||
// expression has no contextual type, the right operand is contextually typed by the type of the left operand.
var type = getContextualType(binaryExpression);
if (!type && node === binaryExpression.right) {
type = checkExpression(binaryExpression.left);
}
return type;
}
else if (operator === 52 /* AmpersandAmpersandToken */ || operator === 25 /* CommaToken */) {
if (node === binaryExpression.right) {
return getContextualType(binaryExpression);
}
}
return undefined;
}
// Apply a mapping function to a contextual type and return the resulting type. If the contextual type
// is a union type, the mapping function is applied to each constituent type and a union of the resulting
// types is returned.
function applyToContextualType(type, mapper) {
if (!(type.flags & 65536 /* Union */)) {
return mapper(type);
}
var types = type.types;
var mappedType;
var mappedTypes;
for (var _i = 0, types_13 = types; _i < types_13.length; _i++) {
var current = types_13[_i];
var t = mapper(current);
if (t) {
if (!mappedType) {
mappedType = t;
}
else if (!mappedTypes) {
mappedTypes = [mappedType, t];
}
else {
mappedTypes.push(t);
}
}
}
return mappedTypes ? getUnionType(mappedTypes) : mappedType;
}
function getTypeOfPropertyOfContextualType(type, name) {
return applyToContextualType(type, function (t) {
var prop = t.flags & 229376 /* StructuredType */ ? getPropertyOfType(t, name) : undefined;
return prop ? getTypeOfSymbol(prop) : undefined;
});
}
function getIndexTypeOfContextualType(type, kind) {
return applyToContextualType(type, function (t) { return getIndexTypeOfStructuredType(t, kind); });
}
// Return true if the given contextual type is a tuple-like type
function contextualTypeIsTupleLikeType(type) {
return !!(type.flags & 65536 /* Union */ ? ts.forEach(type.types, isTupleLikeType) : isTupleLikeType(type));
}
// In an object literal contextually typed by a type T, the contextual type of a property assignment is the type of
// the matching property in T, if one exists. Otherwise, it is the type of the numeric index signature in T, if one
// exists. Otherwise, it is the type of the string index signature in T, if one exists.
function getContextualTypeForObjectLiteralMethod(node) {
ts.Debug.assert(ts.isObjectLiteralMethod(node));
if (isInsideWithStatementBody(node)) {
// We cannot answer semantic questions within a with block, do not proceed any further
return undefined;
}
return getContextualTypeForObjectLiteralElement(node);
}
function getContextualTypeForObjectLiteralElement(element) {
var objectLiteral = element.parent;
var type = getApparentTypeOfContextualType(objectLiteral);
if (type) {
if (!ts.hasDynamicName(element)) {
// For a (non-symbol) computed property, there is no reason to look up the name
// in the type. It will just be "__computed", which does not appear in any
// SymbolTable.
var symbolName = getSymbolOfNode(element).name;
var propertyType = getTypeOfPropertyOfContextualType(type, symbolName);
if (propertyType) {
return propertyType;
}
}
return isNumericName(element.name) && getIndexTypeOfContextualType(type, 1 /* Number */) ||
getIndexTypeOfContextualType(type, 0 /* String */);
}
return undefined;
}
// In an array literal contextually typed by a type T, the contextual type of an element expression at index N is
// the type of the property with the numeric name N in T, if one exists. Otherwise, if T has a numeric index signature,
// it is the type of the numeric index signature in T. Otherwise, in ES6 and higher, the contextual type is the iterated
// type of T.
function getContextualTypeForElementExpression(node) {
var arrayLiteral = node.parent;
var type = getApparentTypeOfContextualType(arrayLiteral);
if (type) {
var index = ts.indexOf(arrayLiteral.elements, node);
return getTypeOfPropertyOfContextualType(type, "" + index)
|| getIndexTypeOfContextualType(type, 1 /* Number */)
|| (languageVersion >= 2 /* ES2015 */ ? getElementTypeOfIterable(type, /*errorNode*/ undefined) : undefined);
}
return undefined;
}
// In a contextually typed conditional expression, the true/false expressions are contextually typed by the same type.
function getContextualTypeForConditionalOperand(node) {
var conditional = node.parent;
return node === conditional.whenTrue || node === conditional.whenFalse ? getContextualType(conditional) : undefined;
}
function getContextualTypeForJsxAttribute(attribute) {
var kind = attribute.kind;
var jsxElement = attribute.parent;
var attrsType = getJsxElementAttributesType(jsxElement);
if (attribute.kind === 250 /* JsxAttribute */) {
if (!attrsType || isTypeAny(attrsType)) {
return undefined;
}
return getTypeOfPropertyOfType(attrsType, attribute.name.text);
}
else if (attribute.kind === 251 /* JsxSpreadAttribute */) {
return attrsType;
}
ts.Debug.fail("Expected JsxAttribute or JsxSpreadAttribute, got ts.SyntaxKind[" + kind + "]");
}
// Return the contextual type for a given expression node. During overload resolution, a contextual type may temporarily
// be "pushed" onto a node using the contextualType property.
function getApparentTypeOfContextualType(node) {
var type = getContextualType(node);
return type && getApparentType(type);
}
/**
* Woah! Do you really want to use this function?
*
* Unless you're trying to get the *non-apparent* type for a
* value-literal type or you're authoring relevant portions of this algorithm,
* you probably meant to use 'getApparentTypeOfContextualType'.
* Otherwise this may not be very useful.
*
* In cases where you *are* working on this function, you should understand
* when it is appropriate to use 'getContextualType' and 'getApparentTypeOfContextualType'.
*
* - Use 'getContextualType' when you are simply going to propagate the result to the expression.
* - Use 'getApparentTypeOfContextualType' when you're going to need the members of the type.
*
* @param node the expression whose contextual type will be returned.
* @returns the contextual type of an expression.
*/
function getContextualType(node) {
if (isInsideWithStatementBody(node)) {
// We cannot answer semantic questions within a with block, do not proceed any further
return undefined;
}
if (node.contextualType) {
return node.contextualType;
}
var parent = node.parent;
switch (parent.kind) {
case 223 /* VariableDeclaration */:
case 144 /* Parameter */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 174 /* BindingElement */:
return getContextualTypeForInitializerExpression(node);
case 185 /* ArrowFunction */:
case 216 /* ReturnStatement */:
return getContextualTypeForReturnExpression(node);
case 195 /* YieldExpression */:
return getContextualTypeForYieldOperand(parent);
case 179 /* CallExpression */:
case 180 /* NewExpression */:
return getContextualTypeForArgument(parent, node);
case 182 /* TypeAssertionExpression */:
case 200 /* AsExpression */:
return getTypeFromTypeNode(parent.type);
case 192 /* BinaryExpression */:
return getContextualTypeForBinaryOperand(node);
case 257 /* PropertyAssignment */:
case 258 /* ShorthandPropertyAssignment */:
return getContextualTypeForObjectLiteralElement(parent);
case 175 /* ArrayLiteralExpression */:
return getContextualTypeForElementExpression(node);
case 193 /* ConditionalExpression */:
return getContextualTypeForConditionalOperand(node);
case 202 /* TemplateSpan */:
ts.Debug.assert(parent.parent.kind === 194 /* TemplateExpression */);
return getContextualTypeForSubstitutionExpression(parent.parent, node);
case 183 /* ParenthesizedExpression */:
return getContextualType(parent);
case 252 /* JsxExpression */:
return getContextualType(parent);
case 250 /* JsxAttribute */:
case 251 /* JsxSpreadAttribute */:
return getContextualTypeForJsxAttribute(parent);
}
return undefined;
}
// If the given type is an object or union type, if that type has a single signature, and if
// that signature is non-generic, return the signature. Otherwise return undefined.
function getNonGenericSignature(type, node) {
var signatures = getSignaturesOfStructuredType(type, 0 /* Call */);
if (signatures.length === 1) {
var signature = signatures[0];
if (!signature.typeParameters && !isAritySmaller(signature, node)) {
return signature;
}
}
}
/** If the contextual signature has fewer parameters than the function expression, do not use it */
function isAritySmaller(signature, target) {
var targetParameterCount = 0;
for (; targetParameterCount < target.parameters.length; targetParameterCount++) {
var param = target.parameters[targetParameterCount];
if (param.initializer || param.questionToken || param.dotDotDotToken || isJSDocOptionalParameter(param)) {
break;
}
}
if (target.parameters.length && ts.parameterIsThisKeyword(target.parameters[0])) {
targetParameterCount--;
}
var sourceLength = signature.hasRestParameter ? Number.MAX_VALUE : signature.parameters.length;
return sourceLength < targetParameterCount;
}
function isFunctionExpressionOrArrowFunction(node) {
return node.kind === 184 /* FunctionExpression */ || node.kind === 185 /* ArrowFunction */;
}
function getContextualSignatureForFunctionLikeDeclaration(node) {
// Only function expressions, arrow functions, and object literal methods are contextually typed.
return isFunctionExpressionOrArrowFunction(node) || ts.isObjectLiteralMethod(node)
? getContextualSignature(node)
: undefined;
}
function getContextualTypeForFunctionLikeDeclaration(node) {
return ts.isObjectLiteralMethod(node) ?
getContextualTypeForObjectLiteralMethod(node) :
getApparentTypeOfContextualType(node);
}
// Return the contextual signature for a given expression node. A contextual type provides a
// contextual signature if it has a single call signature and if that call signature is non-generic.
// If the contextual type is a union type, get the signature from each type possible and if they are
// all identical ignoring their return type, the result is same signature but with return type as
// union type of return types from these signatures
function getContextualSignature(node) {
ts.Debug.assert(node.kind !== 149 /* MethodDeclaration */ || ts.isObjectLiteralMethod(node));
var type = getContextualTypeForFunctionLikeDeclaration(node);
if (!type) {
return undefined;
}
if (!(type.flags & 65536 /* Union */)) {
return getNonGenericSignature(type, node);
}
var signatureList;
var types = type.types;
for (var _i = 0, types_14 = types; _i < types_14.length; _i++) {
var current = types_14[_i];
var signature = getNonGenericSignature(current, node);
if (signature) {
if (!signatureList) {
// This signature will contribute to contextual union signature
signatureList = [signature];
}
else if (!compareSignaturesIdentical(signatureList[0], signature, /*partialMatch*/ false, /*ignoreThisTypes*/ true, /*ignoreReturnTypes*/ true, compareTypesIdentical)) {
// Signatures aren't identical, do not use
return undefined;
}
else {
// Use this signature for contextual union signature
signatureList.push(signature);
}
}
}
// Result is union of signatures collected (return type is union of return types of this signature set)
var result;
if (signatureList) {
result = cloneSignature(signatureList[0]);
// Clear resolved return type we possibly got from cloneSignature
result.resolvedReturnType = undefined;
result.unionSignatures = signatureList;
}
return result;
}
/**
* Detect if the mapper implies an inference context. Specifically, there are 4 possible values
* for a mapper. Let's go through each one of them:
*
* 1. undefined - this means we are not doing inferential typing, but we may do contextual typing,
* which could cause us to assign a parameter a type
* 2. identityMapper - means we want to avoid assigning a parameter a type, whether or not we are in
* inferential typing (context is undefined for the identityMapper)
* 3. a mapper created by createInferenceMapper - we are doing inferential typing, we want to assign
* types to parameters and fix type parameters (context is defined)
* 4. an instantiation mapper created by createTypeMapper or createTypeEraser - this should never be
* passed as the contextual mapper when checking an expression (context is undefined for these)
*
* isInferentialContext is detecting if we are in case 3
*/
function isInferentialContext(mapper) {
return mapper && mapper.context;
}
function checkSpreadExpression(node, contextualMapper) {
// It is usually not safe to call checkExpressionCached if we can be contextually typing.
// You can tell that we are contextually typing because of the contextualMapper parameter.
// While it is true that a spread element can have a contextual type, it does not do anything
// with this type. It is neither affected by it, nor does it propagate it to its operand.
// So the fact that contextualMapper is passed is not important, because the operand of a spread
// element is not contextually typed.
var arrayOrIterableType = checkExpressionCached(node.expression, contextualMapper);
return checkIteratedTypeOrElementType(arrayOrIterableType, node.expression, /*allowStringInput*/ false);
}
function hasDefaultValue(node) {
return (node.kind === 174 /* BindingElement */ && !!node.initializer) ||
(node.kind === 192 /* BinaryExpression */ && node.operatorToken.kind === 57 /* EqualsToken */);
}
function checkArrayLiteral(node, contextualMapper) {
var elements = node.elements;
var hasSpreadElement = false;
var elementTypes = [];
var inDestructuringPattern = ts.isAssignmentTarget(node);
for (var _i = 0, elements_1 = elements; _i < elements_1.length; _i++) {
var e = elements_1[_i];
if (inDestructuringPattern && e.kind === 196 /* SpreadElement */) {
// Given the following situation:
// var c: {};
// [...c] = ["", 0];
//
// c is represented in the tree as a spread element in an array literal.
// But c really functions as a rest element, and its purpose is to provide
// a contextual type for the right hand side of the assignment. Therefore,
// instead of calling checkExpression on "...c", which will give an error
// if c is not iterable/array-like, we need to act as if we are trying to
// get the contextual element type from it. So we do something similar to
// getContextualTypeForElementExpression, which will crucially not error
// if there is no index type / iterated type.
var restArrayType = checkExpression(e.expression, contextualMapper);
var restElementType = getIndexTypeOfType(restArrayType, 1 /* Number */) ||
(languageVersion >= 2 /* ES2015 */ ? getElementTypeOfIterable(restArrayType, /*errorNode*/ undefined) : undefined);
if (restElementType) {
elementTypes.push(restElementType);
}
}
else {
var type = checkExpressionForMutableLocation(e, contextualMapper);
elementTypes.push(type);
}
hasSpreadElement = hasSpreadElement || e.kind === 196 /* SpreadElement */;
}
if (!hasSpreadElement) {
// If array literal is actually a destructuring pattern, mark it as an implied type. We do this such
// that we get the same behavior for "var [x, y] = []" and "[x, y] = []".
if (inDestructuringPattern && elementTypes.length) {
var type = cloneTypeReference(createTupleType(elementTypes));
type.pattern = node;
return type;
}
var contextualType = getApparentTypeOfContextualType(node);
if (contextualType && contextualTypeIsTupleLikeType(contextualType)) {
var pattern = contextualType.pattern;
// If array literal is contextually typed by a binding pattern or an assignment pattern, pad the resulting
// tuple type with the corresponding binding or assignment element types to make the lengths equal.
if (pattern && (pattern.kind === 173 /* ArrayBindingPattern */ || pattern.kind === 175 /* ArrayLiteralExpression */)) {
var patternElements = pattern.elements;
for (var i = elementTypes.length; i < patternElements.length; i++) {
var patternElement = patternElements[i];
if (hasDefaultValue(patternElement)) {
elementTypes.push(contextualType.typeArguments[i]);
}
else {
if (patternElement.kind !== 198 /* OmittedExpression */) {
error(patternElement, ts.Diagnostics.Initializer_provides_no_value_for_this_binding_element_and_the_binding_element_has_no_default_value);
}
elementTypes.push(unknownType);
}
}
}
if (elementTypes.length) {
return createTupleType(elementTypes);
}
}
}
return createArrayType(elementTypes.length ?
getUnionType(elementTypes, /*subtypeReduction*/ true) :
strictNullChecks ? neverType : undefinedWideningType);
}
function isNumericName(name) {
return name.kind === 142 /* ComputedPropertyName */ ? isNumericComputedName(name) : isNumericLiteralName(name.text);
}
function isNumericComputedName(name) {
// It seems odd to consider an expression of type Any to result in a numeric name,
// but this behavior is consistent with checkIndexedAccess
return isTypeAnyOrAllConstituentTypesHaveKind(checkComputedPropertyName(name), 340 /* NumberLike */);
}
function isTypeAnyOrAllConstituentTypesHaveKind(type, kind) {
return isTypeAny(type) || isTypeOfKind(type, kind);
}
function isInfinityOrNaNString(name) {
return name === "Infinity" || name === "-Infinity" || name === "NaN";
}
function isNumericLiteralName(name) {
// The intent of numeric names is that
// - they are names with text in a numeric form, and that
// - setting properties/indexing with them is always equivalent to doing so with the numeric literal 'numLit',
// acquired by applying the abstract 'ToNumber' operation on the name's text.
//
// The subtlety is in the latter portion, as we cannot reliably say that anything that looks like a numeric literal is a numeric name.
// In fact, it is the case that the text of the name must be equal to 'ToString(numLit)' for this to hold.
//
// Consider the property name '"0xF00D"'. When one indexes with '0xF00D', they are actually indexing with the value of 'ToString(0xF00D)'
// according to the ECMAScript specification, so it is actually as if the user indexed with the string '"61453"'.
// Thus, the text of all numeric literals equivalent to '61543' such as '0xF00D', '0xf00D', '0170015', etc. are not valid numeric names
// because their 'ToString' representation is not equal to their original text.
// This is motivated by ECMA-262 sections 9.3.1, 9.8.1, 11.1.5, and 11.2.1.
//
// Here, we test whether 'ToString(ToNumber(name))' is exactly equal to 'name'.
// The '+' prefix operator is equivalent here to applying the abstract ToNumber operation.
// Applying the 'toString()' method on a number gives us the abstract ToString operation on a number.
//
// Note that this accepts the values 'Infinity', '-Infinity', and 'NaN', and that this is intentional.
// This is desired behavior, because when indexing with them as numeric entities, you are indexing
// with the strings '"Infinity"', '"-Infinity"', and '"NaN"' respectively.
return (+name).toString() === name;
}
function checkComputedPropertyName(node) {
var links = getNodeLinks(node.expression);
if (!links.resolvedType) {
links.resolvedType = checkExpression(node.expression);
// This will allow types number, string, symbol or any. It will also allow enums, the unknown
// type, and any union of these types (like string | number).
if (!isTypeAnyOrAllConstituentTypesHaveKind(links.resolvedType, 340 /* NumberLike */ | 34 /* StringLike */ | 512 /* ESSymbol */)) {
error(node, ts.Diagnostics.A_computed_property_name_must_be_of_type_string_number_symbol_or_any);
}
else {
checkThatExpressionIsProperSymbolReference(node.expression, links.resolvedType, /*reportError*/ true);
}
}
return links.resolvedType;
}
function getObjectLiteralIndexInfo(node, properties, kind) {
var propTypes = [];
for (var i = 0; i < properties.length; i++) {
if (kind === 0 /* String */ || isNumericName(node.properties[i].name)) {
propTypes.push(getTypeOfSymbol(properties[i]));
}
}
var unionType = propTypes.length ? getUnionType(propTypes, /*subtypeReduction*/ true) : undefinedType;
return createIndexInfo(unionType, /*isReadonly*/ false);
}
function checkObjectLiteral(node, contextualMapper) {
var inDestructuringPattern = ts.isAssignmentTarget(node);
// Grammar checking
checkGrammarObjectLiteralExpression(node, inDestructuringPattern);
var propertiesTable = ts.createMap();
var propertiesArray = [];
var spread = emptyObjectType;
var propagatedFlags = 0;
var contextualType = getApparentTypeOfContextualType(node);
var contextualTypeHasPattern = contextualType && contextualType.pattern &&
(contextualType.pattern.kind === 172 /* ObjectBindingPattern */ || contextualType.pattern.kind === 176 /* ObjectLiteralExpression */);
var typeFlags = 0;
var patternWithComputedProperties = false;
var hasComputedStringProperty = false;
var hasComputedNumberProperty = false;
for (var _i = 0, _a = node.properties; _i < _a.length; _i++) {
var memberDecl = _a[_i];
var member = memberDecl.symbol;
if (memberDecl.kind === 257 /* PropertyAssignment */ ||
memberDecl.kind === 258 /* ShorthandPropertyAssignment */ ||
ts.isObjectLiteralMethod(memberDecl)) {
var type = void 0;
if (memberDecl.kind === 257 /* PropertyAssignment */) {
type = checkPropertyAssignment(memberDecl, contextualMapper);
}
else if (memberDecl.kind === 149 /* MethodDeclaration */) {
type = checkObjectLiteralMethod(memberDecl, contextualMapper);
}
else {
ts.Debug.assert(memberDecl.kind === 258 /* ShorthandPropertyAssignment */);
type = checkExpressionForMutableLocation(memberDecl.name, contextualMapper);
}
typeFlags |= type.flags;
var prop = createSymbol(4 /* Property */ | 67108864 /* Transient */ | member.flags, member.name);
if (inDestructuringPattern) {
// If object literal is an assignment pattern and if the assignment pattern specifies a default value
// for the property, make the property optional.
var isOptional = (memberDecl.kind === 257 /* PropertyAssignment */ && hasDefaultValue(memberDecl.initializer)) ||
(memberDecl.kind === 258 /* ShorthandPropertyAssignment */ && memberDecl.objectAssignmentInitializer);
if (isOptional) {
prop.flags |= 536870912 /* Optional */;
}
if (ts.hasDynamicName(memberDecl)) {
patternWithComputedProperties = true;
}
}
else if (contextualTypeHasPattern && !(getObjectFlags(contextualType) & 512 /* ObjectLiteralPatternWithComputedProperties */)) {
// If object literal is contextually typed by the implied type of a binding pattern, and if the
// binding pattern specifies a default value for the property, make the property optional.
var impliedProp = getPropertyOfType(contextualType, member.name);
if (impliedProp) {
prop.flags |= impliedProp.flags & 536870912 /* Optional */;
}
else if (!compilerOptions.suppressExcessPropertyErrors) {
error(memberDecl.name, ts.Diagnostics.Object_literal_may_only_specify_known_properties_and_0_does_not_exist_in_type_1, symbolToString(member), typeToString(contextualType));
}
}
prop.declarations = member.declarations;
prop.parent = member.parent;
if (member.valueDeclaration) {
prop.valueDeclaration = member.valueDeclaration;
}
prop.type = type;
prop.target = member;
member = prop;
}
else if (memberDecl.kind === 259 /* SpreadAssignment */) {
if (propertiesArray.length > 0) {
spread = getSpreadType(spread, createObjectLiteralType(), /*isFromObjectLiteral*/ true);
propertiesArray = [];
propertiesTable = ts.createMap();
hasComputedStringProperty = false;
hasComputedNumberProperty = false;
typeFlags = 0;
}
var type = checkExpression(memberDecl.expression);
if (!(type.flags & (32768 /* Object */ | 1 /* Any */))) {
error(memberDecl, ts.Diagnostics.Spread_types_may_only_be_created_from_object_types);
return unknownType;
}
spread = getSpreadType(spread, type, /*isFromObjectLiteral*/ false);
continue;
}
else {
// TypeScript 1.0 spec (April 2014)
// A get accessor declaration is processed in the same manner as
// an ordinary function declaration(section 6.1) with no parameters.
// A set accessor declaration is processed in the same manner
// as an ordinary function declaration with a single parameter and a Void return type.
ts.Debug.assert(memberDecl.kind === 151 /* GetAccessor */ || memberDecl.kind === 152 /* SetAccessor */);
checkAccessorDeclaration(memberDecl);
}
if (ts.hasDynamicName(memberDecl)) {
if (isNumericName(memberDecl.name)) {
hasComputedNumberProperty = true;
}
else {
hasComputedStringProperty = true;
}
}
else {
propertiesTable[member.name] = member;
}
propertiesArray.push(member);
}
// If object literal is contextually typed by the implied type of a binding pattern, augment the result
// type with those properties for which the binding pattern specifies a default value.
if (contextualTypeHasPattern) {
for (var _b = 0, _c = getPropertiesOfType(contextualType); _b < _c.length; _b++) {
var prop = _c[_b];
if (!propertiesTable[prop.name]) {
if (!(prop.flags & 536870912 /* Optional */)) {
error(prop.valueDeclaration || prop.bindingElement, ts.Diagnostics.Initializer_provides_no_value_for_this_binding_element_and_the_binding_element_has_no_default_value);
}
propertiesTable[prop.name] = prop;
propertiesArray.push(prop);
}
}
}
if (spread !== emptyObjectType) {
if (propertiesArray.length > 0) {
spread = getSpreadType(spread, createObjectLiteralType(), /*isFromObjectLiteral*/ true);
}
spread.flags |= propagatedFlags;
spread.symbol = node.symbol;
return spread;
}
return createObjectLiteralType();
function createObjectLiteralType() {
var stringIndexInfo = hasComputedStringProperty ? getObjectLiteralIndexInfo(node, propertiesArray, 0 /* String */) : undefined;
var numberIndexInfo = hasComputedNumberProperty ? getObjectLiteralIndexInfo(node, propertiesArray, 1 /* Number */) : undefined;
var result = createAnonymousType(node.symbol, propertiesTable, emptyArray, emptyArray, stringIndexInfo, numberIndexInfo);
var freshObjectLiteralFlag = compilerOptions.suppressExcessPropertyErrors ? 0 : 1048576 /* FreshLiteral */;
result.flags |= 4194304 /* ContainsObjectLiteral */ | freshObjectLiteralFlag | (typeFlags & 14680064 /* PropagatingFlags */);
result.objectFlags |= 128 /* ObjectLiteral */;
if (patternWithComputedProperties) {
result.objectFlags |= 512 /* ObjectLiteralPatternWithComputedProperties */;
}
if (inDestructuringPattern) {
result.pattern = node;
}
if (!(result.flags & 6144 /* Nullable */)) {
propagatedFlags |= (result.flags & 14680064 /* PropagatingFlags */);
}
return result;
}
}
function checkJsxSelfClosingElement(node) {
checkJsxOpeningLikeElement(node);
return jsxElementType || anyType;
}
function checkJsxElement(node) {
// Check attributes
checkJsxOpeningLikeElement(node.openingElement);
// Perform resolution on the closing tag so that rename/go to definition/etc work
if (isJsxIntrinsicIdentifier(node.closingElement.tagName)) {
getIntrinsicTagSymbol(node.closingElement);
}
else {
checkExpression(node.closingElement.tagName);
}
// Check children
for (var _i = 0, _a = node.children; _i < _a.length; _i++) {
var child = _a[_i];
switch (child.kind) {
case 252 /* JsxExpression */:
checkJsxExpression(child);
break;
case 246 /* JsxElement */:
checkJsxElement(child);
break;
case 247 /* JsxSelfClosingElement */:
checkJsxSelfClosingElement(child);
break;
}
}
return jsxElementType || anyType;
}
/**
* Returns true iff the JSX element name would be a valid JS identifier, ignoring restrictions about keywords not being identifiers
*/
function isUnhyphenatedJsxName(name) {
// - is the only character supported in JSX attribute names that isn't valid in JavaScript identifiers
return name.indexOf("-") < 0;
}
/**
* Returns true iff React would emit this tag name as a string rather than an identifier or qualified name
*/
function isJsxIntrinsicIdentifier(tagName) {
// TODO (yuisu): comment
if (tagName.kind === 177 /* PropertyAccessExpression */ || tagName.kind === 98 /* ThisKeyword */) {
return false;
}
else {
return ts.isIntrinsicJsxName(tagName.text);
}
}
function checkJsxAttribute(node, elementAttributesType, nameTable) {
var correspondingPropType = undefined;
// Look up the corresponding property for this attribute
if (elementAttributesType === emptyObjectType && isUnhyphenatedJsxName(node.name.text)) {
// If there is no 'props' property, you may not have non-"data-" attributes
error(node.parent, ts.Diagnostics.JSX_element_class_does_not_support_attributes_because_it_does_not_have_a_0_property, getJsxElementPropertiesName());
}
else if (elementAttributesType && !isTypeAny(elementAttributesType)) {
var correspondingPropSymbol = getPropertyOfType(elementAttributesType, node.name.text);
correspondingPropType = correspondingPropSymbol && getTypeOfSymbol(correspondingPropSymbol);
if (isUnhyphenatedJsxName(node.name.text)) {
var attributeType = getTypeOfPropertyOfType(elementAttributesType, ts.getTextOfPropertyName(node.name)) || getIndexTypeOfType(elementAttributesType, 0 /* String */);
if (attributeType) {
correspondingPropType = attributeType;
}
else {
// If there's no corresponding property with this name, error
if (!correspondingPropType) {
error(node.name, ts.Diagnostics.Property_0_does_not_exist_on_type_1, node.name.text, typeToString(elementAttributesType));
return unknownType;
}
}
}
}
var exprType;
if (node.initializer) {
exprType = checkExpression(node.initializer);
}
else {
// <Elem attr /> is sugar for <Elem attr={true} />
exprType = booleanType;
}
if (correspondingPropType) {
checkTypeAssignableTo(exprType, correspondingPropType, node);
}
nameTable[node.name.text] = true;
return exprType;
}
function checkJsxSpreadAttribute(node, elementAttributesType, nameTable) {
var type = checkExpression(node.expression);
var props = getPropertiesOfType(type);
for (var _i = 0, props_2 = props; _i < props_2.length; _i++) {
var prop = props_2[_i];
// Is there a corresponding property in the element attributes type? Skip checking of properties
// that have already been assigned to, as these are not actually pushed into the resulting type
if (!nameTable[prop.name]) {
var targetPropSym = getPropertyOfType(elementAttributesType, prop.name);
if (targetPropSym) {
var msg = ts.chainDiagnosticMessages(undefined, ts.Diagnostics.Property_0_of_JSX_spread_attribute_is_not_assignable_to_target_property, prop.name);
checkTypeAssignableTo(getTypeOfSymbol(prop), getTypeOfSymbol(targetPropSym), node, undefined, msg);
}
nameTable[prop.name] = true;
}
}
return type;
}
function getJsxType(name) {
if (jsxTypes[name] === undefined) {
return jsxTypes[name] = getExportedTypeFromNamespace(JsxNames.JSX, name) || unknownType;
}
return jsxTypes[name];
}
/**
* Looks up an intrinsic tag name and returns a symbol that either points to an intrinsic
* property (in which case nodeLinks.jsxFlags will be IntrinsicNamedElement) or an intrinsic
* string index signature (in which case nodeLinks.jsxFlags will be IntrinsicIndexedElement).
* May also return unknownSymbol if both of these lookups fail.
*/
function getIntrinsicTagSymbol(node) {
var links = getNodeLinks(node);
if (!links.resolvedSymbol) {
var intrinsicElementsType = getJsxType(JsxNames.IntrinsicElements);
if (intrinsicElementsType !== unknownType) {
// Property case
var intrinsicProp = getPropertyOfType(intrinsicElementsType, node.tagName.text);
if (intrinsicProp) {
links.jsxFlags |= 1 /* IntrinsicNamedElement */;
return links.resolvedSymbol = intrinsicProp;
}
// Intrinsic string indexer case
var indexSignatureType = getIndexTypeOfType(intrinsicElementsType, 0 /* String */);
if (indexSignatureType) {
links.jsxFlags |= 2 /* IntrinsicIndexedElement */;
return links.resolvedSymbol = intrinsicElementsType.symbol;
}
// Wasn't found
error(node, ts.Diagnostics.Property_0_does_not_exist_on_type_1, node.tagName.text, "JSX." + JsxNames.IntrinsicElements);
return links.resolvedSymbol = unknownSymbol;
}
else {
if (compilerOptions.noImplicitAny) {
error(node, ts.Diagnostics.JSX_element_implicitly_has_type_any_because_no_interface_JSX_0_exists, JsxNames.IntrinsicElements);
}
return links.resolvedSymbol = unknownSymbol;
}
}
return links.resolvedSymbol;
}
/**
* Given a JSX element that is a class element, finds the Element Instance Type. If the
* element is not a class element, or the class element type cannot be determined, returns 'undefined'.
* For example, in the element <MyClass>, the element instance type is `MyClass` (not `typeof MyClass`).
*/
function getJsxElementInstanceType(node, valueType) {
ts.Debug.assert(!(valueType.flags & 65536 /* Union */));
if (isTypeAny(valueType)) {
// Short-circuit if the class tag is using an element type 'any'
return anyType;
}
// Resolve the signatures, preferring constructor
var signatures = getSignaturesOfType(valueType, 1 /* Construct */);
if (signatures.length === 0) {
// No construct signatures, try call signatures
signatures = getSignaturesOfType(valueType, 0 /* Call */);
if (signatures.length === 0) {
// We found no signatures at all, which is an error
error(node.tagName, ts.Diagnostics.JSX_element_type_0_does_not_have_any_construct_or_call_signatures, ts.getTextOfNode(node.tagName));
return unknownType;
}
}
return getUnionType(ts.map(signatures, getReturnTypeOfSignature), /*subtypeReduction*/ true);
}
/// e.g. "props" for React.d.ts,
/// or 'undefined' if ElementAttributesProperty doesn't exist (which means all
/// non-intrinsic elements' attributes type is 'any'),
/// or '' if it has 0 properties (which means every
/// non-intrinsic elements' attributes type is the element instance type)
function getJsxElementPropertiesName() {
// JSX
var jsxNamespace = getGlobalSymbol(JsxNames.JSX, 1920 /* Namespace */, /*diagnosticMessage*/ undefined);
// JSX.ElementAttributesProperty [symbol]
var attribsPropTypeSym = jsxNamespace && getSymbol(jsxNamespace.exports, JsxNames.ElementAttributesPropertyNameContainer, 793064 /* Type */);
// JSX.ElementAttributesProperty [type]
var attribPropType = attribsPropTypeSym && getDeclaredTypeOfSymbol(attribsPropTypeSym);
// The properties of JSX.ElementAttributesProperty
var attribProperties = attribPropType && getPropertiesOfType(attribPropType);
if (attribProperties) {
// Element Attributes has zero properties, so the element attributes type will be the class instance type
if (attribProperties.length === 0) {
return "";
}
else if (attribProperties.length === 1) {
return attribProperties[0].name;
}
else {
error(attribsPropTypeSym.declarations[0], ts.Diagnostics.The_global_type_JSX_0_may_not_have_more_than_one_property, JsxNames.ElementAttributesPropertyNameContainer);
return undefined;
}
}
else {
// No interface exists, so the element attributes type will be an implicit any
return undefined;
}
}
/**
* Given React element instance type and the class type, resolve the Jsx type
* Pass elemType to handle individual type in the union typed element type.
*/
function getResolvedJsxType(node, elemType, elemClassType) {
if (!elemType) {
elemType = checkExpression(node.tagName);
}
if (elemType.flags & 65536 /* Union */) {
var types = elemType.types;
return getUnionType(ts.map(types, function (type) {
return getResolvedJsxType(node, type, elemClassType);
}), /*subtypeReduction*/ true);
}
// If the elemType is a string type, we have to return anyType to prevent an error downstream as we will try to find construct or call signature of the type
if (elemType.flags & 2 /* String */) {
return anyType;
}
else if (elemType.flags & 32 /* StringLiteral */) {
// If the elemType is a stringLiteral type, we can then provide a check to make sure that the string literal type is one of the Jsx intrinsic element type
var intrinsicElementsType = getJsxType(JsxNames.IntrinsicElements);
if (intrinsicElementsType !== unknownType) {
var stringLiteralTypeName = elemType.text;
var intrinsicProp = getPropertyOfType(intrinsicElementsType, stringLiteralTypeName);
if (intrinsicProp) {
return getTypeOfSymbol(intrinsicProp);
}
var indexSignatureType = getIndexTypeOfType(intrinsicElementsType, 0 /* String */);
if (indexSignatureType) {
return indexSignatureType;
}
error(node, ts.Diagnostics.Property_0_does_not_exist_on_type_1, stringLiteralTypeName, "JSX." + JsxNames.IntrinsicElements);
}
// If we need to report an error, we already done so here. So just return any to prevent any more error downstream
return anyType;
}
// Get the element instance type (the result of newing or invoking this tag)
var elemInstanceType = getJsxElementInstanceType(node, elemType);
if (!elemClassType || !isTypeAssignableTo(elemInstanceType, elemClassType)) {
// Is this is a stateless function component? See if its single signature's return type is
// assignable to the JSX Element Type
if (jsxElementType) {
var callSignatures = elemType && getSignaturesOfType(elemType, 0 /* Call */);
var callSignature = callSignatures && callSignatures.length > 0 && callSignatures[0];
var callReturnType = callSignature && getReturnTypeOfSignature(callSignature);
var paramType = callReturnType && (callSignature.parameters.length === 0 ? emptyObjectType : getTypeOfSymbol(callSignature.parameters[0]));
if (callReturnType && isTypeAssignableTo(callReturnType, jsxElementType)) {
// Intersect in JSX.IntrinsicAttributes if it exists
var intrinsicAttributes = getJsxType(JsxNames.IntrinsicAttributes);
if (intrinsicAttributes !== unknownType) {
paramType = intersectTypes(intrinsicAttributes, paramType);
}
return paramType;
}
}
}
// Issue an error if this return type isn't assignable to JSX.ElementClass
if (elemClassType) {
checkTypeRelatedTo(elemInstanceType, elemClassType, assignableRelation, node, ts.Diagnostics.JSX_element_type_0_is_not_a_constructor_function_for_JSX_elements);
}
if (isTypeAny(elemInstanceType)) {
return elemInstanceType;
}
var propsName = getJsxElementPropertiesName();
if (propsName === undefined) {
// There is no type ElementAttributesProperty, return 'any'
return anyType;
}
else if (propsName === "") {
// If there is no e.g. 'props' member in ElementAttributesProperty, use the element class type instead
return elemInstanceType;
}
else {
var attributesType = getTypeOfPropertyOfType(elemInstanceType, propsName);
if (!attributesType) {
// There is no property named 'props' on this instance type
return emptyObjectType;
}
else if (isTypeAny(attributesType) || (attributesType === unknownType)) {
// Props is of type 'any' or unknown
return attributesType;
}
else if (attributesType.flags & 65536 /* Union */) {
// Props cannot be a union type
error(node.tagName, ts.Diagnostics.JSX_element_attributes_type_0_may_not_be_a_union_type, typeToString(attributesType));
return anyType;
}
else {
// Normal case -- add in IntrinsicClassElements<T> and IntrinsicElements
var apparentAttributesType = attributesType;
var intrinsicClassAttribs = getJsxType(JsxNames.IntrinsicClassAttributes);
if (intrinsicClassAttribs !== unknownType) {
var typeParams = getLocalTypeParametersOfClassOrInterfaceOrTypeAlias(intrinsicClassAttribs.symbol);
if (typeParams) {
if (typeParams.length === 1) {
apparentAttributesType = intersectTypes(createTypeReference(intrinsicClassAttribs, [elemInstanceType]), apparentAttributesType);
}
}
else {
apparentAttributesType = intersectTypes(attributesType, intrinsicClassAttribs);
}
}
var intrinsicAttribs = getJsxType(JsxNames.IntrinsicAttributes);
if (intrinsicAttribs !== unknownType) {
apparentAttributesType = intersectTypes(intrinsicAttribs, apparentAttributesType);
}
return apparentAttributesType;
}
}
}
/**
* Given an opening/self-closing element, get the 'element attributes type', i.e. the type that tells
* us which attributes are valid on a given element.
*/
function getJsxElementAttributesType(node) {
var links = getNodeLinks(node);
if (!links.resolvedJsxType) {
if (isJsxIntrinsicIdentifier(node.tagName)) {
var symbol = getIntrinsicTagSymbol(node);
if (links.jsxFlags & 1 /* IntrinsicNamedElement */) {
return links.resolvedJsxType = getTypeOfSymbol(symbol);
}
else if (links.jsxFlags & 2 /* IntrinsicIndexedElement */) {
return links.resolvedJsxType = getIndexInfoOfSymbol(symbol, 0 /* String */).type;
}
else {
return links.resolvedJsxType = unknownType;
}
}
else {
var elemClassType = getJsxGlobalElementClassType();
return links.resolvedJsxType = getResolvedJsxType(node, undefined, elemClassType);
}
}
return links.resolvedJsxType;
}
/**
* Given a JSX attribute, returns the symbol for the corresponds property
* of the element attributes type. Will return unknownSymbol for attributes
* that have no matching element attributes type property.
*/
function getJsxAttributePropertySymbol(attrib) {
var attributesType = getJsxElementAttributesType(attrib.parent);
var prop = getPropertyOfType(attributesType, attrib.name.text);
return prop || unknownSymbol;
}
function getJsxGlobalElementClassType() {
if (!jsxElementClassType) {
jsxElementClassType = getExportedTypeFromNamespace(JsxNames.JSX, JsxNames.ElementClass);
}
return jsxElementClassType;
}
/// Returns all the properties of the Jsx.IntrinsicElements interface
function getJsxIntrinsicTagNames() {
var intrinsics = getJsxType(JsxNames.IntrinsicElements);
return intrinsics ? getPropertiesOfType(intrinsics) : emptyArray;
}
function checkJsxPreconditions(errorNode) {
// Preconditions for using JSX
if ((compilerOptions.jsx || 0 /* None */) === 0 /* None */) {
error(errorNode, ts.Diagnostics.Cannot_use_JSX_unless_the_jsx_flag_is_provided);
}
if (jsxElementType === undefined) {
if (compilerOptions.noImplicitAny) {
error(errorNode, ts.Diagnostics.JSX_element_implicitly_has_type_any_because_the_global_type_JSX_Element_does_not_exist);
}
}
}
function checkJsxOpeningLikeElement(node) {
checkGrammarJsxElement(node);
checkJsxPreconditions(node);
// The reactNamespace/jsxFactory's root symbol should be marked as 'used' so we don't incorrectly elide its import.
// And if there is no reactNamespace/jsxFactory's symbol in scope when targeting React emit, we should issue an error.
var reactRefErr = compilerOptions.jsx === 2 /* React */ ? ts.Diagnostics.Cannot_find_name_0 : undefined;
var reactNamespace = getJsxNamespace();
var reactSym = resolveName(node.tagName, reactNamespace, 107455 /* Value */, reactRefErr, reactNamespace);
if (reactSym) {
// Mark local symbol as referenced here because it might not have been marked
// if jsx emit was not react as there wont be error being emitted
reactSym.isReferenced = true;
// If react symbol is alias, mark it as refereced
if (reactSym.flags & 8388608 /* Alias */ && !isConstEnumOrConstEnumOnlyModule(resolveAlias(reactSym))) {
markAliasSymbolAsReferenced(reactSym);
}
}
var targetAttributesType = getJsxElementAttributesType(node);
var nameTable = ts.createMap();
// Process this array in right-to-left order so we know which
// attributes (mostly from spreads) are being overwritten and
// thus should have their types ignored
var sawSpreadedAny = false;
for (var i = node.attributes.length - 1; i >= 0; i--) {
if (node.attributes[i].kind === 250 /* JsxAttribute */) {
checkJsxAttribute((node.attributes[i]), targetAttributesType, nameTable);
}
else {
ts.Debug.assert(node.attributes[i].kind === 251 /* JsxSpreadAttribute */);
var spreadType = checkJsxSpreadAttribute((node.attributes[i]), targetAttributesType, nameTable);
if (isTypeAny(spreadType)) {
sawSpreadedAny = true;
}
}
}
// Check that all required properties have been provided. If an 'any'
// was spreaded in, though, assume that it provided all required properties
if (targetAttributesType && !sawSpreadedAny) {
var targetProperties = getPropertiesOfType(targetAttributesType);
for (var i = 0; i < targetProperties.length; i++) {
if (!(targetProperties[i].flags & 536870912 /* Optional */) &&
!nameTable[targetProperties[i].name]) {
error(node, ts.Diagnostics.Property_0_is_missing_in_type_1, targetProperties[i].name, typeToString(targetAttributesType));
}
}
}
}
function checkJsxExpression(node) {
if (node.expression) {
return checkExpression(node.expression);
}
else {
return unknownType;
}
}
// If a symbol is a synthesized symbol with no value declaration, we assume it is a property. Example of this are the synthesized
// '.prototype' property as well as synthesized tuple index properties.
function getDeclarationKindFromSymbol(s) {
return s.valueDeclaration ? s.valueDeclaration.kind : 147 /* PropertyDeclaration */;
}
function getDeclarationModifierFlagsFromSymbol(s) {
return s.valueDeclaration ? ts.getCombinedModifierFlags(s.valueDeclaration) : s.flags & 134217728 /* Prototype */ ? 4 /* Public */ | 32 /* Static */ : 0;
}
function getDeclarationNodeFlagsFromSymbol(s) {
return s.valueDeclaration ? ts.getCombinedNodeFlags(s.valueDeclaration) : 0;
}
/**
* Check whether the requested property access is valid.
* Returns true if node is a valid property access, and false otherwise.
* @param node The node to be checked.
* @param left The left hand side of the property access (e.g.: the super in `super.foo`).
* @param type The type of left.
* @param prop The symbol for the right hand side of the property access.
*/
function checkClassPropertyAccess(node, left, type, prop) {
var flags = getDeclarationModifierFlagsFromSymbol(prop);
var declaringClass = getDeclaredTypeOfSymbol(getParentOfSymbol(prop));
var errorNode = node.kind === 177 /* PropertyAccessExpression */ || node.kind === 223 /* VariableDeclaration */ ?
node.name :
node.right;
if (left.kind === 96 /* SuperKeyword */) {
// TS 1.0 spec (April 2014): 4.8.2
// - In a constructor, instance member function, instance member accessor, or
// instance member variable initializer where this references a derived class instance,
// a super property access is permitted and must specify a public instance member function of the base class.
// - In a static member function or static member accessor
// where this references the constructor function object of a derived class,
// a super property access is permitted and must specify a public static member function of the base class.
if (languageVersion < 2 /* ES2015 */ && getDeclarationKindFromSymbol(prop) !== 149 /* MethodDeclaration */) {
// `prop` refers to a *property* declared in the super class
// rather than a *method*, so it does not satisfy the above criteria.
error(errorNode, ts.Diagnostics.Only_public_and_protected_methods_of_the_base_class_are_accessible_via_the_super_keyword);
return false;
}
if (flags & 128 /* Abstract */) {
// A method cannot be accessed in a super property access if the method is abstract.
// This error could mask a private property access error. But, a member
// cannot simultaneously be private and abstract, so this will trigger an
// additional error elsewhere.
error(errorNode, ts.Diagnostics.Abstract_method_0_in_class_1_cannot_be_accessed_via_super_expression, symbolToString(prop), typeToString(declaringClass));
return false;
}
}
// Public properties are otherwise accessible.
if (!(flags & 24 /* NonPublicAccessibilityModifier */)) {
return true;
}
// Property is known to be private or protected at this point
// Private property is accessible if the property is within the declaring class
if (flags & 8 /* Private */) {
var declaringClassDeclaration = getClassLikeDeclarationOfSymbol(getParentOfSymbol(prop));
if (!isNodeWithinClass(node, declaringClassDeclaration)) {
error(errorNode, ts.Diagnostics.Property_0_is_private_and_only_accessible_within_class_1, symbolToString(prop), typeToString(declaringClass));
return false;
}
return true;
}
// Property is known to be protected at this point
// All protected properties of a supertype are accessible in a super access
if (left.kind === 96 /* SuperKeyword */) {
return true;
}
// Get the enclosing class that has the declaring class as its base type
var enclosingClass = forEachEnclosingClass(node, function (enclosingDeclaration) {
var enclosingClass = getDeclaredTypeOfSymbol(getSymbolOfNode(enclosingDeclaration));
return hasBaseType(enclosingClass, declaringClass) ? enclosingClass : undefined;
});
// A protected property is accessible if the property is within the declaring class or classes derived from it
if (!enclosingClass) {
error(errorNode, ts.Diagnostics.Property_0_is_protected_and_only_accessible_within_class_1_and_its_subclasses, symbolToString(prop), typeToString(declaringClass));
return false;
}
// No further restrictions for static properties
if (flags & 32 /* Static */) {
return true;
}
// An instance property must be accessed through an instance of the enclosing class
if (type.flags & 16384 /* TypeParameter */ && type.isThisType) {
// get the original type -- represented as the type constraint of the 'this' type
type = getConstraintOfTypeParameter(type);
}
// TODO: why is the first part of this check here?
if (!(getObjectFlags(getTargetType(type)) & 3 /* ClassOrInterface */ && hasBaseType(type, enclosingClass))) {
error(errorNode, ts.Diagnostics.Property_0_is_protected_and_only_accessible_through_an_instance_of_class_1, symbolToString(prop), typeToString(enclosingClass));
return false;
}
return true;
}
function checkNonNullExpression(node) {
var type = checkExpression(node);
if (strictNullChecks) {
var kind = getFalsyFlags(type) & 6144 /* Nullable */;
if (kind) {
error(node, kind & 2048 /* Undefined */ ? kind & 4096 /* Null */ ?
ts.Diagnostics.Object_is_possibly_null_or_undefined :
ts.Diagnostics.Object_is_possibly_undefined :
ts.Diagnostics.Object_is_possibly_null);
}
return getNonNullableType(type);
}
return type;
}
function checkPropertyAccessExpression(node) {
return checkPropertyAccessExpressionOrQualifiedName(node, node.expression, node.name);
}
function checkQualifiedName(node) {
return checkPropertyAccessExpressionOrQualifiedName(node, node.left, node.right);
}
function reportNonexistentProperty(propNode, containingType) {
var errorInfo;
if (containingType.flags & 65536 /* Union */ && !(containingType.flags & 8190 /* Primitive */)) {
for (var _i = 0, _a = containingType.types; _i < _a.length; _i++) {
var subtype = _a[_i];
if (!getPropertyOfType(subtype, propNode.text)) {
errorInfo = ts.chainDiagnosticMessages(errorInfo, ts.Diagnostics.Property_0_does_not_exist_on_type_1, ts.declarationNameToString(propNode), typeToString(subtype));
break;
}
}
}
errorInfo = ts.chainDiagnosticMessages(errorInfo, ts.Diagnostics.Property_0_does_not_exist_on_type_1, ts.declarationNameToString(propNode), typeToString(containingType));
diagnostics.add(ts.createDiagnosticForNodeFromMessageChain(propNode, errorInfo));
}
function markPropertyAsReferenced(prop) {
if (prop &&
noUnusedIdentifiers &&
(prop.flags & 106500 /* ClassMember */) &&
prop.valueDeclaration && (ts.getModifierFlags(prop.valueDeclaration) & 8 /* Private */)) {
if (prop.flags & 16777216 /* Instantiated */) {
getSymbolLinks(prop).target.isReferenced = true;
}
else {
prop.isReferenced = true;
}
}
}
function checkPropertyAccessExpressionOrQualifiedName(node, left, right) {
var type = checkNonNullExpression(left);
if (isTypeAny(type) || type === silentNeverType) {
return type;
}
var apparentType = getApparentType(getWidenedType(type));
if (apparentType === unknownType || (type.flags & 16384 /* TypeParameter */ && isTypeAny(apparentType))) {
// handle cases when type is Type parameter with invalid or any constraint
return apparentType;
}
var prop = getPropertyOfType(apparentType, right.text);
if (!prop) {
if (right.text && !checkAndReportErrorForExtendingInterface(node)) {
reportNonexistentProperty(right, type.flags & 16384 /* TypeParameter */ && type.isThisType ? apparentType : type);
}
return unknownType;
}
markPropertyAsReferenced(prop);
getNodeLinks(node).resolvedSymbol = prop;
if (prop.parent && prop.parent.flags & 32 /* Class */) {
checkClassPropertyAccess(node, left, apparentType, prop);
}
var propType = getTypeOfSymbol(prop);
var assignmentKind = ts.getAssignmentTargetKind(node);
if (assignmentKind) {
if (isReferenceToReadonlyEntity(node, prop) || isReferenceThroughNamespaceImport(node)) {
error(right, ts.Diagnostics.Cannot_assign_to_0_because_it_is_a_constant_or_a_read_only_property, right.text);
return unknownType;
}
}
// Only compute control flow type if this is a property access expression that isn't an
// assignment target, and the referenced property was declared as a variable, property,
// accessor, or optional method.
if (node.kind !== 177 /* PropertyAccessExpression */ || assignmentKind === 1 /* Definite */ ||
!(prop.flags & (3 /* Variable */ | 4 /* Property */ | 98304 /* Accessor */)) &&
!(prop.flags & 8192 /* Method */ && propType.flags & 65536 /* Union */)) {
return propType;
}
var flowType = getFlowTypeOfReference(node, propType, /*assumeInitialized*/ true, /*flowContainer*/ undefined);
return assignmentKind ? getBaseTypeOfLiteralType(flowType) : flowType;
}
function isValidPropertyAccess(node, propertyName) {
var left = node.kind === 177 /* PropertyAccessExpression */
? node.expression
: node.left;
var type = checkExpression(left);
if (type !== unknownType && !isTypeAny(type)) {
var prop = getPropertyOfType(getWidenedType(type), propertyName);
if (prop && prop.parent && prop.parent.flags & 32 /* Class */) {
return checkClassPropertyAccess(node, left, type, prop);
}
}
return true;
}
/**
* Return the symbol of the for-in variable declared or referenced by the given for-in statement.
*/
function getForInVariableSymbol(node) {
var initializer = node.initializer;
if (initializer.kind === 224 /* VariableDeclarationList */) {
var variable = initializer.declarations[0];
if (variable && !ts.isBindingPattern(variable.name)) {
return getSymbolOfNode(variable);
}
}
else if (initializer.kind === 70 /* Identifier */) {
return getResolvedSymbol(initializer);
}
return undefined;
}
/**
* Return true if the given type is considered to have numeric property names.
*/
function hasNumericPropertyNames(type) {
return getIndexTypeOfType(type, 1 /* Number */) && !getIndexTypeOfType(type, 0 /* String */);
}
/**
* Return true if given node is an expression consisting of an identifier (possibly parenthesized)
* that references a for-in variable for an object with numeric property names.
*/
function isForInVariableForNumericPropertyNames(expr) {
var e = ts.skipParentheses(expr);
if (e.kind === 70 /* Identifier */) {
var symbol = getResolvedSymbol(e);
if (symbol.flags & 3 /* Variable */) {
var child = expr;
var node = expr.parent;
while (node) {
if (node.kind === 212 /* ForInStatement */ &&
child === node.statement &&
getForInVariableSymbol(node) === symbol &&
hasNumericPropertyNames(checkExpression(node.expression))) {
return true;
}
child = node;
node = node.parent;
}
}
}
return false;
}
function checkIndexedAccess(node) {
var objectType = checkNonNullExpression(node.expression);
var indexExpression = node.argumentExpression;
if (!indexExpression) {
var sourceFile = ts.getSourceFileOfNode(node);
if (node.parent.kind === 180 /* NewExpression */ && node.parent.expression === node) {
var start = ts.skipTrivia(sourceFile.text, node.expression.end);
var end = node.end;
grammarErrorAtPos(sourceFile, start, end - start, ts.Diagnostics.new_T_cannot_be_used_to_create_an_array_Use_new_Array_T_instead);
}
else {
var start = node.end - "]".length;
var end = node.end;
grammarErrorAtPos(sourceFile, start, end - start, ts.Diagnostics.Expression_expected);
}
return unknownType;
}
var indexType = isForInVariableForNumericPropertyNames(indexExpression) ? numberType : checkExpression(indexExpression);
if (objectType === unknownType || objectType === silentNeverType) {
return objectType;
}
if (isConstEnumObjectType(objectType) && indexExpression.kind !== 9 /* StringLiteral */) {
error(indexExpression, ts.Diagnostics.A_const_enum_member_can_only_be_accessed_using_a_string_literal);
return unknownType;
}
return getIndexedAccessType(objectType, indexType, node);
}
function checkThatExpressionIsProperSymbolReference(expression, expressionType, reportError) {
if (expressionType === unknownType) {
// There is already an error, so no need to report one.
return false;
}
if (!ts.isWellKnownSymbolSyntactically(expression)) {
return false;
}
// Make sure the property type is the primitive symbol type
if ((expressionType.flags & 512 /* ESSymbol */) === 0) {
if (reportError) {
error(expression, ts.Diagnostics.A_computed_property_name_of_the_form_0_must_be_of_type_symbol, ts.getTextOfNode(expression));
}
return false;
}
// The name is Symbol.<someName>, so make sure Symbol actually resolves to the
// global Symbol object
var leftHandSide = expression.expression;
var leftHandSideSymbol = getResolvedSymbol(leftHandSide);
if (!leftHandSideSymbol) {
return false;
}
var globalESSymbol = getGlobalESSymbolConstructorSymbol();
if (!globalESSymbol) {
// Already errored when we tried to look up the symbol
return false;
}
if (leftHandSideSymbol !== globalESSymbol) {
if (reportError) {
error(leftHandSide, ts.Diagnostics.Symbol_reference_does_not_refer_to_the_global_Symbol_constructor_object);
}
return false;
}
return true;
}
function resolveUntypedCall(node) {
if (node.kind === 181 /* TaggedTemplateExpression */) {
checkExpression(node.template);
}
else if (node.kind !== 145 /* Decorator */) {
ts.forEach(node.arguments, function (argument) {
checkExpression(argument);
});
}
return anySignature;
}
function resolveErrorCall(node) {
resolveUntypedCall(node);
return unknownSignature;
}
// Re-order candidate signatures into the result array. Assumes the result array to be empty.
// The candidate list orders groups in reverse, but within a group signatures are kept in declaration order
// A nit here is that we reorder only signatures that belong to the same symbol,
// so order how inherited signatures are processed is still preserved.
// interface A { (x: string): void }
// interface B extends A { (x: 'foo'): string }
// const b: B;
// b('foo') // <- here overloads should be processed as [(x:'foo'): string, (x: string): void]
function reorderCandidates(signatures, result) {
var lastParent;
var lastSymbol;
var cutoffIndex = 0;
var index;
var specializedIndex = -1;
var spliceIndex;
ts.Debug.assert(!result.length);
for (var _i = 0, signatures_2 = signatures; _i < signatures_2.length; _i++) {
var signature = signatures_2[_i];
var symbol = signature.declaration && getSymbolOfNode(signature.declaration);
var parent_9 = signature.declaration && signature.declaration.parent;
if (!lastSymbol || symbol === lastSymbol) {
if (lastParent && parent_9 === lastParent) {
index++;
}
else {
lastParent = parent_9;
index = cutoffIndex;
}
}
else {
// current declaration belongs to a different symbol
// set cutoffIndex so re-orderings in the future won't change result set from 0 to cutoffIndex
index = cutoffIndex = result.length;
lastParent = parent_9;
}
lastSymbol = symbol;
// specialized signatures always need to be placed before non-specialized signatures regardless
// of the cutoff position; see GH#1133
if (signature.hasLiteralTypes) {
specializedIndex++;
spliceIndex = specializedIndex;
// The cutoff index always needs to be greater than or equal to the specialized signature index
// in order to prevent non-specialized signatures from being added before a specialized
// signature.
cutoffIndex++;
}
else {
spliceIndex = index;
}
result.splice(spliceIndex, 0, signature);
}
}
function getSpreadArgumentIndex(args) {
for (var i = 0; i < args.length; i++) {
var arg = args[i];
if (arg && arg.kind === 196 /* SpreadElement */) {
return i;
}
}
return -1;
}
function hasCorrectArity(node, args, signature, signatureHelpTrailingComma) {
if (signatureHelpTrailingComma === void 0) { signatureHelpTrailingComma = false; }
var argCount; // Apparent number of arguments we will have in this call
var typeArguments; // Type arguments (undefined if none)
var callIsIncomplete; // In incomplete call we want to be lenient when we have too few arguments
var isDecorator;
var spreadArgIndex = -1;
if (node.kind === 181 /* TaggedTemplateExpression */) {
var tagExpression = node;
// Even if the call is incomplete, we'll have a missing expression as our last argument,
// so we can say the count is just the arg list length
argCount = args.length;
typeArguments = undefined;
if (tagExpression.template.kind === 194 /* TemplateExpression */) {
// If a tagged template expression lacks a tail literal, the call is incomplete.
// Specifically, a template only can end in a TemplateTail or a Missing literal.
var templateExpression = tagExpression.template;
var lastSpan = ts.lastOrUndefined(templateExpression.templateSpans);
ts.Debug.assert(lastSpan !== undefined); // we should always have at least one span.
callIsIncomplete = ts.nodeIsMissing(lastSpan.literal) || !!lastSpan.literal.isUnterminated;
}
else {
// If the template didn't end in a backtick, or its beginning occurred right prior to EOF,
// then this might actually turn out to be a TemplateHead in the future;
// so we consider the call to be incomplete.
var templateLiteral = tagExpression.template;
ts.Debug.assert(templateLiteral.kind === 12 /* NoSubstitutionTemplateLiteral */);
callIsIncomplete = !!templateLiteral.isUnterminated;
}
}
else if (node.kind === 145 /* Decorator */) {
isDecorator = true;
typeArguments = undefined;
argCount = getEffectiveArgumentCount(node, /*args*/ undefined, signature);
}
else {
var callExpression = node;
if (!callExpression.arguments) {
// This only happens when we have something of the form: 'new C'
ts.Debug.assert(callExpression.kind === 180 /* NewExpression */);
return signature.minArgumentCount === 0;
}
argCount = signatureHelpTrailingComma ? args.length + 1 : args.length;
// If we are missing the close paren, the call is incomplete.
callIsIncomplete = callExpression.arguments.end === callExpression.end;
typeArguments = callExpression.typeArguments;
spreadArgIndex = getSpreadArgumentIndex(args);
}
// If the user supplied type arguments, but the number of type arguments does not match
// the declared number of type parameters, the call has an incorrect arity.
var hasRightNumberOfTypeArgs = !typeArguments ||
(signature.typeParameters && typeArguments.length === signature.typeParameters.length);
if (!hasRightNumberOfTypeArgs) {
return false;
}
// If spread arguments are present, check that they correspond to a rest parameter. If so, no
// further checking is necessary.
if (spreadArgIndex >= 0) {
return isRestParameterIndex(signature, spreadArgIndex);
}
// Too many arguments implies incorrect arity.
if (!signature.hasRestParameter && argCount > signature.parameters.length) {
return false;
}
// If the call is incomplete, we should skip the lower bound check.
var hasEnoughArguments = argCount >= signature.minArgumentCount;
return callIsIncomplete || hasEnoughArguments;
}
// If type has a single call signature and no other members, return that signature. Otherwise, return undefined.
function getSingleCallSignature(type) {
if (type.flags & 32768 /* Object */) {
var resolved = resolveStructuredTypeMembers(type);
if (resolved.callSignatures.length === 1 && resolved.constructSignatures.length === 0 &&
resolved.properties.length === 0 && !resolved.stringIndexInfo && !resolved.numberIndexInfo) {
return resolved.callSignatures[0];
}
}
return undefined;
}
// Instantiate a generic signature in the context of a non-generic signature (section 3.8.5 in TypeScript spec)
function instantiateSignatureInContextOf(signature, contextualSignature, contextualMapper) {
var context = createInferenceContext(signature, /*inferUnionTypes*/ true);
forEachMatchingParameterType(contextualSignature, signature, function (source, target) {
// Type parameters from outer context referenced by source type are fixed by instantiation of the source type
inferTypes(context, instantiateType(source, contextualMapper), target);
});
return getSignatureInstantiation(signature, getInferredTypes(context));
}
function inferTypeArguments(node, signature, args, excludeArgument, context) {
var typeParameters = signature.typeParameters;
var inferenceMapper = getInferenceMapper(context);
// Clear out all the inference results from the last time inferTypeArguments was called on this context
for (var i = 0; i < typeParameters.length; i++) {
// As an optimization, we don't have to clear (and later recompute) inferred types
// for type parameters that have already been fixed on the previous call to inferTypeArguments.
// It would be just as correct to reset all of them. But then we'd be repeating the same work
// for the type parameters that were fixed, namely the work done by getInferredType.
if (!context.inferences[i].isFixed) {
context.inferredTypes[i] = undefined;
}
}
// On this call to inferTypeArguments, we may get more inferences for certain type parameters that were not
// fixed last time. This means that a type parameter that failed inference last time may succeed this time,
// or vice versa. Therefore, the failedTypeParameterIndex is useless if it points to an unfixed type parameter,
// because it may change. So here we reset it. However, getInferredType will not revisit any type parameters
// that were previously fixed. So if a fixed type parameter failed previously, it will fail again because
// it will contain the exact same set of inferences. So if we reset the index from a fixed type parameter,
// we will lose information that we won't recover this time around.
if (context.failedTypeParameterIndex !== undefined && !context.inferences[context.failedTypeParameterIndex].isFixed) {
context.failedTypeParameterIndex = undefined;
}
var thisType = getThisTypeOfSignature(signature);
if (thisType) {
var thisArgumentNode = getThisArgumentOfCall(node);
var thisArgumentType = thisArgumentNode ? checkExpression(thisArgumentNode) : voidType;
inferTypes(context, thisArgumentType, thisType);
}
// We perform two passes over the arguments. In the first pass we infer from all arguments, but use
// wildcards for all context sensitive function expressions.
var argCount = getEffectiveArgumentCount(node, args, signature);
for (var i = 0; i < argCount; i++) {
var arg = getEffectiveArgument(node, args, i);
// If the effective argument is 'undefined', then it is an argument that is present but is synthetic.
if (arg === undefined || arg.kind !== 198 /* OmittedExpression */) {
var paramType = getTypeAtPosition(signature, i);
var argType = getEffectiveArgumentType(node, i);
// If the effective argument type is 'undefined', there is no synthetic type
// for the argument. In that case, we should check the argument.
if (argType === undefined) {
// For context sensitive arguments we pass the identityMapper, which is a signal to treat all
// context sensitive function expressions as wildcards
var mapper = excludeArgument && excludeArgument[i] !== undefined ? identityMapper : inferenceMapper;
argType = checkExpressionWithContextualType(arg, paramType, mapper);
}
inferTypes(context, argType, paramType);
}
}
// In the second pass we visit only context sensitive arguments, and only those that aren't excluded, this
// time treating function expressions normally (which may cause previously inferred type arguments to be fixed
// as we construct types for contextually typed parameters)
// Decorators will not have `excludeArgument`, as their arguments cannot be contextually typed.
// Tagged template expressions will always have `undefined` for `excludeArgument[0]`.
if (excludeArgument) {
for (var i = 0; i < argCount; i++) {
// No need to check for omitted args and template expressions, their exclusion value is always undefined
if (excludeArgument[i] === false) {
var arg = args[i];
var paramType = getTypeAtPosition(signature, i);
inferTypes(context, checkExpressionWithContextualType(arg, paramType, inferenceMapper), paramType);
}
}
}
getInferredTypes(context);
}
function checkTypeArguments(signature, typeArgumentNodes, typeArgumentTypes, reportErrors, headMessage) {
var typeParameters = signature.typeParameters;
var typeArgumentsAreAssignable = true;
var mapper;
for (var i = 0; i < typeParameters.length; i++) {
if (typeArgumentsAreAssignable /* so far */) {
var constraint = getConstraintOfTypeParameter(typeParameters[i]);
if (constraint) {
var errorInfo = void 0;
var typeArgumentHeadMessage = ts.Diagnostics.Type_0_does_not_satisfy_the_constraint_1;
if (reportErrors && headMessage) {
errorInfo = ts.chainDiagnosticMessages(errorInfo, typeArgumentHeadMessage);
typeArgumentHeadMessage = headMessage;
}
if (!mapper) {
mapper = createTypeMapper(typeParameters, typeArgumentTypes);
}
var typeArgument = typeArgumentTypes[i];
typeArgumentsAreAssignable = checkTypeAssignableTo(typeArgument, getTypeWithThisArgument(instantiateType(constraint, mapper), typeArgument), reportErrors ? typeArgumentNodes[i] : undefined, typeArgumentHeadMessage, errorInfo);
}
}
}
return typeArgumentsAreAssignable;
}
function checkApplicableSignature(node, args, signature, relation, excludeArgument, reportErrors) {
var thisType = getThisTypeOfSignature(signature);
if (thisType && thisType !== voidType && node.kind !== 180 /* NewExpression */) {
// If the called expression is not of the form `x.f` or `x["f"]`, then sourceType = voidType
// If the signature's 'this' type is voidType, then the check is skipped -- anything is compatible.
// If the expression is a new expression, then the check is skipped.
var thisArgumentNode = getThisArgumentOfCall(node);
var thisArgumentType = thisArgumentNode ? checkExpression(thisArgumentNode) : voidType;
var errorNode = reportErrors ? (thisArgumentNode || node) : undefined;
var headMessage_1 = ts.Diagnostics.The_this_context_of_type_0_is_not_assignable_to_method_s_this_of_type_1;
if (!checkTypeRelatedTo(thisArgumentType, getThisTypeOfSignature(signature), relation, errorNode, headMessage_1)) {
return false;
}
}
var headMessage = ts.Diagnostics.Argument_of_type_0_is_not_assignable_to_parameter_of_type_1;
var argCount = getEffectiveArgumentCount(node, args, signature);
for (var i = 0; i < argCount; i++) {
var arg = getEffectiveArgument(node, args, i);
// If the effective argument is 'undefined', then it is an argument that is present but is synthetic.
if (arg === undefined || arg.kind !== 198 /* OmittedExpression */) {
// Check spread elements against rest type (from arity check we know spread argument corresponds to a rest parameter)
var paramType = getTypeAtPosition(signature, i);
var argType = getEffectiveArgumentType(node, i);
// If the effective argument type is 'undefined', there is no synthetic type
// for the argument. In that case, we should check the argument.
if (argType === undefined) {
argType = checkExpressionWithContextualType(arg, paramType, excludeArgument && excludeArgument[i] ? identityMapper : undefined);
}
// Use argument expression as error location when reporting errors
var errorNode = reportErrors ? getEffectiveArgumentErrorNode(node, i, arg) : undefined;
if (!checkTypeRelatedTo(argType, paramType, relation, errorNode, headMessage)) {
return false;
}
}
}
return true;
}
/**
* Returns the this argument in calls like x.f(...) and x[f](...). Undefined otherwise.
*/
function getThisArgumentOfCall(node) {
if (node.kind === 179 /* CallExpression */) {
var callee = node.expression;
if (callee.kind === 177 /* PropertyAccessExpression */) {
return callee.expression;
}
else if (callee.kind === 178 /* ElementAccessExpression */) {
return callee.expression;
}
}
}
/**
* Returns the effective arguments for an expression that works like a function invocation.
*
* If 'node' is a CallExpression or a NewExpression, then its argument list is returned.
* If 'node' is a TaggedTemplateExpression, a new argument list is constructed from the substitution
* expressions, where the first element of the list is `undefined`.
* If 'node' is a Decorator, the argument list will be `undefined`, and its arguments and types
* will be supplied from calls to `getEffectiveArgumentCount` and `getEffectiveArgumentType`.
*/
function getEffectiveCallArguments(node) {
var args;
if (node.kind === 181 /* TaggedTemplateExpression */) {
var template = node.template;
args = [undefined];
if (template.kind === 194 /* TemplateExpression */) {
ts.forEach(template.templateSpans, function (span) {
args.push(span.expression);
});
}
}
else if (node.kind === 145 /* Decorator */) {
// For a decorator, we return undefined as we will determine
// the number and types of arguments for a decorator using
// `getEffectiveArgumentCount` and `getEffectiveArgumentType` below.
return undefined;
}
else {
args = node.arguments || emptyArray;
}
return args;
}
/**
* Returns the effective argument count for a node that works like a function invocation.
* If 'node' is a Decorator, the number of arguments is derived from the decoration
* target and the signature:
* If 'node.target' is a class declaration or class expression, the effective argument
* count is 1.
* If 'node.target' is a parameter declaration, the effective argument count is 3.
* If 'node.target' is a property declaration, the effective argument count is 2.
* If 'node.target' is a method or accessor declaration, the effective argument count
* is 3, although it can be 2 if the signature only accepts two arguments, allowing
* us to match a property decorator.
* Otherwise, the argument count is the length of the 'args' array.
*/
function getEffectiveArgumentCount(node, args, signature) {
if (node.kind === 145 /* Decorator */) {
switch (node.parent.kind) {
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
// A class decorator will have one argument (see `ClassDecorator` in core.d.ts)
return 1;
case 147 /* PropertyDeclaration */:
// A property declaration decorator will have two arguments (see
// `PropertyDecorator` in core.d.ts)
return 2;
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
// A method or accessor declaration decorator will have two or three arguments (see
// `PropertyDecorator` and `MethodDecorator` in core.d.ts)
// If we are emitting decorators for ES3, we will only pass two arguments.
if (languageVersion === 0 /* ES3 */) {
return 2;
}
// If the method decorator signature only accepts a target and a key, we will only
// type check those arguments.
return signature.parameters.length >= 3 ? 3 : 2;
case 144 /* Parameter */:
// A parameter declaration decorator will have three arguments (see
// `ParameterDecorator` in core.d.ts)
return 3;
}
}
else {
return args.length;
}
}
/**
* Returns the effective type of the first argument to a decorator.
* If 'node' is a class declaration or class expression, the effective argument type
* is the type of the static side of the class.
* If 'node' is a parameter declaration, the effective argument type is either the type
* of the static or instance side of the class for the parameter's parent method,
* depending on whether the method is declared static.
* For a constructor, the type is always the type of the static side of the class.
* If 'node' is a property, method, or accessor declaration, the effective argument
* type is the type of the static or instance side of the parent class for class
* element, depending on whether the element is declared static.
*/
function getEffectiveDecoratorFirstArgumentType(node) {
// The first argument to a decorator is its `target`.
if (node.kind === 226 /* ClassDeclaration */) {
// For a class decorator, the `target` is the type of the class (e.g. the
// "static" or "constructor" side of the class)
var classSymbol = getSymbolOfNode(node);
return getTypeOfSymbol(classSymbol);
}
if (node.kind === 144 /* Parameter */) {
// For a parameter decorator, the `target` is the parent type of the
// parameter's containing method.
node = node.parent;
if (node.kind === 150 /* Constructor */) {
var classSymbol = getSymbolOfNode(node);
return getTypeOfSymbol(classSymbol);
}
}
if (node.kind === 147 /* PropertyDeclaration */ ||
node.kind === 149 /* MethodDeclaration */ ||
node.kind === 151 /* GetAccessor */ ||
node.kind === 152 /* SetAccessor */) {
// For a property or method decorator, the `target` is the
// "static"-side type of the parent of the member if the member is
// declared "static"; otherwise, it is the "instance"-side type of the
// parent of the member.
return getParentTypeOfClassElement(node);
}
ts.Debug.fail("Unsupported decorator target.");
return unknownType;
}
/**
* Returns the effective type for the second argument to a decorator.
* If 'node' is a parameter, its effective argument type is one of the following:
* If 'node.parent' is a constructor, the effective argument type is 'any', as we
* will emit `undefined`.
* If 'node.parent' is a member with an identifier, numeric, or string literal name,
* the effective argument type will be a string literal type for the member name.
* If 'node.parent' is a computed property name, the effective argument type will
* either be a symbol type or the string type.
* If 'node' is a member with an identifier, numeric, or string literal name, the
* effective argument type will be a string literal type for the member name.
* If 'node' is a computed property name, the effective argument type will either
* be a symbol type or the string type.
* A class decorator does not have a second argument type.
*/
function getEffectiveDecoratorSecondArgumentType(node) {
// The second argument to a decorator is its `propertyKey`
if (node.kind === 226 /* ClassDeclaration */) {
ts.Debug.fail("Class decorators should not have a second synthetic argument.");
return unknownType;
}
if (node.kind === 144 /* Parameter */) {
node = node.parent;
if (node.kind === 150 /* Constructor */) {
// For a constructor parameter decorator, the `propertyKey` will be `undefined`.
return anyType;
}
}
if (node.kind === 147 /* PropertyDeclaration */ ||
node.kind === 149 /* MethodDeclaration */ ||
node.kind === 151 /* GetAccessor */ ||
node.kind === 152 /* SetAccessor */) {
// The `propertyKey` for a property or method decorator will be a
// string literal type if the member name is an identifier, number, or string;
// otherwise, if the member name is a computed property name it will
// be either string or symbol.
var element = node;
switch (element.name.kind) {
case 70 /* Identifier */:
case 8 /* NumericLiteral */:
case 9 /* StringLiteral */:
return getLiteralTypeForText(32 /* StringLiteral */, element.name.text);
case 142 /* ComputedPropertyName */:
var nameType = checkComputedPropertyName(element.name);
if (isTypeOfKind(nameType, 512 /* ESSymbol */)) {
return nameType;
}
else {
return stringType;
}
default:
ts.Debug.fail("Unsupported property name.");
return unknownType;
}
}
ts.Debug.fail("Unsupported decorator target.");
return unknownType;
}
/**
* Returns the effective argument type for the third argument to a decorator.
* If 'node' is a parameter, the effective argument type is the number type.
* If 'node' is a method or accessor, the effective argument type is a
* `TypedPropertyDescriptor<T>` instantiated with the type of the member.
* Class and property decorators do not have a third effective argument.
*/
function getEffectiveDecoratorThirdArgumentType(node) {
// The third argument to a decorator is either its `descriptor` for a method decorator
// or its `parameterIndex` for a parameter decorator
if (node.kind === 226 /* ClassDeclaration */) {
ts.Debug.fail("Class decorators should not have a third synthetic argument.");
return unknownType;
}
if (node.kind === 144 /* Parameter */) {
// The `parameterIndex` for a parameter decorator is always a number
return numberType;
}
if (node.kind === 147 /* PropertyDeclaration */) {
ts.Debug.fail("Property decorators should not have a third synthetic argument.");
return unknownType;
}
if (node.kind === 149 /* MethodDeclaration */ ||
node.kind === 151 /* GetAccessor */ ||
node.kind === 152 /* SetAccessor */) {
// The `descriptor` for a method decorator will be a `TypedPropertyDescriptor<T>`
// for the type of the member.
var propertyType = getTypeOfNode(node);
return createTypedPropertyDescriptorType(propertyType);
}
ts.Debug.fail("Unsupported decorator target.");
return unknownType;
}
/**
* Returns the effective argument type for the provided argument to a decorator.
*/
function getEffectiveDecoratorArgumentType(node, argIndex) {
if (argIndex === 0) {
return getEffectiveDecoratorFirstArgumentType(node.parent);
}
else if (argIndex === 1) {
return getEffectiveDecoratorSecondArgumentType(node.parent);
}
else if (argIndex === 2) {
return getEffectiveDecoratorThirdArgumentType(node.parent);
}
ts.Debug.fail("Decorators should not have a fourth synthetic argument.");
return unknownType;
}
/**
* Gets the effective argument type for an argument in a call expression.
*/
function getEffectiveArgumentType(node, argIndex) {
// Decorators provide special arguments, a tagged template expression provides
// a special first argument, and string literals get string literal types
// unless we're reporting errors
if (node.kind === 145 /* Decorator */) {
return getEffectiveDecoratorArgumentType(node, argIndex);
}
else if (argIndex === 0 && node.kind === 181 /* TaggedTemplateExpression */) {
return getGlobalTemplateStringsArrayType();
}
// This is not a synthetic argument, so we return 'undefined'
// to signal that the caller needs to check the argument.
return undefined;
}
/**
* Gets the effective argument expression for an argument in a call expression.
*/
function getEffectiveArgument(node, args, argIndex) {
// For a decorator or the first argument of a tagged template expression we return undefined.
if (node.kind === 145 /* Decorator */ ||
(argIndex === 0 && node.kind === 181 /* TaggedTemplateExpression */)) {
return undefined;
}
return args[argIndex];
}
/**
* Gets the error node to use when reporting errors for an effective argument.
*/
function getEffectiveArgumentErrorNode(node, argIndex, arg) {
if (node.kind === 145 /* Decorator */) {
// For a decorator, we use the expression of the decorator for error reporting.
return node.expression;
}
else if (argIndex === 0 && node.kind === 181 /* TaggedTemplateExpression */) {
// For a the first argument of a tagged template expression, we use the template of the tag for error reporting.
return node.template;
}
else {
return arg;
}
}
function resolveCall(node, signatures, candidatesOutArray, headMessage) {
var isTaggedTemplate = node.kind === 181 /* TaggedTemplateExpression */;
var isDecorator = node.kind === 145 /* Decorator */;
var typeArguments;
if (!isTaggedTemplate && !isDecorator) {
typeArguments = node.typeArguments;
// We already perform checking on the type arguments on the class declaration itself.
if (node.expression.kind !== 96 /* SuperKeyword */) {
ts.forEach(typeArguments, checkSourceElement);
}
}
var candidates = candidatesOutArray || [];
// reorderCandidates fills up the candidates array directly
reorderCandidates(signatures, candidates);
if (!candidates.length) {
reportError(ts.Diagnostics.Supplied_parameters_do_not_match_any_signature_of_call_target);
return resolveErrorCall(node);
}
var args = getEffectiveCallArguments(node);
// The following applies to any value of 'excludeArgument[i]':
// - true: the argument at 'i' is susceptible to a one-time permanent contextual typing.
// - undefined: the argument at 'i' is *not* susceptible to permanent contextual typing.
// - false: the argument at 'i' *was* and *has been* permanently contextually typed.
//
// The idea is that we will perform type argument inference & assignability checking once
// without using the susceptible parameters that are functions, and once more for each of those
// parameters, contextually typing each as we go along.
//
// For a tagged template, then the first argument be 'undefined' if necessary
// because it represents a TemplateStringsArray.
//
// For a decorator, no arguments are susceptible to contextual typing due to the fact
// decorators are applied to a declaration by the emitter, and not to an expression.
var excludeArgument;
if (!isDecorator) {
// We do not need to call `getEffectiveArgumentCount` here as it only
// applies when calculating the number of arguments for a decorator.
for (var i = isTaggedTemplate ? 1 : 0; i < args.length; i++) {
if (isContextSensitive(args[i])) {
if (!excludeArgument) {
excludeArgument = new Array(args.length);
}
excludeArgument[i] = true;
}
}
}
// The following variables are captured and modified by calls to chooseOverload.
// If overload resolution or type argument inference fails, we want to report the
// best error possible. The best error is one which says that an argument was not
// assignable to a parameter. This implies that everything else about the overload
// was fine. So if there is any overload that is only incorrect because of an
// argument, we will report an error on that one.
//
// function foo(s: string) {}
// function foo(n: number) {} // Report argument error on this overload
// function foo() {}
// foo(true);
//
// If none of the overloads even made it that far, there are two possibilities.
// There was a problem with type arguments for some overload, in which case
// report an error on that. Or none of the overloads even had correct arity,
// in which case give an arity error.
//
// function foo<T>(x: T, y: T) {} // Report type argument inference error
// function foo() {}
// foo(0, true);
//
var candidateForArgumentError;
var candidateForTypeArgumentError;
var resultOfFailedInference;
var result;
// If we are in signature help, a trailing comma indicates that we intend to provide another argument,
// so we will only accept overloads with arity at least 1 higher than the current number of provided arguments.
var signatureHelpTrailingComma = candidatesOutArray && node.kind === 179 /* CallExpression */ && node.arguments.hasTrailingComma;
// Section 4.12.1:
// if the candidate list contains one or more signatures for which the type of each argument
// expression is a subtype of each corresponding parameter type, the return type of the first
// of those signatures becomes the return type of the function call.
// Otherwise, the return type of the first signature in the candidate list becomes the return
// type of the function call.
//
// Whether the call is an error is determined by assignability of the arguments. The subtype pass
// is just important for choosing the best signature. So in the case where there is only one
// signature, the subtype pass is useless. So skipping it is an optimization.
if (candidates.length > 1) {
result = chooseOverload(candidates, subtypeRelation, signatureHelpTrailingComma);
}
if (!result) {
// Reinitialize these pointers for round two
candidateForArgumentError = undefined;
candidateForTypeArgumentError = undefined;
resultOfFailedInference = undefined;
result = chooseOverload(candidates, assignableRelation, signatureHelpTrailingComma);
}
if (result) {
return result;
}
// No signatures were applicable. Now report errors based on the last applicable signature with
// no arguments excluded from assignability checks.
// If candidate is undefined, it means that no candidates had a suitable arity. In that case,
// skip the checkApplicableSignature check.
if (candidateForArgumentError) {
// excludeArgument is undefined, in this case also equivalent to [undefined, undefined, ...]
// The importance of excludeArgument is to prevent us from typing function expression parameters
// in arguments too early. If possible, we'd like to only type them once we know the correct
// overload. However, this matters for the case where the call is correct. When the call is
// an error, we don't need to exclude any arguments, although it would cause no harm to do so.
checkApplicableSignature(node, args, candidateForArgumentError, assignableRelation, /*excludeArgument*/ undefined, /*reportErrors*/ true);
}
else if (candidateForTypeArgumentError) {
if (!isTaggedTemplate && !isDecorator && typeArguments) {
var typeArguments_2 = node.typeArguments;
checkTypeArguments(candidateForTypeArgumentError, typeArguments_2, ts.map(typeArguments_2, getTypeFromTypeNode), /*reportErrors*/ true, headMessage);
}
else {
ts.Debug.assert(resultOfFailedInference.failedTypeParameterIndex >= 0);
var failedTypeParameter = candidateForTypeArgumentError.typeParameters[resultOfFailedInference.failedTypeParameterIndex];
var inferenceCandidates = getInferenceCandidates(resultOfFailedInference, resultOfFailedInference.failedTypeParameterIndex);
var diagnosticChainHead = ts.chainDiagnosticMessages(/*details*/ undefined, // details will be provided by call to reportNoCommonSupertypeError
ts.Diagnostics.The_type_argument_for_type_parameter_0_cannot_be_inferred_from_the_usage_Consider_specifying_the_type_arguments_explicitly, typeToString(failedTypeParameter));
if (headMessage) {
diagnosticChainHead = ts.chainDiagnosticMessages(diagnosticChainHead, headMessage);
}
reportNoCommonSupertypeError(inferenceCandidates, node.expression || node.tag, diagnosticChainHead);
}
}
else {
reportError(ts.Diagnostics.Supplied_parameters_do_not_match_any_signature_of_call_target);
}
// No signature was applicable. We have already reported the errors for the invalid signature.
// If this is a type resolution session, e.g. Language Service, try to get better information that anySignature.
// Pick the first candidate that matches the arity. This way we can get a contextual type for cases like:
// declare function f(a: { xa: number; xb: number; });
// f({ |
if (!produceDiagnostics) {
for (var _i = 0, candidates_1 = candidates; _i < candidates_1.length; _i++) {
var candidate = candidates_1[_i];
if (hasCorrectArity(node, args, candidate)) {
if (candidate.typeParameters && typeArguments) {
candidate = getSignatureInstantiation(candidate, ts.map(typeArguments, getTypeFromTypeNode));
}
return candidate;
}
}
}
return resolveErrorCall(node);
function reportError(message, arg0, arg1, arg2) {
var errorInfo;
errorInfo = ts.chainDiagnosticMessages(errorInfo, message, arg0, arg1, arg2);
if (headMessage) {
errorInfo = ts.chainDiagnosticMessages(errorInfo, headMessage);
}
diagnostics.add(ts.createDiagnosticForNodeFromMessageChain(node, errorInfo));
}
function chooseOverload(candidates, relation, signatureHelpTrailingComma) {
if (signatureHelpTrailingComma === void 0) { signatureHelpTrailingComma = false; }
for (var _i = 0, candidates_2 = candidates; _i < candidates_2.length; _i++) {
var originalCandidate = candidates_2[_i];
if (!hasCorrectArity(node, args, originalCandidate, signatureHelpTrailingComma)) {
continue;
}
var candidate = void 0;
var typeArgumentsAreValid = void 0;
var inferenceContext = originalCandidate.typeParameters
? createInferenceContext(originalCandidate, /*inferUnionTypes*/ false)
: undefined;
while (true) {
candidate = originalCandidate;
if (candidate.typeParameters) {
var typeArgumentTypes = void 0;
if (typeArguments) {
typeArgumentTypes = ts.map(typeArguments, getTypeFromTypeNode);
typeArgumentsAreValid = checkTypeArguments(candidate, typeArguments, typeArgumentTypes, /*reportErrors*/ false);
}
else {
inferTypeArguments(node, candidate, args, excludeArgument, inferenceContext);
typeArgumentsAreValid = inferenceContext.failedTypeParameterIndex === undefined;
typeArgumentTypes = inferenceContext.inferredTypes;
}
if (!typeArgumentsAreValid) {
break;
}
candidate = getSignatureInstantiation(candidate, typeArgumentTypes);
}
if (!checkApplicableSignature(node, args, candidate, relation, excludeArgument, /*reportErrors*/ false)) {
break;
}
var index = excludeArgument ? ts.indexOf(excludeArgument, true) : -1;
if (index < 0) {
return candidate;
}
excludeArgument[index] = false;
}
// A post-mortem of this iteration of the loop. The signature was not applicable,
// so we want to track it as a candidate for reporting an error. If the candidate
// had no type parameters, or had no issues related to type arguments, we can
// report an error based on the arguments. If there was an issue with type
// arguments, then we can only report an error based on the type arguments.
if (originalCandidate.typeParameters) {
var instantiatedCandidate = candidate;
if (typeArgumentsAreValid) {
candidateForArgumentError = instantiatedCandidate;
}
else {
candidateForTypeArgumentError = originalCandidate;
if (!typeArguments) {
resultOfFailedInference = inferenceContext;
}
}
}
else {
ts.Debug.assert(originalCandidate === candidate);
candidateForArgumentError = originalCandidate;
}
}
return undefined;
}
}
function resolveCallExpression(node, candidatesOutArray) {
if (node.expression.kind === 96 /* SuperKeyword */) {
var superType = checkSuperExpression(node.expression);
if (superType !== unknownType) {
// In super call, the candidate signatures are the matching arity signatures of the base constructor function instantiated
// with the type arguments specified in the extends clause.
var baseTypeNode = ts.getClassExtendsHeritageClauseElement(ts.getContainingClass(node));
if (baseTypeNode) {
var baseConstructors = getInstantiatedConstructorsForTypeArguments(superType, baseTypeNode.typeArguments);
return resolveCall(node, baseConstructors, candidatesOutArray);
}
}
return resolveUntypedCall(node);
}
var funcType = checkNonNullExpression(node.expression);
if (funcType === silentNeverType) {
return silentNeverSignature;
}
var apparentType = getApparentType(funcType);
if (apparentType === unknownType) {
// Another error has already been reported
return resolveErrorCall(node);
}
// Technically, this signatures list may be incomplete. We are taking the apparent type,
// but we are not including call signatures that may have been added to the Object or
// Function interface, since they have none by default. This is a bit of a leap of faith
// that the user will not add any.
var callSignatures = getSignaturesOfType(apparentType, 0 /* Call */);
var constructSignatures = getSignaturesOfType(apparentType, 1 /* Construct */);
// TS 1.0 Spec: 4.12
// In an untyped function call no TypeArgs are permitted, Args can be any argument list, no contextual
// types are provided for the argument expressions, and the result is always of type Any.
if (isUntypedFunctionCall(funcType, apparentType, callSignatures.length, constructSignatures.length)) {
// The unknownType indicates that an error already occurred (and was reported). No
// need to report another error in this case.
if (funcType !== unknownType && node.typeArguments) {
error(node, ts.Diagnostics.Untyped_function_calls_may_not_accept_type_arguments);
}
return resolveUntypedCall(node);
}
// If FuncExpr's apparent type(section 3.8.1) is a function type, the call is a typed function call.
// TypeScript employs overload resolution in typed function calls in order to support functions
// with multiple call signatures.
if (!callSignatures.length) {
if (constructSignatures.length) {
error(node, ts.Diagnostics.Value_of_type_0_is_not_callable_Did_you_mean_to_include_new, typeToString(funcType));
}
else {
error(node, ts.Diagnostics.Cannot_invoke_an_expression_whose_type_lacks_a_call_signature_Type_0_has_no_compatible_call_signatures, typeToString(apparentType));
}
return resolveErrorCall(node);
}
return resolveCall(node, callSignatures, candidatesOutArray);
}
/**
* TS 1.0 spec: 4.12
* If FuncExpr is of type Any, or of an object type that has no call or construct signatures
* but is a subtype of the Function interface, the call is an untyped function call.
*/
function isUntypedFunctionCall(funcType, apparentFuncType, numCallSignatures, numConstructSignatures) {
if (isTypeAny(funcType)) {
return true;
}
if (isTypeAny(apparentFuncType) && funcType.flags & 16384 /* TypeParameter */) {
return true;
}
if (!numCallSignatures && !numConstructSignatures) {
// We exclude union types because we may have a union of function types that happen to have
// no common signatures.
if (funcType.flags & 65536 /* Union */) {
return false;
}
return isTypeAssignableTo(funcType, globalFunctionType);
}
return false;
}
function resolveNewExpression(node, candidatesOutArray) {
if (node.arguments && languageVersion < 1 /* ES5 */) {
var spreadIndex = getSpreadArgumentIndex(node.arguments);
if (spreadIndex >= 0) {
error(node.arguments[spreadIndex], ts.Diagnostics.Spread_operator_in_new_expressions_is_only_available_when_targeting_ECMAScript_5_and_higher);
}
}
var expressionType = checkNonNullExpression(node.expression);
if (expressionType === silentNeverType) {
return silentNeverSignature;
}
// If expressionType's apparent type(section 3.8.1) is an object type with one or
// more construct signatures, the expression is processed in the same manner as a
// function call, but using the construct signatures as the initial set of candidate
// signatures for overload resolution. The result type of the function call becomes
// the result type of the operation.
expressionType = getApparentType(expressionType);
if (expressionType === unknownType) {
// Another error has already been reported
return resolveErrorCall(node);
}
// If the expression is a class of abstract type, then it cannot be instantiated.
// Note, only class declarations can be declared abstract.
// In the case of a merged class-module or class-interface declaration,
// only the class declaration node will have the Abstract flag set.
var valueDecl = expressionType.symbol && getClassLikeDeclarationOfSymbol(expressionType.symbol);
if (valueDecl && ts.getModifierFlags(valueDecl) & 128 /* Abstract */) {
error(node, ts.Diagnostics.Cannot_create_an_instance_of_the_abstract_class_0, ts.declarationNameToString(valueDecl.name));
return resolveErrorCall(node);
}
// TS 1.0 spec: 4.11
// If expressionType is of type Any, Args can be any argument
// list and the result of the operation is of type Any.
if (isTypeAny(expressionType)) {
if (node.typeArguments) {
error(node, ts.Diagnostics.Untyped_function_calls_may_not_accept_type_arguments);
}
return resolveUntypedCall(node);
}
// Technically, this signatures list may be incomplete. We are taking the apparent type,
// but we are not including construct signatures that may have been added to the Object or
// Function interface, since they have none by default. This is a bit of a leap of faith
// that the user will not add any.
var constructSignatures = getSignaturesOfType(expressionType, 1 /* Construct */);
if (constructSignatures.length) {
if (!isConstructorAccessible(node, constructSignatures[0])) {
return resolveErrorCall(node);
}
return resolveCall(node, constructSignatures, candidatesOutArray);
}
// If expressionType's apparent type is an object type with no construct signatures but
// one or more call signatures, the expression is processed as a function call. A compile-time
// error occurs if the result of the function call is not Void. The type of the result of the
// operation is Any. It is an error to have a Void this type.
var callSignatures = getSignaturesOfType(expressionType, 0 /* Call */);
if (callSignatures.length) {
var signature = resolveCall(node, callSignatures, candidatesOutArray);
if (getReturnTypeOfSignature(signature) !== voidType) {
error(node, ts.Diagnostics.Only_a_void_function_can_be_called_with_the_new_keyword);
}
if (getThisTypeOfSignature(signature) === voidType) {
error(node, ts.Diagnostics.A_function_that_is_called_with_the_new_keyword_cannot_have_a_this_type_that_is_void);
}
return signature;
}
error(node, ts.Diagnostics.Cannot_use_new_with_an_expression_whose_type_lacks_a_call_or_construct_signature);
return resolveErrorCall(node);
}
function isConstructorAccessible(node, signature) {
if (!signature || !signature.declaration) {
return true;
}
var declaration = signature.declaration;
var modifiers = ts.getModifierFlags(declaration);
// Public constructor is accessible.
if (!(modifiers & 24 /* NonPublicAccessibilityModifier */)) {
return true;
}
var declaringClassDeclaration = getClassLikeDeclarationOfSymbol(declaration.parent.symbol);
var declaringClass = getDeclaredTypeOfSymbol(declaration.parent.symbol);
// A private or protected constructor can only be instantiated within its own class (or a subclass, for protected)
if (!isNodeWithinClass(node, declaringClassDeclaration)) {
var containingClass = ts.getContainingClass(node);
if (containingClass) {
var containingType = getTypeOfNode(containingClass);
var baseTypes = getBaseTypes(containingType);
if (baseTypes.length) {
var baseType = baseTypes[0];
if (modifiers & 16 /* Protected */ &&
baseType.symbol === declaration.parent.symbol) {
return true;
}
}
}
if (modifiers & 8 /* Private */) {
error(node, ts.Diagnostics.Constructor_of_class_0_is_private_and_only_accessible_within_the_class_declaration, typeToString(declaringClass));
}
if (modifiers & 16 /* Protected */) {
error(node, ts.Diagnostics.Constructor_of_class_0_is_protected_and_only_accessible_within_the_class_declaration, typeToString(declaringClass));
}
return false;
}
return true;
}
function resolveTaggedTemplateExpression(node, candidatesOutArray) {
var tagType = checkExpression(node.tag);
var apparentType = getApparentType(tagType);
if (apparentType === unknownType) {
// Another error has already been reported
return resolveErrorCall(node);
}
var callSignatures = getSignaturesOfType(apparentType, 0 /* Call */);
var constructSignatures = getSignaturesOfType(apparentType, 1 /* Construct */);
if (isUntypedFunctionCall(tagType, apparentType, callSignatures.length, constructSignatures.length)) {
return resolveUntypedCall(node);
}
if (!callSignatures.length) {
error(node, ts.Diagnostics.Cannot_invoke_an_expression_whose_type_lacks_a_call_signature_Type_0_has_no_compatible_call_signatures, typeToString(apparentType));
return resolveErrorCall(node);
}
return resolveCall(node, callSignatures, candidatesOutArray);
}
/**
* Gets the localized diagnostic head message to use for errors when resolving a decorator as a call expression.
*/
function getDiagnosticHeadMessageForDecoratorResolution(node) {
switch (node.parent.kind) {
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
return ts.Diagnostics.Unable_to_resolve_signature_of_class_decorator_when_called_as_an_expression;
case 144 /* Parameter */:
return ts.Diagnostics.Unable_to_resolve_signature_of_parameter_decorator_when_called_as_an_expression;
case 147 /* PropertyDeclaration */:
return ts.Diagnostics.Unable_to_resolve_signature_of_property_decorator_when_called_as_an_expression;
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return ts.Diagnostics.Unable_to_resolve_signature_of_method_decorator_when_called_as_an_expression;
}
}
/**
* Resolves a decorator as if it were a call expression.
*/
function resolveDecorator(node, candidatesOutArray) {
var funcType = checkExpression(node.expression);
var apparentType = getApparentType(funcType);
if (apparentType === unknownType) {
return resolveErrorCall(node);
}
var callSignatures = getSignaturesOfType(apparentType, 0 /* Call */);
var constructSignatures = getSignaturesOfType(apparentType, 1 /* Construct */);
if (isUntypedFunctionCall(funcType, apparentType, callSignatures.length, constructSignatures.length)) {
return resolveUntypedCall(node);
}
var headMessage = getDiagnosticHeadMessageForDecoratorResolution(node);
if (!callSignatures.length) {
var errorInfo = void 0;
errorInfo = ts.chainDiagnosticMessages(errorInfo, ts.Diagnostics.Cannot_invoke_an_expression_whose_type_lacks_a_call_signature_Type_0_has_no_compatible_call_signatures, typeToString(apparentType));
errorInfo = ts.chainDiagnosticMessages(errorInfo, headMessage);
diagnostics.add(ts.createDiagnosticForNodeFromMessageChain(node, errorInfo));
return resolveErrorCall(node);
}
return resolveCall(node, callSignatures, candidatesOutArray, headMessage);
}
function resolveSignature(node, candidatesOutArray) {
switch (node.kind) {
case 179 /* CallExpression */:
return resolveCallExpression(node, candidatesOutArray);
case 180 /* NewExpression */:
return resolveNewExpression(node, candidatesOutArray);
case 181 /* TaggedTemplateExpression */:
return resolveTaggedTemplateExpression(node, candidatesOutArray);
case 145 /* Decorator */:
return resolveDecorator(node, candidatesOutArray);
}
ts.Debug.fail("Branch in 'resolveSignature' should be unreachable.");
}
// candidatesOutArray is passed by signature help in the language service, and collectCandidates
// must fill it up with the appropriate candidate signatures
function getResolvedSignature(node, candidatesOutArray) {
var links = getNodeLinks(node);
// If getResolvedSignature has already been called, we will have cached the resolvedSignature.
// However, it is possible that either candidatesOutArray was not passed in the first time,
// or that a different candidatesOutArray was passed in. Therefore, we need to redo the work
// to correctly fill the candidatesOutArray.
var cached = links.resolvedSignature;
if (cached && cached !== resolvingSignature && !candidatesOutArray) {
return cached;
}
links.resolvedSignature = resolvingSignature;
var result = resolveSignature(node, candidatesOutArray);
// If signature resolution originated in control flow type analysis (for example to compute the
// assigned type in a flow assignment) we don't cache the result as it may be based on temporary
// types from the control flow analysis.
links.resolvedSignature = flowLoopStart === flowLoopCount ? result : cached;
return result;
}
function getResolvedOrAnySignature(node) {
// If we're already in the process of resolving the given signature, don't resolve again as
// that could cause infinite recursion. Instead, return anySignature.
return getNodeLinks(node).resolvedSignature === resolvingSignature ? resolvingSignature : getResolvedSignature(node);
}
function getInferredClassType(symbol) {
var links = getSymbolLinks(symbol);
if (!links.inferredClassType) {
links.inferredClassType = createAnonymousType(symbol, symbol.members, emptyArray, emptyArray, /*stringIndexType*/ undefined, /*numberIndexType*/ undefined);
}
return links.inferredClassType;
}
/**
* Syntactically and semantically checks a call or new expression.
* @param node The call/new expression to be checked.
* @returns On success, the expression's signature's return type. On failure, anyType.
*/
function checkCallExpression(node) {
// Grammar checking; stop grammar-checking if checkGrammarTypeArguments return true
checkGrammarTypeArguments(node, node.typeArguments) || checkGrammarArguments(node, node.arguments);
var signature = getResolvedSignature(node);
if (node.expression.kind === 96 /* SuperKeyword */) {
return voidType;
}
if (node.kind === 180 /* NewExpression */) {
var declaration = signature.declaration;
if (declaration &&
declaration.kind !== 150 /* Constructor */ &&
declaration.kind !== 154 /* ConstructSignature */ &&
declaration.kind !== 159 /* ConstructorType */ &&
!ts.isJSDocConstructSignature(declaration)) {
// When resolved signature is a call signature (and not a construct signature) the result type is any, unless
// the declaring function had members created through 'x.prototype.y = expr' or 'this.y = expr' psuedodeclarations
// in a JS file
// Note:JS inferred classes might come from a variable declaration instead of a function declaration.
// In this case, using getResolvedSymbol directly is required to avoid losing the members from the declaration.
var funcSymbol = node.expression.kind === 70 /* Identifier */ ?
getResolvedSymbol(node.expression) :
checkExpression(node.expression).symbol;
if (funcSymbol && funcSymbol.members && (funcSymbol.flags & 16 /* Function */ || ts.isDeclarationOfFunctionExpression(funcSymbol))) {
return getInferredClassType(funcSymbol);
}
else if (compilerOptions.noImplicitAny) {
error(node, ts.Diagnostics.new_expression_whose_target_lacks_a_construct_signature_implicitly_has_an_any_type);
}
return anyType;
}
}
// In JavaScript files, calls to any identifier 'require' are treated as external module imports
if (ts.isInJavaScriptFile(node) && isCommonJsRequire(node)) {
return resolveExternalModuleTypeByLiteral(node.arguments[0]);
}
return getReturnTypeOfSignature(signature);
}
function isCommonJsRequire(node) {
if (!ts.isRequireCall(node, /*checkArgumentIsStringLiteral*/ true)) {
return false;
}
// Make sure require is not a local function
var resolvedRequire = resolveName(node.expression, node.expression.text, 107455 /* Value */, /*nameNotFoundMessage*/ undefined, /*nameArg*/ undefined);
if (!resolvedRequire) {
// project does not contain symbol named 'require' - assume commonjs require
return true;
}
// project includes symbol named 'require' - make sure that it it ambient and local non-alias
if (resolvedRequire.flags & 8388608 /* Alias */) {
return false;
}
var targetDeclarationKind = resolvedRequire.flags & 16 /* Function */
? 225 /* FunctionDeclaration */
: resolvedRequire.flags & 3 /* Variable */
? 223 /* VariableDeclaration */
: 0 /* Unknown */;
if (targetDeclarationKind !== 0 /* Unknown */) {
var decl = ts.getDeclarationOfKind(resolvedRequire, targetDeclarationKind);
// function/variable declaration should be ambient
return ts.isInAmbientContext(decl);
}
return false;
}
function checkTaggedTemplateExpression(node) {
return getReturnTypeOfSignature(getResolvedSignature(node));
}
function checkAssertion(node) {
var exprType = getRegularTypeOfObjectLiteral(getBaseTypeOfLiteralType(checkExpression(node.expression)));
checkSourceElement(node.type);
var targetType = getTypeFromTypeNode(node.type);
if (produceDiagnostics && targetType !== unknownType) {
var widenedType = getWidenedType(exprType);
if (!isTypeComparableTo(targetType, widenedType)) {
checkTypeComparableTo(exprType, targetType, node, ts.Diagnostics.Type_0_cannot_be_converted_to_type_1);
}
}
return targetType;
}
function checkNonNullAssertion(node) {
return getNonNullableType(checkExpression(node.expression));
}
function getTypeOfParameter(symbol) {
var type = getTypeOfSymbol(symbol);
if (strictNullChecks) {
var declaration = symbol.valueDeclaration;
if (declaration && declaration.initializer) {
return includeFalsyTypes(type, 2048 /* Undefined */);
}
}
return type;
}
function getTypeAtPosition(signature, pos) {
return signature.hasRestParameter ?
pos < signature.parameters.length - 1 ? getTypeOfParameter(signature.parameters[pos]) : getRestTypeOfSignature(signature) :
pos < signature.parameters.length ? getTypeOfParameter(signature.parameters[pos]) : anyType;
}
function assignContextualParameterTypes(signature, context, mapper) {
var len = signature.parameters.length - (signature.hasRestParameter ? 1 : 0);
if (isInferentialContext(mapper)) {
for (var i = 0; i < len; i++) {
var declaration = signature.parameters[i].valueDeclaration;
if (declaration.type) {
inferTypes(mapper.context, getTypeFromTypeNode(declaration.type), getTypeAtPosition(context, i));
}
}
}
if (context.thisParameter) {
var parameter = signature.thisParameter;
if (!parameter || parameter.valueDeclaration && !parameter.valueDeclaration.type) {
if (!parameter) {
signature.thisParameter = createTransientSymbol(context.thisParameter, undefined);
}
assignTypeToParameterAndFixTypeParameters(signature.thisParameter, getTypeOfSymbol(context.thisParameter), mapper);
}
}
for (var i = 0; i < len; i++) {
var parameter = signature.parameters[i];
if (!parameter.valueDeclaration.type) {
var contextualParameterType = getTypeAtPosition(context, i);
assignTypeToParameterAndFixTypeParameters(parameter, contextualParameterType, mapper);
}
}
if (signature.hasRestParameter && isRestParameterIndex(context, signature.parameters.length - 1)) {
var parameter = ts.lastOrUndefined(signature.parameters);
if (!parameter.valueDeclaration.type) {
var contextualParameterType = getTypeOfSymbol(ts.lastOrUndefined(context.parameters));
assignTypeToParameterAndFixTypeParameters(parameter, contextualParameterType, mapper);
}
}
}
// When contextual typing assigns a type to a parameter that contains a binding pattern, we also need to push
// the destructured type into the contained binding elements.
function assignBindingElementTypes(node) {
if (ts.isBindingPattern(node.name)) {
for (var _i = 0, _a = node.name.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (!ts.isOmittedExpression(element)) {
if (element.name.kind === 70 /* Identifier */) {
getSymbolLinks(getSymbolOfNode(element)).type = getTypeForBindingElement(element);
}
assignBindingElementTypes(element);
}
}
}
}
function assignTypeToParameterAndFixTypeParameters(parameter, contextualType, mapper) {
var links = getSymbolLinks(parameter);
if (!links.type) {
links.type = instantiateType(contextualType, mapper);
// if inference didn't come up with anything but {}, fall back to the binding pattern if present.
if (links.type === emptyObjectType &&
(parameter.valueDeclaration.name.kind === 172 /* ObjectBindingPattern */ ||
parameter.valueDeclaration.name.kind === 173 /* ArrayBindingPattern */)) {
links.type = getTypeFromBindingPattern(parameter.valueDeclaration.name);
}
assignBindingElementTypes(parameter.valueDeclaration);
}
else if (isInferentialContext(mapper)) {
// Even if the parameter already has a type, it might be because it was given a type while
// processing the function as an argument to a prior signature during overload resolution.
// If this was the case, it may have caused some type parameters to be fixed. So here,
// we need to ensure that type parameters at the same positions get fixed again. This is
// done by calling instantiateType to attach the mapper to the contextualType, and then
// calling inferTypes to force a walk of contextualType so that all the correct fixing
// happens. The choice to pass in links.type may seem kind of arbitrary, but it serves
// to make sure that all the correct positions in contextualType are reached by the walk.
// Here is an example:
//
// interface Base {
// baseProp;
// }
// interface Derived extends Base {
// toBase(): Base;
// }
//
// var derived: Derived;
//
// declare function foo<T>(x: T, func: (p: T) => T): T;
// declare function foo<T>(x: T, func: (p: T) => T): T;
//
// var result = foo(derived, d => d.toBase());
//
// We are typing d while checking the second overload. But we've already given d
// a type (Derived) from the first overload. However, we still want to fix the
// T in the second overload so that we do not infer Base as a candidate for T
// (inferring Base would make type argument inference inconsistent between the two
// overloads).
inferTypes(mapper.context, links.type, instantiateType(contextualType, mapper));
}
}
function getReturnTypeFromJSDocComment(func) {
var returnTag = ts.getJSDocReturnTag(func);
if (returnTag && returnTag.typeExpression) {
return getTypeFromTypeNode(returnTag.typeExpression.type);
}
return undefined;
}
function createPromiseType(promisedType) {
// creates a `Promise<T>` type where `T` is the promisedType argument
var globalPromiseType = getGlobalPromiseType();
if (globalPromiseType !== emptyGenericType) {
// if the promised type is itself a promise, get the underlying type; otherwise, fallback to the promised type
promisedType = getAwaitedType(promisedType);
return createTypeReference(globalPromiseType, [promisedType]);
}
return emptyObjectType;
}
function createPromiseReturnType(func, promisedType) {
var promiseType = createPromiseType(promisedType);
if (promiseType === emptyObjectType) {
error(func, ts.Diagnostics.An_async_function_or_method_must_return_a_Promise_Make_sure_you_have_a_declaration_for_Promise_or_include_ES2015_in_your_lib_option);
return unknownType;
}
return promiseType;
}
function getReturnTypeFromBody(func, contextualMapper) {
var contextualSignature = getContextualSignatureForFunctionLikeDeclaration(func);
if (!func.body) {
return unknownType;
}
var isAsync = ts.isAsyncFunctionLike(func);
var type;
if (func.body.kind !== 204 /* Block */) {
type = checkExpressionCached(func.body, contextualMapper);
if (isAsync) {
// From within an async function you can return either a non-promise value or a promise. Any
// Promise/A+ compatible implementation will always assimilate any foreign promise, so the
// return type of the body should be unwrapped to its awaited type, which we will wrap in
// the native Promise<T> type later in this function.
type = checkAwaitedType(type, func, ts.Diagnostics.Return_expression_in_async_function_does_not_have_a_valid_callable_then_member);
}
}
else {
var types = void 0;
var funcIsGenerator = !!func.asteriskToken;
if (funcIsGenerator) {
types = checkAndAggregateYieldOperandTypes(func, contextualMapper);
if (types.length === 0) {
var iterableIteratorAny = createIterableIteratorType(anyType);
if (compilerOptions.noImplicitAny) {
error(func.asteriskToken, ts.Diagnostics.Generator_implicitly_has_type_0_because_it_does_not_yield_any_values_Consider_supplying_a_return_type, typeToString(iterableIteratorAny));
}
return iterableIteratorAny;
}
}
else {
types = checkAndAggregateReturnExpressionTypes(func, contextualMapper);
if (!types) {
// For an async function, the return type will not be never, but rather a Promise for never.
return isAsync ? createPromiseReturnType(func, neverType) : neverType;
}
if (types.length === 0) {
// For an async function, the return type will not be void, but rather a Promise for void.
return isAsync ? createPromiseReturnType(func, voidType) : voidType;
}
}
// Return a union of the return expression types.
type = getUnionType(types, /*subtypeReduction*/ true);
if (funcIsGenerator) {
type = createIterableIteratorType(type);
}
}
if (!contextualSignature) {
reportErrorsFromWidening(func, type);
}
if (isUnitType(type) &&
!(contextualSignature &&
isLiteralContextualType(contextualSignature === getSignatureFromDeclaration(func) ? type : getReturnTypeOfSignature(contextualSignature)))) {
type = getWidenedLiteralType(type);
}
var widenedType = getWidenedType(type);
// From within an async function you can return either a non-promise value or a promise. Any
// Promise/A+ compatible implementation will always assimilate any foreign promise, so the
// return type of the body is awaited type of the body, wrapped in a native Promise<T> type.
return isAsync ? createPromiseReturnType(func, widenedType) : widenedType;
}
function checkAndAggregateYieldOperandTypes(func, contextualMapper) {
var aggregatedTypes = [];
ts.forEachYieldExpression(func.body, function (yieldExpression) {
var expr = yieldExpression.expression;
if (expr) {
var type = checkExpressionCached(expr, contextualMapper);
if (yieldExpression.asteriskToken) {
// A yield* expression effectively yields everything that its operand yields
type = checkElementTypeOfIterable(type, yieldExpression.expression);
}
if (!ts.contains(aggregatedTypes, type)) {
aggregatedTypes.push(type);
}
}
});
return aggregatedTypes;
}
function isExhaustiveSwitchStatement(node) {
if (!node.possiblyExhaustive) {
return false;
}
var type = checkExpression(node.expression);
if (!isLiteralType(type)) {
return false;
}
var switchTypes = getSwitchClauseTypes(node);
if (!switchTypes.length) {
return false;
}
return eachTypeContainedIn(type, switchTypes);
}
function functionHasImplicitReturn(func) {
if (!(func.flags & 128 /* HasImplicitReturn */)) {
return false;
}
var lastStatement = ts.lastOrUndefined(func.body.statements);
if (lastStatement && lastStatement.kind === 218 /* SwitchStatement */ && isExhaustiveSwitchStatement(lastStatement)) {
return false;
}
return true;
}
function checkAndAggregateReturnExpressionTypes(func, contextualMapper) {
var isAsync = ts.isAsyncFunctionLike(func);
var aggregatedTypes = [];
var hasReturnWithNoExpression = functionHasImplicitReturn(func);
var hasReturnOfTypeNever = false;
ts.forEachReturnStatement(func.body, function (returnStatement) {
var expr = returnStatement.expression;
if (expr) {
var type = checkExpressionCached(expr, contextualMapper);
if (isAsync) {
// From within an async function you can return either a non-promise value or a promise. Any
// Promise/A+ compatible implementation will always assimilate any foreign promise, so the
// return type of the body should be unwrapped to its awaited type, which should be wrapped in
// the native Promise<T> type by the caller.
type = checkAwaitedType(type, func, ts.Diagnostics.Return_expression_in_async_function_does_not_have_a_valid_callable_then_member);
}
if (type.flags & 8192 /* Never */) {
hasReturnOfTypeNever = true;
}
else if (!ts.contains(aggregatedTypes, type)) {
aggregatedTypes.push(type);
}
}
else {
hasReturnWithNoExpression = true;
}
});
if (aggregatedTypes.length === 0 && !hasReturnWithNoExpression && (hasReturnOfTypeNever ||
func.kind === 184 /* FunctionExpression */ || func.kind === 185 /* ArrowFunction */)) {
return undefined;
}
if (strictNullChecks && aggregatedTypes.length && hasReturnWithNoExpression) {
if (!ts.contains(aggregatedTypes, undefinedType)) {
aggregatedTypes.push(undefinedType);
}
}
return aggregatedTypes;
}
/**
* TypeScript Specification 1.0 (6.3) - July 2014
* An explicitly typed function whose return type isn't the Void type,
* the Any type, or a union type containing the Void or Any type as a constituent
* must have at least one return statement somewhere in its body.
* An exception to this rule is if the function implementation consists of a single 'throw' statement.
*
* @param returnType - return type of the function, can be undefined if return type is not explicitly specified
*/
function checkAllCodePathsInNonVoidFunctionReturnOrThrow(func, returnType) {
if (!produceDiagnostics) {
return;
}
// Functions with with an explicitly specified 'void' or 'any' return type don't need any return expressions.
if (returnType && maybeTypeOfKind(returnType, 1 /* Any */ | 1024 /* Void */)) {
return;
}
// If all we have is a function signature, or an arrow function with an expression body, then there is nothing to check.
// also if HasImplicitReturn flag is not set this means that all codepaths in function body end with return or throw
if (ts.nodeIsMissing(func.body) || func.body.kind !== 204 /* Block */ || !functionHasImplicitReturn(func)) {
return;
}
var hasExplicitReturn = func.flags & 256 /* HasExplicitReturn */;
if (returnType && returnType.flags & 8192 /* Never */) {
error(func.type, ts.Diagnostics.A_function_returning_never_cannot_have_a_reachable_end_point);
}
else if (returnType && !hasExplicitReturn) {
// minimal check: function has syntactic return type annotation and no explicit return statements in the body
// this function does not conform to the specification.
// NOTE: having returnType !== undefined is a precondition for entering this branch so func.type will always be present
error(func.type, ts.Diagnostics.A_function_whose_declared_type_is_neither_void_nor_any_must_return_a_value);
}
else if (returnType && strictNullChecks && !isTypeAssignableTo(undefinedType, returnType)) {
error(func.type, ts.Diagnostics.Function_lacks_ending_return_statement_and_return_type_does_not_include_undefined);
}
else if (compilerOptions.noImplicitReturns) {
if (!returnType) {
// If return type annotation is omitted check if function has any explicit return statements.
// If it does not have any - its inferred return type is void - don't do any checks.
// Otherwise get inferred return type from function body and report error only if it is not void / anytype
if (!hasExplicitReturn) {
return;
}
var inferredReturnType = getReturnTypeOfSignature(getSignatureFromDeclaration(func));
if (isUnwrappedReturnTypeVoidOrAny(func, inferredReturnType)) {
return;
}
}
error(func.type || func, ts.Diagnostics.Not_all_code_paths_return_a_value);
}
}
function checkFunctionExpressionOrObjectLiteralMethod(node, contextualMapper) {
ts.Debug.assert(node.kind !== 149 /* MethodDeclaration */ || ts.isObjectLiteralMethod(node));
// Grammar checking
var hasGrammarError = checkGrammarFunctionLikeDeclaration(node);
if (!hasGrammarError && node.kind === 184 /* FunctionExpression */) {
checkGrammarForGenerator(node);
}
// The identityMapper object is used to indicate that function expressions are wildcards
if (contextualMapper === identityMapper && isContextSensitive(node)) {
checkNodeDeferred(node);
return anyFunctionType;
}
var links = getNodeLinks(node);
var type = getTypeOfSymbol(node.symbol);
var contextSensitive = isContextSensitive(node);
var mightFixTypeParameters = contextSensitive && isInferentialContext(contextualMapper);
// Check if function expression is contextually typed and assign parameter types if so.
// See the comment in assignTypeToParameterAndFixTypeParameters to understand why we need to
// check mightFixTypeParameters.
if (mightFixTypeParameters || !(links.flags & 1024 /* ContextChecked */)) {
var contextualSignature = getContextualSignature(node);
// If a type check is started at a function expression that is an argument of a function call, obtaining the
// contextual type may recursively get back to here during overload resolution of the call. If so, we will have
// already assigned contextual types.
var contextChecked = !!(links.flags & 1024 /* ContextChecked */);
if (mightFixTypeParameters || !contextChecked) {
links.flags |= 1024 /* ContextChecked */;
if (contextualSignature) {
var signature = getSignaturesOfType(type, 0 /* Call */)[0];
if (contextSensitive) {
assignContextualParameterTypes(signature, contextualSignature, contextualMapper || identityMapper);
}
if (mightFixTypeParameters || !node.type && !signature.resolvedReturnType) {
var returnType = getReturnTypeFromBody(node, contextualMapper);
if (!signature.resolvedReturnType) {
signature.resolvedReturnType = returnType;
}
}
}
if (!contextChecked) {
checkSignatureDeclaration(node);
checkNodeDeferred(node);
}
}
}
if (produceDiagnostics && node.kind !== 149 /* MethodDeclaration */) {
checkCollisionWithCapturedSuperVariable(node, node.name);
checkCollisionWithCapturedThisVariable(node, node.name);
}
return type;
}
function checkFunctionExpressionOrObjectLiteralMethodDeferred(node) {
ts.Debug.assert(node.kind !== 149 /* MethodDeclaration */ || ts.isObjectLiteralMethod(node));
var isAsync = ts.isAsyncFunctionLike(node);
var returnOrPromisedType = node.type && (isAsync ? checkAsyncFunctionReturnType(node) : getTypeFromTypeNode(node.type));
if (!node.asteriskToken) {
// return is not necessary in the body of generators
checkAllCodePathsInNonVoidFunctionReturnOrThrow(node, returnOrPromisedType);
}
if (node.body) {
if (!node.type) {
// There are some checks that are only performed in getReturnTypeFromBody, that may produce errors
// we need. An example is the noImplicitAny errors resulting from widening the return expression
// of a function. Because checking of function expression bodies is deferred, there was never an
// appropriate time to do this during the main walk of the file (see the comment at the top of
// checkFunctionExpressionBodies). So it must be done now.
getReturnTypeOfSignature(getSignatureFromDeclaration(node));
}
if (node.body.kind === 204 /* Block */) {
checkSourceElement(node.body);
}
else {
// From within an async function you can return either a non-promise value or a promise. Any
// Promise/A+ compatible implementation will always assimilate any foreign promise, so we
// should not be checking assignability of a promise to the return type. Instead, we need to
// check assignability of the awaited type of the expression body against the promised type of
// its return type annotation.
var exprType = checkExpression(node.body);
if (returnOrPromisedType) {
if (isAsync) {
var awaitedType = checkAwaitedType(exprType, node.body, ts.Diagnostics.Expression_body_for_async_arrow_function_does_not_have_a_valid_callable_then_member);
checkTypeAssignableTo(awaitedType, returnOrPromisedType, node.body);
}
else {
checkTypeAssignableTo(exprType, returnOrPromisedType, node.body);
}
}
}
registerForUnusedIdentifiersCheck(node);
}
}
function checkArithmeticOperandType(operand, type, diagnostic) {
if (!isTypeAnyOrAllConstituentTypesHaveKind(type, 340 /* NumberLike */)) {
error(operand, diagnostic);
return false;
}
return true;
}
function isReadonlySymbol(symbol) {
// The following symbols are considered read-only:
// Properties with a 'readonly' modifier
// Variables declared with 'const'
// Get accessors without matching set accessors
// Enum members
// Unions and intersections of the above (unions and intersections eagerly set isReadonly on creation)
return symbol.isReadonly ||
symbol.flags & 4 /* Property */ && (getDeclarationModifierFlagsFromSymbol(symbol) & 64 /* Readonly */) !== 0 ||
symbol.flags & 3 /* Variable */ && (getDeclarationNodeFlagsFromSymbol(symbol) & 2 /* Const */) !== 0 ||
symbol.flags & 98304 /* Accessor */ && !(symbol.flags & 65536 /* SetAccessor */) ||
(symbol.flags & 8 /* EnumMember */) !== 0;
}
function isReferenceToReadonlyEntity(expr, symbol) {
if (isReadonlySymbol(symbol)) {
// Allow assignments to readonly properties within constructors of the same class declaration.
if (symbol.flags & 4 /* Property */ &&
(expr.kind === 177 /* PropertyAccessExpression */ || expr.kind === 178 /* ElementAccessExpression */) &&
expr.expression.kind === 98 /* ThisKeyword */) {
// Look for if this is the constructor for the class that `symbol` is a property of.
var func = ts.getContainingFunction(expr);
if (!(func && func.kind === 150 /* Constructor */))
return true;
// If func.parent is a class and symbol is a (readonly) property of that class, or
// if func is a constructor and symbol is a (readonly) parameter property declared in it,
// then symbol is writeable here.
return !(func.parent === symbol.valueDeclaration.parent || func === symbol.valueDeclaration.parent);
}
return true;
}
return false;
}
function isReferenceThroughNamespaceImport(expr) {
if (expr.kind === 177 /* PropertyAccessExpression */ || expr.kind === 178 /* ElementAccessExpression */) {
var node = ts.skipParentheses(expr.expression);
if (node.kind === 70 /* Identifier */) {
var symbol = getNodeLinks(node).resolvedSymbol;
if (symbol.flags & 8388608 /* Alias */) {
var declaration = getDeclarationOfAliasSymbol(symbol);
return declaration && declaration.kind === 237 /* NamespaceImport */;
}
}
}
return false;
}
function checkReferenceExpression(expr, invalidReferenceMessage) {
// References are combinations of identifiers, parentheses, and property accesses.
var node = ts.skipParentheses(expr);
if (node.kind !== 70 /* Identifier */ && node.kind !== 177 /* PropertyAccessExpression */ && node.kind !== 178 /* ElementAccessExpression */) {
error(expr, invalidReferenceMessage);
return false;
}
return true;
}
function checkDeleteExpression(node) {
checkExpression(node.expression);
return booleanType;
}
function checkTypeOfExpression(node) {
checkExpression(node.expression);
return stringType;
}
function checkVoidExpression(node) {
checkExpression(node.expression);
return undefinedWideningType;
}
function checkAwaitExpression(node) {
// Grammar checking
if (produceDiagnostics) {
if (!(node.flags & 524288 /* AwaitContext */)) {
grammarErrorOnFirstToken(node, ts.Diagnostics.await_expression_is_only_allowed_within_an_async_function);
}
if (isInParameterInitializerBeforeContainingFunction(node)) {
error(node, ts.Diagnostics.await_expressions_cannot_be_used_in_a_parameter_initializer);
}
}
var operandType = checkExpression(node.expression);
return checkAwaitedType(operandType, node);
}
function checkPrefixUnaryExpression(node) {
var operandType = checkExpression(node.operand);
if (operandType === silentNeverType) {
return silentNeverType;
}
if (node.operator === 37 /* MinusToken */ && node.operand.kind === 8 /* NumericLiteral */) {
return getFreshTypeOfLiteralType(getLiteralTypeForText(64 /* NumberLiteral */, "" + -node.operand.text));
}
switch (node.operator) {
case 36 /* PlusToken */:
case 37 /* MinusToken */:
case 51 /* TildeToken */:
if (maybeTypeOfKind(operandType, 512 /* ESSymbol */)) {
error(node.operand, ts.Diagnostics.The_0_operator_cannot_be_applied_to_type_symbol, ts.tokenToString(node.operator));
}
return numberType;
case 50 /* ExclamationToken */:
var facts = getTypeFacts(operandType) & (1048576 /* Truthy */ | 2097152 /* Falsy */);
return facts === 1048576 /* Truthy */ ? falseType :
facts === 2097152 /* Falsy */ ? trueType :
booleanType;
case 42 /* PlusPlusToken */:
case 43 /* MinusMinusToken */:
var ok = checkArithmeticOperandType(node.operand, getNonNullableType(operandType), ts.Diagnostics.An_arithmetic_operand_must_be_of_type_any_number_or_an_enum_type);
if (ok) {
// run check only if former checks succeeded to avoid reporting cascading errors
checkReferenceExpression(node.operand, ts.Diagnostics.The_operand_of_an_increment_or_decrement_operator_must_be_a_variable_or_a_property_access);
}
return numberType;
}
return unknownType;
}
function checkPostfixUnaryExpression(node) {
var operandType = checkExpression(node.operand);
if (operandType === silentNeverType) {
return silentNeverType;
}
var ok = checkArithmeticOperandType(node.operand, getNonNullableType(operandType), ts.Diagnostics.An_arithmetic_operand_must_be_of_type_any_number_or_an_enum_type);
if (ok) {
// run check only if former checks succeeded to avoid reporting cascading errors
checkReferenceExpression(node.operand, ts.Diagnostics.The_operand_of_an_increment_or_decrement_operator_must_be_a_variable_or_a_property_access);
}
return numberType;
}
// Return true if type might be of the given kind. A union or intersection type might be of a given
// kind if at least one constituent type is of the given kind.
function maybeTypeOfKind(type, kind) {
if (type.flags & kind) {
return true;
}
if (type.flags & 196608 /* UnionOrIntersection */) {
var types = type.types;
for (var _i = 0, types_15 = types; _i < types_15.length; _i++) {
var t = types_15[_i];
if (maybeTypeOfKind(t, kind)) {
return true;
}
}
}
return false;
}
// Return true if type is of the given kind. A union type is of a given kind if all constituent types
// are of the given kind. An intersection type is of a given kind if at least one constituent type is
// of the given kind.
function isTypeOfKind(type, kind) {
if (type.flags & kind) {
return true;
}
if (type.flags & 65536 /* Union */) {
var types = type.types;
for (var _i = 0, types_16 = types; _i < types_16.length; _i++) {
var t = types_16[_i];
if (!isTypeOfKind(t, kind)) {
return false;
}
}
return true;
}
if (type.flags & 131072 /* Intersection */) {
var types = type.types;
for (var _a = 0, types_17 = types; _a < types_17.length; _a++) {
var t = types_17[_a];
if (isTypeOfKind(t, kind)) {
return true;
}
}
}
return false;
}
function isConstEnumObjectType(type) {
return getObjectFlags(type) & 16 /* Anonymous */ && type.symbol && isConstEnumSymbol(type.symbol);
}
function isConstEnumSymbol(symbol) {
return (symbol.flags & 128 /* ConstEnum */) !== 0;
}
function checkInstanceOfExpression(left, right, leftType, rightType) {
if (leftType === silentNeverType || rightType === silentNeverType) {
return silentNeverType;
}
// TypeScript 1.0 spec (April 2014): 4.15.4
// The instanceof operator requires the left operand to be of type Any, an object type, or a type parameter type,
// and the right operand to be of type Any or a subtype of the 'Function' interface type.
// The result is always of the Boolean primitive type.
// NOTE: do not raise error if leftType is unknown as related error was already reported
if (isTypeOfKind(leftType, 8190 /* Primitive */)) {
error(left, ts.Diagnostics.The_left_hand_side_of_an_instanceof_expression_must_be_of_type_any_an_object_type_or_a_type_parameter);
}
// NOTE: do not raise error if right is unknown as related error was already reported
if (!(isTypeAny(rightType) || isTypeSubtypeOf(rightType, globalFunctionType))) {
error(right, ts.Diagnostics.The_right_hand_side_of_an_instanceof_expression_must_be_of_type_any_or_of_a_type_assignable_to_the_Function_interface_type);
}
return booleanType;
}
function checkInExpression(left, right, leftType, rightType) {
if (leftType === silentNeverType || rightType === silentNeverType) {
return silentNeverType;
}
// TypeScript 1.0 spec (April 2014): 4.15.5
// The in operator requires the left operand to be of type Any, the String primitive type, or the Number primitive type,
// and the right operand to be of type Any, an object type, or a type parameter type.
// The result is always of the Boolean primitive type.
if (!isTypeAnyOrAllConstituentTypesHaveKind(leftType, 34 /* StringLike */ | 340 /* NumberLike */ | 512 /* ESSymbol */)) {
error(left, ts.Diagnostics.The_left_hand_side_of_an_in_expression_must_be_of_type_any_string_number_or_symbol);
}
if (!isTypeAnyOrAllConstituentTypesHaveKind(rightType, 32768 /* Object */ | 16384 /* TypeParameter */)) {
error(right, ts.Diagnostics.The_right_hand_side_of_an_in_expression_must_be_of_type_any_an_object_type_or_a_type_parameter);
}
return booleanType;
}
function checkObjectLiteralAssignment(node, sourceType) {
var properties = node.properties;
for (var _i = 0, properties_5 = properties; _i < properties_5.length; _i++) {
var p = properties_5[_i];
checkObjectLiteralDestructuringPropertyAssignment(sourceType, p);
}
return sourceType;
}
function checkObjectLiteralDestructuringPropertyAssignment(objectLiteralType, property) {
if (property.kind === 257 /* PropertyAssignment */ || property.kind === 258 /* ShorthandPropertyAssignment */) {
var name_21 = property.name;
if (name_21.kind === 142 /* ComputedPropertyName */) {
checkComputedPropertyName(name_21);
}
if (isComputedNonLiteralName(name_21)) {
return undefined;
}
var text = ts.getTextOfPropertyName(name_21);
var type = isTypeAny(objectLiteralType)
? objectLiteralType
: getTypeOfPropertyOfType(objectLiteralType, text) ||
isNumericLiteralName(text) && getIndexTypeOfType(objectLiteralType, 1 /* Number */) ||
getIndexTypeOfType(objectLiteralType, 0 /* String */);
if (type) {
if (property.kind === 258 /* ShorthandPropertyAssignment */) {
return checkDestructuringAssignment(property, type);
}
else {
// non-shorthand property assignments should always have initializers
return checkDestructuringAssignment(property.initializer, type);
}
}
else {
error(name_21, ts.Diagnostics.Type_0_has_no_property_1_and_no_string_index_signature, typeToString(objectLiteralType), ts.declarationNameToString(name_21));
}
}
else if (property.kind === 259 /* SpreadAssignment */) {
if (property.expression.kind !== 70 /* Identifier */) {
error(property.expression, ts.Diagnostics.An_object_rest_element_must_be_an_identifier);
}
}
else {
error(property, ts.Diagnostics.Property_assignment_expected);
}
}
function checkArrayLiteralAssignment(node, sourceType, contextualMapper) {
// This elementType will be used if the specific property corresponding to this index is not
// present (aka the tuple element property). This call also checks that the parentType is in
// fact an iterable or array (depending on target language).
var elementType = checkIteratedTypeOrElementType(sourceType, node, /*allowStringInput*/ false) || unknownType;
var elements = node.elements;
for (var i = 0; i < elements.length; i++) {
checkArrayLiteralDestructuringElementAssignment(node, sourceType, i, elementType, contextualMapper);
}
return sourceType;
}
function checkArrayLiteralDestructuringElementAssignment(node, sourceType, elementIndex, elementType, contextualMapper) {
var elements = node.elements;
var element = elements[elementIndex];
if (element.kind !== 198 /* OmittedExpression */) {
if (element.kind !== 196 /* SpreadElement */) {
var propName = "" + elementIndex;
var type = isTypeAny(sourceType)
? sourceType
: isTupleLikeType(sourceType)
? getTypeOfPropertyOfType(sourceType, propName)
: elementType;
if (type) {
return checkDestructuringAssignment(element, type, contextualMapper);
}
else {
// We still need to check element expression here because we may need to set appropriate flag on the expression
// such as NodeCheckFlags.LexicalThis on "this"expression.
checkExpression(element);
if (isTupleType(sourceType)) {
error(element, ts.Diagnostics.Tuple_type_0_with_length_1_cannot_be_assigned_to_tuple_with_length_2, typeToString(sourceType), getTypeReferenceArity(sourceType), elements.length);
}
else {
error(element, ts.Diagnostics.Type_0_has_no_property_1, typeToString(sourceType), propName);
}
}
}
else {
if (elementIndex < elements.length - 1) {
error(element, ts.Diagnostics.A_rest_element_must_be_last_in_a_destructuring_pattern);
}
else {
var restExpression = element.expression;
if (restExpression.kind === 192 /* BinaryExpression */ && restExpression.operatorToken.kind === 57 /* EqualsToken */) {
error(restExpression.operatorToken, ts.Diagnostics.A_rest_element_cannot_have_an_initializer);
}
else {
return checkDestructuringAssignment(restExpression, createArrayType(elementType), contextualMapper);
}
}
}
}
return undefined;
}
function checkDestructuringAssignment(exprOrAssignment, sourceType, contextualMapper) {
var target;
if (exprOrAssignment.kind === 258 /* ShorthandPropertyAssignment */) {
var prop = exprOrAssignment;
if (prop.objectAssignmentInitializer) {
// In strict null checking mode, if a default value of a non-undefined type is specified, remove
// undefined from the final type.
if (strictNullChecks &&
!(getFalsyFlags(checkExpression(prop.objectAssignmentInitializer)) & 2048 /* Undefined */)) {
sourceType = getTypeWithFacts(sourceType, 131072 /* NEUndefined */);
}
checkBinaryLikeExpression(prop.name, prop.equalsToken, prop.objectAssignmentInitializer, contextualMapper);
}
target = exprOrAssignment.name;
}
else {
target = exprOrAssignment;
}
if (target.kind === 192 /* BinaryExpression */ && target.operatorToken.kind === 57 /* EqualsToken */) {
checkBinaryExpression(target, contextualMapper);
target = target.left;
}
if (target.kind === 176 /* ObjectLiteralExpression */) {
return checkObjectLiteralAssignment(target, sourceType);
}
if (target.kind === 175 /* ArrayLiteralExpression */) {
return checkArrayLiteralAssignment(target, sourceType, contextualMapper);
}
return checkReferenceAssignment(target, sourceType, contextualMapper);
}
function checkReferenceAssignment(target, sourceType, contextualMapper) {
var targetType = checkExpression(target, contextualMapper);
if (checkReferenceExpression(target, ts.Diagnostics.The_left_hand_side_of_an_assignment_expression_must_be_a_variable_or_a_property_access)) {
checkTypeAssignableTo(sourceType, targetType, target, /*headMessage*/ undefined);
}
return sourceType;
}
/**
* This is a *shallow* check: An expression is side-effect-free if the
* evaluation of the expression *itself* cannot produce side effects.
* For example, x++ / 3 is side-effect free because the / operator
* does not have side effects.
* The intent is to "smell test" an expression for correctness in positions where
* its value is discarded (e.g. the left side of the comma operator).
*/
function isSideEffectFree(node) {
node = ts.skipParentheses(node);
switch (node.kind) {
case 70 /* Identifier */:
case 9 /* StringLiteral */:
case 11 /* RegularExpressionLiteral */:
case 181 /* TaggedTemplateExpression */:
case 194 /* TemplateExpression */:
case 12 /* NoSubstitutionTemplateLiteral */:
case 8 /* NumericLiteral */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
case 94 /* NullKeyword */:
case 137 /* UndefinedKeyword */:
case 184 /* FunctionExpression */:
case 197 /* ClassExpression */:
case 185 /* ArrowFunction */:
case 175 /* ArrayLiteralExpression */:
case 176 /* ObjectLiteralExpression */:
case 187 /* TypeOfExpression */:
case 201 /* NonNullExpression */:
case 247 /* JsxSelfClosingElement */:
case 246 /* JsxElement */:
return true;
case 193 /* ConditionalExpression */:
return isSideEffectFree(node.whenTrue) &&
isSideEffectFree(node.whenFalse);
case 192 /* BinaryExpression */:
if (ts.isAssignmentOperator(node.operatorToken.kind)) {
return false;
}
return isSideEffectFree(node.left) &&
isSideEffectFree(node.right);
case 190 /* PrefixUnaryExpression */:
case 191 /* PostfixUnaryExpression */:
// Unary operators ~, !, +, and - have no side effects.
// The rest do.
switch (node.operator) {
case 50 /* ExclamationToken */:
case 36 /* PlusToken */:
case 37 /* MinusToken */:
case 51 /* TildeToken */:
return true;
}
return false;
// Some forms listed here for clarity
case 188 /* VoidExpression */: // Explicit opt-out
case 182 /* TypeAssertionExpression */: // Not SEF, but can produce useful type warnings
case 200 /* AsExpression */: // Not SEF, but can produce useful type warnings
default:
return false;
}
}
function isTypeEqualityComparableTo(source, target) {
return (target.flags & 6144 /* Nullable */) !== 0 || isTypeComparableTo(source, target);
}
function getBestChoiceType(type1, type2) {
var firstAssignableToSecond = isTypeAssignableTo(type1, type2);
var secondAssignableToFirst = isTypeAssignableTo(type2, type1);
return secondAssignableToFirst && !firstAssignableToSecond ? type1 :
firstAssignableToSecond && !secondAssignableToFirst ? type2 :
getUnionType([type1, type2], /*subtypeReduction*/ true);
}
function checkBinaryExpression(node, contextualMapper) {
return checkBinaryLikeExpression(node.left, node.operatorToken, node.right, contextualMapper, node);
}
function checkBinaryLikeExpression(left, operatorToken, right, contextualMapper, errorNode) {
var operator = operatorToken.kind;
if (operator === 57 /* EqualsToken */ && (left.kind === 176 /* ObjectLiteralExpression */ || left.kind === 175 /* ArrayLiteralExpression */)) {
return checkDestructuringAssignment(left, checkExpression(right, contextualMapper), contextualMapper);
}
var leftType = checkExpression(left, contextualMapper);
var rightType = checkExpression(right, contextualMapper);
switch (operator) {
case 38 /* AsteriskToken */:
case 39 /* AsteriskAsteriskToken */:
case 60 /* AsteriskEqualsToken */:
case 61 /* AsteriskAsteriskEqualsToken */:
case 40 /* SlashToken */:
case 62 /* SlashEqualsToken */:
case 41 /* PercentToken */:
case 63 /* PercentEqualsToken */:
case 37 /* MinusToken */:
case 59 /* MinusEqualsToken */:
case 44 /* LessThanLessThanToken */:
case 64 /* LessThanLessThanEqualsToken */:
case 45 /* GreaterThanGreaterThanToken */:
case 65 /* GreaterThanGreaterThanEqualsToken */:
case 46 /* GreaterThanGreaterThanGreaterThanToken */:
case 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */:
case 48 /* BarToken */:
case 68 /* BarEqualsToken */:
case 49 /* CaretToken */:
case 69 /* CaretEqualsToken */:
case 47 /* AmpersandToken */:
case 67 /* AmpersandEqualsToken */:
if (leftType === silentNeverType || rightType === silentNeverType) {
return silentNeverType;
}
// TypeScript 1.0 spec (April 2014): 4.19.1
// These operators require their operands to be of type Any, the Number primitive type,
// or an enum type. Operands of an enum type are treated
// as having the primitive type Number. If one operand is the null or undefined value,
// it is treated as having the type of the other operand.
// The result is always of the Number primitive type.
if (leftType.flags & 6144 /* Nullable */)
leftType = rightType;
if (rightType.flags & 6144 /* Nullable */)
rightType = leftType;
leftType = getNonNullableType(leftType);
rightType = getNonNullableType(rightType);
var suggestedOperator = void 0;
// if a user tries to apply a bitwise operator to 2 boolean operands
// try and return them a helpful suggestion
if ((leftType.flags & 136 /* BooleanLike */) &&
(rightType.flags & 136 /* BooleanLike */) &&
(suggestedOperator = getSuggestedBooleanOperator(operatorToken.kind)) !== undefined) {
error(errorNode || operatorToken, ts.Diagnostics.The_0_operator_is_not_allowed_for_boolean_types_Consider_using_1_instead, ts.tokenToString(operatorToken.kind), ts.tokenToString(suggestedOperator));
}
else {
// otherwise just check each operand separately and report errors as normal
var leftOk = checkArithmeticOperandType(left, leftType, ts.Diagnostics.The_left_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_or_an_enum_type);
var rightOk = checkArithmeticOperandType(right, rightType, ts.Diagnostics.The_right_hand_side_of_an_arithmetic_operation_must_be_of_type_any_number_or_an_enum_type);
if (leftOk && rightOk) {
checkAssignmentOperator(numberType);
}
}
return numberType;
case 36 /* PlusToken */:
case 58 /* PlusEqualsToken */:
if (leftType === silentNeverType || rightType === silentNeverType) {
return silentNeverType;
}
// TypeScript 1.0 spec (April 2014): 4.19.2
// The binary + operator requires both operands to be of the Number primitive type or an enum type,
// or at least one of the operands to be of type Any or the String primitive type.
// If one operand is the null or undefined value, it is treated as having the type of the other operand.
if (leftType.flags & 6144 /* Nullable */)
leftType = rightType;
if (rightType.flags & 6144 /* Nullable */)
rightType = leftType;
leftType = getNonNullableType(leftType);
rightType = getNonNullableType(rightType);
var resultType = void 0;
if (isTypeOfKind(leftType, 340 /* NumberLike */) && isTypeOfKind(rightType, 340 /* NumberLike */)) {
// Operands of an enum type are treated as having the primitive type Number.
// If both operands are of the Number primitive type, the result is of the Number primitive type.
resultType = numberType;
}
else {
if (isTypeOfKind(leftType, 34 /* StringLike */) || isTypeOfKind(rightType, 34 /* StringLike */)) {
// If one or both operands are of the String primitive type, the result is of the String primitive type.
resultType = stringType;
}
else if (isTypeAny(leftType) || isTypeAny(rightType)) {
// Otherwise, the result is of type Any.
// NOTE: unknown type here denotes error type. Old compiler treated this case as any type so do we.
resultType = leftType === unknownType || rightType === unknownType ? unknownType : anyType;
}
// Symbols are not allowed at all in arithmetic expressions
if (resultType && !checkForDisallowedESSymbolOperand(operator)) {
return resultType;
}
}
if (!resultType) {
reportOperatorError();
return anyType;
}
if (operator === 58 /* PlusEqualsToken */) {
checkAssignmentOperator(resultType);
}
return resultType;
case 26 /* LessThanToken */:
case 28 /* GreaterThanToken */:
case 29 /* LessThanEqualsToken */:
case 30 /* GreaterThanEqualsToken */:
if (checkForDisallowedESSymbolOperand(operator)) {
if (!isTypeComparableTo(leftType, rightType) && !isTypeComparableTo(rightType, leftType)) {
reportOperatorError();
}
}
return booleanType;
case 31 /* EqualsEqualsToken */:
case 32 /* ExclamationEqualsToken */:
case 33 /* EqualsEqualsEqualsToken */:
case 34 /* ExclamationEqualsEqualsToken */:
var leftIsLiteral = isLiteralType(leftType);
var rightIsLiteral = isLiteralType(rightType);
if (!leftIsLiteral || !rightIsLiteral) {
leftType = leftIsLiteral ? getBaseTypeOfLiteralType(leftType) : leftType;
rightType = rightIsLiteral ? getBaseTypeOfLiteralType(rightType) : rightType;
}
if (!isTypeEqualityComparableTo(leftType, rightType) && !isTypeEqualityComparableTo(rightType, leftType)) {
reportOperatorError();
}
return booleanType;
case 92 /* InstanceOfKeyword */:
return checkInstanceOfExpression(left, right, leftType, rightType);
case 91 /* InKeyword */:
return checkInExpression(left, right, leftType, rightType);
case 52 /* AmpersandAmpersandToken */:
return getTypeFacts(leftType) & 1048576 /* Truthy */ ?
includeFalsyTypes(rightType, getFalsyFlags(strictNullChecks ? leftType : getBaseTypeOfLiteralType(rightType))) :
leftType;
case 53 /* BarBarToken */:
return getTypeFacts(leftType) & 2097152 /* Falsy */ ?
getBestChoiceType(removeDefinitelyFalsyTypes(leftType), rightType) :
leftType;
case 57 /* EqualsToken */:
checkAssignmentOperator(rightType);
return getRegularTypeOfObjectLiteral(rightType);
case 25 /* CommaToken */:
if (!compilerOptions.allowUnreachableCode && isSideEffectFree(left)) {
error(left, ts.Diagnostics.Left_side_of_comma_operator_is_unused_and_has_no_side_effects);
}
return rightType;
}
// Return true if there was no error, false if there was an error.
function checkForDisallowedESSymbolOperand(operator) {
var offendingSymbolOperand = maybeTypeOfKind(leftType, 512 /* ESSymbol */) ? left :
maybeTypeOfKind(rightType, 512 /* ESSymbol */) ? right :
undefined;
if (offendingSymbolOperand) {
error(offendingSymbolOperand, ts.Diagnostics.The_0_operator_cannot_be_applied_to_type_symbol, ts.tokenToString(operator));
return false;
}
return true;
}
function getSuggestedBooleanOperator(operator) {
switch (operator) {
case 48 /* BarToken */:
case 68 /* BarEqualsToken */:
return 53 /* BarBarToken */;
case 49 /* CaretToken */:
case 69 /* CaretEqualsToken */:
return 34 /* ExclamationEqualsEqualsToken */;
case 47 /* AmpersandToken */:
case 67 /* AmpersandEqualsToken */:
return 52 /* AmpersandAmpersandToken */;
default:
return undefined;
}
}
function checkAssignmentOperator(valueType) {
if (produceDiagnostics && operator >= 57 /* FirstAssignment */ && operator <= 69 /* LastAssignment */) {
// TypeScript 1.0 spec (April 2014): 4.17
// An assignment of the form
// VarExpr = ValueExpr
// requires VarExpr to be classified as a reference
// A compound assignment furthermore requires VarExpr to be classified as a reference (section 4.1)
// and the type of the non - compound operation to be assignable to the type of VarExpr.
if (checkReferenceExpression(left, ts.Diagnostics.The_left_hand_side_of_an_assignment_expression_must_be_a_variable_or_a_property_access)) {
// to avoid cascading errors check assignability only if 'isReference' check succeeded and no errors were reported
checkTypeAssignableTo(valueType, leftType, left, /*headMessage*/ undefined);
}
}
}
function reportOperatorError() {
error(errorNode || operatorToken, ts.Diagnostics.Operator_0_cannot_be_applied_to_types_1_and_2, ts.tokenToString(operatorToken.kind), typeToString(leftType), typeToString(rightType));
}
}
function isYieldExpressionInClass(node) {
var current = node;
var parent = node.parent;
while (parent) {
if (ts.isFunctionLike(parent) && current === parent.body) {
return false;
}
else if (ts.isClassLike(current)) {
return true;
}
current = parent;
parent = parent.parent;
}
return false;
}
function checkYieldExpression(node) {
// Grammar checking
if (produceDiagnostics) {
if (!(node.flags & 131072 /* YieldContext */) || isYieldExpressionInClass(node)) {
grammarErrorOnFirstToken(node, ts.Diagnostics.A_yield_expression_is_only_allowed_in_a_generator_body);
}
if (isInParameterInitializerBeforeContainingFunction(node)) {
error(node, ts.Diagnostics.yield_expressions_cannot_be_used_in_a_parameter_initializer);
}
}
if (node.expression) {
var func = ts.getContainingFunction(node);
// If the user's code is syntactically correct, the func should always have a star. After all,
// we are in a yield context.
if (func && func.asteriskToken) {
var expressionType = checkExpressionCached(node.expression, /*contextualMapper*/ undefined);
var expressionElementType = void 0;
var nodeIsYieldStar = !!node.asteriskToken;
if (nodeIsYieldStar) {
expressionElementType = checkElementTypeOfIterable(expressionType, node.expression);
}
// There is no point in doing an assignability check if the function
// has no explicit return type because the return type is directly computed
// from the yield expressions.
if (func.type) {
var signatureElementType = getElementTypeOfIterableIterator(getTypeFromTypeNode(func.type)) || anyType;
if (nodeIsYieldStar) {
checkTypeAssignableTo(expressionElementType, signatureElementType, node.expression, /*headMessage*/ undefined);
}
else {
checkTypeAssignableTo(expressionType, signatureElementType, node.expression, /*headMessage*/ undefined);
}
}
}
}
// Both yield and yield* expressions have type 'any'
return anyType;
}
function checkConditionalExpression(node, contextualMapper) {
checkExpression(node.condition);
var type1 = checkExpression(node.whenTrue, contextualMapper);
var type2 = checkExpression(node.whenFalse, contextualMapper);
return getBestChoiceType(type1, type2);
}
function checkLiteralExpression(node) {
if (node.kind === 8 /* NumericLiteral */) {
checkGrammarNumericLiteral(node);
}
switch (node.kind) {
case 9 /* StringLiteral */:
return getFreshTypeOfLiteralType(getLiteralTypeForText(32 /* StringLiteral */, node.text));
case 8 /* NumericLiteral */:
return getFreshTypeOfLiteralType(getLiteralTypeForText(64 /* NumberLiteral */, node.text));
case 100 /* TrueKeyword */:
return trueType;
case 85 /* FalseKeyword */:
return falseType;
}
}
function checkTemplateExpression(node) {
// We just want to check each expressions, but we are unconcerned with
// the type of each expression, as any value may be coerced into a string.
// It is worth asking whether this is what we really want though.
// A place where we actually *are* concerned with the expressions' types are
// in tagged templates.
ts.forEach(node.templateSpans, function (templateSpan) {
checkExpression(templateSpan.expression);
});
return stringType;
}
function checkExpressionWithContextualType(node, contextualType, contextualMapper) {
var saveContextualType = node.contextualType;
node.contextualType = contextualType;
var result = checkExpression(node, contextualMapper);
node.contextualType = saveContextualType;
return result;
}
function checkExpressionCached(node, contextualMapper) {
var links = getNodeLinks(node);
if (!links.resolvedType) {
// When computing a type that we're going to cache, we need to ignore any ongoing control flow
// analysis because variables may have transient types in indeterminable states. Moving flowLoopStart
// to the top of the stack ensures all transient types are computed from a known point.
var saveFlowLoopStart = flowLoopStart;
flowLoopStart = flowLoopCount;
links.resolvedType = checkExpression(node, contextualMapper);
flowLoopStart = saveFlowLoopStart;
}
return links.resolvedType;
}
function isTypeAssertion(node) {
node = ts.skipParentheses(node);
return node.kind === 182 /* TypeAssertionExpression */ || node.kind === 200 /* AsExpression */;
}
function checkDeclarationInitializer(declaration) {
var type = checkExpressionCached(declaration.initializer);
return ts.getCombinedNodeFlags(declaration) & 2 /* Const */ ||
ts.getCombinedModifierFlags(declaration) & 64 /* Readonly */ ||
isTypeAssertion(declaration.initializer) ? type : getWidenedLiteralType(type);
}
function isLiteralContextualType(contextualType) {
if (contextualType) {
if (contextualType.flags & 16384 /* TypeParameter */) {
var apparentType = getApparentTypeOfTypeParameter(contextualType);
// If the type parameter is constrained to the base primitive type we're checking for,
// consider this a literal context. For example, given a type parameter 'T extends string',
// this causes us to infer string literal types for T.
if (apparentType.flags & (2 /* String */ | 4 /* Number */ | 8 /* Boolean */ | 16 /* Enum */)) {
return true;
}
contextualType = apparentType;
}
return maybeTypeOfKind(contextualType, 480 /* Literal */);
}
return false;
}
function checkExpressionForMutableLocation(node, contextualMapper) {
var type = checkExpression(node, contextualMapper);
return isTypeAssertion(node) || isLiteralContextualType(getContextualType(node)) ? type : getWidenedLiteralType(type);
}
function checkPropertyAssignment(node, contextualMapper) {
// Do not use hasDynamicName here, because that returns false for well known symbols.
// We want to perform checkComputedPropertyName for all computed properties, including
// well known symbols.
if (node.name.kind === 142 /* ComputedPropertyName */) {
checkComputedPropertyName(node.name);
}
return checkExpressionForMutableLocation(node.initializer, contextualMapper);
}
function checkObjectLiteralMethod(node, contextualMapper) {
// Grammar checking
checkGrammarMethod(node);
// Do not use hasDynamicName here, because that returns false for well known symbols.
// We want to perform checkComputedPropertyName for all computed properties, including
// well known symbols.
if (node.name.kind === 142 /* ComputedPropertyName */) {
checkComputedPropertyName(node.name);
}
var uninstantiatedType = checkFunctionExpressionOrObjectLiteralMethod(node, contextualMapper);
return instantiateTypeWithSingleGenericCallSignature(node, uninstantiatedType, contextualMapper);
}
function instantiateTypeWithSingleGenericCallSignature(node, type, contextualMapper) {
if (isInferentialContext(contextualMapper)) {
var signature = getSingleCallSignature(type);
if (signature && signature.typeParameters) {
var contextualType = getApparentTypeOfContextualType(node);
if (contextualType) {
var contextualSignature = getSingleCallSignature(contextualType);
if (contextualSignature && !contextualSignature.typeParameters) {
return getOrCreateTypeFromSignature(instantiateSignatureInContextOf(signature, contextualSignature, contextualMapper));
}
}
}
}
return type;
}
// Checks an expression and returns its type. The contextualMapper parameter serves two purposes: When
// contextualMapper is not undefined and not equal to the identityMapper function object it indicates that the
// expression is being inferentially typed (section 4.15.2 in spec) and provides the type mapper to use in
// conjunction with the generic contextual type. When contextualMapper is equal to the identityMapper function
// object, it serves as an indicator that all contained function and arrow expressions should be considered to
// have the wildcard function type; this form of type check is used during overload resolution to exclude
// contextually typed function and arrow expressions in the initial phase.
function checkExpression(node, contextualMapper) {
var type;
if (node.kind === 141 /* QualifiedName */) {
type = checkQualifiedName(node);
}
else {
var uninstantiatedType = checkExpressionWorker(node, contextualMapper);
type = instantiateTypeWithSingleGenericCallSignature(node, uninstantiatedType, contextualMapper);
}
if (isConstEnumObjectType(type)) {
// enum object type for const enums are only permitted in:
// - 'left' in property access
// - 'object' in indexed access
// - target in rhs of import statement
var ok = (node.parent.kind === 177 /* PropertyAccessExpression */ && node.parent.expression === node) ||
(node.parent.kind === 178 /* ElementAccessExpression */ && node.parent.expression === node) ||
((node.kind === 70 /* Identifier */ || node.kind === 141 /* QualifiedName */) && isInRightSideOfImportOrExportAssignment(node));
if (!ok) {
error(node, ts.Diagnostics.const_enums_can_only_be_used_in_property_or_index_access_expressions_or_the_right_hand_side_of_an_import_declaration_or_export_assignment);
}
}
return type;
}
function checkExpressionWorker(node, contextualMapper) {
switch (node.kind) {
case 70 /* Identifier */:
return checkIdentifier(node);
case 98 /* ThisKeyword */:
return checkThisExpression(node);
case 96 /* SuperKeyword */:
return checkSuperExpression(node);
case 94 /* NullKeyword */:
return nullWideningType;
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
return checkLiteralExpression(node);
case 194 /* TemplateExpression */:
return checkTemplateExpression(node);
case 12 /* NoSubstitutionTemplateLiteral */:
return stringType;
case 11 /* RegularExpressionLiteral */:
return globalRegExpType;
case 175 /* ArrayLiteralExpression */:
return checkArrayLiteral(node, contextualMapper);
case 176 /* ObjectLiteralExpression */:
return checkObjectLiteral(node, contextualMapper);
case 177 /* PropertyAccessExpression */:
return checkPropertyAccessExpression(node);
case 178 /* ElementAccessExpression */:
return checkIndexedAccess(node);
case 179 /* CallExpression */:
case 180 /* NewExpression */:
return checkCallExpression(node);
case 181 /* TaggedTemplateExpression */:
return checkTaggedTemplateExpression(node);
case 183 /* ParenthesizedExpression */:
return checkExpression(node.expression, contextualMapper);
case 197 /* ClassExpression */:
return checkClassExpression(node);
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return checkFunctionExpressionOrObjectLiteralMethod(node, contextualMapper);
case 187 /* TypeOfExpression */:
return checkTypeOfExpression(node);
case 182 /* TypeAssertionExpression */:
case 200 /* AsExpression */:
return checkAssertion(node);
case 201 /* NonNullExpression */:
return checkNonNullAssertion(node);
case 186 /* DeleteExpression */:
return checkDeleteExpression(node);
case 188 /* VoidExpression */:
return checkVoidExpression(node);
case 189 /* AwaitExpression */:
return checkAwaitExpression(node);
case 190 /* PrefixUnaryExpression */:
return checkPrefixUnaryExpression(node);
case 191 /* PostfixUnaryExpression */:
return checkPostfixUnaryExpression(node);
case 192 /* BinaryExpression */:
return checkBinaryExpression(node, contextualMapper);
case 193 /* ConditionalExpression */:
return checkConditionalExpression(node, contextualMapper);
case 196 /* SpreadElement */:
return checkSpreadExpression(node, contextualMapper);
case 198 /* OmittedExpression */:
return undefinedWideningType;
case 195 /* YieldExpression */:
return checkYieldExpression(node);
case 252 /* JsxExpression */:
return checkJsxExpression(node);
case 246 /* JsxElement */:
return checkJsxElement(node);
case 247 /* JsxSelfClosingElement */:
return checkJsxSelfClosingElement(node);
case 248 /* JsxOpeningElement */:
ts.Debug.fail("Shouldn't ever directly check a JsxOpeningElement");
}
return unknownType;
}
// DECLARATION AND STATEMENT TYPE CHECKING
function checkTypeParameter(node) {
// Grammar Checking
if (node.expression) {
grammarErrorOnFirstToken(node.expression, ts.Diagnostics.Type_expected);
}
checkSourceElement(node.constraint);
getConstraintOfTypeParameter(getDeclaredTypeOfTypeParameter(getSymbolOfNode(node)));
if (produceDiagnostics) {
checkTypeNameIsReserved(node.name, ts.Diagnostics.Type_parameter_name_cannot_be_0);
}
}
function checkParameter(node) {
// Grammar checking
// It is a SyntaxError if the Identifier "eval" or the Identifier "arguments" occurs as the
// Identifier in a PropertySetParameterList of a PropertyAssignment that is contained in strict code
// or if its FunctionBody is strict code(11.1.5).
// Grammar checking
checkGrammarDecorators(node) || checkGrammarModifiers(node);
checkVariableLikeDeclaration(node);
var func = ts.getContainingFunction(node);
if (ts.getModifierFlags(node) & 92 /* ParameterPropertyModifier */) {
func = ts.getContainingFunction(node);
if (!(func.kind === 150 /* Constructor */ && ts.nodeIsPresent(func.body))) {
error(node, ts.Diagnostics.A_parameter_property_is_only_allowed_in_a_constructor_implementation);
}
}
if (node.questionToken && ts.isBindingPattern(node.name) && func.body) {
error(node, ts.Diagnostics.A_binding_pattern_parameter_cannot_be_optional_in_an_implementation_signature);
}
if (node.name.text === "this") {
if (ts.indexOf(func.parameters, node) !== 0) {
error(node, ts.Diagnostics.A_this_parameter_must_be_the_first_parameter);
}
if (func.kind === 150 /* Constructor */ || func.kind === 154 /* ConstructSignature */ || func.kind === 159 /* ConstructorType */) {
error(node, ts.Diagnostics.A_constructor_cannot_have_a_this_parameter);
}
}
// Only check rest parameter type if it's not a binding pattern. Since binding patterns are
// not allowed in a rest parameter, we already have an error from checkGrammarParameterList.
if (node.dotDotDotToken && !ts.isBindingPattern(node.name) && !isArrayType(getTypeOfSymbol(node.symbol))) {
error(node, ts.Diagnostics.A_rest_parameter_must_be_of_an_array_type);
}
}
function isSyntacticallyValidGenerator(node) {
if (!node.asteriskToken || !node.body) {
return false;
}
return node.kind === 149 /* MethodDeclaration */ ||
node.kind === 225 /* FunctionDeclaration */ ||
node.kind === 184 /* FunctionExpression */;
}
function getTypePredicateParameterIndex(parameterList, parameter) {
if (parameterList) {
for (var i = 0; i < parameterList.length; i++) {
var param = parameterList[i];
if (param.name.kind === 70 /* Identifier */ &&
param.name.text === parameter.text) {
return i;
}
}
}
return -1;
}
function checkTypePredicate(node) {
var parent = getTypePredicateParent(node);
if (!parent) {
// The parent must not be valid.
error(node, ts.Diagnostics.A_type_predicate_is_only_allowed_in_return_type_position_for_functions_and_methods);
return;
}
var typePredicate = getSignatureFromDeclaration(parent).typePredicate;
if (!typePredicate) {
return;
}
var parameterName = node.parameterName;
if (ts.isThisTypePredicate(typePredicate)) {
getTypeFromThisTypeNode(parameterName);
}
else {
if (typePredicate.parameterIndex >= 0) {
if (parent.parameters[typePredicate.parameterIndex].dotDotDotToken) {
error(parameterName, ts.Diagnostics.A_type_predicate_cannot_reference_a_rest_parameter);
}
else {
var leadingError = ts.chainDiagnosticMessages(undefined, ts.Diagnostics.A_type_predicate_s_type_must_be_assignable_to_its_parameter_s_type);
checkTypeAssignableTo(typePredicate.type, getTypeOfNode(parent.parameters[typePredicate.parameterIndex]), node.type,
/*headMessage*/ undefined, leadingError);
}
}
else if (parameterName) {
var hasReportedError = false;
for (var _i = 0, _a = parent.parameters; _i < _a.length; _i++) {
var name_22 = _a[_i].name;
if (ts.isBindingPattern(name_22) &&
checkIfTypePredicateVariableIsDeclaredInBindingPattern(name_22, parameterName, typePredicate.parameterName)) {
hasReportedError = true;
break;
}
}
if (!hasReportedError) {
error(node.parameterName, ts.Diagnostics.Cannot_find_parameter_0, typePredicate.parameterName);
}
}
}
}
function getTypePredicateParent(node) {
switch (node.parent.kind) {
case 185 /* ArrowFunction */:
case 153 /* CallSignature */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 158 /* FunctionType */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
var parent_10 = node.parent;
if (node === parent_10.type) {
return parent_10;
}
}
}
function checkIfTypePredicateVariableIsDeclaredInBindingPattern(pattern, predicateVariableNode, predicateVariableName) {
for (var _i = 0, _a = pattern.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (ts.isOmittedExpression(element)) {
continue;
}
var name_23 = element.name;
if (name_23.kind === 70 /* Identifier */ &&
name_23.text === predicateVariableName) {
error(predicateVariableNode, ts.Diagnostics.A_type_predicate_cannot_reference_element_0_in_a_binding_pattern, predicateVariableName);
return true;
}
else if (name_23.kind === 173 /* ArrayBindingPattern */ ||
name_23.kind === 172 /* ObjectBindingPattern */) {
if (checkIfTypePredicateVariableIsDeclaredInBindingPattern(name_23, predicateVariableNode, predicateVariableName)) {
return true;
}
}
}
}
function checkSignatureDeclaration(node) {
// Grammar checking
if (node.kind === 155 /* IndexSignature */) {
checkGrammarIndexSignature(node);
}
else if (node.kind === 158 /* FunctionType */ || node.kind === 225 /* FunctionDeclaration */ || node.kind === 159 /* ConstructorType */ ||
node.kind === 153 /* CallSignature */ || node.kind === 150 /* Constructor */ ||
node.kind === 154 /* ConstructSignature */) {
checkGrammarFunctionLikeDeclaration(node);
}
checkTypeParameters(node.typeParameters);
ts.forEach(node.parameters, checkParameter);
if (node.type) {
checkSourceElement(node.type);
}
if (produceDiagnostics) {
checkCollisionWithArgumentsInGeneratedCode(node);
if (compilerOptions.noImplicitAny && !node.type) {
switch (node.kind) {
case 154 /* ConstructSignature */:
error(node, ts.Diagnostics.Construct_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type);
break;
case 153 /* CallSignature */:
error(node, ts.Diagnostics.Call_signature_which_lacks_return_type_annotation_implicitly_has_an_any_return_type);
break;
}
}
if (node.type) {
if (languageVersion >= 2 /* ES2015 */ && isSyntacticallyValidGenerator(node)) {
var returnType = getTypeFromTypeNode(node.type);
if (returnType === voidType) {
error(node.type, ts.Diagnostics.A_generator_cannot_have_a_void_type_annotation);
}
else {
var generatorElementType = getElementTypeOfIterableIterator(returnType) || anyType;
var iterableIteratorInstantiation = createIterableIteratorType(generatorElementType);
// Naively, one could check that IterableIterator<any> is assignable to the return type annotation.
// However, that would not catch the error in the following case.
//
// interface BadGenerator extends Iterable<number>, Iterator<string> { }
// function* g(): BadGenerator { } // Iterable and Iterator have different types!
//
checkTypeAssignableTo(iterableIteratorInstantiation, returnType, node.type);
}
}
else if (ts.isAsyncFunctionLike(node)) {
checkAsyncFunctionReturnType(node);
}
}
if (noUnusedIdentifiers && !node.body) {
checkUnusedTypeParameters(node);
}
}
}
function checkClassForDuplicateDeclarations(node) {
var Accessor;
(function (Accessor) {
Accessor[Accessor["Getter"] = 1] = "Getter";
Accessor[Accessor["Setter"] = 2] = "Setter";
Accessor[Accessor["Property"] = 3] = "Property";
})(Accessor || (Accessor = {}));
var instanceNames = ts.createMap();
var staticNames = ts.createMap();
for (var _i = 0, _a = node.members; _i < _a.length; _i++) {
var member = _a[_i];
if (member.kind === 150 /* Constructor */) {
for (var _b = 0, _c = member.parameters; _b < _c.length; _b++) {
var param = _c[_b];
if (ts.isParameterPropertyDeclaration(param)) {
addName(instanceNames, param.name, param.name.text, 3 /* Property */);
}
}
}
else {
var isStatic = ts.forEach(member.modifiers, function (m) { return m.kind === 114 /* StaticKeyword */; });
var names = isStatic ? staticNames : instanceNames;
var memberName = member.name && ts.getPropertyNameForPropertyNameNode(member.name);
if (memberName) {
switch (member.kind) {
case 151 /* GetAccessor */:
addName(names, member.name, memberName, 1 /* Getter */);
break;
case 152 /* SetAccessor */:
addName(names, member.name, memberName, 2 /* Setter */);
break;
case 147 /* PropertyDeclaration */:
addName(names, member.name, memberName, 3 /* Property */);
break;
}
}
}
}
function addName(names, location, name, meaning) {
var prev = names[name];
if (prev) {
if (prev & meaning) {
error(location, ts.Diagnostics.Duplicate_identifier_0, ts.getTextOfNode(location));
}
else {
names[name] = prev | meaning;
}
}
else {
names[name] = meaning;
}
}
}
function checkObjectTypeForDuplicateDeclarations(node) {
var names = ts.createMap();
for (var _i = 0, _a = node.members; _i < _a.length; _i++) {
var member = _a[_i];
if (member.kind == 146 /* PropertySignature */) {
var memberName = void 0;
switch (member.name.kind) {
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
case 70 /* Identifier */:
memberName = member.name.text;
break;
default:
continue;
}
if (names[memberName]) {
error(member.symbol.valueDeclaration.name, ts.Diagnostics.Duplicate_identifier_0, memberName);
error(member.name, ts.Diagnostics.Duplicate_identifier_0, memberName);
}
else {
names[memberName] = true;
}
}
}
}
function checkTypeForDuplicateIndexSignatures(node) {
if (node.kind === 227 /* InterfaceDeclaration */) {
var nodeSymbol = getSymbolOfNode(node);
// in case of merging interface declaration it is possible that we'll enter this check procedure several times for every declaration
// to prevent this run check only for the first declaration of a given kind
if (nodeSymbol.declarations.length > 0 && nodeSymbol.declarations[0] !== node) {
return;
}
}
// TypeScript 1.0 spec (April 2014)
// 3.7.4: An object type can contain at most one string index signature and one numeric index signature.
// 8.5: A class declaration can have at most one string index member declaration and one numeric index member declaration
var indexSymbol = getIndexSymbol(getSymbolOfNode(node));
if (indexSymbol) {
var seenNumericIndexer = false;
var seenStringIndexer = false;
for (var _i = 0, _a = indexSymbol.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
var declaration = decl;
if (declaration.parameters.length === 1 && declaration.parameters[0].type) {
switch (declaration.parameters[0].type.kind) {
case 134 /* StringKeyword */:
if (!seenStringIndexer) {
seenStringIndexer = true;
}
else {
error(declaration, ts.Diagnostics.Duplicate_string_index_signature);
}
break;
case 132 /* NumberKeyword */:
if (!seenNumericIndexer) {
seenNumericIndexer = true;
}
else {
error(declaration, ts.Diagnostics.Duplicate_number_index_signature);
}
break;
}
}
}
}
}
function checkPropertyDeclaration(node) {
// Grammar checking
checkGrammarDecorators(node) || checkGrammarModifiers(node) || checkGrammarProperty(node) || checkGrammarComputedPropertyName(node.name);
checkVariableLikeDeclaration(node);
}
function checkMethodDeclaration(node) {
// Grammar checking
checkGrammarMethod(node) || checkGrammarComputedPropertyName(node.name);
// Grammar checking for modifiers is done inside the function checkGrammarFunctionLikeDeclaration
checkFunctionOrMethodDeclaration(node);
// Abstract methods cannot have an implementation.
// Extra checks are to avoid reporting multiple errors relating to the "abstractness" of the node.
if (ts.getModifierFlags(node) & 128 /* Abstract */ && node.body) {
error(node, ts.Diagnostics.Method_0_cannot_have_an_implementation_because_it_is_marked_abstract, ts.declarationNameToString(node.name));
}
}
function checkConstructorDeclaration(node) {
// Grammar check on signature of constructor and modifier of the constructor is done in checkSignatureDeclaration function.
checkSignatureDeclaration(node);
// Grammar check for checking only related to constructorDeclaration
checkGrammarConstructorTypeParameters(node) || checkGrammarConstructorTypeAnnotation(node);
checkSourceElement(node.body);
registerForUnusedIdentifiersCheck(node);
var symbol = getSymbolOfNode(node);
var firstDeclaration = ts.getDeclarationOfKind(symbol, node.kind);
// Only type check the symbol once
if (node === firstDeclaration) {
checkFunctionOrConstructorSymbol(symbol);
}
// exit early in the case of signature - super checks are not relevant to them
if (ts.nodeIsMissing(node.body)) {
return;
}
if (!produceDiagnostics) {
return;
}
function containsSuperCallAsComputedPropertyName(n) {
return n.name && containsSuperCall(n.name);
}
function containsSuperCall(n) {
if (ts.isSuperCall(n)) {
return true;
}
else if (ts.isFunctionLike(n)) {
return false;
}
else if (ts.isClassLike(n)) {
return ts.forEach(n.members, containsSuperCallAsComputedPropertyName);
}
return ts.forEachChild(n, containsSuperCall);
}
function markThisReferencesAsErrors(n) {
if (n.kind === 98 /* ThisKeyword */) {
error(n, ts.Diagnostics.this_cannot_be_referenced_in_current_location);
}
else if (n.kind !== 184 /* FunctionExpression */ && n.kind !== 225 /* FunctionDeclaration */) {
ts.forEachChild(n, markThisReferencesAsErrors);
}
}
function isInstancePropertyWithInitializer(n) {
return n.kind === 147 /* PropertyDeclaration */ &&
!(ts.getModifierFlags(n) & 32 /* Static */) &&
!!n.initializer;
}
// TS 1.0 spec (April 2014): 8.3.2
// Constructors of classes with no extends clause may not contain super calls, whereas
// constructors of derived classes must contain at least one super call somewhere in their function body.
var containingClassDecl = node.parent;
if (ts.getClassExtendsHeritageClauseElement(containingClassDecl)) {
captureLexicalThis(node.parent, containingClassDecl);
var classExtendsNull = classDeclarationExtendsNull(containingClassDecl);
var superCall = getSuperCallInConstructor(node);
if (superCall) {
if (classExtendsNull) {
error(superCall, ts.Diagnostics.A_constructor_cannot_contain_a_super_call_when_its_class_extends_null);
}
// The first statement in the body of a constructor (excluding prologue directives) must be a super call
// if both of the following are true:
// - The containing class is a derived class.
// - The constructor declares parameter properties
// or the containing class declares instance member variables with initializers.
var superCallShouldBeFirst = ts.forEach(node.parent.members, isInstancePropertyWithInitializer) ||
ts.forEach(node.parameters, function (p) { return ts.getModifierFlags(p) & 92 /* ParameterPropertyModifier */; });
// Skip past any prologue directives to find the first statement
// to ensure that it was a super call.
if (superCallShouldBeFirst) {
var statements = node.body.statements;
var superCallStatement = void 0;
for (var _i = 0, statements_2 = statements; _i < statements_2.length; _i++) {
var statement = statements_2[_i];
if (statement.kind === 207 /* ExpressionStatement */ && ts.isSuperCall(statement.expression)) {
superCallStatement = statement;
break;
}
if (!ts.isPrologueDirective(statement)) {
break;
}
}
if (!superCallStatement) {
error(node, ts.Diagnostics.A_super_call_must_be_the_first_statement_in_the_constructor_when_a_class_contains_initialized_properties_or_has_parameter_properties);
}
}
}
else if (!classExtendsNull) {
error(node, ts.Diagnostics.Constructors_for_derived_classes_must_contain_a_super_call);
}
}
}
function checkAccessorDeclaration(node) {
if (produceDiagnostics) {
// Grammar checking accessors
checkGrammarFunctionLikeDeclaration(node) || checkGrammarAccessor(node) || checkGrammarComputedPropertyName(node.name);
checkDecorators(node);
checkSignatureDeclaration(node);
if (node.kind === 151 /* GetAccessor */) {
if (!ts.isInAmbientContext(node) && ts.nodeIsPresent(node.body) && (node.flags & 128 /* HasImplicitReturn */)) {
if (!(node.flags & 256 /* HasExplicitReturn */)) {
error(node.name, ts.Diagnostics.A_get_accessor_must_return_a_value);
}
}
}
// Do not use hasDynamicName here, because that returns false for well known symbols.
// We want to perform checkComputedPropertyName for all computed properties, including
// well known symbols.
if (node.name.kind === 142 /* ComputedPropertyName */) {
checkComputedPropertyName(node.name);
}
if (!ts.hasDynamicName(node)) {
// TypeScript 1.0 spec (April 2014): 8.4.3
// Accessors for the same member name must specify the same accessibility.
var otherKind = node.kind === 151 /* GetAccessor */ ? 152 /* SetAccessor */ : 151 /* GetAccessor */;
var otherAccessor = ts.getDeclarationOfKind(node.symbol, otherKind);
if (otherAccessor) {
if ((ts.getModifierFlags(node) & 28 /* AccessibilityModifier */) !== (ts.getModifierFlags(otherAccessor) & 28 /* AccessibilityModifier */)) {
error(node.name, ts.Diagnostics.Getter_and_setter_accessors_do_not_agree_in_visibility);
}
if (ts.hasModifier(node, 128 /* Abstract */) !== ts.hasModifier(otherAccessor, 128 /* Abstract */)) {
error(node.name, ts.Diagnostics.Accessors_must_both_be_abstract_or_non_abstract);
}
// TypeScript 1.0 spec (April 2014): 4.5
// If both accessors include type annotations, the specified types must be identical.
checkAccessorDeclarationTypesIdentical(node, otherAccessor, getAnnotatedAccessorType, ts.Diagnostics.get_and_set_accessor_must_have_the_same_type);
checkAccessorDeclarationTypesIdentical(node, otherAccessor, getThisTypeOfDeclaration, ts.Diagnostics.get_and_set_accessor_must_have_the_same_this_type);
}
}
var returnType = getTypeOfAccessors(getSymbolOfNode(node));
if (node.kind === 151 /* GetAccessor */) {
checkAllCodePathsInNonVoidFunctionReturnOrThrow(node, returnType);
}
}
if (node.parent.kind !== 176 /* ObjectLiteralExpression */) {
checkSourceElement(node.body);
registerForUnusedIdentifiersCheck(node);
}
else {
checkNodeDeferred(node);
}
}
function checkAccessorDeclarationTypesIdentical(first, second, getAnnotatedType, message) {
var firstType = getAnnotatedType(first);
var secondType = getAnnotatedType(second);
if (firstType && secondType && !isTypeIdenticalTo(firstType, secondType)) {
error(first, message);
}
}
function checkAccessorDeferred(node) {
checkSourceElement(node.body);
registerForUnusedIdentifiersCheck(node);
}
function checkMissingDeclaration(node) {
checkDecorators(node);
}
function checkTypeArgumentConstraints(typeParameters, typeArgumentNodes) {
var typeArguments;
var mapper;
var result = true;
for (var i = 0; i < typeParameters.length; i++) {
var constraint = getConstraintOfTypeParameter(typeParameters[i]);
if (constraint) {
if (!typeArguments) {
typeArguments = ts.map(typeArgumentNodes, getTypeFromTypeNode);
mapper = createTypeMapper(typeParameters, typeArguments);
}
var typeArgument = typeArguments[i];
result = result && checkTypeAssignableTo(typeArgument, getTypeWithThisArgument(instantiateType(constraint, mapper), typeArgument), typeArgumentNodes[i], ts.Diagnostics.Type_0_does_not_satisfy_the_constraint_1);
}
}
return result;
}
function checkTypeReferenceNode(node) {
checkGrammarTypeArguments(node, node.typeArguments);
var type = getTypeFromTypeReference(node);
if (type !== unknownType) {
if (node.typeArguments) {
// Do type argument local checks only if referenced type is successfully resolved
ts.forEach(node.typeArguments, checkSourceElement);
if (produceDiagnostics) {
var symbol = getNodeLinks(node).resolvedSymbol;
var typeParameters = symbol.flags & 524288 /* TypeAlias */ ? getSymbolLinks(symbol).typeParameters : type.target.localTypeParameters;
checkTypeArgumentConstraints(typeParameters, node.typeArguments);
}
}
if (type.flags & 16 /* Enum */ && !type.memberTypes && getNodeLinks(node).resolvedSymbol.flags & 8 /* EnumMember */) {
error(node, ts.Diagnostics.Enum_type_0_has_members_with_initializers_that_are_not_literals, typeToString(type));
}
}
}
function checkTypeQuery(node) {
getTypeFromTypeQueryNode(node);
}
function checkTypeLiteral(node) {
ts.forEach(node.members, checkSourceElement);
if (produceDiagnostics) {
var type = getTypeFromTypeLiteralOrFunctionOrConstructorTypeNode(node);
checkIndexConstraints(type);
checkTypeForDuplicateIndexSignatures(node);
checkObjectTypeForDuplicateDeclarations(node);
}
}
function checkArrayType(node) {
checkSourceElement(node.elementType);
}
function checkTupleType(node) {
// Grammar checking
var hasErrorFromDisallowedTrailingComma = checkGrammarForDisallowedTrailingComma(node.elementTypes);
if (!hasErrorFromDisallowedTrailingComma && node.elementTypes.length === 0) {
grammarErrorOnNode(node, ts.Diagnostics.A_tuple_type_element_list_cannot_be_empty);
}
ts.forEach(node.elementTypes, checkSourceElement);
}
function checkUnionOrIntersectionType(node) {
ts.forEach(node.types, checkSourceElement);
}
function checkIndexedAccessType(node) {
getTypeFromIndexedAccessTypeNode(node);
}
function checkMappedType(node) {
checkSourceElement(node.typeParameter);
checkSourceElement(node.type);
var type = getTypeFromMappedTypeNode(node);
var constraintType = getConstraintTypeFromMappedType(type);
var keyType = constraintType.flags & 16384 /* TypeParameter */ ? getApparentTypeOfTypeParameter(constraintType) : constraintType;
checkTypeAssignableTo(keyType, stringOrNumberType, node.typeParameter.constraint);
}
function isPrivateWithinAmbient(node) {
return (ts.getModifierFlags(node) & 8 /* Private */) && ts.isInAmbientContext(node);
}
function getEffectiveDeclarationFlags(n, flagsToCheck) {
var flags = ts.getCombinedModifierFlags(n);
// children of classes (even ambient classes) should not be marked as ambient or export
// because those flags have no useful semantics there.
if (n.parent.kind !== 227 /* InterfaceDeclaration */ &&
n.parent.kind !== 226 /* ClassDeclaration */ &&
n.parent.kind !== 197 /* ClassExpression */ &&
ts.isInAmbientContext(n)) {
if (!(flags & 2 /* Ambient */)) {
// It is nested in an ambient context, which means it is automatically exported
flags |= 1 /* Export */;
}
flags |= 2 /* Ambient */;
}
return flags & flagsToCheck;
}
function checkFunctionOrConstructorSymbol(symbol) {
if (!produceDiagnostics) {
return;
}
function getCanonicalOverload(overloads, implementation) {
// Consider the canonical set of flags to be the flags of the bodyDeclaration or the first declaration
// Error on all deviations from this canonical set of flags
// The caveat is that if some overloads are defined in lib.d.ts, we don't want to
// report the errors on those. To achieve this, we will say that the implementation is
// the canonical signature only if it is in the same container as the first overload
var implementationSharesContainerWithFirstOverload = implementation !== undefined && implementation.parent === overloads[0].parent;
return implementationSharesContainerWithFirstOverload ? implementation : overloads[0];
}
function checkFlagAgreementBetweenOverloads(overloads, implementation, flagsToCheck, someOverloadFlags, allOverloadFlags) {
// Error if some overloads have a flag that is not shared by all overloads. To find the
// deviations, we XOR someOverloadFlags with allOverloadFlags
var someButNotAllOverloadFlags = someOverloadFlags ^ allOverloadFlags;
if (someButNotAllOverloadFlags !== 0) {
var canonicalFlags_1 = getEffectiveDeclarationFlags(getCanonicalOverload(overloads, implementation), flagsToCheck);
ts.forEach(overloads, function (o) {
var deviation = getEffectiveDeclarationFlags(o, flagsToCheck) ^ canonicalFlags_1;
if (deviation & 1 /* Export */) {
error(o.name, ts.Diagnostics.Overload_signatures_must_all_be_exported_or_non_exported);
}
else if (deviation & 2 /* Ambient */) {
error(o.name, ts.Diagnostics.Overload_signatures_must_all_be_ambient_or_non_ambient);
}
else if (deviation & (8 /* Private */ | 16 /* Protected */)) {
error(o.name || o, ts.Diagnostics.Overload_signatures_must_all_be_public_private_or_protected);
}
else if (deviation & 128 /* Abstract */) {
error(o.name, ts.Diagnostics.Overload_signatures_must_all_be_abstract_or_non_abstract);
}
});
}
}
function checkQuestionTokenAgreementBetweenOverloads(overloads, implementation, someHaveQuestionToken, allHaveQuestionToken) {
if (someHaveQuestionToken !== allHaveQuestionToken) {
var canonicalHasQuestionToken_1 = ts.hasQuestionToken(getCanonicalOverload(overloads, implementation));
ts.forEach(overloads, function (o) {
var deviation = ts.hasQuestionToken(o) !== canonicalHasQuestionToken_1;
if (deviation) {
error(o.name, ts.Diagnostics.Overload_signatures_must_all_be_optional_or_required);
}
});
}
}
var flagsToCheck = 1 /* Export */ | 2 /* Ambient */ | 8 /* Private */ | 16 /* Protected */ | 128 /* Abstract */;
var someNodeFlags = 0 /* None */;
var allNodeFlags = flagsToCheck;
var someHaveQuestionToken = false;
var allHaveQuestionToken = true;
var hasOverloads = false;
var bodyDeclaration;
var lastSeenNonAmbientDeclaration;
var previousDeclaration;
var declarations = symbol.declarations;
var isConstructor = (symbol.flags & 16384 /* Constructor */) !== 0;
function reportImplementationExpectedError(node) {
if (node.name && ts.nodeIsMissing(node.name)) {
return;
}
var seen = false;
var subsequentNode = ts.forEachChild(node.parent, function (c) {
if (seen) {
return c;
}
else {
seen = c === node;
}
});
// We may be here because of some extra nodes between overloads that could not be parsed into a valid node.
// In this case the subsequent node is not really consecutive (.pos !== node.end), and we must ignore it here.
if (subsequentNode && subsequentNode.pos === node.end) {
if (subsequentNode.kind === node.kind) {
var errorNode_1 = subsequentNode.name || subsequentNode;
// TODO(jfreeman): These are methods, so handle computed name case
if (node.name && subsequentNode.name && node.name.text === subsequentNode.name.text) {
var reportError = (node.kind === 149 /* MethodDeclaration */ || node.kind === 148 /* MethodSignature */) &&
(ts.getModifierFlags(node) & 32 /* Static */) !== (ts.getModifierFlags(subsequentNode) & 32 /* Static */);
// we can get here in two cases
// 1. mixed static and instance class members
// 2. something with the same name was defined before the set of overloads that prevents them from merging
// here we'll report error only for the first case since for second we should already report error in binder
if (reportError) {
var diagnostic = ts.getModifierFlags(node) & 32 /* Static */ ? ts.Diagnostics.Function_overload_must_be_static : ts.Diagnostics.Function_overload_must_not_be_static;
error(errorNode_1, diagnostic);
}
return;
}
else if (ts.nodeIsPresent(subsequentNode.body)) {
error(errorNode_1, ts.Diagnostics.Function_implementation_name_must_be_0, ts.declarationNameToString(node.name));
return;
}
}
}
var errorNode = node.name || node;
if (isConstructor) {
error(errorNode, ts.Diagnostics.Constructor_implementation_is_missing);
}
else {
// Report different errors regarding non-consecutive blocks of declarations depending on whether
// the node in question is abstract.
if (ts.getModifierFlags(node) & 128 /* Abstract */) {
error(errorNode, ts.Diagnostics.All_declarations_of_an_abstract_method_must_be_consecutive);
}
else {
error(errorNode, ts.Diagnostics.Function_implementation_is_missing_or_not_immediately_following_the_declaration);
}
}
}
var duplicateFunctionDeclaration = false;
var multipleConstructorImplementation = false;
for (var _i = 0, declarations_4 = declarations; _i < declarations_4.length; _i++) {
var current = declarations_4[_i];
var node = current;
var inAmbientContext = ts.isInAmbientContext(node);
var inAmbientContextOrInterface = node.parent.kind === 227 /* InterfaceDeclaration */ || node.parent.kind === 161 /* TypeLiteral */ || inAmbientContext;
if (inAmbientContextOrInterface) {
// check if declarations are consecutive only if they are non-ambient
// 1. ambient declarations can be interleaved
// i.e. this is legal
// declare function foo();
// declare function bar();
// declare function foo();
// 2. mixing ambient and non-ambient declarations is a separate error that will be reported - do not want to report an extra one
previousDeclaration = undefined;
}
if (node.kind === 225 /* FunctionDeclaration */ || node.kind === 149 /* MethodDeclaration */ || node.kind === 148 /* MethodSignature */ || node.kind === 150 /* Constructor */) {
var currentNodeFlags = getEffectiveDeclarationFlags(node, flagsToCheck);
someNodeFlags |= currentNodeFlags;
allNodeFlags &= currentNodeFlags;
someHaveQuestionToken = someHaveQuestionToken || ts.hasQuestionToken(node);
allHaveQuestionToken = allHaveQuestionToken && ts.hasQuestionToken(node);
if (ts.nodeIsPresent(node.body) && bodyDeclaration) {
if (isConstructor) {
multipleConstructorImplementation = true;
}
else {
duplicateFunctionDeclaration = true;
}
}
else if (previousDeclaration && previousDeclaration.parent === node.parent && previousDeclaration.end !== node.pos) {
reportImplementationExpectedError(previousDeclaration);
}
if (ts.nodeIsPresent(node.body)) {
if (!bodyDeclaration) {
bodyDeclaration = node;
}
}
else {
hasOverloads = true;
}
previousDeclaration = node;
if (!inAmbientContextOrInterface) {
lastSeenNonAmbientDeclaration = node;
}
}
}
if (multipleConstructorImplementation) {
ts.forEach(declarations, function (declaration) {
error(declaration, ts.Diagnostics.Multiple_constructor_implementations_are_not_allowed);
});
}
if (duplicateFunctionDeclaration) {
ts.forEach(declarations, function (declaration) {
error(declaration.name, ts.Diagnostics.Duplicate_function_implementation);
});
}
// Abstract methods can't have an implementation -- in particular, they don't need one.
if (lastSeenNonAmbientDeclaration && !lastSeenNonAmbientDeclaration.body &&
!(ts.getModifierFlags(lastSeenNonAmbientDeclaration) & 128 /* Abstract */) && !lastSeenNonAmbientDeclaration.questionToken) {
reportImplementationExpectedError(lastSeenNonAmbientDeclaration);
}
if (hasOverloads) {
checkFlagAgreementBetweenOverloads(declarations, bodyDeclaration, flagsToCheck, someNodeFlags, allNodeFlags);
checkQuestionTokenAgreementBetweenOverloads(declarations, bodyDeclaration, someHaveQuestionToken, allHaveQuestionToken);
if (bodyDeclaration) {
var signatures = getSignaturesOfSymbol(symbol);
var bodySignature = getSignatureFromDeclaration(bodyDeclaration);
for (var _a = 0, signatures_3 = signatures; _a < signatures_3.length; _a++) {
var signature = signatures_3[_a];
if (!isImplementationCompatibleWithOverload(bodySignature, signature)) {
error(signature.declaration, ts.Diagnostics.Overload_signature_is_not_compatible_with_function_implementation);
break;
}
}
}
}
}
function checkExportsOnMergedDeclarations(node) {
if (!produceDiagnostics) {
return;
}
// if localSymbol is defined on node then node itself is exported - check is required
var symbol = node.localSymbol;
if (!symbol) {
// local symbol is undefined => this declaration is non-exported.
// however symbol might contain other declarations that are exported
symbol = getSymbolOfNode(node);
if (!(symbol.flags & 7340032 /* Export */)) {
// this is a pure local symbol (all declarations are non-exported) - no need to check anything
return;
}
}
// run the check only for the first declaration in the list
if (ts.getDeclarationOfKind(symbol, node.kind) !== node) {
return;
}
// we use SymbolFlags.ExportValue, SymbolFlags.ExportType and SymbolFlags.ExportNamespace
// to denote disjoint declarationSpaces (without making new enum type).
var exportedDeclarationSpaces = 0 /* None */;
var nonExportedDeclarationSpaces = 0 /* None */;
var defaultExportedDeclarationSpaces = 0 /* None */;
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var d = _a[_i];
var declarationSpaces = getDeclarationSpaces(d);
var effectiveDeclarationFlags = getEffectiveDeclarationFlags(d, 1 /* Export */ | 512 /* Default */);
if (effectiveDeclarationFlags & 1 /* Export */) {
if (effectiveDeclarationFlags & 512 /* Default */) {
defaultExportedDeclarationSpaces |= declarationSpaces;
}
else {
exportedDeclarationSpaces |= declarationSpaces;
}
}
else {
nonExportedDeclarationSpaces |= declarationSpaces;
}
}
// Spaces for anything not declared a 'default export'.
var nonDefaultExportedDeclarationSpaces = exportedDeclarationSpaces | nonExportedDeclarationSpaces;
var commonDeclarationSpacesForExportsAndLocals = exportedDeclarationSpaces & nonExportedDeclarationSpaces;
var commonDeclarationSpacesForDefaultAndNonDefault = defaultExportedDeclarationSpaces & nonDefaultExportedDeclarationSpaces;
if (commonDeclarationSpacesForExportsAndLocals || commonDeclarationSpacesForDefaultAndNonDefault) {
// declaration spaces for exported and non-exported declarations intersect
for (var _b = 0, _c = symbol.declarations; _b < _c.length; _b++) {
var d = _c[_b];
var declarationSpaces = getDeclarationSpaces(d);
// Only error on the declarations that contributed to the intersecting spaces.
if (declarationSpaces & commonDeclarationSpacesForDefaultAndNonDefault) {
error(d.name, ts.Diagnostics.Merged_declaration_0_cannot_include_a_default_export_declaration_Consider_adding_a_separate_export_default_0_declaration_instead, ts.declarationNameToString(d.name));
}
else if (declarationSpaces & commonDeclarationSpacesForExportsAndLocals) {
error(d.name, ts.Diagnostics.Individual_declarations_in_merged_declaration_0_must_be_all_exported_or_all_local, ts.declarationNameToString(d.name));
}
}
}
function getDeclarationSpaces(d) {
switch (d.kind) {
case 227 /* InterfaceDeclaration */:
return 2097152 /* ExportType */;
case 230 /* ModuleDeclaration */:
return ts.isAmbientModule(d) || ts.getModuleInstanceState(d) !== 0 /* NonInstantiated */
? 4194304 /* ExportNamespace */ | 1048576 /* ExportValue */
: 4194304 /* ExportNamespace */;
case 226 /* ClassDeclaration */:
case 229 /* EnumDeclaration */:
return 2097152 /* ExportType */ | 1048576 /* ExportValue */;
case 234 /* ImportEqualsDeclaration */:
var result_2 = 0;
var target = resolveAlias(getSymbolOfNode(d));
ts.forEach(target.declarations, function (d) { result_2 |= getDeclarationSpaces(d); });
return result_2;
default:
return 1048576 /* ExportValue */;
}
}
}
function checkNonThenableType(type, location, message) {
type = getWidenedType(type);
if (!isTypeAny(type) && !isTypeNever(type) && isTypeAssignableTo(type, getGlobalThenableType())) {
if (location) {
if (!message) {
message = ts.Diagnostics.Operand_for_await_does_not_have_a_valid_callable_then_member;
}
error(location, message);
}
return unknownType;
}
return type;
}
/**
* Gets the "promised type" of a promise.
* @param type The type of the promise.
* @remarks The "promised type" of a type is the type of the "value" parameter of the "onfulfilled" callback.
*/
function getPromisedType(promise) {
//
// { // promise
// then( // thenFunction
// onfulfilled: ( // onfulfilledParameterType
// value: T // valueParameterType
// ) => any
// ): any;
// }
//
if (isTypeAny(promise)) {
return undefined;
}
if (getObjectFlags(promise) & 4 /* Reference */) {
if (promise.target === tryGetGlobalPromiseType()
|| promise.target === getGlobalPromiseLikeType()) {
return promise.typeArguments[0];
}
}
var globalPromiseLikeType = getInstantiatedGlobalPromiseLikeType();
if (globalPromiseLikeType === emptyObjectType || !isTypeAssignableTo(promise, globalPromiseLikeType)) {
return undefined;
}
var thenFunction = getTypeOfPropertyOfType(promise, "then");
if (!thenFunction || isTypeAny(thenFunction)) {
return undefined;
}
var thenSignatures = getSignaturesOfType(thenFunction, 0 /* Call */);
if (thenSignatures.length === 0) {
return undefined;
}
var onfulfilledParameterType = getTypeWithFacts(getUnionType(ts.map(thenSignatures, getTypeOfFirstParameterOfSignature)), 131072 /* NEUndefined */);
if (isTypeAny(onfulfilledParameterType)) {
return undefined;
}
var onfulfilledParameterSignatures = getSignaturesOfType(onfulfilledParameterType, 0 /* Call */);
if (onfulfilledParameterSignatures.length === 0) {
return undefined;
}
return getUnionType(ts.map(onfulfilledParameterSignatures, getTypeOfFirstParameterOfSignature), /*subtypeReduction*/ true);
}
function getTypeOfFirstParameterOfSignature(signature) {
return signature.parameters.length > 0 ? getTypeAtPosition(signature, 0) : neverType;
}
/**
* Gets the "awaited type" of a type.
* @param type The type to await.
* @remarks The "awaited type" of an expression is its "promised type" if the expression is a
* Promise-like type; otherwise, it is the type of the expression. This is used to reflect
* The runtime behavior of the `await` keyword.
*/
function getAwaitedType(type) {
return checkAwaitedType(type, /*location*/ undefined, /*message*/ undefined);
}
function checkAwaitedType(type, location, message) {
return checkAwaitedTypeWorker(type);
function checkAwaitedTypeWorker(type) {
if (type.flags & 65536 /* Union */) {
var types = [];
for (var _i = 0, _a = type.types; _i < _a.length; _i++) {
var constituentType = _a[_i];
types.push(checkAwaitedTypeWorker(constituentType));
}
return getUnionType(types, /*subtypeReduction*/ true);
}
else {
var promisedType = getPromisedType(type);
if (promisedType === undefined) {
// The type was not a PromiseLike, so it could not be unwrapped any further.
// As long as the type does not have a callable "then" property, it is
// safe to return the type; otherwise, an error will have been reported in
// the call to checkNonThenableType and we will return unknownType.
//
// An example of a non-promise "thenable" might be:
//
// await { then(): void {} }
//
// The "thenable" does not match the minimal definition for a PromiseLike. When
// a Promise/A+-compatible or ES6 promise tries to adopt this value, the promise
// will never settle. We treat this as an error to help flag an early indicator
// of a runtime problem. If the user wants to return this value from an async
// function, they would need to wrap it in some other value. If they want it to
// be treated as a promise, they can cast to <any>.
return checkNonThenableType(type, location, message);
}
else {
if (type.id === promisedType.id || ts.indexOf(awaitedTypeStack, promisedType.id) >= 0) {
// We have a bad actor in the form of a promise whose promised type is
// the same promise type, or a mutually recursive promise. Return the
// unknown type as we cannot guess the shape. If this were the actual
// case in the JavaScript, this Promise would never resolve.
//
// An example of a bad actor with a singly-recursive promise type might
// be:
//
// interface BadPromise {
// then(
// onfulfilled: (value: BadPromise) => any,
// onrejected: (error: any) => any): BadPromise;
// }
//
// The above interface will pass the PromiseLike check, and return a
// promised type of `BadPromise`. Since this is a self reference, we
// don't want to keep recursing ad infinitum.
//
// An example of a bad actor in the form of a mutually-recursive
// promise type might be:
//
// interface BadPromiseA {
// then(
// onfulfilled: (value: BadPromiseB) => any,
// onrejected: (error: any) => any): BadPromiseB;
// }
//
// interface BadPromiseB {
// then(
// onfulfilled: (value: BadPromiseA) => any,
// onrejected: (error: any) => any): BadPromiseA;
// }
//
if (location) {
error(location, ts.Diagnostics._0_is_referenced_directly_or_indirectly_in_the_fulfillment_callback_of_its_own_then_method, symbolToString(type.symbol));
}
return unknownType;
}
// Keep track of the type we're about to unwrap to avoid bad recursive promise types.
// See the comments above for more information.
awaitedTypeStack.push(type.id);
var awaitedType = checkAwaitedTypeWorker(promisedType);
awaitedTypeStack.pop();
return awaitedType;
}
}
}
}
/**
* Checks the return type of an async function to ensure it is a compatible
* Promise implementation.
*
* This checks that an async function has a valid Promise-compatible return type,
* and returns the *awaited type* of the promise. An async function has a valid
* Promise-compatible return type if the resolved value of the return type has a
* construct signature that takes in an `initializer` function that in turn supplies
* a `resolve` function as one of its arguments and results in an object with a
* callable `then` signature.
*
* @param node The signature to check
*/
function checkAsyncFunctionReturnType(node) {
// As part of our emit for an async function, we will need to emit the entity name of
// the return type annotation as an expression. To meet the necessary runtime semantics
// for __awaiter, we must also check that the type of the declaration (e.g. the static
// side or "constructor" of the promise type) is compatible `PromiseConstructorLike`.
//
// An example might be (from lib.es6.d.ts):
//
// interface Promise<T> { ... }
// interface PromiseConstructor {
// new <T>(...): Promise<T>;
// }
// declare var Promise: PromiseConstructor;
//
// When an async function declares a return type annotation of `Promise<T>`, we
// need to get the type of the `Promise` variable declaration above, which would
// be `PromiseConstructor`.
//
// The same case applies to a class:
//
// declare class Promise<T> {
// constructor(...);
// then<U>(...): Promise<U>;
// }
//
var returnType = getTypeFromTypeNode(node.type);
if (languageVersion >= 2 /* ES2015 */) {
if (returnType === unknownType) {
return unknownType;
}
var globalPromiseType = getGlobalPromiseType();
if (globalPromiseType !== emptyGenericType && globalPromiseType !== getTargetType(returnType)) {
// The promise type was not a valid type reference to the global promise type, so we
// report an error and return the unknown type.
error(node.type, ts.Diagnostics.The_return_type_of_an_async_function_or_method_must_be_the_global_Promise_T_type);
return unknownType;
}
}
else {
// Always mark the type node as referenced if it points to a value
markTypeNodeAsReferenced(node.type);
if (returnType === unknownType) {
return unknownType;
}
var promiseConstructorName = ts.getEntityNameFromTypeNode(node.type);
if (promiseConstructorName === undefined) {
error(node.type, ts.Diagnostics.Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value, typeToString(returnType));
return unknownType;
}
var promiseConstructorSymbol = resolveEntityName(promiseConstructorName, 107455 /* Value */, /*ignoreErrors*/ true);
var promiseConstructorType = promiseConstructorSymbol ? getTypeOfSymbol(promiseConstructorSymbol) : unknownType;
if (promiseConstructorType === unknownType) {
error(node.type, ts.Diagnostics.Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value, ts.entityNameToString(promiseConstructorName));
return unknownType;
}
var globalPromiseConstructorLikeType = getGlobalPromiseConstructorLikeType();
if (globalPromiseConstructorLikeType === emptyObjectType) {
// If we couldn't resolve the global PromiseConstructorLike type we cannot verify
// compatibility with __awaiter.
error(node.type, ts.Diagnostics.Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value, ts.entityNameToString(promiseConstructorName));
return unknownType;
}
if (!checkTypeAssignableTo(promiseConstructorType, globalPromiseConstructorLikeType, node.type, ts.Diagnostics.Type_0_is_not_a_valid_async_function_return_type_in_ES5_SlashES3_because_it_does_not_refer_to_a_Promise_compatible_constructor_value)) {
return unknownType;
}
// Verify there is no local declaration that could collide with the promise constructor.
var rootName = promiseConstructorName && getFirstIdentifier(promiseConstructorName);
var collidingSymbol = getSymbol(node.locals, rootName.text, 107455 /* Value */);
if (collidingSymbol) {
error(collidingSymbol.valueDeclaration, ts.Diagnostics.Duplicate_identifier_0_Compiler_uses_declaration_1_to_support_async_functions, rootName.text, ts.entityNameToString(promiseConstructorName));
return unknownType;
}
}
// Get and return the awaited type of the return type.
return checkAwaitedType(returnType, node, ts.Diagnostics.An_async_function_or_method_must_have_a_valid_awaitable_return_type);
}
/** Check a decorator */
function checkDecorator(node) {
var signature = getResolvedSignature(node);
var returnType = getReturnTypeOfSignature(signature);
if (returnType.flags & 1 /* Any */) {
return;
}
var expectedReturnType;
var headMessage = getDiagnosticHeadMessageForDecoratorResolution(node);
var errorInfo;
switch (node.parent.kind) {
case 226 /* ClassDeclaration */:
var classSymbol = getSymbolOfNode(node.parent);
var classConstructorType = getTypeOfSymbol(classSymbol);
expectedReturnType = getUnionType([classConstructorType, voidType]);
break;
case 144 /* Parameter */:
expectedReturnType = voidType;
errorInfo = ts.chainDiagnosticMessages(errorInfo, ts.Diagnostics.The_return_type_of_a_parameter_decorator_function_must_be_either_void_or_any);
break;
case 147 /* PropertyDeclaration */:
expectedReturnType = voidType;
errorInfo = ts.chainDiagnosticMessages(errorInfo, ts.Diagnostics.The_return_type_of_a_property_decorator_function_must_be_either_void_or_any);
break;
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
var methodType = getTypeOfNode(node.parent);
var descriptorType = createTypedPropertyDescriptorType(methodType);
expectedReturnType = getUnionType([descriptorType, voidType]);
break;
}
checkTypeAssignableTo(returnType, expectedReturnType, node, headMessage, errorInfo);
}
/**
* If a TypeNode can be resolved to a value symbol imported from an external module, it is
* marked as referenced to prevent import elision.
*/
function markTypeNodeAsReferenced(node) {
var typeName = node && ts.getEntityNameFromTypeNode(node);
var rootName = typeName && getFirstIdentifier(typeName);
var rootSymbol = rootName && resolveName(rootName, rootName.text, (typeName.kind === 70 /* Identifier */ ? 793064 /* Type */ : 1920 /* Namespace */) | 8388608 /* Alias */, /*nameNotFoundMessage*/ undefined, /*nameArg*/ undefined);
if (rootSymbol
&& rootSymbol.flags & 8388608 /* Alias */
&& symbolIsValue(rootSymbol)
&& !isConstEnumOrConstEnumOnlyModule(resolveAlias(rootSymbol))) {
markAliasSymbolAsReferenced(rootSymbol);
}
}
/** Check the decorators of a node */
function checkDecorators(node) {
if (!node.decorators) {
return;
}
// skip this check for nodes that cannot have decorators. These should have already had an error reported by
// checkGrammarDecorators.
if (!ts.nodeCanBeDecorated(node)) {
return;
}
if (!compilerOptions.experimentalDecorators) {
error(node, ts.Diagnostics.Experimental_support_for_decorators_is_a_feature_that_is_subject_to_change_in_a_future_release_Set_the_experimentalDecorators_option_to_remove_this_warning);
}
if (compilerOptions.emitDecoratorMetadata) {
// we only need to perform these checks if we are emitting serialized type metadata for the target of a decorator.
switch (node.kind) {
case 226 /* ClassDeclaration */:
var constructor = ts.getFirstConstructorWithBody(node);
if (constructor) {
for (var _i = 0, _a = constructor.parameters; _i < _a.length; _i++) {
var parameter = _a[_i];
markTypeNodeAsReferenced(parameter.type);
}
}
break;
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
for (var _b = 0, _c = node.parameters; _b < _c.length; _b++) {
var parameter = _c[_b];
markTypeNodeAsReferenced(parameter.type);
}
markTypeNodeAsReferenced(node.type);
break;
case 147 /* PropertyDeclaration */:
case 144 /* Parameter */:
markTypeNodeAsReferenced(node.type);
break;
}
}
ts.forEach(node.decorators, checkDecorator);
}
function checkFunctionDeclaration(node) {
if (produceDiagnostics) {
checkFunctionOrMethodDeclaration(node) || checkGrammarForGenerator(node);
checkCollisionWithCapturedSuperVariable(node, node.name);
checkCollisionWithCapturedThisVariable(node, node.name);
checkCollisionWithRequireExportsInGeneratedCode(node, node.name);
checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name);
}
}
function checkFunctionOrMethodDeclaration(node) {
checkDecorators(node);
checkSignatureDeclaration(node);
var isAsync = ts.isAsyncFunctionLike(node);
// Do not use hasDynamicName here, because that returns false for well known symbols.
// We want to perform checkComputedPropertyName for all computed properties, including
// well known symbols.
if (node.name && node.name.kind === 142 /* ComputedPropertyName */) {
// This check will account for methods in class/interface declarations,
// as well as accessors in classes/object literals
checkComputedPropertyName(node.name);
}
if (!ts.hasDynamicName(node)) {
// first we want to check the local symbol that contain this declaration
// - if node.localSymbol !== undefined - this is current declaration is exported and localSymbol points to the local symbol
// - if node.localSymbol === undefined - this node is non-exported so we can just pick the result of getSymbolOfNode
var symbol = getSymbolOfNode(node);
var localSymbol = node.localSymbol || symbol;
// Since the javascript won't do semantic analysis like typescript,
// if the javascript file comes before the typescript file and both contain same name functions,
// checkFunctionOrConstructorSymbol wouldn't be called if we didnt ignore javascript function.
var firstDeclaration = ts.forEach(localSymbol.declarations,
// Get first non javascript function declaration
function (declaration) { return declaration.kind === node.kind && !ts.isSourceFileJavaScript(ts.getSourceFileOfNode(declaration)) ?
declaration : undefined; });
// Only type check the symbol once
if (node === firstDeclaration) {
checkFunctionOrConstructorSymbol(localSymbol);
}
if (symbol.parent) {
// run check once for the first declaration
if (ts.getDeclarationOfKind(symbol, node.kind) === node) {
// run check on export symbol to check that modifiers agree across all exported declarations
checkFunctionOrConstructorSymbol(symbol);
}
}
}
checkSourceElement(node.body);
if (!node.asteriskToken) {
var returnOrPromisedType = node.type && (isAsync ? checkAsyncFunctionReturnType(node) : getTypeFromTypeNode(node.type));
checkAllCodePathsInNonVoidFunctionReturnOrThrow(node, returnOrPromisedType);
}
if (produceDiagnostics && !node.type) {
// Report an implicit any error if there is no body, no explicit return type, and node is not a private method
// in an ambient context
if (compilerOptions.noImplicitAny && ts.nodeIsMissing(node.body) && !isPrivateWithinAmbient(node)) {
reportImplicitAnyError(node, anyType);
}
if (node.asteriskToken && ts.nodeIsPresent(node.body)) {
// A generator with a body and no type annotation can still cause errors. It can error if the
// yielded values have no common supertype, or it can give an implicit any error if it has no
// yielded values. The only way to trigger these errors is to try checking its return type.
getReturnTypeOfSignature(getSignatureFromDeclaration(node));
}
}
registerForUnusedIdentifiersCheck(node);
}
function registerForUnusedIdentifiersCheck(node) {
if (deferredUnusedIdentifierNodes) {
deferredUnusedIdentifierNodes.push(node);
}
}
function checkUnusedIdentifiers() {
if (deferredUnusedIdentifierNodes) {
for (var _i = 0, deferredUnusedIdentifierNodes_1 = deferredUnusedIdentifierNodes; _i < deferredUnusedIdentifierNodes_1.length; _i++) {
var node = deferredUnusedIdentifierNodes_1[_i];
switch (node.kind) {
case 261 /* SourceFile */:
case 230 /* ModuleDeclaration */:
checkUnusedModuleMembers(node);
break;
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
checkUnusedClassMembers(node);
checkUnusedTypeParameters(node);
break;
case 227 /* InterfaceDeclaration */:
checkUnusedTypeParameters(node);
break;
case 204 /* Block */:
case 232 /* CaseBlock */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
checkUnusedLocalsAndParameters(node);
break;
case 150 /* Constructor */:
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
case 185 /* ArrowFunction */:
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
if (node.body) {
checkUnusedLocalsAndParameters(node);
}
checkUnusedTypeParameters(node);
break;
case 148 /* MethodSignature */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
checkUnusedTypeParameters(node);
break;
}
;
}
}
}
function checkUnusedLocalsAndParameters(node) {
if (node.parent.kind !== 227 /* InterfaceDeclaration */ && noUnusedIdentifiers && !ts.isInAmbientContext(node)) {
var _loop_3 = function (key) {
var local = node.locals[key];
if (!local.isReferenced) {
if (local.valueDeclaration && ts.getRootDeclaration(local.valueDeclaration).kind === 144 /* Parameter */) {
var parameter = ts.getRootDeclaration(local.valueDeclaration);
if (compilerOptions.noUnusedParameters &&
!ts.isParameterPropertyDeclaration(parameter) &&
!ts.parameterIsThisKeyword(parameter) &&
!parameterNameStartsWithUnderscore(local.valueDeclaration.name)) {
error(local.valueDeclaration.name, ts.Diagnostics._0_is_declared_but_never_used, local.name);
}
}
else if (compilerOptions.noUnusedLocals) {
ts.forEach(local.declarations, function (d) { return errorUnusedLocal(d.name || d, local.name); });
}
}
};
for (var key in node.locals) {
_loop_3(key);
}
}
}
function errorUnusedLocal(node, name) {
if (isIdentifierThatStartsWithUnderScore(node)) {
var declaration = ts.getRootDeclaration(node.parent);
if (declaration.kind === 223 /* VariableDeclaration */ &&
(declaration.parent.parent.kind === 212 /* ForInStatement */ ||
declaration.parent.parent.kind === 213 /* ForOfStatement */)) {
return;
}
}
error(node, ts.Diagnostics._0_is_declared_but_never_used, name);
}
function parameterNameStartsWithUnderscore(parameterName) {
return parameterName && isIdentifierThatStartsWithUnderScore(parameterName);
}
function isIdentifierThatStartsWithUnderScore(node) {
return node.kind === 70 /* Identifier */ && node.text.charCodeAt(0) === 95 /* _ */;
}
function checkUnusedClassMembers(node) {
if (compilerOptions.noUnusedLocals && !ts.isInAmbientContext(node)) {
if (node.members) {
for (var _i = 0, _a = node.members; _i < _a.length; _i++) {
var member = _a[_i];
if (member.kind === 149 /* MethodDeclaration */ || member.kind === 147 /* PropertyDeclaration */) {
if (!member.symbol.isReferenced && ts.getModifierFlags(member) & 8 /* Private */) {
error(member.name, ts.Diagnostics._0_is_declared_but_never_used, member.symbol.name);
}
}
else if (member.kind === 150 /* Constructor */) {
for (var _b = 0, _c = member.parameters; _b < _c.length; _b++) {
var parameter = _c[_b];
if (!parameter.symbol.isReferenced && ts.getModifierFlags(parameter) & 8 /* Private */) {
error(parameter.name, ts.Diagnostics.Property_0_is_declared_but_never_used, parameter.symbol.name);
}
}
}
}
}
}
}
function checkUnusedTypeParameters(node) {
if (compilerOptions.noUnusedLocals && !ts.isInAmbientContext(node)) {
if (node.typeParameters) {
// Only report errors on the last declaration for the type parameter container;
// this ensures that all uses have been accounted for.
var symbol = getSymbolOfNode(node);
var lastDeclaration = symbol && symbol.declarations && ts.lastOrUndefined(symbol.declarations);
if (lastDeclaration !== node) {
return;
}
for (var _i = 0, _a = node.typeParameters; _i < _a.length; _i++) {
var typeParameter = _a[_i];
if (!getMergedSymbol(typeParameter.symbol).isReferenced) {
error(typeParameter.name, ts.Diagnostics._0_is_declared_but_never_used, typeParameter.symbol.name);
}
}
}
}
}
function checkUnusedModuleMembers(node) {
if (compilerOptions.noUnusedLocals && !ts.isInAmbientContext(node)) {
for (var key in node.locals) {
var local = node.locals[key];
if (!local.isReferenced && !local.exportSymbol) {
for (var _i = 0, _a = local.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (!ts.isAmbientModule(declaration)) {
error(declaration.name, ts.Diagnostics._0_is_declared_but_never_used, local.name);
}
}
}
}
}
}
function checkBlock(node) {
// Grammar checking for SyntaxKind.Block
if (node.kind === 204 /* Block */) {
checkGrammarStatementInAmbientContext(node);
}
ts.forEach(node.statements, checkSourceElement);
if (node.locals) {
registerForUnusedIdentifiersCheck(node);
}
}
function checkCollisionWithArgumentsInGeneratedCode(node) {
// no rest parameters \ declaration context \ overload - no codegen impact
if (!ts.hasDeclaredRestParameter(node) || ts.isInAmbientContext(node) || ts.nodeIsMissing(node.body)) {
return;
}
ts.forEach(node.parameters, function (p) {
if (p.name && !ts.isBindingPattern(p.name) && p.name.text === argumentsSymbol.name) {
error(p, ts.Diagnostics.Duplicate_identifier_arguments_Compiler_uses_arguments_to_initialize_rest_parameters);
}
});
}
function needCollisionCheckForIdentifier(node, identifier, name) {
if (!(identifier && identifier.text === name)) {
return false;
}
if (node.kind === 147 /* PropertyDeclaration */ ||
node.kind === 146 /* PropertySignature */ ||
node.kind === 149 /* MethodDeclaration */ ||
node.kind === 148 /* MethodSignature */ ||
node.kind === 151 /* GetAccessor */ ||
node.kind === 152 /* SetAccessor */) {
// it is ok to have member named '_super' or '_this' - member access is always qualified
return false;
}
if (ts.isInAmbientContext(node)) {
// ambient context - no codegen impact
return false;
}
var root = ts.getRootDeclaration(node);
if (root.kind === 144 /* Parameter */ && ts.nodeIsMissing(root.parent.body)) {
// just an overload - no codegen impact
return false;
}
return true;
}
function checkCollisionWithCapturedThisVariable(node, name) {
if (needCollisionCheckForIdentifier(node, name, "_this")) {
potentialThisCollisions.push(node);
}
}
// this function will run after checking the source file so 'CaptureThis' is correct for all nodes
function checkIfThisIsCapturedInEnclosingScope(node) {
var current = node;
while (current) {
if (getNodeCheckFlags(current) & 4 /* CaptureThis */) {
var isDeclaration_1 = node.kind !== 70 /* Identifier */;
if (isDeclaration_1) {
error(node.name, ts.Diagnostics.Duplicate_identifier_this_Compiler_uses_variable_declaration_this_to_capture_this_reference);
}
else {
error(node, ts.Diagnostics.Expression_resolves_to_variable_declaration_this_that_compiler_uses_to_capture_this_reference);
}
return;
}
current = current.parent;
}
}
function checkCollisionWithCapturedSuperVariable(node, name) {
if (!needCollisionCheckForIdentifier(node, name, "_super")) {
return;
}
// bubble up and find containing type
var enclosingClass = ts.getContainingClass(node);
// if containing type was not found or it is ambient - exit (no codegen)
if (!enclosingClass || ts.isInAmbientContext(enclosingClass)) {
return;
}
if (ts.getClassExtendsHeritageClauseElement(enclosingClass)) {
var isDeclaration_2 = node.kind !== 70 /* Identifier */;
if (isDeclaration_2) {
error(node, ts.Diagnostics.Duplicate_identifier_super_Compiler_uses_super_to_capture_base_class_reference);
}
else {
error(node, ts.Diagnostics.Expression_resolves_to_super_that_compiler_uses_to_capture_base_class_reference);
}
}
}
function checkCollisionWithRequireExportsInGeneratedCode(node, name) {
// No need to check for require or exports for ES6 modules and later
if (modulekind >= ts.ModuleKind.ES2015) {
return;
}
if (!needCollisionCheckForIdentifier(node, name, "require") && !needCollisionCheckForIdentifier(node, name, "exports")) {
return;
}
// Uninstantiated modules shouldnt do this check
if (node.kind === 230 /* ModuleDeclaration */ && ts.getModuleInstanceState(node) !== 1 /* Instantiated */) {
return;
}
// In case of variable declaration, node.parent is variable statement so look at the variable statement's parent
var parent = getDeclarationContainer(node);
if (parent.kind === 261 /* SourceFile */ && ts.isExternalOrCommonJsModule(parent)) {
// If the declaration happens to be in external module, report error that require and exports are reserved keywords
error(name, ts.Diagnostics.Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module, ts.declarationNameToString(name), ts.declarationNameToString(name));
}
}
function checkCollisionWithGlobalPromiseInGeneratedCode(node, name) {
if (!needCollisionCheckForIdentifier(node, name, "Promise")) {
return;
}
// Uninstantiated modules shouldnt do this check
if (node.kind === 230 /* ModuleDeclaration */ && ts.getModuleInstanceState(node) !== 1 /* Instantiated */) {
return;
}
// In case of variable declaration, node.parent is variable statement so look at the variable statement's parent
var parent = getDeclarationContainer(node);
if (parent.kind === 261 /* SourceFile */ && ts.isExternalOrCommonJsModule(parent) && parent.flags & 8192 /* HasAsyncFunctions */) {
// If the declaration happens to be in external module, report error that Promise is a reserved identifier.
error(name, ts.Diagnostics.Duplicate_identifier_0_Compiler_reserves_name_1_in_top_level_scope_of_a_module_containing_async_functions, ts.declarationNameToString(name), ts.declarationNameToString(name));
}
}
function checkVarDeclaredNamesNotShadowed(node) {
// - ScriptBody : StatementList
// It is a Syntax Error if any element of the LexicallyDeclaredNames of StatementList
// also occurs in the VarDeclaredNames of StatementList.
// - Block : { StatementList }
// It is a Syntax Error if any element of the LexicallyDeclaredNames of StatementList
// also occurs in the VarDeclaredNames of StatementList.
// Variable declarations are hoisted to the top of their function scope. They can shadow
// block scoped declarations, which bind tighter. this will not be flagged as duplicate definition
// by the binder as the declaration scope is different.
// A non-initialized declaration is a no-op as the block declaration will resolve before the var
// declaration. the problem is if the declaration has an initializer. this will act as a write to the
// block declared value. this is fine for let, but not const.
// Only consider declarations with initializers, uninitialized const declarations will not
// step on a let/const variable.
// Do not consider const and const declarations, as duplicate block-scoped declarations
// are handled by the binder.
// We are only looking for const declarations that step on let\const declarations from a
// different scope. e.g.:
// {
// const x = 0; // localDeclarationSymbol obtained after name resolution will correspond to this declaration
// const x = 0; // symbol for this declaration will be 'symbol'
// }
// skip block-scoped variables and parameters
if ((ts.getCombinedNodeFlags(node) & 3 /* BlockScoped */) !== 0 || ts.isParameterDeclaration(node)) {
return;
}
// skip variable declarations that don't have initializers
// NOTE: in ES6 spec initializer is required in variable declarations where name is binding pattern
// so we'll always treat binding elements as initialized
if (node.kind === 223 /* VariableDeclaration */ && !node.initializer) {
return;
}
var symbol = getSymbolOfNode(node);
if (symbol.flags & 1 /* FunctionScopedVariable */) {
var localDeclarationSymbol = resolveName(node, node.name.text, 3 /* Variable */, /*nodeNotFoundErrorMessage*/ undefined, /*nameArg*/ undefined);
if (localDeclarationSymbol &&
localDeclarationSymbol !== symbol &&
localDeclarationSymbol.flags & 2 /* BlockScopedVariable */) {
if (getDeclarationNodeFlagsFromSymbol(localDeclarationSymbol) & 3 /* BlockScoped */) {
var varDeclList = ts.getAncestor(localDeclarationSymbol.valueDeclaration, 224 /* VariableDeclarationList */);
var container = varDeclList.parent.kind === 205 /* VariableStatement */ && varDeclList.parent.parent
? varDeclList.parent.parent
: undefined;
// names of block-scoped and function scoped variables can collide only
// if block scoped variable is defined in the function\module\source file scope (because of variable hoisting)
var namesShareScope = container &&
(container.kind === 204 /* Block */ && ts.isFunctionLike(container.parent) ||
container.kind === 231 /* ModuleBlock */ ||
container.kind === 230 /* ModuleDeclaration */ ||
container.kind === 261 /* SourceFile */);
// here we know that function scoped variable is shadowed by block scoped one
// if they are defined in the same scope - binder has already reported redeclaration error
// otherwise if variable has an initializer - show error that initialization will fail
// since LHS will be block scoped name instead of function scoped
if (!namesShareScope) {
var name_24 = symbolToString(localDeclarationSymbol);
error(node, ts.Diagnostics.Cannot_initialize_outer_scoped_variable_0_in_the_same_scope_as_block_scoped_declaration_1, name_24, name_24);
}
}
}
}
}
// Check that a parameter initializer contains no references to parameters declared to the right of itself
function checkParameterInitializer(node) {
if (ts.getRootDeclaration(node).kind !== 144 /* Parameter */) {
return;
}
var func = ts.getContainingFunction(node);
visit(node.initializer);
function visit(n) {
if (ts.isTypeNode(n) || ts.isDeclarationName(n)) {
// do not dive in types
// skip declaration names (i.e. in object literal expressions)
return;
}
if (n.kind === 177 /* PropertyAccessExpression */) {
// skip property names in property access expression
return visit(n.expression);
}
else if (n.kind === 70 /* Identifier */) {
// check FunctionLikeDeclaration.locals (stores parameters\function local variable)
// if it contains entry with a specified name
var symbol = resolveName(n, n.text, 107455 /* Value */ | 8388608 /* Alias */, /*nameNotFoundMessage*/ undefined, /*nameArg*/ undefined);
if (!symbol || symbol === unknownSymbol || !symbol.valueDeclaration) {
return;
}
if (symbol.valueDeclaration === node) {
error(n, ts.Diagnostics.Parameter_0_cannot_be_referenced_in_its_initializer, ts.declarationNameToString(node.name));
return;
}
// locals map for function contain both parameters and function locals
// so we need to do a bit of extra work to check if reference is legal
var enclosingContainer = ts.getEnclosingBlockScopeContainer(symbol.valueDeclaration);
if (enclosingContainer === func) {
if (symbol.valueDeclaration.kind === 144 /* Parameter */) {
// it is ok to reference parameter in initializer if either
// - parameter is located strictly on the left of current parameter declaration
if (symbol.valueDeclaration.pos < node.pos) {
return;
}
// - parameter is wrapped in function-like entity
var current = n;
while (current !== node.initializer) {
if (ts.isFunctionLike(current.parent)) {
return;
}
// computed property names/initializers in instance property declaration of class like entities
// are executed in constructor and thus deferred
if (current.parent.kind === 147 /* PropertyDeclaration */ &&
!(ts.hasModifier(current.parent, 32 /* Static */)) &&
ts.isClassLike(current.parent.parent)) {
return;
}
current = current.parent;
}
}
error(n, ts.Diagnostics.Initializer_of_parameter_0_cannot_reference_identifier_1_declared_after_it, ts.declarationNameToString(node.name), ts.declarationNameToString(n));
}
}
else {
return ts.forEachChild(n, visit);
}
}
}
function convertAutoToAny(type) {
return type === autoType ? anyType : type === autoArrayType ? anyArrayType : type;
}
// Check variable, parameter, or property declaration
function checkVariableLikeDeclaration(node) {
checkDecorators(node);
checkSourceElement(node.type);
// For a computed property, just check the initializer and exit
// Do not use hasDynamicName here, because that returns false for well known symbols.
// We want to perform checkComputedPropertyName for all computed properties, including
// well known symbols.
if (node.name.kind === 142 /* ComputedPropertyName */) {
checkComputedPropertyName(node.name);
if (node.initializer) {
checkExpressionCached(node.initializer);
}
}
if (node.kind === 174 /* BindingElement */) {
// check computed properties inside property names of binding elements
if (node.propertyName && node.propertyName.kind === 142 /* ComputedPropertyName */) {
checkComputedPropertyName(node.propertyName);
}
// check private/protected variable access
var parent_11 = node.parent.parent;
var parentType = getTypeForBindingElementParent(parent_11);
var name_25 = node.propertyName || node.name;
var property = getPropertyOfType(parentType, ts.getTextOfPropertyName(name_25));
markPropertyAsReferenced(property);
if (parent_11.initializer && property && getParentOfSymbol(property)) {
checkClassPropertyAccess(parent_11, parent_11.initializer, parentType, property);
}
}
// For a binding pattern, check contained binding elements
if (ts.isBindingPattern(node.name)) {
ts.forEach(node.name.elements, checkSourceElement);
}
// For a parameter declaration with an initializer, error and exit if the containing function doesn't have a body
if (node.initializer && ts.getRootDeclaration(node).kind === 144 /* Parameter */ && ts.nodeIsMissing(ts.getContainingFunction(node).body)) {
error(node, ts.Diagnostics.A_parameter_initializer_is_only_allowed_in_a_function_or_constructor_implementation);
return;
}
// For a binding pattern, validate the initializer and exit
if (ts.isBindingPattern(node.name)) {
// Don't validate for-in initializer as it is already an error
if (node.initializer && node.parent.parent.kind !== 212 /* ForInStatement */) {
checkTypeAssignableTo(checkExpressionCached(node.initializer), getWidenedTypeForVariableLikeDeclaration(node), node, /*headMessage*/ undefined);
checkParameterInitializer(node);
}
return;
}
var symbol = getSymbolOfNode(node);
var type = convertAutoToAny(getTypeOfVariableOrParameterOrProperty(symbol));
if (node === symbol.valueDeclaration) {
// Node is the primary declaration of the symbol, just validate the initializer
// Don't validate for-in initializer as it is already an error
if (node.initializer && node.parent.parent.kind !== 212 /* ForInStatement */) {
checkTypeAssignableTo(checkExpressionCached(node.initializer), type, node, /*headMessage*/ undefined);
checkParameterInitializer(node);
}
}
else {
// Node is a secondary declaration, check that type is identical to primary declaration and check that
// initializer is consistent with type associated with the node
var declarationType = convertAutoToAny(getWidenedTypeForVariableLikeDeclaration(node));
if (type !== unknownType && declarationType !== unknownType && !isTypeIdenticalTo(type, declarationType)) {
error(node.name, ts.Diagnostics.Subsequent_variable_declarations_must_have_the_same_type_Variable_0_must_be_of_type_1_but_here_has_type_2, ts.declarationNameToString(node.name), typeToString(type), typeToString(declarationType));
}
if (node.initializer) {
checkTypeAssignableTo(checkExpressionCached(node.initializer), declarationType, node, /*headMessage*/ undefined);
}
if (!areDeclarationFlagsIdentical(node, symbol.valueDeclaration)) {
error(symbol.valueDeclaration.name, ts.Diagnostics.All_declarations_of_0_must_have_identical_modifiers, ts.declarationNameToString(node.name));
error(node.name, ts.Diagnostics.All_declarations_of_0_must_have_identical_modifiers, ts.declarationNameToString(node.name));
}
}
if (node.kind !== 147 /* PropertyDeclaration */ && node.kind !== 146 /* PropertySignature */) {
// We know we don't have a binding pattern or computed name here
checkExportsOnMergedDeclarations(node);
if (node.kind === 223 /* VariableDeclaration */ || node.kind === 174 /* BindingElement */) {
checkVarDeclaredNamesNotShadowed(node);
}
checkCollisionWithCapturedSuperVariable(node, node.name);
checkCollisionWithCapturedThisVariable(node, node.name);
checkCollisionWithRequireExportsInGeneratedCode(node, node.name);
checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name);
}
}
function areDeclarationFlagsIdentical(left, right) {
if ((left.kind === 144 /* Parameter */ && right.kind === 223 /* VariableDeclaration */) ||
(left.kind === 223 /* VariableDeclaration */ && right.kind === 144 /* Parameter */)) {
// Differences in optionality between parameters and variables are allowed.
return true;
}
if (ts.hasQuestionToken(left) !== ts.hasQuestionToken(right)) {
return false;
}
var interestingFlags = 8 /* Private */ |
16 /* Protected */ |
256 /* Async */ |
128 /* Abstract */ |
64 /* Readonly */ |
32 /* Static */;
return (ts.getModifierFlags(left) & interestingFlags) === (ts.getModifierFlags(right) & interestingFlags);
}
function checkVariableDeclaration(node) {
checkGrammarVariableDeclaration(node);
return checkVariableLikeDeclaration(node);
}
function checkBindingElement(node) {
checkGrammarBindingElement(node);
return checkVariableLikeDeclaration(node);
}
function checkVariableStatement(node) {
// Grammar checking
checkGrammarDecorators(node) || checkGrammarModifiers(node) || checkGrammarVariableDeclarationList(node.declarationList) || checkGrammarForDisallowedLetOrConstStatement(node);
ts.forEach(node.declarationList.declarations, checkSourceElement);
}
function checkGrammarDisallowedModifiersOnObjectLiteralExpressionMethod(node) {
// We only disallow modifier on a method declaration if it is a property of object-literal-expression
if (node.modifiers && node.parent.kind === 176 /* ObjectLiteralExpression */) {
if (ts.isAsyncFunctionLike(node)) {
if (node.modifiers.length > 1) {
return grammarErrorOnFirstToken(node, ts.Diagnostics.Modifiers_cannot_appear_here);
}
}
else {
return grammarErrorOnFirstToken(node, ts.Diagnostics.Modifiers_cannot_appear_here);
}
}
}
function checkExpressionStatement(node) {
// Grammar checking
checkGrammarStatementInAmbientContext(node);
checkExpression(node.expression);
}
function checkIfStatement(node) {
// Grammar checking
checkGrammarStatementInAmbientContext(node);
checkExpression(node.expression);
checkSourceElement(node.thenStatement);
if (node.thenStatement.kind === 206 /* EmptyStatement */) {
error(node.thenStatement, ts.Diagnostics.The_body_of_an_if_statement_cannot_be_the_empty_statement);
}
checkSourceElement(node.elseStatement);
}
function checkDoStatement(node) {
// Grammar checking
checkGrammarStatementInAmbientContext(node);
checkSourceElement(node.statement);
checkExpression(node.expression);
}
function checkWhileStatement(node) {
// Grammar checking
checkGrammarStatementInAmbientContext(node);
checkExpression(node.expression);
checkSourceElement(node.statement);
}
function checkForStatement(node) {
// Grammar checking
if (!checkGrammarStatementInAmbientContext(node)) {
if (node.initializer && node.initializer.kind === 224 /* VariableDeclarationList */) {
checkGrammarVariableDeclarationList(node.initializer);
}
}
if (node.initializer) {
if (node.initializer.kind === 224 /* VariableDeclarationList */) {
ts.forEach(node.initializer.declarations, checkVariableDeclaration);
}
else {
checkExpression(node.initializer);
}
}
if (node.condition)
checkExpression(node.condition);
if (node.incrementor)
checkExpression(node.incrementor);
checkSourceElement(node.statement);
if (node.locals) {
registerForUnusedIdentifiersCheck(node);
}
}
function checkForOfStatement(node) {
checkGrammarForInOrForOfStatement(node);
// Check the LHS and RHS
// If the LHS is a declaration, just check it as a variable declaration, which will in turn check the RHS
// via checkRightHandSideOfForOf.
// If the LHS is an expression, check the LHS, as a destructuring assignment or as a reference.
// Then check that the RHS is assignable to it.
if (node.initializer.kind === 224 /* VariableDeclarationList */) {
checkForInOrForOfVariableDeclaration(node);
}
else {
var varExpr = node.initializer;
var iteratedType = checkRightHandSideOfForOf(node.expression);
// There may be a destructuring assignment on the left side
if (varExpr.kind === 175 /* ArrayLiteralExpression */ || varExpr.kind === 176 /* ObjectLiteralExpression */) {
// iteratedType may be undefined. In this case, we still want to check the structure of
// varExpr, in particular making sure it's a valid LeftHandSideExpression. But we'd like
// to short circuit the type relation checking as much as possible, so we pass the unknownType.
checkDestructuringAssignment(varExpr, iteratedType || unknownType);
}
else {
var leftType = checkExpression(varExpr);
checkReferenceExpression(varExpr, ts.Diagnostics.The_left_hand_side_of_a_for_of_statement_must_be_a_variable_or_a_property_access);
// iteratedType will be undefined if the rightType was missing properties/signatures
// required to get its iteratedType (like [Symbol.iterator] or next). This may be
// because we accessed properties from anyType, or it may have led to an error inside
// getElementTypeOfIterable.
if (iteratedType) {
checkTypeAssignableTo(iteratedType, leftType, varExpr, /*headMessage*/ undefined);
}
}
}
checkSourceElement(node.statement);
if (node.locals) {
registerForUnusedIdentifiersCheck(node);
}
}
function checkForInStatement(node) {
// Grammar checking
checkGrammarForInOrForOfStatement(node);
// TypeScript 1.0 spec (April 2014): 5.4
// In a 'for-in' statement of the form
// for (let VarDecl in Expr) Statement
// VarDecl must be a variable declaration without a type annotation that declares a variable of type Any,
// and Expr must be an expression of type Any, an object type, or a type parameter type.
if (node.initializer.kind === 224 /* VariableDeclarationList */) {
var variable = node.initializer.declarations[0];
if (variable && ts.isBindingPattern(variable.name)) {
error(variable.name, ts.Diagnostics.The_left_hand_side_of_a_for_in_statement_cannot_be_a_destructuring_pattern);
}
checkForInOrForOfVariableDeclaration(node);
}
else {
// In a 'for-in' statement of the form
// for (Var in Expr) Statement
// Var must be an expression classified as a reference of type Any or the String primitive type,
// and Expr must be an expression of type Any, an object type, or a type parameter type.
var varExpr = node.initializer;
var leftType = checkExpression(varExpr);
if (varExpr.kind === 175 /* ArrayLiteralExpression */ || varExpr.kind === 176 /* ObjectLiteralExpression */) {
error(varExpr, ts.Diagnostics.The_left_hand_side_of_a_for_in_statement_cannot_be_a_destructuring_pattern);
}
else if (!isTypeAnyOrAllConstituentTypesHaveKind(leftType, 34 /* StringLike */)) {
error(varExpr, ts.Diagnostics.The_left_hand_side_of_a_for_in_statement_must_be_of_type_string_or_any);
}
else {
// run check only former check succeeded to avoid cascading errors
checkReferenceExpression(varExpr, ts.Diagnostics.The_left_hand_side_of_a_for_in_statement_must_be_a_variable_or_a_property_access);
}
}
var rightType = checkNonNullExpression(node.expression);
// unknownType is returned i.e. if node.expression is identifier whose name cannot be resolved
// in this case error about missing name is already reported - do not report extra one
if (!isTypeAnyOrAllConstituentTypesHaveKind(rightType, 32768 /* Object */ | 16384 /* TypeParameter */)) {
error(node.expression, ts.Diagnostics.The_right_hand_side_of_a_for_in_statement_must_be_of_type_any_an_object_type_or_a_type_parameter);
}
checkSourceElement(node.statement);
if (node.locals) {
registerForUnusedIdentifiersCheck(node);
}
}
function checkForInOrForOfVariableDeclaration(iterationStatement) {
var variableDeclarationList = iterationStatement.initializer;
// checkGrammarForInOrForOfStatement will check that there is exactly one declaration.
if (variableDeclarationList.declarations.length >= 1) {
var decl = variableDeclarationList.declarations[0];
checkVariableDeclaration(decl);
}
}
function checkRightHandSideOfForOf(rhsExpression) {
var expressionType = checkNonNullExpression(rhsExpression);
return checkIteratedTypeOrElementType(expressionType, rhsExpression, /*allowStringInput*/ true);
}
function checkIteratedTypeOrElementType(inputType, errorNode, allowStringInput) {
if (isTypeAny(inputType)) {
return inputType;
}
if (languageVersion >= 2 /* ES2015 */) {
return checkElementTypeOfIterable(inputType, errorNode);
}
if (allowStringInput) {
return checkElementTypeOfArrayOrString(inputType, errorNode);
}
if (isArrayLikeType(inputType)) {
var indexType = getIndexTypeOfType(inputType, 1 /* Number */);
if (indexType) {
return indexType;
}
}
if (errorNode) {
error(errorNode, ts.Diagnostics.Type_0_is_not_an_array_type, typeToString(inputType));
}
return unknownType;
}
/**
* When errorNode is undefined, it means we should not report any errors.
*/
function checkElementTypeOfIterable(iterable, errorNode) {
var elementType = getElementTypeOfIterable(iterable, errorNode);
// Now even though we have extracted the iteratedType, we will have to validate that the type
// passed in is actually an Iterable.
if (errorNode && elementType) {
checkTypeAssignableTo(iterable, createIterableType(elementType), errorNode);
}
return elementType || anyType;
}
/**
* We want to treat type as an iterable, and get the type it is an iterable of. The iterable
* must have the following structure (annotated with the names of the variables below):
*
* { // iterable
* [Symbol.iterator]: { // iteratorFunction
* (): Iterator<T>
* }
* }
*
* T is the type we are after. At every level that involves analyzing return types
* of signatures, we union the return types of all the signatures.
*
* Another thing to note is that at any step of this process, we could run into a dead end,
* meaning either the property is missing, or we run into the anyType. If either of these things
* happens, we return undefined to signal that we could not find the iterated type. If a property
* is missing, and the previous step did not result in 'any', then we also give an error if the
* caller requested it. Then the caller can decide what to do in the case where there is no iterated
* type. This is different from returning anyType, because that would signify that we have matched the
* whole pattern and that T (above) is 'any'.
*/
function getElementTypeOfIterable(type, errorNode) {
if (isTypeAny(type)) {
return undefined;
}
var typeAsIterable = type;
if (!typeAsIterable.iterableElementType) {
// As an optimization, if the type is instantiated directly using the globalIterableType (Iterable<number>),
// then just grab its type argument.
if ((getObjectFlags(type) & 4 /* Reference */) && type.target === getGlobalIterableType()) {
typeAsIterable.iterableElementType = type.typeArguments[0];
}
else {
var iteratorFunction = getTypeOfPropertyOfType(type, ts.getPropertyNameForKnownSymbolName("iterator"));
if (isTypeAny(iteratorFunction)) {
return undefined;
}
var iteratorFunctionSignatures = iteratorFunction ? getSignaturesOfType(iteratorFunction, 0 /* Call */) : emptyArray;
if (iteratorFunctionSignatures.length === 0) {
if (errorNode) {
error(errorNode, ts.Diagnostics.Type_must_have_a_Symbol_iterator_method_that_returns_an_iterator);
}
return undefined;
}
typeAsIterable.iterableElementType = getElementTypeOfIterator(getUnionType(ts.map(iteratorFunctionSignatures, getReturnTypeOfSignature), /*subtypeReduction*/ true), errorNode);
}
}
return typeAsIterable.iterableElementType;
}
/**
* This function has very similar logic as getElementTypeOfIterable, except that it operates on
* Iterators instead of Iterables. Here is the structure:
*
* { // iterator
* next: { // iteratorNextFunction
* (): { // iteratorNextResult
* value: T // iteratorNextValue
* }
* }
* }
*
*/
function getElementTypeOfIterator(type, errorNode) {
if (isTypeAny(type)) {
return undefined;
}
var typeAsIterator = type;
if (!typeAsIterator.iteratorElementType) {
// As an optimization, if the type is instantiated directly using the globalIteratorType (Iterator<number>),
// then just grab its type argument.
if ((getObjectFlags(type) & 4 /* Reference */) && type.target === getGlobalIteratorType()) {
typeAsIterator.iteratorElementType = type.typeArguments[0];
}
else {
var iteratorNextFunction = getTypeOfPropertyOfType(type, "next");
if (isTypeAny(iteratorNextFunction)) {
return undefined;
}
var iteratorNextFunctionSignatures = iteratorNextFunction ? getSignaturesOfType(iteratorNextFunction, 0 /* Call */) : emptyArray;
if (iteratorNextFunctionSignatures.length === 0) {
if (errorNode) {
error(errorNode, ts.Diagnostics.An_iterator_must_have_a_next_method);
}
return undefined;
}
var iteratorNextResult = getUnionType(ts.map(iteratorNextFunctionSignatures, getReturnTypeOfSignature), /*subtypeReduction*/ true);
if (isTypeAny(iteratorNextResult)) {
return undefined;
}
var iteratorNextValue = getTypeOfPropertyOfType(iteratorNextResult, "value");
if (!iteratorNextValue) {
if (errorNode) {
error(errorNode, ts.Diagnostics.The_type_returned_by_the_next_method_of_an_iterator_must_have_a_value_property);
}
return undefined;
}
typeAsIterator.iteratorElementType = iteratorNextValue;
}
}
return typeAsIterator.iteratorElementType;
}
function getElementTypeOfIterableIterator(type) {
if (isTypeAny(type)) {
return undefined;
}
// As an optimization, if the type is instantiated directly using the globalIterableIteratorType (IterableIterator<number>),
// then just grab its type argument.
if ((getObjectFlags(type) & 4 /* Reference */) && type.target === getGlobalIterableIteratorType()) {
return type.typeArguments[0];
}
return getElementTypeOfIterable(type, /*errorNode*/ undefined) ||
getElementTypeOfIterator(type, /*errorNode*/ undefined);
}
/**
* This function does the following steps:
* 1. Break up arrayOrStringType (possibly a union) into its string constituents and array constituents.
* 2. Take the element types of the array constituents.
* 3. Return the union of the element types, and string if there was a string constituent.
*
* For example:
* string -> string
* number[] -> number
* string[] | number[] -> string | number
* string | number[] -> string | number
* string | string[] | number[] -> string | number
*
* It also errors if:
* 1. Some constituent is neither a string nor an array.
* 2. Some constituent is a string and target is less than ES5 (because in ES3 string is not indexable).
*/
function checkElementTypeOfArrayOrString(arrayOrStringType, errorNode) {
ts.Debug.assert(languageVersion < 2 /* ES2015 */);
// After we remove all types that are StringLike, we will know if there was a string constituent
// based on whether the remaining type is the same as the initial type.
var arrayType = arrayOrStringType;
if (arrayOrStringType.flags & 65536 /* Union */) {
var arrayTypes = arrayOrStringType.types;
var filteredTypes = ts.filter(arrayTypes, function (t) { return !(t.flags & 34 /* StringLike */); });
if (filteredTypes !== arrayTypes) {
arrayType = getUnionType(filteredTypes, /*subtypeReduction*/ true);
}
}
else if (arrayOrStringType.flags & 34 /* StringLike */) {
arrayType = neverType;
}
var hasStringConstituent = arrayOrStringType !== arrayType;
var reportedError = false;
if (hasStringConstituent) {
if (languageVersion < 1 /* ES5 */) {
error(errorNode, ts.Diagnostics.Using_a_string_in_a_for_of_statement_is_only_supported_in_ECMAScript_5_and_higher);
reportedError = true;
}
// Now that we've removed all the StringLike types, if no constituents remain, then the entire
// arrayOrStringType was a string.
if (arrayType.flags & 8192 /* Never */) {
return stringType;
}
}
if (!isArrayLikeType(arrayType)) {
if (!reportedError) {
// Which error we report depends on whether there was a string constituent. For example,
// if the input type is number | string, we want to say that number is not an array type.
// But if the input was just number, we want to say that number is not an array type
// or a string type.
var diagnostic = hasStringConstituent
? ts.Diagnostics.Type_0_is_not_an_array_type
: ts.Diagnostics.Type_0_is_not_an_array_type_or_a_string_type;
error(errorNode, diagnostic, typeToString(arrayType));
}
return hasStringConstituent ? stringType : unknownType;
}
var arrayElementType = getIndexTypeOfType(arrayType, 1 /* Number */) || unknownType;
if (hasStringConstituent) {
// This is just an optimization for the case where arrayOrStringType is string | string[]
if (arrayElementType.flags & 34 /* StringLike */) {
return stringType;
}
return getUnionType([arrayElementType, stringType], /*subtypeReduction*/ true);
}
return arrayElementType;
}
function checkBreakOrContinueStatement(node) {
// Grammar checking
checkGrammarStatementInAmbientContext(node) || checkGrammarBreakOrContinueStatement(node);
// TODO: Check that target label is valid
}
function isGetAccessorWithAnnotatedSetAccessor(node) {
return !!(node.kind === 151 /* GetAccessor */ && ts.getSetAccessorTypeAnnotationNode(ts.getDeclarationOfKind(node.symbol, 152 /* SetAccessor */)));
}
function isUnwrappedReturnTypeVoidOrAny(func, returnType) {
var unwrappedReturnType = ts.isAsyncFunctionLike(func) ? getPromisedType(returnType) : returnType;
return unwrappedReturnType && maybeTypeOfKind(unwrappedReturnType, 1024 /* Void */ | 1 /* Any */);
}
function checkReturnStatement(node) {
// Grammar checking
if (!checkGrammarStatementInAmbientContext(node)) {
var functionBlock = ts.getContainingFunction(node);
if (!functionBlock) {
grammarErrorOnFirstToken(node, ts.Diagnostics.A_return_statement_can_only_be_used_within_a_function_body);
}
}
var func = ts.getContainingFunction(node);
if (func) {
var signature = getSignatureFromDeclaration(func);
var returnType = getReturnTypeOfSignature(signature);
if (strictNullChecks || node.expression || returnType.flags & 8192 /* Never */) {
var exprType = node.expression ? checkExpressionCached(node.expression) : undefinedType;
if (func.asteriskToken) {
// A generator does not need its return expressions checked against its return type.
// Instead, the yield expressions are checked against the element type.
// TODO: Check return expressions of generators when return type tracking is added
// for generators.
return;
}
if (func.kind === 152 /* SetAccessor */) {
if (node.expression) {
error(node.expression, ts.Diagnostics.Setters_cannot_return_a_value);
}
}
else if (func.kind === 150 /* Constructor */) {
if (node.expression && !checkTypeAssignableTo(exprType, returnType, node.expression)) {
error(node.expression, ts.Diagnostics.Return_type_of_constructor_signature_must_be_assignable_to_the_instance_type_of_the_class);
}
}
else if (func.type || isGetAccessorWithAnnotatedSetAccessor(func)) {
if (ts.isAsyncFunctionLike(func)) {
var promisedType = getPromisedType(returnType);
var awaitedType = checkAwaitedType(exprType, node.expression || node, ts.Diagnostics.Return_expression_in_async_function_does_not_have_a_valid_callable_then_member);
if (promisedType) {
// If the function has a return type, but promisedType is
// undefined, an error will be reported in checkAsyncFunctionReturnType
// so we don't need to report one here.
checkTypeAssignableTo(awaitedType, promisedType, node.expression || node);
}
}
else {
checkTypeAssignableTo(exprType, returnType, node.expression || node);
}
}
}
else if (func.kind !== 150 /* Constructor */ && compilerOptions.noImplicitReturns && !isUnwrappedReturnTypeVoidOrAny(func, returnType)) {
// The function has a return type, but the return statement doesn't have an expression.
error(node, ts.Diagnostics.Not_all_code_paths_return_a_value);
}
}
}
function checkWithStatement(node) {
// Grammar checking for withStatement
if (!checkGrammarStatementInAmbientContext(node)) {
if (node.flags & 524288 /* AwaitContext */) {
grammarErrorOnFirstToken(node, ts.Diagnostics.with_statements_are_not_allowed_in_an_async_function_block);
}
}
checkExpression(node.expression);
var sourceFile = ts.getSourceFileOfNode(node);
if (!hasParseDiagnostics(sourceFile)) {
var start = ts.getSpanOfTokenAtPosition(sourceFile, node.pos).start;
var end = node.statement.pos;
grammarErrorAtPos(sourceFile, start, end - start, ts.Diagnostics.The_with_statement_is_not_supported_All_symbols_in_a_with_block_will_have_type_any);
}
}
function checkSwitchStatement(node) {
// Grammar checking
checkGrammarStatementInAmbientContext(node);
var firstDefaultClause;
var hasDuplicateDefaultClause = false;
var expressionType = checkExpression(node.expression);
var expressionIsLiteral = isLiteralType(expressionType);
ts.forEach(node.caseBlock.clauses, function (clause) {
// Grammar check for duplicate default clauses, skip if we already report duplicate default clause
if (clause.kind === 254 /* DefaultClause */ && !hasDuplicateDefaultClause) {
if (firstDefaultClause === undefined) {
firstDefaultClause = clause;
}
else {
var sourceFile = ts.getSourceFileOfNode(node);
var start = ts.skipTrivia(sourceFile.text, clause.pos);
var end = clause.statements.length > 0 ? clause.statements[0].pos : clause.end;
grammarErrorAtPos(sourceFile, start, end - start, ts.Diagnostics.A_default_clause_cannot_appear_more_than_once_in_a_switch_statement);
hasDuplicateDefaultClause = true;
}
}
if (produceDiagnostics && clause.kind === 253 /* CaseClause */) {
var caseClause = clause;
// TypeScript 1.0 spec (April 2014): 5.9
// In a 'switch' statement, each 'case' expression must be of a type that is comparable
// to or from the type of the 'switch' expression.
var caseType = checkExpression(caseClause.expression);
var caseIsLiteral = isLiteralType(caseType);
var comparedExpressionType = expressionType;
if (!caseIsLiteral || !expressionIsLiteral) {
caseType = caseIsLiteral ? getBaseTypeOfLiteralType(caseType) : caseType;
comparedExpressionType = getBaseTypeOfLiteralType(expressionType);
}
if (!isTypeEqualityComparableTo(comparedExpressionType, caseType)) {
// expressionType is not comparable to caseType, try the reversed check and report errors if it fails
checkTypeComparableTo(caseType, comparedExpressionType, caseClause.expression, /*headMessage*/ undefined);
}
}
ts.forEach(clause.statements, checkSourceElement);
});
if (node.caseBlock.locals) {
registerForUnusedIdentifiersCheck(node.caseBlock);
}
}
function checkLabeledStatement(node) {
// Grammar checking
if (!checkGrammarStatementInAmbientContext(node)) {
var current = node.parent;
while (current) {
if (ts.isFunctionLike(current)) {
break;
}
if (current.kind === 219 /* LabeledStatement */ && current.label.text === node.label.text) {
var sourceFile = ts.getSourceFileOfNode(node);
grammarErrorOnNode(node.label, ts.Diagnostics.Duplicate_label_0, ts.getTextOfNodeFromSourceText(sourceFile.text, node.label));
break;
}
current = current.parent;
}
}
// ensure that label is unique
checkSourceElement(node.statement);
}
function checkThrowStatement(node) {
// Grammar checking
if (!checkGrammarStatementInAmbientContext(node)) {
if (node.expression === undefined) {
grammarErrorAfterFirstToken(node, ts.Diagnostics.Line_break_not_permitted_here);
}
}
if (node.expression) {
checkExpression(node.expression);
}
}
function checkTryStatement(node) {
// Grammar checking
checkGrammarStatementInAmbientContext(node);
checkBlock(node.tryBlock);
var catchClause = node.catchClause;
if (catchClause) {
// Grammar checking
if (catchClause.variableDeclaration) {
if (catchClause.variableDeclaration.type) {
grammarErrorOnFirstToken(catchClause.variableDeclaration.type, ts.Diagnostics.Catch_clause_variable_cannot_have_a_type_annotation);
}
else if (catchClause.variableDeclaration.initializer) {
grammarErrorOnFirstToken(catchClause.variableDeclaration.initializer, ts.Diagnostics.Catch_clause_variable_cannot_have_an_initializer);
}
else {
var blockLocals = catchClause.block.locals;
if (blockLocals) {
for (var caughtName in catchClause.locals) {
var blockLocal = blockLocals[caughtName];
if (blockLocal && (blockLocal.flags & 2 /* BlockScopedVariable */) !== 0) {
grammarErrorOnNode(blockLocal.valueDeclaration, ts.Diagnostics.Cannot_redeclare_identifier_0_in_catch_clause, caughtName);
}
}
}
}
}
checkBlock(catchClause.block);
}
if (node.finallyBlock) {
checkBlock(node.finallyBlock);
}
}
function checkIndexConstraints(type) {
var declaredNumberIndexer = getIndexDeclarationOfSymbol(type.symbol, 1 /* Number */);
var declaredStringIndexer = getIndexDeclarationOfSymbol(type.symbol, 0 /* String */);
var stringIndexType = getIndexTypeOfType(type, 0 /* String */);
var numberIndexType = getIndexTypeOfType(type, 1 /* Number */);
if (stringIndexType || numberIndexType) {
ts.forEach(getPropertiesOfObjectType(type), function (prop) {
var propType = getTypeOfSymbol(prop);
checkIndexConstraintForProperty(prop, propType, type, declaredStringIndexer, stringIndexType, 0 /* String */);
checkIndexConstraintForProperty(prop, propType, type, declaredNumberIndexer, numberIndexType, 1 /* Number */);
});
if (getObjectFlags(type) & 1 /* Class */ && ts.isClassLike(type.symbol.valueDeclaration)) {
var classDeclaration = type.symbol.valueDeclaration;
for (var _i = 0, _a = classDeclaration.members; _i < _a.length; _i++) {
var member = _a[_i];
// Only process instance properties with computed names here.
// Static properties cannot be in conflict with indexers,
// and properties with literal names were already checked.
if (!(ts.getModifierFlags(member) & 32 /* Static */) && ts.hasDynamicName(member)) {
var propType = getTypeOfSymbol(member.symbol);
checkIndexConstraintForProperty(member.symbol, propType, type, declaredStringIndexer, stringIndexType, 0 /* String */);
checkIndexConstraintForProperty(member.symbol, propType, type, declaredNumberIndexer, numberIndexType, 1 /* Number */);
}
}
}
}
var errorNode;
if (stringIndexType && numberIndexType) {
errorNode = declaredNumberIndexer || declaredStringIndexer;
// condition 'errorNode === undefined' may appear if types does not declare nor string neither number indexer
if (!errorNode && (getObjectFlags(type) & 2 /* Interface */)) {
var someBaseTypeHasBothIndexers = ts.forEach(getBaseTypes(type), function (base) { return getIndexTypeOfType(base, 0 /* String */) && getIndexTypeOfType(base, 1 /* Number */); });
errorNode = someBaseTypeHasBothIndexers ? undefined : type.symbol.declarations[0];
}
}
if (errorNode && !isTypeAssignableTo(numberIndexType, stringIndexType)) {
error(errorNode, ts.Diagnostics.Numeric_index_type_0_is_not_assignable_to_string_index_type_1, typeToString(numberIndexType), typeToString(stringIndexType));
}
function checkIndexConstraintForProperty(prop, propertyType, containingType, indexDeclaration, indexType, indexKind) {
if (!indexType) {
return;
}
// index is numeric and property name is not valid numeric literal
if (indexKind === 1 /* Number */ && !isNumericName(prop.valueDeclaration.name)) {
return;
}
// perform property check if property or indexer is declared in 'type'
// this allows to rule out cases when both property and indexer are inherited from the base class
var errorNode;
if (prop.valueDeclaration.name.kind === 142 /* ComputedPropertyName */ || prop.parent === containingType.symbol) {
errorNode = prop.valueDeclaration;
}
else if (indexDeclaration) {
errorNode = indexDeclaration;
}
else if (getObjectFlags(containingType) & 2 /* Interface */) {
// for interfaces property and indexer might be inherited from different bases
// check if any base class already has both property and indexer.
// check should be performed only if 'type' is the first type that brings property\indexer together
var someBaseClassHasBothPropertyAndIndexer = ts.forEach(getBaseTypes(containingType), function (base) { return getPropertyOfObjectType(base, prop.name) && getIndexTypeOfType(base, indexKind); });
errorNode = someBaseClassHasBothPropertyAndIndexer ? undefined : containingType.symbol.declarations[0];
}
if (errorNode && !isTypeAssignableTo(propertyType, indexType)) {
var errorMessage = indexKind === 0 /* String */
? ts.Diagnostics.Property_0_of_type_1_is_not_assignable_to_string_index_type_2
: ts.Diagnostics.Property_0_of_type_1_is_not_assignable_to_numeric_index_type_2;
error(errorNode, errorMessage, symbolToString(prop), typeToString(propertyType), typeToString(indexType));
}
}
}
function checkTypeNameIsReserved(name, message) {
// TS 1.0 spec (April 2014): 3.6.1
// The predefined type keywords are reserved and cannot be used as names of user defined types.
switch (name.text) {
case "any":
case "number":
case "boolean":
case "string":
case "symbol":
case "void":
error(name, message, name.text);
}
}
/** Check each type parameter and check that type parameters have no duplicate type parameter declarations */
function checkTypeParameters(typeParameterDeclarations) {
if (typeParameterDeclarations) {
for (var i = 0, n = typeParameterDeclarations.length; i < n; i++) {
var node = typeParameterDeclarations[i];
checkTypeParameter(node);
if (produceDiagnostics) {
for (var j = 0; j < i; j++) {
if (typeParameterDeclarations[j].symbol === node.symbol) {
error(node.name, ts.Diagnostics.Duplicate_identifier_0, ts.declarationNameToString(node.name));
}
}
}
}
}
}
/** Check that type parameter lists are identical across multiple declarations */
function checkTypeParameterListsIdentical(node, symbol) {
if (symbol.declarations.length === 1) {
return;
}
var firstDecl;
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (declaration.kind === 226 /* ClassDeclaration */ || declaration.kind === 227 /* InterfaceDeclaration */) {
if (!firstDecl) {
firstDecl = declaration;
}
else if (!areTypeParametersIdentical(firstDecl.typeParameters, node.typeParameters)) {
error(node.name, ts.Diagnostics.All_declarations_of_0_must_have_identical_type_parameters, node.name.text);
}
}
}
}
function checkClassExpression(node) {
checkClassLikeDeclaration(node);
checkNodeDeferred(node);
return getTypeOfSymbol(getSymbolOfNode(node));
}
function checkClassExpressionDeferred(node) {
ts.forEach(node.members, checkSourceElement);
registerForUnusedIdentifiersCheck(node);
}
function checkClassDeclaration(node) {
if (!node.name && !(ts.getModifierFlags(node) & 512 /* Default */)) {
grammarErrorOnFirstToken(node, ts.Diagnostics.A_class_declaration_without_the_default_modifier_must_have_a_name);
}
checkClassLikeDeclaration(node);
ts.forEach(node.members, checkSourceElement);
registerForUnusedIdentifiersCheck(node);
}
function checkClassLikeDeclaration(node) {
checkGrammarClassDeclarationHeritageClauses(node);
checkDecorators(node);
if (node.name) {
checkTypeNameIsReserved(node.name, ts.Diagnostics.Class_name_cannot_be_0);
checkCollisionWithCapturedThisVariable(node, node.name);
checkCollisionWithRequireExportsInGeneratedCode(node, node.name);
checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name);
}
checkTypeParameters(node.typeParameters);
checkExportsOnMergedDeclarations(node);
var symbol = getSymbolOfNode(node);
var type = getDeclaredTypeOfSymbol(symbol);
var typeWithThis = getTypeWithThisArgument(type);
var staticType = getTypeOfSymbol(symbol);
checkTypeParameterListsIdentical(node, symbol);
checkClassForDuplicateDeclarations(node);
var baseTypeNode = ts.getClassExtendsHeritageClauseElement(node);
if (baseTypeNode) {
var baseTypes = getBaseTypes(type);
if (baseTypes.length && produceDiagnostics) {
var baseType_1 = baseTypes[0];
var staticBaseType = getBaseConstructorTypeOfClass(type);
checkBaseTypeAccessibility(staticBaseType, baseTypeNode);
checkSourceElement(baseTypeNode.expression);
if (baseTypeNode.typeArguments) {
ts.forEach(baseTypeNode.typeArguments, checkSourceElement);
for (var _i = 0, _a = getConstructorsForTypeArguments(staticBaseType, baseTypeNode.typeArguments); _i < _a.length; _i++) {
var constructor = _a[_i];
if (!checkTypeArgumentConstraints(constructor.typeParameters, baseTypeNode.typeArguments)) {
break;
}
}
}
checkTypeAssignableTo(typeWithThis, getTypeWithThisArgument(baseType_1, type.thisType), node.name || node, ts.Diagnostics.Class_0_incorrectly_extends_base_class_1);
checkTypeAssignableTo(staticType, getTypeWithoutSignatures(staticBaseType), node.name || node, ts.Diagnostics.Class_static_side_0_incorrectly_extends_base_class_static_side_1);
if (baseType_1.symbol.valueDeclaration &&
!ts.isInAmbientContext(baseType_1.symbol.valueDeclaration) &&
baseType_1.symbol.valueDeclaration.kind === 226 /* ClassDeclaration */) {
if (!isBlockScopedNameDeclaredBeforeUse(baseType_1.symbol.valueDeclaration, node)) {
error(baseTypeNode, ts.Diagnostics.A_class_must_be_declared_after_its_base_class);
}
}
if (!(staticBaseType.symbol && staticBaseType.symbol.flags & 32 /* Class */)) {
// When the static base type is a "class-like" constructor function (but not actually a class), we verify
// that all instantiated base constructor signatures return the same type. We can simply compare the type
// references (as opposed to checking the structure of the types) because elsewhere we have already checked
// that the base type is a class or interface type (and not, for example, an anonymous object type).
var constructors = getInstantiatedConstructorsForTypeArguments(staticBaseType, baseTypeNode.typeArguments);
if (ts.forEach(constructors, function (sig) { return getReturnTypeOfSignature(sig) !== baseType_1; })) {
error(baseTypeNode.expression, ts.Diagnostics.Base_constructors_must_all_have_the_same_return_type);
}
}
checkKindsOfPropertyMemberOverrides(type, baseType_1);
}
}
var implementedTypeNodes = ts.getClassImplementsHeritageClauseElements(node);
if (implementedTypeNodes) {
for (var _b = 0, implementedTypeNodes_1 = implementedTypeNodes; _b < implementedTypeNodes_1.length; _b++) {
var typeRefNode = implementedTypeNodes_1[_b];
if (!ts.isEntityNameExpression(typeRefNode.expression)) {
error(typeRefNode.expression, ts.Diagnostics.A_class_can_only_implement_an_identifier_Slashqualified_name_with_optional_type_arguments);
}
checkTypeReferenceNode(typeRefNode);
if (produceDiagnostics) {
var t = getTypeFromTypeNode(typeRefNode);
if (t !== unknownType) {
var declaredType = getObjectFlags(t) & 4 /* Reference */ ? t.target : t;
if (getObjectFlags(declaredType) & 3 /* ClassOrInterface */) {
checkTypeAssignableTo(typeWithThis, getTypeWithThisArgument(t, type.thisType), node.name || node, ts.Diagnostics.Class_0_incorrectly_implements_interface_1);
}
else {
error(typeRefNode, ts.Diagnostics.A_class_may_only_implement_another_class_or_interface);
}
}
}
}
}
if (produceDiagnostics) {
checkIndexConstraints(type);
checkTypeForDuplicateIndexSignatures(node);
}
}
function checkBaseTypeAccessibility(type, node) {
var signatures = getSignaturesOfType(type, 1 /* Construct */);
if (signatures.length) {
var declaration = signatures[0].declaration;
if (declaration && ts.getModifierFlags(declaration) & 8 /* Private */) {
var typeClassDeclaration = getClassLikeDeclarationOfSymbol(type.symbol);
if (!isNodeWithinClass(node, typeClassDeclaration)) {
error(node, ts.Diagnostics.Cannot_extend_a_class_0_Class_constructor_is_marked_as_private, getFullyQualifiedName(type.symbol));
}
}
}
}
function getTargetSymbol(s) {
// if symbol is instantiated its flags are not copied from the 'target'
// so we'll need to get back original 'target' symbol to work with correct set of flags
return s.flags & 16777216 /* Instantiated */ ? getSymbolLinks(s).target : s;
}
function getClassLikeDeclarationOfSymbol(symbol) {
return ts.forEach(symbol.declarations, function (d) { return ts.isClassLike(d) ? d : undefined; });
}
function checkKindsOfPropertyMemberOverrides(type, baseType) {
// TypeScript 1.0 spec (April 2014): 8.2.3
// A derived class inherits all members from its base class it doesn't override.
// Inheritance means that a derived class implicitly contains all non - overridden members of the base class.
// Both public and private property members are inherited, but only public property members can be overridden.
// A property member in a derived class is said to override a property member in a base class
// when the derived class property member has the same name and kind(instance or static)
// as the base class property member.
// The type of an overriding property member must be assignable(section 3.8.4)
// to the type of the overridden property member, or otherwise a compile - time error occurs.
// Base class instance member functions can be overridden by derived class instance member functions,
// but not by other kinds of members.
// Base class instance member variables and accessors can be overridden by
// derived class instance member variables and accessors, but not by other kinds of members.
// NOTE: assignability is checked in checkClassDeclaration
var baseProperties = getPropertiesOfObjectType(baseType);
for (var _i = 0, baseProperties_1 = baseProperties; _i < baseProperties_1.length; _i++) {
var baseProperty = baseProperties_1[_i];
var base = getTargetSymbol(baseProperty);
if (base.flags & 134217728 /* Prototype */) {
continue;
}
var derived = getTargetSymbol(getPropertyOfObjectType(type, base.name));
var baseDeclarationFlags = getDeclarationModifierFlagsFromSymbol(base);
ts.Debug.assert(!!derived, "derived should point to something, even if it is the base class' declaration.");
if (derived) {
// In order to resolve whether the inherited method was overridden in the base class or not,
// we compare the Symbols obtained. Since getTargetSymbol returns the symbol on the *uninstantiated*
// type declaration, derived and base resolve to the same symbol even in the case of generic classes.
if (derived === base) {
// derived class inherits base without override/redeclaration
var derivedClassDecl = getClassLikeDeclarationOfSymbol(type.symbol);
// It is an error to inherit an abstract member without implementing it or being declared abstract.
// If there is no declaration for the derived class (as in the case of class expressions),
// then the class cannot be declared abstract.
if (baseDeclarationFlags & 128 /* Abstract */ && (!derivedClassDecl || !(ts.getModifierFlags(derivedClassDecl) & 128 /* Abstract */))) {
if (derivedClassDecl.kind === 197 /* ClassExpression */) {
error(derivedClassDecl, ts.Diagnostics.Non_abstract_class_expression_does_not_implement_inherited_abstract_member_0_from_class_1, symbolToString(baseProperty), typeToString(baseType));
}
else {
error(derivedClassDecl, ts.Diagnostics.Non_abstract_class_0_does_not_implement_inherited_abstract_member_1_from_class_2, typeToString(type), symbolToString(baseProperty), typeToString(baseType));
}
}
}
else {
// derived overrides base.
var derivedDeclarationFlags = getDeclarationModifierFlagsFromSymbol(derived);
if ((baseDeclarationFlags & 8 /* Private */) || (derivedDeclarationFlags & 8 /* Private */)) {
// either base or derived property is private - not override, skip it
continue;
}
if ((baseDeclarationFlags & 32 /* Static */) !== (derivedDeclarationFlags & 32 /* Static */)) {
// value of 'static' is not the same for properties - not override, skip it
continue;
}
if ((base.flags & derived.flags & 8192 /* Method */) || ((base.flags & 98308 /* PropertyOrAccessor */) && (derived.flags & 98308 /* PropertyOrAccessor */))) {
// method is overridden with method or property/accessor is overridden with property/accessor - correct case
continue;
}
var errorMessage = void 0;
if (base.flags & 8192 /* Method */) {
if (derived.flags & 98304 /* Accessor */) {
errorMessage = ts.Diagnostics.Class_0_defines_instance_member_function_1_but_extended_class_2_defines_it_as_instance_member_accessor;
}
else {
ts.Debug.assert((derived.flags & 4 /* Property */) !== 0);
errorMessage = ts.Diagnostics.Class_0_defines_instance_member_function_1_but_extended_class_2_defines_it_as_instance_member_property;
}
}
else if (base.flags & 4 /* Property */) {
ts.Debug.assert((derived.flags & 8192 /* Method */) !== 0);
errorMessage = ts.Diagnostics.Class_0_defines_instance_member_property_1_but_extended_class_2_defines_it_as_instance_member_function;
}
else {
ts.Debug.assert((base.flags & 98304 /* Accessor */) !== 0);
ts.Debug.assert((derived.flags & 8192 /* Method */) !== 0);
errorMessage = ts.Diagnostics.Class_0_defines_instance_member_accessor_1_but_extended_class_2_defines_it_as_instance_member_function;
}
error(derived.valueDeclaration.name, errorMessage, typeToString(baseType), symbolToString(base), typeToString(type));
}
}
}
}
function isAccessor(kind) {
return kind === 151 /* GetAccessor */ || kind === 152 /* SetAccessor */;
}
function areTypeParametersIdentical(list1, list2) {
if (!list1 && !list2) {
return true;
}
if (!list1 || !list2 || list1.length !== list2.length) {
return false;
}
// TypeScript 1.0 spec (April 2014):
// When a generic interface has multiple declarations, all declarations must have identical type parameter
// lists, i.e. identical type parameter names with identical constraints in identical order.
for (var i = 0, len = list1.length; i < len; i++) {
var tp1 = list1[i];
var tp2 = list2[i];
if (tp1.name.text !== tp2.name.text) {
return false;
}
if (!tp1.constraint && !tp2.constraint) {
continue;
}
if (!tp1.constraint || !tp2.constraint) {
return false;
}
if (!isTypeIdenticalTo(getTypeFromTypeNode(tp1.constraint), getTypeFromTypeNode(tp2.constraint))) {
return false;
}
}
return true;
}
function checkInheritedPropertiesAreIdentical(type, typeNode) {
var baseTypes = getBaseTypes(type);
if (baseTypes.length < 2) {
return true;
}
var seen = ts.createMap();
ts.forEach(resolveDeclaredMembers(type).declaredProperties, function (p) { seen[p.name] = { prop: p, containingType: type }; });
var ok = true;
for (var _i = 0, baseTypes_2 = baseTypes; _i < baseTypes_2.length; _i++) {
var base = baseTypes_2[_i];
var properties = getPropertiesOfObjectType(getTypeWithThisArgument(base, type.thisType));
for (var _a = 0, properties_6 = properties; _a < properties_6.length; _a++) {
var prop = properties_6[_a];
var existing = seen[prop.name];
if (!existing) {
seen[prop.name] = { prop: prop, containingType: base };
}
else {
var isInheritedProperty = existing.containingType !== type;
if (isInheritedProperty && !isPropertyIdenticalTo(existing.prop, prop)) {
ok = false;
var typeName1 = typeToString(existing.containingType);
var typeName2 = typeToString(base);
var errorInfo = ts.chainDiagnosticMessages(undefined, ts.Diagnostics.Named_property_0_of_types_1_and_2_are_not_identical, symbolToString(prop), typeName1, typeName2);
errorInfo = ts.chainDiagnosticMessages(errorInfo, ts.Diagnostics.Interface_0_cannot_simultaneously_extend_types_1_and_2, typeToString(type), typeName1, typeName2);
diagnostics.add(ts.createDiagnosticForNodeFromMessageChain(typeNode, errorInfo));
}
}
}
}
return ok;
}
function checkInterfaceDeclaration(node) {
// Grammar checking
checkGrammarDecorators(node) || checkGrammarModifiers(node) || checkGrammarInterfaceDeclaration(node);
checkTypeParameters(node.typeParameters);
if (produceDiagnostics) {
checkTypeNameIsReserved(node.name, ts.Diagnostics.Interface_name_cannot_be_0);
checkExportsOnMergedDeclarations(node);
var symbol = getSymbolOfNode(node);
checkTypeParameterListsIdentical(node, symbol);
// Only check this symbol once
var firstInterfaceDecl = ts.getDeclarationOfKind(symbol, 227 /* InterfaceDeclaration */);
if (node === firstInterfaceDecl) {
var type = getDeclaredTypeOfSymbol(symbol);
var typeWithThis = getTypeWithThisArgument(type);
// run subsequent checks only if first set succeeded
if (checkInheritedPropertiesAreIdentical(type, node.name)) {
for (var _i = 0, _a = getBaseTypes(type); _i < _a.length; _i++) {
var baseType = _a[_i];
checkTypeAssignableTo(typeWithThis, getTypeWithThisArgument(baseType, type.thisType), node.name, ts.Diagnostics.Interface_0_incorrectly_extends_interface_1);
}
checkIndexConstraints(type);
}
}
checkObjectTypeForDuplicateDeclarations(node);
}
ts.forEach(ts.getInterfaceBaseTypeNodes(node), function (heritageElement) {
if (!ts.isEntityNameExpression(heritageElement.expression)) {
error(heritageElement.expression, ts.Diagnostics.An_interface_can_only_extend_an_identifier_Slashqualified_name_with_optional_type_arguments);
}
checkTypeReferenceNode(heritageElement);
});
ts.forEach(node.members, checkSourceElement);
if (produceDiagnostics) {
checkTypeForDuplicateIndexSignatures(node);
registerForUnusedIdentifiersCheck(node);
}
}
function checkTypeAliasDeclaration(node) {
// Grammar checking
checkGrammarDecorators(node) || checkGrammarModifiers(node);
checkTypeNameIsReserved(node.name, ts.Diagnostics.Type_alias_name_cannot_be_0);
checkTypeParameters(node.typeParameters);
checkSourceElement(node.type);
}
function computeEnumMemberValues(node) {
var nodeLinks = getNodeLinks(node);
if (!(nodeLinks.flags & 16384 /* EnumValuesComputed */)) {
var enumSymbol = getSymbolOfNode(node);
var enumType = getDeclaredTypeOfSymbol(enumSymbol);
var autoValue = 0; // set to undefined when enum member is non-constant
var ambient = ts.isInAmbientContext(node);
var enumIsConst = ts.isConst(node);
for (var _i = 0, _a = node.members; _i < _a.length; _i++) {
var member = _a[_i];
if (isComputedNonLiteralName(member.name)) {
error(member.name, ts.Diagnostics.Computed_property_names_are_not_allowed_in_enums);
}
else {
var text = ts.getTextOfPropertyName(member.name);
if (isNumericLiteralName(text) && !isInfinityOrNaNString(text)) {
error(member.name, ts.Diagnostics.An_enum_member_cannot_have_a_numeric_name);
}
}
var previousEnumMemberIsNonConstant = autoValue === undefined;
var initializer = member.initializer;
if (initializer) {
autoValue = computeConstantValueForEnumMemberInitializer(initializer, enumType, enumIsConst, ambient);
}
else if (ambient && !enumIsConst) {
// In ambient enum declarations that specify no const modifier, enum member declarations
// that omit a value are considered computed members (as opposed to having auto-incremented values assigned).
autoValue = undefined;
}
else if (previousEnumMemberIsNonConstant) {
// If the member declaration specifies no value, the member is considered a constant enum member.
// If the member is the first member in the enum declaration, it is assigned the value zero.
// Otherwise, it is assigned the value of the immediately preceding member plus one,
// and an error occurs if the immediately preceding member is not a constant enum member
error(member.name, ts.Diagnostics.Enum_member_must_have_initializer);
}
if (autoValue !== undefined) {
getNodeLinks(member).enumMemberValue = autoValue;
autoValue++;
}
}
nodeLinks.flags |= 16384 /* EnumValuesComputed */;
}
function computeConstantValueForEnumMemberInitializer(initializer, enumType, enumIsConst, ambient) {
// Controls if error should be reported after evaluation of constant value is completed
// Can be false if another more precise error was already reported during evaluation.
var reportError = true;
var value = evalConstant(initializer);
if (reportError) {
if (value === undefined) {
if (enumIsConst) {
error(initializer, ts.Diagnostics.In_const_enum_declarations_member_initializer_must_be_constant_expression);
}
else if (ambient) {
error(initializer, ts.Diagnostics.In_ambient_enum_declarations_member_initializer_must_be_constant_expression);
}
else {
// Only here do we need to check that the initializer is assignable to the enum type.
checkTypeAssignableTo(checkExpression(initializer), enumType, initializer, /*headMessage*/ undefined);
}
}
else if (enumIsConst) {
if (isNaN(value)) {
error(initializer, ts.Diagnostics.const_enum_member_initializer_was_evaluated_to_disallowed_value_NaN);
}
else if (!isFinite(value)) {
error(initializer, ts.Diagnostics.const_enum_member_initializer_was_evaluated_to_a_non_finite_value);
}
}
}
return value;
function evalConstant(e) {
switch (e.kind) {
case 190 /* PrefixUnaryExpression */:
var value_1 = evalConstant(e.operand);
if (value_1 === undefined) {
return undefined;
}
switch (e.operator) {
case 36 /* PlusToken */: return value_1;
case 37 /* MinusToken */: return -value_1;
case 51 /* TildeToken */: return ~value_1;
}
return undefined;
case 192 /* BinaryExpression */:
var left = evalConstant(e.left);
if (left === undefined) {
return undefined;
}
var right = evalConstant(e.right);
if (right === undefined) {
return undefined;
}
switch (e.operatorToken.kind) {
case 48 /* BarToken */: return left | right;
case 47 /* AmpersandToken */: return left & right;
case 45 /* GreaterThanGreaterThanToken */: return left >> right;
case 46 /* GreaterThanGreaterThanGreaterThanToken */: return left >>> right;
case 44 /* LessThanLessThanToken */: return left << right;
case 49 /* CaretToken */: return left ^ right;
case 38 /* AsteriskToken */: return left * right;
case 40 /* SlashToken */: return left / right;
case 36 /* PlusToken */: return left + right;
case 37 /* MinusToken */: return left - right;
case 41 /* PercentToken */: return left % right;
}
return undefined;
case 8 /* NumericLiteral */:
return +e.text;
case 183 /* ParenthesizedExpression */:
return evalConstant(e.expression);
case 70 /* Identifier */:
case 178 /* ElementAccessExpression */:
case 177 /* PropertyAccessExpression */:
var member = initializer.parent;
var currentType = getTypeOfSymbol(getSymbolOfNode(member.parent));
var enumType_1;
var propertyName = void 0;
if (e.kind === 70 /* Identifier */) {
// unqualified names can refer to member that reside in different declaration of the enum so just doing name resolution won't work.
// instead pick current enum type and later try to fetch member from the type
enumType_1 = currentType;
propertyName = e.text;
}
else {
var expression = void 0;
if (e.kind === 178 /* ElementAccessExpression */) {
if (e.argumentExpression === undefined ||
e.argumentExpression.kind !== 9 /* StringLiteral */) {
return undefined;
}
expression = e.expression;
propertyName = e.argumentExpression.text;
}
else {
expression = e.expression;
propertyName = e.name.text;
}
// expression part in ElementAccess\PropertyAccess should be either identifier or dottedName
var current = expression;
while (current) {
if (current.kind === 70 /* Identifier */) {
break;
}
else if (current.kind === 177 /* PropertyAccessExpression */) {
current = current.expression;
}
else {
return undefined;
}
}
enumType_1 = checkExpression(expression);
// allow references to constant members of other enums
if (!(enumType_1.symbol && (enumType_1.symbol.flags & 384 /* Enum */))) {
return undefined;
}
}
if (propertyName === undefined) {
return undefined;
}
var property = getPropertyOfObjectType(enumType_1, propertyName);
if (!property || !(property.flags & 8 /* EnumMember */)) {
return undefined;
}
var propertyDecl = property.valueDeclaration;
// self references are illegal
if (member === propertyDecl) {
return undefined;
}
// illegal case: forward reference
if (!isBlockScopedNameDeclaredBeforeUse(propertyDecl, member)) {
reportError = false;
error(e, ts.Diagnostics.A_member_initializer_in_a_enum_declaration_cannot_reference_members_declared_after_it_including_members_defined_in_other_enums);
return undefined;
}
return getNodeLinks(propertyDecl).enumMemberValue;
}
}
}
}
function checkEnumDeclaration(node) {
if (!produceDiagnostics) {
return;
}
// Grammar checking
checkGrammarDecorators(node) || checkGrammarModifiers(node);
checkTypeNameIsReserved(node.name, ts.Diagnostics.Enum_name_cannot_be_0);
checkCollisionWithCapturedThisVariable(node, node.name);
checkCollisionWithRequireExportsInGeneratedCode(node, node.name);
checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name);
checkExportsOnMergedDeclarations(node);
computeEnumMemberValues(node);
var enumIsConst = ts.isConst(node);
if (compilerOptions.isolatedModules && enumIsConst && ts.isInAmbientContext(node)) {
error(node.name, ts.Diagnostics.Ambient_const_enums_are_not_allowed_when_the_isolatedModules_flag_is_provided);
}
// Spec 2014 - Section 9.3:
// It isn't possible for one enum declaration to continue the automatic numbering sequence of another,
// and when an enum type has multiple declarations, only one declaration is permitted to omit a value
// for the first member.
//
// Only perform this check once per symbol
var enumSymbol = getSymbolOfNode(node);
var firstDeclaration = ts.getDeclarationOfKind(enumSymbol, node.kind);
if (node === firstDeclaration) {
if (enumSymbol.declarations.length > 1) {
// check that const is placed\omitted on all enum declarations
ts.forEach(enumSymbol.declarations, function (decl) {
if (ts.isConstEnumDeclaration(decl) !== enumIsConst) {
error(decl.name, ts.Diagnostics.Enum_declarations_must_all_be_const_or_non_const);
}
});
}
var seenEnumMissingInitialInitializer_1 = false;
ts.forEach(enumSymbol.declarations, function (declaration) {
// return true if we hit a violation of the rule, false otherwise
if (declaration.kind !== 229 /* EnumDeclaration */) {
return false;
}
var enumDeclaration = declaration;
if (!enumDeclaration.members.length) {
return false;
}
var firstEnumMember = enumDeclaration.members[0];
if (!firstEnumMember.initializer) {
if (seenEnumMissingInitialInitializer_1) {
error(firstEnumMember.name, ts.Diagnostics.In_an_enum_with_multiple_declarations_only_one_declaration_can_omit_an_initializer_for_its_first_enum_element);
}
else {
seenEnumMissingInitialInitializer_1 = true;
}
}
});
}
}
function getFirstNonAmbientClassOrFunctionDeclaration(symbol) {
var declarations = symbol.declarations;
for (var _i = 0, declarations_5 = declarations; _i < declarations_5.length; _i++) {
var declaration = declarations_5[_i];
if ((declaration.kind === 226 /* ClassDeclaration */ ||
(declaration.kind === 225 /* FunctionDeclaration */ && ts.nodeIsPresent(declaration.body))) &&
!ts.isInAmbientContext(declaration)) {
return declaration;
}
}
return undefined;
}
function inSameLexicalScope(node1, node2) {
var container1 = ts.getEnclosingBlockScopeContainer(node1);
var container2 = ts.getEnclosingBlockScopeContainer(node2);
if (isGlobalSourceFile(container1)) {
return isGlobalSourceFile(container2);
}
else if (isGlobalSourceFile(container2)) {
return false;
}
else {
return container1 === container2;
}
}
function checkModuleDeclaration(node) {
if (produceDiagnostics) {
// Grammar checking
var isGlobalAugmentation = ts.isGlobalScopeAugmentation(node);
var inAmbientContext = ts.isInAmbientContext(node);
if (isGlobalAugmentation && !inAmbientContext) {
error(node.name, ts.Diagnostics.Augmentations_for_the_global_scope_should_have_declare_modifier_unless_they_appear_in_already_ambient_context);
}
var isAmbientExternalModule = ts.isAmbientModule(node);
var contextErrorMessage = isAmbientExternalModule
? ts.Diagnostics.An_ambient_module_declaration_is_only_allowed_at_the_top_level_in_a_file
: ts.Diagnostics.A_namespace_declaration_is_only_allowed_in_a_namespace_or_module;
if (checkGrammarModuleElementContext(node, contextErrorMessage)) {
// If we hit a module declaration in an illegal context, just bail out to avoid cascading errors.
return;
}
if (!checkGrammarDecorators(node) && !checkGrammarModifiers(node)) {
if (!inAmbientContext && node.name.kind === 9 /* StringLiteral */) {
grammarErrorOnNode(node.name, ts.Diagnostics.Only_ambient_modules_can_use_quoted_names);
}
}
if (ts.isIdentifier(node.name)) {
checkCollisionWithCapturedThisVariable(node, node.name);
checkCollisionWithRequireExportsInGeneratedCode(node, node.name);
checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name);
}
checkExportsOnMergedDeclarations(node);
var symbol = getSymbolOfNode(node);
// The following checks only apply on a non-ambient instantiated module declaration.
if (symbol.flags & 512 /* ValueModule */
&& symbol.declarations.length > 1
&& !inAmbientContext
&& ts.isInstantiatedModule(node, compilerOptions.preserveConstEnums || compilerOptions.isolatedModules)) {
var firstNonAmbientClassOrFunc = getFirstNonAmbientClassOrFunctionDeclaration(symbol);
if (firstNonAmbientClassOrFunc) {
if (ts.getSourceFileOfNode(node) !== ts.getSourceFileOfNode(firstNonAmbientClassOrFunc)) {
error(node.name, ts.Diagnostics.A_namespace_declaration_cannot_be_in_a_different_file_from_a_class_or_function_with_which_it_is_merged);
}
else if (node.pos < firstNonAmbientClassOrFunc.pos) {
error(node.name, ts.Diagnostics.A_namespace_declaration_cannot_be_located_prior_to_a_class_or_function_with_which_it_is_merged);
}
}
// if the module merges with a class declaration in the same lexical scope,
// we need to track this to ensure the correct emit.
var mergedClass = ts.getDeclarationOfKind(symbol, 226 /* ClassDeclaration */);
if (mergedClass &&
inSameLexicalScope(node, mergedClass)) {
getNodeLinks(node).flags |= 32768 /* LexicalModuleMergesWithClass */;
}
}
if (isAmbientExternalModule) {
if (ts.isExternalModuleAugmentation(node)) {
// body of the augmentation should be checked for consistency only if augmentation was applied to its target (either global scope or module)
// otherwise we'll be swamped in cascading errors.
// We can detect if augmentation was applied using following rules:
// - augmentation for a global scope is always applied
// - augmentation for some external module is applied if symbol for augmentation is merged (it was combined with target module).
var checkBody = isGlobalAugmentation || (getSymbolOfNode(node).flags & 33554432 /* Merged */);
if (checkBody && node.body) {
// body of ambient external module is always a module block
for (var _i = 0, _a = node.body.statements; _i < _a.length; _i++) {
var statement = _a[_i];
checkModuleAugmentationElement(statement, isGlobalAugmentation);
}
}
}
else if (isGlobalSourceFile(node.parent)) {
if (isGlobalAugmentation) {
error(node.name, ts.Diagnostics.Augmentations_for_the_global_scope_can_only_be_directly_nested_in_external_modules_or_ambient_module_declarations);
}
else if (ts.isExternalModuleNameRelative(node.name.text)) {
error(node.name, ts.Diagnostics.Ambient_module_declaration_cannot_specify_relative_module_name);
}
}
else {
if (isGlobalAugmentation) {
error(node.name, ts.Diagnostics.Augmentations_for_the_global_scope_can_only_be_directly_nested_in_external_modules_or_ambient_module_declarations);
}
else {
// Node is not an augmentation and is not located on the script level.
// This means that this is declaration of ambient module that is located in other module or namespace which is prohibited.
error(node.name, ts.Diagnostics.Ambient_modules_cannot_be_nested_in_other_modules_or_namespaces);
}
}
}
}
if (node.body) {
checkSourceElement(node.body);
if (!ts.isGlobalScopeAugmentation(node)) {
registerForUnusedIdentifiersCheck(node);
}
}
}
function checkModuleAugmentationElement(node, isGlobalAugmentation) {
switch (node.kind) {
case 205 /* VariableStatement */:
// error each individual name in variable statement instead of marking the entire variable statement
for (var _i = 0, _a = node.declarationList.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
checkModuleAugmentationElement(decl, isGlobalAugmentation);
}
break;
case 240 /* ExportAssignment */:
case 241 /* ExportDeclaration */:
grammarErrorOnFirstToken(node, ts.Diagnostics.Exports_and_export_assignments_are_not_permitted_in_module_augmentations);
break;
case 234 /* ImportEqualsDeclaration */:
case 235 /* ImportDeclaration */:
grammarErrorOnFirstToken(node, ts.Diagnostics.Imports_are_not_permitted_in_module_augmentations_Consider_moving_them_to_the_enclosing_external_module);
break;
case 174 /* BindingElement */:
case 223 /* VariableDeclaration */:
var name_26 = node.name;
if (ts.isBindingPattern(name_26)) {
for (var _b = 0, _c = name_26.elements; _b < _c.length; _b++) {
var el = _c[_b];
// mark individual names in binding pattern
checkModuleAugmentationElement(el, isGlobalAugmentation);
}
break;
}
// fallthrough
case 226 /* ClassDeclaration */:
case 229 /* EnumDeclaration */:
case 225 /* FunctionDeclaration */:
case 227 /* InterfaceDeclaration */:
case 230 /* ModuleDeclaration */:
case 228 /* TypeAliasDeclaration */:
if (isGlobalAugmentation) {
return;
}
var symbol = getSymbolOfNode(node);
if (symbol) {
// module augmentations cannot introduce new names on the top level scope of the module
// this is done it two steps
// 1. quick check - if symbol for node is not merged - this is local symbol to this augmentation - report error
// 2. main check - report error if value declaration of the parent symbol is module augmentation)
var reportError = !(symbol.flags & 33554432 /* Merged */);
if (!reportError) {
// symbol should not originate in augmentation
reportError = ts.isExternalModuleAugmentation(symbol.parent.declarations[0]);
}
}
break;
}
}
function getFirstIdentifier(node) {
switch (node.kind) {
case 70 /* Identifier */:
return node;
case 141 /* QualifiedName */:
do {
node = node.left;
} while (node.kind !== 70 /* Identifier */);
return node;
case 177 /* PropertyAccessExpression */:
do {
node = node.expression;
} while (node.kind !== 70 /* Identifier */);
return node;
}
}
function checkExternalImportOrExportDeclaration(node) {
var moduleName = ts.getExternalModuleName(node);
if (!ts.nodeIsMissing(moduleName) && moduleName.kind !== 9 /* StringLiteral */) {
error(moduleName, ts.Diagnostics.String_literal_expected);
return false;
}
var inAmbientExternalModule = node.parent.kind === 231 /* ModuleBlock */ && ts.isAmbientModule(node.parent.parent);
if (node.parent.kind !== 261 /* SourceFile */ && !inAmbientExternalModule) {
error(moduleName, node.kind === 241 /* ExportDeclaration */ ?
ts.Diagnostics.Export_declarations_are_not_permitted_in_a_namespace :
ts.Diagnostics.Import_declarations_in_a_namespace_cannot_reference_a_module);
return false;
}
if (inAmbientExternalModule && ts.isExternalModuleNameRelative(moduleName.text)) {
// we have already reported errors on top level imports\exports in external module augmentations in checkModuleDeclaration
// no need to do this again.
if (!isTopLevelInExternalModuleAugmentation(node)) {
// TypeScript 1.0 spec (April 2013): 12.1.6
// An ExternalImportDeclaration in an AmbientExternalModuleDeclaration may reference
// other external modules only through top - level external module names.
// Relative external module names are not permitted.
error(node, ts.Diagnostics.Import_or_export_declaration_in_an_ambient_module_declaration_cannot_reference_module_through_relative_module_name);
return false;
}
}
return true;
}
function checkAliasSymbol(node) {
var symbol = getSymbolOfNode(node);
var target = resolveAlias(symbol);
if (target !== unknownSymbol) {
// For external modules symbol represent local symbol for an alias.
// This local symbol will merge any other local declarations (excluding other aliases)
// and symbol.flags will contains combined representation for all merged declaration.
// Based on symbol.flags we can compute a set of excluded meanings (meaning that resolved alias should not have,
// otherwise it will conflict with some local declaration). Note that in addition to normal flags we include matching SymbolFlags.Export*
// in order to prevent collisions with declarations that were exported from the current module (they still contribute to local names).
var excludedMeanings = (symbol.flags & (107455 /* Value */ | 1048576 /* ExportValue */) ? 107455 /* Value */ : 0) |
(symbol.flags & 793064 /* Type */ ? 793064 /* Type */ : 0) |
(symbol.flags & 1920 /* Namespace */ ? 1920 /* Namespace */ : 0);
if (target.flags & excludedMeanings) {
var message = node.kind === 243 /* ExportSpecifier */ ?
ts.Diagnostics.Export_declaration_conflicts_with_exported_declaration_of_0 :
ts.Diagnostics.Import_declaration_conflicts_with_local_declaration_of_0;
error(node, message, symbolToString(symbol));
}
}
}
function checkImportBinding(node) {
checkCollisionWithCapturedThisVariable(node, node.name);
checkCollisionWithRequireExportsInGeneratedCode(node, node.name);
checkCollisionWithGlobalPromiseInGeneratedCode(node, node.name);
checkAliasSymbol(node);
}
function checkImportDeclaration(node) {
if (checkGrammarModuleElementContext(node, ts.Diagnostics.An_import_declaration_can_only_be_used_in_a_namespace_or_module)) {
// If we hit an import declaration in an illegal context, just bail out to avoid cascading errors.
return;
}
if (!checkGrammarDecorators(node) && !checkGrammarModifiers(node) && ts.getModifierFlags(node) !== 0) {
grammarErrorOnFirstToken(node, ts.Diagnostics.An_import_declaration_cannot_have_modifiers);
}
if (checkExternalImportOrExportDeclaration(node)) {
var importClause = node.importClause;
if (importClause) {
if (importClause.name) {
checkImportBinding(importClause);
}
if (importClause.namedBindings) {
if (importClause.namedBindings.kind === 237 /* NamespaceImport */) {
checkImportBinding(importClause.namedBindings);
}
else {
ts.forEach(importClause.namedBindings.elements, checkImportBinding);
}
}
}
}
}
function checkImportEqualsDeclaration(node) {
if (checkGrammarModuleElementContext(node, ts.Diagnostics.An_import_declaration_can_only_be_used_in_a_namespace_or_module)) {
// If we hit an import declaration in an illegal context, just bail out to avoid cascading errors.
return;
}
checkGrammarDecorators(node) || checkGrammarModifiers(node);
if (ts.isInternalModuleImportEqualsDeclaration(node) || checkExternalImportOrExportDeclaration(node)) {
checkImportBinding(node);
if (ts.getModifierFlags(node) & 1 /* Export */) {
markExportAsReferenced(node);
}
if (ts.isInternalModuleImportEqualsDeclaration(node)) {
var target = resolveAlias(getSymbolOfNode(node));
if (target !== unknownSymbol) {
if (target.flags & 107455 /* Value */) {
// Target is a value symbol, check that it is not hidden by a local declaration with the same name
var moduleName = getFirstIdentifier(node.moduleReference);
if (!(resolveEntityName(moduleName, 107455 /* Value */ | 1920 /* Namespace */).flags & 1920 /* Namespace */)) {
error(moduleName, ts.Diagnostics.Module_0_is_hidden_by_a_local_declaration_with_the_same_name, ts.declarationNameToString(moduleName));
}
}
if (target.flags & 793064 /* Type */) {
checkTypeNameIsReserved(node.name, ts.Diagnostics.Import_name_cannot_be_0);
}
}
}
else {
if (modulekind === ts.ModuleKind.ES2015 && !ts.isInAmbientContext(node)) {
// Import equals declaration is deprecated in es6 or above
grammarErrorOnNode(node, ts.Diagnostics.Import_assignment_cannot_be_used_when_targeting_ECMAScript_2015_modules_Consider_using_import_Asterisk_as_ns_from_mod_import_a_from_mod_import_d_from_mod_or_another_module_format_instead);
}
}
}
}
function checkExportDeclaration(node) {
if (checkGrammarModuleElementContext(node, ts.Diagnostics.An_export_declaration_can_only_be_used_in_a_module)) {
// If we hit an export in an illegal context, just bail out to avoid cascading errors.
return;
}
if (!checkGrammarDecorators(node) && !checkGrammarModifiers(node) && ts.getModifierFlags(node) !== 0) {
grammarErrorOnFirstToken(node, ts.Diagnostics.An_export_declaration_cannot_have_modifiers);
}
if (!node.moduleSpecifier || checkExternalImportOrExportDeclaration(node)) {
if (node.exportClause) {
// export { x, y }
// export { x, y } from "foo"
ts.forEach(node.exportClause.elements, checkExportSpecifier);
var inAmbientExternalModule = node.parent.kind === 231 /* ModuleBlock */ && ts.isAmbientModule(node.parent.parent);
if (node.parent.kind !== 261 /* SourceFile */ && !inAmbientExternalModule) {
error(node, ts.Diagnostics.Export_declarations_are_not_permitted_in_a_namespace);
}
}
else {
// export * from "foo"
var moduleSymbol = resolveExternalModuleName(node, node.moduleSpecifier);
if (moduleSymbol && hasExportAssignmentSymbol(moduleSymbol)) {
error(node.moduleSpecifier, ts.Diagnostics.Module_0_uses_export_and_cannot_be_used_with_export_Asterisk, symbolToString(moduleSymbol));
}
}
}
}
function checkGrammarModuleElementContext(node, errorMessage) {
var isInAppropriateContext = node.parent.kind === 261 /* SourceFile */ || node.parent.kind === 231 /* ModuleBlock */ || node.parent.kind === 230 /* ModuleDeclaration */;
if (!isInAppropriateContext) {
grammarErrorOnFirstToken(node, errorMessage);
}
return !isInAppropriateContext;
}
function checkExportSpecifier(node) {
checkAliasSymbol(node);
if (!node.parent.parent.moduleSpecifier) {
var exportedName = node.propertyName || node.name;
// find immediate value referenced by exported name (SymbolFlags.Alias is set so we don't chase down aliases)
var symbol = resolveName(exportedName, exportedName.text, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */ | 8388608 /* Alias */,
/*nameNotFoundMessage*/ undefined, /*nameArg*/ undefined);
if (symbol && (symbol === undefinedSymbol || isGlobalSourceFile(getDeclarationContainer(symbol.declarations[0])))) {
error(exportedName, ts.Diagnostics.Cannot_export_0_Only_local_declarations_can_be_exported_from_a_module, exportedName.text);
}
else {
markExportAsReferenced(node);
}
}
}
function checkExportAssignment(node) {
if (checkGrammarModuleElementContext(node, ts.Diagnostics.An_export_assignment_can_only_be_used_in_a_module)) {
// If we hit an export assignment in an illegal context, just bail out to avoid cascading errors.
return;
}
var container = node.parent.kind === 261 /* SourceFile */ ? node.parent : node.parent.parent;
if (container.kind === 230 /* ModuleDeclaration */ && !ts.isAmbientModule(container)) {
error(node, ts.Diagnostics.An_export_assignment_cannot_be_used_in_a_namespace);
return;
}
// Grammar checking
if (!checkGrammarDecorators(node) && !checkGrammarModifiers(node) && ts.getModifierFlags(node) !== 0) {
grammarErrorOnFirstToken(node, ts.Diagnostics.An_export_assignment_cannot_have_modifiers);
}
if (node.expression.kind === 70 /* Identifier */) {
markExportAsReferenced(node);
}
else {
checkExpressionCached(node.expression);
}
checkExternalModuleExports(container);
if (node.isExportEquals && !ts.isInAmbientContext(node)) {
if (modulekind === ts.ModuleKind.ES2015) {
// export assignment is not supported in es6 modules
grammarErrorOnNode(node, ts.Diagnostics.Export_assignment_cannot_be_used_when_targeting_ECMAScript_2015_modules_Consider_using_export_default_or_another_module_format_instead);
}
else if (modulekind === ts.ModuleKind.System) {
// system modules does not support export assignment
grammarErrorOnNode(node, ts.Diagnostics.Export_assignment_is_not_supported_when_module_flag_is_system);
}
}
}
function hasExportedMembers(moduleSymbol) {
for (var id in moduleSymbol.exports) {
if (id !== "export=") {
return true;
}
}
return false;
}
function checkExternalModuleExports(node) {
var moduleSymbol = getSymbolOfNode(node);
var links = getSymbolLinks(moduleSymbol);
if (!links.exportsChecked) {
var exportEqualsSymbol = moduleSymbol.exports["export="];
if (exportEqualsSymbol && hasExportedMembers(moduleSymbol)) {
var declaration = getDeclarationOfAliasSymbol(exportEqualsSymbol) || exportEqualsSymbol.valueDeclaration;
if (!isTopLevelInExternalModuleAugmentation(declaration)) {
error(declaration, ts.Diagnostics.An_export_assignment_cannot_be_used_in_a_module_with_other_exported_elements);
}
}
// Checks for export * conflicts
var exports = getExportsOfModule(moduleSymbol);
for (var id in exports) {
if (id === "__export") {
continue;
}
var _a = exports[id], declarations = _a.declarations, flags = _a.flags;
// ECMA262: 15.2.1.1 It is a Syntax Error if the ExportedNames of ModuleItemList contains any duplicate entries.
// (TS Exceptions: namespaces, function overloads, enums, and interfaces)
if (flags & (1920 /* Namespace */ | 64 /* Interface */ | 384 /* Enum */)) {
continue;
}
var exportedDeclarationsCount = ts.countWhere(declarations, isNotOverload);
if (flags & 524288 /* TypeAlias */ && exportedDeclarationsCount <= 2) {
// it is legal to merge type alias with other values
// so count should be either 1 (just type alias) or 2 (type alias + merged value)
continue;
}
if (exportedDeclarationsCount > 1) {
for (var _i = 0, declarations_6 = declarations; _i < declarations_6.length; _i++) {
var declaration = declarations_6[_i];
if (isNotOverload(declaration)) {
diagnostics.add(ts.createDiagnosticForNode(declaration, ts.Diagnostics.Cannot_redeclare_exported_variable_0, id));
}
}
}
}
links.exportsChecked = true;
}
function isNotOverload(declaration) {
return (declaration.kind !== 225 /* FunctionDeclaration */ && declaration.kind !== 149 /* MethodDeclaration */) ||
!!declaration.body;
}
}
function checkSourceElement(node) {
if (!node) {
return;
}
var kind = node.kind;
if (cancellationToken) {
// Only bother checking on a few construct kinds. We don't want to be excessively
// hitting the cancellation token on every node we check.
switch (kind) {
case 230 /* ModuleDeclaration */:
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 225 /* FunctionDeclaration */:
cancellationToken.throwIfCancellationRequested();
}
}
switch (kind) {
case 143 /* TypeParameter */:
return checkTypeParameter(node);
case 144 /* Parameter */:
return checkParameter(node);
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
return checkPropertyDeclaration(node);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
return checkSignatureDeclaration(node);
case 155 /* IndexSignature */:
return checkSignatureDeclaration(node);
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
return checkMethodDeclaration(node);
case 150 /* Constructor */:
return checkConstructorDeclaration(node);
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return checkAccessorDeclaration(node);
case 157 /* TypeReference */:
return checkTypeReferenceNode(node);
case 156 /* TypePredicate */:
return checkTypePredicate(node);
case 160 /* TypeQuery */:
return checkTypeQuery(node);
case 161 /* TypeLiteral */:
return checkTypeLiteral(node);
case 162 /* ArrayType */:
return checkArrayType(node);
case 163 /* TupleType */:
return checkTupleType(node);
case 164 /* UnionType */:
case 165 /* IntersectionType */:
return checkUnionOrIntersectionType(node);
case 166 /* ParenthesizedType */:
case 168 /* TypeOperator */:
return checkSourceElement(node.type);
case 169 /* IndexedAccessType */:
return checkIndexedAccessType(node);
case 170 /* MappedType */:
return checkMappedType(node);
case 225 /* FunctionDeclaration */:
return checkFunctionDeclaration(node);
case 204 /* Block */:
case 231 /* ModuleBlock */:
return checkBlock(node);
case 205 /* VariableStatement */:
return checkVariableStatement(node);
case 207 /* ExpressionStatement */:
return checkExpressionStatement(node);
case 208 /* IfStatement */:
return checkIfStatement(node);
case 209 /* DoStatement */:
return checkDoStatement(node);
case 210 /* WhileStatement */:
return checkWhileStatement(node);
case 211 /* ForStatement */:
return checkForStatement(node);
case 212 /* ForInStatement */:
return checkForInStatement(node);
case 213 /* ForOfStatement */:
return checkForOfStatement(node);
case 214 /* ContinueStatement */:
case 215 /* BreakStatement */:
return checkBreakOrContinueStatement(node);
case 216 /* ReturnStatement */:
return checkReturnStatement(node);
case 217 /* WithStatement */:
return checkWithStatement(node);
case 218 /* SwitchStatement */:
return checkSwitchStatement(node);
case 219 /* LabeledStatement */:
return checkLabeledStatement(node);
case 220 /* ThrowStatement */:
return checkThrowStatement(node);
case 221 /* TryStatement */:
return checkTryStatement(node);
case 223 /* VariableDeclaration */:
return checkVariableDeclaration(node);
case 174 /* BindingElement */:
return checkBindingElement(node);
case 226 /* ClassDeclaration */:
return checkClassDeclaration(node);
case 227 /* InterfaceDeclaration */:
return checkInterfaceDeclaration(node);
case 228 /* TypeAliasDeclaration */:
return checkTypeAliasDeclaration(node);
case 229 /* EnumDeclaration */:
return checkEnumDeclaration(node);
case 230 /* ModuleDeclaration */:
return checkModuleDeclaration(node);
case 235 /* ImportDeclaration */:
return checkImportDeclaration(node);
case 234 /* ImportEqualsDeclaration */:
return checkImportEqualsDeclaration(node);
case 241 /* ExportDeclaration */:
return checkExportDeclaration(node);
case 240 /* ExportAssignment */:
return checkExportAssignment(node);
case 206 /* EmptyStatement */:
checkGrammarStatementInAmbientContext(node);
return;
case 222 /* DebuggerStatement */:
checkGrammarStatementInAmbientContext(node);
return;
case 244 /* MissingDeclaration */:
return checkMissingDeclaration(node);
}
}
// Function and class expression bodies are checked after all statements in the enclosing body. This is
// to ensure constructs like the following are permitted:
// const foo = function () {
// const s = foo();
// return "hello";
// }
// Here, performing a full type check of the body of the function expression whilst in the process of
// determining the type of foo would cause foo to be given type any because of the recursive reference.
// Delaying the type check of the body ensures foo has been assigned a type.
function checkNodeDeferred(node) {
if (deferredNodes) {
deferredNodes.push(node);
}
}
function checkDeferredNodes() {
for (var _i = 0, deferredNodes_1 = deferredNodes; _i < deferredNodes_1.length; _i++) {
var node = deferredNodes_1[_i];
switch (node.kind) {
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
checkFunctionExpressionOrObjectLiteralMethodDeferred(node);
break;
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
checkAccessorDeferred(node);
break;
case 197 /* ClassExpression */:
checkClassExpressionDeferred(node);
break;
}
}
}
function checkSourceFile(node) {
ts.performance.mark("beforeCheck");
checkSourceFileWorker(node);
ts.performance.mark("afterCheck");
ts.performance.measure("Check", "beforeCheck", "afterCheck");
}
// Fully type check a source file and collect the relevant diagnostics.
function checkSourceFileWorker(node) {
var links = getNodeLinks(node);
if (!(links.flags & 1 /* TypeChecked */)) {
// If skipLibCheck is enabled, skip type checking if file is a declaration file.
// If skipDefaultLibCheck is enabled, skip type checking if file contains a
// '/// <reference no-default-lib="true"/>' directive.
if (compilerOptions.skipLibCheck && node.isDeclarationFile || compilerOptions.skipDefaultLibCheck && node.hasNoDefaultLib) {
return;
}
// Grammar checking
checkGrammarSourceFile(node);
potentialThisCollisions.length = 0;
deferredNodes = [];
deferredUnusedIdentifierNodes = produceDiagnostics && noUnusedIdentifiers ? [] : undefined;
ts.forEach(node.statements, checkSourceElement);
checkDeferredNodes();
if (ts.isExternalModule(node)) {
registerForUnusedIdentifiersCheck(node);
}
if (!node.isDeclarationFile) {
checkUnusedIdentifiers();
}
deferredNodes = undefined;
deferredUnusedIdentifierNodes = undefined;
if (ts.isExternalOrCommonJsModule(node)) {
checkExternalModuleExports(node);
}
if (potentialThisCollisions.length) {
ts.forEach(potentialThisCollisions, checkIfThisIsCapturedInEnclosingScope);
potentialThisCollisions.length = 0;
}
links.flags |= 1 /* TypeChecked */;
}
}
function getDiagnostics(sourceFile, ct) {
try {
// Record the cancellation token so it can be checked later on during checkSourceElement.
// Do this in a finally block so we can ensure that it gets reset back to nothing after
// this call is done.
cancellationToken = ct;
return getDiagnosticsWorker(sourceFile);
}
finally {
cancellationToken = undefined;
}
}
function getDiagnosticsWorker(sourceFile) {
throwIfNonDiagnosticsProducing();
if (sourceFile) {
// Some global diagnostics are deferred until they are needed and
// may not be reported in the firt call to getGlobalDiagnostics.
// We should catch these changes and report them.
var previousGlobalDiagnostics = diagnostics.getGlobalDiagnostics();
var previousGlobalDiagnosticsSize = previousGlobalDiagnostics.length;
checkSourceFile(sourceFile);
var semanticDiagnostics = diagnostics.getDiagnostics(sourceFile.fileName);
var currentGlobalDiagnostics = diagnostics.getGlobalDiagnostics();
if (currentGlobalDiagnostics !== previousGlobalDiagnostics) {
// If the arrays are not the same reference, new diagnostics were added.
var deferredGlobalDiagnostics = ts.relativeComplement(previousGlobalDiagnostics, currentGlobalDiagnostics, ts.compareDiagnostics);
return ts.concatenate(deferredGlobalDiagnostics, semanticDiagnostics);
}
else if (previousGlobalDiagnosticsSize === 0 && currentGlobalDiagnostics.length > 0) {
// If the arrays are the same reference, but the length has changed, a single
// new diagnostic was added as DiagnosticCollection attempts to reuse the
// same array.
return ts.concatenate(currentGlobalDiagnostics, semanticDiagnostics);
}
return semanticDiagnostics;
}
// Global diagnostics are always added when a file is not provided to
// getDiagnostics
ts.forEach(host.getSourceFiles(), checkSourceFile);
return diagnostics.getDiagnostics();
}
function getGlobalDiagnostics() {
throwIfNonDiagnosticsProducing();
return diagnostics.getGlobalDiagnostics();
}
function throwIfNonDiagnosticsProducing() {
if (!produceDiagnostics) {
throw new Error("Trying to get diagnostics from a type checker that does not produce them.");
}
}
// Language service support
function isInsideWithStatementBody(node) {
if (node) {
while (node.parent) {
if (node.parent.kind === 217 /* WithStatement */ && node.parent.statement === node) {
return true;
}
node = node.parent;
}
}
return false;
}
function getSymbolsInScope(location, meaning) {
var symbols = ts.createMap();
var memberFlags = 0 /* None */;
if (isInsideWithStatementBody(location)) {
// We cannot answer semantic questions within a with block, do not proceed any further
return [];
}
populateSymbols();
return symbolsToArray(symbols);
function populateSymbols() {
while (location) {
if (location.locals && !isGlobalSourceFile(location)) {
copySymbols(location.locals, meaning);
}
switch (location.kind) {
case 261 /* SourceFile */:
if (!ts.isExternalOrCommonJsModule(location)) {
break;
}
case 230 /* ModuleDeclaration */:
copySymbols(getSymbolOfNode(location).exports, meaning & 8914931 /* ModuleMember */);
break;
case 229 /* EnumDeclaration */:
copySymbols(getSymbolOfNode(location).exports, meaning & 8 /* EnumMember */);
break;
case 197 /* ClassExpression */:
var className = location.name;
if (className) {
copySymbol(location.symbol, meaning);
}
// fall through; this fall-through is necessary because we would like to handle
// type parameter inside class expression similar to how we handle it in classDeclaration and interface Declaration
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
// If we didn't come from static member of class or interface,
// add the type parameters into the symbol table
// (type parameters of classDeclaration/classExpression and interface are in member property of the symbol.
// Note: that the memberFlags come from previous iteration.
if (!(memberFlags & 32 /* Static */)) {
copySymbols(getSymbolOfNode(location).members, meaning & 793064 /* Type */);
}
break;
case 184 /* FunctionExpression */:
var funcName = location.name;
if (funcName) {
copySymbol(location.symbol, meaning);
}
break;
}
if (ts.introducesArgumentsExoticObject(location)) {
copySymbol(argumentsSymbol, meaning);
}
memberFlags = ts.getModifierFlags(location);
location = location.parent;
}
copySymbols(globals, meaning);
}
/**
* Copy the given symbol into symbol tables if the symbol has the given meaning
* and it doesn't already existed in the symbol table
* @param key a key for storing in symbol table; if undefined, use symbol.name
* @param symbol the symbol to be added into symbol table
* @param meaning meaning of symbol to filter by before adding to symbol table
*/
function copySymbol(symbol, meaning) {
if (symbol.flags & meaning) {
var id = symbol.name;
// We will copy all symbol regardless of its reserved name because
// symbolsToArray will check whether the key is a reserved name and
// it will not copy symbol with reserved name to the array
if (!symbols[id]) {
symbols[id] = symbol;
}
}
}
function copySymbols(source, meaning) {
if (meaning) {
for (var id in source) {
var symbol = source[id];
copySymbol(symbol, meaning);
}
}
}
}
function isTypeDeclarationName(name) {
return name.kind === 70 /* Identifier */ &&
isTypeDeclaration(name.parent) &&
name.parent.name === name;
}
function isTypeDeclaration(node) {
switch (node.kind) {
case 143 /* TypeParameter */:
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 229 /* EnumDeclaration */:
return true;
}
}
// True if the given identifier is part of a type reference
function isTypeReferenceIdentifier(entityName) {
var node = entityName;
while (node.parent && node.parent.kind === 141 /* QualifiedName */) {
node = node.parent;
}
return node.parent && (node.parent.kind === 157 /* TypeReference */ || node.parent.kind === 272 /* JSDocTypeReference */);
}
function isHeritageClauseElementIdentifier(entityName) {
var node = entityName;
while (node.parent && node.parent.kind === 177 /* PropertyAccessExpression */) {
node = node.parent;
}
return node.parent && node.parent.kind === 199 /* ExpressionWithTypeArguments */;
}
function forEachEnclosingClass(node, callback) {
var result;
while (true) {
node = ts.getContainingClass(node);
if (!node)
break;
if (result = callback(node))
break;
}
return result;
}
function isNodeWithinClass(node, classDeclaration) {
return !!forEachEnclosingClass(node, function (n) { return n === classDeclaration; });
}
function getLeftSideOfImportEqualsOrExportAssignment(nodeOnRightSide) {
while (nodeOnRightSide.parent.kind === 141 /* QualifiedName */) {
nodeOnRightSide = nodeOnRightSide.parent;
}
if (nodeOnRightSide.parent.kind === 234 /* ImportEqualsDeclaration */) {
return nodeOnRightSide.parent.moduleReference === nodeOnRightSide && nodeOnRightSide.parent;
}
if (nodeOnRightSide.parent.kind === 240 /* ExportAssignment */) {
return nodeOnRightSide.parent.expression === nodeOnRightSide && nodeOnRightSide.parent;
}
return undefined;
}
function isInRightSideOfImportOrExportAssignment(node) {
return getLeftSideOfImportEqualsOrExportAssignment(node) !== undefined;
}
function getSymbolOfEntityNameOrPropertyAccessExpression(entityName) {
if (ts.isDeclarationName(entityName)) {
return getSymbolOfNode(entityName.parent);
}
if (ts.isInJavaScriptFile(entityName) && entityName.parent.kind === 177 /* PropertyAccessExpression */) {
var specialPropertyAssignmentKind = ts.getSpecialPropertyAssignmentKind(entityName.parent.parent);
switch (specialPropertyAssignmentKind) {
case 1 /* ExportsProperty */:
case 3 /* PrototypeProperty */:
return getSymbolOfNode(entityName.parent);
case 4 /* ThisProperty */:
case 2 /* ModuleExports */:
return getSymbolOfNode(entityName.parent.parent);
default:
}
}
if (entityName.parent.kind === 240 /* ExportAssignment */ && ts.isEntityNameExpression(entityName)) {
return resolveEntityName(entityName,
/*all meanings*/ 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */ | 8388608 /* Alias */);
}
if (entityName.kind !== 177 /* PropertyAccessExpression */ && isInRightSideOfImportOrExportAssignment(entityName)) {
// Since we already checked for ExportAssignment, this really could only be an Import
var importEqualsDeclaration = ts.getAncestor(entityName, 234 /* ImportEqualsDeclaration */);
ts.Debug.assert(importEqualsDeclaration !== undefined);
return getSymbolOfPartOfRightHandSideOfImportEquals(entityName, /*dontResolveAlias*/ true);
}
if (ts.isRightSideOfQualifiedNameOrPropertyAccess(entityName)) {
entityName = entityName.parent;
}
if (isHeritageClauseElementIdentifier(entityName)) {
var meaning = 0 /* None */;
// In an interface or class, we're definitely interested in a type.
if (entityName.parent.kind === 199 /* ExpressionWithTypeArguments */) {
meaning = 793064 /* Type */;
// In a class 'extends' clause we are also looking for a value.
if (ts.isExpressionWithTypeArgumentsInClassExtendsClause(entityName.parent)) {
meaning |= 107455 /* Value */;
}
}
else {
meaning = 1920 /* Namespace */;
}
meaning |= 8388608 /* Alias */;
return resolveEntityName(entityName, meaning);
}
else if (ts.isPartOfExpression(entityName)) {
if (ts.nodeIsMissing(entityName)) {
// Missing entity name.
return undefined;
}
if (entityName.kind === 70 /* Identifier */) {
if (ts.isJSXTagName(entityName) && isJsxIntrinsicIdentifier(entityName)) {
return getIntrinsicTagSymbol(entityName.parent);
}
return resolveEntityName(entityName, 107455 /* Value */, /*ignoreErrors*/ false, /*dontResolveAlias*/ true);
}
else if (entityName.kind === 177 /* PropertyAccessExpression */) {
var symbol = getNodeLinks(entityName).resolvedSymbol;
if (!symbol) {
checkPropertyAccessExpression(entityName);
}
return getNodeLinks(entityName).resolvedSymbol;
}
else if (entityName.kind === 141 /* QualifiedName */) {
var symbol = getNodeLinks(entityName).resolvedSymbol;
if (!symbol) {
checkQualifiedName(entityName);
}
return getNodeLinks(entityName).resolvedSymbol;
}
}
else if (isTypeReferenceIdentifier(entityName)) {
var meaning = (entityName.parent.kind === 157 /* TypeReference */ || entityName.parent.kind === 272 /* JSDocTypeReference */) ? 793064 /* Type */ : 1920 /* Namespace */;
return resolveEntityName(entityName, meaning, /*ignoreErrors*/ false, /*dontResolveAlias*/ true);
}
else if (entityName.parent.kind === 250 /* JsxAttribute */) {
return getJsxAttributePropertySymbol(entityName.parent);
}
if (entityName.parent.kind === 156 /* TypePredicate */) {
return resolveEntityName(entityName, /*meaning*/ 1 /* FunctionScopedVariable */);
}
// Do we want to return undefined here?
return undefined;
}
function getSymbolAtLocation(node) {
if (node.kind === 261 /* SourceFile */) {
return ts.isExternalModule(node) ? getMergedSymbol(node.symbol) : undefined;
}
if (isInsideWithStatementBody(node)) {
// We cannot answer semantic questions within a with block, do not proceed any further
return undefined;
}
if (ts.isDeclarationName(node)) {
// This is a declaration, call getSymbolOfNode
return getSymbolOfNode(node.parent);
}
else if (ts.isLiteralComputedPropertyDeclarationName(node)) {
return getSymbolOfNode(node.parent.parent);
}
if (node.kind === 70 /* Identifier */) {
if (isInRightSideOfImportOrExportAssignment(node)) {
return getSymbolOfEntityNameOrPropertyAccessExpression(node);
}
else if (node.parent.kind === 174 /* BindingElement */ &&
node.parent.parent.kind === 172 /* ObjectBindingPattern */ &&
node === node.parent.propertyName) {
var typeOfPattern = getTypeOfNode(node.parent.parent);
var propertyDeclaration = typeOfPattern && getPropertyOfType(typeOfPattern, node.text);
if (propertyDeclaration) {
return propertyDeclaration;
}
}
}
switch (node.kind) {
case 70 /* Identifier */:
case 177 /* PropertyAccessExpression */:
case 141 /* QualifiedName */:
return getSymbolOfEntityNameOrPropertyAccessExpression(node);
case 98 /* ThisKeyword */:
var container = ts.getThisContainer(node, /*includeArrowFunctions*/ false);
if (ts.isFunctionLike(container)) {
var sig = getSignatureFromDeclaration(container);
if (sig.thisParameter) {
return sig.thisParameter;
}
}
// fallthrough
case 96 /* SuperKeyword */:
var type = ts.isPartOfExpression(node) ? checkExpression(node) : getTypeFromTypeNode(node);
return type.symbol;
case 167 /* ThisType */:
return getTypeFromTypeNode(node).symbol;
case 122 /* ConstructorKeyword */:
// constructor keyword for an overload, should take us to the definition if it exist
var constructorDeclaration = node.parent;
if (constructorDeclaration && constructorDeclaration.kind === 150 /* Constructor */) {
return constructorDeclaration.parent.symbol;
}
return undefined;
case 9 /* StringLiteral */:
// External module name in an import declaration
if ((ts.isExternalModuleImportEqualsDeclaration(node.parent.parent) &&
ts.getExternalModuleImportEqualsDeclarationExpression(node.parent.parent) === node) ||
((node.parent.kind === 235 /* ImportDeclaration */ || node.parent.kind === 241 /* ExportDeclaration */) &&
node.parent.moduleSpecifier === node)) {
return resolveExternalModuleName(node, node);
}
if (ts.isInJavaScriptFile(node) && ts.isRequireCall(node.parent, /*checkArgumentIsStringLiteral*/ false)) {
return resolveExternalModuleName(node, node);
}
// Fall through
case 8 /* NumericLiteral */:
// index access
if (node.parent.kind === 178 /* ElementAccessExpression */ && node.parent.argumentExpression === node) {
var objectType = checkExpression(node.parent.expression);
if (objectType === unknownType)
return undefined;
var apparentType = getApparentType(objectType);
if (apparentType === unknownType)
return undefined;
return getPropertyOfType(apparentType, node.text);
}
break;
}
return undefined;
}
function getShorthandAssignmentValueSymbol(location) {
// The function returns a value symbol of an identifier in the short-hand property assignment.
// This is necessary as an identifier in short-hand property assignment can contains two meaning:
// property name and property value.
if (location && location.kind === 258 /* ShorthandPropertyAssignment */) {
return resolveEntityName(location.name, 107455 /* Value */ | 8388608 /* Alias */);
}
return undefined;
}
/** Returns the target of an export specifier without following aliases */
function getExportSpecifierLocalTargetSymbol(node) {
return node.parent.parent.moduleSpecifier ?
getExternalModuleMember(node.parent.parent, node) :
resolveEntityName(node.propertyName || node.name, 107455 /* Value */ | 793064 /* Type */ | 1920 /* Namespace */ | 8388608 /* Alias */);
}
function getTypeOfNode(node) {
if (isInsideWithStatementBody(node)) {
// We cannot answer semantic questions within a with block, do not proceed any further
return unknownType;
}
if (ts.isPartOfTypeNode(node)) {
return getTypeFromTypeNode(node);
}
if (ts.isPartOfExpression(node)) {
return getTypeOfExpression(node);
}
if (ts.isExpressionWithTypeArgumentsInClassExtendsClause(node)) {
// A SyntaxKind.ExpressionWithTypeArguments is considered a type node, except when it occurs in the
// extends clause of a class. We handle that case here.
return getBaseTypes(getDeclaredTypeOfSymbol(getSymbolOfNode(node.parent.parent)))[0];
}
if (isTypeDeclaration(node)) {
// In this case, we call getSymbolOfNode instead of getSymbolAtLocation because it is a declaration
var symbol = getSymbolOfNode(node);
return getDeclaredTypeOfSymbol(symbol);
}
if (isTypeDeclarationName(node)) {
var symbol = getSymbolAtLocation(node);
return symbol && getDeclaredTypeOfSymbol(symbol);
}
if (ts.isDeclaration(node)) {
// In this case, we call getSymbolOfNode instead of getSymbolAtLocation because it is a declaration
var symbol = getSymbolOfNode(node);
return getTypeOfSymbol(symbol);
}
if (ts.isDeclarationName(node)) {
var symbol = getSymbolAtLocation(node);
return symbol && getTypeOfSymbol(symbol);
}
if (ts.isBindingPattern(node)) {
return getTypeForVariableLikeDeclaration(node.parent, /*includeOptionality*/ true);
}
if (isInRightSideOfImportOrExportAssignment(node)) {
var symbol = getSymbolAtLocation(node);
var declaredType = symbol && getDeclaredTypeOfSymbol(symbol);
return declaredType !== unknownType ? declaredType : getTypeOfSymbol(symbol);
}
return unknownType;
}
// Gets the type of object literal or array literal of destructuring assignment.
// { a } from
// for ( { a } of elems) {
// }
// [ a ] from
// [a] = [ some array ...]
function getTypeOfArrayLiteralOrObjectLiteralDestructuringAssignment(expr) {
ts.Debug.assert(expr.kind === 176 /* ObjectLiteralExpression */ || expr.kind === 175 /* ArrayLiteralExpression */);
// If this is from "for of"
// for ( { a } of elems) {
// }
if (expr.parent.kind === 213 /* ForOfStatement */) {
var iteratedType = checkRightHandSideOfForOf(expr.parent.expression);
return checkDestructuringAssignment(expr, iteratedType || unknownType);
}
// If this is from "for" initializer
// for ({a } = elems[0];.....) { }
if (expr.parent.kind === 192 /* BinaryExpression */) {
var iteratedType = checkExpression(expr.parent.right);
return checkDestructuringAssignment(expr, iteratedType || unknownType);
}
// If this is from nested object binding pattern
// for ({ skills: { primary, secondary } } = multiRobot, i = 0; i < 1; i++) {
if (expr.parent.kind === 257 /* PropertyAssignment */) {
var typeOfParentObjectLiteral = getTypeOfArrayLiteralOrObjectLiteralDestructuringAssignment(expr.parent.parent);
return checkObjectLiteralDestructuringPropertyAssignment(typeOfParentObjectLiteral || unknownType, expr.parent);
}
// Array literal assignment - array destructuring pattern
ts.Debug.assert(expr.parent.kind === 175 /* ArrayLiteralExpression */);
// [{ property1: p1, property2 }] = elems;
var typeOfArrayLiteral = getTypeOfArrayLiteralOrObjectLiteralDestructuringAssignment(expr.parent);
var elementType = checkIteratedTypeOrElementType(typeOfArrayLiteral || unknownType, expr.parent, /*allowStringInput*/ false) || unknownType;
return checkArrayLiteralDestructuringElementAssignment(expr.parent, typeOfArrayLiteral, ts.indexOf(expr.parent.elements, expr), elementType || unknownType);
}
// Gets the property symbol corresponding to the property in destructuring assignment
// 'property1' from
// for ( { property1: a } of elems) {
// }
// 'property1' at location 'a' from:
// [a] = [ property1, property2 ]
function getPropertySymbolOfDestructuringAssignment(location) {
// Get the type of the object or array literal and then look for property of given name in the type
var typeOfObjectLiteral = getTypeOfArrayLiteralOrObjectLiteralDestructuringAssignment(location.parent.parent);
return typeOfObjectLiteral && getPropertyOfType(typeOfObjectLiteral, location.text);
}
function getTypeOfExpression(expr) {
if (ts.isRightSideOfQualifiedNameOrPropertyAccess(expr)) {
expr = expr.parent;
}
return getRegularTypeOfLiteralType(checkExpression(expr));
}
/**
* Gets either the static or instance type of a class element, based on
* whether the element is declared as "static".
*/
function getParentTypeOfClassElement(node) {
var classSymbol = getSymbolOfNode(node.parent);
return ts.getModifierFlags(node) & 32 /* Static */
? getTypeOfSymbol(classSymbol)
: getDeclaredTypeOfSymbol(classSymbol);
}
// Return the list of properties of the given type, augmented with properties from Function
// if the type has call or construct signatures
function getAugmentedPropertiesOfType(type) {
type = getApparentType(type);
var propsByName = createSymbolTable(getPropertiesOfType(type));
if (getSignaturesOfType(type, 0 /* Call */).length || getSignaturesOfType(type, 1 /* Construct */).length) {
ts.forEach(getPropertiesOfType(globalFunctionType), function (p) {
if (!propsByName[p.name]) {
propsByName[p.name] = p;
}
});
}
return getNamedMembers(propsByName);
}
function getRootSymbols(symbol) {
if (symbol.flags & 268435456 /* SyntheticProperty */) {
var symbols_3 = [];
var name_27 = symbol.name;
ts.forEach(getSymbolLinks(symbol).containingType.types, function (t) {
var symbol = getPropertyOfType(t, name_27);
if (symbol) {
symbols_3.push(symbol);
}
});
return symbols_3;
}
else if (symbol.flags & 67108864 /* Transient */) {
if (symbol.leftSpread) {
var links = symbol;
return [links.leftSpread, links.rightSpread];
}
var target = void 0;
var next = symbol;
while (next = getSymbolLinks(next).target) {
target = next;
}
if (target) {
return [target];
}
}
return [symbol];
}
// Emitter support
function isArgumentsLocalBinding(node) {
if (!ts.isGeneratedIdentifier(node)) {
node = ts.getParseTreeNode(node, ts.isIdentifier);
if (node) {
return getReferencedValueSymbol(node) === argumentsSymbol;
}
}
return false;
}
function moduleExportsSomeValue(moduleReferenceExpression) {
var moduleSymbol = resolveExternalModuleName(moduleReferenceExpression.parent, moduleReferenceExpression);
if (!moduleSymbol || ts.isShorthandAmbientModuleSymbol(moduleSymbol)) {
// If the module is not found or is shorthand, assume that it may export a value.
return true;
}
var hasExportAssignment = hasExportAssignmentSymbol(moduleSymbol);
// if module has export assignment then 'resolveExternalModuleSymbol' will return resolved symbol for export assignment
// otherwise it will return moduleSymbol itself
moduleSymbol = resolveExternalModuleSymbol(moduleSymbol);
var symbolLinks = getSymbolLinks(moduleSymbol);
if (symbolLinks.exportsSomeValue === undefined) {
// for export assignments - check if resolved symbol for RHS is itself a value
// otherwise - check if at least one export is value
symbolLinks.exportsSomeValue = hasExportAssignment
? !!(moduleSymbol.flags & 107455 /* Value */)
: ts.forEachProperty(getExportsOfModule(moduleSymbol), isValue);
}
return symbolLinks.exportsSomeValue;
function isValue(s) {
s = resolveSymbol(s);
return s && !!(s.flags & 107455 /* Value */);
}
}
function isNameOfModuleOrEnumDeclaration(node) {
var parent = node.parent;
return ts.isModuleOrEnumDeclaration(parent) && node === parent.name;
}
// When resolved as an expression identifier, if the given node references an exported entity, return the declaration
// node of the exported entity's container. Otherwise, return undefined.
function getReferencedExportContainer(node, prefixLocals) {
node = ts.getParseTreeNode(node, ts.isIdentifier);
if (node) {
// When resolving the export container for the name of a module or enum
// declaration, we need to start resolution at the declaration's container.
// Otherwise, we could incorrectly resolve the export container as the
// declaration if it contains an exported member with the same name.
var symbol = getReferencedValueSymbol(node, /*startInDeclarationContainer*/ isNameOfModuleOrEnumDeclaration(node));
if (symbol) {
if (symbol.flags & 1048576 /* ExportValue */) {
// If we reference an exported entity within the same module declaration, then whether
// we prefix depends on the kind of entity. SymbolFlags.ExportHasLocal encompasses all the
// kinds that we do NOT prefix.
var exportSymbol = getMergedSymbol(symbol.exportSymbol);
if (!prefixLocals && exportSymbol.flags & 944 /* ExportHasLocal */) {
return undefined;
}
symbol = exportSymbol;
}
var parentSymbol = getParentOfSymbol(symbol);
if (parentSymbol) {
if (parentSymbol.flags & 512 /* ValueModule */ && parentSymbol.valueDeclaration.kind === 261 /* SourceFile */) {
var symbolFile = parentSymbol.valueDeclaration;
var referenceFile = ts.getSourceFileOfNode(node);
// If `node` accesses an export and that export isn't in the same file, then symbol is a namespace export, so return undefined.
var symbolIsUmdExport = symbolFile !== referenceFile;
return symbolIsUmdExport ? undefined : symbolFile;
}
for (var n = node.parent; n; n = n.parent) {
if (ts.isModuleOrEnumDeclaration(n) && getSymbolOfNode(n) === parentSymbol) {
return n;
}
}
}
}
}
}
// When resolved as an expression identifier, if the given node references an import, return the declaration of
// that import. Otherwise, return undefined.
function getReferencedImportDeclaration(node) {
node = ts.getParseTreeNode(node, ts.isIdentifier);
if (node) {
var symbol = getReferencedValueSymbol(node);
if (symbol && symbol.flags & 8388608 /* Alias */) {
return getDeclarationOfAliasSymbol(symbol);
}
}
return undefined;
}
function isSymbolOfDeclarationWithCollidingName(symbol) {
if (symbol.flags & 418 /* BlockScoped */) {
var links = getSymbolLinks(symbol);
if (links.isDeclarationWithCollidingName === undefined) {
var container = ts.getEnclosingBlockScopeContainer(symbol.valueDeclaration);
if (ts.isStatementWithLocals(container)) {
var nodeLinks_1 = getNodeLinks(symbol.valueDeclaration);
if (!!resolveName(container.parent, symbol.name, 107455 /* Value */, /*nameNotFoundMessage*/ undefined, /*nameArg*/ undefined)) {
// redeclaration - always should be renamed
links.isDeclarationWithCollidingName = true;
}
else if (nodeLinks_1.flags & 131072 /* CapturedBlockScopedBinding */) {
// binding is captured in the function
// should be renamed if:
// - binding is not top level - top level bindings never collide with anything
// AND
// - binding is not declared in loop, should be renamed to avoid name reuse across siblings
// let a, b
// { let x = 1; a = () => x; }
// { let x = 100; b = () => x; }
// console.log(a()); // should print '1'
// console.log(b()); // should print '100'
// OR
// - binding is declared inside loop but not in inside initializer of iteration statement or directly inside loop body
// * variables from initializer are passed to rewritten loop body as parameters so they are not captured directly
// * variables that are declared immediately in loop body will become top level variable after loop is rewritten and thus
// they will not collide with anything
var isDeclaredInLoop = nodeLinks_1.flags & 262144 /* BlockScopedBindingInLoop */;
var inLoopInitializer = ts.isIterationStatement(container, /*lookInLabeledStatements*/ false);
var inLoopBodyBlock = container.kind === 204 /* Block */ && ts.isIterationStatement(container.parent, /*lookInLabeledStatements*/ false);
links.isDeclarationWithCollidingName = !ts.isBlockScopedContainerTopLevel(container) && (!isDeclaredInLoop || (!inLoopInitializer && !inLoopBodyBlock));
}
else {
links.isDeclarationWithCollidingName = false;
}
}
}
return links.isDeclarationWithCollidingName;
}
return false;
}
// When resolved as an expression identifier, if the given node references a nested block scoped entity with
// a name that either hides an existing name or might hide it when compiled downlevel,
// return the declaration of that entity. Otherwise, return undefined.
function getReferencedDeclarationWithCollidingName(node) {
if (!ts.isGeneratedIdentifier(node)) {
node = ts.getParseTreeNode(node, ts.isIdentifier);
if (node) {
var symbol = getReferencedValueSymbol(node);
if (symbol && isSymbolOfDeclarationWithCollidingName(symbol)) {
return symbol.valueDeclaration;
}
}
}
return undefined;
}
// Return true if the given node is a declaration of a nested block scoped entity with a name that either hides an
// existing name or might hide a name when compiled downlevel
function isDeclarationWithCollidingName(node) {
node = ts.getParseTreeNode(node, ts.isDeclaration);
if (node) {
var symbol = getSymbolOfNode(node);
if (symbol) {
return isSymbolOfDeclarationWithCollidingName(symbol);
}
}
return false;
}
function isValueAliasDeclaration(node) {
node = ts.getParseTreeNode(node);
if (node === undefined) {
// A synthesized node comes from an emit transformation and is always a value.
return true;
}
switch (node.kind) {
case 234 /* ImportEqualsDeclaration */:
case 236 /* ImportClause */:
case 237 /* NamespaceImport */:
case 239 /* ImportSpecifier */:
case 243 /* ExportSpecifier */:
return isAliasResolvedToValue(getSymbolOfNode(node) || unknownSymbol);
case 241 /* ExportDeclaration */:
var exportClause = node.exportClause;
return exportClause && ts.forEach(exportClause.elements, isValueAliasDeclaration);
case 240 /* ExportAssignment */:
return node.expression
&& node.expression.kind === 70 /* Identifier */
? isAliasResolvedToValue(getSymbolOfNode(node) || unknownSymbol)
: true;
}
return false;
}
function isTopLevelValueImportEqualsWithEntityName(node) {
node = ts.getParseTreeNode(node, ts.isImportEqualsDeclaration);
if (node === undefined || node.parent.kind !== 261 /* SourceFile */ || !ts.isInternalModuleImportEqualsDeclaration(node)) {
// parent is not source file or it is not reference to internal module
return false;
}
var isValue = isAliasResolvedToValue(getSymbolOfNode(node));
return isValue && node.moduleReference && !ts.nodeIsMissing(node.moduleReference);
}
function isAliasResolvedToValue(symbol) {
var target = resolveAlias(symbol);
if (target === unknownSymbol) {
return true;
}
// const enums and modules that contain only const enums are not considered values from the emit perspective
// unless 'preserveConstEnums' option is set to true
return target.flags & 107455 /* Value */ &&
(compilerOptions.preserveConstEnums || !isConstEnumOrConstEnumOnlyModule(target));
}
function isConstEnumOrConstEnumOnlyModule(s) {
return isConstEnumSymbol(s) || s.constEnumOnlyModule;
}
function isReferencedAliasDeclaration(node, checkChildren) {
node = ts.getParseTreeNode(node);
// Purely synthesized nodes are always emitted.
if (node === undefined) {
return true;
}
if (ts.isAliasSymbolDeclaration(node)) {
var symbol = getSymbolOfNode(node);
if (symbol && getSymbolLinks(symbol).referenced) {
return true;
}
}
if (checkChildren) {
return ts.forEachChild(node, function (node) { return isReferencedAliasDeclaration(node, checkChildren); });
}
return false;
}
function isImplementationOfOverload(node) {
if (ts.nodeIsPresent(node.body)) {
var symbol = getSymbolOfNode(node);
var signaturesOfSymbol = getSignaturesOfSymbol(symbol);
// If this function body corresponds to function with multiple signature, it is implementation of overload
// e.g.: function foo(a: string): string;
// function foo(a: number): number;
// function foo(a: any) { // This is implementation of the overloads
// return a;
// }
return signaturesOfSymbol.length > 1 ||
// If there is single signature for the symbol, it is overload if that signature isn't coming from the node
// e.g.: function foo(a: string): string;
// function foo(a: any) { // This is implementation of the overloads
// return a;
// }
(signaturesOfSymbol.length === 1 && signaturesOfSymbol[0].declaration !== node);
}
return false;
}
function getNodeCheckFlags(node) {
node = ts.getParseTreeNode(node);
return node ? getNodeLinks(node).flags : undefined;
}
function getEnumMemberValue(node) {
computeEnumMemberValues(node.parent);
return getNodeLinks(node).enumMemberValue;
}
function getConstantValue(node) {
if (node.kind === 260 /* EnumMember */) {
return getEnumMemberValue(node);
}
var symbol = getNodeLinks(node).resolvedSymbol;
if (symbol && (symbol.flags & 8 /* EnumMember */)) {
// inline property\index accesses only for const enums
if (ts.isConstEnumDeclaration(symbol.valueDeclaration.parent)) {
return getEnumMemberValue(symbol.valueDeclaration);
}
}
return undefined;
}
function isFunctionType(type) {
return type.flags & 32768 /* Object */ && getSignaturesOfType(type, 0 /* Call */).length > 0;
}
function getTypeReferenceSerializationKind(typeName, location) {
// Resolve the symbol as a value to ensure the type can be reached at runtime during emit.
var valueSymbol = resolveEntityName(typeName, 107455 /* Value */, /*ignoreErrors*/ true, /*dontResolveAlias*/ false, location);
var globalPromiseSymbol = tryGetGlobalPromiseConstructorSymbol();
if (globalPromiseSymbol && valueSymbol === globalPromiseSymbol) {
return ts.TypeReferenceSerializationKind.Promise;
}
var constructorType = valueSymbol ? getTypeOfSymbol(valueSymbol) : undefined;
if (constructorType && isConstructorType(constructorType)) {
return ts.TypeReferenceSerializationKind.TypeWithConstructSignatureAndValue;
}
// Resolve the symbol as a type so that we can provide a more useful hint for the type serializer.
var typeSymbol = resolveEntityName(typeName, 793064 /* Type */, /*ignoreErrors*/ true, /*dontResolveAlias*/ false, location);
// We might not be able to resolve type symbol so use unknown type in that case (eg error case)
if (!typeSymbol) {
return ts.TypeReferenceSerializationKind.ObjectType;
}
var type = getDeclaredTypeOfSymbol(typeSymbol);
if (type === unknownType) {
return ts.TypeReferenceSerializationKind.Unknown;
}
else if (type.flags & 1 /* Any */) {
return ts.TypeReferenceSerializationKind.ObjectType;
}
else if (isTypeOfKind(type, 1024 /* Void */ | 6144 /* Nullable */ | 8192 /* Never */)) {
return ts.TypeReferenceSerializationKind.VoidNullableOrNeverType;
}
else if (isTypeOfKind(type, 136 /* BooleanLike */)) {
return ts.TypeReferenceSerializationKind.BooleanType;
}
else if (isTypeOfKind(type, 340 /* NumberLike */)) {
return ts.TypeReferenceSerializationKind.NumberLikeType;
}
else if (isTypeOfKind(type, 34 /* StringLike */)) {
return ts.TypeReferenceSerializationKind.StringLikeType;
}
else if (isTupleType(type)) {
return ts.TypeReferenceSerializationKind.ArrayLikeType;
}
else if (isTypeOfKind(type, 512 /* ESSymbol */)) {
return ts.TypeReferenceSerializationKind.ESSymbolType;
}
else if (isFunctionType(type)) {
return ts.TypeReferenceSerializationKind.TypeWithCallSignature;
}
else if (isArrayType(type)) {
return ts.TypeReferenceSerializationKind.ArrayLikeType;
}
else {
return ts.TypeReferenceSerializationKind.ObjectType;
}
}
function writeTypeOfDeclaration(declaration, enclosingDeclaration, flags, writer) {
// Get type of the symbol if this is the valid symbol otherwise get type at location
var symbol = getSymbolOfNode(declaration);
var type = symbol && !(symbol.flags & (2048 /* TypeLiteral */ | 131072 /* Signature */))
? getWidenedLiteralType(getTypeOfSymbol(symbol))
: unknownType;
getSymbolDisplayBuilder().buildTypeDisplay(type, writer, enclosingDeclaration, flags);
}
function writeReturnTypeOfSignatureDeclaration(signatureDeclaration, enclosingDeclaration, flags, writer) {
var signature = getSignatureFromDeclaration(signatureDeclaration);
getSymbolDisplayBuilder().buildTypeDisplay(getReturnTypeOfSignature(signature), writer, enclosingDeclaration, flags);
}
function writeTypeOfExpression(expr, enclosingDeclaration, flags, writer) {
var type = getWidenedType(getTypeOfExpression(expr));
getSymbolDisplayBuilder().buildTypeDisplay(type, writer, enclosingDeclaration, flags);
}
function writeBaseConstructorTypeOfClass(node, enclosingDeclaration, flags, writer) {
var classType = getDeclaredTypeOfSymbol(getSymbolOfNode(node));
resolveBaseTypesOfClass(classType);
var baseType = classType.resolvedBaseTypes.length ? classType.resolvedBaseTypes[0] : unknownType;
getSymbolDisplayBuilder().buildTypeDisplay(baseType, writer, enclosingDeclaration, flags);
}
function hasGlobalName(name) {
return !!globals[name];
}
function getReferencedValueSymbol(reference, startInDeclarationContainer) {
var resolvedSymbol = getNodeLinks(reference).resolvedSymbol;
if (resolvedSymbol) {
return resolvedSymbol;
}
var location = reference;
if (startInDeclarationContainer) {
// When resolving the name of a declaration as a value, we need to start resolution
// at a point outside of the declaration.
var parent_12 = reference.parent;
if (ts.isDeclaration(parent_12) && reference === parent_12.name) {
location = getDeclarationContainer(parent_12);
}
}
return resolveName(location, reference.text, 107455 /* Value */ | 1048576 /* ExportValue */ | 8388608 /* Alias */, /*nodeNotFoundMessage*/ undefined, /*nameArg*/ undefined);
}
function getReferencedValueDeclaration(reference) {
if (!ts.isGeneratedIdentifier(reference)) {
reference = ts.getParseTreeNode(reference, ts.isIdentifier);
if (reference) {
var symbol = getReferencedValueSymbol(reference);
if (symbol) {
return getExportSymbolOfValueSymbolIfExported(symbol).valueDeclaration;
}
}
}
return undefined;
}
function isLiteralConstDeclaration(node) {
if (ts.isConst(node)) {
var type = getTypeOfSymbol(getSymbolOfNode(node));
return !!(type.flags & 96 /* StringOrNumberLiteral */ && type.flags & 1048576 /* FreshLiteral */);
}
return false;
}
function writeLiteralConstValue(node, writer) {
var type = getTypeOfSymbol(getSymbolOfNode(node));
writer.writeStringLiteral(literalTypeToString(type));
}
function createResolver() {
// this variable and functions that use it are deliberately moved here from the outer scope
// to avoid scope pollution
var resolvedTypeReferenceDirectives = host.getResolvedTypeReferenceDirectives();
var fileToDirective;
if (resolvedTypeReferenceDirectives) {
// populate reverse mapping: file path -> type reference directive that was resolved to this file
fileToDirective = ts.createFileMap();
for (var key in resolvedTypeReferenceDirectives) {
var resolvedDirective = resolvedTypeReferenceDirectives[key];
if (!resolvedDirective) {
continue;
}
var file = host.getSourceFile(resolvedDirective.resolvedFileName);
fileToDirective.set(file.path, key);
}
}
return {
getReferencedExportContainer: getReferencedExportContainer,
getReferencedImportDeclaration: getReferencedImportDeclaration,
getReferencedDeclarationWithCollidingName: getReferencedDeclarationWithCollidingName,
isDeclarationWithCollidingName: isDeclarationWithCollidingName,
isValueAliasDeclaration: isValueAliasDeclaration,
hasGlobalName: hasGlobalName,
isReferencedAliasDeclaration: isReferencedAliasDeclaration,
getNodeCheckFlags: getNodeCheckFlags,
isTopLevelValueImportEqualsWithEntityName: isTopLevelValueImportEqualsWithEntityName,
isDeclarationVisible: isDeclarationVisible,
isImplementationOfOverload: isImplementationOfOverload,
writeTypeOfDeclaration: writeTypeOfDeclaration,
writeReturnTypeOfSignatureDeclaration: writeReturnTypeOfSignatureDeclaration,
writeTypeOfExpression: writeTypeOfExpression,
writeBaseConstructorTypeOfClass: writeBaseConstructorTypeOfClass,
isSymbolAccessible: isSymbolAccessible,
isEntityNameVisible: isEntityNameVisible,
getConstantValue: getConstantValue,
collectLinkedAliases: collectLinkedAliases,
getReferencedValueDeclaration: getReferencedValueDeclaration,
getTypeReferenceSerializationKind: getTypeReferenceSerializationKind,
isOptionalParameter: isOptionalParameter,
moduleExportsSomeValue: moduleExportsSomeValue,
isArgumentsLocalBinding: isArgumentsLocalBinding,
getExternalModuleFileFromDeclaration: getExternalModuleFileFromDeclaration,
getTypeReferenceDirectivesForEntityName: getTypeReferenceDirectivesForEntityName,
getTypeReferenceDirectivesForSymbol: getTypeReferenceDirectivesForSymbol,
isLiteralConstDeclaration: isLiteralConstDeclaration,
writeLiteralConstValue: writeLiteralConstValue,
getJsxFactoryEntity: function () { return _jsxFactoryEntity; }
};
// defined here to avoid outer scope pollution
function getTypeReferenceDirectivesForEntityName(node) {
// program does not have any files with type reference directives - bail out
if (!fileToDirective) {
return undefined;
}
// property access can only be used as values
// qualified names can only be used as types\namespaces
// identifiers are treated as values only if they appear in type queries
var meaning = (node.kind === 177 /* PropertyAccessExpression */) || (node.kind === 70 /* Identifier */ && isInTypeQuery(node))
? 107455 /* Value */ | 1048576 /* ExportValue */
: 793064 /* Type */ | 1920 /* Namespace */;
var symbol = resolveEntityName(node, meaning, /*ignoreErrors*/ true);
return symbol && symbol !== unknownSymbol ? getTypeReferenceDirectivesForSymbol(symbol, meaning) : undefined;
}
// defined here to avoid outer scope pollution
function getTypeReferenceDirectivesForSymbol(symbol, meaning) {
// program does not have any files with type reference directives - bail out
if (!fileToDirective) {
return undefined;
}
if (!isSymbolFromTypeDeclarationFile(symbol)) {
return undefined;
}
// check what declarations in the symbol can contribute to the target meaning
var typeReferenceDirectives;
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
// check meaning of the local symbol to see if declaration needs to be analyzed further
if (decl.symbol && decl.symbol.flags & meaning) {
var file = ts.getSourceFileOfNode(decl);
var typeReferenceDirective = fileToDirective.get(file.path);
if (typeReferenceDirective) {
(typeReferenceDirectives || (typeReferenceDirectives = [])).push(typeReferenceDirective);
}
else {
// found at least one entry that does not originate from type reference directive
return undefined;
}
}
}
return typeReferenceDirectives;
}
function isSymbolFromTypeDeclarationFile(symbol) {
// bail out if symbol does not have associated declarations (i.e. this is transient symbol created for property in binding pattern)
if (!symbol.declarations) {
return false;
}
// walk the parent chain for symbols to make sure that top level parent symbol is in the global scope
// external modules cannot define or contribute to type declaration files
var current = symbol;
while (true) {
var parent_13 = getParentOfSymbol(current);
if (parent_13) {
current = parent_13;
}
else {
break;
}
}
if (current.valueDeclaration && current.valueDeclaration.kind === 261 /* SourceFile */ && current.flags & 512 /* ValueModule */) {
return false;
}
// check that at least one declaration of top level symbol originates from type declaration file
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
var file = ts.getSourceFileOfNode(decl);
if (fileToDirective.contains(file.path)) {
return true;
}
}
return false;
}
}
function getExternalModuleFileFromDeclaration(declaration) {
var specifier = ts.getExternalModuleName(declaration);
var moduleSymbol = resolveExternalModuleNameWorker(specifier, specifier, /*moduleNotFoundError*/ undefined);
if (!moduleSymbol) {
return undefined;
}
return ts.getDeclarationOfKind(moduleSymbol, 261 /* SourceFile */);
}
function initializeTypeChecker() {
// Bind all source files and propagate errors
for (var _i = 0, _a = host.getSourceFiles(); _i < _a.length; _i++) {
var file = _a[_i];
ts.bindSourceFile(file, compilerOptions);
}
// Initialize global symbol table
var augmentations;
var requestedExternalEmitHelpers = 0;
var firstFileRequestingExternalHelpers;
for (var _b = 0, _c = host.getSourceFiles(); _b < _c.length; _b++) {
var file = _c[_b];
if (!ts.isExternalOrCommonJsModule(file)) {
mergeSymbolTable(globals, file.locals);
}
if (file.patternAmbientModules && file.patternAmbientModules.length) {
patternAmbientModules = ts.concatenate(patternAmbientModules, file.patternAmbientModules);
}
if (file.moduleAugmentations.length) {
(augmentations || (augmentations = [])).push(file.moduleAugmentations);
}
if (file.symbol && file.symbol.globalExports) {
// Merge in UMD exports with first-in-wins semantics (see #9771)
var source = file.symbol.globalExports;
for (var id in source) {
if (!(id in globals)) {
globals[id] = source[id];
}
}
}
if ((compilerOptions.isolatedModules || ts.isExternalModule(file)) && !file.isDeclarationFile) {
var fileRequestedExternalEmitHelpers = file.flags & 64512 /* EmitHelperFlags */;
if (fileRequestedExternalEmitHelpers) {
requestedExternalEmitHelpers |= fileRequestedExternalEmitHelpers;
if (firstFileRequestingExternalHelpers === undefined) {
firstFileRequestingExternalHelpers = file;
}
}
}
}
if (augmentations) {
// merge module augmentations.
// this needs to be done after global symbol table is initialized to make sure that all ambient modules are indexed
for (var _d = 0, augmentations_1 = augmentations; _d < augmentations_1.length; _d++) {
var list = augmentations_1[_d];
for (var _e = 0, list_1 = list; _e < list_1.length; _e++) {
var augmentation = list_1[_e];
mergeModuleAugmentation(augmentation);
}
}
}
// Setup global builtins
addToSymbolTable(globals, builtinGlobals, ts.Diagnostics.Declaration_name_conflicts_with_built_in_global_identifier_0);
getSymbolLinks(undefinedSymbol).type = undefinedWideningType;
getSymbolLinks(argumentsSymbol).type = getGlobalType("IArguments");
getSymbolLinks(unknownSymbol).type = unknownType;
// Initialize special types
globalArrayType = getGlobalType("Array", /*arity*/ 1);
globalObjectType = getGlobalType("Object");
globalFunctionType = getGlobalType("Function");
globalStringType = getGlobalType("String");
globalNumberType = getGlobalType("Number");
globalBooleanType = getGlobalType("Boolean");
globalRegExpType = getGlobalType("RegExp");
jsxElementType = getExportedTypeFromNamespace("JSX", JsxNames.Element);
getGlobalClassDecoratorType = ts.memoize(function () { return getGlobalType("ClassDecorator"); });
getGlobalPropertyDecoratorType = ts.memoize(function () { return getGlobalType("PropertyDecorator"); });
getGlobalMethodDecoratorType = ts.memoize(function () { return getGlobalType("MethodDecorator"); });
getGlobalParameterDecoratorType = ts.memoize(function () { return getGlobalType("ParameterDecorator"); });
getGlobalTypedPropertyDescriptorType = ts.memoize(function () { return getGlobalType("TypedPropertyDescriptor", /*arity*/ 1); });
getGlobalESSymbolConstructorSymbol = ts.memoize(function () { return getGlobalValueSymbol("Symbol"); });
getGlobalPromiseType = ts.memoize(function () { return getGlobalType("Promise", /*arity*/ 1); });
tryGetGlobalPromiseType = ts.memoize(function () { return getGlobalSymbol("Promise", 793064 /* Type */, /*diagnostic*/ undefined) && getGlobalPromiseType(); });
getGlobalPromiseLikeType = ts.memoize(function () { return getGlobalType("PromiseLike", /*arity*/ 1); });
getInstantiatedGlobalPromiseLikeType = ts.memoize(createInstantiatedPromiseLikeType);
getGlobalPromiseConstructorSymbol = ts.memoize(function () { return getGlobalValueSymbol("Promise"); });
tryGetGlobalPromiseConstructorSymbol = ts.memoize(function () { return getGlobalSymbol("Promise", 107455 /* Value */, /*diagnostic*/ undefined) && getGlobalPromiseConstructorSymbol(); });
getGlobalPromiseConstructorLikeType = ts.memoize(function () { return getGlobalType("PromiseConstructorLike"); });
getGlobalThenableType = ts.memoize(createThenableType);
getGlobalTemplateStringsArrayType = ts.memoize(function () { return getGlobalType("TemplateStringsArray"); });
if (languageVersion >= 2 /* ES2015 */) {
getGlobalESSymbolType = ts.memoize(function () { return getGlobalType("Symbol"); });
getGlobalIterableType = ts.memoize(function () { return getGlobalType("Iterable", /*arity*/ 1); });
getGlobalIteratorType = ts.memoize(function () { return getGlobalType("Iterator", /*arity*/ 1); });
getGlobalIterableIteratorType = ts.memoize(function () { return getGlobalType("IterableIterator", /*arity*/ 1); });
}
else {
getGlobalESSymbolType = ts.memoize(function () { return emptyObjectType; });
getGlobalIterableType = ts.memoize(function () { return emptyGenericType; });
getGlobalIteratorType = ts.memoize(function () { return emptyGenericType; });
getGlobalIterableIteratorType = ts.memoize(function () { return emptyGenericType; });
}
anyArrayType = createArrayType(anyType);
autoArrayType = createArrayType(autoType);
var symbol = getGlobalSymbol("ReadonlyArray", 793064 /* Type */, /*diagnostic*/ undefined);
globalReadonlyArrayType = symbol && getTypeOfGlobalSymbol(symbol, /*arity*/ 1);
anyReadonlyArrayType = globalReadonlyArrayType ? createTypeFromGenericGlobalType(globalReadonlyArrayType, [anyType]) : anyArrayType;
// If we have specified that we are importing helpers, we should report global
// errors if we cannot resolve the helpers external module, or if it does not have
// the necessary helpers exported.
if (compilerOptions.importHelpers && firstFileRequestingExternalHelpers) {
// Find the first reference to the helpers module.
var helpersModule = resolveExternalModule(firstFileRequestingExternalHelpers, ts.externalHelpersModuleNameText, ts.Diagnostics.Cannot_find_module_0,
/*errorNode*/ undefined);
// If we found the module, report errors if it does not have the necessary exports.
if (helpersModule) {
var exports = helpersModule.exports;
if (requestedExternalEmitHelpers & 1024 /* HasClassExtends */ && languageVersion < 2 /* ES2015 */) {
verifyHelperSymbol(exports, "__extends", 107455 /* Value */);
}
if (requestedExternalEmitHelpers & 16384 /* HasSpreadAttribute */ &&
(languageVersion < 5 /* ESNext */ || compilerOptions.jsx === 2 /* React */)) {
verifyHelperSymbol(exports, "__assign", 107455 /* Value */);
}
if (languageVersion < 5 /* ESNext */ && requestedExternalEmitHelpers & 32768 /* HasRestAttribute */) {
verifyHelperSymbol(exports, "__rest", 107455 /* Value */);
}
if (requestedExternalEmitHelpers & 2048 /* HasDecorators */) {
verifyHelperSymbol(exports, "__decorate", 107455 /* Value */);
if (compilerOptions.emitDecoratorMetadata) {
verifyHelperSymbol(exports, "__metadata", 107455 /* Value */);
}
}
if (requestedExternalEmitHelpers & 4096 /* HasParamDecorators */) {
verifyHelperSymbol(exports, "__param", 107455 /* Value */);
}
if (requestedExternalEmitHelpers & 8192 /* HasAsyncFunctions */) {
verifyHelperSymbol(exports, "__awaiter", 107455 /* Value */);
if (languageVersion < 2 /* ES2015 */) {
verifyHelperSymbol(exports, "__generator", 107455 /* Value */);
}
}
}
}
}
function verifyHelperSymbol(symbols, name, meaning) {
var symbol = getSymbol(symbols, ts.escapeIdentifier(name), meaning);
if (!symbol) {
error(/*location*/ undefined, ts.Diagnostics.Module_0_has_no_exported_member_1, ts.externalHelpersModuleNameText, name);
}
}
function createInstantiatedPromiseLikeType() {
var promiseLikeType = getGlobalPromiseLikeType();
if (promiseLikeType !== emptyGenericType) {
return createTypeReference(promiseLikeType, [anyType]);
}
return emptyObjectType;
}
function createThenableType() {
// build the thenable type that is used to verify against a non-promise "thenable" operand to `await`.
var thenPropertySymbol = createSymbol(67108864 /* Transient */ | 4 /* Property */, "then");
getSymbolLinks(thenPropertySymbol).type = globalFunctionType;
var thenableType = createObjectType(16 /* Anonymous */);
thenableType.properties = [thenPropertySymbol];
thenableType.members = createSymbolTable(thenableType.properties);
thenableType.callSignatures = [];
thenableType.constructSignatures = [];
return thenableType;
}
// GRAMMAR CHECKING
function checkGrammarDecorators(node) {
if (!node.decorators) {
return false;
}
if (!ts.nodeCanBeDecorated(node)) {
if (node.kind === 149 /* MethodDeclaration */ && !ts.nodeIsPresent(node.body)) {
return grammarErrorOnFirstToken(node, ts.Diagnostics.A_decorator_can_only_decorate_a_method_implementation_not_an_overload);
}
else {
return grammarErrorOnFirstToken(node, ts.Diagnostics.Decorators_are_not_valid_here);
}
}
else if (node.kind === 151 /* GetAccessor */ || node.kind === 152 /* SetAccessor */) {
var accessors = ts.getAllAccessorDeclarations(node.parent.members, node);
if (accessors.firstAccessor.decorators && node === accessors.secondAccessor) {
return grammarErrorOnFirstToken(node, ts.Diagnostics.Decorators_cannot_be_applied_to_multiple_get_Slashset_accessors_of_the_same_name);
}
}
return false;
}
function checkGrammarModifiers(node) {
var quickResult = reportObviousModifierErrors(node);
if (quickResult !== undefined) {
return quickResult;
}
var lastStatic, lastPrivate, lastProtected, lastDeclare, lastAsync, lastReadonly;
var flags = 0 /* None */;
for (var _i = 0, _a = node.modifiers; _i < _a.length; _i++) {
var modifier = _a[_i];
if (modifier.kind !== 130 /* ReadonlyKeyword */) {
if (node.kind === 146 /* PropertySignature */ || node.kind === 148 /* MethodSignature */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_type_member, ts.tokenToString(modifier.kind));
}
if (node.kind === 155 /* IndexSignature */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_an_index_signature, ts.tokenToString(modifier.kind));
}
}
switch (modifier.kind) {
case 75 /* ConstKeyword */:
if (node.kind !== 229 /* EnumDeclaration */ && node.parent.kind === 226 /* ClassDeclaration */) {
return grammarErrorOnNode(node, ts.Diagnostics.A_class_member_cannot_have_the_0_keyword, ts.tokenToString(75 /* ConstKeyword */));
}
break;
case 113 /* PublicKeyword */:
case 112 /* ProtectedKeyword */:
case 111 /* PrivateKeyword */:
var text = visibilityToString(ts.modifierToFlag(modifier.kind));
if (modifier.kind === 112 /* ProtectedKeyword */) {
lastProtected = modifier;
}
else if (modifier.kind === 111 /* PrivateKeyword */) {
lastPrivate = modifier;
}
if (flags & 28 /* AccessibilityModifier */) {
return grammarErrorOnNode(modifier, ts.Diagnostics.Accessibility_modifier_already_seen);
}
else if (flags & 32 /* Static */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, text, "static");
}
else if (flags & 64 /* Readonly */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, text, "readonly");
}
else if (flags & 256 /* Async */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, text, "async");
}
else if (node.parent.kind === 231 /* ModuleBlock */ || node.parent.kind === 261 /* SourceFile */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_module_or_namespace_element, text);
}
else if (flags & 128 /* Abstract */) {
if (modifier.kind === 111 /* PrivateKeyword */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_be_used_with_1_modifier, text, "abstract");
}
else {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, text, "abstract");
}
}
flags |= ts.modifierToFlag(modifier.kind);
break;
case 114 /* StaticKeyword */:
if (flags & 32 /* Static */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_already_seen, "static");
}
else if (flags & 64 /* Readonly */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, "static", "readonly");
}
else if (flags & 256 /* Async */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, "static", "async");
}
else if (node.parent.kind === 231 /* ModuleBlock */ || node.parent.kind === 261 /* SourceFile */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_module_or_namespace_element, "static");
}
else if (node.kind === 144 /* Parameter */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_parameter, "static");
}
else if (flags & 128 /* Abstract */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_be_used_with_1_modifier, "static", "abstract");
}
flags |= 32 /* Static */;
lastStatic = modifier;
break;
case 130 /* ReadonlyKeyword */:
if (flags & 64 /* Readonly */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_already_seen, "readonly");
}
else if (node.kind !== 147 /* PropertyDeclaration */ && node.kind !== 146 /* PropertySignature */ && node.kind !== 155 /* IndexSignature */ && node.kind !== 144 /* Parameter */) {
// If node.kind === SyntaxKind.Parameter, checkParameter report an error if it's not a parameter property.
return grammarErrorOnNode(modifier, ts.Diagnostics.readonly_modifier_can_only_appear_on_a_property_declaration_or_index_signature);
}
flags |= 64 /* Readonly */;
lastReadonly = modifier;
break;
case 83 /* ExportKeyword */:
if (flags & 1 /* Export */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_already_seen, "export");
}
else if (flags & 2 /* Ambient */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, "export", "declare");
}
else if (flags & 128 /* Abstract */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, "export", "abstract");
}
else if (flags & 256 /* Async */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_must_precede_1_modifier, "export", "async");
}
else if (node.parent.kind === 226 /* ClassDeclaration */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_class_element, "export");
}
else if (node.kind === 144 /* Parameter */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_parameter, "export");
}
flags |= 1 /* Export */;
break;
case 123 /* DeclareKeyword */:
if (flags & 2 /* Ambient */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_already_seen, "declare");
}
else if (flags & 256 /* Async */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_be_used_in_an_ambient_context, "async");
}
else if (node.parent.kind === 226 /* ClassDeclaration */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_class_element, "declare");
}
else if (node.kind === 144 /* Parameter */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_parameter, "declare");
}
else if (ts.isInAmbientContext(node.parent) && node.parent.kind === 231 /* ModuleBlock */) {
return grammarErrorOnNode(modifier, ts.Diagnostics.A_declare_modifier_cannot_be_used_in_an_already_ambient_context);
}
flags |= 2 /* Ambient */;
lastDeclare = modifier;
break;
case 116 /* AbstractKeyword */:
if (flags & 128 /* Abstract */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_already_seen, "abstract");
}
if (node.kind !== 226 /* ClassDeclaration */) {
if (node.kind !== 149 /* MethodDeclaration */ &&
node.kind !== 147 /* PropertyDeclaration */ &&
node.kind !== 151 /* GetAccessor */ &&
node.kind !== 152 /* SetAccessor */) {
return grammarErrorOnNode(modifier, ts.Diagnostics.abstract_modifier_can_only_appear_on_a_class_method_or_property_declaration);
}
if (!(node.parent.kind === 226 /* ClassDeclaration */ && ts.getModifierFlags(node.parent) & 128 /* Abstract */)) {
return grammarErrorOnNode(modifier, ts.Diagnostics.Abstract_methods_can_only_appear_within_an_abstract_class);
}
if (flags & 32 /* Static */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_be_used_with_1_modifier, "static", "abstract");
}
if (flags & 8 /* Private */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_be_used_with_1_modifier, "private", "abstract");
}
}
flags |= 128 /* Abstract */;
break;
case 119 /* AsyncKeyword */:
if (flags & 256 /* Async */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_already_seen, "async");
}
else if (flags & 2 /* Ambient */ || ts.isInAmbientContext(node.parent)) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_be_used_in_an_ambient_context, "async");
}
else if (node.kind === 144 /* Parameter */) {
return grammarErrorOnNode(modifier, ts.Diagnostics._0_modifier_cannot_appear_on_a_parameter, "async");
}
flags |= 256 /* Async */;
lastAsync = modifier;
break;
}
}
if (node.kind === 150 /* Constructor */) {
if (flags & 32 /* Static */) {
return grammarErrorOnNode(lastStatic, ts.Diagnostics._0_modifier_cannot_appear_on_a_constructor_declaration, "static");
}
if (flags & 128 /* Abstract */) {
return grammarErrorOnNode(lastStatic, ts.Diagnostics._0_modifier_cannot_appear_on_a_constructor_declaration, "abstract");
}
else if (flags & 256 /* Async */) {
return grammarErrorOnNode(lastAsync, ts.Diagnostics._0_modifier_cannot_appear_on_a_constructor_declaration, "async");
}
else if (flags & 64 /* Readonly */) {
return grammarErrorOnNode(lastReadonly, ts.Diagnostics._0_modifier_cannot_appear_on_a_constructor_declaration, "readonly");
}
return;
}
else if ((node.kind === 235 /* ImportDeclaration */ || node.kind === 234 /* ImportEqualsDeclaration */) && flags & 2 /* Ambient */) {
return grammarErrorOnNode(lastDeclare, ts.Diagnostics.A_0_modifier_cannot_be_used_with_an_import_declaration, "declare");
}
else if (node.kind === 144 /* Parameter */ && (flags & 92 /* ParameterPropertyModifier */) && ts.isBindingPattern(node.name)) {
return grammarErrorOnNode(node, ts.Diagnostics.A_parameter_property_may_not_be_declared_using_a_binding_pattern);
}
else if (node.kind === 144 /* Parameter */ && (flags & 92 /* ParameterPropertyModifier */) && node.dotDotDotToken) {
return grammarErrorOnNode(node, ts.Diagnostics.A_parameter_property_cannot_be_declared_using_a_rest_parameter);
}
if (flags & 256 /* Async */) {
return checkGrammarAsyncModifier(node, lastAsync);
}
}
/**
* true | false: Early return this value from checkGrammarModifiers.
* undefined: Need to do full checking on the modifiers.
*/
function reportObviousModifierErrors(node) {
return !node.modifiers
? false
: shouldReportBadModifier(node)
? grammarErrorOnFirstToken(node, ts.Diagnostics.Modifiers_cannot_appear_here)
: undefined;
}
function shouldReportBadModifier(node) {
switch (node.kind) {
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 150 /* Constructor */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 155 /* IndexSignature */:
case 230 /* ModuleDeclaration */:
case 235 /* ImportDeclaration */:
case 234 /* ImportEqualsDeclaration */:
case 241 /* ExportDeclaration */:
case 240 /* ExportAssignment */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 144 /* Parameter */:
return false;
default:
if (node.parent.kind === 231 /* ModuleBlock */ || node.parent.kind === 261 /* SourceFile */) {
return false;
}
switch (node.kind) {
case 225 /* FunctionDeclaration */:
return nodeHasAnyModifiersExcept(node, 119 /* AsyncKeyword */);
case 226 /* ClassDeclaration */:
return nodeHasAnyModifiersExcept(node, 116 /* AbstractKeyword */);
case 227 /* InterfaceDeclaration */:
case 205 /* VariableStatement */:
case 228 /* TypeAliasDeclaration */:
return true;
case 229 /* EnumDeclaration */:
return nodeHasAnyModifiersExcept(node, 75 /* ConstKeyword */);
default:
ts.Debug.fail();
return false;
}
}
}
function nodeHasAnyModifiersExcept(node, allowedModifier) {
return node.modifiers.length > 1 || node.modifiers[0].kind !== allowedModifier;
}
function checkGrammarAsyncModifier(node, asyncModifier) {
switch (node.kind) {
case 149 /* MethodDeclaration */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
if (!node.asteriskToken) {
return false;
}
break;
}
return grammarErrorOnNode(asyncModifier, ts.Diagnostics._0_modifier_cannot_be_used_here, "async");
}
function checkGrammarForDisallowedTrailingComma(list) {
if (list && list.hasTrailingComma) {
var start = list.end - ",".length;
var end = list.end;
var sourceFile = ts.getSourceFileOfNode(list[0]);
return grammarErrorAtPos(sourceFile, start, end - start, ts.Diagnostics.Trailing_comma_not_allowed);
}
}
function checkGrammarTypeParameterList(typeParameters, file) {
if (checkGrammarForDisallowedTrailingComma(typeParameters)) {
return true;
}
if (typeParameters && typeParameters.length === 0) {
var start = typeParameters.pos - "<".length;
var end = ts.skipTrivia(file.text, typeParameters.end) + ">".length;
return grammarErrorAtPos(file, start, end - start, ts.Diagnostics.Type_parameter_list_cannot_be_empty);
}
}
function checkGrammarParameterList(parameters) {
var seenOptionalParameter = false;
var parameterCount = parameters.length;
for (var i = 0; i < parameterCount; i++) {
var parameter = parameters[i];
if (parameter.dotDotDotToken) {
if (i !== (parameterCount - 1)) {
return grammarErrorOnNode(parameter.dotDotDotToken, ts.Diagnostics.A_rest_parameter_must_be_last_in_a_parameter_list);
}
if (ts.isBindingPattern(parameter.name)) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.A_rest_element_cannot_contain_a_binding_pattern);
}
if (parameter.questionToken) {
return grammarErrorOnNode(parameter.questionToken, ts.Diagnostics.A_rest_parameter_cannot_be_optional);
}
if (parameter.initializer) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.A_rest_parameter_cannot_have_an_initializer);
}
}
else if (parameter.questionToken) {
seenOptionalParameter = true;
if (parameter.initializer) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.Parameter_cannot_have_question_mark_and_initializer);
}
}
else if (seenOptionalParameter && !parameter.initializer) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.A_required_parameter_cannot_follow_an_optional_parameter);
}
}
}
function checkGrammarFunctionLikeDeclaration(node) {
// Prevent cascading error by short-circuit
var file = ts.getSourceFileOfNode(node);
return checkGrammarDecorators(node) || checkGrammarModifiers(node) || checkGrammarTypeParameterList(node.typeParameters, file) ||
checkGrammarParameterList(node.parameters) || checkGrammarArrowFunction(node, file);
}
function checkGrammarArrowFunction(node, file) {
if (node.kind === 185 /* ArrowFunction */) {
var arrowFunction = node;
var startLine = ts.getLineAndCharacterOfPosition(file, arrowFunction.equalsGreaterThanToken.pos).line;
var endLine = ts.getLineAndCharacterOfPosition(file, arrowFunction.equalsGreaterThanToken.end).line;
if (startLine !== endLine) {
return grammarErrorOnNode(arrowFunction.equalsGreaterThanToken, ts.Diagnostics.Line_terminator_not_permitted_before_arrow);
}
}
return false;
}
function checkGrammarIndexSignatureParameters(node) {
var parameter = node.parameters[0];
if (node.parameters.length !== 1) {
if (parameter) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.An_index_signature_must_have_exactly_one_parameter);
}
else {
return grammarErrorOnNode(node, ts.Diagnostics.An_index_signature_must_have_exactly_one_parameter);
}
}
if (parameter.dotDotDotToken) {
return grammarErrorOnNode(parameter.dotDotDotToken, ts.Diagnostics.An_index_signature_cannot_have_a_rest_parameter);
}
if (ts.getModifierFlags(parameter) !== 0) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.An_index_signature_parameter_cannot_have_an_accessibility_modifier);
}
if (parameter.questionToken) {
return grammarErrorOnNode(parameter.questionToken, ts.Diagnostics.An_index_signature_parameter_cannot_have_a_question_mark);
}
if (parameter.initializer) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.An_index_signature_parameter_cannot_have_an_initializer);
}
if (!parameter.type) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.An_index_signature_parameter_must_have_a_type_annotation);
}
if (parameter.type.kind !== 134 /* StringKeyword */ && parameter.type.kind !== 132 /* NumberKeyword */) {
return grammarErrorOnNode(parameter.name, ts.Diagnostics.An_index_signature_parameter_type_must_be_string_or_number);
}
if (!node.type) {
return grammarErrorOnNode(node, ts.Diagnostics.An_index_signature_must_have_a_type_annotation);
}
}
function checkGrammarIndexSignature(node) {
// Prevent cascading error by short-circuit
return checkGrammarDecorators(node) || checkGrammarModifiers(node) || checkGrammarIndexSignatureParameters(node);
}
function checkGrammarForAtLeastOneTypeArgument(node, typeArguments) {
if (typeArguments && typeArguments.length === 0) {
var sourceFile = ts.getSourceFileOfNode(node);
var start = typeArguments.pos - "<".length;
var end = ts.skipTrivia(sourceFile.text, typeArguments.end) + ">".length;
return grammarErrorAtPos(sourceFile, start, end - start, ts.Diagnostics.Type_argument_list_cannot_be_empty);
}
}
function checkGrammarTypeArguments(node, typeArguments) {
return checkGrammarForDisallowedTrailingComma(typeArguments) ||
checkGrammarForAtLeastOneTypeArgument(node, typeArguments);
}
function checkGrammarForOmittedArgument(node, args) {
if (args) {
var sourceFile = ts.getSourceFileOfNode(node);
for (var _i = 0, args_4 = args; _i < args_4.length; _i++) {
var arg = args_4[_i];
if (arg.kind === 198 /* OmittedExpression */) {
return grammarErrorAtPos(sourceFile, arg.pos, 0, ts.Diagnostics.Argument_expression_expected);
}
}
}
}
function checkGrammarArguments(node, args) {
return checkGrammarForOmittedArgument(node, args);
}
function checkGrammarHeritageClause(node) {
var types = node.types;
if (checkGrammarForDisallowedTrailingComma(types)) {
return true;
}
if (types && types.length === 0) {
var listType = ts.tokenToString(node.token);
var sourceFile = ts.getSourceFileOfNode(node);
return grammarErrorAtPos(sourceFile, types.pos, 0, ts.Diagnostics._0_list_cannot_be_empty, listType);
}
}
function checkGrammarClassDeclarationHeritageClauses(node) {
var seenExtendsClause = false;
var seenImplementsClause = false;
if (!checkGrammarDecorators(node) && !checkGrammarModifiers(node) && node.heritageClauses) {
for (var _i = 0, _a = node.heritageClauses; _i < _a.length; _i++) {
var heritageClause = _a[_i];
if (heritageClause.token === 84 /* ExtendsKeyword */) {
if (seenExtendsClause) {
return grammarErrorOnFirstToken(heritageClause, ts.Diagnostics.extends_clause_already_seen);
}
if (seenImplementsClause) {
return grammarErrorOnFirstToken(heritageClause, ts.Diagnostics.extends_clause_must_precede_implements_clause);
}
if (heritageClause.types.length > 1) {
return grammarErrorOnFirstToken(heritageClause.types[1], ts.Diagnostics.Classes_can_only_extend_a_single_class);
}
seenExtendsClause = true;
}
else {
ts.Debug.assert(heritageClause.token === 107 /* ImplementsKeyword */);
if (seenImplementsClause) {
return grammarErrorOnFirstToken(heritageClause, ts.Diagnostics.implements_clause_already_seen);
}
seenImplementsClause = true;
}
// Grammar checking heritageClause inside class declaration
checkGrammarHeritageClause(heritageClause);
}
}
}
function checkGrammarInterfaceDeclaration(node) {
var seenExtendsClause = false;
if (node.heritageClauses) {
for (var _i = 0, _a = node.heritageClauses; _i < _a.length; _i++) {
var heritageClause = _a[_i];
if (heritageClause.token === 84 /* ExtendsKeyword */) {
if (seenExtendsClause) {
return grammarErrorOnFirstToken(heritageClause, ts.Diagnostics.extends_clause_already_seen);
}
seenExtendsClause = true;
}
else {
ts.Debug.assert(heritageClause.token === 107 /* ImplementsKeyword */);
return grammarErrorOnFirstToken(heritageClause, ts.Diagnostics.Interface_declaration_cannot_have_implements_clause);
}
// Grammar checking heritageClause inside class declaration
checkGrammarHeritageClause(heritageClause);
}
}
return false;
}
function checkGrammarComputedPropertyName(node) {
// If node is not a computedPropertyName, just skip the grammar checking
if (node.kind !== 142 /* ComputedPropertyName */) {
return false;
}
var computedPropertyName = node;
if (computedPropertyName.expression.kind === 192 /* BinaryExpression */ && computedPropertyName.expression.operatorToken.kind === 25 /* CommaToken */) {
return grammarErrorOnNode(computedPropertyName.expression, ts.Diagnostics.A_comma_expression_is_not_allowed_in_a_computed_property_name);
}
}
function checkGrammarForGenerator(node) {
if (node.asteriskToken) {
ts.Debug.assert(node.kind === 225 /* FunctionDeclaration */ ||
node.kind === 184 /* FunctionExpression */ ||
node.kind === 149 /* MethodDeclaration */);
if (ts.isInAmbientContext(node)) {
return grammarErrorOnNode(node.asteriskToken, ts.Diagnostics.Generators_are_not_allowed_in_an_ambient_context);
}
if (!node.body) {
return grammarErrorOnNode(node.asteriskToken, ts.Diagnostics.An_overload_signature_cannot_be_declared_as_a_generator);
}
if (languageVersion < 2 /* ES2015 */) {
return grammarErrorOnNode(node.asteriskToken, ts.Diagnostics.Generators_are_only_available_when_targeting_ECMAScript_2015_or_higher);
}
}
}
function checkGrammarForInvalidQuestionMark(questionToken, message) {
if (questionToken) {
return grammarErrorOnNode(questionToken, message);
}
}
function checkGrammarObjectLiteralExpression(node, inDestructuring) {
var seen = ts.createMap();
var Property = 1;
var GetAccessor = 2;
var SetAccessor = 4;
var GetOrSetAccessor = GetAccessor | SetAccessor;
for (var _i = 0, _a = node.properties; _i < _a.length; _i++) {
var prop = _a[_i];
if (prop.kind === 259 /* SpreadAssignment */) {
continue;
}
var name_28 = prop.name;
if (name_28.kind === 142 /* ComputedPropertyName */) {
// If the name is not a ComputedPropertyName, the grammar checking will skip it
checkGrammarComputedPropertyName(name_28);
}
if (prop.kind === 258 /* ShorthandPropertyAssignment */ && !inDestructuring && prop.objectAssignmentInitializer) {
// having objectAssignmentInitializer is only valid in ObjectAssignmentPattern
// outside of destructuring it is a syntax error
return grammarErrorOnNode(prop.equalsToken, ts.Diagnostics.can_only_be_used_in_an_object_literal_property_inside_a_destructuring_assignment);
}
// Modifiers are never allowed on properties except for 'async' on a method declaration
if (prop.modifiers) {
for (var _b = 0, _c = prop.modifiers; _b < _c.length; _b++) {
var mod = _c[_b];
if (mod.kind !== 119 /* AsyncKeyword */ || prop.kind !== 149 /* MethodDeclaration */) {
grammarErrorOnNode(mod, ts.Diagnostics._0_modifier_cannot_be_used_here, ts.getTextOfNode(mod));
}
}
}
// ECMA-262 11.1.5 Object Initializer
// If previous is not undefined then throw a SyntaxError exception if any of the following conditions are true
// a.This production is contained in strict code and IsDataDescriptor(previous) is true and
// IsDataDescriptor(propId.descriptor) is true.
// b.IsDataDescriptor(previous) is true and IsAccessorDescriptor(propId.descriptor) is true.
// c.IsAccessorDescriptor(previous) is true and IsDataDescriptor(propId.descriptor) is true.
// d.IsAccessorDescriptor(previous) is true and IsAccessorDescriptor(propId.descriptor) is true
// and either both previous and propId.descriptor have[[Get]] fields or both previous and propId.descriptor have[[Set]] fields
var currentKind = void 0;
if (prop.kind === 257 /* PropertyAssignment */ || prop.kind === 258 /* ShorthandPropertyAssignment */) {
// Grammar checking for computedPropertyName and shorthandPropertyAssignment
checkGrammarForInvalidQuestionMark(prop.questionToken, ts.Diagnostics.An_object_member_cannot_be_declared_optional);
if (name_28.kind === 8 /* NumericLiteral */) {
checkGrammarNumericLiteral(name_28);
}
currentKind = Property;
}
else if (prop.kind === 149 /* MethodDeclaration */) {
currentKind = Property;
}
else if (prop.kind === 151 /* GetAccessor */) {
currentKind = GetAccessor;
}
else if (prop.kind === 152 /* SetAccessor */) {
currentKind = SetAccessor;
}
else {
ts.Debug.fail("Unexpected syntax kind:" + prop.kind);
}
var effectiveName = ts.getPropertyNameForPropertyNameNode(name_28);
if (effectiveName === undefined) {
continue;
}
if (!seen[effectiveName]) {
seen[effectiveName] = currentKind;
}
else {
var existingKind = seen[effectiveName];
if (currentKind === Property && existingKind === Property) {
grammarErrorOnNode(name_28, ts.Diagnostics.Duplicate_identifier_0, ts.getTextOfNode(name_28));
}
else if ((currentKind & GetOrSetAccessor) && (existingKind & GetOrSetAccessor)) {
if (existingKind !== GetOrSetAccessor && currentKind !== existingKind) {
seen[effectiveName] = currentKind | existingKind;
}
else {
return grammarErrorOnNode(name_28, ts.Diagnostics.An_object_literal_cannot_have_multiple_get_Slashset_accessors_with_the_same_name);
}
}
else {
return grammarErrorOnNode(name_28, ts.Diagnostics.An_object_literal_cannot_have_property_and_accessor_with_the_same_name);
}
}
}
}
function checkGrammarJsxElement(node) {
var seen = ts.createMap();
for (var _i = 0, _a = node.attributes; _i < _a.length; _i++) {
var attr = _a[_i];
if (attr.kind === 251 /* JsxSpreadAttribute */) {
continue;
}
var jsxAttr = attr;
var name_29 = jsxAttr.name;
if (!seen[name_29.text]) {
seen[name_29.text] = true;
}
else {
return grammarErrorOnNode(name_29, ts.Diagnostics.JSX_elements_cannot_have_multiple_attributes_with_the_same_name);
}
var initializer = jsxAttr.initializer;
if (initializer && initializer.kind === 252 /* JsxExpression */ && !initializer.expression) {
return grammarErrorOnNode(jsxAttr.initializer, ts.Diagnostics.JSX_attributes_must_only_be_assigned_a_non_empty_expression);
}
}
}
function checkGrammarForInOrForOfStatement(forInOrOfStatement) {
if (checkGrammarStatementInAmbientContext(forInOrOfStatement)) {
return true;
}
if (forInOrOfStatement.initializer.kind === 224 /* VariableDeclarationList */) {
var variableList = forInOrOfStatement.initializer;
if (!checkGrammarVariableDeclarationList(variableList)) {
var declarations = variableList.declarations;
// declarations.length can be zero if there is an error in variable declaration in for-of or for-in
// See http://www.ecma-international.org/ecma-262/6.0/#sec-for-in-and-for-of-statements for details
// For example:
// var let = 10;
// for (let of [1,2,3]) {} // this is invalid ES6 syntax
// for (let in [1,2,3]) {} // this is invalid ES6 syntax
// We will then want to skip on grammar checking on variableList declaration
if (!declarations.length) {
return false;
}
if (declarations.length > 1) {
var diagnostic = forInOrOfStatement.kind === 212 /* ForInStatement */
? ts.Diagnostics.Only_a_single_variable_declaration_is_allowed_in_a_for_in_statement
: ts.Diagnostics.Only_a_single_variable_declaration_is_allowed_in_a_for_of_statement;
return grammarErrorOnFirstToken(variableList.declarations[1], diagnostic);
}
var firstDeclaration = declarations[0];
if (firstDeclaration.initializer) {
var diagnostic = forInOrOfStatement.kind === 212 /* ForInStatement */
? ts.Diagnostics.The_variable_declaration_of_a_for_in_statement_cannot_have_an_initializer
: ts.Diagnostics.The_variable_declaration_of_a_for_of_statement_cannot_have_an_initializer;
return grammarErrorOnNode(firstDeclaration.name, diagnostic);
}
if (firstDeclaration.type) {
var diagnostic = forInOrOfStatement.kind === 212 /* ForInStatement */
? ts.Diagnostics.The_left_hand_side_of_a_for_in_statement_cannot_use_a_type_annotation
: ts.Diagnostics.The_left_hand_side_of_a_for_of_statement_cannot_use_a_type_annotation;
return grammarErrorOnNode(firstDeclaration, diagnostic);
}
}
}
return false;
}
function checkGrammarAccessor(accessor) {
var kind = accessor.kind;
if (languageVersion < 1 /* ES5 */) {
return grammarErrorOnNode(accessor.name, ts.Diagnostics.Accessors_are_only_available_when_targeting_ECMAScript_5_and_higher);
}
else if (ts.isInAmbientContext(accessor)) {
return grammarErrorOnNode(accessor.name, ts.Diagnostics.An_accessor_cannot_be_declared_in_an_ambient_context);
}
else if (accessor.body === undefined && !(ts.getModifierFlags(accessor) & 128 /* Abstract */)) {
return grammarErrorAtPos(ts.getSourceFileOfNode(accessor), accessor.end - 1, ";".length, ts.Diagnostics._0_expected, "{");
}
else if (accessor.typeParameters) {
return grammarErrorOnNode(accessor.name, ts.Diagnostics.An_accessor_cannot_have_type_parameters);
}
else if (!doesAccessorHaveCorrectParameterCount(accessor)) {
return grammarErrorOnNode(accessor.name, kind === 151 /* GetAccessor */ ?
ts.Diagnostics.A_get_accessor_cannot_have_parameters :
ts.Diagnostics.A_set_accessor_must_have_exactly_one_parameter);
}
else if (kind === 152 /* SetAccessor */) {
if (accessor.type) {
return grammarErrorOnNode(accessor.name, ts.Diagnostics.A_set_accessor_cannot_have_a_return_type_annotation);
}
else {
var parameter = accessor.parameters[0];
if (parameter.dotDotDotToken) {
return grammarErrorOnNode(parameter.dotDotDotToken, ts.Diagnostics.A_set_accessor_cannot_have_rest_parameter);
}
else if (parameter.questionToken) {
return grammarErrorOnNode(parameter.questionToken, ts.Diagnostics.A_set_accessor_cannot_have_an_optional_parameter);
}
else if (parameter.initializer) {
return grammarErrorOnNode(accessor.name, ts.Diagnostics.A_set_accessor_parameter_cannot_have_an_initializer);
}
}
}
}
/** Does the accessor have the right number of parameters?
A get accessor has no parameters or a single `this` parameter.
A set accessor has one parameter or a `this` parameter and one more parameter */
function doesAccessorHaveCorrectParameterCount(accessor) {
return getAccessorThisParameter(accessor) || accessor.parameters.length === (accessor.kind === 151 /* GetAccessor */ ? 0 : 1);
}
function getAccessorThisParameter(accessor) {
if (accessor.parameters.length === (accessor.kind === 151 /* GetAccessor */ ? 1 : 2)) {
return ts.getThisParameter(accessor);
}
}
function checkGrammarForNonSymbolComputedProperty(node, message) {
if (ts.isDynamicName(node)) {
return grammarErrorOnNode(node, message);
}
}
function checkGrammarMethod(node) {
if (checkGrammarDisallowedModifiersOnObjectLiteralExpressionMethod(node) ||
checkGrammarFunctionLikeDeclaration(node) ||
checkGrammarForGenerator(node)) {
return true;
}
if (node.parent.kind === 176 /* ObjectLiteralExpression */) {
if (checkGrammarForInvalidQuestionMark(node.questionToken, ts.Diagnostics.An_object_member_cannot_be_declared_optional)) {
return true;
}
else if (node.body === undefined) {
return grammarErrorAtPos(ts.getSourceFileOfNode(node), node.end - 1, ";".length, ts.Diagnostics._0_expected, "{");
}
}
if (ts.isClassLike(node.parent)) {
// Technically, computed properties in ambient contexts is disallowed
// for property declarations and accessors too, not just methods.
// However, property declarations disallow computed names in general,
// and accessors are not allowed in ambient contexts in general,
// so this error only really matters for methods.
if (ts.isInAmbientContext(node)) {
return checkGrammarForNonSymbolComputedProperty(node.name, ts.Diagnostics.A_computed_property_name_in_an_ambient_context_must_directly_refer_to_a_built_in_symbol);
}
else if (!node.body) {
return checkGrammarForNonSymbolComputedProperty(node.name, ts.Diagnostics.A_computed_property_name_in_a_method_overload_must_directly_refer_to_a_built_in_symbol);
}
}
else if (node.parent.kind === 227 /* InterfaceDeclaration */) {
return checkGrammarForNonSymbolComputedProperty(node.name, ts.Diagnostics.A_computed_property_name_in_an_interface_must_directly_refer_to_a_built_in_symbol);
}
else if (node.parent.kind === 161 /* TypeLiteral */) {
return checkGrammarForNonSymbolComputedProperty(node.name, ts.Diagnostics.A_computed_property_name_in_a_type_literal_must_directly_refer_to_a_built_in_symbol);
}
}
function checkGrammarBreakOrContinueStatement(node) {
var current = node;
while (current) {
if (ts.isFunctionLike(current)) {
return grammarErrorOnNode(node, ts.Diagnostics.Jump_target_cannot_cross_function_boundary);
}
switch (current.kind) {
case 219 /* LabeledStatement */:
if (node.label && current.label.text === node.label.text) {
// found matching label - verify that label usage is correct
// continue can only target labels that are on iteration statements
var isMisplacedContinueLabel = node.kind === 214 /* ContinueStatement */
&& !ts.isIterationStatement(current.statement, /*lookInLabeledStatement*/ true);
if (isMisplacedContinueLabel) {
return grammarErrorOnNode(node, ts.Diagnostics.A_continue_statement_can_only_jump_to_a_label_of_an_enclosing_iteration_statement);
}
return false;
}
break;
case 218 /* SwitchStatement */:
if (node.kind === 215 /* BreakStatement */ && !node.label) {
// unlabeled break within switch statement - ok
return false;
}
break;
default:
if (ts.isIterationStatement(current, /*lookInLabeledStatement*/ false) && !node.label) {
// unlabeled break or continue within iteration statement - ok
return false;
}
break;
}
current = current.parent;
}
if (node.label) {
var message = node.kind === 215 /* BreakStatement */
? ts.Diagnostics.A_break_statement_can_only_jump_to_a_label_of_an_enclosing_statement
: ts.Diagnostics.A_continue_statement_can_only_jump_to_a_label_of_an_enclosing_iteration_statement;
return grammarErrorOnNode(node, message);
}
else {
var message = node.kind === 215 /* BreakStatement */
? ts.Diagnostics.A_break_statement_can_only_be_used_within_an_enclosing_iteration_or_switch_statement
: ts.Diagnostics.A_continue_statement_can_only_be_used_within_an_enclosing_iteration_statement;
return grammarErrorOnNode(node, message);
}
}
function checkGrammarBindingElement(node) {
if (node.dotDotDotToken) {
var elements = node.parent.elements;
if (node !== ts.lastOrUndefined(elements)) {
return grammarErrorOnNode(node, ts.Diagnostics.A_rest_element_must_be_last_in_a_destructuring_pattern);
}
if (node.name.kind === 173 /* ArrayBindingPattern */ || node.name.kind === 172 /* ObjectBindingPattern */) {
return grammarErrorOnNode(node.name, ts.Diagnostics.A_rest_element_cannot_contain_a_binding_pattern);
}
if (node.initializer) {
// Error on equals token which immediately precedes the initializer
return grammarErrorAtPos(ts.getSourceFileOfNode(node), node.initializer.pos - 1, 1, ts.Diagnostics.A_rest_element_cannot_have_an_initializer);
}
}
}
function isStringOrNumberLiteralExpression(expr) {
return expr.kind === 9 /* StringLiteral */ || expr.kind === 8 /* NumericLiteral */ ||
expr.kind === 190 /* PrefixUnaryExpression */ && expr.operator === 37 /* MinusToken */ &&
expr.operand.kind === 8 /* NumericLiteral */;
}
function checkGrammarVariableDeclaration(node) {
if (node.parent.parent.kind !== 212 /* ForInStatement */ && node.parent.parent.kind !== 213 /* ForOfStatement */) {
if (ts.isInAmbientContext(node)) {
if (node.initializer) {
if (ts.isConst(node) && !node.type) {
if (!isStringOrNumberLiteralExpression(node.initializer)) {
return grammarErrorOnNode(node.initializer, ts.Diagnostics.A_const_initializer_in_an_ambient_context_must_be_a_string_or_numeric_literal);
}
}
else {
// Error on equals token which immediate precedes the initializer
var equalsTokenLength = "=".length;
return grammarErrorAtPos(ts.getSourceFileOfNode(node), node.initializer.pos - equalsTokenLength, equalsTokenLength, ts.Diagnostics.Initializers_are_not_allowed_in_ambient_contexts);
}
}
if (node.initializer && !(ts.isConst(node) && isStringOrNumberLiteralExpression(node.initializer))) {
// Error on equals token which immediate precedes the initializer
var equalsTokenLength = "=".length;
return grammarErrorAtPos(ts.getSourceFileOfNode(node), node.initializer.pos - equalsTokenLength, equalsTokenLength, ts.Diagnostics.Initializers_are_not_allowed_in_ambient_contexts);
}
}
else if (!node.initializer) {
if (ts.isBindingPattern(node.name) && !ts.isBindingPattern(node.parent)) {
return grammarErrorOnNode(node, ts.Diagnostics.A_destructuring_declaration_must_have_an_initializer);
}
if (ts.isConst(node)) {
return grammarErrorOnNode(node, ts.Diagnostics.const_declarations_must_be_initialized);
}
}
}
var checkLetConstNames = (ts.isLet(node) || ts.isConst(node));
// 1. LexicalDeclaration : LetOrConst BindingList ;
// It is a Syntax Error if the BoundNames of BindingList contains "let".
// 2. ForDeclaration: ForDeclaration : LetOrConst ForBinding
// It is a Syntax Error if the BoundNames of ForDeclaration contains "let".
// It is a SyntaxError if a VariableDeclaration or VariableDeclarationNoIn occurs within strict code
// and its Identifier is eval or arguments
return checkLetConstNames && checkGrammarNameInLetOrConstDeclarations(node.name);
}
function checkGrammarNameInLetOrConstDeclarations(name) {
if (name.kind === 70 /* Identifier */) {
if (name.originalKeywordKind === 109 /* LetKeyword */) {
return grammarErrorOnNode(name, ts.Diagnostics.let_is_not_allowed_to_be_used_as_a_name_in_let_or_const_declarations);
}
}
else {
var elements = name.elements;
for (var _i = 0, elements_2 = elements; _i < elements_2.length; _i++) {
var element = elements_2[_i];
if (!ts.isOmittedExpression(element)) {
checkGrammarNameInLetOrConstDeclarations(element.name);
}
}
}
}
function checkGrammarVariableDeclarationList(declarationList) {
var declarations = declarationList.declarations;
if (checkGrammarForDisallowedTrailingComma(declarationList.declarations)) {
return true;
}
if (!declarationList.declarations.length) {
return grammarErrorAtPos(ts.getSourceFileOfNode(declarationList), declarations.pos, declarations.end - declarations.pos, ts.Diagnostics.Variable_declaration_list_cannot_be_empty);
}
}
function allowLetAndConstDeclarations(parent) {
switch (parent.kind) {
case 208 /* IfStatement */:
case 209 /* DoStatement */:
case 210 /* WhileStatement */:
case 217 /* WithStatement */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
return false;
case 219 /* LabeledStatement */:
return allowLetAndConstDeclarations(parent.parent);
}
return true;
}
function checkGrammarForDisallowedLetOrConstStatement(node) {
if (!allowLetAndConstDeclarations(node.parent)) {
if (ts.isLet(node.declarationList)) {
return grammarErrorOnNode(node, ts.Diagnostics.let_declarations_can_only_be_declared_inside_a_block);
}
else if (ts.isConst(node.declarationList)) {
return grammarErrorOnNode(node, ts.Diagnostics.const_declarations_can_only_be_declared_inside_a_block);
}
}
}
function hasParseDiagnostics(sourceFile) {
return sourceFile.parseDiagnostics.length > 0;
}
function grammarErrorOnFirstToken(node, message, arg0, arg1, arg2) {
var sourceFile = ts.getSourceFileOfNode(node);
if (!hasParseDiagnostics(sourceFile)) {
var span_4 = ts.getSpanOfTokenAtPosition(sourceFile, node.pos);
diagnostics.add(ts.createFileDiagnostic(sourceFile, span_4.start, span_4.length, message, arg0, arg1, arg2));
return true;
}
}
function grammarErrorAtPos(sourceFile, start, length, message, arg0, arg1, arg2) {
if (!hasParseDiagnostics(sourceFile)) {
diagnostics.add(ts.createFileDiagnostic(sourceFile, start, length, message, arg0, arg1, arg2));
return true;
}
}
function grammarErrorOnNode(node, message, arg0, arg1, arg2) {
var sourceFile = ts.getSourceFileOfNode(node);
if (!hasParseDiagnostics(sourceFile)) {
diagnostics.add(ts.createDiagnosticForNode(node, message, arg0, arg1, arg2));
return true;
}
}
function checkGrammarConstructorTypeParameters(node) {
if (node.typeParameters) {
return grammarErrorAtPos(ts.getSourceFileOfNode(node), node.typeParameters.pos, node.typeParameters.end - node.typeParameters.pos, ts.Diagnostics.Type_parameters_cannot_appear_on_a_constructor_declaration);
}
}
function checkGrammarConstructorTypeAnnotation(node) {
if (node.type) {
return grammarErrorOnNode(node.type, ts.Diagnostics.Type_annotation_cannot_appear_on_a_constructor_declaration);
}
}
function checkGrammarProperty(node) {
if (ts.isClassLike(node.parent)) {
if (checkGrammarForNonSymbolComputedProperty(node.name, ts.Diagnostics.A_computed_property_name_in_a_class_property_declaration_must_directly_refer_to_a_built_in_symbol)) {
return true;
}
}
else if (node.parent.kind === 227 /* InterfaceDeclaration */) {
if (checkGrammarForNonSymbolComputedProperty(node.name, ts.Diagnostics.A_computed_property_name_in_an_interface_must_directly_refer_to_a_built_in_symbol)) {
return true;
}
if (node.initializer) {
return grammarErrorOnNode(node.initializer, ts.Diagnostics.An_interface_property_cannot_have_an_initializer);
}
}
else if (node.parent.kind === 161 /* TypeLiteral */) {
if (checkGrammarForNonSymbolComputedProperty(node.name, ts.Diagnostics.A_computed_property_name_in_a_type_literal_must_directly_refer_to_a_built_in_symbol)) {
return true;
}
if (node.initializer) {
return grammarErrorOnNode(node.initializer, ts.Diagnostics.A_type_literal_property_cannot_have_an_initializer);
}
}
if (ts.isInAmbientContext(node) && node.initializer) {
return grammarErrorOnFirstToken(node.initializer, ts.Diagnostics.Initializers_are_not_allowed_in_ambient_contexts);
}
}
function checkGrammarTopLevelElementForRequiredDeclareModifier(node) {
// A declare modifier is required for any top level .d.ts declaration except export=, export default, export as namespace
// interfaces and imports categories:
//
// DeclarationElement:
// ExportAssignment
// export_opt InterfaceDeclaration
// export_opt TypeAliasDeclaration
// export_opt ImportDeclaration
// export_opt ExternalImportDeclaration
// export_opt AmbientDeclaration
//
// TODO: The spec needs to be amended to reflect this grammar.
if (node.kind === 227 /* InterfaceDeclaration */ ||
node.kind === 228 /* TypeAliasDeclaration */ ||
node.kind === 235 /* ImportDeclaration */ ||
node.kind === 234 /* ImportEqualsDeclaration */ ||
node.kind === 241 /* ExportDeclaration */ ||
node.kind === 240 /* ExportAssignment */ ||
node.kind === 233 /* NamespaceExportDeclaration */ ||
ts.getModifierFlags(node) & (2 /* Ambient */ | 1 /* Export */ | 512 /* Default */)) {
return false;
}
return grammarErrorOnFirstToken(node, ts.Diagnostics.A_declare_modifier_is_required_for_a_top_level_declaration_in_a_d_ts_file);
}
function checkGrammarTopLevelElementsForRequiredDeclareModifier(file) {
for (var _i = 0, _a = file.statements; _i < _a.length; _i++) {
var decl = _a[_i];
if (ts.isDeclaration(decl) || decl.kind === 205 /* VariableStatement */) {
if (checkGrammarTopLevelElementForRequiredDeclareModifier(decl)) {
return true;
}
}
}
}
function checkGrammarSourceFile(node) {
return ts.isInAmbientContext(node) && checkGrammarTopLevelElementsForRequiredDeclareModifier(node);
}
function checkGrammarStatementInAmbientContext(node) {
if (ts.isInAmbientContext(node)) {
// An accessors is already reported about the ambient context
if (isAccessor(node.parent.kind)) {
return getNodeLinks(node).hasReportedStatementInAmbientContext = true;
}
// Find containing block which is either Block, ModuleBlock, SourceFile
var links = getNodeLinks(node);
if (!links.hasReportedStatementInAmbientContext && ts.isFunctionLike(node.parent)) {
return getNodeLinks(node).hasReportedStatementInAmbientContext = grammarErrorOnFirstToken(node, ts.Diagnostics.An_implementation_cannot_be_declared_in_ambient_contexts);
}
// We are either parented by another statement, or some sort of block.
// If we're in a block, we only want to really report an error once
// to prevent noisiness. So use a bit on the block to indicate if
// this has already been reported, and don't report if it has.
//
if (node.parent.kind === 204 /* Block */ || node.parent.kind === 231 /* ModuleBlock */ || node.parent.kind === 261 /* SourceFile */) {
var links_1 = getNodeLinks(node.parent);
// Check if the containing block ever report this error
if (!links_1.hasReportedStatementInAmbientContext) {
return links_1.hasReportedStatementInAmbientContext = grammarErrorOnFirstToken(node, ts.Diagnostics.Statements_are_not_allowed_in_ambient_contexts);
}
}
else {
}
}
}
function checkGrammarNumericLiteral(node) {
// Grammar checking
if (node.isOctalLiteral && languageVersion >= 1 /* ES5 */) {
return grammarErrorOnNode(node, ts.Diagnostics.Octal_literals_are_not_available_when_targeting_ECMAScript_5_and_higher);
}
}
function grammarErrorAfterFirstToken(node, message, arg0, arg1, arg2) {
var sourceFile = ts.getSourceFileOfNode(node);
if (!hasParseDiagnostics(sourceFile)) {
var span_5 = ts.getSpanOfTokenAtPosition(sourceFile, node.pos);
diagnostics.add(ts.createFileDiagnostic(sourceFile, ts.textSpanEnd(span_5), /*length*/ 0, message, arg0, arg1, arg2));
return true;
}
}
function getAmbientModules() {
var result = [];
for (var sym in globals) {
if (ambientModuleSymbolRegex.test(sym)) {
result.push(globals[sym]);
}
}
return result;
}
}
ts.createTypeChecker = createTypeChecker;
})(ts || (ts = {}));
/// <reference path="checker.ts" />
/// <reference path="factory.ts" />
/// <reference path="utilities.ts" />
/* @internal */
var ts;
(function (ts) {
;
/**
* This map contains information about the shape of each Node in "types.ts" pertaining to how
* each node should be traversed during a transformation.
*
* Each edge corresponds to a property in a Node subtype that should be traversed when visiting
* each child. The properties are assigned in the order in which traversal should occur.
*
* We only add entries for nodes that do not have a create/update pair defined in factory.ts
*
* NOTE: This needs to be kept up to date with changes to nodes in "types.ts". Currently, this
* map is not comprehensive. Only node edges relevant to tree transformation are
* currently defined. We may extend this to be more comprehensive, and eventually
* supplant the existing `forEachChild` implementation if performance is not
* significantly impacted.
*/
var nodeEdgeTraversalMap = ts.createMap((_a = {},
_a[141 /* QualifiedName */] = [
{ name: "left", test: ts.isEntityName },
{ name: "right", test: ts.isIdentifier }
],
_a[145 /* Decorator */] = [
{ name: "expression", test: ts.isLeftHandSideExpression }
],
_a[182 /* TypeAssertionExpression */] = [
{ name: "type", test: ts.isTypeNode },
{ name: "expression", test: ts.isUnaryExpression }
],
_a[200 /* AsExpression */] = [
{ name: "expression", test: ts.isExpression },
{ name: "type", test: ts.isTypeNode }
],
_a[201 /* NonNullExpression */] = [
{ name: "expression", test: ts.isLeftHandSideExpression }
],
_a[229 /* EnumDeclaration */] = [
{ name: "decorators", test: ts.isDecorator },
{ name: "modifiers", test: ts.isModifier },
{ name: "name", test: ts.isIdentifier },
{ name: "members", test: ts.isEnumMember }
],
_a[230 /* ModuleDeclaration */] = [
{ name: "decorators", test: ts.isDecorator },
{ name: "modifiers", test: ts.isModifier },
{ name: "name", test: ts.isModuleName },
{ name: "body", test: ts.isModuleBody }
],
_a[231 /* ModuleBlock */] = [
{ name: "statements", test: ts.isStatement }
],
_a[234 /* ImportEqualsDeclaration */] = [
{ name: "decorators", test: ts.isDecorator },
{ name: "modifiers", test: ts.isModifier },
{ name: "name", test: ts.isIdentifier },
{ name: "moduleReference", test: ts.isModuleReference }
],
_a[245 /* ExternalModuleReference */] = [
{ name: "expression", test: ts.isExpression, optional: true }
],
_a[260 /* EnumMember */] = [
{ name: "name", test: ts.isPropertyName },
{ name: "initializer", test: ts.isExpression, optional: true, parenthesize: ts.parenthesizeExpressionForList }
],
_a));
function reduceNode(node, f, initial) {
return node ? f(initial, node) : initial;
}
/**
* Similar to `reduceLeft`, performs a reduction against each child of a node.
* NOTE: Unlike `forEachChild`, this does *not* visit every node. Only nodes added to the
* `nodeEdgeTraversalMap` above will be visited.
*
* @param node The node containing the children to reduce.
* @param f The callback function
* @param initial The initial value to supply to the reduction.
*/
function reduceEachChild(node, f, initial) {
if (node === undefined) {
return initial;
}
var kind = node.kind;
// No need to visit nodes with no children.
if ((kind > 0 /* FirstToken */ && kind <= 140 /* LastToken */)) {
return initial;
}
// We do not yet support types.
if ((kind >= 156 /* TypePredicate */ && kind <= 171 /* LiteralType */)) {
return initial;
}
var result = initial;
switch (node.kind) {
// Leaf nodes
case 203 /* SemicolonClassElement */:
case 206 /* EmptyStatement */:
case 198 /* OmittedExpression */:
case 222 /* DebuggerStatement */:
case 292 /* NotEmittedStatement */:
// No need to visit nodes with no children.
break;
// Names
case 142 /* ComputedPropertyName */:
result = reduceNode(node.expression, f, result);
break;
// Signature elements
case 144 /* Parameter */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.initializer, f, result);
break;
case 145 /* Decorator */:
result = reduceNode(node.expression, f, result);
break;
// Type member
case 147 /* PropertyDeclaration */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.initializer, f, result);
break;
case 149 /* MethodDeclaration */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = ts.reduceLeft(node.typeParameters, f, result);
result = ts.reduceLeft(node.parameters, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.body, f, result);
break;
case 150 /* Constructor */:
result = ts.reduceLeft(node.modifiers, f, result);
result = ts.reduceLeft(node.parameters, f, result);
result = reduceNode(node.body, f, result);
break;
case 151 /* GetAccessor */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = ts.reduceLeft(node.parameters, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.body, f, result);
break;
case 152 /* SetAccessor */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = ts.reduceLeft(node.parameters, f, result);
result = reduceNode(node.body, f, result);
break;
// Binding patterns
case 172 /* ObjectBindingPattern */:
case 173 /* ArrayBindingPattern */:
result = ts.reduceLeft(node.elements, f, result);
break;
case 174 /* BindingElement */:
result = reduceNode(node.propertyName, f, result);
result = reduceNode(node.name, f, result);
result = reduceNode(node.initializer, f, result);
break;
// Expression
case 175 /* ArrayLiteralExpression */:
result = ts.reduceLeft(node.elements, f, result);
break;
case 176 /* ObjectLiteralExpression */:
result = ts.reduceLeft(node.properties, f, result);
break;
case 177 /* PropertyAccessExpression */:
result = reduceNode(node.expression, f, result);
result = reduceNode(node.name, f, result);
break;
case 178 /* ElementAccessExpression */:
result = reduceNode(node.expression, f, result);
result = reduceNode(node.argumentExpression, f, result);
break;
case 179 /* CallExpression */:
result = reduceNode(node.expression, f, result);
result = ts.reduceLeft(node.typeArguments, f, result);
result = ts.reduceLeft(node.arguments, f, result);
break;
case 180 /* NewExpression */:
result = reduceNode(node.expression, f, result);
result = ts.reduceLeft(node.typeArguments, f, result);
result = ts.reduceLeft(node.arguments, f, result);
break;
case 181 /* TaggedTemplateExpression */:
result = reduceNode(node.tag, f, result);
result = reduceNode(node.template, f, result);
break;
case 184 /* FunctionExpression */:
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = ts.reduceLeft(node.typeParameters, f, result);
result = ts.reduceLeft(node.parameters, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.body, f, result);
break;
case 185 /* ArrowFunction */:
result = ts.reduceLeft(node.modifiers, f, result);
result = ts.reduceLeft(node.typeParameters, f, result);
result = ts.reduceLeft(node.parameters, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.body, f, result);
break;
case 183 /* ParenthesizedExpression */:
case 186 /* DeleteExpression */:
case 187 /* TypeOfExpression */:
case 188 /* VoidExpression */:
case 189 /* AwaitExpression */:
case 195 /* YieldExpression */:
case 196 /* SpreadElement */:
case 201 /* NonNullExpression */:
result = reduceNode(node.expression, f, result);
break;
case 190 /* PrefixUnaryExpression */:
case 191 /* PostfixUnaryExpression */:
result = reduceNode(node.operand, f, result);
break;
case 192 /* BinaryExpression */:
result = reduceNode(node.left, f, result);
result = reduceNode(node.right, f, result);
break;
case 193 /* ConditionalExpression */:
result = reduceNode(node.condition, f, result);
result = reduceNode(node.whenTrue, f, result);
result = reduceNode(node.whenFalse, f, result);
break;
case 194 /* TemplateExpression */:
result = reduceNode(node.head, f, result);
result = ts.reduceLeft(node.templateSpans, f, result);
break;
case 197 /* ClassExpression */:
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = ts.reduceLeft(node.typeParameters, f, result);
result = ts.reduceLeft(node.heritageClauses, f, result);
result = ts.reduceLeft(node.members, f, result);
break;
case 199 /* ExpressionWithTypeArguments */:
result = reduceNode(node.expression, f, result);
result = ts.reduceLeft(node.typeArguments, f, result);
break;
// Misc
case 202 /* TemplateSpan */:
result = reduceNode(node.expression, f, result);
result = reduceNode(node.literal, f, result);
break;
// Element
case 204 /* Block */:
result = ts.reduceLeft(node.statements, f, result);
break;
case 205 /* VariableStatement */:
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.declarationList, f, result);
break;
case 207 /* ExpressionStatement */:
result = reduceNode(node.expression, f, result);
break;
case 208 /* IfStatement */:
result = reduceNode(node.expression, f, result);
result = reduceNode(node.thenStatement, f, result);
result = reduceNode(node.elseStatement, f, result);
break;
case 209 /* DoStatement */:
result = reduceNode(node.statement, f, result);
result = reduceNode(node.expression, f, result);
break;
case 210 /* WhileStatement */:
case 217 /* WithStatement */:
result = reduceNode(node.expression, f, result);
result = reduceNode(node.statement, f, result);
break;
case 211 /* ForStatement */:
result = reduceNode(node.initializer, f, result);
result = reduceNode(node.condition, f, result);
result = reduceNode(node.incrementor, f, result);
result = reduceNode(node.statement, f, result);
break;
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
result = reduceNode(node.initializer, f, result);
result = reduceNode(node.expression, f, result);
result = reduceNode(node.statement, f, result);
break;
case 216 /* ReturnStatement */:
case 220 /* ThrowStatement */:
result = reduceNode(node.expression, f, result);
break;
case 218 /* SwitchStatement */:
result = reduceNode(node.expression, f, result);
result = reduceNode(node.caseBlock, f, result);
break;
case 219 /* LabeledStatement */:
result = reduceNode(node.label, f, result);
result = reduceNode(node.statement, f, result);
break;
case 221 /* TryStatement */:
result = reduceNode(node.tryBlock, f, result);
result = reduceNode(node.catchClause, f, result);
result = reduceNode(node.finallyBlock, f, result);
break;
case 223 /* VariableDeclaration */:
result = reduceNode(node.name, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.initializer, f, result);
break;
case 224 /* VariableDeclarationList */:
result = ts.reduceLeft(node.declarations, f, result);
break;
case 225 /* FunctionDeclaration */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = ts.reduceLeft(node.typeParameters, f, result);
result = ts.reduceLeft(node.parameters, f, result);
result = reduceNode(node.type, f, result);
result = reduceNode(node.body, f, result);
break;
case 226 /* ClassDeclaration */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.name, f, result);
result = ts.reduceLeft(node.typeParameters, f, result);
result = ts.reduceLeft(node.heritageClauses, f, result);
result = ts.reduceLeft(node.members, f, result);
break;
case 232 /* CaseBlock */:
result = ts.reduceLeft(node.clauses, f, result);
break;
case 235 /* ImportDeclaration */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.importClause, f, result);
result = reduceNode(node.moduleSpecifier, f, result);
break;
case 236 /* ImportClause */:
result = reduceNode(node.name, f, result);
result = reduceNode(node.namedBindings, f, result);
break;
case 237 /* NamespaceImport */:
result = reduceNode(node.name, f, result);
break;
case 238 /* NamedImports */:
case 242 /* NamedExports */:
result = ts.reduceLeft(node.elements, f, result);
break;
case 239 /* ImportSpecifier */:
case 243 /* ExportSpecifier */:
result = reduceNode(node.propertyName, f, result);
result = reduceNode(node.name, f, result);
break;
case 240 /* ExportAssignment */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.expression, f, result);
break;
case 241 /* ExportDeclaration */:
result = ts.reduceLeft(node.decorators, f, result);
result = ts.reduceLeft(node.modifiers, f, result);
result = reduceNode(node.exportClause, f, result);
result = reduceNode(node.moduleSpecifier, f, result);
break;
// JSX
case 246 /* JsxElement */:
result = reduceNode(node.openingElement, f, result);
result = ts.reduceLeft(node.children, f, result);
result = reduceNode(node.closingElement, f, result);
break;
case 247 /* JsxSelfClosingElement */:
case 248 /* JsxOpeningElement */:
result = reduceNode(node.tagName, f, result);
result = ts.reduceLeft(node.attributes, f, result);
break;
case 249 /* JsxClosingElement */:
result = reduceNode(node.tagName, f, result);
break;
case 250 /* JsxAttribute */:
result = reduceNode(node.name, f, result);
result = reduceNode(node.initializer, f, result);
break;
case 251 /* JsxSpreadAttribute */:
result = reduceNode(node.expression, f, result);
break;
case 252 /* JsxExpression */:
result = reduceNode(node.expression, f, result);
break;
// Clauses
case 253 /* CaseClause */:
result = reduceNode(node.expression, f, result);
// fall-through
case 254 /* DefaultClause */:
result = ts.reduceLeft(node.statements, f, result);
break;
case 255 /* HeritageClause */:
result = ts.reduceLeft(node.types, f, result);
break;
case 256 /* CatchClause */:
result = reduceNode(node.variableDeclaration, f, result);
result = reduceNode(node.block, f, result);
break;
// Property assignments
case 257 /* PropertyAssignment */:
result = reduceNode(node.name, f, result);
result = reduceNode(node.initializer, f, result);
break;
case 258 /* ShorthandPropertyAssignment */:
result = reduceNode(node.name, f, result);
result = reduceNode(node.objectAssignmentInitializer, f, result);
break;
case 259 /* SpreadAssignment */:
result = reduceNode(node.expression, f, result);
break;
// Top-level nodes
case 261 /* SourceFile */:
result = ts.reduceLeft(node.statements, f, result);
break;
case 293 /* PartiallyEmittedExpression */:
result = reduceNode(node.expression, f, result);
break;
default:
var edgeTraversalPath = nodeEdgeTraversalMap[kind];
if (edgeTraversalPath) {
for (var _i = 0, edgeTraversalPath_1 = edgeTraversalPath; _i < edgeTraversalPath_1.length; _i++) {
var edge = edgeTraversalPath_1[_i];
var value = node[edge.name];
if (value !== undefined) {
result = ts.isArray(value)
? ts.reduceLeft(value, f, result)
: f(result, value);
}
}
}
break;
}
return result;
}
ts.reduceEachChild = reduceEachChild;
function visitNode(node, visitor, test, optional, lift, parenthesize, parentNode) {
if (node === undefined) {
return undefined;
}
aggregateTransformFlags(node);
var visited = visitor(node);
if (visited === node) {
return node;
}
var visitedNode;
if (visited === undefined) {
if (!optional) {
Debug.failNotOptional();
}
return undefined;
}
else if (ts.isArray(visited)) {
visitedNode = (lift || extractSingleNode)(visited);
}
else {
visitedNode = visited;
}
if (parenthesize !== undefined) {
visitedNode = parenthesize(visitedNode, parentNode);
}
Debug.assertNode(visitedNode, test);
aggregateTransformFlags(visitedNode);
return visitedNode;
}
ts.visitNode = visitNode;
function visitNodes(nodes, visitor, test, start, count, parenthesize, parentNode) {
if (nodes === undefined) {
return undefined;
}
var updated;
// Ensure start and count have valid values
var length = nodes.length;
if (start === undefined || start < 0) {
start = 0;
}
if (count === undefined || count > length - start) {
count = length - start;
}
if (start > 0 || count < length) {
// If we are not visiting all of the original nodes, we must always create a new array.
// Since this is a fragment of a node array, we do not copy over the previous location
// and will only copy over `hasTrailingComma` if we are including the last element.
updated = ts.createNodeArray([], /*location*/ undefined,
/*hasTrailingComma*/ nodes.hasTrailingComma && start + count === length);
}
// Visit each original node.
for (var i = 0; i < count; i++) {
var node = nodes[i + start];
aggregateTransformFlags(node);
var visited = node !== undefined ? visitor(node) : undefined;
if (updated !== undefined || visited === undefined || visited !== node) {
if (updated === undefined) {
// Ensure we have a copy of `nodes`, up to the current index.
updated = ts.createNodeArray(nodes.slice(0, i), /*location*/ nodes, nodes.hasTrailingComma);
}
if (visited) {
if (ts.isArray(visited)) {
for (var _i = 0, visited_1 = visited; _i < visited_1.length; _i++) {
var visitedNode = visited_1[_i];
visitedNode = parenthesize
? parenthesize(visitedNode, parentNode)
: visitedNode;
Debug.assertNode(visitedNode, test);
aggregateTransformFlags(visitedNode);
updated.push(visitedNode);
}
}
else {
var visitedNode = parenthesize
? parenthesize(visited, parentNode)
: visited;
Debug.assertNode(visitedNode, test);
aggregateTransformFlags(visitedNode);
updated.push(visitedNode);
}
}
}
}
return updated || nodes;
}
ts.visitNodes = visitNodes;
function visitEachChild(node, visitor, context) {
if (node === undefined) {
return undefined;
}
var kind = node.kind;
// No need to visit nodes with no children.
if ((kind > 0 /* FirstToken */ && kind <= 140 /* LastToken */)) {
return node;
}
// We do not yet support types.
if ((kind >= 156 /* TypePredicate */ && kind <= 171 /* LiteralType */)) {
return node;
}
switch (node.kind) {
case 203 /* SemicolonClassElement */:
case 206 /* EmptyStatement */:
case 198 /* OmittedExpression */:
case 222 /* DebuggerStatement */:
// No need to visit nodes with no children.
return node;
// Names
case 142 /* ComputedPropertyName */:
return ts.updateComputedPropertyName(node, visitNode(node.expression, visitor, ts.isExpression));
// Signature elements
case 144 /* Parameter */:
return ts.updateParameter(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isBindingName), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), visitNode(node.initializer, visitor, ts.isExpression, /*optional*/ true));
// Type member
case 147 /* PropertyDeclaration */:
return ts.updateProperty(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isPropertyName), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), visitNode(node.initializer, visitor, ts.isExpression, /*optional*/ true));
case 149 /* MethodDeclaration */:
return ts.updateMethod(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isPropertyName), visitNodes(node.typeParameters, visitor, ts.isTypeParameter), (context.startLexicalEnvironment(), visitNodes(node.parameters, visitor, ts.isParameter)), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), mergeFunctionBodyLexicalEnvironment(visitNode(node.body, visitor, ts.isFunctionBody, /*optional*/ true), context.endLexicalEnvironment()));
case 150 /* Constructor */:
return ts.updateConstructor(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), (context.startLexicalEnvironment(), visitNodes(node.parameters, visitor, ts.isParameter)), mergeFunctionBodyLexicalEnvironment(visitNode(node.body, visitor, ts.isFunctionBody, /*optional*/ true), context.endLexicalEnvironment()));
case 151 /* GetAccessor */:
return ts.updateGetAccessor(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isPropertyName), (context.startLexicalEnvironment(), visitNodes(node.parameters, visitor, ts.isParameter)), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), mergeFunctionBodyLexicalEnvironment(visitNode(node.body, visitor, ts.isFunctionBody, /*optional*/ true), context.endLexicalEnvironment()));
case 152 /* SetAccessor */:
return ts.updateSetAccessor(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isPropertyName), (context.startLexicalEnvironment(), visitNodes(node.parameters, visitor, ts.isParameter)), mergeFunctionBodyLexicalEnvironment(visitNode(node.body, visitor, ts.isFunctionBody, /*optional*/ true), context.endLexicalEnvironment()));
// Binding patterns
case 172 /* ObjectBindingPattern */:
return ts.updateObjectBindingPattern(node, visitNodes(node.elements, visitor, ts.isBindingElement));
case 173 /* ArrayBindingPattern */:
return ts.updateArrayBindingPattern(node, visitNodes(node.elements, visitor, ts.isArrayBindingElement));
case 174 /* BindingElement */:
return ts.updateBindingElement(node, visitNode(node.propertyName, visitor, ts.isPropertyName, /*optional*/ true), visitNode(node.name, visitor, ts.isBindingName), visitNode(node.initializer, visitor, ts.isExpression, /*optional*/ true));
// Expression
case 175 /* ArrayLiteralExpression */:
return ts.updateArrayLiteral(node, visitNodes(node.elements, visitor, ts.isExpression));
case 176 /* ObjectLiteralExpression */:
return ts.updateObjectLiteral(node, visitNodes(node.properties, visitor, ts.isObjectLiteralElementLike));
case 177 /* PropertyAccessExpression */:
return ts.updatePropertyAccess(node, visitNode(node.expression, visitor, ts.isExpression), visitNode(node.name, visitor, ts.isIdentifier));
case 178 /* ElementAccessExpression */:
return ts.updateElementAccess(node, visitNode(node.expression, visitor, ts.isExpression), visitNode(node.argumentExpression, visitor, ts.isExpression));
case 179 /* CallExpression */:
return ts.updateCall(node, visitNode(node.expression, visitor, ts.isExpression), visitNodes(node.typeArguments, visitor, ts.isTypeNode), visitNodes(node.arguments, visitor, ts.isExpression));
case 180 /* NewExpression */:
return ts.updateNew(node, visitNode(node.expression, visitor, ts.isExpression), visitNodes(node.typeArguments, visitor, ts.isTypeNode), visitNodes(node.arguments, visitor, ts.isExpression));
case 181 /* TaggedTemplateExpression */:
return ts.updateTaggedTemplate(node, visitNode(node.tag, visitor, ts.isExpression), visitNode(node.template, visitor, ts.isTemplateLiteral));
case 183 /* ParenthesizedExpression */:
return ts.updateParen(node, visitNode(node.expression, visitor, ts.isExpression));
case 184 /* FunctionExpression */:
return ts.updateFunctionExpression(node, visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isPropertyName), visitNodes(node.typeParameters, visitor, ts.isTypeParameter), (context.startLexicalEnvironment(), visitNodes(node.parameters, visitor, ts.isParameter)), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), mergeFunctionBodyLexicalEnvironment(visitNode(node.body, visitor, ts.isFunctionBody, /*optional*/ true), context.endLexicalEnvironment()));
case 185 /* ArrowFunction */:
return ts.updateArrowFunction(node, visitNodes(node.modifiers, visitor, ts.isModifier), visitNodes(node.typeParameters, visitor, ts.isTypeParameter), (context.startLexicalEnvironment(), visitNodes(node.parameters, visitor, ts.isParameter)), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), mergeFunctionBodyLexicalEnvironment(visitNode(node.body, visitor, ts.isConciseBody, /*optional*/ true), context.endLexicalEnvironment()));
case 186 /* DeleteExpression */:
return ts.updateDelete(node, visitNode(node.expression, visitor, ts.isExpression));
case 187 /* TypeOfExpression */:
return ts.updateTypeOf(node, visitNode(node.expression, visitor, ts.isExpression));
case 188 /* VoidExpression */:
return ts.updateVoid(node, visitNode(node.expression, visitor, ts.isExpression));
case 189 /* AwaitExpression */:
return ts.updateAwait(node, visitNode(node.expression, visitor, ts.isExpression));
case 192 /* BinaryExpression */:
return ts.updateBinary(node, visitNode(node.left, visitor, ts.isExpression), visitNode(node.right, visitor, ts.isExpression));
case 190 /* PrefixUnaryExpression */:
return ts.updatePrefix(node, visitNode(node.operand, visitor, ts.isExpression));
case 191 /* PostfixUnaryExpression */:
return ts.updatePostfix(node, visitNode(node.operand, visitor, ts.isExpression));
case 193 /* ConditionalExpression */:
return ts.updateConditional(node, visitNode(node.condition, visitor, ts.isExpression), visitNode(node.whenTrue, visitor, ts.isExpression), visitNode(node.whenFalse, visitor, ts.isExpression));
case 194 /* TemplateExpression */:
return ts.updateTemplateExpression(node, visitNode(node.head, visitor, ts.isTemplateHead), visitNodes(node.templateSpans, visitor, ts.isTemplateSpan));
case 195 /* YieldExpression */:
return ts.updateYield(node, visitNode(node.expression, visitor, ts.isExpression));
case 196 /* SpreadElement */:
return ts.updateSpread(node, visitNode(node.expression, visitor, ts.isExpression));
case 197 /* ClassExpression */:
return ts.updateClassExpression(node, visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isIdentifier, /*optional*/ true), visitNodes(node.typeParameters, visitor, ts.isTypeParameter), visitNodes(node.heritageClauses, visitor, ts.isHeritageClause), visitNodes(node.members, visitor, ts.isClassElement));
case 199 /* ExpressionWithTypeArguments */:
return ts.updateExpressionWithTypeArguments(node, visitNodes(node.typeArguments, visitor, ts.isTypeNode), visitNode(node.expression, visitor, ts.isExpression));
// Misc
case 202 /* TemplateSpan */:
return ts.updateTemplateSpan(node, visitNode(node.expression, visitor, ts.isExpression), visitNode(node.literal, visitor, ts.isTemplateMiddleOrTemplateTail));
// Element
case 204 /* Block */:
return ts.updateBlock(node, visitNodes(node.statements, visitor, ts.isStatement));
case 205 /* VariableStatement */:
return ts.updateVariableStatement(node, visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.declarationList, visitor, ts.isVariableDeclarationList));
case 207 /* ExpressionStatement */:
return ts.updateStatement(node, visitNode(node.expression, visitor, ts.isExpression));
case 208 /* IfStatement */:
return ts.updateIf(node, visitNode(node.expression, visitor, ts.isExpression), visitNode(node.thenStatement, visitor, ts.isStatement, /*optional*/ false, liftToBlock), visitNode(node.elseStatement, visitor, ts.isStatement, /*optional*/ true, liftToBlock));
case 209 /* DoStatement */:
return ts.updateDo(node, visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, liftToBlock), visitNode(node.expression, visitor, ts.isExpression));
case 210 /* WhileStatement */:
return ts.updateWhile(node, visitNode(node.expression, visitor, ts.isExpression), visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, liftToBlock));
case 211 /* ForStatement */:
return ts.updateFor(node, visitNode(node.initializer, visitor, ts.isForInitializer), visitNode(node.condition, visitor, ts.isExpression), visitNode(node.incrementor, visitor, ts.isExpression), visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, liftToBlock));
case 212 /* ForInStatement */:
return ts.updateForIn(node, visitNode(node.initializer, visitor, ts.isForInitializer), visitNode(node.expression, visitor, ts.isExpression), visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, liftToBlock));
case 213 /* ForOfStatement */:
return ts.updateForOf(node, visitNode(node.initializer, visitor, ts.isForInitializer), visitNode(node.expression, visitor, ts.isExpression), visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, liftToBlock));
case 214 /* ContinueStatement */:
return ts.updateContinue(node, visitNode(node.label, visitor, ts.isIdentifier, /*optional*/ true));
case 215 /* BreakStatement */:
return ts.updateBreak(node, visitNode(node.label, visitor, ts.isIdentifier, /*optional*/ true));
case 216 /* ReturnStatement */:
return ts.updateReturn(node, visitNode(node.expression, visitor, ts.isExpression, /*optional*/ true));
case 217 /* WithStatement */:
return ts.updateWith(node, visitNode(node.expression, visitor, ts.isExpression), visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, liftToBlock));
case 218 /* SwitchStatement */:
return ts.updateSwitch(node, visitNode(node.expression, visitor, ts.isExpression), visitNode(node.caseBlock, visitor, ts.isCaseBlock));
case 219 /* LabeledStatement */:
return ts.updateLabel(node, visitNode(node.label, visitor, ts.isIdentifier), visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, liftToBlock));
case 220 /* ThrowStatement */:
return ts.updateThrow(node, visitNode(node.expression, visitor, ts.isExpression));
case 221 /* TryStatement */:
return ts.updateTry(node, visitNode(node.tryBlock, visitor, ts.isBlock), visitNode(node.catchClause, visitor, ts.isCatchClause, /*optional*/ true), visitNode(node.finallyBlock, visitor, ts.isBlock, /*optional*/ true));
case 223 /* VariableDeclaration */:
return ts.updateVariableDeclaration(node, visitNode(node.name, visitor, ts.isBindingName), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), visitNode(node.initializer, visitor, ts.isExpression, /*optional*/ true));
case 224 /* VariableDeclarationList */:
return ts.updateVariableDeclarationList(node, visitNodes(node.declarations, visitor, ts.isVariableDeclaration));
case 225 /* FunctionDeclaration */:
return ts.updateFunctionDeclaration(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isPropertyName), visitNodes(node.typeParameters, visitor, ts.isTypeParameter), (context.startLexicalEnvironment(), visitNodes(node.parameters, visitor, ts.isParameter)), visitNode(node.type, visitor, ts.isTypeNode, /*optional*/ true), mergeFunctionBodyLexicalEnvironment(visitNode(node.body, visitor, ts.isFunctionBody, /*optional*/ true), context.endLexicalEnvironment()));
case 226 /* ClassDeclaration */:
return ts.updateClassDeclaration(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.name, visitor, ts.isIdentifier, /*optional*/ true), visitNodes(node.typeParameters, visitor, ts.isTypeParameter), visitNodes(node.heritageClauses, visitor, ts.isHeritageClause), visitNodes(node.members, visitor, ts.isClassElement));
case 232 /* CaseBlock */:
return ts.updateCaseBlock(node, visitNodes(node.clauses, visitor, ts.isCaseOrDefaultClause));
case 235 /* ImportDeclaration */:
return ts.updateImportDeclaration(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.importClause, visitor, ts.isImportClause, /*optional*/ true), visitNode(node.moduleSpecifier, visitor, ts.isExpression));
case 236 /* ImportClause */:
return ts.updateImportClause(node, visitNode(node.name, visitor, ts.isIdentifier, /*optional*/ true), visitNode(node.namedBindings, visitor, ts.isNamedImportBindings, /*optional*/ true));
case 237 /* NamespaceImport */:
return ts.updateNamespaceImport(node, visitNode(node.name, visitor, ts.isIdentifier));
case 238 /* NamedImports */:
return ts.updateNamedImports(node, visitNodes(node.elements, visitor, ts.isImportSpecifier));
case 239 /* ImportSpecifier */:
return ts.updateImportSpecifier(node, visitNode(node.propertyName, visitor, ts.isIdentifier, /*optional*/ true), visitNode(node.name, visitor, ts.isIdentifier));
case 240 /* ExportAssignment */:
return ts.updateExportAssignment(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.expression, visitor, ts.isExpression));
case 241 /* ExportDeclaration */:
return ts.updateExportDeclaration(node, visitNodes(node.decorators, visitor, ts.isDecorator), visitNodes(node.modifiers, visitor, ts.isModifier), visitNode(node.exportClause, visitor, ts.isNamedExports, /*optional*/ true), visitNode(node.moduleSpecifier, visitor, ts.isExpression, /*optional*/ true));
case 242 /* NamedExports */:
return ts.updateNamedExports(node, visitNodes(node.elements, visitor, ts.isExportSpecifier));
case 243 /* ExportSpecifier */:
return ts.updateExportSpecifier(node, visitNode(node.propertyName, visitor, ts.isIdentifier, /*optional*/ true), visitNode(node.name, visitor, ts.isIdentifier));
// JSX
case 246 /* JsxElement */:
return ts.updateJsxElement(node, visitNode(node.openingElement, visitor, ts.isJsxOpeningElement), visitNodes(node.children, visitor, ts.isJsxChild), visitNode(node.closingElement, visitor, ts.isJsxClosingElement));
case 247 /* JsxSelfClosingElement */:
return ts.updateJsxSelfClosingElement(node, visitNode(node.tagName, visitor, ts.isJsxTagNameExpression), visitNodes(node.attributes, visitor, ts.isJsxAttributeLike));
case 248 /* JsxOpeningElement */:
return ts.updateJsxOpeningElement(node, visitNode(node.tagName, visitor, ts.isJsxTagNameExpression), visitNodes(node.attributes, visitor, ts.isJsxAttributeLike));
case 249 /* JsxClosingElement */:
return ts.updateJsxClosingElement(node, visitNode(node.tagName, visitor, ts.isJsxTagNameExpression));
case 250 /* JsxAttribute */:
return ts.updateJsxAttribute(node, visitNode(node.name, visitor, ts.isIdentifier), visitNode(node.initializer, visitor, ts.isStringLiteralOrJsxExpression));
case 251 /* JsxSpreadAttribute */:
return ts.updateJsxSpreadAttribute(node, visitNode(node.expression, visitor, ts.isExpression));
case 252 /* JsxExpression */:
return ts.updateJsxExpression(node, visitNode(node.expression, visitor, ts.isExpression));
// Clauses
case 253 /* CaseClause */:
return ts.updateCaseClause(node, visitNode(node.expression, visitor, ts.isExpression), visitNodes(node.statements, visitor, ts.isStatement));
case 254 /* DefaultClause */:
return ts.updateDefaultClause(node, visitNodes(node.statements, visitor, ts.isStatement));
case 255 /* HeritageClause */:
return ts.updateHeritageClause(node, visitNodes(node.types, visitor, ts.isExpressionWithTypeArguments));
case 256 /* CatchClause */:
return ts.updateCatchClause(node, visitNode(node.variableDeclaration, visitor, ts.isVariableDeclaration), visitNode(node.block, visitor, ts.isBlock));
// Property assignments
case 257 /* PropertyAssignment */:
return ts.updatePropertyAssignment(node, visitNode(node.name, visitor, ts.isPropertyName), visitNode(node.initializer, visitor, ts.isExpression));
case 258 /* ShorthandPropertyAssignment */:
return ts.updateShorthandPropertyAssignment(node, visitNode(node.name, visitor, ts.isIdentifier), visitNode(node.objectAssignmentInitializer, visitor, ts.isExpression));
case 259 /* SpreadAssignment */:
return ts.updateSpreadAssignment(node, visitNode(node.expression, visitor, ts.isExpression));
// Top-level nodes
case 261 /* SourceFile */:
context.startLexicalEnvironment();
return ts.updateSourceFileNode(node, ts.createNodeArray(ts.concatenate(visitNodes(node.statements, visitor, ts.isStatement), context.endLexicalEnvironment()), node.statements));
// Transformation nodes
case 293 /* PartiallyEmittedExpression */:
return ts.updatePartiallyEmittedExpression(node, visitNode(node.expression, visitor, ts.isExpression));
default:
var updated = void 0;
var edgeTraversalPath = nodeEdgeTraversalMap[kind];
if (edgeTraversalPath) {
for (var _i = 0, edgeTraversalPath_2 = edgeTraversalPath; _i < edgeTraversalPath_2.length; _i++) {
var edge = edgeTraversalPath_2[_i];
var value = node[edge.name];
if (value !== undefined) {
var visited = ts.isArray(value)
? visitNodes(value, visitor, edge.test, 0, value.length, edge.parenthesize, node)
: visitNode(value, visitor, edge.test, edge.optional, edge.lift, edge.parenthesize, node);
if (updated !== undefined || visited !== value) {
if (updated === undefined) {
updated = ts.getMutableClone(node);
}
if (visited !== value) {
updated[edge.name] = visited;
}
}
}
}
}
return updated ? ts.updateNode(updated, node) : node;
}
// return node;
}
ts.visitEachChild = visitEachChild;
function mergeFunctionBodyLexicalEnvironment(body, declarations) {
if (body && declarations !== undefined && declarations.length > 0) {
if (ts.isBlock(body)) {
return ts.updateBlock(body, ts.createNodeArray(ts.concatenate(body.statements, declarations), body.statements));
}
else {
return ts.createBlock(ts.createNodeArray([ts.createReturn(body, /*location*/ body)].concat(declarations), body),
/*location*/ body,
/*multiLine*/ true);
}
}
return body;
}
ts.mergeFunctionBodyLexicalEnvironment = mergeFunctionBodyLexicalEnvironment;
/**
* Lifts a NodeArray containing only Statement nodes to a block.
*
* @param nodes The NodeArray.
*/
function liftToBlock(nodes) {
Debug.assert(ts.every(nodes, ts.isStatement), "Cannot lift nodes to a Block.");
return ts.singleOrUndefined(nodes) || ts.createBlock(nodes);
}
ts.liftToBlock = liftToBlock;
/**
* Extracts the single node from a NodeArray.
*
* @param nodes The NodeArray.
*/
function extractSingleNode(nodes) {
Debug.assert(nodes.length <= 1, "Too many nodes written to output.");
return ts.singleOrUndefined(nodes);
}
/**
* Aggregates the TransformFlags for a Node and its subtree.
*/
function aggregateTransformFlags(node) {
aggregateTransformFlagsForNode(node);
return node;
}
ts.aggregateTransformFlags = aggregateTransformFlags;
/**
* Aggregates the TransformFlags for a Node and its subtree. The flags for the subtree are
* computed first, then the transform flags for the current node are computed from the subtree
* flags and the state of the current node. Finally, the transform flags of the node are
* returned, excluding any flags that should not be included in its parent node's subtree
* flags.
*/
function aggregateTransformFlagsForNode(node) {
if (node === undefined) {
return 0 /* None */;
}
else if (node.transformFlags & 536870912 /* HasComputedFlags */) {
return node.transformFlags & ~ts.getTransformFlagsSubtreeExclusions(node.kind);
}
else {
var subtreeFlags = aggregateTransformFlagsForSubtree(node);
return ts.computeTransformFlagsForNode(node, subtreeFlags);
}
}
/**
* Aggregates the transform flags for the subtree of a node.
*/
function aggregateTransformFlagsForSubtree(node) {
// We do not transform ambient declarations or types, so there is no need to
// recursively aggregate transform flags.
if (ts.hasModifier(node, 2 /* Ambient */) || ts.isTypeNode(node)) {
return 0 /* None */;
}
// Aggregate the transform flags of each child.
return reduceEachChild(node, aggregateTransformFlagsForChildNode, 0 /* None */);
}
/**
* Aggregates the TransformFlags of a child node with the TransformFlags of its
* siblings.
*/
function aggregateTransformFlagsForChildNode(transformFlags, child) {
return transformFlags | aggregateTransformFlagsForNode(child);
}
var Debug;
(function (Debug) {
Debug.failNotOptional = Debug.shouldAssert(1 /* Normal */)
? function (message) { return Debug.assert(false, message || "Node not optional."); }
: ts.noop;
Debug.failBadSyntaxKind = Debug.shouldAssert(1 /* Normal */)
? function (node, message) { return Debug.assert(false, message || "Unexpected node.", function () { return "Node " + ts.formatSyntaxKind(node.kind) + " was unexpected."; }); }
: ts.noop;
Debug.assertNode = Debug.shouldAssert(1 /* Normal */)
? function (node, test, message) { return Debug.assert(test === undefined || test(node), message || "Unexpected node.", function () { return "Node " + ts.formatSyntaxKind(node.kind) + " did not pass test '" + getFunctionName(test) + "'."; }); }
: ts.noop;
function getFunctionName(func) {
if (typeof func !== "function") {
return "";
}
else if (func.hasOwnProperty("name")) {
return func.name;
}
else {
var text = Function.prototype.toString.call(func);
var match = /^function\s+([\w\$]+)\s*\(/.exec(text);
return match ? match[1] : "";
}
}
})(Debug = ts.Debug || (ts.Debug = {}));
var _a;
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
/**
* Flattens a destructuring assignment expression.
*
* @param root The destructuring assignment expression.
* @param needsValue Indicates whether the value from the right-hand-side of the
* destructuring assignment is needed as part of a larger expression.
* @param recordTempVariable A callback used to record new temporary variables.
* @param visitor An optional visitor to use to visit expressions.
*/
function flattenDestructuringAssignment(context, node, needsValue, recordTempVariable, visitor, transformRest) {
if (ts.isEmptyObjectLiteralOrArrayLiteral(node.left)) {
var right = node.right;
if (ts.isDestructuringAssignment(right)) {
return flattenDestructuringAssignment(context, right, needsValue, recordTempVariable, visitor);
}
else {
return node.right;
}
}
var location = node;
var value = node.right;
var expressions = [];
if (needsValue) {
// If the right-hand value of the destructuring assignment needs to be preserved (as
// is the case when the destructuring assignmen) is part of a larger expression),
// then we need to cache the right-hand value.
//
// The source map location for the assignment should point to the entire binary
// expression.
value = ensureIdentifier(value, /*reuseIdentifierExpressions*/ true, location, emitTempVariableAssignment, visitor);
}
else if (ts.nodeIsSynthesized(node)) {
// Generally, the source map location for a destructuring assignment is the root
// expression.
//
// However, if the root expression is synthesized (as in the case
// of the initializer when transforming a ForOfStatement), then the source map
// location should point to the right-hand value of the expression.
location = value;
}
flattenDestructuring(node, value, location, emitAssignment, emitTempVariableAssignment, recordTempVariable, emitRestAssignment, transformRest, visitor);
if (needsValue) {
expressions.push(value);
}
var expression = ts.inlineExpressions(expressions);
ts.aggregateTransformFlags(expression);
return expression;
function emitAssignment(name, value, location) {
var expression = ts.createAssignment(name, value, location);
// NOTE: this completely disables source maps, but aligns with the behavior of
// `emitAssignment` in the old emitter.
ts.setEmitFlags(expression, 2048 /* NoNestedSourceMaps */);
ts.aggregateTransformFlags(expression);
expressions.push(expression);
}
function emitTempVariableAssignment(value, location) {
var name = ts.createTempVariable(recordTempVariable);
emitAssignment(name, value, location);
return name;
}
function emitRestAssignment(elements, value, location) {
emitAssignment(ts.createObjectLiteral(elements), value, location);
}
}
ts.flattenDestructuringAssignment = flattenDestructuringAssignment;
/**
* Flattens binding patterns in a parameter declaration.
*
* @param node The ParameterDeclaration to flatten.
* @param value The rhs value for the binding pattern.
* @param visitor An optional visitor to use to visit expressions.
*/
function flattenParameterDestructuring(node, value, visitor, transformRest) {
var declarations = [];
flattenDestructuring(node, value, node, emitAssignment, emitTempVariableAssignment, ts.noop, emitRestAssignment, transformRest, visitor);
return declarations;
function emitAssignment(name, value, location) {
var declaration = ts.createVariableDeclaration(name, /*type*/ undefined, value, location);
// NOTE: this completely disables source maps, but aligns with the behavior of
// `emitAssignment` in the old emitter.
ts.setEmitFlags(declaration, 2048 /* NoNestedSourceMaps */);
ts.aggregateTransformFlags(declaration);
declarations.push(declaration);
}
function emitTempVariableAssignment(value, location) {
var name = ts.createTempVariable(/*recordTempVariable*/ undefined);
emitAssignment(name, value, location);
return name;
}
function emitRestAssignment(elements, value, location) {
emitAssignment(ts.createObjectBindingPattern(elements), value, location);
}
}
ts.flattenParameterDestructuring = flattenParameterDestructuring;
/**
* Flattens binding patterns in a variable declaration.
*
* @param node The VariableDeclaration to flatten.
* @param value An optional rhs value for the binding pattern.
* @param visitor An optional visitor to use to visit expressions.
*/
function flattenVariableDestructuring(node, value, visitor, recordTempVariable, transformRest) {
var declarations = [];
var pendingAssignments;
flattenDestructuring(node, value, node, emitAssignment, emitTempVariableAssignment, recordTempVariable, emitRestAssignment, transformRest, visitor);
return declarations;
function emitAssignment(name, value, location, original) {
if (pendingAssignments) {
pendingAssignments.push(value);
value = ts.inlineExpressions(pendingAssignments);
pendingAssignments = undefined;
}
var declaration = ts.createVariableDeclaration(name, /*type*/ undefined, value, location);
declaration.original = original;
// NOTE: this completely disables source maps, but aligns with the behavior of
// `emitAssignment` in the old emitter.
ts.setEmitFlags(declaration, 2048 /* NoNestedSourceMaps */);
declarations.push(declaration);
ts.aggregateTransformFlags(declaration);
}
function emitTempVariableAssignment(value, location) {
var name = ts.createTempVariable(recordTempVariable);
if (recordTempVariable) {
var assignment = ts.createAssignment(name, value, location);
if (pendingAssignments) {
pendingAssignments.push(assignment);
}
else {
pendingAssignments = [assignment];
}
}
else {
emitAssignment(name, value, location, /*original*/ undefined);
}
return name;
}
function emitRestAssignment(elements, value, location, original) {
emitAssignment(ts.createObjectBindingPattern(elements), value, location, original);
}
}
ts.flattenVariableDestructuring = flattenVariableDestructuring;
/**
* Flattens binding patterns in a variable declaration and transforms them into an expression.
*
* @param node The VariableDeclaration to flatten.
* @param recordTempVariable A callback used to record new temporary variables.
* @param createAssignmentCallback An optional callback used to create assignment expressions
* for non-temporary variables.
* @param visitor An optional visitor to use to visit expressions.
*/
function flattenVariableDestructuringToExpression(node, recordTempVariable, createAssignmentCallback, visitor) {
var pendingAssignments = [];
flattenDestructuring(node, /*value*/ undefined, node, emitAssignment, emitTempVariableAssignment, ts.noop, emitRestAssignment, /*transformRest*/ false, visitor);
var expression = ts.inlineExpressions(pendingAssignments);
ts.aggregateTransformFlags(expression);
return expression;
function emitAssignment(name, value, location, original) {
var expression = createAssignmentCallback
? createAssignmentCallback(name.kind === 70 /* Identifier */ ? name : emitTempVariableAssignment(name, location), value, location)
: ts.createAssignment(name, value, location);
emitPendingAssignment(expression, original);
}
function emitTempVariableAssignment(value, location) {
var name = ts.createTempVariable(recordTempVariable);
emitPendingAssignment(ts.createAssignment(name, value, location), /*original*/ undefined);
return name;
}
function emitRestAssignment(elements, value, location, original) {
emitAssignment(ts.createObjectLiteral(elements), value, location, original);
}
function emitPendingAssignment(expression, original) {
expression.original = original;
// NOTE: this completely disables source maps, but aligns with the behavior of
// `emitAssignment` in the old emitter.
ts.setEmitFlags(expression, 2048 /* NoNestedSourceMaps */);
pendingAssignments.push(expression);
}
}
ts.flattenVariableDestructuringToExpression = flattenVariableDestructuringToExpression;
function flattenDestructuring(root, value, location, emitAssignment, emitTempVariableAssignment, recordTempVariable, emitRestAssignment, transformRest, visitor) {
if (value && visitor) {
value = ts.visitNode(value, visitor, ts.isExpression);
}
if (ts.isBinaryExpression(root)) {
emitDestructuringAssignment(root.left, value, location);
}
else {
emitBindingElement(root, value);
}
function emitDestructuringAssignment(bindingTarget, value, location) {
// When emitting target = value use source map node to highlight, including any temporary assignments needed for this
var target;
if (ts.isShorthandPropertyAssignment(bindingTarget)) {
var initializer = visitor
? ts.visitNode(bindingTarget.objectAssignmentInitializer, visitor, ts.isExpression)
: bindingTarget.objectAssignmentInitializer;
if (initializer) {
value = createDefaultValueCheck(value, initializer, location);
}
target = bindingTarget.name;
}
else if (ts.isBinaryExpression(bindingTarget) && bindingTarget.operatorToken.kind === 57 /* EqualsToken */) {
var initializer = visitor
? ts.visitNode(bindingTarget.right, visitor, ts.isExpression)
: bindingTarget.right;
value = createDefaultValueCheck(value, initializer, location);
target = bindingTarget.left;
}
else {
target = bindingTarget;
}
if (target.kind === 176 /* ObjectLiteralExpression */) {
emitObjectLiteralAssignment(target, value, location);
}
else if (target.kind === 175 /* ArrayLiteralExpression */) {
emitArrayLiteralAssignment(target, value, location);
}
else {
var name_30 = ts.getMutableClone(target);
ts.setSourceMapRange(name_30, target);
ts.setCommentRange(name_30, target);
emitAssignment(name_30, value, location, /*original*/ undefined);
}
}
function emitObjectLiteralAssignment(target, value, location) {
var properties = target.properties;
if (properties.length !== 1) {
// For anything but a single element destructuring we need to generate a temporary
// to ensure value is evaluated exactly once.
// When doing so we want to hightlight the passed in source map node since thats the one needing this temp assignment
value = ensureIdentifier(value, /*reuseIdentifierExpressions*/ true, location, emitTempVariableAssignment);
}
var bindingElements = [];
for (var i = 0; i < properties.length; i++) {
var p = properties[i];
if (p.kind === 257 /* PropertyAssignment */ || p.kind === 258 /* ShorthandPropertyAssignment */) {
if (!transformRest ||
p.transformFlags & 8388608 /* ContainsSpreadExpression */ ||
(p.kind === 257 /* PropertyAssignment */ && p.initializer.transformFlags & 8388608 /* ContainsSpreadExpression */)) {
if (bindingElements.length) {
emitRestAssignment(bindingElements, value, location, target);
bindingElements = [];
}
var propName = p.name;
var bindingTarget = p.kind === 258 /* ShorthandPropertyAssignment */ ? p : p.initializer || propName;
// Assignment for bindingTarget = value.propName should highlight whole property, hence use p as source map node
emitDestructuringAssignment(bindingTarget, createDestructuringPropertyAccess(value, propName), p);
}
else {
bindingElements.push(p);
}
}
else if (i === properties.length - 1 &&
p.kind === 259 /* SpreadAssignment */ &&
p.expression.kind === 70 /* Identifier */) {
if (bindingElements.length) {
emitRestAssignment(bindingElements, value, location, target);
bindingElements = [];
}
var propName = p.expression;
var restCall = createRestCall(value, target.properties, function (p) { return p.name; }, target);
emitDestructuringAssignment(propName, restCall, p);
}
}
if (bindingElements.length) {
emitRestAssignment(bindingElements, value, location, target);
bindingElements = [];
}
}
function emitArrayLiteralAssignment(target, value, location) {
if (transformRest) {
emitESNextArrayLiteralAssignment(target, value, location);
}
else {
emitES2015ArrayLiteralAssignment(target, value, location);
}
}
function emitESNextArrayLiteralAssignment(target, value, location) {
var elements = target.elements;
var numElements = elements.length;
if (numElements !== 1) {
// For anything but a single element destructuring we need to generate a temporary
// to ensure value is evaluated exactly once.
// When doing so we want to highlight the passed-in source map node since thats the one needing this temp assignment
value = ensureIdentifier(value, /*reuseIdentifierExpressions*/ true, location, emitTempVariableAssignment);
}
var expressions = [];
var spreadContainingExpressions = [];
for (var i = 0; i < numElements; i++) {
var e = elements[i];
if (e.kind === 198 /* OmittedExpression */) {
continue;
}
if (e.transformFlags & 8388608 /* ContainsSpreadExpression */ && i < numElements - 1) {
var tmp = ts.createTempVariable(recordTempVariable);
spreadContainingExpressions.push([e, tmp]);
expressions.push(tmp);
}
else {
expressions.push(e);
}
}
emitAssignment(ts.updateArrayLiteral(target, expressions), value, undefined, undefined);
for (var _i = 0, spreadContainingExpressions_1 = spreadContainingExpressions; _i < spreadContainingExpressions_1.length; _i++) {
var _a = spreadContainingExpressions_1[_i], e = _a[0], tmp = _a[1];
emitDestructuringAssignment(e, tmp, e);
}
}
function emitES2015ArrayLiteralAssignment(target, value, location) {
var elements = target.elements;
var numElements = elements.length;
if (numElements !== 1) {
// For anything but a single element destructuring we need to generate a temporary
// to ensure value is evaluated exactly once.
// When doing so we want to highlight the passed-in source map node since thats the one needing this temp assignment
value = ensureIdentifier(value, /*reuseIdentifierExpressions*/ true, location, emitTempVariableAssignment);
}
for (var i = 0; i < numElements; i++) {
var e = elements[i];
if (e.kind !== 198 /* OmittedExpression */) {
// Assignment for target = value.propName should highligh whole property, hence use e as source map node
if (e.kind !== 196 /* SpreadElement */) {
emitDestructuringAssignment(e, ts.createElementAccess(value, ts.createLiteral(i)), e);
}
else if (i === numElements - 1) {
emitDestructuringAssignment(e.expression, ts.createArraySlice(value, i), e);
}
}
}
}
/** Given value: o, propName: p, pattern: { a, b, ...p } from the original statement
* `{ a, b, ...p } = o`, create `p = __rest(o, ["a", "b"]);`*/
function createRestCall(value, elements, getPropertyName, location) {
var propertyNames = [];
for (var i = 0; i < elements.length - 1; i++) {
if (ts.isOmittedExpression(elements[i])) {
continue;
}
var str = ts.createSynthesizedNode(9 /* StringLiteral */);
str.pos = location.pos;
str.end = location.end;
str.text = ts.getTextOfPropertyName(getPropertyName(elements[i]));
propertyNames.push(str);
}
var args = ts.createSynthesizedNodeArray([value, ts.createArrayLiteral(propertyNames, location)]);
return ts.createCall(ts.createIdentifier("__rest"), undefined, args);
}
function emitBindingElement(target, value) {
// Any temporary assignments needed to emit target = value should point to target
var initializer = visitor ? ts.visitNode(target.initializer, visitor, ts.isExpression) : target.initializer;
if (transformRest) {
value = value || initializer;
}
else if (initializer) {
// Combine value and initializer
value = value ? createDefaultValueCheck(value, initializer, target) : initializer;
}
else if (!value) {
// Use 'void 0' in absence of value and initializer
value = ts.createVoidZero();
}
var name = target.name;
if (!ts.isBindingPattern(name)) {
emitAssignment(name, value, target, target);
}
else {
var numElements = name.elements.length;
if (numElements !== 1) {
// For anything other than a single-element destructuring we need to generate a temporary
// to ensure value is evaluated exactly once. Additionally, if we have zero elements
// we need to emit *something* to ensure that in case a 'var' keyword was already emitted,
// so in that case, we'll intentionally create that temporary.
value = ensureIdentifier(value, /*reuseIdentifierExpressions*/ numElements !== 0, target, emitTempVariableAssignment);
}
if (name.kind === 173 /* ArrayBindingPattern */) {
emitArrayBindingElement(name, value);
}
else {
emitObjectBindingElement(target, value);
}
}
}
function emitArrayBindingElement(name, value) {
if (transformRest) {
emitESNextArrayBindingElement(name, value);
}
else {
emitES2015ArrayBindingElement(name, value);
}
}
function emitES2015ArrayBindingElement(name, value) {
var elements = name.elements;
var numElements = elements.length;
for (var i = 0; i < numElements; i++) {
var element = elements[i];
if (ts.isOmittedExpression(element)) {
continue;
}
if (!element.dotDotDotToken) {
// Rewrite element to a declaration that accesses array element at index i
emitBindingElement(element, ts.createElementAccess(value, i));
}
else if (i === numElements - 1) {
emitBindingElement(element, ts.createArraySlice(value, i));
}
}
}
function emitESNextArrayBindingElement(name, value) {
var elements = name.elements;
var numElements = elements.length;
var bindingElements = [];
var spreadContainingElements = [];
for (var i = 0; i < numElements; i++) {
var element = elements[i];
if (ts.isOmittedExpression(element)) {
continue;
}
if (element.transformFlags & 8388608 /* ContainsSpreadExpression */ && i < numElements - 1) {
spreadContainingElements.push(element);
bindingElements.push(ts.createBindingElement(undefined, undefined, ts.getGeneratedNameForNode(element), undefined, value));
}
else {
bindingElements.push(element);
}
}
emitAssignment(ts.updateArrayBindingPattern(name, bindingElements), value, undefined, undefined);
for (var _i = 0, spreadContainingElements_1 = spreadContainingElements; _i < spreadContainingElements_1.length; _i++) {
var element = spreadContainingElements_1[_i];
emitBindingElement(element, ts.getGeneratedNameForNode(element));
}
}
function emitObjectBindingElement(target, value) {
var name = target.name;
var elements = name.elements;
var numElements = elements.length;
var bindingElements = [];
for (var i = 0; i < numElements; i++) {
var element = elements[i];
if (ts.isOmittedExpression(element)) {
continue;
}
if (i === numElements - 1 && element.dotDotDotToken) {
if (bindingElements.length) {
emitRestAssignment(bindingElements, value, target, target);
bindingElements = [];
}
var restCall = createRestCall(value, name.elements, function (element) { return element.propertyName || element.name; }, name);
emitBindingElement(element, restCall);
}
else if (transformRest && !(element.transformFlags & 8388608 /* ContainsSpreadExpression */)) {
// do not emit until we have a complete bundle of ES2015 syntax
bindingElements.push(element);
}
else {
if (bindingElements.length) {
emitRestAssignment(bindingElements, value, target, target);
bindingElements = [];
}
// Rewrite element to a declaration with an initializer that fetches property
var propName = element.propertyName || element.name;
emitBindingElement(element, createDestructuringPropertyAccess(value, propName));
}
}
if (bindingElements.length) {
emitRestAssignment(bindingElements, value, target, target);
bindingElements = [];
}
}
function createDefaultValueCheck(value, defaultValue, location) {
value = ensureIdentifier(value, /*reuseIdentifierExpressions*/ true, location, emitTempVariableAssignment);
return ts.createConditional(ts.createStrictEquality(value, ts.createVoidZero()), ts.createToken(54 /* QuestionToken */), defaultValue, ts.createToken(55 /* ColonToken */), value);
}
/**
* Creates either a PropertyAccessExpression or an ElementAccessExpression for the
* right-hand side of a transformed destructuring assignment.
*
* @param expression The right-hand expression that is the source of the property.
* @param propertyName The destructuring property name.
*/
function createDestructuringPropertyAccess(expression, propertyName) {
if (ts.isComputedPropertyName(propertyName)) {
return ts.createElementAccess(expression, ensureIdentifier(propertyName.expression, /*reuseIdentifierExpressions*/ false, /*location*/ propertyName, emitTempVariableAssignment));
}
else if (ts.isLiteralExpression(propertyName)) {
var clone_2 = ts.getSynthesizedClone(propertyName);
clone_2.text = ts.unescapeIdentifier(clone_2.text);
return ts.createElementAccess(expression, clone_2);
}
else {
if (ts.isGeneratedIdentifier(propertyName)) {
var clone_3 = ts.getSynthesizedClone(propertyName);
clone_3.text = ts.unescapeIdentifier(clone_3.text);
return ts.createPropertyAccess(expression, clone_3);
}
else {
return ts.createPropertyAccess(expression, ts.createIdentifier(ts.unescapeIdentifier(propertyName.text)));
}
}
}
}
/**
* Ensures that there exists a declared identifier whose value holds the given expression.
* This function is useful to ensure that the expression's value can be read from in subsequent expressions.
* Unless 'reuseIdentifierExpressions' is false, 'value' will be returned if it is just an identifier.
*
* @param value the expression whose value needs to be bound.
* @param reuseIdentifierExpressions true if identifier expressions can simply be returned;
* false if it is necessary to always emit an identifier.
* @param location The location to use for source maps and comments.
* @param emitTempVariableAssignment A callback used to emit a temporary variable.
* @param visitor An optional callback used to visit the value.
*/
function ensureIdentifier(value, reuseIdentifierExpressions, location, emitTempVariableAssignment, visitor) {
if (ts.isIdentifier(value) && reuseIdentifierExpressions) {
return value;
}
else {
if (visitor) {
value = ts.visitNode(value, visitor, ts.isExpression);
}
return emitTempVariableAssignment(value, location);
}
}
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/// <reference path="./destructuring.ts" />
/*@internal*/
var ts;
(function (ts) {
/**
* Indicates whether to emit type metadata in the new format.
*/
var USE_NEW_TYPE_METADATA_FORMAT = false;
var TypeScriptSubstitutionFlags;
(function (TypeScriptSubstitutionFlags) {
/** Enables substitutions for decorated classes. */
TypeScriptSubstitutionFlags[TypeScriptSubstitutionFlags["ClassAliases"] = 1] = "ClassAliases";
/** Enables substitutions for namespace exports. */
TypeScriptSubstitutionFlags[TypeScriptSubstitutionFlags["NamespaceExports"] = 2] = "NamespaceExports";
/* Enables substitutions for unqualified enum members */
TypeScriptSubstitutionFlags[TypeScriptSubstitutionFlags["NonQualifiedEnumMembers"] = 8] = "NonQualifiedEnumMembers";
})(TypeScriptSubstitutionFlags || (TypeScriptSubstitutionFlags = {}));
function transformTypeScript(context) {
var startLexicalEnvironment = context.startLexicalEnvironment, endLexicalEnvironment = context.endLexicalEnvironment, hoistVariableDeclaration = context.hoistVariableDeclaration;
var resolver = context.getEmitResolver();
var compilerOptions = context.getCompilerOptions();
var languageVersion = ts.getEmitScriptTarget(compilerOptions);
var moduleKind = ts.getEmitModuleKind(compilerOptions);
// Save the previous transformation hooks.
var previousOnEmitNode = context.onEmitNode;
var previousOnSubstituteNode = context.onSubstituteNode;
// Set new transformation hooks.
context.onEmitNode = onEmitNode;
context.onSubstituteNode = onSubstituteNode;
// Enable substitution for property/element access to emit const enum values.
context.enableSubstitution(177 /* PropertyAccessExpression */);
context.enableSubstitution(178 /* ElementAccessExpression */);
// These variables contain state that changes as we descend into the tree.
var currentSourceFile;
var currentNamespace;
var currentNamespaceContainerName;
var currentScope;
var currentScopeFirstDeclarationsOfName;
var currentExternalHelpersModuleName;
/**
* Keeps track of whether expression substitution has been enabled for specific edge cases.
* They are persisted between each SourceFile transformation and should not be reset.
*/
var enabledSubstitutions;
/**
* A map that keeps track of aliases created for classes with decorators to avoid issues
* with the double-binding behavior of classes.
*/
var classAliases;
/**
* Keeps track of whether we are within any containing namespaces when performing
* just-in-time substitution while printing an expression identifier.
*/
var applicableSubstitutions;
return transformSourceFile;
/**
* Transform TypeScript-specific syntax in a SourceFile.
*
* @param node A SourceFile node.
*/
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)) {
return node;
}
return ts.visitNode(node, visitor, ts.isSourceFile);
}
/**
* Visits a node, saving and restoring state variables on the stack.
*
* @param node The node to visit.
*/
function saveStateAndInvoke(node, f) {
// Save state
var savedCurrentScope = currentScope;
var savedCurrentScopeFirstDeclarationsOfName = currentScopeFirstDeclarationsOfName;
// Handle state changes before visiting a node.
onBeforeVisitNode(node);
var visited = f(node);
// Restore state
if (currentScope !== savedCurrentScope) {
currentScopeFirstDeclarationsOfName = savedCurrentScopeFirstDeclarationsOfName;
}
currentScope = savedCurrentScope;
return visited;
}
/**
* General-purpose node visitor.
*
* @param node The node to visit.
*/
function visitor(node) {
return saveStateAndInvoke(node, visitorWorker);
}
/**
* Visits and possibly transforms any node.
*
* @param node The node to visit.
*/
function visitorWorker(node) {
if (node.kind === 261 /* SourceFile */) {
return visitSourceFile(node);
}
else if (node.transformFlags & 1 /* TypeScript */) {
// This node is explicitly marked as TypeScript, so we should transform the node.
return visitTypeScript(node);
}
else if (node.transformFlags & 2 /* ContainsTypeScript */) {
// This node contains TypeScript, so we should visit its children.
return ts.visitEachChild(node, visitor, context);
}
return node;
}
/**
* Specialized visitor that visits the immediate children of a SourceFile.
*
* @param node The node to visit.
*/
function sourceElementVisitor(node) {
return saveStateAndInvoke(node, sourceElementVisitorWorker);
}
/**
* Specialized visitor that visits the immediate children of a SourceFile.
*
* @param node The node to visit.
*/
function sourceElementVisitorWorker(node) {
switch (node.kind) {
case 235 /* ImportDeclaration */:
return visitImportDeclaration(node);
case 234 /* ImportEqualsDeclaration */:
return visitImportEqualsDeclaration(node);
case 240 /* ExportAssignment */:
return visitExportAssignment(node);
case 241 /* ExportDeclaration */:
return visitExportDeclaration(node);
default:
return visitorWorker(node);
}
}
/**
* Specialized visitor that visits the immediate children of a namespace.
*
* @param node The node to visit.
*/
function namespaceElementVisitor(node) {
return saveStateAndInvoke(node, namespaceElementVisitorWorker);
}
/**
* Specialized visitor that visits the immediate children of a namespace.
*
* @param node The node to visit.
*/
function namespaceElementVisitorWorker(node) {
if (node.kind === 241 /* ExportDeclaration */ ||
node.kind === 235 /* ImportDeclaration */ ||
node.kind === 236 /* ImportClause */ ||
(node.kind === 234 /* ImportEqualsDeclaration */ &&
node.moduleReference.kind === 245 /* ExternalModuleReference */)) {
// do not emit ES6 imports and exports since they are illegal inside a namespace
return undefined;
}
else if (node.transformFlags & 1 /* TypeScript */ || ts.hasModifier(node, 1 /* Export */)) {
// This node is explicitly marked as TypeScript, or is exported at the namespace
// level, so we should transform the node.
return visitTypeScript(node);
}
else if (node.transformFlags & 2 /* ContainsTypeScript */) {
// This node contains TypeScript, so we should visit its children.
return ts.visitEachChild(node, visitor, context);
}
return node;
}
/**
* Specialized visitor that visits the immediate children of a class with TypeScript syntax.
*
* @param node The node to visit.
*/
function classElementVisitor(node) {
return saveStateAndInvoke(node, classElementVisitorWorker);
}
/**
* Specialized visitor that visits the immediate children of a class with TypeScript syntax.
*
* @param node The node to visit.
*/
function classElementVisitorWorker(node) {
switch (node.kind) {
case 150 /* Constructor */:
// TypeScript constructors are transformed in `visitClassDeclaration`.
// We elide them here as `visitorWorker` checks transform flags, which could
// erronously include an ES6 constructor without TypeScript syntax.
return undefined;
case 147 /* PropertyDeclaration */:
case 155 /* IndexSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 149 /* MethodDeclaration */:
// Fallback to the default visit behavior.
return visitorWorker(node);
case 203 /* SemicolonClassElement */:
return node;
default:
ts.Debug.failBadSyntaxKind(node);
return undefined;
}
}
function modifierVisitor(node) {
if (ts.modifierToFlag(node.kind) & 2270 /* TypeScriptModifier */) {
return undefined;
}
else if (currentNamespace && node.kind === 83 /* ExportKeyword */) {
return undefined;
}
return node;
}
/**
* Branching visitor, visits a TypeScript syntax node.
*
* @param node The node to visit.
*/
function visitTypeScript(node) {
if (ts.hasModifier(node, 2 /* Ambient */) && ts.isStatement(node)) {
// TypeScript ambient declarations are elided, but some comments may be preserved.
// See the implementation of `getLeadingComments` in comments.ts for more details.
return ts.createNotEmittedStatement(node);
}
switch (node.kind) {
case 83 /* ExportKeyword */:
case 78 /* DefaultKeyword */:
// ES6 export and default modifiers are elided when inside a namespace.
return currentNamespace ? undefined : node;
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 116 /* AbstractKeyword */:
case 75 /* ConstKeyword */:
case 123 /* DeclareKeyword */:
case 130 /* ReadonlyKeyword */:
// TypeScript accessibility and readonly modifiers are elided.
case 162 /* ArrayType */:
case 163 /* TupleType */:
case 161 /* TypeLiteral */:
case 156 /* TypePredicate */:
case 143 /* TypeParameter */:
case 118 /* AnyKeyword */:
case 121 /* BooleanKeyword */:
case 134 /* StringKeyword */:
case 132 /* NumberKeyword */:
case 129 /* NeverKeyword */:
case 104 /* VoidKeyword */:
case 135 /* SymbolKeyword */:
case 159 /* ConstructorType */:
case 158 /* FunctionType */:
case 160 /* TypeQuery */:
case 157 /* TypeReference */:
case 164 /* UnionType */:
case 165 /* IntersectionType */:
case 166 /* ParenthesizedType */:
case 167 /* ThisType */:
case 168 /* TypeOperator */:
case 169 /* IndexedAccessType */:
case 170 /* MappedType */:
case 171 /* LiteralType */:
// TypeScript type nodes are elided.
case 155 /* IndexSignature */:
// TypeScript index signatures are elided.
case 145 /* Decorator */:
// TypeScript decorators are elided. They will be emitted as part of visitClassDeclaration.
case 228 /* TypeAliasDeclaration */:
// TypeScript type-only declarations are elided.
case 147 /* PropertyDeclaration */:
// TypeScript property declarations are elided.
case 150 /* Constructor */:
return visitConstructor(node);
case 227 /* InterfaceDeclaration */:
// TypeScript interfaces are elided, but some comments may be preserved.
// See the implementation of `getLeadingComments` in comments.ts for more details.
return ts.createNotEmittedStatement(node);
case 226 /* ClassDeclaration */:
// This is a class declaration with TypeScript syntax extensions.
//
// TypeScript class syntax extensions include:
// - decorators
// - optional `implements` heritage clause
// - parameter property assignments in the constructor
// - property declarations
// - index signatures
// - method overload signatures
return visitClassDeclaration(node);
case 197 /* ClassExpression */:
// This is a class expression with TypeScript syntax extensions.
//
// TypeScript class syntax extensions include:
// - decorators
// - optional `implements` heritage clause
// - parameter property assignments in the constructor
// - property declarations
// - index signatures
// - method overload signatures
return visitClassExpression(node);
case 255 /* HeritageClause */:
// This is a heritage clause with TypeScript syntax extensions.
//
// TypeScript heritage clause extensions include:
// - `implements` clause
return visitHeritageClause(node);
case 199 /* ExpressionWithTypeArguments */:
// TypeScript supports type arguments on an expression in an `extends` heritage clause.
return visitExpressionWithTypeArguments(node);
case 149 /* MethodDeclaration */:
// TypeScript method declarations may have decorators, modifiers
// or type annotations.
return visitMethodDeclaration(node);
case 151 /* GetAccessor */:
// Get Accessors can have TypeScript modifiers, decorators, and type annotations.
return visitGetAccessor(node);
case 152 /* SetAccessor */:
// Set Accessors can have TypeScript modifiers and type annotations.
return visitSetAccessor(node);
case 225 /* FunctionDeclaration */:
// Typescript function declarations can have modifiers, decorators, and type annotations.
return visitFunctionDeclaration(node);
case 184 /* FunctionExpression */:
// TypeScript function expressions can have modifiers and type annotations.
return visitFunctionExpression(node);
case 185 /* ArrowFunction */:
// TypeScript arrow functions can have modifiers and type annotations.
return visitArrowFunction(node);
case 144 /* Parameter */:
// This is a parameter declaration with TypeScript syntax extensions.
//
// TypeScript parameter declaration syntax extensions include:
// - decorators
// - accessibility modifiers
// - the question mark (?) token for optional parameters
// - type annotations
// - this parameters
return visitParameter(node);
case 183 /* ParenthesizedExpression */:
// ParenthesizedExpressions are TypeScript if their expression is a
// TypeAssertion or AsExpression
return visitParenthesizedExpression(node);
case 182 /* TypeAssertionExpression */:
case 200 /* AsExpression */:
// TypeScript type assertions are removed, but their subtrees are preserved.
return visitAssertionExpression(node);
case 179 /* CallExpression */:
return visitCallExpression(node);
case 180 /* NewExpression */:
return visitNewExpression(node);
case 201 /* NonNullExpression */:
// TypeScript non-null expressions are removed, but their subtrees are preserved.
return visitNonNullExpression(node);
case 229 /* EnumDeclaration */:
// TypeScript enum declarations do not exist in ES6 and must be rewritten.
return visitEnumDeclaration(node);
case 205 /* VariableStatement */:
// TypeScript namespace exports for variable statements must be transformed.
return visitVariableStatement(node);
case 223 /* VariableDeclaration */:
return visitVariableDeclaration(node);
case 230 /* ModuleDeclaration */:
// TypeScript namespace declarations must be transformed.
return visitModuleDeclaration(node);
case 234 /* ImportEqualsDeclaration */:
// TypeScript namespace or external module import.
return visitImportEqualsDeclaration(node);
default:
ts.Debug.failBadSyntaxKind(node);
return ts.visitEachChild(node, visitor, context);
}
}
/**
* Performs actions that should always occur immediately before visiting a node.
*
* @param node The node to visit.
*/
function onBeforeVisitNode(node) {
switch (node.kind) {
case 261 /* SourceFile */:
case 232 /* CaseBlock */:
case 231 /* ModuleBlock */:
case 204 /* Block */:
currentScope = node;
currentScopeFirstDeclarationsOfName = undefined;
break;
case 226 /* ClassDeclaration */:
case 225 /* FunctionDeclaration */:
if (ts.hasModifier(node, 2 /* Ambient */)) {
break;
}
recordEmittedDeclarationInScope(node);
break;
}
}
function visitSourceFile(node) {
currentSourceFile = node;
// ensure "use strict" is emitted in all scenarios in alwaysStrict mode
// There is no need to emit "use strict" in the following cases:
// 1. The file is an external module and target is es2015 or higher
// or 2. The file is an external module and module-kind is es6 or es2015 as such value is not allowed when targeting es5 or lower
if (compilerOptions.alwaysStrict &&
!(ts.isExternalModule(node) && (compilerOptions.target >= 2 /* ES2015 */ || compilerOptions.module === ts.ModuleKind.ES2015))) {
node = ts.ensureUseStrict(node);
}
// If the source file requires any helpers and is an external module, and
// the importHelpers compiler option is enabled, emit a synthesized import
// statement for the helpers library.
if (node.flags & 64512 /* EmitHelperFlags */
&& compilerOptions.importHelpers
&& (ts.isExternalModule(node) || compilerOptions.isolatedModules)) {
startLexicalEnvironment();
var statements = [];
var statementOffset = ts.addPrologueDirectives(statements, node.statements, /*ensureUseStrict*/ false, visitor);
var externalHelpersModuleName = ts.createUniqueName(ts.externalHelpersModuleNameText);
var externalHelpersModuleImport = ts.createImportDeclaration(
/*decorators*/ undefined,
/*modifiers*/ undefined, ts.createImportClause(/*name*/ undefined, ts.createNamespaceImport(externalHelpersModuleName)), ts.createLiteral(ts.externalHelpersModuleNameText));
externalHelpersModuleImport.parent = node;
externalHelpersModuleImport.flags &= ~8 /* Synthesized */;
statements.push(externalHelpersModuleImport);
currentExternalHelpersModuleName = externalHelpersModuleName;
ts.addRange(statements, ts.visitNodes(node.statements, sourceElementVisitor, ts.isStatement, statementOffset));
ts.addRange(statements, endLexicalEnvironment());
currentExternalHelpersModuleName = undefined;
node = ts.updateSourceFileNode(node, ts.createNodeArray(statements, node.statements));
node.externalHelpersModuleName = externalHelpersModuleName;
}
else {
node = ts.visitEachChild(node, sourceElementVisitor, context);
}
ts.setEmitFlags(node, 1 /* EmitEmitHelpers */ | ts.getEmitFlags(node));
return node;
}
/**
* Tests whether we should emit a __decorate call for a class declaration.
*/
function shouldEmitDecorateCallForClass(node) {
if (node.decorators && node.decorators.length > 0) {
return true;
}
var constructor = ts.getFirstConstructorWithBody(node);
if (constructor) {
return ts.forEach(constructor.parameters, shouldEmitDecorateCallForParameter);
}
return false;
}
/**
* Tests whether we should emit a __decorate call for a parameter declaration.
*/
function shouldEmitDecorateCallForParameter(parameter) {
return parameter.decorators !== undefined && parameter.decorators.length > 0;
}
/**
* Transforms a class declaration with TypeScript syntax into compatible ES6.
*
* This function will only be called when one of the following conditions are met:
* - The class has decorators.
* - The class has property declarations with initializers.
* - The class contains a constructor that contains parameters with accessibility modifiers.
* - The class is an export in a TypeScript namespace.
*
* @param node The node to transform.
*/
function visitClassDeclaration(node) {
var staticProperties = getInitializedProperties(node, /*isStatic*/ true);
var hasExtendsClause = ts.getClassExtendsHeritageClauseElement(node) !== undefined;
var isDecoratedClass = shouldEmitDecorateCallForClass(node);
// emit name if
// - node has a name
// - node has static initializers
//
var name = node.name;
if (!name && staticProperties.length > 0) {
name = ts.getGeneratedNameForNode(node);
}
var classStatement = isDecoratedClass
? createClassDeclarationHeadWithDecorators(node, name, hasExtendsClause)
: createClassDeclarationHeadWithoutDecorators(node, name, hasExtendsClause, staticProperties.length > 0);
var statements = [classStatement];
// Emit static property assignment. Because classDeclaration is lexically evaluated,
// it is safe to emit static property assignment after classDeclaration
// From ES6 specification:
// HasLexicalDeclaration (N) : Determines if the argument identifier has a binding in this environment record that was created using
// a lexical declaration such as a LexicalDeclaration or a ClassDeclaration.
if (staticProperties.length) {
addInitializedPropertyStatements(statements, staticProperties, ts.getLocalName(node));
}
// Write any decorators of the node.
addClassElementDecorationStatements(statements, node, /*isStatic*/ false);
addClassElementDecorationStatements(statements, node, /*isStatic*/ true);
addConstructorDecorationStatement(statements, node);
// If the class is exported as part of a TypeScript namespace, emit the namespace export.
// Otherwise, if the class was exported at the top level and was decorated, emit an export
// declaration or export default for the class.
if (isNamespaceExport(node)) {
addExportMemberAssignment(statements, node);
}
else if (isDecoratedClass) {
if (isDefaultExternalModuleExport(node)) {
statements.push(ts.createExportDefault(ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true)));
}
else if (isNamedExternalModuleExport(node)) {
statements.push(ts.createExternalModuleExport(ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true)));
}
}
if (statements.length > 1) {
// Add a DeclarationMarker as a marker for the end of the declaration
statements.push(ts.createEndOfDeclarationMarker(node));
ts.setEmitFlags(classStatement, ts.getEmitFlags(classStatement) | 33554432 /* HasEndOfDeclarationMarker */);
}
return ts.singleOrMany(statements);
}
/**
* Transforms a non-decorated class declaration and appends the resulting statements.
*
* @param node A ClassDeclaration node.
* @param name The name of the class.
* @param hasExtendsClause A value indicating whether the class has an extends clause.
* @param hasStaticProperties A value indicating whether the class has static properties.
*/
function createClassDeclarationHeadWithoutDecorators(node, name, hasExtendsClause, hasStaticProperties) {
// ${modifiers} class ${name} ${heritageClauses} {
// ${members}
// }
var classDeclaration = ts.createClassDeclaration(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), name,
/*typeParameters*/ undefined, ts.visitNodes(node.heritageClauses, visitor, ts.isHeritageClause), transformClassMembers(node, hasExtendsClause), node);
var emitFlags = ts.getEmitFlags(node);
// To better align with the old emitter, we should not emit a trailing source map
// entry if the class has static properties.
if (hasStaticProperties) {
emitFlags |= 1024 /* NoTrailingSourceMap */;
}
ts.setOriginalNode(classDeclaration, node);
ts.setEmitFlags(classDeclaration, emitFlags);
return classDeclaration;
}
/**
* Transforms a decorated class declaration and appends the resulting statements. If
* the class requires an alias to avoid issues with double-binding, the alias is returned.
*
* @param statements A statement list to which to add the declaration.
* @param node A ClassDeclaration node.
* @param name The name of the class.
* @param hasExtendsClause A value indicating whether the class has an extends clause.
*/
function createClassDeclarationHeadWithDecorators(node, name, hasExtendsClause) {
// When we emit an ES6 class that has a class decorator, we must tailor the
// emit to certain specific cases.
//
// In the simplest case, we emit the class declaration as a let declaration, and
// evaluate decorators after the close of the class body:
//
// [Example 1]
// ---------------------------------------------------------------------
// TypeScript | Javascript
// ---------------------------------------------------------------------
// @dec | let C = class C {
// class C { | }
// } | C = __decorate([dec], C);
// ---------------------------------------------------------------------
// @dec | let C = class C {
// export class C { | }
// } | C = __decorate([dec], C);
// | export { C };
// ---------------------------------------------------------------------
//
// If a class declaration contains a reference to itself *inside* of the class body,
// this introduces two bindings to the class: One outside of the class body, and one
// inside of the class body. If we apply decorators as in [Example 1] above, there
// is the possibility that the decorator `dec` will return a new value for the
// constructor, which would result in the binding inside of the class no longer
// pointing to the same reference as the binding outside of the class.
//
// As a result, we must instead rewrite all references to the class *inside* of the
// class body to instead point to a local temporary alias for the class:
//
// [Example 2]
// ---------------------------------------------------------------------
// TypeScript | Javascript
// ---------------------------------------------------------------------
// @dec | let C = C_1 = class C {
// class C { | static x() { return C_1.y; }
// static x() { return C.y; } | }
// static y = 1; | C.y = 1;
// } | C = C_1 = __decorate([dec], C);
// | var C_1;
// ---------------------------------------------------------------------
// @dec | let C = class C {
// export class C { | static x() { return C_1.y; }
// static x() { return C.y; } | }
// static y = 1; | C.y = 1;
// } | C = C_1 = __decorate([dec], C);
// | export { C };
// | var C_1;
// ---------------------------------------------------------------------
//
// If a class declaration is the default export of a module, we instead emit
// the export after the decorated declaration:
//
// [Example 3]
// ---------------------------------------------------------------------
// TypeScript | Javascript
// ---------------------------------------------------------------------
// @dec | let default_1 = class {
// export default class { | }
// } | default_1 = __decorate([dec], default_1);
// | export default default_1;
// ---------------------------------------------------------------------
// @dec | let C = class C {
// export default class C { | }
// } | C = __decorate([dec], C);
// | export default C;
// ---------------------------------------------------------------------
//
// If the class declaration is the default export and a reference to itself
// inside of the class body, we must emit both an alias for the class *and*
// move the export after the declaration:
//
// [Example 4]
// ---------------------------------------------------------------------
// TypeScript | Javascript
// ---------------------------------------------------------------------
// @dec | let C = class C {
// export default class C { | static x() { return C_1.y; }
// static x() { return C.y; } | }
// static y = 1; | C.y = 1;
// } | C = C_1 = __decorate([dec], C);
// | export default C;
// | var C_1;
// ---------------------------------------------------------------------
//
var location = ts.moveRangePastDecorators(node);
var classAlias = getClassAliasIfNeeded(node);
var declName = ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true);
// ... = class ${name} ${heritageClauses} {
// ${members}
// }
var heritageClauses = ts.visitNodes(node.heritageClauses, visitor, ts.isHeritageClause);
var members = transformClassMembers(node, hasExtendsClause);
var classExpression = ts.createClassExpression(/*modifiers*/ undefined, name, /*typeParameters*/ undefined, heritageClauses, members, location);
ts.setOriginalNode(classExpression, node);
// let ${name} = ${classExpression} where name is either declaredName if the class doesn't contain self-reference
// or decoratedClassAlias if the class contain self-reference.
var statement = ts.createLetStatement(declName, classAlias ? ts.createAssignment(classAlias, classExpression) : classExpression, location);
ts.setOriginalNode(statement, node);
ts.setCommentRange(statement, node);
return statement;
}
/**
* Transforms a class expression with TypeScript syntax into compatible ES6.
*
* This function will only be called when one of the following conditions are met:
* - The class has property declarations with initializers.
* - The class contains a constructor that contains parameters with accessibility modifiers.
*
* @param node The node to transform.
*/
function visitClassExpression(node) {
var staticProperties = getInitializedProperties(node, /*isStatic*/ true);
var heritageClauses = ts.visitNodes(node.heritageClauses, visitor, ts.isHeritageClause);
var members = transformClassMembers(node, ts.some(heritageClauses, function (c) { return c.token === 84 /* ExtendsKeyword */; }));
var classExpression = ts.setOriginalNode(ts.createClassExpression(
/*modifiers*/ undefined, node.name,
/*typeParameters*/ undefined, heritageClauses, members,
/*location*/ node), node);
if (staticProperties.length > 0) {
var expressions = [];
var temp = ts.createTempVariable(hoistVariableDeclaration);
if (resolver.getNodeCheckFlags(node) & 8388608 /* ClassWithConstructorReference */) {
// record an alias as the class name is not in scope for statics.
enableSubstitutionForClassAliases();
classAliases[ts.getOriginalNodeId(node)] = ts.getSynthesizedClone(temp);
}
// To preserve the behavior of the old emitter, we explicitly indent
// the body of a class with static initializers.
ts.setEmitFlags(classExpression, 524288 /* Indented */ | ts.getEmitFlags(classExpression));
expressions.push(ts.startOnNewLine(ts.createAssignment(temp, classExpression)));
ts.addRange(expressions, generateInitializedPropertyExpressions(staticProperties, temp));
expressions.push(ts.startOnNewLine(temp));
return ts.inlineExpressions(expressions);
}
return classExpression;
}
/**
* Transforms the members of a class.
*
* @param node The current class.
* @param hasExtendsClause A value indicating whether the class has an extends clause.
*/
function transformClassMembers(node, hasExtendsClause) {
var members = [];
var constructor = transformConstructor(node, hasExtendsClause);
if (constructor) {
members.push(constructor);
}
ts.addRange(members, ts.visitNodes(node.members, classElementVisitor, ts.isClassElement));
return ts.createNodeArray(members, /*location*/ node.members);
}
/**
* Transforms (or creates) a constructor for a class.
*
* @param node The current class.
* @param hasExtendsClause A value indicating whether the class has an extends clause.
*/
function transformConstructor(node, hasExtendsClause) {
// Check if we have property assignment inside class declaration.
// If there is a property assignment, we need to emit constructor whether users define it or not
// If there is no property assignment, we can omit constructor if users do not define it
var hasInstancePropertyWithInitializer = ts.forEach(node.members, isInstanceInitializedProperty);
var hasParameterPropertyAssignments = node.transformFlags & 4194304 /* ContainsParameterPropertyAssignments */;
var constructor = ts.getFirstConstructorWithBody(node);
// If the class does not contain nodes that require a synthesized constructor,
// accept the current constructor if it exists.
if (!hasInstancePropertyWithInitializer && !hasParameterPropertyAssignments) {
return ts.visitEachChild(constructor, visitor, context);
}
var parameters = transformConstructorParameters(constructor);
var body = transformConstructorBody(node, constructor, hasExtendsClause);
// constructor(${parameters}) {
// ${body}
// }
return ts.startOnNewLine(ts.setOriginalNode(ts.createConstructor(
/*decorators*/ undefined,
/*modifiers*/ undefined, parameters, body,
/*location*/ constructor || node), constructor));
}
/**
* Transforms (or creates) the parameters for the constructor of a class with
* parameter property assignments or instance property initializers.
*
* @param constructor The constructor declaration.
* @param hasExtendsClause A value indicating whether the class has an extends clause.
*/
function transformConstructorParameters(constructor) {
// The ES2015 spec specifies in 14.5.14. Runtime Semantics: ClassDefinitionEvaluation:
// If constructor is empty, then
// If ClassHeritag_eopt is present and protoParent is not null, then
// Let constructor be the result of parsing the source text
// constructor(...args) { super (...args);}
// using the syntactic grammar with the goal symbol MethodDefinition[~Yield].
// Else,
// Let constructor be the result of parsing the source text
// constructor( ){ }
// using the syntactic grammar with the goal symbol MethodDefinition[~Yield].
//
// While we could emit the '...args' rest parameter, certain later tools in the pipeline might
// downlevel the '...args' portion less efficiently by naively copying the contents of 'arguments' to an array.
// Instead, we'll avoid using a rest parameter and spread into the super call as
// 'super(...arguments)' instead of 'super(...args)', as you can see in "transformConstructorBody".
return constructor
? ts.visitNodes(constructor.parameters, visitor, ts.isParameter)
: [];
}
/**
* Transforms (or creates) a constructor body for a class with parameter property
* assignments or instance property initializers.
*
* @param node The current class.
* @param constructor The current class constructor.
* @param hasExtendsClause A value indicating whether the class has an extends clause.
*/
function transformConstructorBody(node, constructor, hasExtendsClause) {
var statements = [];
var indexOfFirstStatement = 0;
// The body of a constructor is a new lexical environment
startLexicalEnvironment();
if (constructor) {
indexOfFirstStatement = addPrologueDirectivesAndInitialSuperCall(constructor, statements);
// Add parameters with property assignments. Transforms this:
//
// constructor (public x, public y) {
// }
//
// Into this:
//
// constructor (x, y) {
// this.x = x;
// this.y = y;
// }
//
var propertyAssignments = getParametersWithPropertyAssignments(constructor);
ts.addRange(statements, ts.map(propertyAssignments, transformParameterWithPropertyAssignment));
}
else if (hasExtendsClause) {
// Add a synthetic `super` call:
//
// super(...arguments);
//
statements.push(ts.createStatement(ts.createCall(ts.createSuper(),
/*typeArguments*/ undefined, [ts.createSpread(ts.createIdentifier("arguments"))])));
}
// Add the property initializers. Transforms this:
//
// public x = 1;
//
// Into this:
//
// constructor() {
// this.x = 1;
// }
//
var properties = getInitializedProperties(node, /*isStatic*/ false);
addInitializedPropertyStatements(statements, properties, ts.createThis());
if (constructor) {
// The class already had a constructor, so we should add the existing statements, skipping the initial super call.
ts.addRange(statements, ts.visitNodes(constructor.body.statements, visitor, ts.isStatement, indexOfFirstStatement));
}
// End the lexical environment.
ts.addRange(statements, endLexicalEnvironment());
return ts.setMultiLine(ts.createBlock(ts.createNodeArray(statements,
/*location*/ constructor ? constructor.body.statements : node.members),
/*location*/ constructor ? constructor.body : undefined), true);
}
/**
* Adds super call and preceding prologue directives into the list of statements.
*
* @param ctor The constructor node.
* @returns index of the statement that follows super call
*/
function addPrologueDirectivesAndInitialSuperCall(ctor, result) {
if (ctor.body) {
var statements = ctor.body.statements;
// add prologue directives to the list (if any)
var index = ts.addPrologueDirectives(result, statements, /*ensureUseStrict*/ false, visitor);
if (index === statements.length) {
// list contains nothing but prologue directives (or empty) - exit
return index;
}
var statement = statements[index];
if (statement.kind === 207 /* ExpressionStatement */ && ts.isSuperCall(statement.expression)) {
result.push(ts.visitNode(statement, visitor, ts.isStatement));
return index + 1;
}
return index;
}
return 0;
}
/**
* Gets all parameters of a constructor that should be transformed into property assignments.
*
* @param node The constructor node.
*/
function getParametersWithPropertyAssignments(node) {
return ts.filter(node.parameters, isParameterWithPropertyAssignment);
}
/**
* Determines whether a parameter should be transformed into a property assignment.
*
* @param parameter The parameter node.
*/
function isParameterWithPropertyAssignment(parameter) {
return ts.hasModifier(parameter, 92 /* ParameterPropertyModifier */)
&& ts.isIdentifier(parameter.name);
}
/**
* Transforms a parameter into a property assignment statement.
*
* @param node The parameter declaration.
*/
function transformParameterWithPropertyAssignment(node) {
ts.Debug.assert(ts.isIdentifier(node.name));
var name = node.name;
var propertyName = ts.getMutableClone(name);
ts.setEmitFlags(propertyName, 49152 /* NoComments */ | 1536 /* NoSourceMap */);
var localName = ts.getMutableClone(name);
ts.setEmitFlags(localName, 49152 /* NoComments */);
return ts.startOnNewLine(ts.createStatement(ts.createAssignment(ts.createPropertyAccess(ts.createThis(), propertyName,
/*location*/ node.name), localName),
/*location*/ ts.moveRangePos(node, -1)));
}
/**
* Gets all property declarations with initializers on either the static or instance side of a class.
*
* @param node The class node.
* @param isStatic A value indicating whether to get properties from the static or instance side of the class.
*/
function getInitializedProperties(node, isStatic) {
return ts.filter(node.members, isStatic ? isStaticInitializedProperty : isInstanceInitializedProperty);
}
/**
* Gets a value indicating whether a class element is a static property declaration with an initializer.
*
* @param member The class element node.
*/
function isStaticInitializedProperty(member) {
return isInitializedProperty(member, /*isStatic*/ true);
}
/**
* Gets a value indicating whether a class element is an instance property declaration with an initializer.
*
* @param member The class element node.
*/
function isInstanceInitializedProperty(member) {
return isInitializedProperty(member, /*isStatic*/ false);
}
/**
* Gets a value indicating whether a class element is either a static or an instance property declaration with an initializer.
*
* @param member The class element node.
* @param isStatic A value indicating whether the member should be a static or instance member.
*/
function isInitializedProperty(member, isStatic) {
return member.kind === 147 /* PropertyDeclaration */
&& isStatic === ts.hasModifier(member, 32 /* Static */)
&& member.initializer !== undefined;
}
/**
* Generates assignment statements for property initializers.
*
* @param properties An array of property declarations to transform.
* @param receiver The receiver on which each property should be assigned.
*/
function addInitializedPropertyStatements(statements, properties, receiver) {
for (var _i = 0, properties_7 = properties; _i < properties_7.length; _i++) {
var property = properties_7[_i];
var statement = ts.createStatement(transformInitializedProperty(property, receiver));
ts.setSourceMapRange(statement, ts.moveRangePastModifiers(property));
ts.setCommentRange(statement, property);
statements.push(statement);
}
}
/**
* Generates assignment expressions for property initializers.
*
* @param properties An array of property declarations to transform.
* @param receiver The receiver on which each property should be assigned.
*/
function generateInitializedPropertyExpressions(properties, receiver) {
var expressions = [];
for (var _i = 0, properties_8 = properties; _i < properties_8.length; _i++) {
var property = properties_8[_i];
var expression = transformInitializedProperty(property, receiver);
expression.startsOnNewLine = true;
ts.setSourceMapRange(expression, ts.moveRangePastModifiers(property));
ts.setCommentRange(expression, property);
expressions.push(expression);
}
return expressions;
}
/**
* Transforms a property initializer into an assignment statement.
*
* @param property The property declaration.
* @param receiver The object receiving the property assignment.
*/
function transformInitializedProperty(property, receiver) {
var propertyName = visitPropertyNameOfClassElement(property);
var initializer = ts.visitNode(property.initializer, visitor, ts.isExpression);
var memberAccess = ts.createMemberAccessForPropertyName(receiver, propertyName, /*location*/ propertyName);
return ts.createAssignment(memberAccess, initializer);
}
/**
* Gets either the static or instance members of a class that are decorated, or have
* parameters that are decorated.
*
* @param node The class containing the member.
* @param isStatic A value indicating whether to retrieve static or instance members of
* the class.
*/
function getDecoratedClassElements(node, isStatic) {
return ts.filter(node.members, isStatic ? isStaticDecoratedClassElement : isInstanceDecoratedClassElement);
}
/**
* Determines whether a class member is a static member of a class that is decorated, or
* has parameters that are decorated.
*
* @param member The class member.
*/
function isStaticDecoratedClassElement(member) {
return isDecoratedClassElement(member, /*isStatic*/ true);
}
/**
* Determines whether a class member is an instance member of a class that is decorated,
* or has parameters that are decorated.
*
* @param member The class member.
*/
function isInstanceDecoratedClassElement(member) {
return isDecoratedClassElement(member, /*isStatic*/ false);
}
/**
* Determines whether a class member is either a static or an instance member of a class
* that is decorated, or has parameters that are decorated.
*
* @param member The class member.
*/
function isDecoratedClassElement(member, isStatic) {
return ts.nodeOrChildIsDecorated(member)
&& isStatic === ts.hasModifier(member, 32 /* Static */);
}
/**
* Gets an array of arrays of decorators for the parameters of a function-like node.
* The offset into the result array should correspond to the offset of the parameter.
*
* @param node The function-like node.
*/
function getDecoratorsOfParameters(node) {
var decorators;
if (node) {
var parameters = node.parameters;
for (var i = 0; i < parameters.length; i++) {
var parameter = parameters[i];
if (decorators || parameter.decorators) {
if (!decorators) {
decorators = new Array(parameters.length);
}
decorators[i] = parameter.decorators;
}
}
}
return decorators;
}
/**
* Gets an AllDecorators object containing the decorators for the class and the decorators for the
* parameters of the constructor of the class.
*
* @param node The class node.
*/
function getAllDecoratorsOfConstructor(node) {
var decorators = node.decorators;
var parameters = getDecoratorsOfParameters(ts.getFirstConstructorWithBody(node));
if (!decorators && !parameters) {
return undefined;
}
return {
decorators: decorators,
parameters: parameters
};
}
/**
* Gets an AllDecorators object containing the decorators for the member and its parameters.
*
* @param node The class node that contains the member.
* @param member The class member.
*/
function getAllDecoratorsOfClassElement(node, member) {
switch (member.kind) {
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return getAllDecoratorsOfAccessors(node, member);
case 149 /* MethodDeclaration */:
return getAllDecoratorsOfMethod(member);
case 147 /* PropertyDeclaration */:
return getAllDecoratorsOfProperty(member);
default:
return undefined;
}
}
/**
* Gets an AllDecorators object containing the decorators for the accessor and its parameters.
*
* @param node The class node that contains the accessor.
* @param accessor The class accessor member.
*/
function getAllDecoratorsOfAccessors(node, accessor) {
if (!accessor.body) {
return undefined;
}
var _a = ts.getAllAccessorDeclarations(node.members, accessor), firstAccessor = _a.firstAccessor, secondAccessor = _a.secondAccessor, setAccessor = _a.setAccessor;
if (accessor !== firstAccessor) {
return undefined;
}
var decorators = firstAccessor.decorators || (secondAccessor && secondAccessor.decorators);
var parameters = getDecoratorsOfParameters(setAccessor);
if (!decorators && !parameters) {
return undefined;
}
return { decorators: decorators, parameters: parameters };
}
/**
* Gets an AllDecorators object containing the decorators for the method and its parameters.
*
* @param method The class method member.
*/
function getAllDecoratorsOfMethod(method) {
if (!method.body) {
return undefined;
}
var decorators = method.decorators;
var parameters = getDecoratorsOfParameters(method);
if (!decorators && !parameters) {
return undefined;
}
return { decorators: decorators, parameters: parameters };
}
/**
* Gets an AllDecorators object containing the decorators for the property.
*
* @param property The class property member.
*/
function getAllDecoratorsOfProperty(property) {
var decorators = property.decorators;
if (!decorators) {
return undefined;
}
return { decorators: decorators };
}
/**
* Transforms all of the decorators for a declaration into an array of expressions.
*
* @param node The declaration node.
* @param allDecorators An object containing all of the decorators for the declaration.
*/
function transformAllDecoratorsOfDeclaration(node, allDecorators) {
if (!allDecorators) {
return undefined;
}
var decoratorExpressions = [];
ts.addRange(decoratorExpressions, ts.map(allDecorators.decorators, transformDecorator));
ts.addRange(decoratorExpressions, ts.flatMap(allDecorators.parameters, transformDecoratorsOfParameter));
addTypeMetadata(node, decoratorExpressions);
return decoratorExpressions;
}
/**
* Generates statements used to apply decorators to either the static or instance members
* of a class.
*
* @param node The class node.
* @param isStatic A value indicating whether to generate statements for static or
* instance members.
*/
function addClassElementDecorationStatements(statements, node, isStatic) {
ts.addRange(statements, ts.map(generateClassElementDecorationExpressions(node, isStatic), expressionToStatement));
}
/**
* Generates expressions used to apply decorators to either the static or instance members
* of a class.
*
* @param node The class node.
* @param isStatic A value indicating whether to generate expressions for static or
* instance members.
*/
function generateClassElementDecorationExpressions(node, isStatic) {
var members = getDecoratedClassElements(node, isStatic);
var expressions;
for (var _i = 0, members_2 = members; _i < members_2.length; _i++) {
var member = members_2[_i];
var expression = generateClassElementDecorationExpression(node, member);
if (expression) {
if (!expressions) {
expressions = [expression];
}
else {
expressions.push(expression);
}
}
}
return expressions;
}
/**
* Generates an expression used to evaluate class element decorators at runtime.
*
* @param node The class node that contains the member.
* @param member The class member.
*/
function generateClassElementDecorationExpression(node, member) {
var allDecorators = getAllDecoratorsOfClassElement(node, member);
var decoratorExpressions = transformAllDecoratorsOfDeclaration(member, allDecorators);
if (!decoratorExpressions) {
return undefined;
}
// Emit the call to __decorate. Given the following:
//
// class C {
// @dec method(@dec2 x) {}
// @dec get accessor() {}
// @dec prop;
// }
//
// The emit for a method is:
//
// __decorate([
// dec,
// __param(0, dec2),
// __metadata("design:type", Function),
// __metadata("design:paramtypes", [Object]),
// __metadata("design:returntype", void 0)
// ], C.prototype, "method", undefined);
//
// The emit for an accessor is:
//
// __decorate([
// dec
// ], C.prototype, "accessor", undefined);
//
// The emit for a property is:
//
// __decorate([
// dec
// ], C.prototype, "prop");
//
var prefix = getClassMemberPrefix(node, member);
var memberName = getExpressionForPropertyName(member, /*generateNameForComputedPropertyName*/ true);
var descriptor = languageVersion > 0 /* ES3 */
? member.kind === 147 /* PropertyDeclaration */
? ts.createVoidZero()
: ts.createNull()
: undefined;
var helper = ts.createDecorateHelper(currentExternalHelpersModuleName, decoratorExpressions, prefix, memberName, descriptor, ts.moveRangePastDecorators(member));
ts.setEmitFlags(helper, 49152 /* NoComments */);
return helper;
}
/**
* Generates a __decorate helper call for a class constructor.
*
* @param node The class node.
*/
function addConstructorDecorationStatement(statements, node) {
var expression = generateConstructorDecorationExpression(node);
if (expression) {
statements.push(ts.setOriginalNode(ts.createStatement(expression), node));
}
}
/**
* Generates a __decorate helper call for a class constructor.
*
* @param node The class node.
*/
function generateConstructorDecorationExpression(node) {
var allDecorators = getAllDecoratorsOfConstructor(node);
var decoratorExpressions = transformAllDecoratorsOfDeclaration(node, allDecorators);
if (!decoratorExpressions) {
return undefined;
}
var classAlias = classAliases && classAliases[ts.getOriginalNodeId(node)];
var localName = ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true);
var decorate = ts.createDecorateHelper(currentExternalHelpersModuleName, decoratorExpressions, localName);
var expression = ts.createAssignment(localName, classAlias ? ts.createAssignment(classAlias, decorate) : decorate);
ts.setEmitFlags(expression, 49152 /* NoComments */);
ts.setSourceMapRange(expression, ts.moveRangePastDecorators(node));
return expression;
}
/**
* Transforms a decorator into an expression.
*
* @param decorator The decorator node.
*/
function transformDecorator(decorator) {
return ts.visitNode(decorator.expression, visitor, ts.isExpression);
}
/**
* Transforms the decorators of a parameter.
*
* @param decorators The decorators for the parameter at the provided offset.
* @param parameterOffset The offset of the parameter.
*/
function transformDecoratorsOfParameter(decorators, parameterOffset) {
var expressions;
if (decorators) {
expressions = [];
for (var _i = 0, decorators_1 = decorators; _i < decorators_1.length; _i++) {
var decorator = decorators_1[_i];
var helper = ts.createParamHelper(currentExternalHelpersModuleName, transformDecorator(decorator), parameterOffset,
/*location*/ decorator.expression);
ts.setEmitFlags(helper, 49152 /* NoComments */);
expressions.push(helper);
}
}
return expressions;
}
/**
* Adds optional type metadata for a declaration.
*
* @param node The declaration node.
* @param decoratorExpressions The destination array to which to add new decorator expressions.
*/
function addTypeMetadata(node, decoratorExpressions) {
if (USE_NEW_TYPE_METADATA_FORMAT) {
addNewTypeMetadata(node, decoratorExpressions);
}
else {
addOldTypeMetadata(node, decoratorExpressions);
}
}
function addOldTypeMetadata(node, decoratorExpressions) {
if (compilerOptions.emitDecoratorMetadata) {
if (shouldAddTypeMetadata(node)) {
decoratorExpressions.push(ts.createMetadataHelper(currentExternalHelpersModuleName, "design:type", serializeTypeOfNode(node)));
}
if (shouldAddParamTypesMetadata(node)) {
decoratorExpressions.push(ts.createMetadataHelper(currentExternalHelpersModuleName, "design:paramtypes", serializeParameterTypesOfNode(node)));
}
if (shouldAddReturnTypeMetadata(node)) {
decoratorExpressions.push(ts.createMetadataHelper(currentExternalHelpersModuleName, "design:returntype", serializeReturnTypeOfNode(node)));
}
}
}
function addNewTypeMetadata(node, decoratorExpressions) {
if (compilerOptions.emitDecoratorMetadata) {
var properties = void 0;
if (shouldAddTypeMetadata(node)) {
(properties || (properties = [])).push(ts.createPropertyAssignment("type", ts.createArrowFunction(/*modifiers*/ undefined, /*typeParameters*/ undefined, [], /*type*/ undefined, ts.createToken(35 /* EqualsGreaterThanToken */), serializeTypeOfNode(node))));
}
if (shouldAddParamTypesMetadata(node)) {
(properties || (properties = [])).push(ts.createPropertyAssignment("paramTypes", ts.createArrowFunction(/*modifiers*/ undefined, /*typeParameters*/ undefined, [], /*type*/ undefined, ts.createToken(35 /* EqualsGreaterThanToken */), serializeParameterTypesOfNode(node))));
}
if (shouldAddReturnTypeMetadata(node)) {
(properties || (properties = [])).push(ts.createPropertyAssignment("returnType", ts.createArrowFunction(/*modifiers*/ undefined, /*typeParameters*/ undefined, [], /*type*/ undefined, ts.createToken(35 /* EqualsGreaterThanToken */), serializeReturnTypeOfNode(node))));
}
if (properties) {
decoratorExpressions.push(ts.createMetadataHelper(currentExternalHelpersModuleName, "design:typeinfo", ts.createObjectLiteral(properties, /*location*/ undefined, /*multiLine*/ true)));
}
}
}
/**
* Determines whether to emit the "design:type" metadata based on the node's kind.
* The caller should have already tested whether the node has decorators and whether the
* emitDecoratorMetadata compiler option is set.
*
* @param node The node to test.
*/
function shouldAddTypeMetadata(node) {
var kind = node.kind;
return kind === 149 /* MethodDeclaration */
|| kind === 151 /* GetAccessor */
|| kind === 152 /* SetAccessor */
|| kind === 147 /* PropertyDeclaration */;
}
/**
* Determines whether to emit the "design:returntype" metadata based on the node's kind.
* The caller should have already tested whether the node has decorators and whether the
* emitDecoratorMetadata compiler option is set.
*
* @param node The node to test.
*/
function shouldAddReturnTypeMetadata(node) {
return node.kind === 149 /* MethodDeclaration */;
}
/**
* Determines whether to emit the "design:paramtypes" metadata based on the node's kind.
* The caller should have already tested whether the node has decorators and whether the
* emitDecoratorMetadata compiler option is set.
*
* @param node The node to test.
*/
function shouldAddParamTypesMetadata(node) {
var kind = node.kind;
return kind === 226 /* ClassDeclaration */
|| kind === 197 /* ClassExpression */
|| kind === 149 /* MethodDeclaration */
|| kind === 151 /* GetAccessor */
|| kind === 152 /* SetAccessor */;
}
/**
* Serializes the type of a node for use with decorator type metadata.
*
* @param node The node that should have its type serialized.
*/
function serializeTypeOfNode(node) {
switch (node.kind) {
case 147 /* PropertyDeclaration */:
case 144 /* Parameter */:
case 151 /* GetAccessor */:
return serializeTypeNode(node.type);
case 152 /* SetAccessor */:
return serializeTypeNode(ts.getSetAccessorTypeAnnotationNode(node));
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 149 /* MethodDeclaration */:
return ts.createIdentifier("Function");
default:
return ts.createVoidZero();
}
}
/**
* Gets the most likely element type for a TypeNode. This is not an exhaustive test
* as it assumes a rest argument can only be an array type (either T[], or Array<T>).
*
* @param node The type node.
*/
function getRestParameterElementType(node) {
if (node && node.kind === 162 /* ArrayType */) {
return node.elementType;
}
else if (node && node.kind === 157 /* TypeReference */) {
return ts.singleOrUndefined(node.typeArguments);
}
else {
return undefined;
}
}
/**
* Serializes the types of the parameters of a node for use with decorator type metadata.
*
* @param node The node that should have its parameter types serialized.
*/
function serializeParameterTypesOfNode(node) {
var valueDeclaration = ts.isClassLike(node)
? ts.getFirstConstructorWithBody(node)
: ts.isFunctionLike(node) && ts.nodeIsPresent(node.body)
? node
: undefined;
var expressions = [];
if (valueDeclaration) {
var parameters = valueDeclaration.parameters;
var numParameters = parameters.length;
for (var i = 0; i < numParameters; i++) {
var parameter = parameters[i];
if (i === 0 && ts.isIdentifier(parameter.name) && parameter.name.text === "this") {
continue;
}
if (parameter.dotDotDotToken) {
expressions.push(serializeTypeNode(getRestParameterElementType(parameter.type)));
}
else {
expressions.push(serializeTypeOfNode(parameter));
}
}
}
return ts.createArrayLiteral(expressions);
}
/**
* Serializes the return type of a node for use with decorator type metadata.
*
* @param node The node that should have its return type serialized.
*/
function serializeReturnTypeOfNode(node) {
if (ts.isFunctionLike(node) && node.type) {
return serializeTypeNode(node.type);
}
else if (ts.isAsyncFunctionLike(node)) {
return ts.createIdentifier("Promise");
}
return ts.createVoidZero();
}
/**
* Serializes a type node for use with decorator type metadata.
*
* Types are serialized in the following fashion:
* - Void types point to "undefined" (e.g. "void 0")
* - Function and Constructor types point to the global "Function" constructor.
* - Interface types with a call or construct signature types point to the global
* "Function" constructor.
* - Array and Tuple types point to the global "Array" constructor.
* - Type predicates and booleans point to the global "Boolean" constructor.
* - String literal types and strings point to the global "String" constructor.
* - Enum and number types point to the global "Number" constructor.
* - Symbol types point to the global "Symbol" constructor.
* - Type references to classes (or class-like variables) point to the constructor for the class.
* - Anything else points to the global "Object" constructor.
*
* @param node The type node to serialize.
*/
function serializeTypeNode(node) {
if (node === undefined) {
return ts.createIdentifier("Object");
}
switch (node.kind) {
case 104 /* VoidKeyword */:
return ts.createVoidZero();
case 166 /* ParenthesizedType */:
return serializeTypeNode(node.type);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
return ts.createIdentifier("Function");
case 162 /* ArrayType */:
case 163 /* TupleType */:
return ts.createIdentifier("Array");
case 156 /* TypePredicate */:
case 121 /* BooleanKeyword */:
return ts.createIdentifier("Boolean");
case 134 /* StringKeyword */:
return ts.createIdentifier("String");
case 171 /* LiteralType */:
switch (node.literal.kind) {
case 9 /* StringLiteral */:
return ts.createIdentifier("String");
case 8 /* NumericLiteral */:
return ts.createIdentifier("Number");
case 100 /* TrueKeyword */:
case 85 /* FalseKeyword */:
return ts.createIdentifier("Boolean");
default:
ts.Debug.failBadSyntaxKind(node.literal);
break;
}
break;
case 132 /* NumberKeyword */:
return ts.createIdentifier("Number");
case 135 /* SymbolKeyword */:
return languageVersion < 2 /* ES2015 */
? getGlobalSymbolNameWithFallback()
: ts.createIdentifier("Symbol");
case 157 /* TypeReference */:
return serializeTypeReferenceNode(node);
case 165 /* IntersectionType */:
case 164 /* UnionType */:
{
var unionOrIntersection = node;
var serializedUnion = void 0;
for (var _i = 0, _a = unionOrIntersection.types; _i < _a.length; _i++) {
var typeNode = _a[_i];
var serializedIndividual = serializeTypeNode(typeNode);
// Non identifier
if (serializedIndividual.kind !== 70 /* Identifier */) {
serializedUnion = undefined;
break;
}
// One of the individual is global object, return immediately
if (serializedIndividual.text === "Object") {
return serializedIndividual;
}
// Different types
if (serializedUnion && serializedUnion.text !== serializedIndividual.text) {
serializedUnion = undefined;
break;
}
serializedUnion = serializedIndividual;
}
// If we were able to find common type
if (serializedUnion) {
return serializedUnion;
}
}
// Fallthrough
case 160 /* TypeQuery */:
case 168 /* TypeOperator */:
case 169 /* IndexedAccessType */:
case 170 /* MappedType */:
case 161 /* TypeLiteral */:
case 118 /* AnyKeyword */:
case 167 /* ThisType */:
break;
default:
ts.Debug.failBadSyntaxKind(node);
break;
}
return ts.createIdentifier("Object");
}
/**
* Serializes a TypeReferenceNode to an appropriate JS constructor value for use with
* decorator type metadata.
*
* @param node The type reference node.
*/
function serializeTypeReferenceNode(node) {
switch (resolver.getTypeReferenceSerializationKind(node.typeName, currentScope)) {
case ts.TypeReferenceSerializationKind.Unknown:
var serialized = serializeEntityNameAsExpression(node.typeName, /*useFallback*/ true);
var temp = ts.createTempVariable(hoistVariableDeclaration);
return ts.createLogicalOr(ts.createLogicalAnd(ts.createStrictEquality(ts.createTypeOf(ts.createAssignment(temp, serialized)), ts.createLiteral("function")), temp), ts.createIdentifier("Object"));
case ts.TypeReferenceSerializationKind.TypeWithConstructSignatureAndValue:
return serializeEntityNameAsExpression(node.typeName, /*useFallback*/ false);
case ts.TypeReferenceSerializationKind.VoidNullableOrNeverType:
return ts.createVoidZero();
case ts.TypeReferenceSerializationKind.BooleanType:
return ts.createIdentifier("Boolean");
case ts.TypeReferenceSerializationKind.NumberLikeType:
return ts.createIdentifier("Number");
case ts.TypeReferenceSerializationKind.StringLikeType:
return ts.createIdentifier("String");
case ts.TypeReferenceSerializationKind.ArrayLikeType:
return ts.createIdentifier("Array");
case ts.TypeReferenceSerializationKind.ESSymbolType:
return languageVersion < 2 /* ES2015 */
? getGlobalSymbolNameWithFallback()
: ts.createIdentifier("Symbol");
case ts.TypeReferenceSerializationKind.TypeWithCallSignature:
return ts.createIdentifier("Function");
case ts.TypeReferenceSerializationKind.Promise:
return ts.createIdentifier("Promise");
case ts.TypeReferenceSerializationKind.ObjectType:
default:
return ts.createIdentifier("Object");
}
}
/**
* Serializes an entity name as an expression for decorator type metadata.
*
* @param node The entity name to serialize.
* @param useFallback A value indicating whether to use logical operators to test for the
* entity name at runtime.
*/
function serializeEntityNameAsExpression(node, useFallback) {
switch (node.kind) {
case 70 /* Identifier */:
// Create a clone of the name with a new parent, and treat it as if it were
// a source tree node for the purposes of the checker.
var name_31 = ts.getMutableClone(node);
name_31.flags &= ~8 /* Synthesized */;
name_31.original = undefined;
name_31.parent = currentScope;
if (useFallback) {
return ts.createLogicalAnd(ts.createStrictInequality(ts.createTypeOf(name_31), ts.createLiteral("undefined")), name_31);
}
return name_31;
case 141 /* QualifiedName */:
return serializeQualifiedNameAsExpression(node, useFallback);
}
}
/**
* Serializes an qualified name as an expression for decorator type metadata.
*
* @param node The qualified name to serialize.
* @param useFallback A value indicating whether to use logical operators to test for the
* qualified name at runtime.
*/
function serializeQualifiedNameAsExpression(node, useFallback) {
var left;
if (node.left.kind === 70 /* Identifier */) {
left = serializeEntityNameAsExpression(node.left, useFallback);
}
else if (useFallback) {
var temp = ts.createTempVariable(hoistVariableDeclaration);
left = ts.createLogicalAnd(ts.createAssignment(temp, serializeEntityNameAsExpression(node.left, /*useFallback*/ true)), temp);
}
else {
left = serializeEntityNameAsExpression(node.left, /*useFallback*/ false);
}
return ts.createPropertyAccess(left, node.right);
}
/**
* Gets an expression that points to the global "Symbol" constructor at runtime if it is
* available.
*/
function getGlobalSymbolNameWithFallback() {
return ts.createConditional(ts.createStrictEquality(ts.createTypeOf(ts.createIdentifier("Symbol")), ts.createLiteral("function")), ts.createToken(54 /* QuestionToken */), ts.createIdentifier("Symbol"), ts.createToken(55 /* ColonToken */), ts.createIdentifier("Object"));
}
/**
* Gets an expression that represents a property name. For a computed property, a
* name is generated for the node.
*
* @param member The member whose name should be converted into an expression.
*/
function getExpressionForPropertyName(member, generateNameForComputedPropertyName) {
var name = member.name;
if (ts.isComputedPropertyName(name)) {
return generateNameForComputedPropertyName
? ts.getGeneratedNameForNode(name)
: name.expression;
}
else if (ts.isIdentifier(name)) {
return ts.createLiteral(name.text);
}
else {
return ts.getSynthesizedClone(name);
}
}
/**
* Visits the property name of a class element, for use when emitting property
* initializers. For a computed property on a node with decorators, a temporary
* value is stored for later use.
*
* @param member The member whose name should be visited.
*/
function visitPropertyNameOfClassElement(member) {
var name = member.name;
if (ts.isComputedPropertyName(name)) {
var expression = ts.visitNode(name.expression, visitor, ts.isExpression);
if (member.decorators) {
var generatedName = ts.getGeneratedNameForNode(name);
hoistVariableDeclaration(generatedName);
expression = ts.createAssignment(generatedName, expression);
}
return ts.setOriginalNode(ts.createComputedPropertyName(expression, /*location*/ name), name);
}
else {
return name;
}
}
/**
* Transforms a HeritageClause with TypeScript syntax.
*
* This function will only be called when one of the following conditions are met:
* - The node is a non-`extends` heritage clause that should be elided.
* - The node is an `extends` heritage clause that should be visited, but only allow a single type.
*
* @param node The HeritageClause to transform.
*/
function visitHeritageClause(node) {
if (node.token === 84 /* ExtendsKeyword */) {
var types = ts.visitNodes(node.types, visitor, ts.isExpressionWithTypeArguments, 0, 1);
return ts.createHeritageClause(84 /* ExtendsKeyword */, types, node);
}
return undefined;
}
/**
* Transforms an ExpressionWithTypeArguments with TypeScript syntax.
*
* This function will only be called when one of the following conditions are met:
* - The node contains type arguments that should be elided.
*
* @param node The ExpressionWithTypeArguments to transform.
*/
function visitExpressionWithTypeArguments(node) {
var expression = ts.visitNode(node.expression, visitor, ts.isLeftHandSideExpression);
return ts.createExpressionWithTypeArguments(
/*typeArguments*/ undefined, expression, node);
}
/**
* Determines whether to emit a function-like declaration. We should not emit the
* declaration if it does not have a body.
*
* @param node The declaration node.
*/
function shouldEmitFunctionLikeDeclaration(node) {
return !ts.nodeIsMissing(node.body);
}
function visitConstructor(node) {
if (!shouldEmitFunctionLikeDeclaration(node)) {
return undefined;
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a method declaration of a class.
*
* This function will be called when one of the following conditions are met:
* - The node is an overload
* - The node is marked as abstract, public, private, protected, or readonly
* - The node has both a decorator and a computed property name
*
* @param node The method node.
*/
function visitMethodDeclaration(node) {
if (!shouldEmitFunctionLikeDeclaration(node)) {
return undefined;
}
var method = ts.createMethod(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), node.asteriskToken, visitPropertyNameOfClassElement(node),
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, transformFunctionBody(node),
/*location*/ node);
// While we emit the source map for the node after skipping decorators and modifiers,
// we need to emit the comments for the original range.
ts.setCommentRange(method, node);
ts.setSourceMapRange(method, ts.moveRangePastDecorators(node));
ts.setOriginalNode(method, node);
return method;
}
/**
* Determines whether to emit an accessor declaration. We should not emit the
* declaration if it does not have a body and is abstract.
*
* @param node The declaration node.
*/
function shouldEmitAccessorDeclaration(node) {
return !(ts.nodeIsMissing(node.body) && ts.hasModifier(node, 128 /* Abstract */));
}
/**
* Visits a get accessor declaration of a class.
*
* This function will be called when one of the following conditions are met:
* - The node is marked as abstract, public, private, or protected
* - The node has both a decorator and a computed property name
*
* @param node The get accessor node.
*/
function visitGetAccessor(node) {
if (!shouldEmitAccessorDeclaration(node)) {
return undefined;
}
var accessor = ts.createGetAccessor(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), visitPropertyNameOfClassElement(node), ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, node.body ? ts.visitEachChild(node.body, visitor, context) : ts.createBlock([]),
/*location*/ node);
// While we emit the source map for the node after skipping decorators and modifiers,
// we need to emit the comments for the original range.
ts.setOriginalNode(accessor, node);
ts.setCommentRange(accessor, node);
ts.setSourceMapRange(accessor, ts.moveRangePastDecorators(node));
return accessor;
}
/**
* Visits a set accessor declaration of a class.
*
* This function will be called when one of the following conditions are met:
* - The node is marked as abstract, public, private, or protected
* - The node has both a decorator and a computed property name
*
* @param node The set accessor node.
*/
function visitSetAccessor(node) {
if (!shouldEmitAccessorDeclaration(node)) {
return undefined;
}
var accessor = ts.createSetAccessor(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), visitPropertyNameOfClassElement(node), ts.visitNodes(node.parameters, visitor, ts.isParameter), node.body ? ts.visitEachChild(node.body, visitor, context) : ts.createBlock([]),
/*location*/ node);
// While we emit the source map for the node after skipping decorators and modifiers,
// we need to emit the comments for the original range.
ts.setOriginalNode(accessor, node);
ts.setCommentRange(accessor, node);
ts.setSourceMapRange(accessor, ts.moveRangePastDecorators(node));
return accessor;
}
/**
* Visits a function declaration.
*
* This function will be called when one of the following conditions are met:
* - The node is an overload
* - The node is exported from a TypeScript namespace
* - The node has decorators
*
* @param node The function node.
*/
function visitFunctionDeclaration(node) {
if (!shouldEmitFunctionLikeDeclaration(node)) {
return ts.createNotEmittedStatement(node);
}
var func = ts.createFunctionDeclaration(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), node.asteriskToken, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, transformFunctionBody(node),
/*location*/ node);
ts.setOriginalNode(func, node);
if (isNamespaceExport(node)) {
var statements = [func];
addExportMemberAssignment(statements, node);
return statements;
}
return func;
}
/**
* Visits a function expression node.
*
* This function will be called when one of the following conditions are met:
* - The node has type annotations
*
* @param node The function expression node.
*/
function visitFunctionExpression(node) {
if (ts.nodeIsMissing(node.body)) {
return ts.createOmittedExpression();
}
var func = ts.createFunctionExpression(ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), node.asteriskToken, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, transformFunctionBody(node),
/*location*/ node);
ts.setOriginalNode(func, node);
return func;
}
/**
* @remarks
* This function will be called when one of the following conditions are met:
* - The node has type annotations
*/
function visitArrowFunction(node) {
var func = ts.createArrowFunction(ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier),
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, node.equalsGreaterThanToken, transformConciseBody(node),
/*location*/ node);
ts.setOriginalNode(func, node);
return func;
}
function transformFunctionBody(node) {
return transformFunctionBodyWorker(node.body);
}
function transformFunctionBodyWorker(body, start) {
if (start === void 0) { start = 0; }
var savedCurrentScope = currentScope;
var savedCurrentScopeFirstDeclarationsOfName = currentScopeFirstDeclarationsOfName;
currentScope = body;
currentScopeFirstDeclarationsOfName = ts.createMap();
startLexicalEnvironment();
var statements = ts.visitNodes(body.statements, visitor, ts.isStatement, start);
var visited = ts.updateBlock(body, statements);
var declarations = endLexicalEnvironment();
currentScope = savedCurrentScope;
currentScopeFirstDeclarationsOfName = savedCurrentScopeFirstDeclarationsOfName;
return ts.mergeFunctionBodyLexicalEnvironment(visited, declarations);
}
function transformConciseBody(node) {
return transformConciseBodyWorker(node.body, /*forceBlockFunctionBody*/ false);
}
function transformConciseBodyWorker(body, forceBlockFunctionBody) {
if (ts.isBlock(body)) {
return transformFunctionBodyWorker(body);
}
else {
startLexicalEnvironment();
var visited = ts.visitNode(body, visitor, ts.isConciseBody);
var declarations = endLexicalEnvironment();
var merged = ts.mergeFunctionBodyLexicalEnvironment(visited, declarations);
if (forceBlockFunctionBody && !ts.isBlock(merged)) {
return ts.createBlock([
ts.createReturn(merged)
]);
}
else {
return merged;
}
}
}
/**
* Visits a parameter declaration node.
*
* This function will be called when one of the following conditions are met:
* - The node has an accessibility modifier.
* - The node has a questionToken.
* - The node's kind is ThisKeyword.
*
* @param node The parameter declaration node.
*/
function visitParameter(node) {
if (ts.parameterIsThisKeyword(node)) {
return undefined;
}
var parameter = ts.createParameter(
/*decorators*/ undefined,
/*modifiers*/ undefined, node.dotDotDotToken, ts.visitNode(node.name, visitor, ts.isBindingName),
/*questionToken*/ undefined,
/*type*/ undefined, ts.visitNode(node.initializer, visitor, ts.isExpression),
/*location*/ ts.moveRangePastModifiers(node));
// While we emit the source map for the node after skipping decorators and modifiers,
// we need to emit the comments for the original range.
ts.setOriginalNode(parameter, node);
ts.setCommentRange(parameter, node);
ts.setSourceMapRange(parameter, ts.moveRangePastModifiers(node));
ts.setEmitFlags(parameter.name, 1024 /* NoTrailingSourceMap */);
return parameter;
}
/**
* Visits a variable statement in a namespace.
*
* This function will be called when one of the following conditions are met:
* - The node is exported from a TypeScript namespace.
*/
function visitVariableStatement(node) {
if (isNamespaceExport(node)) {
var variables = ts.getInitializedVariables(node.declarationList);
if (variables.length === 0) {
// elide statement if there are no initialized variables.
return undefined;
}
return ts.createStatement(ts.inlineExpressions(ts.map(variables, transformInitializedVariable)),
/*location*/ node);
}
else {
return ts.visitEachChild(node, visitor, context);
}
}
function transformInitializedVariable(node) {
var name = node.name;
if (ts.isBindingPattern(name)) {
return ts.flattenVariableDestructuringToExpression(node, hoistVariableDeclaration, createNamespaceExportExpression, visitor);
}
else {
return ts.createAssignment(getNamespaceMemberNameWithSourceMapsAndWithoutComments(name), ts.visitNode(node.initializer, visitor, ts.isExpression),
/*location*/ node);
}
}
function visitVariableDeclaration(node) {
return ts.updateVariableDeclaration(node, ts.visitNode(node.name, visitor, ts.isBindingName),
/*type*/ undefined, ts.visitNode(node.initializer, visitor, ts.isExpression));
}
/**
* Visits a parenthesized expression that contains either a type assertion or an `as`
* expression.
*
* @param node The parenthesized expression node.
*/
function visitParenthesizedExpression(node) {
var innerExpression = ts.skipOuterExpressions(node.expression, ~2 /* Assertions */);
if (ts.isAssertionExpression(innerExpression)) {
// Make sure we consider all nested cast expressions, e.g.:
// (<any><number><any>-A).x;
var expression = ts.visitNode(node.expression, visitor, ts.isExpression);
// We have an expression of the form: (<Type>SubExpr). Emitting this as (SubExpr)
// is really not desirable. We would like to emit the subexpression as-is. Omitting
// the parentheses, however, could cause change in the semantics of the generated
// code if the casted expression has a lower precedence than the rest of the
// expression.
//
// Due to the auto-parenthesization rules used by the visitor and factory functions
// we can safely elide the parentheses here, as a new synthetic
// ParenthesizedExpression will be inserted if we remove parentheses too
// aggressively.
//
// To preserve comments, we return a "PartiallyEmittedExpression" here which will
// preserve the position information of the original expression.
return ts.createPartiallyEmittedExpression(expression, node);
}
return ts.visitEachChild(node, visitor, context);
}
function visitAssertionExpression(node) {
var expression = ts.visitNode(node.expression, visitor, ts.isExpression);
return ts.createPartiallyEmittedExpression(expression, node);
}
function visitNonNullExpression(node) {
var expression = ts.visitNode(node.expression, visitor, ts.isLeftHandSideExpression);
return ts.createPartiallyEmittedExpression(expression, node);
}
function visitCallExpression(node) {
return ts.updateCall(node, ts.visitNode(node.expression, visitor, ts.isExpression),
/*typeArguments*/ undefined, ts.visitNodes(node.arguments, visitor, ts.isExpression));
}
function visitNewExpression(node) {
return ts.updateNew(node, ts.visitNode(node.expression, visitor, ts.isExpression),
/*typeArguments*/ undefined, ts.visitNodes(node.arguments, visitor, ts.isExpression));
}
/**
* Determines whether to emit an enum declaration.
*
* @param node The enum declaration node.
*/
function shouldEmitEnumDeclaration(node) {
return !ts.isConst(node)
|| compilerOptions.preserveConstEnums
|| compilerOptions.isolatedModules;
}
/**
* Visits an enum declaration.
*
* This function will be called any time a TypeScript enum is encountered.
*
* @param node The enum declaration node.
*/
function visitEnumDeclaration(node) {
if (!shouldEmitEnumDeclaration(node)) {
return undefined;
}
var statements = [];
// We request to be advised when the printer is about to print this node. This allows
// us to set up the correct state for later substitutions.
var emitFlags = 64 /* AdviseOnEmitNode */;
// If needed, we should emit a variable declaration for the enum. If we emit
// a leading variable declaration, we should not emit leading comments for the
// enum body.
if (addVarForEnumOrModuleDeclaration(statements, node)) {
// We should still emit the comments if we are emitting a system module.
if (moduleKind !== ts.ModuleKind.System || currentScope !== currentSourceFile) {
emitFlags |= 16384 /* NoLeadingComments */;
}
}
// `parameterName` is the declaration name used inside of the enum.
var parameterName = getNamespaceParameterName(node);
// `containerName` is the expression used inside of the enum for assignments.
var containerName = getNamespaceContainerName(node);
// `exportName` is the expression used within this node's container for any exported references.
var exportName = ts.hasModifier(node, 1 /* Export */)
? ts.getExternalModuleOrNamespaceExportName(currentNamespaceContainerName, node, /*allowComments*/ false, /*allowSourceMaps*/ true)
: ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true);
// x || (x = {})
// exports.x || (exports.x = {})
var moduleArg = ts.createLogicalOr(exportName, ts.createAssignment(exportName, ts.createObjectLiteral()));
if (hasNamespaceQualifiedExportName(node)) {
// `localName` is the expression used within this node's containing scope for any local references.
var localName = ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true);
// x = (exports.x || (exports.x = {}))
moduleArg = ts.createAssignment(localName, moduleArg);
}
// (function (x) {
// x[x["y"] = 0] = "y";
// ...
// })(x || (x = {}));
var enumStatement = ts.createStatement(ts.createCall(ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, [ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, parameterName)],
/*type*/ undefined, transformEnumBody(node, containerName)),
/*typeArguments*/ undefined, [moduleArg]),
/*location*/ node);
ts.setOriginalNode(enumStatement, node);
ts.setEmitFlags(enumStatement, emitFlags);
statements.push(enumStatement);
// Add a DeclarationMarker for the enum to preserve trailing comments and mark
// the end of the declaration.
statements.push(ts.createEndOfDeclarationMarker(node));
return statements;
}
/**
* Transforms the body of an enum declaration.
*
* @param node The enum declaration node.
*/
function transformEnumBody(node, localName) {
var savedCurrentNamespaceLocalName = currentNamespaceContainerName;
currentNamespaceContainerName = localName;
var statements = [];
startLexicalEnvironment();
ts.addRange(statements, ts.map(node.members, transformEnumMember));
ts.addRange(statements, endLexicalEnvironment());
currentNamespaceContainerName = savedCurrentNamespaceLocalName;
return ts.createBlock(ts.createNodeArray(statements, /*location*/ node.members),
/*location*/ undefined,
/*multiLine*/ true);
}
/**
* Transforms an enum member into a statement.
*
* @param member The enum member node.
*/
function transformEnumMember(member) {
// enums don't support computed properties
// we pass false as 'generateNameForComputedPropertyName' for a backward compatibility purposes
// old emitter always generate 'expression' part of the name as-is.
var name = getExpressionForPropertyName(member, /*generateNameForComputedPropertyName*/ false);
return ts.createStatement(ts.createAssignment(ts.createElementAccess(currentNamespaceContainerName, ts.createAssignment(ts.createElementAccess(currentNamespaceContainerName, name), transformEnumMemberDeclarationValue(member))), name,
/*location*/ member),
/*location*/ member);
}
/**
* Transforms the value of an enum member.
*
* @param member The enum member node.
*/
function transformEnumMemberDeclarationValue(member) {
var value = resolver.getConstantValue(member);
if (value !== undefined) {
return ts.createLiteral(value);
}
else {
enableSubstitutionForNonQualifiedEnumMembers();
if (member.initializer) {
return ts.visitNode(member.initializer, visitor, ts.isExpression);
}
else {
return ts.createVoidZero();
}
}
}
/**
* Determines whether to elide a module declaration.
*
* @param node The module declaration node.
*/
function shouldEmitModuleDeclaration(node) {
return ts.isInstantiatedModule(node, compilerOptions.preserveConstEnums || compilerOptions.isolatedModules);
}
/**
* Determines whether an exported declaration will have a qualified export name (e.g. `f.x`
* or `exports.x`).
*/
function hasNamespaceQualifiedExportName(node) {
return isNamespaceExport(node)
|| (isExternalModuleExport(node)
&& moduleKind !== ts.ModuleKind.ES2015
&& moduleKind !== ts.ModuleKind.System);
}
/**
* Records that a declaration was emitted in the current scope, if it was the first
* declaration for the provided symbol.
*
* NOTE: if there is ever a transformation above this one, we may not be able to rely
* on symbol names.
*/
function recordEmittedDeclarationInScope(node) {
var name = node.symbol && node.symbol.name;
if (name) {
if (!currentScopeFirstDeclarationsOfName) {
currentScopeFirstDeclarationsOfName = ts.createMap();
}
if (!(name in currentScopeFirstDeclarationsOfName)) {
currentScopeFirstDeclarationsOfName[name] = node;
}
}
}
/**
* Determines whether a declaration is the first declaration with the same name emitted
* in the current scope.
*/
function isFirstEmittedDeclarationInScope(node) {
if (currentScopeFirstDeclarationsOfName) {
var name_32 = node.symbol && node.symbol.name;
if (name_32) {
return currentScopeFirstDeclarationsOfName[name_32] === node;
}
}
return false;
}
/**
* Adds a leading VariableStatement for a enum or module declaration.
*/
function addVarForEnumOrModuleDeclaration(statements, node) {
// Emit a variable statement for the module.
var statement = ts.createVariableStatement(ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), [
ts.createVariableDeclaration(ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true))
]);
ts.setOriginalNode(statement, node);
recordEmittedDeclarationInScope(node);
if (isFirstEmittedDeclarationInScope(node)) {
// Adjust the source map emit to match the old emitter.
if (node.kind === 229 /* EnumDeclaration */) {
ts.setSourceMapRange(statement.declarationList, node);
}
else {
ts.setSourceMapRange(statement, node);
}
// Trailing comments for module declaration should be emitted after the function closure
// instead of the variable statement:
//
// /** Module comment*/
// module m1 {
// function foo4Export() {
// }
// } // trailing comment module
//
// Should emit:
//
// /** Module comment*/
// var m1;
// (function (m1) {
// function foo4Export() {
// }
// })(m1 || (m1 = {})); // trailing comment module
//
ts.setCommentRange(statement, node);
ts.setEmitFlags(statement, 32768 /* NoTrailingComments */ | 33554432 /* HasEndOfDeclarationMarker */);
statements.push(statement);
return true;
}
else {
// For an EnumDeclaration or ModuleDeclaration that merges with a preceeding
// declaration we do not emit a leading variable declaration. To preserve the
// begin/end semantics of the declararation and to properly handle exports
// we wrap the leading variable declaration in a `MergeDeclarationMarker`.
var mergeMarker = ts.createMergeDeclarationMarker(statement);
ts.setEmitFlags(mergeMarker, 49152 /* NoComments */ | 33554432 /* HasEndOfDeclarationMarker */);
statements.push(mergeMarker);
return false;
}
}
/**
* Visits a module declaration node.
*
* This function will be called any time a TypeScript namespace (ModuleDeclaration) is encountered.
*
* @param node The module declaration node.
*/
function visitModuleDeclaration(node) {
if (!shouldEmitModuleDeclaration(node)) {
return ts.createNotEmittedStatement(node);
}
ts.Debug.assert(ts.isIdentifier(node.name), "TypeScript module should have an Identifier name.");
enableSubstitutionForNamespaceExports();
var statements = [];
// We request to be advised when the printer is about to print this node. This allows
// us to set up the correct state for later substitutions.
var emitFlags = 64 /* AdviseOnEmitNode */;
// If needed, we should emit a variable declaration for the module. If we emit
// a leading variable declaration, we should not emit leading comments for the
// module body.
if (addVarForEnumOrModuleDeclaration(statements, node)) {
// We should still emit the comments if we are emitting a system module.
if (moduleKind !== ts.ModuleKind.System || currentScope !== currentSourceFile) {
emitFlags |= 16384 /* NoLeadingComments */;
}
}
// `parameterName` is the declaration name used inside of the namespace.
var parameterName = getNamespaceParameterName(node);
// `containerName` is the expression used inside of the namespace for exports.
var containerName = getNamespaceContainerName(node);
// `exportName` is the expression used within this node's container for any exported references.
var exportName = ts.hasModifier(node, 1 /* Export */)
? ts.getExternalModuleOrNamespaceExportName(currentNamespaceContainerName, node, /*allowComments*/ false, /*allowSourceMaps*/ true)
: ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true);
// x || (x = {})
// exports.x || (exports.x = {})
var moduleArg = ts.createLogicalOr(exportName, ts.createAssignment(exportName, ts.createObjectLiteral()));
if (hasNamespaceQualifiedExportName(node)) {
// `localName` is the expression used within this node's containing scope for any local references.
var localName = ts.getLocalName(node, /*allowComments*/ false, /*allowSourceMaps*/ true);
// x = (exports.x || (exports.x = {}))
moduleArg = ts.createAssignment(localName, moduleArg);
}
// (function (x_1) {
// x_1.y = ...;
// })(x || (x = {}));
var moduleStatement = ts.createStatement(ts.createCall(ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, [ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, parameterName)],
/*type*/ undefined, transformModuleBody(node, containerName)),
/*typeArguments*/ undefined, [moduleArg]),
/*location*/ node);
ts.setOriginalNode(moduleStatement, node);
ts.setEmitFlags(moduleStatement, emitFlags);
statements.push(moduleStatement);
// Add a DeclarationMarker for the namespace to preserve trailing comments and mark
// the end of the declaration.
statements.push(ts.createEndOfDeclarationMarker(node));
return statements;
}
/**
* Transforms the body of a module declaration.
*
* @param node The module declaration node.
*/
function transformModuleBody(node, namespaceLocalName) {
var savedCurrentNamespaceContainerName = currentNamespaceContainerName;
var savedCurrentNamespace = currentNamespace;
var savedCurrentScopeFirstDeclarationsOfName = currentScopeFirstDeclarationsOfName;
currentNamespaceContainerName = namespaceLocalName;
currentNamespace = node;
currentScopeFirstDeclarationsOfName = undefined;
var statements = [];
startLexicalEnvironment();
var statementsLocation;
var blockLocation;
var body = node.body;
if (body.kind === 231 /* ModuleBlock */) {
ts.addRange(statements, ts.visitNodes(body.statements, namespaceElementVisitor, ts.isStatement));
statementsLocation = body.statements;
blockLocation = body;
}
else {
var result = visitModuleDeclaration(body);
if (result) {
if (ts.isArray(result)) {
ts.addRange(statements, result);
}
else {
statements.push(result);
}
}
var moduleBlock = getInnerMostModuleDeclarationFromDottedModule(node).body;
statementsLocation = ts.moveRangePos(moduleBlock.statements, -1);
}
ts.addRange(statements, endLexicalEnvironment());
currentNamespaceContainerName = savedCurrentNamespaceContainerName;
currentNamespace = savedCurrentNamespace;
currentScopeFirstDeclarationsOfName = savedCurrentScopeFirstDeclarationsOfName;
var block = ts.createBlock(ts.createNodeArray(statements,
/*location*/ statementsLocation),
/*location*/ blockLocation,
/*multiLine*/ true);
// namespace hello.hi.world {
// function foo() {}
//
// // TODO, blah
// }
//
// should be emitted as
//
// var hello;
// (function (hello) {
// var hi;
// (function (hi) {
// var world;
// (function (world) {
// function foo() { }
// // TODO, blah
// })(world = hi.world || (hi.world = {}));
// })(hi = hello.hi || (hello.hi = {}));
// })(hello || (hello = {}));
// We only want to emit comment on the namespace which contains block body itself, not the containing namespaces.
if (body.kind !== 231 /* ModuleBlock */) {
ts.setEmitFlags(block, ts.getEmitFlags(block) | 49152 /* NoComments */);
}
return block;
}
function getInnerMostModuleDeclarationFromDottedModule(moduleDeclaration) {
if (moduleDeclaration.body.kind === 230 /* ModuleDeclaration */) {
var recursiveInnerModule = getInnerMostModuleDeclarationFromDottedModule(moduleDeclaration.body);
return recursiveInnerModule || moduleDeclaration.body;
}
}
/**
* Visits an import declaration, eliding it if it is not referenced.
*
* @param node The import declaration node.
*/
function visitImportDeclaration(node) {
if (!node.importClause) {
// Do not elide a side-effect only import declaration.
// import "foo";
return node;
}
// Elide the declaration if the import clause was elided.
var importClause = ts.visitNode(node.importClause, visitImportClause, ts.isImportClause, /*optional*/ true);
return importClause
? ts.updateImportDeclaration(node,
/*decorators*/ undefined,
/*modifiers*/ undefined, importClause, node.moduleSpecifier)
: undefined;
}
/**
* Visits an import clause, eliding it if it is not referenced.
*
* @param node The import clause node.
*/
function visitImportClause(node) {
// Elide the import clause if we elide both its name and its named bindings.
var name = resolver.isReferencedAliasDeclaration(node) ? node.name : undefined;
var namedBindings = ts.visitNode(node.namedBindings, visitNamedImportBindings, ts.isNamedImportBindings, /*optional*/ true);
return (name || namedBindings) ? ts.updateImportClause(node, name, namedBindings) : undefined;
}
/**
* Visits named import bindings, eliding it if it is not referenced.
*
* @param node The named import bindings node.
*/
function visitNamedImportBindings(node) {
if (node.kind === 237 /* NamespaceImport */) {
// Elide a namespace import if it is not referenced.
return resolver.isReferencedAliasDeclaration(node) ? node : undefined;
}
else {
// Elide named imports if all of its import specifiers are elided.
var elements = ts.visitNodes(node.elements, visitImportSpecifier, ts.isImportSpecifier);
return ts.some(elements) ? ts.updateNamedImports(node, elements) : undefined;
}
}
/**
* Visits an import specifier, eliding it if it is not referenced.
*
* @param node The import specifier node.
*/
function visitImportSpecifier(node) {
// Elide an import specifier if it is not referenced.
return resolver.isReferencedAliasDeclaration(node) ? node : undefined;
}
/**
* Visits an export assignment, eliding it if it does not contain a clause that resolves
* to a value.
*
* @param node The export assignment node.
*/
function visitExportAssignment(node) {
// Elide the export assignment if it does not reference a value.
return resolver.isValueAliasDeclaration(node)
? ts.visitEachChild(node, visitor, context)
: undefined;
}
/**
* Visits an export declaration, eliding it if it does not contain a clause that resolves
* to a value.
*
* @param node The export declaration node.
*/
function visitExportDeclaration(node) {
if (!node.exportClause) {
// Elide a star export if the module it references does not export a value.
return resolver.moduleExportsSomeValue(node.moduleSpecifier) ? node : undefined;
}
if (!resolver.isValueAliasDeclaration(node)) {
// Elide the export declaration if it does not export a value.
return undefined;
}
// Elide the export declaration if all of its named exports are elided.
var exportClause = ts.visitNode(node.exportClause, visitNamedExports, ts.isNamedExports, /*optional*/ true);
return exportClause
? ts.updateExportDeclaration(node,
/*decorators*/ undefined,
/*modifiers*/ undefined, exportClause, node.moduleSpecifier)
: undefined;
}
/**
* Visits named exports, eliding it if it does not contain an export specifier that
* resolves to a value.
*
* @param node The named exports node.
*/
function visitNamedExports(node) {
// Elide the named exports if all of its export specifiers were elided.
var elements = ts.visitNodes(node.elements, visitExportSpecifier, ts.isExportSpecifier);
return ts.some(elements) ? ts.updateNamedExports(node, elements) : undefined;
}
/**
* Visits an export specifier, eliding it if it does not resolve to a value.
*
* @param node The export specifier node.
*/
function visitExportSpecifier(node) {
// Elide an export specifier if it does not reference a value.
return resolver.isValueAliasDeclaration(node) ? node : undefined;
}
/**
* Determines whether to emit an import equals declaration.
*
* @param node The import equals declaration node.
*/
function shouldEmitImportEqualsDeclaration(node) {
// preserve old compiler's behavior: emit 'var' for import declaration (even if we do not consider them referenced) when
// - current file is not external module
// - import declaration is top level and target is value imported by entity name
return resolver.isReferencedAliasDeclaration(node)
|| (!ts.isExternalModule(currentSourceFile)
&& resolver.isTopLevelValueImportEqualsWithEntityName(node));
}
/**
* Visits an import equals declaration.
*
* @param node The import equals declaration node.
*/
function visitImportEqualsDeclaration(node) {
if (ts.isExternalModuleImportEqualsDeclaration(node)) {
// Elide external module `import=` if it is not referenced.
return resolver.isReferencedAliasDeclaration(node)
? ts.visitEachChild(node, visitor, context)
: undefined;
}
if (!shouldEmitImportEqualsDeclaration(node)) {
return undefined;
}
var moduleReference = ts.createExpressionFromEntityName(node.moduleReference);
ts.setEmitFlags(moduleReference, 49152 /* NoComments */ | 65536 /* NoNestedComments */);
if (isNamedExternalModuleExport(node) || !isNamespaceExport(node)) {
// export var ${name} = ${moduleReference};
// var ${name} = ${moduleReference};
return ts.setOriginalNode(ts.createVariableStatement(ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), ts.createVariableDeclarationList([
ts.setOriginalNode(ts.createVariableDeclaration(node.name,
/*type*/ undefined, moduleReference), node)
]), node), node);
}
else {
// exports.${name} = ${moduleReference};
return ts.setOriginalNode(createNamespaceExport(node.name, moduleReference, node), node);
}
}
/**
* Gets a value indicating whether the node is exported from a namespace.
*
* @param node The node to test.
*/
function isNamespaceExport(node) {
return currentNamespace !== undefined && ts.hasModifier(node, 1 /* Export */);
}
/**
* Gets a value indicating whether the node is exported from an external module.
*
* @param node The node to test.
*/
function isExternalModuleExport(node) {
return currentNamespace === undefined && ts.hasModifier(node, 1 /* Export */);
}
/**
* Gets a value indicating whether the node is a named export from an external module.
*
* @param node The node to test.
*/
function isNamedExternalModuleExport(node) {
return isExternalModuleExport(node)
&& !ts.hasModifier(node, 512 /* Default */);
}
/**
* Gets a value indicating whether the node is the default export of an external module.
*
* @param node The node to test.
*/
function isDefaultExternalModuleExport(node) {
return isExternalModuleExport(node)
&& ts.hasModifier(node, 512 /* Default */);
}
/**
* Creates a statement for the provided expression. This is used in calls to `map`.
*/
function expressionToStatement(expression) {
return ts.createStatement(expression, /*location*/ undefined);
}
function addExportMemberAssignment(statements, node) {
var expression = ts.createAssignment(ts.getExternalModuleOrNamespaceExportName(currentNamespaceContainerName, node, /*allowComments*/ false, /*allowSourceMaps*/ true), ts.getLocalName(node));
ts.setSourceMapRange(expression, ts.createRange(node.name.pos, node.end));
var statement = ts.createStatement(expression);
ts.setSourceMapRange(statement, ts.createRange(-1, node.end));
statements.push(statement);
}
function createNamespaceExport(exportName, exportValue, location) {
return ts.createStatement(ts.createAssignment(ts.getNamespaceMemberName(currentNamespaceContainerName, exportName, /*allowComments*/ false, /*allowSourceMaps*/ true), exportValue), location);
}
function createNamespaceExportExpression(exportName, exportValue, location) {
return ts.createAssignment(getNamespaceMemberNameWithSourceMapsAndWithoutComments(exportName), exportValue, location);
}
function getNamespaceMemberNameWithSourceMapsAndWithoutComments(name) {
return ts.getNamespaceMemberName(currentNamespaceContainerName, name, /*allowComments*/ false, /*allowSourceMaps*/ true);
}
/**
* Gets the declaration name used inside of a namespace or enum.
*/
function getNamespaceParameterName(node) {
var name = ts.getGeneratedNameForNode(node);
ts.setSourceMapRange(name, node.name);
return name;
}
/**
* Gets the expression used to refer to a namespace or enum within the body
* of its declaration.
*/
function getNamespaceContainerName(node) {
return ts.getGeneratedNameForNode(node);
}
/**
* Gets a local alias for a class declaration if it is a decorated class with an internal
* reference to the static side of the class. This is necessary to avoid issues with
* double-binding semantics for the class name.
*/
function getClassAliasIfNeeded(node) {
if (resolver.getNodeCheckFlags(node) & 8388608 /* ClassWithConstructorReference */) {
enableSubstitutionForClassAliases();
var classAlias = ts.createUniqueName(node.name && !ts.isGeneratedIdentifier(node.name) ? node.name.text : "default");
classAliases[ts.getOriginalNodeId(node)] = classAlias;
hoistVariableDeclaration(classAlias);
return classAlias;
}
}
function getClassPrototype(node) {
return ts.createPropertyAccess(ts.getDeclarationName(node), "prototype");
}
function getClassMemberPrefix(node, member) {
return ts.hasModifier(member, 32 /* Static */)
? ts.getDeclarationName(node)
: getClassPrototype(node);
}
function enableSubstitutionForNonQualifiedEnumMembers() {
if ((enabledSubstitutions & 8 /* NonQualifiedEnumMembers */) === 0) {
enabledSubstitutions |= 8 /* NonQualifiedEnumMembers */;
context.enableSubstitution(70 /* Identifier */);
}
}
function enableSubstitutionForClassAliases() {
if ((enabledSubstitutions & 1 /* ClassAliases */) === 0) {
enabledSubstitutions |= 1 /* ClassAliases */;
// We need to enable substitutions for identifiers. This allows us to
// substitute class names inside of a class declaration.
context.enableSubstitution(70 /* Identifier */);
// Keep track of class aliases.
classAliases = ts.createMap();
}
}
function enableSubstitutionForNamespaceExports() {
if ((enabledSubstitutions & 2 /* NamespaceExports */) === 0) {
enabledSubstitutions |= 2 /* NamespaceExports */;
// We need to enable substitutions for identifiers and shorthand property assignments. This allows us to
// substitute the names of exported members of a namespace.
context.enableSubstitution(70 /* Identifier */);
context.enableSubstitution(258 /* ShorthandPropertyAssignment */);
// We need to be notified when entering and exiting namespaces.
context.enableEmitNotification(230 /* ModuleDeclaration */);
}
}
function isTransformedModuleDeclaration(node) {
return ts.getOriginalNode(node).kind === 230 /* ModuleDeclaration */;
}
function isTransformedEnumDeclaration(node) {
return ts.getOriginalNode(node).kind === 229 /* EnumDeclaration */;
}
/**
* Hook for node emit.
*
* @param emitContext A context hint for the emitter.
* @param node The node to emit.
* @param emit A callback used to emit the node in the printer.
*/
function onEmitNode(emitContext, node, emitCallback) {
var savedApplicableSubstitutions = applicableSubstitutions;
if (enabledSubstitutions & 2 /* NamespaceExports */ && isTransformedModuleDeclaration(node)) {
applicableSubstitutions |= 2 /* NamespaceExports */;
}
if (enabledSubstitutions & 8 /* NonQualifiedEnumMembers */ && isTransformedEnumDeclaration(node)) {
applicableSubstitutions |= 8 /* NonQualifiedEnumMembers */;
}
previousOnEmitNode(emitContext, node, emitCallback);
applicableSubstitutions = savedApplicableSubstitutions;
}
/**
* Hooks node substitutions.
*
* @param emitContext A context hint for the emitter.
* @param node The node to substitute.
*/
function onSubstituteNode(emitContext, node) {
node = previousOnSubstituteNode(emitContext, node);
if (emitContext === 1 /* Expression */) {
return substituteExpression(node);
}
else if (ts.isShorthandPropertyAssignment(node)) {
return substituteShorthandPropertyAssignment(node);
}
return node;
}
function substituteShorthandPropertyAssignment(node) {
if (enabledSubstitutions & 2 /* NamespaceExports */) {
var name_33 = node.name;
var exportedName = trySubstituteNamespaceExportedName(name_33);
if (exportedName) {
// A shorthand property with an assignment initializer is probably part of a
// destructuring assignment
if (node.objectAssignmentInitializer) {
var initializer = ts.createAssignment(exportedName, node.objectAssignmentInitializer);
return ts.createPropertyAssignment(name_33, initializer, /*location*/ node);
}
return ts.createPropertyAssignment(name_33, exportedName, /*location*/ node);
}
}
return node;
}
function substituteExpression(node) {
switch (node.kind) {
case 70 /* Identifier */:
return substituteExpressionIdentifier(node);
case 177 /* PropertyAccessExpression */:
return substitutePropertyAccessExpression(node);
case 178 /* ElementAccessExpression */:
return substituteElementAccessExpression(node);
}
return node;
}
function substituteExpressionIdentifier(node) {
return trySubstituteClassAlias(node)
|| trySubstituteNamespaceExportedName(node)
|| node;
}
function trySubstituteClassAlias(node) {
if (enabledSubstitutions & 1 /* ClassAliases */) {
if (resolver.getNodeCheckFlags(node) & 16777216 /* ConstructorReferenceInClass */) {
// Due to the emit for class decorators, any reference to the class from inside of the class body
// must instead be rewritten to point to a temporary variable to avoid issues with the double-bind
// behavior of class names in ES6.
// Also, when emitting statics for class expressions, we must substitute a class alias for
// constructor references in static property initializers.
var declaration = resolver.getReferencedValueDeclaration(node);
if (declaration) {
var classAlias = classAliases[declaration.id];
if (classAlias) {
var clone_4 = ts.getSynthesizedClone(classAlias);
ts.setSourceMapRange(clone_4, node);
ts.setCommentRange(clone_4, node);
return clone_4;
}
}
}
}
return undefined;
}
function trySubstituteNamespaceExportedName(node) {
// If this is explicitly a local name, do not substitute.
if (enabledSubstitutions & applicableSubstitutions && !ts.isLocalName(node)) {
// If we are nested within a namespace declaration, we may need to qualifiy
// an identifier that is exported from a merged namespace.
var container = resolver.getReferencedExportContainer(node, /*prefixLocals*/ false);
if (container && container.kind !== 261 /* SourceFile */) {
var substitute = (applicableSubstitutions & 2 /* NamespaceExports */ && container.kind === 230 /* ModuleDeclaration */) ||
(applicableSubstitutions & 8 /* NonQualifiedEnumMembers */ && container.kind === 229 /* EnumDeclaration */);
if (substitute) {
return ts.createPropertyAccess(ts.getGeneratedNameForNode(container), node, /*location*/ node);
}
}
}
return undefined;
}
function substitutePropertyAccessExpression(node) {
return substituteConstantValue(node);
}
function substituteElementAccessExpression(node) {
return substituteConstantValue(node);
}
function substituteConstantValue(node) {
var constantValue = tryGetConstEnumValue(node);
if (constantValue !== undefined) {
var substitute = ts.createLiteral(constantValue);
ts.setSourceMapRange(substitute, node);
ts.setCommentRange(substitute, node);
if (!compilerOptions.removeComments) {
var propertyName = ts.isPropertyAccessExpression(node)
? ts.declarationNameToString(node.name)
: ts.getTextOfNode(node.argumentExpression);
substitute.trailingComment = " " + propertyName + " ";
}
ts.setConstantValue(node, constantValue);
return substitute;
}
return node;
}
function tryGetConstEnumValue(node) {
if (compilerOptions.isolatedModules) {
return undefined;
}
return ts.isPropertyAccessExpression(node) || ts.isElementAccessExpression(node)
? resolver.getConstantValue(node)
: undefined;
}
}
ts.transformTypeScript = transformTypeScript;
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
var entities = createEntitiesMap();
function transformJsx(context) {
var compilerOptions = context.getCompilerOptions();
var currentSourceFile;
return transformSourceFile;
/**
* Transform JSX-specific syntax in a SourceFile.
*
* @param node A SourceFile node.
*/
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)) {
return node;
}
currentSourceFile = node;
node = ts.visitEachChild(node, visitor, context);
currentSourceFile = undefined;
return node;
}
function visitor(node) {
if (node.transformFlags & 4 /* Jsx */) {
return visitorWorker(node);
}
else if (node.transformFlags & 8 /* ContainsJsx */) {
return ts.visitEachChild(node, visitor, context);
}
else {
return node;
}
}
function visitorWorker(node) {
switch (node.kind) {
case 246 /* JsxElement */:
return visitJsxElement(node, /*isChild*/ false);
case 247 /* JsxSelfClosingElement */:
return visitJsxSelfClosingElement(node, /*isChild*/ false);
case 252 /* JsxExpression */:
return visitJsxExpression(node);
default:
ts.Debug.failBadSyntaxKind(node);
return undefined;
}
}
function transformJsxChildToExpression(node) {
switch (node.kind) {
case 10 /* JsxText */:
return visitJsxText(node);
case 252 /* JsxExpression */:
return visitJsxExpression(node);
case 246 /* JsxElement */:
return visitJsxElement(node, /*isChild*/ true);
case 247 /* JsxSelfClosingElement */:
return visitJsxSelfClosingElement(node, /*isChild*/ true);
default:
ts.Debug.failBadSyntaxKind(node);
return undefined;
}
}
function visitJsxElement(node, isChild) {
return visitJsxOpeningLikeElement(node.openingElement, node.children, isChild, /*location*/ node);
}
function visitJsxSelfClosingElement(node, isChild) {
return visitJsxOpeningLikeElement(node, /*children*/ undefined, isChild, /*location*/ node);
}
function visitJsxOpeningLikeElement(node, children, isChild, location) {
var tagName = getTagName(node);
var objectProperties;
var attrs = node.attributes;
if (attrs.length === 0) {
// When there are no attributes, React wants "null"
objectProperties = ts.createNull();
}
else {
// Map spans of JsxAttribute nodes into object literals and spans
// of JsxSpreadAttribute nodes into expressions.
var segments = ts.flatten(ts.spanMap(attrs, ts.isJsxSpreadAttribute, function (attrs, isSpread) { return isSpread
? ts.map(attrs, transformJsxSpreadAttributeToExpression)
: ts.createObjectLiteral(ts.map(attrs, transformJsxAttributeToObjectLiteralElement)); }));
if (ts.isJsxSpreadAttribute(attrs[0])) {
// We must always emit at least one object literal before a spread
// argument.
segments.unshift(ts.createObjectLiteral());
}
// Either emit one big object literal (no spread attribs), or
// a call to the __assign helper.
objectProperties = ts.singleOrUndefined(segments)
|| ts.createAssignHelper(currentSourceFile.externalHelpersModuleName, segments);
}
var element = ts.createExpressionForJsxElement(context.getEmitResolver().getJsxFactoryEntity(), compilerOptions.reactNamespace, tagName, objectProperties, ts.filter(ts.map(children, transformJsxChildToExpression), ts.isDefined), node, location);
if (isChild) {
ts.startOnNewLine(element);
}
return element;
}
function transformJsxSpreadAttributeToExpression(node) {
return ts.visitNode(node.expression, visitor, ts.isExpression);
}
function transformJsxAttributeToObjectLiteralElement(node) {
var name = getAttributeName(node);
var expression = transformJsxAttributeInitializer(node.initializer);
return ts.createPropertyAssignment(name, expression);
}
function transformJsxAttributeInitializer(node) {
if (node === undefined) {
return ts.createLiteral(true);
}
else if (node.kind === 9 /* StringLiteral */) {
var decoded = tryDecodeEntities(node.text);
return decoded ? ts.createLiteral(decoded, /*location*/ node) : node;
}
else if (node.kind === 252 /* JsxExpression */) {
return visitJsxExpression(node);
}
else {
ts.Debug.failBadSyntaxKind(node);
}
}
function visitJsxText(node) {
var text = ts.getTextOfNode(node, /*includeTrivia*/ true);
var parts;
var firstNonWhitespace = 0;
var lastNonWhitespace = -1;
// JSX trims whitespace at the end and beginning of lines, except that the
// start/end of a tag is considered a start/end of a line only if that line is
// on the same line as the closing tag. See examples in
// tests/cases/conformance/jsx/tsxReactEmitWhitespace.tsx
for (var i = 0; i < text.length; i++) {
var c = text.charCodeAt(i);
if (ts.isLineBreak(c)) {
if (firstNonWhitespace !== -1 && (lastNonWhitespace - firstNonWhitespace + 1 > 0)) {
var part = text.substr(firstNonWhitespace, lastNonWhitespace - firstNonWhitespace + 1);
if (!parts) {
parts = [];
}
// We do not escape the string here as that is handled by the printer
// when it emits the literal. We do, however, need to decode JSX entities.
parts.push(ts.createLiteral(decodeEntities(part)));
}
firstNonWhitespace = -1;
}
else if (!ts.isWhiteSpace(c)) {
lastNonWhitespace = i;
if (firstNonWhitespace === -1) {
firstNonWhitespace = i;
}
}
}
if (firstNonWhitespace !== -1) {
var part = text.substr(firstNonWhitespace);
if (!parts) {
parts = [];
}
// We do not escape the string here as that is handled by the printer
// when it emits the literal. We do, however, need to decode JSX entities.
parts.push(ts.createLiteral(decodeEntities(part)));
}
if (parts) {
return ts.reduceLeft(parts, aggregateJsxTextParts);
}
return undefined;
}
/**
* Aggregates two expressions by interpolating them with a whitespace literal.
*/
function aggregateJsxTextParts(left, right) {
return ts.createAdd(ts.createAdd(left, ts.createLiteral(" ")), right);
}
/**
* Replace entities like "&nbsp;", "&#123;", and "&#xDEADBEEF;" with the characters they encode.
* See https://en.wikipedia.org/wiki/List_of_XML_and_HTML_character_entity_references
*/
function decodeEntities(text) {
return text.replace(/&((#((\d+)|x([\da-fA-F]+)))|(\w+));/g, function (match, _all, _number, _digits, decimal, hex, word) {
if (decimal) {
return String.fromCharCode(parseInt(decimal, 10));
}
else if (hex) {
return String.fromCharCode(parseInt(hex, 16));
}
else {
var ch = entities[word];
// If this is not a valid entity, then just use `match` (replace it with itself, i.e. don't replace)
return ch ? String.fromCharCode(ch) : match;
}
});
}
/** Like `decodeEntities` but returns `undefined` if there were no entities to decode. */
function tryDecodeEntities(text) {
var decoded = decodeEntities(text);
return decoded === text ? undefined : decoded;
}
function getTagName(node) {
if (node.kind === 246 /* JsxElement */) {
return getTagName(node.openingElement);
}
else {
var name_34 = node.tagName;
if (ts.isIdentifier(name_34) && ts.isIntrinsicJsxName(name_34.text)) {
return ts.createLiteral(name_34.text);
}
else {
return ts.createExpressionFromEntityName(name_34);
}
}
}
/**
* Emit an attribute name, which is quoted if it needs to be quoted. Because
* these emit into an object literal property name, we don't need to be worried
* about keywords, just non-identifier characters
*/
function getAttributeName(node) {
var name = node.name;
if (/^[A-Za-z_]\w*$/.test(name.text)) {
return name;
}
else {
return ts.createLiteral(name.text);
}
}
function visitJsxExpression(node) {
return ts.visitNode(node.expression, visitor, ts.isExpression);
}
}
ts.transformJsx = transformJsx;
function createEntitiesMap() {
return ts.createMap({
"quot": 0x0022,
"amp": 0x0026,
"apos": 0x0027,
"lt": 0x003C,
"gt": 0x003E,
"nbsp": 0x00A0,
"iexcl": 0x00A1,
"cent": 0x00A2,
"pound": 0x00A3,
"curren": 0x00A4,
"yen": 0x00A5,
"brvbar": 0x00A6,
"sect": 0x00A7,
"uml": 0x00A8,
"copy": 0x00A9,
"ordf": 0x00AA,
"laquo": 0x00AB,
"not": 0x00AC,
"shy": 0x00AD,
"reg": 0x00AE,
"macr": 0x00AF,
"deg": 0x00B0,
"plusmn": 0x00B1,
"sup2": 0x00B2,
"sup3": 0x00B3,
"acute": 0x00B4,
"micro": 0x00B5,
"para": 0x00B6,
"middot": 0x00B7,
"cedil": 0x00B8,
"sup1": 0x00B9,
"ordm": 0x00BA,
"raquo": 0x00BB,
"frac14": 0x00BC,
"frac12": 0x00BD,
"frac34": 0x00BE,
"iquest": 0x00BF,
"Agrave": 0x00C0,
"Aacute": 0x00C1,
"Acirc": 0x00C2,
"Atilde": 0x00C3,
"Auml": 0x00C4,
"Aring": 0x00C5,
"AElig": 0x00C6,
"Ccedil": 0x00C7,
"Egrave": 0x00C8,
"Eacute": 0x00C9,
"Ecirc": 0x00CA,
"Euml": 0x00CB,
"Igrave": 0x00CC,
"Iacute": 0x00CD,
"Icirc": 0x00CE,
"Iuml": 0x00CF,
"ETH": 0x00D0,
"Ntilde": 0x00D1,
"Ograve": 0x00D2,
"Oacute": 0x00D3,
"Ocirc": 0x00D4,
"Otilde": 0x00D5,
"Ouml": 0x00D6,
"times": 0x00D7,
"Oslash": 0x00D8,
"Ugrave": 0x00D9,
"Uacute": 0x00DA,
"Ucirc": 0x00DB,
"Uuml": 0x00DC,
"Yacute": 0x00DD,
"THORN": 0x00DE,
"szlig": 0x00DF,
"agrave": 0x00E0,
"aacute": 0x00E1,
"acirc": 0x00E2,
"atilde": 0x00E3,
"auml": 0x00E4,
"aring": 0x00E5,
"aelig": 0x00E6,
"ccedil": 0x00E7,
"egrave": 0x00E8,
"eacute": 0x00E9,
"ecirc": 0x00EA,
"euml": 0x00EB,
"igrave": 0x00EC,
"iacute": 0x00ED,
"icirc": 0x00EE,
"iuml": 0x00EF,
"eth": 0x00F0,
"ntilde": 0x00F1,
"ograve": 0x00F2,
"oacute": 0x00F3,
"ocirc": 0x00F4,
"otilde": 0x00F5,
"ouml": 0x00F6,
"divide": 0x00F7,
"oslash": 0x00F8,
"ugrave": 0x00F9,
"uacute": 0x00FA,
"ucirc": 0x00FB,
"uuml": 0x00FC,
"yacute": 0x00FD,
"thorn": 0x00FE,
"yuml": 0x00FF,
"OElig": 0x0152,
"oelig": 0x0153,
"Scaron": 0x0160,
"scaron": 0x0161,
"Yuml": 0x0178,
"fnof": 0x0192,
"circ": 0x02C6,
"tilde": 0x02DC,
"Alpha": 0x0391,
"Beta": 0x0392,
"Gamma": 0x0393,
"Delta": 0x0394,
"Epsilon": 0x0395,
"Zeta": 0x0396,
"Eta": 0x0397,
"Theta": 0x0398,
"Iota": 0x0399,
"Kappa": 0x039A,
"Lambda": 0x039B,
"Mu": 0x039C,
"Nu": 0x039D,
"Xi": 0x039E,
"Omicron": 0x039F,
"Pi": 0x03A0,
"Rho": 0x03A1,
"Sigma": 0x03A3,
"Tau": 0x03A4,
"Upsilon": 0x03A5,
"Phi": 0x03A6,
"Chi": 0x03A7,
"Psi": 0x03A8,
"Omega": 0x03A9,
"alpha": 0x03B1,
"beta": 0x03B2,
"gamma": 0x03B3,
"delta": 0x03B4,
"epsilon": 0x03B5,
"zeta": 0x03B6,
"eta": 0x03B7,
"theta": 0x03B8,
"iota": 0x03B9,
"kappa": 0x03BA,
"lambda": 0x03BB,
"mu": 0x03BC,
"nu": 0x03BD,
"xi": 0x03BE,
"omicron": 0x03BF,
"pi": 0x03C0,
"rho": 0x03C1,
"sigmaf": 0x03C2,
"sigma": 0x03C3,
"tau": 0x03C4,
"upsilon": 0x03C5,
"phi": 0x03C6,
"chi": 0x03C7,
"psi": 0x03C8,
"omega": 0x03C9,
"thetasym": 0x03D1,
"upsih": 0x03D2,
"piv": 0x03D6,
"ensp": 0x2002,
"emsp": 0x2003,
"thinsp": 0x2009,
"zwnj": 0x200C,
"zwj": 0x200D,
"lrm": 0x200E,
"rlm": 0x200F,
"ndash": 0x2013,
"mdash": 0x2014,
"lsquo": 0x2018,
"rsquo": 0x2019,
"sbquo": 0x201A,
"ldquo": 0x201C,
"rdquo": 0x201D,
"bdquo": 0x201E,
"dagger": 0x2020,
"Dagger": 0x2021,
"bull": 0x2022,
"hellip": 0x2026,
"permil": 0x2030,
"prime": 0x2032,
"Prime": 0x2033,
"lsaquo": 0x2039,
"rsaquo": 0x203A,
"oline": 0x203E,
"frasl": 0x2044,
"euro": 0x20AC,
"image": 0x2111,
"weierp": 0x2118,
"real": 0x211C,
"trade": 0x2122,
"alefsym": 0x2135,
"larr": 0x2190,
"uarr": 0x2191,
"rarr": 0x2192,
"darr": 0x2193,
"harr": 0x2194,
"crarr": 0x21B5,
"lArr": 0x21D0,
"uArr": 0x21D1,
"rArr": 0x21D2,
"dArr": 0x21D3,
"hArr": 0x21D4,
"forall": 0x2200,
"part": 0x2202,
"exist": 0x2203,
"empty": 0x2205,
"nabla": 0x2207,
"isin": 0x2208,
"notin": 0x2209,
"ni": 0x220B,
"prod": 0x220F,
"sum": 0x2211,
"minus": 0x2212,
"lowast": 0x2217,
"radic": 0x221A,
"prop": 0x221D,
"infin": 0x221E,
"ang": 0x2220,
"and": 0x2227,
"or": 0x2228,
"cap": 0x2229,
"cup": 0x222A,
"int": 0x222B,
"there4": 0x2234,
"sim": 0x223C,
"cong": 0x2245,
"asymp": 0x2248,
"ne": 0x2260,
"equiv": 0x2261,
"le": 0x2264,
"ge": 0x2265,
"sub": 0x2282,
"sup": 0x2283,
"nsub": 0x2284,
"sube": 0x2286,
"supe": 0x2287,
"oplus": 0x2295,
"otimes": 0x2297,
"perp": 0x22A5,
"sdot": 0x22C5,
"lceil": 0x2308,
"rceil": 0x2309,
"lfloor": 0x230A,
"rfloor": 0x230B,
"lang": 0x2329,
"rang": 0x232A,
"loz": 0x25CA,
"spades": 0x2660,
"clubs": 0x2663,
"hearts": 0x2665,
"diams": 0x2666
});
}
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
function transformESNext(context) {
var hoistVariableDeclaration = context.hoistVariableDeclaration;
var currentSourceFile;
return transformSourceFile;
function transformSourceFile(node) {
currentSourceFile = node;
return ts.visitEachChild(node, visitor, context);
}
function visitor(node) {
if (node.transformFlags & 16 /* ESNext */) {
return visitorWorker(node);
}
else if (node.transformFlags & 32 /* ContainsESNext */) {
return ts.visitEachChild(node, visitor, context);
}
else {
return node;
}
}
function visitorWorker(node) {
switch (node.kind) {
case 176 /* ObjectLiteralExpression */:
return visitObjectLiteralExpression(node);
case 192 /* BinaryExpression */:
return visitBinaryExpression(node);
case 223 /* VariableDeclaration */:
return visitVariableDeclaration(node);
case 213 /* ForOfStatement */:
return visitForOfStatement(node);
case 172 /* ObjectBindingPattern */:
case 173 /* ArrayBindingPattern */:
return node;
case 225 /* FunctionDeclaration */:
return visitFunctionDeclaration(node);
case 184 /* FunctionExpression */:
return visitFunctionExpression(node);
case 185 /* ArrowFunction */:
return visitArrowFunction(node);
case 144 /* Parameter */:
return visitParameter(node);
default:
ts.Debug.failBadSyntaxKind(node);
return ts.visitEachChild(node, visitor, context);
}
}
function chunkObjectLiteralElements(elements) {
var chunkObject;
var objects = [];
for (var _i = 0, elements_3 = elements; _i < elements_3.length; _i++) {
var e = elements_3[_i];
if (e.kind === 259 /* SpreadAssignment */) {
if (chunkObject) {
objects.push(ts.createObjectLiteral(chunkObject));
chunkObject = undefined;
}
var target = e.expression;
objects.push(ts.visitNode(target, visitor, ts.isExpression));
}
else {
if (!chunkObject) {
chunkObject = [];
}
if (e.kind === 257 /* PropertyAssignment */) {
var p = e;
chunkObject.push(ts.createPropertyAssignment(p.name, ts.visitNode(p.initializer, visitor, ts.isExpression)));
}
else {
chunkObject.push(e);
}
}
}
if (chunkObject) {
objects.push(ts.createObjectLiteral(chunkObject));
}
return objects;
}
function visitObjectLiteralExpression(node) {
// spread elements emit like so:
// non-spread elements are chunked together into object literals, and then all are passed to __assign:
// { a, ...o, b } => __assign({a}, o, {b});
// If the first element is a spread element, then the first argument to __assign is {}:
// { ...o, a, b, ...o2 } => __assign({}, o, {a, b}, o2)
var objects = chunkObjectLiteralElements(node.properties);
if (objects.length && objects[0].kind !== 176 /* ObjectLiteralExpression */) {
objects.unshift(ts.createObjectLiteral());
}
return ts.createCall(ts.createIdentifier("__assign"), undefined, objects);
}
/**
* Visits a BinaryExpression that contains a destructuring assignment.
*
* @param node A BinaryExpression node.
*/
function visitBinaryExpression(node) {
if (ts.isDestructuringAssignment(node) && node.left.transformFlags & 48 /* AssertESNext */) {
return ts.flattenDestructuringAssignment(context, node, /*needsDestructuringValue*/ true, hoistVariableDeclaration, visitor, /*transformRest*/ true);
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a VariableDeclaration node with a binding pattern.
*
* @param node A VariableDeclaration node.
*/
function visitVariableDeclaration(node) {
// If we are here it is because the name contains a binding pattern with a rest somewhere in it.
if (ts.isBindingPattern(node.name) && node.name.transformFlags & 48 /* AssertESNext */) {
var result = ts.flattenVariableDestructuring(node, /*value*/ undefined, visitor, /*recordTempVariable*/ undefined, /*transformRest*/ true);
return result;
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a ForOfStatement and converts it into a ES2015-compatible ForOfStatement.
*
* @param node A ForOfStatement.
*/
function visitForOfStatement(node) {
// The following ESNext code:
//
// for (let { x, y, ...rest } of expr) { }
//
// should be emitted as
//
// for (var _a of expr) {
// let { x, y } = _a, rest = __rest(_a, ["x", "y"]);
// }
//
// where _a is a temp emitted to capture the RHS.
// When the left hand side is an expression instead of a let declaration,
// the `let` before the `{ x, y }` is not emitted.
// When the left hand side is a let/const, the v is renamed if there is
// another v in scope.
// Note that all assignments to the LHS are emitted in the body, including
// all destructuring.
// Note also that because an extra statement is needed to assign to the LHS,
// for-of bodies are always emitted as blocks.
// for (<init> of <expression>) <statement>
// where <init> is [let] variabledeclarationlist | expression
var initializer = node.initializer;
if (!isRestBindingPattern(initializer) && !isRestAssignment(initializer)) {
return ts.visitEachChild(node, visitor, context);
}
return ts.convertForOf(node, undefined, visitor, ts.noop, context, /*transformRest*/ true);
}
function isRestBindingPattern(initializer) {
if (ts.isVariableDeclarationList(initializer)) {
var declaration = ts.firstOrUndefined(initializer.declarations);
return declaration && declaration.name &&
declaration.name.kind === 172 /* ObjectBindingPattern */ &&
!!(declaration.name.transformFlags & 8388608 /* ContainsSpreadExpression */);
}
return false;
}
function isRestAssignment(initializer) {
return initializer.kind === 176 /* ObjectLiteralExpression */ &&
initializer.transformFlags & 8388608 /* ContainsSpreadExpression */;
}
function visitParameter(node) {
if (isObjectRestParameter(node)) {
// Binding patterns are converted into a generated name and are
// evaluated inside the function body.
return ts.setOriginalNode(ts.createParameter(
/*decorators*/ undefined,
/*modifiers*/ undefined,
/*dotDotDotToken*/ undefined, ts.getGeneratedNameForNode(node),
/*questionToken*/ undefined,
/*type*/ undefined, node.initializer,
/*location*/ node),
/*original*/ node);
}
else {
return node;
}
}
function isObjectRestParameter(node) {
return node.name &&
node.name.kind === 172 /* ObjectBindingPattern */ &&
!!(node.name.transformFlags & 8388608 /* ContainsSpreadExpression */);
}
function visitFunctionDeclaration(node) {
var hasRest = ts.forEach(node.parameters, isObjectRestParameter);
var body = hasRest ?
ts.transformFunctionBody(node, visitor, currentSourceFile, context, ts.noop, /*convertObjectRest*/ true) :
ts.visitEachChild(node.body, visitor, context);
return ts.setOriginalNode(ts.createFunctionDeclaration(
/*decorators*/ undefined, node.modifiers, node.asteriskToken, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, body,
/*location*/ node),
/*original*/ node);
}
function visitArrowFunction(node) {
var hasRest = ts.forEach(node.parameters, isObjectRestParameter);
var body = hasRest ?
ts.transformFunctionBody(node, visitor, currentSourceFile, context, ts.noop, /*convertObjectRest*/ true) :
ts.visitEachChild(node.body, visitor, context);
var func = ts.setOriginalNode(ts.createArrowFunction(
/*modifiers*/ undefined,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, node.equalsGreaterThanToken, body,
/*location*/ node),
/*original*/ node);
ts.setEmitFlags(func, 256 /* CapturesThis */);
return func;
}
function visitFunctionExpression(node) {
var hasRest = ts.forEach(node.parameters, isObjectRestParameter);
var body = hasRest ?
ts.transformFunctionBody(node, visitor, currentSourceFile, context, ts.noop, /*convertObjectRest*/ true) :
ts.visitEachChild(node.body, visitor, context);
return ts.setOriginalNode(ts.createFunctionExpression(
/*modifiers*/ undefined, node.asteriskToken, name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, body,
/*location*/ node),
/*original*/ node);
}
}
ts.transformESNext = transformESNext;
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
function transformES2017(context) {
var ES2017SubstitutionFlags;
(function (ES2017SubstitutionFlags) {
/** Enables substitutions for async methods with `super` calls. */
ES2017SubstitutionFlags[ES2017SubstitutionFlags["AsyncMethodsWithSuper"] = 1] = "AsyncMethodsWithSuper";
})(ES2017SubstitutionFlags || (ES2017SubstitutionFlags = {}));
var startLexicalEnvironment = context.startLexicalEnvironment, endLexicalEnvironment = context.endLexicalEnvironment;
var resolver = context.getEmitResolver();
var compilerOptions = context.getCompilerOptions();
var languageVersion = ts.getEmitScriptTarget(compilerOptions);
// These variables contain state that changes as we descend into the tree.
var currentSourceFileExternalHelpersModuleName;
/**
* Keeps track of whether expression substitution has been enabled for specific edge cases.
* They are persisted between each SourceFile transformation and should not be reset.
*/
var enabledSubstitutions;
/**
* Keeps track of whether we are within any containing namespaces when performing
* just-in-time substitution while printing an expression identifier.
*/
var applicableSubstitutions;
/**
* This keeps track of containers where `super` is valid, for use with
* just-in-time substitution for `super` expressions inside of async methods.
*/
var currentSuperContainer;
// Save the previous transformation hooks.
var previousOnEmitNode = context.onEmitNode;
var previousOnSubstituteNode = context.onSubstituteNode;
// Set new transformation hooks.
context.onEmitNode = onEmitNode;
context.onSubstituteNode = onSubstituteNode;
var currentScope;
return transformSourceFile;
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)) {
return node;
}
currentSourceFileExternalHelpersModuleName = node.externalHelpersModuleName;
return ts.visitEachChild(node, visitor, context);
}
function visitor(node) {
if (node.transformFlags & 64 /* ES2017 */) {
return visitorWorker(node);
}
else if (node.transformFlags & 128 /* ContainsES2017 */) {
return ts.visitEachChild(node, visitor, context);
}
return node;
}
function visitorWorker(node) {
switch (node.kind) {
case 119 /* AsyncKeyword */:
// ES2017 async modifier should be elided for targets < ES2017
return undefined;
case 189 /* AwaitExpression */:
// ES2017 'await' expressions must be transformed for targets < ES2017.
return visitAwaitExpression(node);
case 149 /* MethodDeclaration */:
// ES2017 method declarations may be 'async'
return visitMethodDeclaration(node);
case 225 /* FunctionDeclaration */:
// ES2017 function declarations may be 'async'
return visitFunctionDeclaration(node);
case 184 /* FunctionExpression */:
// ES2017 function expressions may be 'async'
return visitFunctionExpression(node);
case 185 /* ArrowFunction */:
// ES2017 arrow functions may be 'async'
return visitArrowFunction(node);
default:
ts.Debug.failBadSyntaxKind(node);
return node;
}
}
/**
* Visits an await expression.
*
* This function will be called any time a ES2017 await expression is encountered.
*
* @param node The await expression node.
*/
function visitAwaitExpression(node) {
return ts.setOriginalNode(ts.createYield(
/*asteriskToken*/ undefined, ts.visitNode(node.expression, visitor, ts.isExpression),
/*location*/ node), node);
}
/**
* Visits a method declaration of a class.
*
* This function will be called when one of the following conditions are met:
* - The node is marked as async
*
* @param node The method node.
*/
function visitMethodDeclaration(node) {
if (!ts.isAsyncFunctionLike(node)) {
return node;
}
var method = ts.createMethod(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, visitor, ts.isModifier), node.asteriskToken, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, transformFunctionBody(node),
/*location*/ node);
// While we emit the source map for the node after skipping decorators and modifiers,
// we need to emit the comments for the original range.
ts.setCommentRange(method, node);
ts.setSourceMapRange(method, ts.moveRangePastDecorators(node));
ts.setOriginalNode(method, node);
return method;
}
/**
* Visits a function declaration.
*
* This function will be called when one of the following conditions are met:
* - The node is marked async
*
* @param node The function node.
*/
function visitFunctionDeclaration(node) {
if (!ts.isAsyncFunctionLike(node)) {
return node;
}
var func = ts.createFunctionDeclaration(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, visitor, ts.isModifier), node.asteriskToken, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, transformFunctionBody(node),
/*location*/ node);
ts.setOriginalNode(func, node);
return func;
}
/**
* Visits a function expression node.
*
* This function will be called when one of the following conditions are met:
* - The node is marked async
*
* @param node The function expression node.
*/
function visitFunctionExpression(node) {
if (!ts.isAsyncFunctionLike(node)) {
return node;
}
if (ts.nodeIsMissing(node.body)) {
return ts.createOmittedExpression();
}
var func = ts.createFunctionExpression(
/*modifiers*/ undefined, node.asteriskToken, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, transformFunctionBody(node),
/*location*/ node);
ts.setOriginalNode(func, node);
return func;
}
/**
* @remarks
* This function will be called when one of the following conditions are met:
* - The node is marked async
*/
function visitArrowFunction(node) {
if (!ts.isAsyncFunctionLike(node)) {
return node;
}
var func = ts.createArrowFunction(ts.visitNodes(node.modifiers, visitor, ts.isModifier),
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, node.equalsGreaterThanToken, transformConciseBody(node),
/*location*/ node);
ts.setOriginalNode(func, node);
return func;
}
function transformFunctionBody(node) {
return transformAsyncFunctionBody(node);
}
function transformConciseBody(node) {
return transformAsyncFunctionBody(node);
}
function transformFunctionBodyWorker(body, start) {
if (start === void 0) { start = 0; }
var savedCurrentScope = currentScope;
currentScope = body;
startLexicalEnvironment();
var statements = ts.visitNodes(body.statements, visitor, ts.isStatement, start);
var visited = ts.updateBlock(body, statements);
var declarations = endLexicalEnvironment();
currentScope = savedCurrentScope;
return ts.mergeFunctionBodyLexicalEnvironment(visited, declarations);
}
function transformAsyncFunctionBody(node) {
var original = ts.getOriginalNode(node, ts.isFunctionLike);
var nodeType = original.type;
var promiseConstructor = languageVersion < 2 /* ES2015 */ ? getPromiseConstructor(nodeType) : undefined;
var isArrowFunction = node.kind === 185 /* ArrowFunction */;
var hasLexicalArguments = (resolver.getNodeCheckFlags(node) & 8192 /* CaptureArguments */) !== 0;
// An async function is emit as an outer function that calls an inner
// generator function. To preserve lexical bindings, we pass the current
// `this` and `arguments` objects to `__awaiter`. The generator function
// passed to `__awaiter` is executed inside of the callback to the
// promise constructor.
if (!isArrowFunction) {
var statements = [];
var statementOffset = ts.addPrologueDirectives(statements, node.body.statements, /*ensureUseStrict*/ false, visitor);
statements.push(ts.createReturn(ts.createAwaiterHelper(currentSourceFileExternalHelpersModuleName, hasLexicalArguments, promiseConstructor, transformFunctionBodyWorker(node.body, statementOffset))));
var block = ts.createBlock(statements, /*location*/ node.body, /*multiLine*/ true);
// Minor optimization, emit `_super` helper to capture `super` access in an arrow.
// This step isn't needed if we eventually transform this to ES5.
if (languageVersion >= 2 /* ES2015 */) {
if (resolver.getNodeCheckFlags(node) & 4096 /* AsyncMethodWithSuperBinding */) {
enableSubstitutionForAsyncMethodsWithSuper();
ts.setEmitFlags(block, 8 /* EmitAdvancedSuperHelper */);
}
else if (resolver.getNodeCheckFlags(node) & 2048 /* AsyncMethodWithSuper */) {
enableSubstitutionForAsyncMethodsWithSuper();
ts.setEmitFlags(block, 4 /* EmitSuperHelper */);
}
}
return block;
}
else {
return ts.createAwaiterHelper(currentSourceFileExternalHelpersModuleName, hasLexicalArguments, promiseConstructor, transformConciseBodyWorker(node.body, /*forceBlockFunctionBody*/ true));
}
}
function transformConciseBodyWorker(body, forceBlockFunctionBody) {
if (ts.isBlock(body)) {
return transformFunctionBodyWorker(body);
}
else {
startLexicalEnvironment();
var visited = ts.visitNode(body, visitor, ts.isConciseBody);
var declarations = endLexicalEnvironment();
var merged = ts.mergeFunctionBodyLexicalEnvironment(visited, declarations);
if (forceBlockFunctionBody && !ts.isBlock(merged)) {
return ts.createBlock([
ts.createReturn(merged)
]);
}
else {
return merged;
}
}
}
function getPromiseConstructor(type) {
if (type) {
var typeName = ts.getEntityNameFromTypeNode(type);
if (typeName && ts.isEntityName(typeName)) {
var serializationKind = resolver.getTypeReferenceSerializationKind(typeName);
if (serializationKind === ts.TypeReferenceSerializationKind.TypeWithConstructSignatureAndValue
|| serializationKind === ts.TypeReferenceSerializationKind.Unknown) {
return typeName;
}
}
}
return undefined;
}
function enableSubstitutionForAsyncMethodsWithSuper() {
if ((enabledSubstitutions & 1 /* AsyncMethodsWithSuper */) === 0) {
enabledSubstitutions |= 1 /* AsyncMethodsWithSuper */;
// We need to enable substitutions for call, property access, and element access
// if we need to rewrite super calls.
context.enableSubstitution(179 /* CallExpression */);
context.enableSubstitution(177 /* PropertyAccessExpression */);
context.enableSubstitution(178 /* ElementAccessExpression */);
// We need to be notified when entering and exiting declarations that bind super.
context.enableEmitNotification(226 /* ClassDeclaration */);
context.enableEmitNotification(149 /* MethodDeclaration */);
context.enableEmitNotification(151 /* GetAccessor */);
context.enableEmitNotification(152 /* SetAccessor */);
context.enableEmitNotification(150 /* Constructor */);
}
}
function substituteExpression(node) {
switch (node.kind) {
case 177 /* PropertyAccessExpression */:
return substitutePropertyAccessExpression(node);
case 178 /* ElementAccessExpression */:
return substituteElementAccessExpression(node);
case 179 /* CallExpression */:
if (enabledSubstitutions & 1 /* AsyncMethodsWithSuper */) {
return substituteCallExpression(node);
}
break;
}
return node;
}
function substitutePropertyAccessExpression(node) {
if (enabledSubstitutions & 1 /* AsyncMethodsWithSuper */ && node.expression.kind === 96 /* SuperKeyword */) {
var flags = getSuperContainerAsyncMethodFlags();
if (flags) {
return createSuperAccessInAsyncMethod(ts.createLiteral(node.name.text), flags, node);
}
}
return node;
}
function substituteElementAccessExpression(node) {
if (enabledSubstitutions & 1 /* AsyncMethodsWithSuper */ && node.expression.kind === 96 /* SuperKeyword */) {
var flags = getSuperContainerAsyncMethodFlags();
if (flags) {
return createSuperAccessInAsyncMethod(node.argumentExpression, flags, node);
}
}
return node;
}
function substituteCallExpression(node) {
var expression = node.expression;
if (ts.isSuperProperty(expression)) {
var flags = getSuperContainerAsyncMethodFlags();
if (flags) {
var argumentExpression = ts.isPropertyAccessExpression(expression)
? substitutePropertyAccessExpression(expression)
: substituteElementAccessExpression(expression);
return ts.createCall(ts.createPropertyAccess(argumentExpression, "call"),
/*typeArguments*/ undefined, [
ts.createThis()
].concat(node.arguments));
}
}
return node;
}
function isSuperContainer(node) {
var kind = node.kind;
return kind === 226 /* ClassDeclaration */
|| kind === 150 /* Constructor */
|| kind === 149 /* MethodDeclaration */
|| kind === 151 /* GetAccessor */
|| kind === 152 /* SetAccessor */;
}
/**
* Hook for node emit.
*
* @param node The node to emit.
* @param emit A callback used to emit the node in the printer.
*/
function onEmitNode(emitContext, node, emitCallback) {
var savedApplicableSubstitutions = applicableSubstitutions;
var savedCurrentSuperContainer = currentSuperContainer;
// If we need to support substitutions for `super` in an async method,
// we should track it here.
if (enabledSubstitutions & 1 /* AsyncMethodsWithSuper */ && isSuperContainer(node)) {
currentSuperContainer = node;
}
previousOnEmitNode(emitContext, node, emitCallback);
applicableSubstitutions = savedApplicableSubstitutions;
currentSuperContainer = savedCurrentSuperContainer;
}
/**
* Hooks node substitutions.
*
* @param node The node to substitute.
* @param isExpression A value indicating whether the node is to be used in an expression
* position.
*/
function onSubstituteNode(emitContext, node) {
node = previousOnSubstituteNode(emitContext, node);
if (emitContext === 1 /* Expression */) {
return substituteExpression(node);
}
return node;
}
function createSuperAccessInAsyncMethod(argumentExpression, flags, location) {
if (flags & 4096 /* AsyncMethodWithSuperBinding */) {
return ts.createPropertyAccess(ts.createCall(ts.createIdentifier("_super"),
/*typeArguments*/ undefined, [argumentExpression]), "value", location);
}
else {
return ts.createCall(ts.createIdentifier("_super"),
/*typeArguments*/ undefined, [argumentExpression], location);
}
}
function getSuperContainerAsyncMethodFlags() {
return currentSuperContainer !== undefined
&& resolver.getNodeCheckFlags(currentSuperContainer) & (2048 /* AsyncMethodWithSuper */ | 4096 /* AsyncMethodWithSuperBinding */);
}
}
ts.transformES2017 = transformES2017;
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
function transformES2016(context) {
var hoistVariableDeclaration = context.hoistVariableDeclaration;
return transformSourceFile;
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)) {
return node;
}
return ts.visitEachChild(node, visitor, context);
}
function visitor(node) {
if (node.transformFlags & 256 /* ES2016 */) {
return visitorWorker(node);
}
else if (node.transformFlags & 512 /* ContainsES2016 */) {
return ts.visitEachChild(node, visitor, context);
}
else {
return node;
}
}
function visitorWorker(node) {
switch (node.kind) {
case 192 /* BinaryExpression */:
return visitBinaryExpression(node);
default:
ts.Debug.failBadSyntaxKind(node);
return ts.visitEachChild(node, visitor, context);
}
}
function visitBinaryExpression(node) {
// We are here because ES2016 adds support for the exponentiation operator.
var left = ts.visitNode(node.left, visitor, ts.isExpression);
var right = ts.visitNode(node.right, visitor, ts.isExpression);
if (node.operatorToken.kind === 61 /* AsteriskAsteriskEqualsToken */) {
var target = void 0;
var value = void 0;
if (ts.isElementAccessExpression(left)) {
// Transforms `a[x] **= b` into `(_a = a)[_x = x] = Math.pow(_a[_x], b)`
var expressionTemp = ts.createTempVariable(hoistVariableDeclaration);
var argumentExpressionTemp = ts.createTempVariable(hoistVariableDeclaration);
target = ts.createElementAccess(ts.createAssignment(expressionTemp, left.expression, /*location*/ left.expression), ts.createAssignment(argumentExpressionTemp, left.argumentExpression, /*location*/ left.argumentExpression),
/*location*/ left);
value = ts.createElementAccess(expressionTemp, argumentExpressionTemp,
/*location*/ left);
}
else if (ts.isPropertyAccessExpression(left)) {
// Transforms `a.x **= b` into `(_a = a).x = Math.pow(_a.x, b)`
var expressionTemp = ts.createTempVariable(hoistVariableDeclaration);
target = ts.createPropertyAccess(ts.createAssignment(expressionTemp, left.expression, /*location*/ left.expression), left.name,
/*location*/ left);
value = ts.createPropertyAccess(expressionTemp, left.name,
/*location*/ left);
}
else {
// Transforms `a **= b` into `a = Math.pow(a, b)`
target = left;
value = left;
}
return ts.createAssignment(target, ts.createMathPow(value, right, /*location*/ node), /*location*/ node);
}
else if (node.operatorToken.kind === 39 /* AsteriskAsteriskToken */) {
// Transforms `a ** b` into `Math.pow(a, b)`
return ts.createMathPow(left, right, /*location*/ node);
}
else {
ts.Debug.failBadSyntaxKind(node);
return ts.visitEachChild(node, visitor, context);
}
}
}
ts.transformES2016 = transformES2016;
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
var ES2015SubstitutionFlags;
(function (ES2015SubstitutionFlags) {
/** Enables substitutions for captured `this` */
ES2015SubstitutionFlags[ES2015SubstitutionFlags["CapturedThis"] = 1] = "CapturedThis";
/** Enables substitutions for block-scoped bindings. */
ES2015SubstitutionFlags[ES2015SubstitutionFlags["BlockScopedBindings"] = 2] = "BlockScopedBindings";
})(ES2015SubstitutionFlags || (ES2015SubstitutionFlags = {}));
var CopyDirection;
(function (CopyDirection) {
CopyDirection[CopyDirection["ToOriginal"] = 0] = "ToOriginal";
CopyDirection[CopyDirection["ToOutParameter"] = 1] = "ToOutParameter";
})(CopyDirection || (CopyDirection = {}));
var Jump;
(function (Jump) {
Jump[Jump["Break"] = 2] = "Break";
Jump[Jump["Continue"] = 4] = "Continue";
Jump[Jump["Return"] = 8] = "Return";
})(Jump || (Jump = {}));
var SuperCaptureResult;
(function (SuperCaptureResult) {
/**
* A capture may have been added for calls to 'super', but
* the caller should emit subsequent statements normally.
*/
SuperCaptureResult[SuperCaptureResult["NoReplacement"] = 0] = "NoReplacement";
/**
* A call to 'super()' got replaced with a capturing statement like:
*
* var _this = _super.call(...) || this;
*
* Callers should skip the current statement.
*/
SuperCaptureResult[SuperCaptureResult["ReplaceSuperCapture"] = 1] = "ReplaceSuperCapture";
/**
* A call to 'super()' got replaced with a capturing statement like:
*
* return _super.call(...) || this;
*
* Callers should skip the current statement and avoid any returns of '_this'.
*/
SuperCaptureResult[SuperCaptureResult["ReplaceWithReturn"] = 2] = "ReplaceWithReturn";
})(SuperCaptureResult || (SuperCaptureResult = {}));
function transformES2015(context) {
var startLexicalEnvironment = context.startLexicalEnvironment, endLexicalEnvironment = context.endLexicalEnvironment, hoistVariableDeclaration = context.hoistVariableDeclaration;
var resolver = context.getEmitResolver();
var previousOnSubstituteNode = context.onSubstituteNode;
var previousOnEmitNode = context.onEmitNode;
context.onEmitNode = onEmitNode;
context.onSubstituteNode = onSubstituteNode;
var currentSourceFile;
var currentText;
var currentParent;
var currentNode;
var enclosingVariableStatement;
var enclosingBlockScopeContainer;
var enclosingBlockScopeContainerParent;
var enclosingFunction;
var enclosingNonArrowFunction;
var enclosingNonAsyncFunctionBody;
var isInConstructorWithCapturedSuper;
/**
* Used to track if we are emitting body of the converted loop
*/
var convertedLoopState;
/**
* Keeps track of whether substitutions have been enabled for specific cases.
* They are persisted between each SourceFile transformation and should not
* be reset.
*/
var enabledSubstitutions;
return transformSourceFile;
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)) {
return node;
}
currentSourceFile = node;
currentText = node.text;
return ts.visitNode(node, visitor, ts.isSourceFile);
}
function visitor(node) {
return saveStateAndInvoke(node, dispatcher);
}
function dispatcher(node) {
return convertedLoopState
? visitorForConvertedLoopWorker(node)
: visitorWorker(node);
}
function saveStateAndInvoke(node, f) {
var savedEnclosingFunction = enclosingFunction;
var savedEnclosingNonArrowFunction = enclosingNonArrowFunction;
var savedEnclosingNonAsyncFunctionBody = enclosingNonAsyncFunctionBody;
var savedEnclosingBlockScopeContainer = enclosingBlockScopeContainer;
var savedEnclosingBlockScopeContainerParent = enclosingBlockScopeContainerParent;
var savedEnclosingVariableStatement = enclosingVariableStatement;
var savedCurrentParent = currentParent;
var savedCurrentNode = currentNode;
var savedConvertedLoopState = convertedLoopState;
var savedIsInConstructorWithCapturedSuper = isInConstructorWithCapturedSuper;
if (ts.nodeStartsNewLexicalEnvironment(node)) {
// don't treat content of nodes that start new lexical environment as part of converted loop copy or constructor body
isInConstructorWithCapturedSuper = false;
convertedLoopState = undefined;
}
onBeforeVisitNode(node);
var visited = f(node);
isInConstructorWithCapturedSuper = savedIsInConstructorWithCapturedSuper;
convertedLoopState = savedConvertedLoopState;
enclosingFunction = savedEnclosingFunction;
enclosingNonArrowFunction = savedEnclosingNonArrowFunction;
enclosingNonAsyncFunctionBody = savedEnclosingNonAsyncFunctionBody;
enclosingBlockScopeContainer = savedEnclosingBlockScopeContainer;
enclosingBlockScopeContainerParent = savedEnclosingBlockScopeContainerParent;
enclosingVariableStatement = savedEnclosingVariableStatement;
currentParent = savedCurrentParent;
currentNode = savedCurrentNode;
return visited;
}
function returnCapturedThis(node) {
return ts.setOriginalNode(ts.createReturn(ts.createIdentifier("_this")), node);
}
function isReturnVoidStatementInConstructorWithCapturedSuper(node) {
return isInConstructorWithCapturedSuper && node.kind === 216 /* ReturnStatement */ && !node.expression;
}
function shouldCheckNode(node) {
return (node.transformFlags & 1024 /* ES2015 */) !== 0 ||
node.kind === 219 /* LabeledStatement */ ||
(ts.isIterationStatement(node, /*lookInLabeledStatements*/ false) && shouldConvertIterationStatementBody(node));
}
function visitorWorker(node) {
if (isReturnVoidStatementInConstructorWithCapturedSuper(node)) {
return returnCapturedThis(node);
}
else if (shouldCheckNode(node)) {
return visitJavaScript(node);
}
else if (node.transformFlags & 2048 /* ContainsES2015 */ || (isInConstructorWithCapturedSuper && !ts.isExpression(node))) {
// we want to dive in this branch either if node has children with ES2015 specific syntax
// or we are inside constructor that captures result of the super call so all returns without expression should be
// rewritten. Note: we skip expressions since returns should never appear there
return ts.visitEachChild(node, visitor, context);
}
else {
return node;
}
}
function visitorForConvertedLoopWorker(node) {
var result;
if (shouldCheckNode(node)) {
result = visitJavaScript(node);
}
else {
result = visitNodesInConvertedLoop(node);
}
return result;
}
function visitNodesInConvertedLoop(node) {
switch (node.kind) {
case 216 /* ReturnStatement */:
node = isReturnVoidStatementInConstructorWithCapturedSuper(node) ? returnCapturedThis(node) : node;
return visitReturnStatement(node);
case 205 /* VariableStatement */:
return visitVariableStatement(node);
case 218 /* SwitchStatement */:
return visitSwitchStatement(node);
case 215 /* BreakStatement */:
case 214 /* ContinueStatement */:
return visitBreakOrContinueStatement(node);
case 98 /* ThisKeyword */:
return visitThisKeyword(node);
case 70 /* Identifier */:
return visitIdentifier(node);
default:
return ts.visitEachChild(node, visitor, context);
}
}
function visitJavaScript(node) {
switch (node.kind) {
case 114 /* StaticKeyword */:
return undefined; // elide static keyword
case 226 /* ClassDeclaration */:
return visitClassDeclaration(node);
case 197 /* ClassExpression */:
return visitClassExpression(node);
case 144 /* Parameter */:
return visitParameter(node);
case 225 /* FunctionDeclaration */:
return visitFunctionDeclaration(node);
case 185 /* ArrowFunction */:
return visitArrowFunction(node);
case 184 /* FunctionExpression */:
return visitFunctionExpression(node);
case 223 /* VariableDeclaration */:
return visitVariableDeclaration(node);
case 70 /* Identifier */:
return visitIdentifier(node);
case 224 /* VariableDeclarationList */:
return visitVariableDeclarationList(node);
case 219 /* LabeledStatement */:
return visitLabeledStatement(node);
case 209 /* DoStatement */:
return visitDoStatement(node);
case 210 /* WhileStatement */:
return visitWhileStatement(node);
case 211 /* ForStatement */:
return visitForStatement(node);
case 212 /* ForInStatement */:
return visitForInStatement(node);
case 213 /* ForOfStatement */:
return visitForOfStatement(node);
case 207 /* ExpressionStatement */:
return visitExpressionStatement(node);
case 176 /* ObjectLiteralExpression */:
return visitObjectLiteralExpression(node);
case 256 /* CatchClause */:
return visitCatchClause(node);
case 258 /* ShorthandPropertyAssignment */:
return visitShorthandPropertyAssignment(node);
case 175 /* ArrayLiteralExpression */:
return visitArrayLiteralExpression(node);
case 179 /* CallExpression */:
return visitCallExpression(node);
case 180 /* NewExpression */:
return visitNewExpression(node);
case 183 /* ParenthesizedExpression */:
return visitParenthesizedExpression(node, /*needsDestructuringValue*/ true);
case 192 /* BinaryExpression */:
return visitBinaryExpression(node, /*needsDestructuringValue*/ true);
case 12 /* NoSubstitutionTemplateLiteral */:
case 13 /* TemplateHead */:
case 14 /* TemplateMiddle */:
case 15 /* TemplateTail */:
return visitTemplateLiteral(node);
case 181 /* TaggedTemplateExpression */:
return visitTaggedTemplateExpression(node);
case 194 /* TemplateExpression */:
return visitTemplateExpression(node);
case 195 /* YieldExpression */:
return visitYieldExpression(node);
case 96 /* SuperKeyword */:
return visitSuperKeyword();
case 195 /* YieldExpression */:
// `yield` will be handled by a generators transform.
return ts.visitEachChild(node, visitor, context);
case 149 /* MethodDeclaration */:
return visitMethodDeclaration(node);
case 261 /* SourceFile */:
return visitSourceFileNode(node);
case 205 /* VariableStatement */:
return visitVariableStatement(node);
default:
ts.Debug.failBadSyntaxKind(node);
return ts.visitEachChild(node, visitor, context);
}
}
function onBeforeVisitNode(node) {
if (currentNode) {
if (ts.isBlockScope(currentNode, currentParent)) {
enclosingBlockScopeContainer = currentNode;
enclosingBlockScopeContainerParent = currentParent;
}
if (ts.isFunctionLike(currentNode)) {
enclosingFunction = currentNode;
if (currentNode.kind !== 185 /* ArrowFunction */) {
enclosingNonArrowFunction = currentNode;
if (!(ts.getEmitFlags(currentNode) & 2097152 /* AsyncFunctionBody */)) {
enclosingNonAsyncFunctionBody = currentNode;
}
}
}
// keep track of the enclosing variable statement when in the context of
// variable statements, variable declarations, binding elements, and binding
// patterns.
switch (currentNode.kind) {
case 205 /* VariableStatement */:
enclosingVariableStatement = currentNode;
break;
case 224 /* VariableDeclarationList */:
case 223 /* VariableDeclaration */:
case 174 /* BindingElement */:
case 172 /* ObjectBindingPattern */:
case 173 /* ArrayBindingPattern */:
break;
default:
enclosingVariableStatement = undefined;
}
}
currentParent = currentNode;
currentNode = node;
}
function visitSwitchStatement(node) {
ts.Debug.assert(convertedLoopState !== undefined);
var savedAllowedNonLabeledJumps = convertedLoopState.allowedNonLabeledJumps;
// for switch statement allow only non-labeled break
convertedLoopState.allowedNonLabeledJumps |= 2 /* Break */;
var result = ts.visitEachChild(node, visitor, context);
convertedLoopState.allowedNonLabeledJumps = savedAllowedNonLabeledJumps;
return result;
}
function visitReturnStatement(node) {
ts.Debug.assert(convertedLoopState !== undefined);
convertedLoopState.nonLocalJumps |= 8 /* Return */;
return ts.createReturn(ts.createObjectLiteral([
ts.createPropertyAssignment(ts.createIdentifier("value"), node.expression
? ts.visitNode(node.expression, visitor, ts.isExpression)
: ts.createVoidZero())
]));
}
function visitThisKeyword(node) {
ts.Debug.assert(convertedLoopState !== undefined);
if (enclosingFunction && enclosingFunction.kind === 185 /* ArrowFunction */) {
// if the enclosing function is an ArrowFunction is then we use the captured 'this' keyword.
convertedLoopState.containsLexicalThis = true;
return node;
}
return convertedLoopState.thisName || (convertedLoopState.thisName = ts.createUniqueName("this"));
}
function visitIdentifier(node) {
if (!convertedLoopState) {
return node;
}
if (ts.isGeneratedIdentifier(node)) {
return node;
}
if (node.text !== "arguments" && !resolver.isArgumentsLocalBinding(node)) {
return node;
}
return convertedLoopState.argumentsName || (convertedLoopState.argumentsName = ts.createUniqueName("arguments"));
}
function visitBreakOrContinueStatement(node) {
if (convertedLoopState) {
// check if we can emit break/continue as is
// it is possible if either
// - break/continue is labeled and label is located inside the converted loop
// - break/continue is non-labeled and located in non-converted loop/switch statement
var jump = node.kind === 215 /* BreakStatement */ ? 2 /* Break */ : 4 /* Continue */;
var canUseBreakOrContinue = (node.label && convertedLoopState.labels && convertedLoopState.labels[node.label.text]) ||
(!node.label && (convertedLoopState.allowedNonLabeledJumps & jump));
if (!canUseBreakOrContinue) {
var labelMarker = void 0;
if (!node.label) {
if (node.kind === 215 /* BreakStatement */) {
convertedLoopState.nonLocalJumps |= 2 /* Break */;
labelMarker = "break";
}
else {
convertedLoopState.nonLocalJumps |= 4 /* Continue */;
// note: return value is emitted only to simplify debugging, call to converted loop body does not do any dispatching on it.
labelMarker = "continue";
}
}
else {
if (node.kind === 215 /* BreakStatement */) {
labelMarker = "break-" + node.label.text;
setLabeledJump(convertedLoopState, /*isBreak*/ true, node.label.text, labelMarker);
}
else {
labelMarker = "continue-" + node.label.text;
setLabeledJump(convertedLoopState, /*isBreak*/ false, node.label.text, labelMarker);
}
}
var returnExpression = ts.createLiteral(labelMarker);
if (convertedLoopState.loopOutParameters.length) {
var outParams = convertedLoopState.loopOutParameters;
var expr = void 0;
for (var i = 0; i < outParams.length; i++) {
var copyExpr = copyOutParameter(outParams[i], 1 /* ToOutParameter */);
if (i === 0) {
expr = copyExpr;
}
else {
expr = ts.createBinary(expr, 25 /* CommaToken */, copyExpr);
}
}
returnExpression = ts.createBinary(expr, 25 /* CommaToken */, returnExpression);
}
return ts.createReturn(returnExpression);
}
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a ClassDeclaration and transforms it into a variable statement.
*
* @param node A ClassDeclaration node.
*/
function visitClassDeclaration(node) {
// [source]
// class C { }
//
// [output]
// var C = (function () {
// function C() {
// }
// return C;
// }());
var variable = ts.createVariableDeclaration(ts.getLocalName(node, /*allowComments*/ true),
/*type*/ undefined, transformClassLikeDeclarationToExpression(node));
ts.setOriginalNode(variable, node);
var statements = [];
var statement = ts.createVariableStatement(/*modifiers*/ undefined, ts.createVariableDeclarationList([variable]), /*location*/ node);
ts.setOriginalNode(statement, node);
ts.startOnNewLine(statement);
statements.push(statement);
// Add an `export default` statement for default exports (for `--target es5 --module es6`)
if (ts.hasModifier(node, 1 /* Export */)) {
var exportStatement = ts.hasModifier(node, 512 /* Default */)
? ts.createExportDefault(ts.getLocalName(node))
: ts.createExternalModuleExport(ts.getLocalName(node));
ts.setOriginalNode(exportStatement, statement);
statements.push(exportStatement);
}
var emitFlags = ts.getEmitFlags(node);
if ((emitFlags & 33554432 /* HasEndOfDeclarationMarker */) === 0) {
// Add a DeclarationMarker as a marker for the end of the declaration
statements.push(ts.createEndOfDeclarationMarker(node));
ts.setEmitFlags(statement, emitFlags | 33554432 /* HasEndOfDeclarationMarker */);
}
return ts.singleOrMany(statements);
}
/**
* Visits a ClassExpression and transforms it into an expression.
*
* @param node A ClassExpression node.
*/
function visitClassExpression(node) {
// [source]
// C = class { }
//
// [output]
// C = (function () {
// function class_1() {
// }
// return class_1;
// }())
return transformClassLikeDeclarationToExpression(node);
}
/**
* Transforms a ClassExpression or ClassDeclaration into an expression.
*
* @param node A ClassExpression or ClassDeclaration node.
*/
function transformClassLikeDeclarationToExpression(node) {
// [source]
// class C extends D {
// constructor() {}
// method() {}
// get prop() {}
// set prop(v) {}
// }
//
// [output]
// (function (_super) {
// __extends(C, _super);
// function C() {
// }
// C.prototype.method = function () {}
// Object.defineProperty(C.prototype, "prop", {
// get: function() {},
// set: function() {},
// enumerable: true,
// configurable: true
// });
// return C;
// }(D))
if (node.name) {
enableSubstitutionsForBlockScopedBindings();
}
var extendsClauseElement = ts.getClassExtendsHeritageClauseElement(node);
var classFunction = ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, extendsClauseElement ? [ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "_super")] : [],
/*type*/ undefined, transformClassBody(node, extendsClauseElement));
// To preserve the behavior of the old emitter, we explicitly indent
// the body of the function here if it was requested in an earlier
// transformation.
if (ts.getEmitFlags(node) & 524288 /* Indented */) {
ts.setEmitFlags(classFunction, 524288 /* Indented */);
}
// "inner" and "outer" below are added purely to preserve source map locations from
// the old emitter
var inner = ts.createPartiallyEmittedExpression(classFunction);
inner.end = node.end;
ts.setEmitFlags(inner, 49152 /* NoComments */);
var outer = ts.createPartiallyEmittedExpression(inner);
outer.end = ts.skipTrivia(currentText, node.pos);
ts.setEmitFlags(outer, 49152 /* NoComments */);
return ts.createParen(ts.createCall(outer,
/*typeArguments*/ undefined, extendsClauseElement
? [ts.visitNode(extendsClauseElement.expression, visitor, ts.isExpression)]
: []));
}
/**
* Transforms a ClassExpression or ClassDeclaration into a function body.
*
* @param node A ClassExpression or ClassDeclaration node.
* @param extendsClauseElement The expression for the class `extends` clause.
*/
function transformClassBody(node, extendsClauseElement) {
var statements = [];
startLexicalEnvironment();
addExtendsHelperIfNeeded(statements, node, extendsClauseElement);
addConstructor(statements, node, extendsClauseElement);
addClassMembers(statements, node);
// Create a synthetic text range for the return statement.
var closingBraceLocation = ts.createTokenRange(ts.skipTrivia(currentText, node.members.end), 17 /* CloseBraceToken */);
var localName = ts.getLocalName(node);
// The following partially-emitted expression exists purely to align our sourcemap
// emit with the original emitter.
var outer = ts.createPartiallyEmittedExpression(localName);
outer.end = closingBraceLocation.end;
ts.setEmitFlags(outer, 49152 /* NoComments */);
var statement = ts.createReturn(outer);
statement.pos = closingBraceLocation.pos;
ts.setEmitFlags(statement, 49152 /* NoComments */ | 12288 /* NoTokenSourceMaps */);
statements.push(statement);
ts.addRange(statements, endLexicalEnvironment());
var block = ts.createBlock(ts.createNodeArray(statements, /*location*/ node.members), /*location*/ undefined, /*multiLine*/ true);
ts.setEmitFlags(block, 49152 /* NoComments */);
return block;
}
/**
* Adds a call to the `__extends` helper if needed for a class.
*
* @param statements The statements of the class body function.
* @param node The ClassExpression or ClassDeclaration node.
* @param extendsClauseElement The expression for the class `extends` clause.
*/
function addExtendsHelperIfNeeded(statements, node, extendsClauseElement) {
if (extendsClauseElement) {
statements.push(ts.createStatement(ts.createExtendsHelper(currentSourceFile.externalHelpersModuleName, ts.getLocalName(node)),
/*location*/ extendsClauseElement));
}
}
/**
* Adds the constructor of the class to a class body function.
*
* @param statements The statements of the class body function.
* @param node The ClassExpression or ClassDeclaration node.
* @param extendsClauseElement The expression for the class `extends` clause.
*/
function addConstructor(statements, node, extendsClauseElement) {
var constructor = ts.getFirstConstructorWithBody(node);
var hasSynthesizedSuper = hasSynthesizedDefaultSuperCall(constructor, extendsClauseElement !== undefined);
var constructorFunction = ts.createFunctionDeclaration(
/*decorators*/ undefined,
/*modifiers*/ undefined,
/*asteriskToken*/ undefined, ts.getDeclarationName(node),
/*typeParameters*/ undefined, transformConstructorParameters(constructor, hasSynthesizedSuper),
/*type*/ undefined, transformConstructorBody(constructor, node, extendsClauseElement, hasSynthesizedSuper),
/*location*/ constructor || node);
if (extendsClauseElement) {
ts.setEmitFlags(constructorFunction, 256 /* CapturesThis */);
}
statements.push(constructorFunction);
}
/**
* Transforms the parameters of the constructor declaration of a class.
*
* @param constructor The constructor for the class.
* @param hasSynthesizedSuper A value indicating whether the constructor starts with a
* synthesized `super` call.
*/
function transformConstructorParameters(constructor, hasSynthesizedSuper) {
// If the TypeScript transformer needed to synthesize a constructor for property
// initializers, it would have also added a synthetic `...args` parameter and
// `super` call.
// If this is the case, we do not include the synthetic `...args` parameter and
// will instead use the `arguments` object in ES5/3.
if (constructor && !hasSynthesizedSuper) {
return ts.visitNodes(constructor.parameters, visitor, ts.isParameter);
}
return [];
}
/**
* Transforms the body of a constructor declaration of a class.
*
* @param constructor The constructor for the class.
* @param node The node which contains the constructor.
* @param extendsClauseElement The expression for the class `extends` clause.
* @param hasSynthesizedSuper A value indicating whether the constructor starts with a
* synthesized `super` call.
*/
function transformConstructorBody(constructor, node, extendsClauseElement, hasSynthesizedSuper) {
var statements = [];
startLexicalEnvironment();
var statementOffset = -1;
if (hasSynthesizedSuper) {
// If a super call has already been synthesized,
// we're going to assume that we should just transform everything after that.
// The assumption is that no prior step in the pipeline has added any prologue directives.
statementOffset = 1;
}
else if (constructor) {
// Otherwise, try to emit all potential prologue directives first.
statementOffset = ts.addPrologueDirectives(statements, constructor.body.statements, /*ensureUseStrict*/ false, visitor);
}
if (constructor) {
ts.addDefaultValueAssignmentsIfNeeded(statements, constructor, visitor, /*convertObjectRest*/ false);
ts.addRestParameterIfNeeded(statements, constructor, hasSynthesizedSuper);
ts.Debug.assert(statementOffset >= 0, "statementOffset not initialized correctly!");
}
var superCaptureStatus = declareOrCaptureOrReturnThisForConstructorIfNeeded(statements, constructor, !!extendsClauseElement, hasSynthesizedSuper, statementOffset);
// The last statement expression was replaced. Skip it.
if (superCaptureStatus === 1 /* ReplaceSuperCapture */ || superCaptureStatus === 2 /* ReplaceWithReturn */) {
statementOffset++;
}
if (constructor) {
var body = saveStateAndInvoke(constructor, function (constructor) {
isInConstructorWithCapturedSuper = superCaptureStatus === 1 /* ReplaceSuperCapture */;
return ts.visitNodes(constructor.body.statements, visitor, ts.isStatement, /*start*/ statementOffset);
});
ts.addRange(statements, body);
}
// Return `_this` unless we're sure enough that it would be pointless to add a return statement.
// If there's a constructor that we can tell returns in enough places, then we *do not* want to add a return.
if (extendsClauseElement
&& superCaptureStatus !== 2 /* ReplaceWithReturn */
&& !(constructor && isSufficientlyCoveredByReturnStatements(constructor.body))) {
statements.push(ts.createReturn(ts.createIdentifier("_this")));
}
ts.addRange(statements, endLexicalEnvironment());
var block = ts.createBlock(ts.createNodeArray(statements,
/*location*/ constructor ? constructor.body.statements : node.members),
/*location*/ constructor ? constructor.body : node,
/*multiLine*/ true);
if (!constructor) {
ts.setEmitFlags(block, 49152 /* NoComments */);
}
return block;
}
/**
* We want to try to avoid emitting a return statement in certain cases if a user already returned something.
* It would generate obviously dead code, so we'll try to make things a little bit prettier
* by doing a minimal check on whether some common patterns always explicitly return.
*/
function isSufficientlyCoveredByReturnStatements(statement) {
// A return statement is considered covered.
if (statement.kind === 216 /* ReturnStatement */) {
return true;
}
else if (statement.kind === 208 /* IfStatement */) {
var ifStatement = statement;
if (ifStatement.elseStatement) {
return isSufficientlyCoveredByReturnStatements(ifStatement.thenStatement) &&
isSufficientlyCoveredByReturnStatements(ifStatement.elseStatement);
}
}
else if (statement.kind === 204 /* Block */) {
var lastStatement = ts.lastOrUndefined(statement.statements);
if (lastStatement && isSufficientlyCoveredByReturnStatements(lastStatement)) {
return true;
}
}
return false;
}
/**
* Declares a `_this` variable for derived classes and for when arrow functions capture `this`.
*
* @returns The new statement offset into the `statements` array.
*/
function declareOrCaptureOrReturnThisForConstructorIfNeeded(statements, ctor, hasExtendsClause, hasSynthesizedSuper, statementOffset) {
// If this isn't a derived class, just capture 'this' for arrow functions if necessary.
if (!hasExtendsClause) {
if (ctor) {
ts.addCaptureThisForNodeIfNeeded(statements, ctor, enableSubstitutionsForCapturedThis);
}
return 0 /* NoReplacement */;
}
// We must be here because the user didn't write a constructor
// but we needed to call 'super(...args)' anyway as per 14.5.14 of the ES2016 spec.
// If that's the case we can just immediately return the result of a 'super()' call.
if (!ctor) {
statements.push(ts.createReturn(createDefaultSuperCallOrThis()));
return 2 /* ReplaceWithReturn */;
}
// The constructor exists, but it and the 'super()' call it contains were generated
// for something like property initializers.
// Create a captured '_this' variable and assume it will subsequently be used.
if (hasSynthesizedSuper) {
ts.captureThisForNode(statements, ctor, createDefaultSuperCallOrThis());
enableSubstitutionsForCapturedThis();
return 1 /* ReplaceSuperCapture */;
}
// Most of the time, a 'super' call will be the first real statement in a constructor body.
// In these cases, we'd like to transform these into a *single* statement instead of a declaration
// followed by an assignment statement for '_this'. For instance, if we emitted without an initializer,
// we'd get:
//
// var _this;
// _this = _super.call(...) || this;
//
// instead of
//
// var _this = _super.call(...) || this;
//
// Additionally, if the 'super()' call is the last statement, we should just avoid capturing
// entirely and immediately return the result like so:
//
// return _super.call(...) || this;
//
var firstStatement;
var superCallExpression;
var ctorStatements = ctor.body.statements;
if (statementOffset < ctorStatements.length) {
firstStatement = ctorStatements[statementOffset];
if (firstStatement.kind === 207 /* ExpressionStatement */ && ts.isSuperCall(firstStatement.expression)) {
var superCall = firstStatement.expression;
superCallExpression = ts.setOriginalNode(saveStateAndInvoke(superCall, visitImmediateSuperCallInBody), superCall);
}
}
// Return the result if we have an immediate super() call on the last statement.
if (superCallExpression && statementOffset === ctorStatements.length - 1) {
statements.push(ts.createReturn(superCallExpression));
return 2 /* ReplaceWithReturn */;
}
// Perform the capture.
ts.captureThisForNode(statements, ctor, superCallExpression, enableSubstitutionsForCapturedThis, firstStatement);
// If we're actually replacing the original statement, we need to signal this to the caller.
if (superCallExpression) {
return 1 /* ReplaceSuperCapture */;
}
return 0 /* NoReplacement */;
}
function createDefaultSuperCallOrThis() {
var actualThis = ts.createThis();
ts.setEmitFlags(actualThis, 128 /* NoSubstitution */);
var superCall = ts.createFunctionApply(ts.createIdentifier("_super"), actualThis, ts.createIdentifier("arguments"));
return ts.createLogicalOr(superCall, actualThis);
}
/**
* Visits a parameter declaration.
*
* @param node A ParameterDeclaration node.
*/
function visitParameter(node) {
if (node.dotDotDotToken) {
// rest parameters are elided
return undefined;
}
else if (ts.isBindingPattern(node.name)) {
// Binding patterns are converted into a generated name and are
// evaluated inside the function body.
return ts.setOriginalNode(ts.createParameter(
/*decorators*/ undefined,
/*modifiers*/ undefined,
/*dotDotDotToken*/ undefined, ts.getGeneratedNameForNode(node),
/*questionToken*/ undefined,
/*type*/ undefined,
/*initializer*/ undefined,
/*location*/ node),
/*original*/ node);
}
else if (node.initializer) {
// Initializers are elided
return ts.setOriginalNode(ts.createParameter(
/*decorators*/ undefined,
/*modifiers*/ undefined,
/*dotDotDotToken*/ undefined, node.name,
/*questionToken*/ undefined,
/*type*/ undefined,
/*initializer*/ undefined,
/*location*/ node),
/*original*/ node);
}
else {
return node;
}
}
/**
* Adds statements to the class body function for a class to define the members of the
* class.
*
* @param statements The statements for the class body function.
* @param node The ClassExpression or ClassDeclaration node.
*/
function addClassMembers(statements, node) {
for (var _i = 0, _a = node.members; _i < _a.length; _i++) {
var member = _a[_i];
switch (member.kind) {
case 203 /* SemicolonClassElement */:
statements.push(transformSemicolonClassElementToStatement(member));
break;
case 149 /* MethodDeclaration */:
statements.push(transformClassMethodDeclarationToStatement(getClassMemberPrefix(node, member), member));
break;
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
var accessors = ts.getAllAccessorDeclarations(node.members, member);
if (member === accessors.firstAccessor) {
statements.push(transformAccessorsToStatement(getClassMemberPrefix(node, member), accessors));
}
break;
case 150 /* Constructor */:
// Constructors are handled in visitClassExpression/visitClassDeclaration
break;
default:
ts.Debug.failBadSyntaxKind(node);
break;
}
}
}
/**
* Transforms a SemicolonClassElement into a statement for a class body function.
*
* @param member The SemicolonClassElement node.
*/
function transformSemicolonClassElementToStatement(member) {
return ts.createEmptyStatement(/*location*/ member);
}
/**
* Transforms a MethodDeclaration into a statement for a class body function.
*
* @param receiver The receiver for the member.
* @param member The MethodDeclaration node.
*/
function transformClassMethodDeclarationToStatement(receiver, member) {
var commentRange = ts.getCommentRange(member);
var sourceMapRange = ts.getSourceMapRange(member);
var func = transformFunctionLikeToExpression(member, /*location*/ member, /*name*/ undefined);
ts.setEmitFlags(func, 49152 /* NoComments */);
ts.setSourceMapRange(func, sourceMapRange);
var statement = ts.createStatement(ts.createAssignment(ts.createMemberAccessForPropertyName(receiver, ts.visitNode(member.name, visitor, ts.isPropertyName),
/*location*/ member.name), func),
/*location*/ member);
ts.setOriginalNode(statement, member);
ts.setCommentRange(statement, commentRange);
// The location for the statement is used to emit comments only.
// No source map should be emitted for this statement to align with the
// old emitter.
ts.setEmitFlags(statement, 1536 /* NoSourceMap */);
return statement;
}
/**
* Transforms a set of related of get/set accessors into a statement for a class body function.
*
* @param receiver The receiver for the member.
* @param accessors The set of related get/set accessors.
*/
function transformAccessorsToStatement(receiver, accessors) {
var statement = ts.createStatement(transformAccessorsToExpression(receiver, accessors, /*startsOnNewLine*/ false),
/*location*/ ts.getSourceMapRange(accessors.firstAccessor));
// The location for the statement is used to emit source maps only.
// No comments should be emitted for this statement to align with the
// old emitter.
ts.setEmitFlags(statement, 49152 /* NoComments */);
return statement;
}
/**
* Transforms a set of related get/set accessors into an expression for either a class
* body function or an ObjectLiteralExpression with computed properties.
*
* @param receiver The receiver for the member.
*/
function transformAccessorsToExpression(receiver, _a, startsOnNewLine) {
var firstAccessor = _a.firstAccessor, getAccessor = _a.getAccessor, setAccessor = _a.setAccessor;
// To align with source maps in the old emitter, the receiver and property name
// arguments are both mapped contiguously to the accessor name.
var target = ts.getMutableClone(receiver);
ts.setEmitFlags(target, 49152 /* NoComments */ | 1024 /* NoTrailingSourceMap */);
ts.setSourceMapRange(target, firstAccessor.name);
var propertyName = ts.createExpressionForPropertyName(ts.visitNode(firstAccessor.name, visitor, ts.isPropertyName));
ts.setEmitFlags(propertyName, 49152 /* NoComments */ | 512 /* NoLeadingSourceMap */);
ts.setSourceMapRange(propertyName, firstAccessor.name);
var properties = [];
if (getAccessor) {
var getterFunction = transformFunctionLikeToExpression(getAccessor, /*location*/ undefined, /*name*/ undefined);
ts.setSourceMapRange(getterFunction, ts.getSourceMapRange(getAccessor));
ts.setEmitFlags(getterFunction, 16384 /* NoLeadingComments */);
var getter = ts.createPropertyAssignment("get", getterFunction);
ts.setCommentRange(getter, ts.getCommentRange(getAccessor));
properties.push(getter);
}
if (setAccessor) {
var setterFunction = transformFunctionLikeToExpression(setAccessor, /*location*/ undefined, /*name*/ undefined);
ts.setSourceMapRange(setterFunction, ts.getSourceMapRange(setAccessor));
ts.setEmitFlags(setterFunction, 16384 /* NoLeadingComments */);
var setter = ts.createPropertyAssignment("set", setterFunction);
ts.setCommentRange(setter, ts.getCommentRange(setAccessor));
properties.push(setter);
}
properties.push(ts.createPropertyAssignment("enumerable", ts.createLiteral(true)), ts.createPropertyAssignment("configurable", ts.createLiteral(true)));
var call = ts.createCall(ts.createPropertyAccess(ts.createIdentifier("Object"), "defineProperty"),
/*typeArguments*/ undefined, [
target,
propertyName,
ts.createObjectLiteral(properties, /*location*/ undefined, /*multiLine*/ true)
]);
if (startsOnNewLine) {
call.startsOnNewLine = true;
}
return call;
}
/**
* Visits an ArrowFunction and transforms it into a FunctionExpression.
*
* @param node An ArrowFunction node.
*/
function visitArrowFunction(node) {
if (node.transformFlags & 262144 /* ContainsLexicalThis */) {
enableSubstitutionsForCapturedThis();
}
var func = transformFunctionLikeToExpression(node, /*location*/ node, /*name*/ undefined);
ts.setEmitFlags(func, 256 /* CapturesThis */);
return func;
}
/**
* Visits a FunctionExpression node.
*
* @param node a FunctionExpression node.
*/
function visitFunctionExpression(node) {
return transformFunctionLikeToExpression(node, /*location*/ node, node.name);
}
/**
* Visits a FunctionDeclaration node.
*
* @param node a FunctionDeclaration node.
*/
function visitFunctionDeclaration(node) {
return ts.setOriginalNode(ts.createFunctionDeclaration(
/*decorators*/ undefined, node.modifiers, node.asteriskToken, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, ts.transformFunctionBody(node, visitor, currentSourceFile, context, enableSubstitutionsForCapturedThis),
/*location*/ node),
/*original*/ node);
}
/**
* Transforms a function-like node into a FunctionExpression.
*
* @param node The function-like node to transform.
* @param location The source-map location for the new FunctionExpression.
* @param name The name of the new FunctionExpression.
*/
function transformFunctionLikeToExpression(node, location, name) {
var savedContainingNonArrowFunction = enclosingNonArrowFunction;
if (node.kind !== 185 /* ArrowFunction */) {
enclosingNonArrowFunction = node;
}
var expression = ts.setOriginalNode(ts.createFunctionExpression(
/*modifiers*/ undefined, node.asteriskToken, name,
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, visitor, ts.isParameter),
/*type*/ undefined, saveStateAndInvoke(node, function (node) { return ts.transformFunctionBody(node, visitor, currentSourceFile, context, enableSubstitutionsForCapturedThis); }), location),
/*original*/ node);
enclosingNonArrowFunction = savedContainingNonArrowFunction;
return expression;
}
/**
* Visits an ExpressionStatement that contains a destructuring assignment.
*
* @param node An ExpressionStatement node.
*/
function visitExpressionStatement(node) {
// If we are here it is most likely because our expression is a destructuring assignment.
switch (node.expression.kind) {
case 183 /* ParenthesizedExpression */:
return ts.updateStatement(node, visitParenthesizedExpression(node.expression, /*needsDestructuringValue*/ false));
case 192 /* BinaryExpression */:
return ts.updateStatement(node, visitBinaryExpression(node.expression, /*needsDestructuringValue*/ false));
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a ParenthesizedExpression that may contain a destructuring assignment.
*
* @param node A ParenthesizedExpression node.
* @param needsDestructuringValue A value indicating whether we need to hold onto the rhs
* of a destructuring assignment.
*/
function visitParenthesizedExpression(node, needsDestructuringValue) {
// If we are here it is most likely because our expression is a destructuring assignment.
if (needsDestructuringValue) {
switch (node.expression.kind) {
case 183 /* ParenthesizedExpression */:
return ts.createParen(visitParenthesizedExpression(node.expression, /*needsDestructuringValue*/ true),
/*location*/ node);
case 192 /* BinaryExpression */:
return ts.createParen(visitBinaryExpression(node.expression, /*needsDestructuringValue*/ true),
/*location*/ node);
}
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a BinaryExpression that contains a destructuring assignment.
*
* @param node A BinaryExpression node.
* @param needsDestructuringValue A value indicating whether we need to hold onto the rhs
* of a destructuring assignment.
*/
function visitBinaryExpression(node, needsDestructuringValue) {
// If we are here it is because this is a destructuring assignment.
ts.Debug.assert(ts.isDestructuringAssignment(node));
return ts.flattenDestructuringAssignment(context, node, needsDestructuringValue, hoistVariableDeclaration, visitor);
}
function visitVariableStatement(node) {
if (convertedLoopState && (ts.getCombinedNodeFlags(node.declarationList) & 3 /* BlockScoped */) == 0) {
// we are inside a converted loop - hoist variable declarations
var assignments = void 0;
for (var _i = 0, _a = node.declarationList.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
hoistVariableDeclarationDeclaredInConvertedLoop(convertedLoopState, decl);
if (decl.initializer) {
var assignment = void 0;
if (ts.isBindingPattern(decl.name)) {
assignment = ts.flattenVariableDestructuringToExpression(decl, hoistVariableDeclaration, /*createAssignmentCallback*/ undefined, visitor);
}
else {
assignment = ts.createBinary(decl.name, 57 /* EqualsToken */, ts.visitNode(decl.initializer, visitor, ts.isExpression));
}
(assignments || (assignments = [])).push(assignment);
}
}
if (assignments) {
return ts.createStatement(ts.reduceLeft(assignments, function (acc, v) { return ts.createBinary(v, 25 /* CommaToken */, acc); }), node);
}
else {
// none of declarations has initializer - the entire variable statement can be deleted
return undefined;
}
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a VariableDeclarationList that is block scoped (e.g. `let` or `const`).
*
* @param node A VariableDeclarationList node.
*/
function visitVariableDeclarationList(node) {
if (node.flags & 3 /* BlockScoped */) {
enableSubstitutionsForBlockScopedBindings();
}
var declarations = ts.flatten(ts.map(node.declarations, node.flags & 1 /* Let */
? visitVariableDeclarationInLetDeclarationList
: visitVariableDeclaration));
var declarationList = ts.createVariableDeclarationList(declarations, /*location*/ node);
ts.setOriginalNode(declarationList, node);
ts.setCommentRange(declarationList, node);
if (node.transformFlags & 67108864 /* ContainsBindingPattern */
&& (ts.isBindingPattern(node.declarations[0].name)
|| ts.isBindingPattern(ts.lastOrUndefined(node.declarations).name))) {
// If the first or last declaration is a binding pattern, we need to modify
// the source map range for the declaration list.
var firstDeclaration = ts.firstOrUndefined(declarations);
var lastDeclaration = ts.lastOrUndefined(declarations);
ts.setSourceMapRange(declarationList, ts.createRange(firstDeclaration.pos, lastDeclaration.end));
}
return declarationList;
}
/**
* Gets a value indicating whether we should emit an explicit initializer for a variable
* declaration in a `let` declaration list.
*
* @param node A VariableDeclaration node.
*/
function shouldEmitExplicitInitializerForLetDeclaration(node) {
// Nested let bindings might need to be initialized explicitly to preserve
// ES6 semantic:
//
// { let x = 1; }
// { let x; } // x here should be undefined. not 1
//
// Top level bindings never collide with anything and thus don't require
// explicit initialization. As for nested let bindings there are two cases:
//
// - Nested let bindings that were not renamed definitely should be
// initialized explicitly:
//
// { let x = 1; }
// { let x; if (some-condition) { x = 1}; if (x) { /*1*/ } }
//
// Without explicit initialization code in /*1*/ can be executed even if
// some-condition is evaluated to false.
//
// - Renaming introduces fresh name that should not collide with any
// existing names, however renamed bindings sometimes also should be
// explicitly initialized. One particular case: non-captured binding
// declared inside loop body (but not in loop initializer):
//
// let x;
// for (;;) {
// let x;
// }
//
// In downlevel codegen inner 'x' will be renamed so it won't collide
// with outer 'x' however it will should be reset on every iteration as
// if it was declared anew.
//
// * Why non-captured binding?
// - Because if loop contains block scoped binding captured in some
// function then loop body will be rewritten to have a fresh scope
// on every iteration so everything will just work.
//
// * Why loop initializer is excluded?
// - Since we've introduced a fresh name it already will be undefined.
var flags = resolver.getNodeCheckFlags(node);
var isCapturedInFunction = flags & 131072 /* CapturedBlockScopedBinding */;
var isDeclaredInLoop = flags & 262144 /* BlockScopedBindingInLoop */;
var emittedAsTopLevel = ts.isBlockScopedContainerTopLevel(enclosingBlockScopeContainer)
|| (isCapturedInFunction
&& isDeclaredInLoop
&& ts.isBlock(enclosingBlockScopeContainer)
&& ts.isIterationStatement(enclosingBlockScopeContainerParent, /*lookInLabeledStatements*/ false));
var emitExplicitInitializer = !emittedAsTopLevel
&& enclosingBlockScopeContainer.kind !== 212 /* ForInStatement */
&& enclosingBlockScopeContainer.kind !== 213 /* ForOfStatement */
&& (!resolver.isDeclarationWithCollidingName(node)
|| (isDeclaredInLoop
&& !isCapturedInFunction
&& !ts.isIterationStatement(enclosingBlockScopeContainer, /*lookInLabeledStatements*/ false)));
return emitExplicitInitializer;
}
/**
* Visits a VariableDeclaration in a `let` declaration list.
*
* @param node A VariableDeclaration node.
*/
function visitVariableDeclarationInLetDeclarationList(node) {
// For binding pattern names that lack initializers there is no point to emit
// explicit initializer since downlevel codegen for destructuring will fail
// in the absence of initializer so all binding elements will say uninitialized
var name = node.name;
if (ts.isBindingPattern(name)) {
return visitVariableDeclaration(node);
}
if (!node.initializer && shouldEmitExplicitInitializerForLetDeclaration(node)) {
var clone_5 = ts.getMutableClone(node);
clone_5.initializer = ts.createVoidZero();
return clone_5;
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a VariableDeclaration node with a binding pattern.
*
* @param node A VariableDeclaration node.
*/
function visitVariableDeclaration(node) {
// If we are here it is because the name contains a binding pattern.
if (ts.isBindingPattern(node.name)) {
var recordTempVariablesInLine = !enclosingVariableStatement
|| !ts.hasModifier(enclosingVariableStatement, 1 /* Export */);
return ts.flattenVariableDestructuring(node, /*value*/ undefined, visitor, recordTempVariablesInLine ? undefined : hoistVariableDeclaration);
}
return ts.visitEachChild(node, visitor, context);
}
function visitLabeledStatement(node) {
if (convertedLoopState) {
if (!convertedLoopState.labels) {
convertedLoopState.labels = ts.createMap();
}
convertedLoopState.labels[node.label.text] = node.label.text;
}
var result;
if (ts.isIterationStatement(node.statement, /*lookInLabeledStatements*/ false) && shouldConvertIterationStatementBody(node.statement)) {
result = ts.visitNodes(ts.createNodeArray([node.statement]), visitor, ts.isStatement);
}
else {
result = ts.visitEachChild(node, visitor, context);
}
if (convertedLoopState) {
convertedLoopState.labels[node.label.text] = undefined;
}
return result;
}
function visitDoStatement(node) {
return convertIterationStatementBodyIfNecessary(node);
}
function visitWhileStatement(node) {
return convertIterationStatementBodyIfNecessary(node);
}
function visitForStatement(node) {
return convertIterationStatementBodyIfNecessary(node);
}
function visitForInStatement(node) {
return convertIterationStatementBodyIfNecessary(node);
}
/**
* Visits a ForOfStatement and converts it into a compatible ForStatement.
*
* @param node A ForOfStatement.
*/
function visitForOfStatement(node) {
return convertIterationStatementBodyIfNecessary(node, convertForOfToFor);
}
function convertForOfToFor(node, convertedLoopBodyStatements) {
return ts.convertForOf(node, convertedLoopBodyStatements, visitor, enableSubstitutionsForBlockScopedBindings, context, /*transformRest*/ false);
}
/**
* Visits an ObjectLiteralExpression with computed propety names.
*
* @param node An ObjectLiteralExpression node.
*/
function visitObjectLiteralExpression(node) {
// We are here because a ComputedPropertyName was used somewhere in the expression.
var properties = node.properties;
var numProperties = properties.length;
// Find the first computed property.
// Everything until that point can be emitted as part of the initial object literal.
var numInitialProperties = numProperties;
for (var i = 0; i < numProperties; i++) {
var property = properties[i];
if (property.transformFlags & 134217728 /* ContainsYield */
|| property.name.kind === 142 /* ComputedPropertyName */) {
numInitialProperties = i;
break;
}
}
ts.Debug.assert(numInitialProperties !== numProperties);
// For computed properties, we need to create a unique handle to the object
// literal so we can modify it without risking internal assignments tainting the object.
var temp = ts.createTempVariable(hoistVariableDeclaration);
// Write out the first non-computed properties, then emit the rest through indexing on the temp variable.
var expressions = [];
var assignment = ts.createAssignment(temp, ts.setEmitFlags(ts.createObjectLiteral(ts.visitNodes(properties, visitor, ts.isObjectLiteralElementLike, 0, numInitialProperties),
/*location*/ undefined, node.multiLine), 524288 /* Indented */));
if (node.multiLine) {
assignment.startsOnNewLine = true;
}
expressions.push(assignment);
addObjectLiteralMembers(expressions, node, temp, numInitialProperties);
// We need to clone the temporary identifier so that we can write it on a
// new line
expressions.push(node.multiLine ? ts.startOnNewLine(ts.getMutableClone(temp)) : temp);
return ts.inlineExpressions(expressions);
}
function shouldConvertIterationStatementBody(node) {
return (resolver.getNodeCheckFlags(node) & 65536 /* LoopWithCapturedBlockScopedBinding */) !== 0;
}
/**
* Records constituents of name for the given variable to be hoisted in the outer scope.
*/
function hoistVariableDeclarationDeclaredInConvertedLoop(state, node) {
if (!state.hoistedLocalVariables) {
state.hoistedLocalVariables = [];
}
visit(node.name);
function visit(node) {
if (node.kind === 70 /* Identifier */) {
state.hoistedLocalVariables.push(node);
}
else {
for (var _i = 0, _a = node.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (!ts.isOmittedExpression(element)) {
visit(element.name);
}
}
}
}
}
function convertIterationStatementBodyIfNecessary(node, convert) {
if (!shouldConvertIterationStatementBody(node)) {
var saveAllowedNonLabeledJumps = void 0;
if (convertedLoopState) {
// we get here if we are trying to emit normal loop loop inside converted loop
// set allowedNonLabeledJumps to Break | Continue to mark that break\continue inside the loop should be emitted as is
saveAllowedNonLabeledJumps = convertedLoopState.allowedNonLabeledJumps;
convertedLoopState.allowedNonLabeledJumps = 2 /* Break */ | 4 /* Continue */;
}
var result = convert ? convert(node, /*convertedLoopBodyStatements*/ undefined) : ts.visitEachChild(node, visitor, context);
if (convertedLoopState) {
convertedLoopState.allowedNonLabeledJumps = saveAllowedNonLabeledJumps;
}
return result;
}
var functionName = ts.createUniqueName("_loop");
var loopInitializer;
switch (node.kind) {
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
var initializer = node.initializer;
if (initializer && initializer.kind === 224 /* VariableDeclarationList */) {
loopInitializer = initializer;
}
break;
}
// variables that will be passed to the loop as parameters
var loopParameters = [];
// variables declared in the loop initializer that will be changed inside the loop
var loopOutParameters = [];
if (loopInitializer && (ts.getCombinedNodeFlags(loopInitializer) & 3 /* BlockScoped */)) {
for (var _i = 0, _a = loopInitializer.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
processLoopVariableDeclaration(decl, loopParameters, loopOutParameters);
}
}
var outerConvertedLoopState = convertedLoopState;
convertedLoopState = { loopOutParameters: loopOutParameters };
if (outerConvertedLoopState) {
// convertedOuterLoopState !== undefined means that this converted loop is nested in another converted loop.
// if outer converted loop has already accumulated some state - pass it through
if (outerConvertedLoopState.argumentsName) {
// outer loop has already used 'arguments' so we've already have some name to alias it
// use the same name in all nested loops
convertedLoopState.argumentsName = outerConvertedLoopState.argumentsName;
}
if (outerConvertedLoopState.thisName) {
// outer loop has already used 'this' so we've already have some name to alias it
// use the same name in all nested loops
convertedLoopState.thisName = outerConvertedLoopState.thisName;
}
if (outerConvertedLoopState.hoistedLocalVariables) {
// we've already collected some non-block scoped variable declarations in enclosing loop
// use the same storage in nested loop
convertedLoopState.hoistedLocalVariables = outerConvertedLoopState.hoistedLocalVariables;
}
}
var loopBody = ts.visitNode(node.statement, visitor, ts.isStatement);
var currentState = convertedLoopState;
convertedLoopState = outerConvertedLoopState;
if (loopOutParameters.length) {
var statements_3 = ts.isBlock(loopBody) ? loopBody.statements.slice() : [loopBody];
copyOutParameters(loopOutParameters, 1 /* ToOutParameter */, statements_3);
loopBody = ts.createBlock(statements_3, /*location*/ undefined, /*multiline*/ true);
}
if (!ts.isBlock(loopBody)) {
loopBody = ts.createBlock([loopBody], /*location*/ undefined, /*multiline*/ true);
}
var isAsyncBlockContainingAwait = enclosingNonArrowFunction
&& (ts.getEmitFlags(enclosingNonArrowFunction) & 2097152 /* AsyncFunctionBody */) !== 0
&& (node.statement.transformFlags & 134217728 /* ContainsYield */) !== 0;
var loopBodyFlags = 0;
if (currentState.containsLexicalThis) {
loopBodyFlags |= 256 /* CapturesThis */;
}
if (isAsyncBlockContainingAwait) {
loopBodyFlags |= 2097152 /* AsyncFunctionBody */;
}
var convertedLoopVariable = ts.createVariableStatement(
/*modifiers*/ undefined, ts.setEmitFlags(ts.createVariableDeclarationList([
ts.createVariableDeclaration(functionName,
/*type*/ undefined, ts.setEmitFlags(ts.createFunctionExpression(
/*modifiers*/ undefined, isAsyncBlockContainingAwait ? ts.createToken(38 /* AsteriskToken */) : undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, loopParameters,
/*type*/ undefined, loopBody), loopBodyFlags))
]), 16777216 /* NoHoisting */));
var statements = [convertedLoopVariable];
var extraVariableDeclarations;
// propagate state from the inner loop to the outer loop if necessary
if (currentState.argumentsName) {
// if alias for arguments is set
if (outerConvertedLoopState) {
// pass it to outer converted loop
outerConvertedLoopState.argumentsName = currentState.argumentsName;
}
else {
// this is top level converted loop and we need to create an alias for 'arguments' object
(extraVariableDeclarations || (extraVariableDeclarations = [])).push(ts.createVariableDeclaration(currentState.argumentsName,
/*type*/ undefined, ts.createIdentifier("arguments")));
}
}
if (currentState.thisName) {
// if alias for this is set
if (outerConvertedLoopState) {
// pass it to outer converted loop
outerConvertedLoopState.thisName = currentState.thisName;
}
else {
// this is top level converted loop so we need to create an alias for 'this' here
// NOTE:
// if converted loops were all nested in arrow function then we'll always emit '_this' so convertedLoopState.thisName will not be set.
// If it is set this means that all nested loops are not nested in arrow function and it is safe to capture 'this'.
(extraVariableDeclarations || (extraVariableDeclarations = [])).push(ts.createVariableDeclaration(currentState.thisName,
/*type*/ undefined, ts.createIdentifier("this")));
}
}
if (currentState.hoistedLocalVariables) {
// if hoistedLocalVariables !== undefined this means that we've possibly collected some variable declarations to be hoisted later
if (outerConvertedLoopState) {
// pass them to outer converted loop
outerConvertedLoopState.hoistedLocalVariables = currentState.hoistedLocalVariables;
}
else {
if (!extraVariableDeclarations) {
extraVariableDeclarations = [];
}
// hoist collected variable declarations
for (var _b = 0, _c = currentState.hoistedLocalVariables; _b < _c.length; _b++) {
var identifier = _c[_b];
extraVariableDeclarations.push(ts.createVariableDeclaration(identifier));
}
}
}
// add extra variables to hold out parameters if necessary
if (loopOutParameters.length) {
if (!extraVariableDeclarations) {
extraVariableDeclarations = [];
}
for (var _d = 0, loopOutParameters_1 = loopOutParameters; _d < loopOutParameters_1.length; _d++) {
var outParam = loopOutParameters_1[_d];
extraVariableDeclarations.push(ts.createVariableDeclaration(outParam.outParamName));
}
}
// create variable statement to hold all introduced variable declarations
if (extraVariableDeclarations) {
statements.push(ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList(extraVariableDeclarations)));
}
var convertedLoopBodyStatements = generateCallToConvertedLoop(functionName, loopParameters, currentState, isAsyncBlockContainingAwait);
var loop;
if (convert) {
loop = convert(node, convertedLoopBodyStatements);
}
else {
loop = ts.getMutableClone(node);
// clean statement part
loop.statement = undefined;
// visit childnodes to transform initializer/condition/incrementor parts
loop = ts.visitEachChild(loop, visitor, context);
// set loop statement
loop.statement = ts.createBlock(convertedLoopBodyStatements,
/*location*/ undefined,
/*multiline*/ true);
// reset and re-aggregate the transform flags
loop.transformFlags = 0;
ts.aggregateTransformFlags(loop);
}
statements.push(currentParent.kind === 219 /* LabeledStatement */
? ts.createLabel(currentParent.label, loop)
: loop);
return statements;
}
function copyOutParameter(outParam, copyDirection) {
var source = copyDirection === 0 /* ToOriginal */ ? outParam.outParamName : outParam.originalName;
var target = copyDirection === 0 /* ToOriginal */ ? outParam.originalName : outParam.outParamName;
return ts.createBinary(target, 57 /* EqualsToken */, source);
}
function copyOutParameters(outParams, copyDirection, statements) {
for (var _i = 0, outParams_1 = outParams; _i < outParams_1.length; _i++) {
var outParam = outParams_1[_i];
statements.push(ts.createStatement(copyOutParameter(outParam, copyDirection)));
}
}
function generateCallToConvertedLoop(loopFunctionExpressionName, parameters, state, isAsyncBlockContainingAwait) {
var outerConvertedLoopState = convertedLoopState;
var statements = [];
// loop is considered simple if it does not have any return statements or break\continue that transfer control outside of the loop
// simple loops are emitted as just 'loop()';
// NOTE: if loop uses only 'continue' it still will be emitted as simple loop
var isSimpleLoop = !(state.nonLocalJumps & ~4 /* Continue */) &&
!state.labeledNonLocalBreaks &&
!state.labeledNonLocalContinues;
var call = ts.createCall(loopFunctionExpressionName, /*typeArguments*/ undefined, ts.map(parameters, function (p) { return p.name; }));
var callResult = isAsyncBlockContainingAwait ? ts.createYield(ts.createToken(38 /* AsteriskToken */), call) : call;
if (isSimpleLoop) {
statements.push(ts.createStatement(callResult));
copyOutParameters(state.loopOutParameters, 0 /* ToOriginal */, statements);
}
else {
var loopResultName = ts.createUniqueName("state");
var stateVariable = ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList([ts.createVariableDeclaration(loopResultName, /*type*/ undefined, callResult)]));
statements.push(stateVariable);
copyOutParameters(state.loopOutParameters, 0 /* ToOriginal */, statements);
if (state.nonLocalJumps & 8 /* Return */) {
var returnStatement = void 0;
if (outerConvertedLoopState) {
outerConvertedLoopState.nonLocalJumps |= 8 /* Return */;
returnStatement = ts.createReturn(loopResultName);
}
else {
returnStatement = ts.createReturn(ts.createPropertyAccess(loopResultName, "value"));
}
statements.push(ts.createIf(ts.createBinary(ts.createTypeOf(loopResultName), 33 /* EqualsEqualsEqualsToken */, ts.createLiteral("object")), returnStatement));
}
if (state.nonLocalJumps & 2 /* Break */) {
statements.push(ts.createIf(ts.createBinary(loopResultName, 33 /* EqualsEqualsEqualsToken */, ts.createLiteral("break")), ts.createBreak()));
}
if (state.labeledNonLocalBreaks || state.labeledNonLocalContinues) {
var caseClauses = [];
processLabeledJumps(state.labeledNonLocalBreaks, /*isBreak*/ true, loopResultName, outerConvertedLoopState, caseClauses);
processLabeledJumps(state.labeledNonLocalContinues, /*isBreak*/ false, loopResultName, outerConvertedLoopState, caseClauses);
statements.push(ts.createSwitch(loopResultName, ts.createCaseBlock(caseClauses)));
}
}
return statements;
}
function setLabeledJump(state, isBreak, labelText, labelMarker) {
if (isBreak) {
if (!state.labeledNonLocalBreaks) {
state.labeledNonLocalBreaks = ts.createMap();
}
state.labeledNonLocalBreaks[labelText] = labelMarker;
}
else {
if (!state.labeledNonLocalContinues) {
state.labeledNonLocalContinues = ts.createMap();
}
state.labeledNonLocalContinues[labelText] = labelMarker;
}
}
function processLabeledJumps(table, isBreak, loopResultName, outerLoop, caseClauses) {
if (!table) {
return;
}
for (var labelText in table) {
var labelMarker = table[labelText];
var statements = [];
// if there are no outer converted loop or outer label in question is located inside outer converted loop
// then emit labeled break\continue
// otherwise propagate pair 'label -> marker' to outer converted loop and emit 'return labelMarker' so outer loop can later decide what to do
if (!outerLoop || (outerLoop.labels && outerLoop.labels[labelText])) {
var label = ts.createIdentifier(labelText);
statements.push(isBreak ? ts.createBreak(label) : ts.createContinue(label));
}
else {
setLabeledJump(outerLoop, isBreak, labelText, labelMarker);
statements.push(ts.createReturn(loopResultName));
}
caseClauses.push(ts.createCaseClause(ts.createLiteral(labelMarker), statements));
}
}
function processLoopVariableDeclaration(decl, loopParameters, loopOutParameters) {
var name = decl.name;
if (ts.isBindingPattern(name)) {
for (var _i = 0, _a = name.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (!ts.isOmittedExpression(element)) {
processLoopVariableDeclaration(element, loopParameters, loopOutParameters);
}
}
}
else {
loopParameters.push(ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, name));
if (resolver.getNodeCheckFlags(decl) & 2097152 /* NeedsLoopOutParameter */) {
var outParamName = ts.createUniqueName("out_" + name.text);
loopOutParameters.push({ originalName: name, outParamName: outParamName });
}
}
}
/**
* Adds the members of an object literal to an array of expressions.
*
* @param expressions An array of expressions.
* @param node An ObjectLiteralExpression node.
* @param receiver The receiver for members of the ObjectLiteralExpression.
* @param numInitialNonComputedProperties The number of initial properties without
* computed property names.
*/
function addObjectLiteralMembers(expressions, node, receiver, start) {
var properties = node.properties;
var numProperties = properties.length;
for (var i = start; i < numProperties; i++) {
var property = properties[i];
switch (property.kind) {
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
var accessors = ts.getAllAccessorDeclarations(node.properties, property);
if (property === accessors.firstAccessor) {
expressions.push(transformAccessorsToExpression(receiver, accessors, node.multiLine));
}
break;
case 257 /* PropertyAssignment */:
expressions.push(transformPropertyAssignmentToExpression(property, receiver, node.multiLine));
break;
case 258 /* ShorthandPropertyAssignment */:
expressions.push(transformShorthandPropertyAssignmentToExpression(property, receiver, node.multiLine));
break;
case 149 /* MethodDeclaration */:
expressions.push(transformObjectLiteralMethodDeclarationToExpression(property, receiver, node.multiLine));
break;
default:
ts.Debug.failBadSyntaxKind(node);
break;
}
}
}
/**
* Transforms a PropertyAssignment node into an expression.
*
* @param node The ObjectLiteralExpression that contains the PropertyAssignment.
* @param property The PropertyAssignment node.
* @param receiver The receiver for the assignment.
*/
function transformPropertyAssignmentToExpression(property, receiver, startsOnNewLine) {
var expression = ts.createAssignment(ts.createMemberAccessForPropertyName(receiver, ts.visitNode(property.name, visitor, ts.isPropertyName)), ts.visitNode(property.initializer, visitor, ts.isExpression),
/*location*/ property);
if (startsOnNewLine) {
expression.startsOnNewLine = true;
}
return expression;
}
/**
* Transforms a ShorthandPropertyAssignment node into an expression.
*
* @param node The ObjectLiteralExpression that contains the ShorthandPropertyAssignment.
* @param property The ShorthandPropertyAssignment node.
* @param receiver The receiver for the assignment.
*/
function transformShorthandPropertyAssignmentToExpression(property, receiver, startsOnNewLine) {
var expression = ts.createAssignment(ts.createMemberAccessForPropertyName(receiver, ts.visitNode(property.name, visitor, ts.isPropertyName)), ts.getSynthesizedClone(property.name),
/*location*/ property);
if (startsOnNewLine) {
expression.startsOnNewLine = true;
}
return expression;
}
/**
* Transforms a MethodDeclaration of an ObjectLiteralExpression into an expression.
*
* @param node The ObjectLiteralExpression that contains the MethodDeclaration.
* @param method The MethodDeclaration node.
* @param receiver The receiver for the assignment.
*/
function transformObjectLiteralMethodDeclarationToExpression(method, receiver, startsOnNewLine) {
var expression = ts.createAssignment(ts.createMemberAccessForPropertyName(receiver, ts.visitNode(method.name, visitor, ts.isPropertyName)), transformFunctionLikeToExpression(method, /*location*/ method, /*name*/ undefined),
/*location*/ method);
if (startsOnNewLine) {
expression.startsOnNewLine = true;
}
return expression;
}
function visitCatchClause(node) {
ts.Debug.assert(ts.isBindingPattern(node.variableDeclaration.name));
var temp = ts.createTempVariable(undefined);
var newVariableDeclaration = ts.createVariableDeclaration(temp, undefined, undefined, node.variableDeclaration);
var vars = ts.flattenVariableDestructuring(node.variableDeclaration, temp, visitor);
var list = ts.createVariableDeclarationList(vars, /*location*/ node.variableDeclaration, /*flags*/ node.variableDeclaration.flags);
var destructure = ts.createVariableStatement(undefined, list);
return ts.updateCatchClause(node, newVariableDeclaration, addStatementToStartOfBlock(node.block, destructure));
}
function addStatementToStartOfBlock(block, statement) {
var transformedStatements = ts.visitNodes(block.statements, visitor, ts.isStatement);
return ts.updateBlock(block, [statement].concat(transformedStatements));
}
/**
* Visits a MethodDeclaration of an ObjectLiteralExpression and transforms it into a
* PropertyAssignment.
*
* @param node A MethodDeclaration node.
*/
function visitMethodDeclaration(node) {
// We should only get here for methods on an object literal with regular identifier names.
// Methods on classes are handled in visitClassDeclaration/visitClassExpression.
// Methods with computed property names are handled in visitObjectLiteralExpression.
ts.Debug.assert(!ts.isComputedPropertyName(node.name));
var functionExpression = transformFunctionLikeToExpression(node, /*location*/ ts.moveRangePos(node, -1), /*name*/ undefined);
ts.setEmitFlags(functionExpression, 16384 /* NoLeadingComments */ | ts.getEmitFlags(functionExpression));
return ts.createPropertyAssignment(node.name, functionExpression,
/*location*/ node);
}
/**
* Visits a ShorthandPropertyAssignment and transforms it into a PropertyAssignment.
*
* @param node A ShorthandPropertyAssignment node.
*/
function visitShorthandPropertyAssignment(node) {
return ts.createPropertyAssignment(node.name, ts.getSynthesizedClone(node.name),
/*location*/ node);
}
/**
* Visits a YieldExpression node.
*
* @param node A YieldExpression node.
*/
function visitYieldExpression(node) {
// `yield` expressions are transformed using the generators transformer.
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits an ArrayLiteralExpression that contains a spread element.
*
* @param node An ArrayLiteralExpression node.
*/
function visitArrayLiteralExpression(node) {
// We are here because we contain a SpreadElementExpression.
return transformAndSpreadElements(node.elements, /*needsUniqueCopy*/ true, node.multiLine, /*hasTrailingComma*/ node.elements.hasTrailingComma);
}
/**
* Visits a CallExpression that contains either a spread element or `super`.
*
* @param node a CallExpression.
*/
function visitCallExpression(node) {
return visitCallExpressionWithPotentialCapturedThisAssignment(node, /*assignToCapturedThis*/ true);
}
function visitImmediateSuperCallInBody(node) {
return visitCallExpressionWithPotentialCapturedThisAssignment(node, /*assignToCapturedThis*/ false);
}
function visitCallExpressionWithPotentialCapturedThisAssignment(node, assignToCapturedThis) {
// We are here either because SuperKeyword was used somewhere in the expression, or
// because we contain a SpreadElementExpression.
var _a = ts.createCallBinding(node.expression, hoistVariableDeclaration), target = _a.target, thisArg = _a.thisArg;
if (node.expression.kind === 96 /* SuperKeyword */) {
ts.setEmitFlags(thisArg, 128 /* NoSubstitution */);
}
var resultingCall;
if (node.transformFlags & 8388608 /* ContainsSpreadExpression */) {
// [source]
// f(...a, b)
// x.m(...a, b)
// super(...a, b)
// super.m(...a, b) // in static
// super.m(...a, b) // in instance
//
// [output]
// f.apply(void 0, a.concat([b]))
// (_a = x).m.apply(_a, a.concat([b]))
// _super.apply(this, a.concat([b]))
// _super.m.apply(this, a.concat([b]))
// _super.prototype.m.apply(this, a.concat([b]))
resultingCall = ts.createFunctionApply(ts.visitNode(target, visitor, ts.isExpression), ts.visitNode(thisArg, visitor, ts.isExpression), transformAndSpreadElements(node.arguments, /*needsUniqueCopy*/ false, /*multiLine*/ false, /*hasTrailingComma*/ false));
}
else {
// [source]
// super(a)
// super.m(a) // in static
// super.m(a) // in instance
//
// [output]
// _super.call(this, a)
// _super.m.call(this, a)
// _super.prototype.m.call(this, a)
resultingCall = ts.createFunctionCall(ts.visitNode(target, visitor, ts.isExpression), ts.visitNode(thisArg, visitor, ts.isExpression), ts.visitNodes(node.arguments, visitor, ts.isExpression),
/*location*/ node);
}
if (node.expression.kind === 96 /* SuperKeyword */) {
var actualThis = ts.createThis();
ts.setEmitFlags(actualThis, 128 /* NoSubstitution */);
var initializer = ts.createLogicalOr(resultingCall, actualThis);
return assignToCapturedThis
? ts.createAssignment(ts.createIdentifier("_this"), initializer)
: initializer;
}
return resultingCall;
}
/**
* Visits a NewExpression that contains a spread element.
*
* @param node A NewExpression node.
*/
function visitNewExpression(node) {
// We are here because we contain a SpreadElementExpression.
ts.Debug.assert((node.transformFlags & 8388608 /* ContainsSpreadExpression */) !== 0);
// [source]
// new C(...a)
//
// [output]
// new ((_a = C).bind.apply(_a, [void 0].concat(a)))()
var _a = ts.createCallBinding(ts.createPropertyAccess(node.expression, "bind"), hoistVariableDeclaration), target = _a.target, thisArg = _a.thisArg;
return ts.createNew(ts.createFunctionApply(ts.visitNode(target, visitor, ts.isExpression), thisArg, transformAndSpreadElements(ts.createNodeArray([ts.createVoidZero()].concat(node.arguments)), /*needsUniqueCopy*/ false, /*multiLine*/ false, /*hasTrailingComma*/ false)),
/*typeArguments*/ undefined, []);
}
/**
* Transforms an array of Expression nodes that contains a SpreadExpression.
*
* @param elements The array of Expression nodes.
* @param needsUniqueCopy A value indicating whether to ensure that the result is a fresh array.
* @param multiLine A value indicating whether the result should be emitted on multiple lines.
*/
function transformAndSpreadElements(elements, needsUniqueCopy, multiLine, hasTrailingComma) {
// [source]
// [a, ...b, c]
//
// [output]
// [a].concat(b, [c])
// Map spans of spread expressions into their expressions and spans of other
// expressions into an array literal.
var numElements = elements.length;
var segments = ts.flatten(ts.spanMap(elements, partitionSpread, function (partition, visitPartition, _start, end) {
return visitPartition(partition, multiLine, hasTrailingComma && end === numElements);
}));
if (segments.length === 1) {
var firstElement = elements[0];
return needsUniqueCopy && ts.isSpreadExpression(firstElement) && firstElement.expression.kind !== 175 /* ArrayLiteralExpression */
? ts.createArraySlice(segments[0])
: segments[0];
}
// Rewrite using the pattern <segment0>.concat(<segment1>, <segment2>, ...)
return ts.createArrayConcat(segments.shift(), segments);
}
function partitionSpread(node) {
return ts.isSpreadExpression(node)
? visitSpanOfSpreads
: visitSpanOfNonSpreads;
}
function visitSpanOfSpreads(chunk) {
return ts.map(chunk, visitExpressionOfSpread);
}
function visitSpanOfNonSpreads(chunk, multiLine, hasTrailingComma) {
return ts.createArrayLiteral(ts.visitNodes(ts.createNodeArray(chunk, /*location*/ undefined, hasTrailingComma), visitor, ts.isExpression),
/*location*/ undefined, multiLine);
}
/**
* Transforms the expression of a SpreadExpression node.
*
* @param node A SpreadExpression node.
*/
function visitExpressionOfSpread(node) {
return ts.visitNode(node.expression, visitor, ts.isExpression);
}
/**
* Visits a template literal.
*
* @param node A template literal.
*/
function visitTemplateLiteral(node) {
return ts.createLiteral(node.text, /*location*/ node);
}
/**
* Visits a TaggedTemplateExpression node.
*
* @param node A TaggedTemplateExpression node.
*/
function visitTaggedTemplateExpression(node) {
// Visit the tag expression
var tag = ts.visitNode(node.tag, visitor, ts.isExpression);
// Allocate storage for the template site object
var temp = ts.createTempVariable(hoistVariableDeclaration);
// Build up the template arguments and the raw and cooked strings for the template.
var templateArguments = [temp];
var cookedStrings = [];
var rawStrings = [];
var template = node.template;
if (ts.isNoSubstitutionTemplateLiteral(template)) {
cookedStrings.push(ts.createLiteral(template.text));
rawStrings.push(getRawLiteral(template));
}
else {
cookedStrings.push(ts.createLiteral(template.head.text));
rawStrings.push(getRawLiteral(template.head));
for (var _i = 0, _a = template.templateSpans; _i < _a.length; _i++) {
var templateSpan = _a[_i];
cookedStrings.push(ts.createLiteral(templateSpan.literal.text));
rawStrings.push(getRawLiteral(templateSpan.literal));
templateArguments.push(ts.visitNode(templateSpan.expression, visitor, ts.isExpression));
}
}
// NOTE: The parentheses here is entirely optional as we are now able to auto-
// parenthesize when rebuilding the tree. This should be removed in a
// future version. It is here for now to match our existing emit.
return ts.createParen(ts.inlineExpressions([
ts.createAssignment(temp, ts.createArrayLiteral(cookedStrings)),
ts.createAssignment(ts.createPropertyAccess(temp, "raw"), ts.createArrayLiteral(rawStrings)),
ts.createCall(tag, /*typeArguments*/ undefined, templateArguments)
]));
}
/**
* Creates an ES5 compatible literal from an ES6 template literal.
*
* @param node The ES6 template literal.
*/
function getRawLiteral(node) {
// Find original source text, since we need to emit the raw strings of the tagged template.
// The raw strings contain the (escaped) strings of what the user wrote.
// Examples: `\n` is converted to "\\n", a template string with a newline to "\n".
var text = ts.getSourceTextOfNodeFromSourceFile(currentSourceFile, node);
// text contains the original source, it will also contain quotes ("`"), dolar signs and braces ("${" and "}"),
// thus we need to remove those characters.
// First template piece starts with "`", others with "}"
// Last template piece ends with "`", others with "${"
var isLast = node.kind === 12 /* NoSubstitutionTemplateLiteral */ || node.kind === 15 /* TemplateTail */;
text = text.substring(1, text.length - (isLast ? 1 : 2));
// Newline normalization:
// ES6 Spec 11.8.6.1 - Static Semantics of TV's and TRV's
// <CR><LF> and <CR> LineTerminatorSequences are normalized to <LF> for both TV and TRV.
text = text.replace(/\r\n?/g, "\n");
return ts.createLiteral(text, /*location*/ node);
}
/**
* Visits a TemplateExpression node.
*
* @param node A TemplateExpression node.
*/
function visitTemplateExpression(node) {
var expressions = [];
addTemplateHead(expressions, node);
addTemplateSpans(expressions, node);
// createAdd will check if each expression binds less closely than binary '+'.
// If it does, it wraps the expression in parentheses. Otherwise, something like
// `abc${ 1 << 2 }`
// becomes
// "abc" + 1 << 2 + ""
// which is really
// ("abc" + 1) << (2 + "")
// rather than
// "abc" + (1 << 2) + ""
var expression = ts.reduceLeft(expressions, ts.createAdd);
if (ts.nodeIsSynthesized(expression)) {
ts.setTextRange(expression, node);
}
return expression;
}
/**
* Gets a value indicating whether we need to include the head of a TemplateExpression.
*
* @param node A TemplateExpression node.
*/
function shouldAddTemplateHead(node) {
// If this expression has an empty head literal and the first template span has a non-empty
// literal, then emitting the empty head literal is not necessary.
// `${ foo } and ${ bar }`
// can be emitted as
// foo + " and " + bar
// This is because it is only required that one of the first two operands in the emit
// output must be a string literal, so that the other operand and all following operands
// are forced into strings.
//
// If the first template span has an empty literal, then the head must still be emitted.
// `${ foo }${ bar }`
// must still be emitted as
// "" + foo + bar
// There is always atleast one templateSpan in this code path, since
// NoSubstitutionTemplateLiterals are directly emitted via emitLiteral()
ts.Debug.assert(node.templateSpans.length !== 0);
return node.head.text.length !== 0 || node.templateSpans[0].literal.text.length === 0;
}
/**
* Adds the head of a TemplateExpression to an array of expressions.
*
* @param expressions An array of expressions.
* @param node A TemplateExpression node.
*/
function addTemplateHead(expressions, node) {
if (!shouldAddTemplateHead(node)) {
return;
}
expressions.push(ts.createLiteral(node.head.text));
}
/**
* Visits and adds the template spans of a TemplateExpression to an array of expressions.
*
* @param expressions An array of expressions.
* @param node A TemplateExpression node.
*/
function addTemplateSpans(expressions, node) {
for (var _i = 0, _a = node.templateSpans; _i < _a.length; _i++) {
var span_6 = _a[_i];
expressions.push(ts.visitNode(span_6.expression, visitor, ts.isExpression));
// Only emit if the literal is non-empty.
// The binary '+' operator is left-associative, so the first string concatenation
// with the head will force the result up to this point to be a string.
// Emitting a '+ ""' has no semantic effect for middles and tails.
if (span_6.literal.text.length !== 0) {
expressions.push(ts.createLiteral(span_6.literal.text));
}
}
}
/**
* Visits the `super` keyword
*/
function visitSuperKeyword() {
return enclosingNonAsyncFunctionBody
&& ts.isClassElement(enclosingNonAsyncFunctionBody)
&& !ts.hasModifier(enclosingNonAsyncFunctionBody, 32 /* Static */)
&& currentParent.kind !== 179 /* CallExpression */
? ts.createPropertyAccess(ts.createIdentifier("_super"), "prototype")
: ts.createIdentifier("_super");
}
function visitSourceFileNode(node) {
var _a = ts.span(node.statements, ts.isPrologueDirective), prologue = _a[0], remaining = _a[1];
var statements = [];
startLexicalEnvironment();
ts.addRange(statements, prologue);
ts.addCaptureThisForNodeIfNeeded(statements, node, enableSubstitutionsForCapturedThis);
ts.addRange(statements, ts.visitNodes(ts.createNodeArray(remaining), visitor, ts.isStatement));
ts.addRange(statements, endLexicalEnvironment());
var clone = ts.getMutableClone(node);
clone.statements = ts.createNodeArray(statements, /*location*/ node.statements);
return clone;
}
/**
* Called by the printer just before a node is printed.
*
* @param node The node to be printed.
*/
function onEmitNode(emitContext, node, emitCallback) {
var savedEnclosingFunction = enclosingFunction;
if (enabledSubstitutions & 1 /* CapturedThis */ && ts.isFunctionLike(node)) {
// If we are tracking a captured `this`, keep track of the enclosing function.
enclosingFunction = node;
}
previousOnEmitNode(emitContext, node, emitCallback);
enclosingFunction = savedEnclosingFunction;
}
/**
* Enables a more costly code path for substitutions when we determine a source file
* contains block-scoped bindings (e.g. `let` or `const`).
*/
function enableSubstitutionsForBlockScopedBindings() {
if ((enabledSubstitutions & 2 /* BlockScopedBindings */) === 0) {
enabledSubstitutions |= 2 /* BlockScopedBindings */;
context.enableSubstitution(70 /* Identifier */);
}
}
/**
* Enables a more costly code path for substitutions when we determine a source file
* contains a captured `this`.
*/
function enableSubstitutionsForCapturedThis() {
if ((enabledSubstitutions & 1 /* CapturedThis */) === 0) {
enabledSubstitutions |= 1 /* CapturedThis */;
context.enableSubstitution(98 /* ThisKeyword */);
context.enableEmitNotification(150 /* Constructor */);
context.enableEmitNotification(149 /* MethodDeclaration */);
context.enableEmitNotification(151 /* GetAccessor */);
context.enableEmitNotification(152 /* SetAccessor */);
context.enableEmitNotification(185 /* ArrowFunction */);
context.enableEmitNotification(184 /* FunctionExpression */);
context.enableEmitNotification(225 /* FunctionDeclaration */);
}
}
/**
* Hooks node substitutions.
*
* @param emitContext The context for the emitter.
* @param node The node to substitute.
*/
function onSubstituteNode(emitContext, node) {
node = previousOnSubstituteNode(emitContext, node);
if (emitContext === 1 /* Expression */) {
return substituteExpression(node);
}
if (ts.isIdentifier(node)) {
return substituteIdentifier(node);
}
return node;
}
/**
* Hooks substitutions for non-expression identifiers.
*/
function substituteIdentifier(node) {
// Only substitute the identifier if we have enabled substitutions for block-scoped
// bindings.
if (enabledSubstitutions & 2 /* BlockScopedBindings */) {
var original = ts.getParseTreeNode(node, ts.isIdentifier);
if (original && isNameOfDeclarationWithCollidingName(original)) {
return ts.getGeneratedNameForNode(original);
}
}
return node;
}
/**
* Determines whether a name is the name of a declaration with a colliding name.
* NOTE: This function expects to be called with an original source tree node.
*
* @param node An original source tree node.
*/
function isNameOfDeclarationWithCollidingName(node) {
var parent = node.parent;
switch (parent.kind) {
case 174 /* BindingElement */:
case 226 /* ClassDeclaration */:
case 229 /* EnumDeclaration */:
case 223 /* VariableDeclaration */:
return parent.name === node
&& resolver.isDeclarationWithCollidingName(parent);
}
return false;
}
/**
* Substitutes an expression.
*
* @param node An Expression node.
*/
function substituteExpression(node) {
switch (node.kind) {
case 70 /* Identifier */:
return substituteExpressionIdentifier(node);
case 98 /* ThisKeyword */:
return substituteThisKeyword(node);
}
return node;
}
/**
* Substitutes an expression identifier.
*
* @param node An Identifier node.
*/
function substituteExpressionIdentifier(node) {
if (enabledSubstitutions & 2 /* BlockScopedBindings */) {
var declaration = resolver.getReferencedDeclarationWithCollidingName(node);
if (declaration) {
return ts.getGeneratedNameForNode(declaration.name);
}
}
return node;
}
/**
* Substitutes `this` when contained within an arrow function.
*
* @param node The ThisKeyword node.
*/
function substituteThisKeyword(node) {
if (enabledSubstitutions & 1 /* CapturedThis */
&& enclosingFunction
&& ts.getEmitFlags(enclosingFunction) & 256 /* CapturesThis */) {
return ts.createIdentifier("_this", /*location*/ node);
}
return node;
}
function getClassMemberPrefix(node, member) {
var expression = ts.getLocalName(node);
return ts.hasModifier(member, 32 /* Static */) ? expression : ts.createPropertyAccess(expression, "prototype");
}
function hasSynthesizedDefaultSuperCall(constructor, hasExtendsClause) {
if (!constructor || !hasExtendsClause) {
return false;
}
var parameter = ts.singleOrUndefined(constructor.parameters);
if (!parameter || !ts.nodeIsSynthesized(parameter) || !parameter.dotDotDotToken) {
return false;
}
var statement = ts.firstOrUndefined(constructor.body.statements);
if (!statement || !ts.nodeIsSynthesized(statement) || statement.kind !== 207 /* ExpressionStatement */) {
return false;
}
var statementExpression = statement.expression;
if (!ts.nodeIsSynthesized(statementExpression) || statementExpression.kind !== 179 /* CallExpression */) {
return false;
}
var callTarget = statementExpression.expression;
if (!ts.nodeIsSynthesized(callTarget) || callTarget.kind !== 96 /* SuperKeyword */) {
return false;
}
var callArgument = ts.singleOrUndefined(statementExpression.arguments);
if (!callArgument || !ts.nodeIsSynthesized(callArgument) || callArgument.kind !== 196 /* SpreadElement */) {
return false;
}
var expression = callArgument.expression;
return ts.isIdentifier(expression) && expression === parameter.name;
}
}
ts.transformES2015 = transformES2015;
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
// Transforms generator functions into a compatible ES5 representation with similar runtime
// semantics. This is accomplished by first transforming the body of each generator
// function into an intermediate representation that is the compiled into a JavaScript
// switch statement.
//
// Many functions in this transformer will contain comments indicating the expected
// intermediate representation. For illustrative purposes, the following intermediate
// language is used to define this intermediate representation:
//
// .nop - Performs no operation.
// .local NAME, ... - Define local variable declarations.
// .mark LABEL - Mark the location of a label.
// .br LABEL - Jump to a label. If jumping out of a protected
// region, all .finally blocks are executed.
// .brtrue LABEL, (x) - Jump to a label IIF the expression `x` is truthy.
// If jumping out of a protected region, all .finally
// blocks are executed.
// .brfalse LABEL, (x) - Jump to a label IIF the expression `x` is falsey.
// If jumping out of a protected region, all .finally
// blocks are executed.
// .yield (x) - Yield the value of the optional expression `x`.
// Resume at the next label.
// .yieldstar (x) - Delegate yield to the value of the optional
// expression `x`. Resume at the next label.
// NOTE: `x` must be an Iterator, not an Iterable.
// .loop CONTINUE, BREAK - Marks the beginning of a loop. Any "continue" or
// "break" abrupt completions jump to the CONTINUE or
// BREAK labels, respectively.
// .endloop - Marks the end of a loop.
// .with (x) - Marks the beginning of a WithStatement block, using
// the supplied expression.
// .endwith - Marks the end of a WithStatement.
// .switch - Marks the beginning of a SwitchStatement.
// .endswitch - Marks the end of a SwitchStatement.
// .labeled NAME - Marks the beginning of a LabeledStatement with the
// supplied name.
// .endlabeled - Marks the end of a LabeledStatement.
// .try TRY, CATCH, FINALLY, END - Marks the beginning of a protected region, and the
// labels for each block.
// .catch (x) - Marks the beginning of a catch block.
// .finally - Marks the beginning of a finally block.
// .endfinally - Marks the end of a finally block.
// .endtry - Marks the end of a protected region.
// .throw (x) - Throws the value of the expression `x`.
// .return (x) - Returns the value of the expression `x`.
//
// In addition, the illustrative intermediate representation introduces some special
// variables:
//
// %sent% - Either returns the next value sent to the generator,
// returns the result of a delegated yield, or throws
// the exception sent to the generator.
// %error% - Returns the value of the current exception in a
// catch block.
//
// This intermediate representation is then compiled into JavaScript syntax. The resulting
// compilation output looks something like the following:
//
// function f() {
// var /*locals*/;
// /*functions*/
// return __generator(function (state) {
// switch (state.label) {
// /*cases per label*/
// }
// });
// }
//
// Each of the above instructions corresponds to JavaScript emit similar to the following:
//
// .local NAME | var NAME;
// -------------------------------|----------------------------------------------
// .mark LABEL | case LABEL:
// -------------------------------|----------------------------------------------
// .br LABEL | return [3 /*break*/, LABEL];
// -------------------------------|----------------------------------------------
// .brtrue LABEL, (x) | if (x) return [3 /*break*/, LABEL];
// -------------------------------|----------------------------------------------
// .brfalse LABEL, (x) | if (!(x)) return [3, /*break*/, LABEL];
// -------------------------------|----------------------------------------------
// .yield (x) | return [4 /*yield*/, x];
// .mark RESUME | case RESUME:
// a = %sent%; | a = state.sent();
// -------------------------------|----------------------------------------------
// .yieldstar (x) | return [5 /*yield**/, x];
// .mark RESUME | case RESUME:
// a = %sent%; | a = state.sent();
// -------------------------------|----------------------------------------------
// .with (_a) | with (_a) {
// a(); | a();
// | }
// | state.label = LABEL;
// .mark LABEL | case LABEL:
// | with (_a) {
// b(); | b();
// | }
// .endwith |
// -------------------------------|----------------------------------------------
// | case 0:
// | state.trys = [];
// | ...
// .try TRY, CATCH, FINALLY, END |
// .mark TRY | case TRY:
// | state.trys.push([TRY, CATCH, FINALLY, END]);
// .nop |
// a(); | a();
// .br END | return [3 /*break*/, END];
// .catch (e) |
// .mark CATCH | case CATCH:
// | e = state.sent();
// b(); | b();
// .br END | return [3 /*break*/, END];
// .finally |
// .mark FINALLY | case FINALLY:
// c(); | c();
// .endfinally | return [7 /*endfinally*/];
// .endtry |
// .mark END | case END:
/*@internal*/
var ts;
(function (ts) {
var OpCode;
(function (OpCode) {
OpCode[OpCode["Nop"] = 0] = "Nop";
OpCode[OpCode["Statement"] = 1] = "Statement";
OpCode[OpCode["Assign"] = 2] = "Assign";
OpCode[OpCode["Break"] = 3] = "Break";
OpCode[OpCode["BreakWhenTrue"] = 4] = "BreakWhenTrue";
OpCode[OpCode["BreakWhenFalse"] = 5] = "BreakWhenFalse";
OpCode[OpCode["Yield"] = 6] = "Yield";
OpCode[OpCode["YieldStar"] = 7] = "YieldStar";
OpCode[OpCode["Return"] = 8] = "Return";
OpCode[OpCode["Throw"] = 9] = "Throw";
OpCode[OpCode["Endfinally"] = 10] = "Endfinally"; // Marks the end of a `finally` block
})(OpCode || (OpCode = {}));
// whether a generated code block is opening or closing at the current operation for a FunctionBuilder
var BlockAction;
(function (BlockAction) {
BlockAction[BlockAction["Open"] = 0] = "Open";
BlockAction[BlockAction["Close"] = 1] = "Close";
})(BlockAction || (BlockAction = {}));
// the kind for a generated code block in a FunctionBuilder
var CodeBlockKind;
(function (CodeBlockKind) {
CodeBlockKind[CodeBlockKind["Exception"] = 0] = "Exception";
CodeBlockKind[CodeBlockKind["With"] = 1] = "With";
CodeBlockKind[CodeBlockKind["Switch"] = 2] = "Switch";
CodeBlockKind[CodeBlockKind["Loop"] = 3] = "Loop";
CodeBlockKind[CodeBlockKind["Labeled"] = 4] = "Labeled";
})(CodeBlockKind || (CodeBlockKind = {}));
// the state for a generated code exception block
var ExceptionBlockState;
(function (ExceptionBlockState) {
ExceptionBlockState[ExceptionBlockState["Try"] = 0] = "Try";
ExceptionBlockState[ExceptionBlockState["Catch"] = 1] = "Catch";
ExceptionBlockState[ExceptionBlockState["Finally"] = 2] = "Finally";
ExceptionBlockState[ExceptionBlockState["Done"] = 3] = "Done";
})(ExceptionBlockState || (ExceptionBlockState = {}));
// NOTE: changes to this enum should be reflected in the __generator helper.
var Instruction;
(function (Instruction) {
Instruction[Instruction["Next"] = 0] = "Next";
Instruction[Instruction["Throw"] = 1] = "Throw";
Instruction[Instruction["Return"] = 2] = "Return";
Instruction[Instruction["Break"] = 3] = "Break";
Instruction[Instruction["Yield"] = 4] = "Yield";
Instruction[Instruction["YieldStar"] = 5] = "YieldStar";
Instruction[Instruction["Catch"] = 6] = "Catch";
Instruction[Instruction["Endfinally"] = 7] = "Endfinally";
})(Instruction || (Instruction = {}));
var instructionNames = ts.createMap((_a = {},
_a[2 /* Return */] = "return",
_a[3 /* Break */] = "break",
_a[4 /* Yield */] = "yield",
_a[5 /* YieldStar */] = "yield*",
_a[7 /* Endfinally */] = "endfinally",
_a));
function transformGenerators(context) {
var startLexicalEnvironment = context.startLexicalEnvironment, endLexicalEnvironment = context.endLexicalEnvironment, hoistFunctionDeclaration = context.hoistFunctionDeclaration, hoistVariableDeclaration = context.hoistVariableDeclaration;
var compilerOptions = context.getCompilerOptions();
var languageVersion = ts.getEmitScriptTarget(compilerOptions);
var resolver = context.getEmitResolver();
var previousOnSubstituteNode = context.onSubstituteNode;
context.onSubstituteNode = onSubstituteNode;
var currentSourceFile;
var renamedCatchVariables;
var renamedCatchVariableDeclarations;
var inGeneratorFunctionBody;
var inStatementContainingYield;
// The following three arrays store information about generated code blocks.
// All three arrays are correlated by their index. This approach is used over allocating
// objects to store the same information to avoid GC overhead.
//
var blocks; // Information about the code block
var blockOffsets; // The operation offset at which a code block begins or ends
var blockActions; // Whether the code block is opened or closed
var blockStack; // A stack of currently open code blocks
// Labels are used to mark locations in the code that can be the target of a Break (jump)
// operation. These are translated into case clauses in a switch statement.
// The following two arrays are correlated by their index. This approach is used over
// allocating objects to store the same information to avoid GC overhead.
//
var labelOffsets; // The operation offset at which the label is defined.
var labelExpressions; // The NumericLiteral nodes bound to each label.
var nextLabelId = 1; // The next label id to use.
// Operations store information about generated code for the function body. This
// Includes things like statements, assignments, breaks (jumps), and yields.
// The following three arrays are correlated by their index. This approach is used over
// allocating objects to store the same information to avoid GC overhead.
//
var operations; // The operation to perform.
var operationArguments; // The arguments to the operation.
var operationLocations; // The source map location for the operation.
var state; // The name of the state object used by the generator at runtime.
// The following variables store information used by the `build` function:
//
var blockIndex = 0; // The index of the current block.
var labelNumber = 0; // The current label number.
var labelNumbers;
var lastOperationWasAbrupt; // Indicates whether the last operation was abrupt (break/continue).
var lastOperationWasCompletion; // Indicates whether the last operation was a completion (return/throw).
var clauses; // The case clauses generated for labels.
var statements; // The statements for the current label.
var exceptionBlockStack; // A stack of containing exception blocks.
var currentExceptionBlock; // The current exception block.
var withBlockStack; // A stack containing `with` blocks.
return transformSourceFile;
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)) {
return node;
}
if (node.transformFlags & 8192 /* ContainsGenerator */) {
currentSourceFile = node;
node = ts.visitEachChild(node, visitor, context);
currentSourceFile = undefined;
}
return node;
}
/**
* Visits a node.
*
* @param node The node to visit.
*/
function visitor(node) {
var transformFlags = node.transformFlags;
if (inStatementContainingYield) {
return visitJavaScriptInStatementContainingYield(node);
}
else if (inGeneratorFunctionBody) {
return visitJavaScriptInGeneratorFunctionBody(node);
}
else if (transformFlags & 4096 /* Generator */) {
return visitGenerator(node);
}
else if (transformFlags & 8192 /* ContainsGenerator */) {
return ts.visitEachChild(node, visitor, context);
}
else {
return node;
}
}
/**
* Visits a node that is contained within a statement that contains yield.
*
* @param node The node to visit.
*/
function visitJavaScriptInStatementContainingYield(node) {
switch (node.kind) {
case 209 /* DoStatement */:
return visitDoStatement(node);
case 210 /* WhileStatement */:
return visitWhileStatement(node);
case 218 /* SwitchStatement */:
return visitSwitchStatement(node);
case 219 /* LabeledStatement */:
return visitLabeledStatement(node);
default:
return visitJavaScriptInGeneratorFunctionBody(node);
}
}
/**
* Visits a node that is contained within a generator function.
*
* @param node The node to visit.
*/
function visitJavaScriptInGeneratorFunctionBody(node) {
switch (node.kind) {
case 225 /* FunctionDeclaration */:
return visitFunctionDeclaration(node);
case 184 /* FunctionExpression */:
return visitFunctionExpression(node);
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return visitAccessorDeclaration(node);
case 205 /* VariableStatement */:
return visitVariableStatement(node);
case 211 /* ForStatement */:
return visitForStatement(node);
case 212 /* ForInStatement */:
return visitForInStatement(node);
case 215 /* BreakStatement */:
return visitBreakStatement(node);
case 214 /* ContinueStatement */:
return visitContinueStatement(node);
case 216 /* ReturnStatement */:
return visitReturnStatement(node);
default:
if (node.transformFlags & 134217728 /* ContainsYield */) {
return visitJavaScriptContainingYield(node);
}
else if (node.transformFlags & (8192 /* ContainsGenerator */ | 268435456 /* ContainsHoistedDeclarationOrCompletion */)) {
return ts.visitEachChild(node, visitor, context);
}
else {
return node;
}
}
}
/**
* Visits a node that contains a YieldExpression.
*
* @param node The node to visit.
*/
function visitJavaScriptContainingYield(node) {
switch (node.kind) {
case 192 /* BinaryExpression */:
return visitBinaryExpression(node);
case 193 /* ConditionalExpression */:
return visitConditionalExpression(node);
case 195 /* YieldExpression */:
return visitYieldExpression(node);
case 175 /* ArrayLiteralExpression */:
return visitArrayLiteralExpression(node);
case 176 /* ObjectLiteralExpression */:
return visitObjectLiteralExpression(node);
case 178 /* ElementAccessExpression */:
return visitElementAccessExpression(node);
case 179 /* CallExpression */:
return visitCallExpression(node);
case 180 /* NewExpression */:
return visitNewExpression(node);
default:
return ts.visitEachChild(node, visitor, context);
}
}
/**
* Visits a generator function.
*
* @param node The node to visit.
*/
function visitGenerator(node) {
switch (node.kind) {
case 225 /* FunctionDeclaration */:
return visitFunctionDeclaration(node);
case 184 /* FunctionExpression */:
return visitFunctionExpression(node);
default:
ts.Debug.failBadSyntaxKind(node);
return ts.visitEachChild(node, visitor, context);
}
}
/**
* Visits a function declaration.
*
* This will be called when one of the following conditions are met:
* - The function declaration is a generator function.
* - The function declaration is contained within the body of a generator function.
*
* @param node The node to visit.
*/
function visitFunctionDeclaration(node) {
// Currently, we only support generators that were originally async functions.
if (node.asteriskToken && ts.getEmitFlags(node) & 2097152 /* AsyncFunctionBody */) {
node = ts.setOriginalNode(ts.createFunctionDeclaration(
/*decorators*/ undefined,
/*modifiers*/ undefined,
/*asteriskToken*/ undefined, node.name,
/*typeParameters*/ undefined, node.parameters,
/*type*/ undefined, transformGeneratorFunctionBody(node.body),
/*location*/ node), node);
}
else {
var savedInGeneratorFunctionBody = inGeneratorFunctionBody;
var savedInStatementContainingYield = inStatementContainingYield;
inGeneratorFunctionBody = false;
inStatementContainingYield = false;
node = ts.visitEachChild(node, visitor, context);
inGeneratorFunctionBody = savedInGeneratorFunctionBody;
inStatementContainingYield = savedInStatementContainingYield;
}
if (inGeneratorFunctionBody) {
// Function declarations in a generator function body are hoisted
// to the top of the lexical scope and elided from the current statement.
hoistFunctionDeclaration(node);
return undefined;
}
else {
return node;
}
}
/**
* Visits a function expression.
*
* This will be called when one of the following conditions are met:
* - The function expression is a generator function.
* - The function expression is contained within the body of a generator function.
*
* @param node The node to visit.
*/
function visitFunctionExpression(node) {
// Currently, we only support generators that were originally async functions.
if (node.asteriskToken && ts.getEmitFlags(node) & 2097152 /* AsyncFunctionBody */) {
node = ts.setOriginalNode(ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined, node.name,
/*typeParameters*/ undefined, node.parameters,
/*type*/ undefined, transformGeneratorFunctionBody(node.body),
/*location*/ node), node);
}
else {
var savedInGeneratorFunctionBody = inGeneratorFunctionBody;
var savedInStatementContainingYield = inStatementContainingYield;
inGeneratorFunctionBody = false;
inStatementContainingYield = false;
node = ts.visitEachChild(node, visitor, context);
inGeneratorFunctionBody = savedInGeneratorFunctionBody;
inStatementContainingYield = savedInStatementContainingYield;
}
return node;
}
/**
* Visits a get or set accessor declaration.
*
* This will be called when one of the following conditions are met:
* - The accessor is contained within the body of a generator function.
*
* @param node The node to visit.
*/
function visitAccessorDeclaration(node) {
var savedInGeneratorFunctionBody = inGeneratorFunctionBody;
var savedInStatementContainingYield = inStatementContainingYield;
inGeneratorFunctionBody = false;
inStatementContainingYield = false;
node = ts.visitEachChild(node, visitor, context);
inGeneratorFunctionBody = savedInGeneratorFunctionBody;
inStatementContainingYield = savedInStatementContainingYield;
return node;
}
/**
* Transforms the body of a generator function declaration.
*
* @param node The function body to transform.
*/
function transformGeneratorFunctionBody(body) {
// Save existing generator state
var statements = [];
var savedInGeneratorFunctionBody = inGeneratorFunctionBody;
var savedInStatementContainingYield = inStatementContainingYield;
var savedBlocks = blocks;
var savedBlockOffsets = blockOffsets;
var savedBlockActions = blockActions;
var savedBlockStack = blockStack;
var savedLabelOffsets = labelOffsets;
var savedLabelExpressions = labelExpressions;
var savedNextLabelId = nextLabelId;
var savedOperations = operations;
var savedOperationArguments = operationArguments;
var savedOperationLocations = operationLocations;
var savedState = state;
// Initialize generator state
inGeneratorFunctionBody = true;
inStatementContainingYield = false;
blocks = undefined;
blockOffsets = undefined;
blockActions = undefined;
blockStack = undefined;
labelOffsets = undefined;
labelExpressions = undefined;
nextLabelId = 1;
operations = undefined;
operationArguments = undefined;
operationLocations = undefined;
state = ts.createTempVariable(/*recordTempVariable*/ undefined);
// Build the generator
startLexicalEnvironment();
var statementOffset = ts.addPrologueDirectives(statements, body.statements, /*ensureUseStrict*/ false, visitor);
transformAndEmitStatements(body.statements, statementOffset);
var buildResult = build();
ts.addRange(statements, endLexicalEnvironment());
statements.push(ts.createReturn(buildResult));
// Restore previous generator state
inGeneratorFunctionBody = savedInGeneratorFunctionBody;
inStatementContainingYield = savedInStatementContainingYield;
blocks = savedBlocks;
blockOffsets = savedBlockOffsets;
blockActions = savedBlockActions;
blockStack = savedBlockStack;
labelOffsets = savedLabelOffsets;
labelExpressions = savedLabelExpressions;
nextLabelId = savedNextLabelId;
operations = savedOperations;
operationArguments = savedOperationArguments;
operationLocations = savedOperationLocations;
state = savedState;
return ts.createBlock(statements, /*location*/ body, body.multiLine);
}
/**
* Visits a variable statement.
*
* This will be called when one of the following conditions are met:
* - The variable statement is contained within the body of a generator function.
*
* @param node The node to visit.
*/
function visitVariableStatement(node) {
if (node.transformFlags & 134217728 /* ContainsYield */) {
transformAndEmitVariableDeclarationList(node.declarationList);
return undefined;
}
else {
// Do not hoist custom prologues.
if (ts.getEmitFlags(node) & 8388608 /* CustomPrologue */) {
return node;
}
for (var _i = 0, _a = node.declarationList.declarations; _i < _a.length; _i++) {
var variable = _a[_i];
hoistVariableDeclaration(variable.name);
}
var variables = ts.getInitializedVariables(node.declarationList);
if (variables.length === 0) {
return undefined;
}
return ts.createStatement(ts.inlineExpressions(ts.map(variables, transformInitializedVariable)));
}
}
/**
* Visits a binary expression.
*
* This will be called when one of the following conditions are met:
* - The node contains a YieldExpression.
*
* @param node The node to visit.
*/
function visitBinaryExpression(node) {
switch (ts.getExpressionAssociativity(node)) {
case 0 /* Left */:
return visitLeftAssociativeBinaryExpression(node);
case 1 /* Right */:
return visitRightAssociativeBinaryExpression(node);
default:
ts.Debug.fail("Unknown associativity.");
}
}
function isCompoundAssignment(kind) {
return kind >= 58 /* FirstCompoundAssignment */
&& kind <= 69 /* LastCompoundAssignment */;
}
function getOperatorForCompoundAssignment(kind) {
switch (kind) {
case 58 /* PlusEqualsToken */: return 36 /* PlusToken */;
case 59 /* MinusEqualsToken */: return 37 /* MinusToken */;
case 60 /* AsteriskEqualsToken */: return 38 /* AsteriskToken */;
case 61 /* AsteriskAsteriskEqualsToken */: return 39 /* AsteriskAsteriskToken */;
case 62 /* SlashEqualsToken */: return 40 /* SlashToken */;
case 63 /* PercentEqualsToken */: return 41 /* PercentToken */;
case 64 /* LessThanLessThanEqualsToken */: return 44 /* LessThanLessThanToken */;
case 65 /* GreaterThanGreaterThanEqualsToken */: return 45 /* GreaterThanGreaterThanToken */;
case 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */: return 46 /* GreaterThanGreaterThanGreaterThanToken */;
case 67 /* AmpersandEqualsToken */: return 47 /* AmpersandToken */;
case 68 /* BarEqualsToken */: return 48 /* BarToken */;
case 69 /* CaretEqualsToken */: return 49 /* CaretToken */;
}
}
/**
* Visits a right-associative binary expression containing `yield`.
*
* @param node The node to visit.
*/
function visitRightAssociativeBinaryExpression(node) {
var left = node.left, right = node.right;
if (containsYield(right)) {
var target = void 0;
switch (left.kind) {
case 177 /* PropertyAccessExpression */:
// [source]
// a.b = yield;
//
// [intermediate]
// .local _a
// _a = a;
// .yield resumeLabel
// .mark resumeLabel
// _a.b = %sent%;
target = ts.updatePropertyAccess(left, cacheExpression(ts.visitNode(left.expression, visitor, ts.isLeftHandSideExpression)), left.name);
break;
case 178 /* ElementAccessExpression */:
// [source]
// a[b] = yield;
//
// [intermediate]
// .local _a, _b
// _a = a;
// _b = b;
// .yield resumeLabel
// .mark resumeLabel
// _a[_b] = %sent%;
target = ts.updateElementAccess(left, cacheExpression(ts.visitNode(left.expression, visitor, ts.isLeftHandSideExpression)), cacheExpression(ts.visitNode(left.argumentExpression, visitor, ts.isExpression)));
break;
default:
target = ts.visitNode(left, visitor, ts.isExpression);
break;
}
var operator = node.operatorToken.kind;
if (isCompoundAssignment(operator)) {
return ts.createBinary(target, 57 /* EqualsToken */, ts.createBinary(cacheExpression(target), getOperatorForCompoundAssignment(operator), ts.visitNode(right, visitor, ts.isExpression), node), node);
}
else {
return ts.updateBinary(node, target, ts.visitNode(right, visitor, ts.isExpression));
}
}
return ts.visitEachChild(node, visitor, context);
}
function visitLeftAssociativeBinaryExpression(node) {
if (containsYield(node.right)) {
if (ts.isLogicalOperator(node.operatorToken.kind)) {
return visitLogicalBinaryExpression(node);
}
else if (node.operatorToken.kind === 25 /* CommaToken */) {
return visitCommaExpression(node);
}
// [source]
// a() + (yield) + c()
//
// [intermediate]
// .local _a
// _a = a();
// .yield resumeLabel
// _a + %sent% + c()
var clone_6 = ts.getMutableClone(node);
clone_6.left = cacheExpression(ts.visitNode(node.left, visitor, ts.isExpression));
clone_6.right = ts.visitNode(node.right, visitor, ts.isExpression);
return clone_6;
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a logical binary expression containing `yield`.
*
* @param node A node to visit.
*/
function visitLogicalBinaryExpression(node) {
// Logical binary expressions (`&&` and `||`) are shortcutting expressions and need
// to be transformed as such:
//
// [source]
// x = a() && yield;
//
// [intermediate]
// .local _a
// _a = a();
// .brfalse resultLabel, (_a)
// .yield resumeLabel
// .mark resumeLabel
// _a = %sent%;
// .mark resultLabel
// x = _a;
//
// [source]
// x = a() || yield;
//
// [intermediate]
// .local _a
// _a = a();
// .brtrue resultLabel, (_a)
// .yield resumeLabel
// .mark resumeLabel
// _a = %sent%;
// .mark resultLabel
// x = _a;
var resultLabel = defineLabel();
var resultLocal = declareLocal();
emitAssignment(resultLocal, ts.visitNode(node.left, visitor, ts.isExpression), /*location*/ node.left);
if (node.operatorToken.kind === 52 /* AmpersandAmpersandToken */) {
// Logical `&&` shortcuts when the left-hand operand is falsey.
emitBreakWhenFalse(resultLabel, resultLocal, /*location*/ node.left);
}
else {
// Logical `||` shortcuts when the left-hand operand is truthy.
emitBreakWhenTrue(resultLabel, resultLocal, /*location*/ node.left);
}
emitAssignment(resultLocal, ts.visitNode(node.right, visitor, ts.isExpression), /*location*/ node.right);
markLabel(resultLabel);
return resultLocal;
}
/**
* Visits a comma expression containing `yield`.
*
* @param node The node to visit.
*/
function visitCommaExpression(node) {
// [source]
// x = a(), yield, b();
//
// [intermediate]
// a();
// .yield resumeLabel
// .mark resumeLabel
// x = %sent%, b();
var pendingExpressions = [];
visit(node.left);
visit(node.right);
return ts.inlineExpressions(pendingExpressions);
function visit(node) {
if (ts.isBinaryExpression(node) && node.operatorToken.kind === 25 /* CommaToken */) {
visit(node.left);
visit(node.right);
}
else {
if (containsYield(node) && pendingExpressions.length > 0) {
emitWorker(1 /* Statement */, [ts.createStatement(ts.inlineExpressions(pendingExpressions))]);
pendingExpressions = [];
}
pendingExpressions.push(ts.visitNode(node, visitor, ts.isExpression));
}
}
}
/**
* Visits a conditional expression containing `yield`.
*
* @param node The node to visit.
*/
function visitConditionalExpression(node) {
// [source]
// x = a() ? yield : b();
//
// [intermediate]
// .local _a
// .brfalse whenFalseLabel, (a())
// .yield resumeLabel
// .mark resumeLabel
// _a = %sent%;
// .br resultLabel
// .mark whenFalseLabel
// _a = b();
// .mark resultLabel
// x = _a;
// We only need to perform a specific transformation if a `yield` expression exists
// in either the `whenTrue` or `whenFalse` branches.
// A `yield` in the condition will be handled by the normal visitor.
if (containsYield(node.whenTrue) || containsYield(node.whenFalse)) {
var whenFalseLabel = defineLabel();
var resultLabel = defineLabel();
var resultLocal = declareLocal();
emitBreakWhenFalse(whenFalseLabel, ts.visitNode(node.condition, visitor, ts.isExpression), /*location*/ node.condition);
emitAssignment(resultLocal, ts.visitNode(node.whenTrue, visitor, ts.isExpression), /*location*/ node.whenTrue);
emitBreak(resultLabel);
markLabel(whenFalseLabel);
emitAssignment(resultLocal, ts.visitNode(node.whenFalse, visitor, ts.isExpression), /*location*/ node.whenFalse);
markLabel(resultLabel);
return resultLocal;
}
return ts.visitEachChild(node, visitor, context);
}
/**
* Visits a `yield` expression.
*
* @param node The node to visit.
*/
function visitYieldExpression(node) {
// [source]
// x = yield a();
//
// [intermediate]
// .yield resumeLabel, (a())
// .mark resumeLabel
// x = %sent%;
// NOTE: we are explicitly not handling YieldStar at this time.
var resumeLabel = defineLabel();
var expression = ts.visitNode(node.expression, visitor, ts.isExpression);
if (node.asteriskToken) {
emitYieldStar(expression, /*location*/ node);
}
else {
emitYield(expression, /*location*/ node);
}
markLabel(resumeLabel);
return createGeneratorResume();
}
/**
* Visits an ArrayLiteralExpression that contains a YieldExpression.
*
* @param node The node to visit.
*/
function visitArrayLiteralExpression(node) {
return visitElements(node.elements, node.multiLine);
}
/**
* Visits an array of expressions containing one or more YieldExpression nodes
* and returns an expression for the resulting value.
*
* @param elements The elements to visit.
* @param multiLine Whether array literals created should be emitted on multiple lines.
*/
function visitElements(elements, _multiLine) {
// [source]
// ar = [1, yield, 2];
//
// [intermediate]
// .local _a
// _a = [1];
// .yield resumeLabel
// .mark resumeLabel
// ar = _a.concat([%sent%, 2]);
var numInitialElements = countInitialNodesWithoutYield(elements);
var temp = declareLocal();
var hasAssignedTemp = false;
if (numInitialElements > 0) {
emitAssignment(temp, ts.createArrayLiteral(ts.visitNodes(elements, visitor, ts.isExpression, 0, numInitialElements)));
hasAssignedTemp = true;
}
var expressions = ts.reduceLeft(elements, reduceElement, [], numInitialElements);
return hasAssignedTemp
? ts.createArrayConcat(temp, [ts.createArrayLiteral(expressions)])
: ts.createArrayLiteral(expressions);
function reduceElement(expressions, element) {
if (containsYield(element) && expressions.length > 0) {
emitAssignment(temp, hasAssignedTemp
? ts.createArrayConcat(temp, [ts.createArrayLiteral(expressions)])
: ts.createArrayLiteral(expressions));
hasAssignedTemp = true;
expressions = [];
}
expressions.push(ts.visitNode(element, visitor, ts.isExpression));
return expressions;
}
}
function visitObjectLiteralExpression(node) {
// [source]
// o = {
// a: 1,
// b: yield,
// c: 2
// };
//
// [intermediate]
// .local _a
// _a = {
// a: 1
// };
// .yield resumeLabel
// .mark resumeLabel
// o = (_a.b = %sent%,
// _a.c = 2,
// _a);
var properties = node.properties;
var multiLine = node.multiLine;
var numInitialProperties = countInitialNodesWithoutYield(properties);
var temp = declareLocal();
emitAssignment(temp, ts.createObjectLiteral(ts.visitNodes(properties, visitor, ts.isObjectLiteralElementLike, 0, numInitialProperties),
/*location*/ undefined, multiLine));
var expressions = ts.reduceLeft(properties, reduceProperty, [], numInitialProperties);
expressions.push(multiLine ? ts.startOnNewLine(ts.getMutableClone(temp)) : temp);
return ts.inlineExpressions(expressions);
function reduceProperty(expressions, property) {
if (containsYield(property) && expressions.length > 0) {
emitStatement(ts.createStatement(ts.inlineExpressions(expressions)));
expressions = [];
}
var expression = ts.createExpressionForObjectLiteralElementLike(node, property, temp);
var visited = ts.visitNode(expression, visitor, ts.isExpression);
if (visited) {
if (multiLine) {
visited.startsOnNewLine = true;
}
expressions.push(visited);
}
return expressions;
}
}
/**
* Visits an ElementAccessExpression that contains a YieldExpression.
*
* @param node The node to visit.
*/
function visitElementAccessExpression(node) {
if (containsYield(node.argumentExpression)) {
// [source]
// a = x[yield];
//
// [intermediate]
// .local _a
// _a = x;
// .yield resumeLabel
// .mark resumeLabel
// a = _a[%sent%]
var clone_7 = ts.getMutableClone(node);
clone_7.expression = cacheExpression(ts.visitNode(node.expression, visitor, ts.isLeftHandSideExpression));
clone_7.argumentExpression = ts.visitNode(node.argumentExpression, visitor, ts.isExpression);
return clone_7;
}
return ts.visitEachChild(node, visitor, context);
}
function visitCallExpression(node) {
if (ts.forEach(node.arguments, containsYield)) {
// [source]
// a.b(1, yield, 2);
//
// [intermediate]
// .local _a, _b, _c
// _b = (_a = a).b;
// _c = [1];
// .yield resumeLabel
// .mark resumeLabel
// _b.apply(_a, _c.concat([%sent%, 2]));
var _a = ts.createCallBinding(node.expression, hoistVariableDeclaration, languageVersion, /*cacheIdentifiers*/ true), target = _a.target, thisArg = _a.thisArg;
return ts.setOriginalNode(ts.createFunctionApply(cacheExpression(ts.visitNode(target, visitor, ts.isLeftHandSideExpression)), thisArg, visitElements(node.arguments),
/*location*/ node), node);
}
return ts.visitEachChild(node, visitor, context);
}
function visitNewExpression(node) {
if (ts.forEach(node.arguments, containsYield)) {
// [source]
// new a.b(1, yield, 2);
//
// [intermediate]
// .local _a, _b, _c
// _b = (_a = a.b).bind;
// _c = [1];
// .yield resumeLabel
// .mark resumeLabel
// new (_b.apply(_a, _c.concat([%sent%, 2])));
var _a = ts.createCallBinding(ts.createPropertyAccess(node.expression, "bind"), hoistVariableDeclaration), target = _a.target, thisArg = _a.thisArg;
return ts.setOriginalNode(ts.createNew(ts.createFunctionApply(cacheExpression(ts.visitNode(target, visitor, ts.isExpression)), thisArg, visitElements(node.arguments)),
/*typeArguments*/ undefined, [],
/*location*/ node), node);
}
return ts.visitEachChild(node, visitor, context);
}
function transformAndEmitStatements(statements, start) {
if (start === void 0) { start = 0; }
var numStatements = statements.length;
for (var i = start; i < numStatements; i++) {
transformAndEmitStatement(statements[i]);
}
}
function transformAndEmitEmbeddedStatement(node) {
if (ts.isBlock(node)) {
transformAndEmitStatements(node.statements);
}
else {
transformAndEmitStatement(node);
}
}
function transformAndEmitStatement(node) {
var savedInStatementContainingYield = inStatementContainingYield;
if (!inStatementContainingYield) {
inStatementContainingYield = containsYield(node);
}
transformAndEmitStatementWorker(node);
inStatementContainingYield = savedInStatementContainingYield;
}
function transformAndEmitStatementWorker(node) {
switch (node.kind) {
case 204 /* Block */:
return transformAndEmitBlock(node);
case 207 /* ExpressionStatement */:
return transformAndEmitExpressionStatement(node);
case 208 /* IfStatement */:
return transformAndEmitIfStatement(node);
case 209 /* DoStatement */:
return transformAndEmitDoStatement(node);
case 210 /* WhileStatement */:
return transformAndEmitWhileStatement(node);
case 211 /* ForStatement */:
return transformAndEmitForStatement(node);
case 212 /* ForInStatement */:
return transformAndEmitForInStatement(node);
case 214 /* ContinueStatement */:
return transformAndEmitContinueStatement(node);
case 215 /* BreakStatement */:
return transformAndEmitBreakStatement(node);
case 216 /* ReturnStatement */:
return transformAndEmitReturnStatement(node);
case 217 /* WithStatement */:
return transformAndEmitWithStatement(node);
case 218 /* SwitchStatement */:
return transformAndEmitSwitchStatement(node);
case 219 /* LabeledStatement */:
return transformAndEmitLabeledStatement(node);
case 220 /* ThrowStatement */:
return transformAndEmitThrowStatement(node);
case 221 /* TryStatement */:
return transformAndEmitTryStatement(node);
default:
return emitStatement(ts.visitNode(node, visitor, ts.isStatement, /*optional*/ true));
}
}
function transformAndEmitBlock(node) {
if (containsYield(node)) {
transformAndEmitStatements(node.statements);
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function transformAndEmitExpressionStatement(node) {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
function transformAndEmitVariableDeclarationList(node) {
for (var _i = 0, _a = node.declarations; _i < _a.length; _i++) {
var variable = _a[_i];
hoistVariableDeclaration(variable.name);
}
var variables = ts.getInitializedVariables(node);
var numVariables = variables.length;
var variablesWritten = 0;
var pendingExpressions = [];
while (variablesWritten < numVariables) {
for (var i = variablesWritten; i < numVariables; i++) {
var variable = variables[i];
if (containsYield(variable.initializer) && pendingExpressions.length > 0) {
break;
}
pendingExpressions.push(transformInitializedVariable(variable));
}
if (pendingExpressions.length) {
emitStatement(ts.createStatement(ts.inlineExpressions(pendingExpressions)));
variablesWritten += pendingExpressions.length;
pendingExpressions = [];
}
}
return undefined;
}
function transformInitializedVariable(node) {
return ts.createAssignment(ts.getSynthesizedClone(node.name), ts.visitNode(node.initializer, visitor, ts.isExpression));
}
function transformAndEmitIfStatement(node) {
if (containsYield(node)) {
// [source]
// if (x)
// /*thenStatement*/
// else
// /*elseStatement*/
//
// [intermediate]
// .brfalse elseLabel, (x)
// /*thenStatement*/
// .br endLabel
// .mark elseLabel
// /*elseStatement*/
// .mark endLabel
if (containsYield(node.thenStatement) || containsYield(node.elseStatement)) {
var endLabel = defineLabel();
var elseLabel = node.elseStatement ? defineLabel() : undefined;
emitBreakWhenFalse(node.elseStatement ? elseLabel : endLabel, ts.visitNode(node.expression, visitor, ts.isExpression));
transformAndEmitEmbeddedStatement(node.thenStatement);
if (node.elseStatement) {
emitBreak(endLabel);
markLabel(elseLabel);
transformAndEmitEmbeddedStatement(node.elseStatement);
}
markLabel(endLabel);
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function transformAndEmitDoStatement(node) {
if (containsYield(node)) {
// [source]
// do {
// /*body*/
// }
// while (i < 10);
//
// [intermediate]
// .loop conditionLabel, endLabel
// .mark loopLabel
// /*body*/
// .mark conditionLabel
// .brtrue loopLabel, (i < 10)
// .endloop
// .mark endLabel
var conditionLabel = defineLabel();
var loopLabel = defineLabel();
beginLoopBlock(/*continueLabel*/ conditionLabel);
markLabel(loopLabel);
transformAndEmitEmbeddedStatement(node.statement);
markLabel(conditionLabel);
emitBreakWhenTrue(loopLabel, ts.visitNode(node.expression, visitor, ts.isExpression));
endLoopBlock();
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function visitDoStatement(node) {
if (inStatementContainingYield) {
beginScriptLoopBlock();
node = ts.visitEachChild(node, visitor, context);
endLoopBlock();
return node;
}
else {
return ts.visitEachChild(node, visitor, context);
}
}
function transformAndEmitWhileStatement(node) {
if (containsYield(node)) {
// [source]
// while (i < 10) {
// /*body*/
// }
//
// [intermediate]
// .loop loopLabel, endLabel
// .mark loopLabel
// .brfalse endLabel, (i < 10)
// /*body*/
// .br loopLabel
// .endloop
// .mark endLabel
var loopLabel = defineLabel();
var endLabel = beginLoopBlock(loopLabel);
markLabel(loopLabel);
emitBreakWhenFalse(endLabel, ts.visitNode(node.expression, visitor, ts.isExpression));
transformAndEmitEmbeddedStatement(node.statement);
emitBreak(loopLabel);
endLoopBlock();
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function visitWhileStatement(node) {
if (inStatementContainingYield) {
beginScriptLoopBlock();
node = ts.visitEachChild(node, visitor, context);
endLoopBlock();
return node;
}
else {
return ts.visitEachChild(node, visitor, context);
}
}
function transformAndEmitForStatement(node) {
if (containsYield(node)) {
// [source]
// for (var i = 0; i < 10; i++) {
// /*body*/
// }
//
// [intermediate]
// .local i
// i = 0;
// .loop incrementLabel, endLoopLabel
// .mark conditionLabel
// .brfalse endLoopLabel, (i < 10)
// /*body*/
// .mark incrementLabel
// i++;
// .br conditionLabel
// .endloop
// .mark endLoopLabel
var conditionLabel = defineLabel();
var incrementLabel = defineLabel();
var endLabel = beginLoopBlock(incrementLabel);
if (node.initializer) {
var initializer = node.initializer;
if (ts.isVariableDeclarationList(initializer)) {
transformAndEmitVariableDeclarationList(initializer);
}
else {
emitStatement(ts.createStatement(ts.visitNode(initializer, visitor, ts.isExpression),
/*location*/ initializer));
}
}
markLabel(conditionLabel);
if (node.condition) {
emitBreakWhenFalse(endLabel, ts.visitNode(node.condition, visitor, ts.isExpression));
}
transformAndEmitEmbeddedStatement(node.statement);
markLabel(incrementLabel);
if (node.incrementor) {
emitStatement(ts.createStatement(ts.visitNode(node.incrementor, visitor, ts.isExpression),
/*location*/ node.incrementor));
}
emitBreak(conditionLabel);
endLoopBlock();
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function visitForStatement(node) {
if (inStatementContainingYield) {
beginScriptLoopBlock();
}
var initializer = node.initializer;
if (ts.isVariableDeclarationList(initializer)) {
for (var _i = 0, _a = initializer.declarations; _i < _a.length; _i++) {
var variable = _a[_i];
hoistVariableDeclaration(variable.name);
}
var variables = ts.getInitializedVariables(initializer);
node = ts.updateFor(node, variables.length > 0
? ts.inlineExpressions(ts.map(variables, transformInitializedVariable))
: undefined, ts.visitNode(node.condition, visitor, ts.isExpression, /*optional*/ true), ts.visitNode(node.incrementor, visitor, ts.isExpression, /*optional*/ true), ts.visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, ts.liftToBlock));
}
else {
node = ts.visitEachChild(node, visitor, context);
}
if (inStatementContainingYield) {
endLoopBlock();
}
return node;
}
function transformAndEmitForInStatement(node) {
// TODO(rbuckton): Source map locations
if (containsYield(node)) {
// [source]
// for (var p in o) {
// /*body*/
// }
//
// [intermediate]
// .local _a, _b, _i
// _a = [];
// for (_b in o) _a.push(_b);
// _i = 0;
// .loop incrementLabel, endLoopLabel
// .mark conditionLabel
// .brfalse endLoopLabel, (_i < _a.length)
// p = _a[_i];
// /*body*/
// .mark incrementLabel
// _b++;
// .br conditionLabel
// .endloop
// .mark endLoopLabel
var keysArray = declareLocal(); // _a
var key = declareLocal(); // _b
var keysIndex = ts.createLoopVariable(); // _i
var initializer = node.initializer;
hoistVariableDeclaration(keysIndex);
emitAssignment(keysArray, ts.createArrayLiteral());
emitStatement(ts.createForIn(key, ts.visitNode(node.expression, visitor, ts.isExpression), ts.createStatement(ts.createCall(ts.createPropertyAccess(keysArray, "push"),
/*typeArguments*/ undefined, [key]))));
emitAssignment(keysIndex, ts.createLiteral(0));
var conditionLabel = defineLabel();
var incrementLabel = defineLabel();
var endLabel = beginLoopBlock(incrementLabel);
markLabel(conditionLabel);
emitBreakWhenFalse(endLabel, ts.createLessThan(keysIndex, ts.createPropertyAccess(keysArray, "length")));
var variable = void 0;
if (ts.isVariableDeclarationList(initializer)) {
for (var _i = 0, _a = initializer.declarations; _i < _a.length; _i++) {
var variable_1 = _a[_i];
hoistVariableDeclaration(variable_1.name);
}
variable = ts.getSynthesizedClone(initializer.declarations[0].name);
}
else {
variable = ts.visitNode(initializer, visitor, ts.isExpression);
ts.Debug.assert(ts.isLeftHandSideExpression(variable));
}
emitAssignment(variable, ts.createElementAccess(keysArray, keysIndex));
transformAndEmitEmbeddedStatement(node.statement);
markLabel(incrementLabel);
emitStatement(ts.createStatement(ts.createPostfixIncrement(keysIndex)));
emitBreak(conditionLabel);
endLoopBlock();
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function visitForInStatement(node) {
// [source]
// for (var x in a) {
// /*body*/
// }
//
// [intermediate]
// .local x
// .loop
// for (x in a) {
// /*body*/
// }
// .endloop
if (inStatementContainingYield) {
beginScriptLoopBlock();
}
var initializer = node.initializer;
if (ts.isVariableDeclarationList(initializer)) {
for (var _i = 0, _a = initializer.declarations; _i < _a.length; _i++) {
var variable = _a[_i];
hoistVariableDeclaration(variable.name);
}
node = ts.updateForIn(node, initializer.declarations[0].name, ts.visitNode(node.expression, visitor, ts.isExpression), ts.visitNode(node.statement, visitor, ts.isStatement, /*optional*/ false, ts.liftToBlock));
}
else {
node = ts.visitEachChild(node, visitor, context);
}
if (inStatementContainingYield) {
endLoopBlock();
}
return node;
}
function transformAndEmitContinueStatement(node) {
var label = findContinueTarget(node.label ? node.label.text : undefined);
ts.Debug.assert(label > 0, "Expected continue statment to point to a valid Label.");
emitBreak(label, /*location*/ node);
}
function visitContinueStatement(node) {
if (inStatementContainingYield) {
var label = findContinueTarget(node.label && node.label.text);
if (label > 0) {
return createInlineBreak(label, /*location*/ node);
}
}
return ts.visitEachChild(node, visitor, context);
}
function transformAndEmitBreakStatement(node) {
var label = findBreakTarget(node.label ? node.label.text : undefined);
ts.Debug.assert(label > 0, "Expected break statment to point to a valid Label.");
emitBreak(label, /*location*/ node);
}
function visitBreakStatement(node) {
if (inStatementContainingYield) {
var label = findBreakTarget(node.label && node.label.text);
if (label > 0) {
return createInlineBreak(label, /*location*/ node);
}
}
return ts.visitEachChild(node, visitor, context);
}
function transformAndEmitReturnStatement(node) {
emitReturn(ts.visitNode(node.expression, visitor, ts.isExpression, /*optional*/ true),
/*location*/ node);
}
function visitReturnStatement(node) {
return createInlineReturn(ts.visitNode(node.expression, visitor, ts.isExpression, /*optional*/ true),
/*location*/ node);
}
function transformAndEmitWithStatement(node) {
if (containsYield(node)) {
// [source]
// with (x) {
// /*body*/
// }
//
// [intermediate]
// .with (x)
// /*body*/
// .endwith
beginWithBlock(cacheExpression(ts.visitNode(node.expression, visitor, ts.isExpression)));
transformAndEmitEmbeddedStatement(node.statement);
endWithBlock();
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function transformAndEmitSwitchStatement(node) {
if (containsYield(node.caseBlock)) {
// [source]
// switch (x) {
// case a:
// /*caseStatements*/
// case b:
// /*caseStatements*/
// default:
// /*defaultStatements*/
// }
//
// [intermediate]
// .local _a
// .switch endLabel
// _a = x;
// switch (_a) {
// case a:
// .br clauseLabels[0]
// }
// switch (_a) {
// case b:
// .br clauseLabels[1]
// }
// .br clauseLabels[2]
// .mark clauseLabels[0]
// /*caseStatements*/
// .mark clauseLabels[1]
// /*caseStatements*/
// .mark clauseLabels[2]
// /*caseStatements*/
// .endswitch
// .mark endLabel
var caseBlock = node.caseBlock;
var numClauses = caseBlock.clauses.length;
var endLabel = beginSwitchBlock();
var expression = cacheExpression(ts.visitNode(node.expression, visitor, ts.isExpression));
// Create labels for each clause and find the index of the first default clause.
var clauseLabels = [];
var defaultClauseIndex = -1;
for (var i = 0; i < numClauses; i++) {
var clause = caseBlock.clauses[i];
clauseLabels.push(defineLabel());
if (clause.kind === 254 /* DefaultClause */ && defaultClauseIndex === -1) {
defaultClauseIndex = i;
}
}
// Emit switch statements for each run of case clauses either from the first case
// clause or the next case clause with a `yield` in its expression, up to the next
// case clause with a `yield` in its expression.
var clausesWritten = 0;
var pendingClauses = [];
while (clausesWritten < numClauses) {
var defaultClausesSkipped = 0;
for (var i = clausesWritten; i < numClauses; i++) {
var clause = caseBlock.clauses[i];
if (clause.kind === 253 /* CaseClause */) {
var caseClause = clause;
if (containsYield(caseClause.expression) && pendingClauses.length > 0) {
break;
}
pendingClauses.push(ts.createCaseClause(ts.visitNode(caseClause.expression, visitor, ts.isExpression), [
createInlineBreak(clauseLabels[i], /*location*/ caseClause.expression)
]));
}
else {
defaultClausesSkipped++;
}
}
if (pendingClauses.length) {
emitStatement(ts.createSwitch(expression, ts.createCaseBlock(pendingClauses)));
clausesWritten += pendingClauses.length;
pendingClauses = [];
}
if (defaultClausesSkipped > 0) {
clausesWritten += defaultClausesSkipped;
defaultClausesSkipped = 0;
}
}
if (defaultClauseIndex >= 0) {
emitBreak(clauseLabels[defaultClauseIndex]);
}
else {
emitBreak(endLabel);
}
for (var i = 0; i < numClauses; i++) {
markLabel(clauseLabels[i]);
transformAndEmitStatements(caseBlock.clauses[i].statements);
}
endSwitchBlock();
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function visitSwitchStatement(node) {
if (inStatementContainingYield) {
beginScriptSwitchBlock();
}
node = ts.visitEachChild(node, visitor, context);
if (inStatementContainingYield) {
endSwitchBlock();
}
return node;
}
function transformAndEmitLabeledStatement(node) {
if (containsYield(node)) {
// [source]
// x: {
// /*body*/
// }
//
// [intermediate]
// .labeled "x", endLabel
// /*body*/
// .endlabeled
// .mark endLabel
beginLabeledBlock(node.label.text);
transformAndEmitEmbeddedStatement(node.statement);
endLabeledBlock();
}
else {
emitStatement(ts.visitNode(node, visitor, ts.isStatement));
}
}
function visitLabeledStatement(node) {
if (inStatementContainingYield) {
beginScriptLabeledBlock(node.label.text);
}
node = ts.visitEachChild(node, visitor, context);
if (inStatementContainingYield) {
endLabeledBlock();
}
return node;
}
function transformAndEmitThrowStatement(node) {
emitThrow(ts.visitNode(node.expression, visitor, ts.isExpression),
/*location*/ node);
}
function transformAndEmitTryStatement(node) {
if (containsYield(node)) {
// [source]
// try {
// /*tryBlock*/
// }
// catch (e) {
// /*catchBlock*/
// }
// finally {
// /*finallyBlock*/
// }
//
// [intermediate]
// .local _a
// .try tryLabel, catchLabel, finallyLabel, endLabel
// .mark tryLabel
// .nop
// /*tryBlock*/
// .br endLabel
// .catch
// .mark catchLabel
// _a = %error%;
// /*catchBlock*/
// .br endLabel
// .finally
// .mark finallyLabel
// /*finallyBlock*/
// .endfinally
// .endtry
// .mark endLabel
beginExceptionBlock();
transformAndEmitEmbeddedStatement(node.tryBlock);
if (node.catchClause) {
beginCatchBlock(node.catchClause.variableDeclaration);
transformAndEmitEmbeddedStatement(node.catchClause.block);
}
if (node.finallyBlock) {
beginFinallyBlock();
transformAndEmitEmbeddedStatement(node.finallyBlock);
}
endExceptionBlock();
}
else {
emitStatement(ts.visitEachChild(node, visitor, context));
}
}
function containsYield(node) {
return node && (node.transformFlags & 134217728 /* ContainsYield */) !== 0;
}
function countInitialNodesWithoutYield(nodes) {
var numNodes = nodes.length;
for (var i = 0; i < numNodes; i++) {
if (containsYield(nodes[i])) {
return i;
}
}
return -1;
}
function onSubstituteNode(emitContext, node) {
node = previousOnSubstituteNode(emitContext, node);
if (emitContext === 1 /* Expression */) {
return substituteExpression(node);
}
return node;
}
function substituteExpression(node) {
if (ts.isIdentifier(node)) {
return substituteExpressionIdentifier(node);
}
return node;
}
function substituteExpressionIdentifier(node) {
if (renamedCatchVariables && ts.hasProperty(renamedCatchVariables, node.text)) {
var original = ts.getOriginalNode(node);
if (ts.isIdentifier(original) && original.parent) {
var declaration = resolver.getReferencedValueDeclaration(original);
if (declaration) {
var name_35 = ts.getProperty(renamedCatchVariableDeclarations, String(ts.getOriginalNodeId(declaration)));
if (name_35) {
var clone_8 = ts.getMutableClone(name_35);
ts.setSourceMapRange(clone_8, node);
ts.setCommentRange(clone_8, node);
return clone_8;
}
}
}
}
return node;
}
function cacheExpression(node) {
var temp;
if (ts.isGeneratedIdentifier(node)) {
return node;
}
temp = ts.createTempVariable(hoistVariableDeclaration);
emitAssignment(temp, node, /*location*/ node);
return temp;
}
function declareLocal(name) {
var temp = name
? ts.createUniqueName(name)
: ts.createTempVariable(/*recordTempVariable*/ undefined);
hoistVariableDeclaration(temp);
return temp;
}
/**
* Defines a label, uses as the target of a Break operation.
*/
function defineLabel() {
if (!labelOffsets) {
labelOffsets = [];
}
var label = nextLabelId;
nextLabelId++;
labelOffsets[label] = -1;
return label;
}
/**
* Marks the current operation with the specified label.
*/
function markLabel(label) {
ts.Debug.assert(labelOffsets !== undefined, "No labels were defined.");
labelOffsets[label] = operations ? operations.length : 0;
}
/**
* Begins a block operation (With, Break/Continue, Try/Catch/Finally)
*
* @param block Information about the block.
*/
function beginBlock(block) {
if (!blocks) {
blocks = [];
blockActions = [];
blockOffsets = [];
blockStack = [];
}
var index = blockActions.length;
blockActions[index] = 0 /* Open */;
blockOffsets[index] = operations ? operations.length : 0;
blocks[index] = block;
blockStack.push(block);
return index;
}
/**
* Ends the current block operation.
*/
function endBlock() {
var block = peekBlock();
ts.Debug.assert(block !== undefined, "beginBlock was never called.");
var index = blockActions.length;
blockActions[index] = 1 /* Close */;
blockOffsets[index] = operations ? operations.length : 0;
blocks[index] = block;
blockStack.pop();
return block;
}
/**
* Gets the current open block.
*/
function peekBlock() {
return ts.lastOrUndefined(blockStack);
}
/**
* Gets the kind of the current open block.
*/
function peekBlockKind() {
var block = peekBlock();
return block && block.kind;
}
/**
* Begins a code block for a generated `with` statement.
*
* @param expression An identifier representing expression for the `with` block.
*/
function beginWithBlock(expression) {
var startLabel = defineLabel();
var endLabel = defineLabel();
markLabel(startLabel);
beginBlock({
kind: 1 /* With */,
expression: expression,
startLabel: startLabel,
endLabel: endLabel
});
}
/**
* Ends a code block for a generated `with` statement.
*/
function endWithBlock() {
ts.Debug.assert(peekBlockKind() === 1 /* With */);
var block = endBlock();
markLabel(block.endLabel);
}
function isWithBlock(block) {
return block.kind === 1 /* With */;
}
/**
* Begins a code block for a generated `try` statement.
*/
function beginExceptionBlock() {
var startLabel = defineLabel();
var endLabel = defineLabel();
markLabel(startLabel);
beginBlock({
kind: 0 /* Exception */,
state: 0 /* Try */,
startLabel: startLabel,
endLabel: endLabel
});
emitNop();
return endLabel;
}
/**
* Enters the `catch` clause of a generated `try` statement.
*
* @param variable The catch variable.
*/
function beginCatchBlock(variable) {
ts.Debug.assert(peekBlockKind() === 0 /* Exception */);
var text = variable.name.text;
var name = declareLocal(text);
if (!renamedCatchVariables) {
renamedCatchVariables = ts.createMap();
renamedCatchVariableDeclarations = ts.createMap();
context.enableSubstitution(70 /* Identifier */);
}
renamedCatchVariables[text] = true;
renamedCatchVariableDeclarations[ts.getOriginalNodeId(variable)] = name;
var exception = peekBlock();
ts.Debug.assert(exception.state < 1 /* Catch */);
var endLabel = exception.endLabel;
emitBreak(endLabel);
var catchLabel = defineLabel();
markLabel(catchLabel);
exception.state = 1 /* Catch */;
exception.catchVariable = name;
exception.catchLabel = catchLabel;
emitAssignment(name, ts.createCall(ts.createPropertyAccess(state, "sent"), /*typeArguments*/ undefined, []));
emitNop();
}
/**
* Enters the `finally` block of a generated `try` statement.
*/
function beginFinallyBlock() {
ts.Debug.assert(peekBlockKind() === 0 /* Exception */);
var exception = peekBlock();
ts.Debug.assert(exception.state < 2 /* Finally */);
var endLabel = exception.endLabel;
emitBreak(endLabel);
var finallyLabel = defineLabel();
markLabel(finallyLabel);
exception.state = 2 /* Finally */;
exception.finallyLabel = finallyLabel;
}
/**
* Ends the code block for a generated `try` statement.
*/
function endExceptionBlock() {
ts.Debug.assert(peekBlockKind() === 0 /* Exception */);
var exception = endBlock();
var state = exception.state;
if (state < 2 /* Finally */) {
emitBreak(exception.endLabel);
}
else {
emitEndfinally();
}
markLabel(exception.endLabel);
emitNop();
exception.state = 3 /* Done */;
}
function isExceptionBlock(block) {
return block.kind === 0 /* Exception */;
}
/**
* Begins a code block that supports `break` or `continue` statements that are defined in
* the source tree and not from generated code.
*
* @param labelText Names from containing labeled statements.
*/
function beginScriptLoopBlock() {
beginBlock({
kind: 3 /* Loop */,
isScript: true,
breakLabel: -1,
continueLabel: -1
});
}
/**
* Begins a code block that supports `break` or `continue` statements that are defined in
* generated code. Returns a label used to mark the operation to which to jump when a
* `break` statement targets this block.
*
* @param continueLabel A Label used to mark the operation to which to jump when a
* `continue` statement targets this block.
*/
function beginLoopBlock(continueLabel) {
var breakLabel = defineLabel();
beginBlock({
kind: 3 /* Loop */,
isScript: false,
breakLabel: breakLabel,
continueLabel: continueLabel
});
return breakLabel;
}
/**
* Ends a code block that supports `break` or `continue` statements that are defined in
* generated code or in the source tree.
*/
function endLoopBlock() {
ts.Debug.assert(peekBlockKind() === 3 /* Loop */);
var block = endBlock();
var breakLabel = block.breakLabel;
if (!block.isScript) {
markLabel(breakLabel);
}
}
/**
* Begins a code block that supports `break` statements that are defined in the source
* tree and not from generated code.
*
*/
function beginScriptSwitchBlock() {
beginBlock({
kind: 2 /* Switch */,
isScript: true,
breakLabel: -1
});
}
/**
* Begins a code block that supports `break` statements that are defined in generated code.
* Returns a label used to mark the operation to which to jump when a `break` statement
* targets this block.
*/
function beginSwitchBlock() {
var breakLabel = defineLabel();
beginBlock({
kind: 2 /* Switch */,
isScript: false,
breakLabel: breakLabel
});
return breakLabel;
}
/**
* Ends a code block that supports `break` statements that are defined in generated code.
*/
function endSwitchBlock() {
ts.Debug.assert(peekBlockKind() === 2 /* Switch */);
var block = endBlock();
var breakLabel = block.breakLabel;
if (!block.isScript) {
markLabel(breakLabel);
}
}
function beginScriptLabeledBlock(labelText) {
beginBlock({
kind: 4 /* Labeled */,
isScript: true,
labelText: labelText,
breakLabel: -1
});
}
function beginLabeledBlock(labelText) {
var breakLabel = defineLabel();
beginBlock({
kind: 4 /* Labeled */,
isScript: false,
labelText: labelText,
breakLabel: breakLabel
});
}
function endLabeledBlock() {
ts.Debug.assert(peekBlockKind() === 4 /* Labeled */);
var block = endBlock();
if (!block.isScript) {
markLabel(block.breakLabel);
}
}
/**
* Indicates whether the provided block supports `break` statements.
*
* @param block A code block.
*/
function supportsUnlabeledBreak(block) {
return block.kind === 2 /* Switch */
|| block.kind === 3 /* Loop */;
}
/**
* Indicates whether the provided block supports `break` statements with labels.
*
* @param block A code block.
*/
function supportsLabeledBreakOrContinue(block) {
return block.kind === 4 /* Labeled */;
}
/**
* Indicates whether the provided block supports `continue` statements.
*
* @param block A code block.
*/
function supportsUnlabeledContinue(block) {
return block.kind === 3 /* Loop */;
}
function hasImmediateContainingLabeledBlock(labelText, start) {
for (var j = start; j >= 0; j--) {
var containingBlock = blockStack[j];
if (supportsLabeledBreakOrContinue(containingBlock)) {
if (containingBlock.labelText === labelText) {
return true;
}
}
else {
break;
}
}
return false;
}
/**
* Finds the label that is the target for a `break` statement.
*
* @param labelText An optional name of a containing labeled statement.
*/
function findBreakTarget(labelText) {
ts.Debug.assert(blocks !== undefined);
if (labelText) {
for (var i = blockStack.length - 1; i >= 0; i--) {
var block = blockStack[i];
if (supportsLabeledBreakOrContinue(block) && block.labelText === labelText) {
return block.breakLabel;
}
else if (supportsUnlabeledBreak(block) && hasImmediateContainingLabeledBlock(labelText, i - 1)) {
return block.breakLabel;
}
}
}
else {
for (var i = blockStack.length - 1; i >= 0; i--) {
var block = blockStack[i];
if (supportsUnlabeledBreak(block)) {
return block.breakLabel;
}
}
}
return 0;
}
/**
* Finds the label that is the target for a `continue` statement.
*
* @param labelText An optional name of a containing labeled statement.
*/
function findContinueTarget(labelText) {
ts.Debug.assert(blocks !== undefined);
if (labelText) {
for (var i = blockStack.length - 1; i >= 0; i--) {
var block = blockStack[i];
if (supportsUnlabeledContinue(block) && hasImmediateContainingLabeledBlock(labelText, i - 1)) {
return block.continueLabel;
}
}
}
else {
for (var i = blockStack.length - 1; i >= 0; i--) {
var block = blockStack[i];
if (supportsUnlabeledContinue(block)) {
return block.continueLabel;
}
}
}
return 0;
}
/**
* Creates an expression that can be used to indicate the value for a label.
*
* @param label A label.
*/
function createLabel(label) {
if (label > 0) {
if (labelExpressions === undefined) {
labelExpressions = [];
}
var expression = ts.createLiteral(-1);
if (labelExpressions[label] === undefined) {
labelExpressions[label] = [expression];
}
else {
labelExpressions[label].push(expression);
}
return expression;
}
return ts.createOmittedExpression();
}
/**
* Creates a numeric literal for the provided instruction.
*/
function createInstruction(instruction) {
var literal = ts.createLiteral(instruction);
literal.trailingComment = instructionNames[instruction];
return literal;
}
/**
* Creates a statement that can be used indicate a Break operation to the provided label.
*
* @param label A label.
* @param location An optional source map location for the statement.
*/
function createInlineBreak(label, location) {
ts.Debug.assert(label > 0, "Invalid label: " + label);
return ts.createReturn(ts.createArrayLiteral([
createInstruction(3 /* Break */),
createLabel(label)
]), location);
}
/**
* Creates a statement that can be used indicate a Return operation.
*
* @param expression The expression for the return statement.
* @param location An optional source map location for the statement.
*/
function createInlineReturn(expression, location) {
return ts.createReturn(ts.createArrayLiteral(expression
? [createInstruction(2 /* Return */), expression]
: [createInstruction(2 /* Return */)]), location);
}
/**
* Creates an expression that can be used to resume from a Yield operation.
*/
function createGeneratorResume(location) {
return ts.createCall(ts.createPropertyAccess(state, "sent"), /*typeArguments*/ undefined, [], location);
}
/**
* Emits an empty instruction.
*/
function emitNop() {
emitWorker(0 /* Nop */);
}
/**
* Emits a Statement.
*
* @param node A statement.
*/
function emitStatement(node) {
if (node) {
emitWorker(1 /* Statement */, [node]);
}
else {
emitNop();
}
}
/**
* Emits an Assignment operation.
*
* @param left The left-hand side of the assignment.
* @param right The right-hand side of the assignment.
* @param location An optional source map location for the assignment.
*/
function emitAssignment(left, right, location) {
emitWorker(2 /* Assign */, [left, right], location);
}
/**
* Emits a Break operation to the specified label.
*
* @param label A label.
* @param location An optional source map location for the assignment.
*/
function emitBreak(label, location) {
emitWorker(3 /* Break */, [label], location);
}
/**
* Emits a Break operation to the specified label when a condition evaluates to a truthy
* value at runtime.
*
* @param label A label.
* @param condition The condition.
* @param location An optional source map location for the assignment.
*/
function emitBreakWhenTrue(label, condition, location) {
emitWorker(4 /* BreakWhenTrue */, [label, condition], location);
}
/**
* Emits a Break to the specified label when a condition evaluates to a falsey value at
* runtime.
*
* @param label A label.
* @param condition The condition.
* @param location An optional source map location for the assignment.
*/
function emitBreakWhenFalse(label, condition, location) {
emitWorker(5 /* BreakWhenFalse */, [label, condition], location);
}
/**
* Emits a YieldStar operation for the provided expression.
*
* @param expression An optional value for the yield operation.
* @param location An optional source map location for the assignment.
*/
function emitYieldStar(expression, location) {
emitWorker(7 /* YieldStar */, [expression], location);
}
/**
* Emits a Yield operation for the provided expression.
*
* @param expression An optional value for the yield operation.
* @param location An optional source map location for the assignment.
*/
function emitYield(expression, location) {
emitWorker(6 /* Yield */, [expression], location);
}
/**
* Emits a Return operation for the provided expression.
*
* @param expression An optional value for the operation.
* @param location An optional source map location for the assignment.
*/
function emitReturn(expression, location) {
emitWorker(8 /* Return */, [expression], location);
}
/**
* Emits a Throw operation for the provided expression.
*
* @param expression A value for the operation.
* @param location An optional source map location for the assignment.
*/
function emitThrow(expression, location) {
emitWorker(9 /* Throw */, [expression], location);
}
/**
* Emits an Endfinally operation. This is used to handle `finally` block semantics.
*/
function emitEndfinally() {
emitWorker(10 /* Endfinally */);
}
/**
* Emits an operation.
*
* @param code The OpCode for the operation.
* @param args The optional arguments for the operation.
*/
function emitWorker(code, args, location) {
if (operations === undefined) {
operations = [];
operationArguments = [];
operationLocations = [];
}
if (labelOffsets === undefined) {
// mark entry point
markLabel(defineLabel());
}
var operationIndex = operations.length;
operations[operationIndex] = code;
operationArguments[operationIndex] = args;
operationLocations[operationIndex] = location;
}
/**
* Builds the generator function body.
*/
function build() {
blockIndex = 0;
labelNumber = 0;
labelNumbers = undefined;
lastOperationWasAbrupt = false;
lastOperationWasCompletion = false;
clauses = undefined;
statements = undefined;
exceptionBlockStack = undefined;
currentExceptionBlock = undefined;
withBlockStack = undefined;
var buildResult = buildStatements();
return ts.createCall(ts.createHelperName(currentSourceFile.externalHelpersModuleName, "__generator"),
/*typeArguments*/ undefined, [
ts.createThis(),
ts.setEmitFlags(ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, [ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, state)],
/*type*/ undefined, ts.createBlock(buildResult,
/*location*/ undefined,
/*multiLine*/ buildResult.length > 0)), 4194304 /* ReuseTempVariableScope */)
]);
}
/**
* Builds the statements for the generator function body.
*/
function buildStatements() {
if (operations) {
for (var operationIndex = 0; operationIndex < operations.length; operationIndex++) {
writeOperation(operationIndex);
}
flushFinalLabel(operations.length);
}
else {
flushFinalLabel(0);
}
if (clauses) {
var labelExpression = ts.createPropertyAccess(state, "label");
var switchStatement = ts.createSwitch(labelExpression, ts.createCaseBlock(clauses));
switchStatement.startsOnNewLine = true;
return [switchStatement];
}
if (statements) {
return statements;
}
return [];
}
/**
* Flush the current label and advance to a new label.
*/
function flushLabel() {
if (!statements) {
return;
}
appendLabel(/*markLabelEnd*/ !lastOperationWasAbrupt);
lastOperationWasAbrupt = false;
lastOperationWasCompletion = false;
labelNumber++;
}
/**
* Flush the final label of the generator function body.
*/
function flushFinalLabel(operationIndex) {
if (isFinalLabelReachable(operationIndex)) {
tryEnterLabel(operationIndex);
withBlockStack = undefined;
writeReturn(/*expression*/ undefined, /*operationLocation*/ undefined);
}
if (statements && clauses) {
appendLabel(/*markLabelEnd*/ false);
}
updateLabelExpressions();
}
/**
* Tests whether the final label of the generator function body
* is reachable by user code.
*/
function isFinalLabelReachable(operationIndex) {
// if the last operation was *not* a completion (return/throw) then
// the final label is reachable.
if (!lastOperationWasCompletion) {
return true;
}
// if there are no labels defined or referenced, then the final label is
// not reachable.
if (!labelOffsets || !labelExpressions) {
return false;
}
// if the label for this offset is referenced, then the final label
// is reachable.
for (var label = 0; label < labelOffsets.length; label++) {
if (labelOffsets[label] === operationIndex && labelExpressions[label]) {
return true;
}
}
return false;
}
/**
* Appends a case clause for the last label and sets the new label.
*
* @param markLabelEnd Indicates that the transition between labels was a fall-through
* from a previous case clause and the change in labels should be
* reflected on the `state` object.
*/
function appendLabel(markLabelEnd) {
if (!clauses) {
clauses = [];
}
if (statements) {
if (withBlockStack) {
// The previous label was nested inside one or more `with` blocks, so we
// surround the statements in generated `with` blocks to create the same environment.
for (var i = withBlockStack.length - 1; i >= 0; i--) {
var withBlock = withBlockStack[i];
statements = [ts.createWith(withBlock.expression, ts.createBlock(statements))];
}
}
if (currentExceptionBlock) {
// The previous label was nested inside of an exception block, so we must
// indicate entry into a protected region by pushing the label numbers
// for each block in the protected region.
var startLabel = currentExceptionBlock.startLabel, catchLabel = currentExceptionBlock.catchLabel, finallyLabel = currentExceptionBlock.finallyLabel, endLabel = currentExceptionBlock.endLabel;
statements.unshift(ts.createStatement(ts.createCall(ts.createPropertyAccess(ts.createPropertyAccess(state, "trys"), "push"),
/*typeArguments*/ undefined, [
ts.createArrayLiteral([
createLabel(startLabel),
createLabel(catchLabel),
createLabel(finallyLabel),
createLabel(endLabel)
])
])));
currentExceptionBlock = undefined;
}
if (markLabelEnd) {
// The case clause for the last label falls through to this label, so we
// add an assignment statement to reflect the change in labels.
statements.push(ts.createStatement(ts.createAssignment(ts.createPropertyAccess(state, "label"), ts.createLiteral(labelNumber + 1))));
}
}
clauses.push(ts.createCaseClause(ts.createLiteral(labelNumber), statements || []));
statements = undefined;
}
/**
* Tries to enter into a new label at the current operation index.
*/
function tryEnterLabel(operationIndex) {
if (!labelOffsets) {
return;
}
for (var label = 0; label < labelOffsets.length; label++) {
if (labelOffsets[label] === operationIndex) {
flushLabel();
if (labelNumbers === undefined) {
labelNumbers = [];
}
if (labelNumbers[labelNumber] === undefined) {
labelNumbers[labelNumber] = [label];
}
else {
labelNumbers[labelNumber].push(label);
}
}
}
}
/**
* Updates literal expressions for labels with actual label numbers.
*/
function updateLabelExpressions() {
if (labelExpressions !== undefined && labelNumbers !== undefined) {
for (var labelNumber_1 = 0; labelNumber_1 < labelNumbers.length; labelNumber_1++) {
var labels = labelNumbers[labelNumber_1];
if (labels !== undefined) {
for (var _i = 0, labels_1 = labels; _i < labels_1.length; _i++) {
var label = labels_1[_i];
var expressions = labelExpressions[label];
if (expressions !== undefined) {
for (var _a = 0, expressions_1 = expressions; _a < expressions_1.length; _a++) {
var expression = expressions_1[_a];
expression.text = String(labelNumber_1);
}
}
}
}
}
}
}
/**
* Tries to enter or leave a code block.
*/
function tryEnterOrLeaveBlock(operationIndex) {
if (blocks) {
for (; blockIndex < blockActions.length && blockOffsets[blockIndex] <= operationIndex; blockIndex++) {
var block = blocks[blockIndex];
var blockAction = blockActions[blockIndex];
if (isExceptionBlock(block)) {
if (blockAction === 0 /* Open */) {
if (!exceptionBlockStack) {
exceptionBlockStack = [];
}
if (!statements) {
statements = [];
}
exceptionBlockStack.push(currentExceptionBlock);
currentExceptionBlock = block;
}
else if (blockAction === 1 /* Close */) {
currentExceptionBlock = exceptionBlockStack.pop();
}
}
else if (isWithBlock(block)) {
if (blockAction === 0 /* Open */) {
if (!withBlockStack) {
withBlockStack = [];
}
withBlockStack.push(block);
}
else if (blockAction === 1 /* Close */) {
withBlockStack.pop();
}
}
}
}
}
/**
* Writes an operation as a statement to the current label's statement list.
*
* @param operation The OpCode of the operation
*/
function writeOperation(operationIndex) {
tryEnterLabel(operationIndex);
tryEnterOrLeaveBlock(operationIndex);
// early termination, nothing else to process in this label
if (lastOperationWasAbrupt) {
return;
}
lastOperationWasAbrupt = false;
lastOperationWasCompletion = false;
var opcode = operations[operationIndex];
if (opcode === 0 /* Nop */) {
return;
}
else if (opcode === 10 /* Endfinally */) {
return writeEndfinally();
}
var args = operationArguments[operationIndex];
if (opcode === 1 /* Statement */) {
return writeStatement(args[0]);
}
var location = operationLocations[operationIndex];
switch (opcode) {
case 2 /* Assign */:
return writeAssign(args[0], args[1], location);
case 3 /* Break */:
return writeBreak(args[0], location);
case 4 /* BreakWhenTrue */:
return writeBreakWhenTrue(args[0], args[1], location);
case 5 /* BreakWhenFalse */:
return writeBreakWhenFalse(args[0], args[1], location);
case 6 /* Yield */:
return writeYield(args[0], location);
case 7 /* YieldStar */:
return writeYieldStar(args[0], location);
case 8 /* Return */:
return writeReturn(args[0], location);
case 9 /* Throw */:
return writeThrow(args[0], location);
}
}
/**
* Writes a statement to the current label's statement list.
*
* @param statement A statement to write.
*/
function writeStatement(statement) {
if (statement) {
if (!statements) {
statements = [statement];
}
else {
statements.push(statement);
}
}
}
/**
* Writes an Assign operation to the current label's statement list.
*
* @param left The left-hand side of the assignment.
* @param right The right-hand side of the assignment.
* @param operationLocation The source map location for the operation.
*/
function writeAssign(left, right, operationLocation) {
writeStatement(ts.createStatement(ts.createAssignment(left, right), operationLocation));
}
/**
* Writes a Throw operation to the current label's statement list.
*
* @param expression The value to throw.
* @param operationLocation The source map location for the operation.
*/
function writeThrow(expression, operationLocation) {
lastOperationWasAbrupt = true;
lastOperationWasCompletion = true;
writeStatement(ts.createThrow(expression, operationLocation));
}
/**
* Writes a Return operation to the current label's statement list.
*
* @param expression The value to return.
* @param operationLocation The source map location for the operation.
*/
function writeReturn(expression, operationLocation) {
lastOperationWasAbrupt = true;
lastOperationWasCompletion = true;
writeStatement(ts.createReturn(ts.createArrayLiteral(expression
? [createInstruction(2 /* Return */), expression]
: [createInstruction(2 /* Return */)]), operationLocation));
}
/**
* Writes a Break operation to the current label's statement list.
*
* @param label The label for the Break.
* @param operationLocation The source map location for the operation.
*/
function writeBreak(label, operationLocation) {
lastOperationWasAbrupt = true;
writeStatement(ts.createReturn(ts.createArrayLiteral([
createInstruction(3 /* Break */),
createLabel(label)
]), operationLocation));
}
/**
* Writes a BreakWhenTrue operation to the current label's statement list.
*
* @param label The label for the Break.
* @param condition The condition for the Break.
* @param operationLocation The source map location for the operation.
*/
function writeBreakWhenTrue(label, condition, operationLocation) {
writeStatement(ts.createIf(condition, ts.createReturn(ts.createArrayLiteral([
createInstruction(3 /* Break */),
createLabel(label)
]), operationLocation)));
}
/**
* Writes a BreakWhenFalse operation to the current label's statement list.
*
* @param label The label for the Break.
* @param condition The condition for the Break.
* @param operationLocation The source map location for the operation.
*/
function writeBreakWhenFalse(label, condition, operationLocation) {
writeStatement(ts.createIf(ts.createLogicalNot(condition), ts.createReturn(ts.createArrayLiteral([
createInstruction(3 /* Break */),
createLabel(label)
]), operationLocation)));
}
/**
* Writes a Yield operation to the current label's statement list.
*
* @param expression The expression to yield.
* @param operationLocation The source map location for the operation.
*/
function writeYield(expression, operationLocation) {
lastOperationWasAbrupt = true;
writeStatement(ts.createReturn(ts.createArrayLiteral(expression
? [createInstruction(4 /* Yield */), expression]
: [createInstruction(4 /* Yield */)]), operationLocation));
}
/**
* Writes a YieldStar instruction to the current label's statement list.
*
* @param expression The expression to yield.
* @param operationLocation The source map location for the operation.
*/
function writeYieldStar(expression, operationLocation) {
lastOperationWasAbrupt = true;
writeStatement(ts.createReturn(ts.createArrayLiteral([
createInstruction(5 /* YieldStar */),
expression
]), operationLocation));
}
/**
* Writes an Endfinally instruction to the current label's statement list.
*/
function writeEndfinally() {
lastOperationWasAbrupt = true;
writeStatement(ts.createReturn(ts.createArrayLiteral([
createInstruction(7 /* Endfinally */)
])));
}
}
ts.transformGenerators = transformGenerators;
var _a;
})(ts || (ts = {}));
/// <reference path="../factory.ts" />
/// <reference path="../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
/**
* Transforms ES5 syntax into ES3 syntax.
*
* @param context Context and state information for the transformation.
*/
function transformES5(context) {
var previousOnSubstituteNode = context.onSubstituteNode;
context.onSubstituteNode = onSubstituteNode;
context.enableSubstitution(177 /* PropertyAccessExpression */);
context.enableSubstitution(257 /* PropertyAssignment */);
return transformSourceFile;
/**
* Transforms an ES5 source file to ES3.
*
* @param node A SourceFile
*/
function transformSourceFile(node) {
return node;
}
/**
* Hooks node substitutions.
*
* @param emitContext The context for the emitter.
* @param node The node to substitute.
*/
function onSubstituteNode(emitContext, node) {
node = previousOnSubstituteNode(emitContext, node);
if (ts.isPropertyAccessExpression(node)) {
return substitutePropertyAccessExpression(node);
}
else if (ts.isPropertyAssignment(node)) {
return substitutePropertyAssignment(node);
}
return node;
}
/**
* Substitutes a PropertyAccessExpression whose name is a reserved word.
*
* @param node A PropertyAccessExpression
*/
function substitutePropertyAccessExpression(node) {
var literalName = trySubstituteReservedName(node.name);
if (literalName) {
return ts.createElementAccess(node.expression, literalName, /*location*/ node);
}
return node;
}
/**
* Substitutes a PropertyAssignment whose name is a reserved word.
*
* @param node A PropertyAssignment
*/
function substitutePropertyAssignment(node) {
var literalName = ts.isIdentifier(node.name) && trySubstituteReservedName(node.name);
if (literalName) {
return ts.updatePropertyAssignment(node, literalName, node.initializer);
}
return node;
}
/**
* If an identifier name is a reserved word, returns a string literal for the name.
*
* @param name An Identifier
*/
function trySubstituteReservedName(name) {
var token = name.originalKeywordKind || (ts.nodeIsSynthesized(name) ? ts.stringToToken(name.text) : undefined);
if (token >= 71 /* FirstReservedWord */ && token <= 106 /* LastReservedWord */) {
return ts.createLiteral(name, /*location*/ name);
}
return undefined;
}
}
ts.transformES5 = transformES5;
})(ts || (ts = {}));
/// <reference path="../../factory.ts" />
/// <reference path="../../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
function transformES2015Module(context) {
var compilerOptions = context.getCompilerOptions();
return transformSourceFile;
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)) {
return node;
}
if (ts.isExternalModule(node) || compilerOptions.isolatedModules) {
return ts.visitEachChild(node, visitor, context);
}
return node;
}
function visitor(node) {
switch (node.kind) {
case 234 /* ImportEqualsDeclaration */:
// Elide `import=` as it is not legal with --module ES6
return undefined;
case 240 /* ExportAssignment */:
return visitExportAssignment(node);
}
return node;
}
function visitExportAssignment(node) {
// Elide `export=` as it is not legal with --module ES6
return node.isExportEquals ? undefined : node;
}
}
ts.transformES2015Module = transformES2015Module;
})(ts || (ts = {}));
/// <reference path="../../factory.ts" />
/// <reference path="../../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
function transformSystemModule(context) {
var startLexicalEnvironment = context.startLexicalEnvironment, endLexicalEnvironment = context.endLexicalEnvironment, hoistVariableDeclaration = context.hoistVariableDeclaration;
var compilerOptions = context.getCompilerOptions();
var resolver = context.getEmitResolver();
var host = context.getEmitHost();
var previousOnSubstituteNode = context.onSubstituteNode;
var previousOnEmitNode = context.onEmitNode;
context.onSubstituteNode = onSubstituteNode;
context.onEmitNode = onEmitNode;
context.enableSubstitution(70 /* Identifier */); // Substitutes expression identifiers for imported symbols.
context.enableSubstitution(192 /* BinaryExpression */); // Substitutes assignments to exported symbols.
context.enableSubstitution(190 /* PrefixUnaryExpression */); // Substitutes updates to exported symbols.
context.enableSubstitution(191 /* PostfixUnaryExpression */); // Substitutes updates to exported symbols.
context.enableEmitNotification(261 /* SourceFile */); // Restore state when substituting nodes in a file.
var moduleInfoMap = ts.createMap(); // The ExternalModuleInfo for each file.
var deferredExports = ts.createMap(); // Exports to defer until an EndOfDeclarationMarker is found.
var exportFunctionsMap = ts.createMap(); // The export function associated with a source file.
var noSubstitutionMap = ts.createMap(); // Set of nodes for which substitution rules should be ignored for each file.
var currentSourceFile; // The current file.
var moduleInfo; // ExternalModuleInfo for the current file.
var exportFunction; // The export function for the current file.
var contextObject; // The context object for the current file.
var hoistedStatements;
var enclosingBlockScopedContainer;
var noSubstitution; // Set of nodes for which substitution rules should be ignored.
return transformSourceFile;
/**
* Transforms the module aspects of a SourceFile.
*
* @param node The SourceFile node.
*/
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)
|| !(ts.isExternalModule(node)
|| compilerOptions.isolatedModules)) {
return node;
}
var id = ts.getOriginalNodeId(node);
currentSourceFile = node;
enclosingBlockScopedContainer = node;
// System modules have the following shape:
//
// System.register(['dep-1', ... 'dep-n'], function(exports) {/* module body function */})
//
// The parameter 'exports' here is a callback '<T>(name: string, value: T) => T' that
// is used to publish exported values. 'exports' returns its 'value' argument so in
// most cases expressions that mutate exported values can be rewritten as:
//
// expr -> exports('name', expr)
//
// The only exception in this rule is postfix unary operators,
// see comment to 'substitutePostfixUnaryExpression' for more details
// Collect information about the external module and dependency groups.
moduleInfo = moduleInfoMap[id] = ts.collectExternalModuleInfo(node, resolver);
// Make sure that the name of the 'exports' function does not conflict with
// existing identifiers.
exportFunction = exportFunctionsMap[id] = ts.createUniqueName("exports");
contextObject = ts.createUniqueName("context");
// Add the body of the module.
var dependencyGroups = collectDependencyGroups(moduleInfo.externalImports);
var moduleBodyFunction = ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, [
ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, exportFunction),
ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, contextObject)
],
/*type*/ undefined, createSystemModuleBody(node, dependencyGroups));
// Write the call to `System.register`
// Clear the emit-helpers flag for later passes since we'll have already used it in the module body
// So the helper will be emit at the correct position instead of at the top of the source-file
var moduleName = ts.tryGetModuleNameFromFile(node, host, compilerOptions);
var dependencies = ts.createArrayLiteral(ts.map(dependencyGroups, function (dependencyGroup) { return dependencyGroup.name; }));
var updated = ts.updateSourceFileNode(node, ts.createNodeArray([
ts.createStatement(ts.createCall(ts.createPropertyAccess(ts.createIdentifier("System"), "register"),
/*typeArguments*/ undefined, moduleName
? [moduleName, dependencies, moduleBodyFunction]
: [dependencies, moduleBodyFunction]))
], node.statements));
ts.setEmitFlags(updated, ts.getEmitFlags(node) & ~1 /* EmitEmitHelpers */);
if (noSubstitution) {
noSubstitutionMap[id] = noSubstitution;
noSubstitution = undefined;
}
currentSourceFile = undefined;
moduleInfo = undefined;
exportFunction = undefined;
contextObject = undefined;
hoistedStatements = undefined;
enclosingBlockScopedContainer = undefined;
return ts.aggregateTransformFlags(updated);
}
/**
* Collects the dependency groups for this files imports.
*
* @param externalImports The imports for the file.
*/
function collectDependencyGroups(externalImports) {
var groupIndices = ts.createMap();
var dependencyGroups = [];
for (var i = 0; i < externalImports.length; i++) {
var externalImport = externalImports[i];
var externalModuleName = ts.getExternalModuleNameLiteral(externalImport, currentSourceFile, host, resolver, compilerOptions);
var text = externalModuleName.text;
if (ts.hasProperty(groupIndices, text)) {
// deduplicate/group entries in dependency list by the dependency name
var groupIndex = groupIndices[text];
dependencyGroups[groupIndex].externalImports.push(externalImport);
}
else {
groupIndices[text] = dependencyGroups.length;
dependencyGroups.push({
name: externalModuleName,
externalImports: [externalImport]
});
}
}
return dependencyGroups;
}
/**
* Adds the statements for the module body function for the source file.
*
* @param node The source file for the module.
* @param dependencyGroups The grouped dependencies of the module.
*/
function createSystemModuleBody(node, dependencyGroups) {
// Shape of the body in system modules:
//
// function (exports) {
// <list of local aliases for imports>
// <hoisted variable declarations>
// <hoisted function declarations>
// return {
// setters: [
// <list of setter function for imports>
// ],
// execute: function() {
// <module statements>
// }
// }
// <temp declarations>
// }
//
// i.e:
//
// import {x} from 'file1'
// var y = 1;
// export function foo() { return y + x(); }
// console.log(y);
//
// Will be transformed to:
//
// function(exports) {
// function foo() { return y + file_1.x(); }
// exports("foo", foo);
// var file_1, y;
// return {
// setters: [
// function(v) { file_1 = v }
// ],
// execute(): function() {
// y = 1;
// console.log(y);
// }
// };
// }
var statements = [];
// We start a new lexical environment in this function body, but *not* in the
// body of the execute function. This allows us to emit temporary declarations
// only in the outer module body and not in the inner one.
startLexicalEnvironment();
// Add any prologue directives.
var statementOffset = ts.addPrologueDirectives(statements, node.statements, /*ensureUseStrict*/ !compilerOptions.noImplicitUseStrict, sourceElementVisitor);
// var __moduleName = context_1 && context_1.id;
statements.push(ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList([
ts.createVariableDeclaration("__moduleName",
/*type*/ undefined, ts.createLogicalAnd(contextObject, ts.createPropertyAccess(contextObject, "id")))
])));
// Visit the statements of the source file, emitting any transformations into
// the `executeStatements` array. We do this *before* we fill the `setters` array
// as we both emit transformations as well as aggregate some data used when creating
// setters. This allows us to reduce the number of times we need to loop through the
// statements of the source file.
var executeStatements = ts.visitNodes(node.statements, sourceElementVisitor, ts.isStatement, statementOffset);
// Emit early exports for function declarations.
ts.addRange(statements, hoistedStatements);
// We emit hoisted variables early to align roughly with our previous emit output.
// Two key differences in this approach are:
// - Temporary variables will appear at the top rather than at the bottom of the file
ts.addRange(statements, endLexicalEnvironment());
var exportStarFunction = addExportStarIfNeeded(statements);
statements.push(ts.createReturn(ts.setMultiLine(ts.createObjectLiteral([
ts.createPropertyAssignment("setters", createSettersArray(exportStarFunction, dependencyGroups)),
ts.createPropertyAssignment("execute", ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined,
/*parameters*/ [],
/*type*/ undefined, ts.createBlock(executeStatements,
/*location*/ undefined,
/*multiLine*/ true)))
]),
/*multiLine*/ true)));
var body = ts.createBlock(statements, /*location*/ undefined, /*multiLine*/ true);
ts.setEmitFlags(body, 1 /* EmitEmitHelpers */);
return body;
}
/**
* Adds an exportStar function to a statement list if it is needed for the file.
*
* @param statements A statement list.
*/
function addExportStarIfNeeded(statements) {
if (!moduleInfo.hasExportStarsToExportValues) {
return;
}
// when resolving exports local exported entries/indirect exported entries in the module
// should always win over entries with similar names that were added via star exports
// to support this we store names of local/indirect exported entries in a set.
// this set is used to filter names brought by star expors.
// local names set should only be added if we have anything exported
if (!moduleInfo.exportedNames && ts.isEmpty(moduleInfo.exportSpecifiers)) {
// no exported declarations (export var ...) or export specifiers (export {x})
// check if we have any non star export declarations.
var hasExportDeclarationWithExportClause = false;
for (var _i = 0, _a = moduleInfo.externalImports; _i < _a.length; _i++) {
var externalImport = _a[_i];
if (externalImport.kind === 241 /* ExportDeclaration */ && externalImport.exportClause) {
hasExportDeclarationWithExportClause = true;
break;
}
}
if (!hasExportDeclarationWithExportClause) {
// we still need to emit exportStar helper
var exportStarFunction_1 = createExportStarFunction(/*localNames*/ undefined);
statements.push(exportStarFunction_1);
return exportStarFunction_1.name;
}
}
var exportedNames = [];
if (moduleInfo.exportedNames) {
for (var _b = 0, _c = moduleInfo.exportedNames; _b < _c.length; _b++) {
var exportedLocalName = _c[_b];
if (exportedLocalName.text === "default") {
continue;
}
// write name of exported declaration, i.e 'export var x...'
exportedNames.push(ts.createPropertyAssignment(ts.createLiteral(exportedLocalName), ts.createLiteral(true)));
}
}
for (var _d = 0, _e = moduleInfo.externalImports; _d < _e.length; _d++) {
var externalImport = _e[_d];
if (externalImport.kind !== 241 /* ExportDeclaration */) {
continue;
}
var exportDecl = externalImport;
if (!exportDecl.exportClause) {
// export * from ...
continue;
}
for (var _f = 0, _g = exportDecl.exportClause.elements; _f < _g.length; _f++) {
var element = _g[_f];
// write name of indirectly exported entry, i.e. 'export {x} from ...'
exportedNames.push(ts.createPropertyAssignment(ts.createLiteral((element.name || element.propertyName).text), ts.createLiteral(true)));
}
}
var exportedNamesStorageRef = ts.createUniqueName("exportedNames");
statements.push(ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList([
ts.createVariableDeclaration(exportedNamesStorageRef,
/*type*/ undefined, ts.createObjectLiteral(exportedNames, /*location*/ undefined, /*multiline*/ true))
])));
var exportStarFunction = createExportStarFunction(exportedNamesStorageRef);
statements.push(exportStarFunction);
return exportStarFunction.name;
}
/**
* Creates an exportStar function for the file, with an optional set of excluded local
* names.
*
* @param localNames An optional reference to an object containing a set of excluded local
* names.
*/
function createExportStarFunction(localNames) {
var exportStarFunction = ts.createUniqueName("exportStar");
var m = ts.createIdentifier("m");
var n = ts.createIdentifier("n");
var exports = ts.createIdentifier("exports");
var condition = ts.createStrictInequality(n, ts.createLiteral("default"));
if (localNames) {
condition = ts.createLogicalAnd(condition, ts.createLogicalNot(ts.createHasOwnProperty(localNames, n)));
}
return ts.createFunctionDeclaration(
/*decorators*/ undefined,
/*modifiers*/ undefined,
/*asteriskToken*/ undefined, exportStarFunction,
/*typeParameters*/ undefined, [ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, m)],
/*type*/ undefined, ts.createBlock([
ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList([
ts.createVariableDeclaration(exports,
/*type*/ undefined, ts.createObjectLiteral([]))
])),
ts.createForIn(ts.createVariableDeclarationList([
ts.createVariableDeclaration(n, /*type*/ undefined)
]), m, ts.createBlock([
ts.setEmitFlags(ts.createIf(condition, ts.createStatement(ts.createAssignment(ts.createElementAccess(exports, n), ts.createElementAccess(m, n)))), 32 /* SingleLine */)
])),
ts.createStatement(ts.createCall(exportFunction,
/*typeArguments*/ undefined, [exports]))
],
/*location*/ undefined,
/*multiline*/ true));
}
/**
* Creates an array setter callbacks for each dependency group.
*
* @param exportStarFunction A reference to an exportStarFunction for the file.
* @param dependencyGroups An array of grouped dependencies.
*/
function createSettersArray(exportStarFunction, dependencyGroups) {
var setters = [];
for (var _i = 0, dependencyGroups_1 = dependencyGroups; _i < dependencyGroups_1.length; _i++) {
var group = dependencyGroups_1[_i];
// derive a unique name for parameter from the first named entry in the group
var localName = ts.forEach(group.externalImports, function (i) { return ts.getLocalNameForExternalImport(i, currentSourceFile); });
var parameterName = localName ? ts.getGeneratedNameForNode(localName) : ts.createUniqueName("");
var statements = [];
for (var _a = 0, _b = group.externalImports; _a < _b.length; _a++) {
var entry = _b[_a];
var importVariableName = ts.getLocalNameForExternalImport(entry, currentSourceFile);
switch (entry.kind) {
case 235 /* ImportDeclaration */:
if (!entry.importClause) {
// 'import "..."' case
// module is imported only for side-effects, no emit required
break;
}
// fall-through
case 234 /* ImportEqualsDeclaration */:
ts.Debug.assert(importVariableName !== undefined);
// save import into the local
statements.push(ts.createStatement(ts.createAssignment(importVariableName, parameterName)));
break;
case 241 /* ExportDeclaration */:
ts.Debug.assert(importVariableName !== undefined);
if (entry.exportClause) {
// export {a, b as c} from 'foo'
//
// emit as:
//
// exports_({
// "a": _["a"],
// "c": _["b"]
// });
var properties = [];
for (var _c = 0, _d = entry.exportClause.elements; _c < _d.length; _c++) {
var e = _d[_c];
properties.push(ts.createPropertyAssignment(ts.createLiteral(e.name.text), ts.createElementAccess(parameterName, ts.createLiteral((e.propertyName || e.name).text))));
}
statements.push(ts.createStatement(ts.createCall(exportFunction,
/*typeArguments*/ undefined, [ts.createObjectLiteral(properties, /*location*/ undefined, /*multiline*/ true)])));
}
else {
// export * from 'foo'
//
// emit as:
//
// exportStar(foo_1_1);
statements.push(ts.createStatement(ts.createCall(exportStarFunction,
/*typeArguments*/ undefined, [parameterName])));
}
break;
}
}
setters.push(ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, [ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, parameterName)],
/*type*/ undefined, ts.createBlock(statements, /*location*/ undefined, /*multiLine*/ true)));
}
return ts.createArrayLiteral(setters, /*location*/ undefined, /*multiLine*/ true);
}
//
// Top-level Source Element Visitors
//
/**
* Visit source elements at the top-level of a module.
*
* @param node The node to visit.
*/
function sourceElementVisitor(node) {
switch (node.kind) {
case 235 /* ImportDeclaration */:
return visitImportDeclaration(node);
case 234 /* ImportEqualsDeclaration */:
return visitImportEqualsDeclaration(node);
case 241 /* ExportDeclaration */:
// ExportDeclarations are elided as they are handled via
// `appendExportsOfDeclaration`.
return undefined;
case 240 /* ExportAssignment */:
return visitExportAssignment(node);
default:
return nestedElementVisitor(node);
}
}
/**
* Visits an ImportDeclaration node.
*
* @param node The node to visit.
*/
function visitImportDeclaration(node) {
var statements;
if (node.importClause) {
hoistVariableDeclaration(ts.getLocalNameForExternalImport(node, currentSourceFile));
}
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfImportDeclaration(deferredExports[id], node);
}
else {
statements = appendExportsOfImportDeclaration(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Visits an ImportEqualsDeclaration node.
*
* @param node The node to visit.
*/
function visitImportEqualsDeclaration(node) {
ts.Debug.assert(ts.isExternalModuleImportEqualsDeclaration(node), "import= for internal module references should be handled in an earlier transformer.");
var statements;
hoistVariableDeclaration(ts.getLocalNameForExternalImport(node, currentSourceFile));
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfImportEqualsDeclaration(deferredExports[id], node);
}
else {
statements = appendExportsOfImportEqualsDeclaration(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Visits an ExportAssignment node.
*
* @param node The node to visit.
*/
function visitExportAssignment(node) {
if (node.isExportEquals) {
// Elide `export=` as it is illegal in a SystemJS module.
return undefined;
}
var expression = ts.visitNode(node.expression, destructuringVisitor, ts.isExpression);
var original = node.original;
if (original && hasAssociatedEndOfDeclarationMarker(original)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportStatement(deferredExports[id], ts.createIdentifier("default"), expression, /*allowComments*/ true);
}
else {
return createExportStatement(ts.createIdentifier("default"), expression, /*allowComments*/ true);
}
}
/**
* Visits a FunctionDeclaration, hoisting it to the outer module body function.
*
* @param node The node to visit.
*/
function visitFunctionDeclaration(node) {
if (ts.hasModifier(node, 1 /* Export */)) {
hoistedStatements = ts.append(hoistedStatements, ts.updateFunctionDeclaration(node, node.decorators, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), ts.getDeclarationName(node, /*allowComments*/ true, /*allowSourceMaps*/ true),
/*typeParameters*/ undefined, ts.visitNodes(node.parameters, destructuringVisitor, ts.isParameterDeclaration),
/*type*/ undefined, ts.visitNode(node.body, destructuringVisitor, ts.isBlock)));
}
else {
hoistedStatements = ts.append(hoistedStatements, node);
}
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfHoistedDeclaration(deferredExports[id], node);
}
else {
hoistedStatements = appendExportsOfHoistedDeclaration(hoistedStatements, node);
}
return undefined;
}
/**
* Visits a ClassDeclaration, hoisting its name to the outer module body function.
*
* @param node The node to visit.
*/
function visitClassDeclaration(node) {
var statements;
// Hoist the name of the class declaration to the outer module body function.
var name = ts.getLocalName(node);
hoistVariableDeclaration(name);
// Rewrite the class declaration into an assignment of a class expression.
statements = ts.append(statements, ts.createStatement(ts.createAssignment(name, ts.createClassExpression(
/*modifiers*/ undefined, node.name,
/*typeParameters*/ undefined, ts.visitNodes(node.heritageClauses, destructuringVisitor, ts.isHeritageClause), ts.visitNodes(node.members, destructuringVisitor, ts.isClassElement),
/*location*/ node)),
/*location*/ node));
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfHoistedDeclaration(deferredExports[id], node);
}
else {
statements = appendExportsOfHoistedDeclaration(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Visits a variable statement, hoisting declared names to the top-level module body.
* Each declaration is rewritten into an assignment expression.
*
* @param node The node to visit.
*/
function visitVariableStatement(node) {
if (!shouldHoistVariableDeclarationList(node.declarationList)) {
return ts.visitNode(node, destructuringVisitor, ts.isStatement);
}
var expressions;
var isExportedDeclaration = ts.hasModifier(node, 1 /* Export */);
var isMarkedDeclaration = hasAssociatedEndOfDeclarationMarker(node);
for (var _i = 0, _a = node.declarationList.declarations; _i < _a.length; _i++) {
var variable = _a[_i];
if (variable.initializer) {
expressions = ts.append(expressions, transformInitializedVariable(variable, isExportedDeclaration && !isMarkedDeclaration));
}
else {
hoistBindingElement(variable);
}
}
var statements;
if (expressions) {
statements = ts.append(statements, ts.createStatement(ts.inlineExpressions(expressions), /*location*/ node));
}
if (isMarkedDeclaration) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfVariableStatement(deferredExports[id], node, isExportedDeclaration);
}
else {
statements = appendExportsOfVariableStatement(statements, node, /*exportSelf*/ false);
}
return ts.singleOrMany(statements);
}
/**
* Hoists the declared names of a VariableDeclaration or BindingElement.
*
* @param node The declaration to hoist.
*/
function hoistBindingElement(node) {
if (ts.isBindingPattern(node.name)) {
for (var _i = 0, _a = node.name.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (!ts.isOmittedExpression(element)) {
hoistBindingElement(element);
}
}
}
else {
hoistVariableDeclaration(ts.getSynthesizedClone(node.name));
}
}
/**
* Determines whether a VariableDeclarationList should be hoisted.
*
* @param node The node to test.
*/
function shouldHoistVariableDeclarationList(node) {
// hoist only non-block scoped declarations or block scoped declarations parented by source file
return (ts.getEmitFlags(node) & 16777216 /* NoHoisting */) === 0
&& (enclosingBlockScopedContainer.kind === 261 /* SourceFile */
|| (ts.getOriginalNode(node).flags & 3 /* BlockScoped */) === 0);
}
/**
* Transform an initialized variable declaration into an expression.
*
* @param node The node to transform.
* @param isExportedDeclaration A value indicating whether the variable is exported.
*/
function transformInitializedVariable(node, isExportedDeclaration) {
var createAssignment = isExportedDeclaration ? createExportedVariableAssignment : createNonExportedVariableAssignment;
return ts.isBindingPattern(node.name)
? ts.flattenVariableDestructuringToExpression(node, hoistVariableDeclaration, createAssignment, destructuringVisitor)
: createAssignment(node.name, ts.visitNode(node.initializer, destructuringVisitor, ts.isExpression));
}
/**
* Creates an assignment expression for an exported variable declaration.
*
* @param name The name of the variable.
* @param value The value of the variable's initializer.
* @param location The source map location for the assignment.
*/
function createExportedVariableAssignment(name, value, location) {
return createVariableAssignment(name, value, location, /*isExportedDeclaration*/ true);
}
/**
* Creates an assignment expression for a non-exported variable declaration.
*
* @param name The name of the variable.
* @param value The value of the variable's initializer.
* @param location The source map location for the assignment.
*/
function createNonExportedVariableAssignment(name, value, location) {
return createVariableAssignment(name, value, location, /*isExportedDeclaration*/ false);
}
/**
* Creates an assignment expression for a variable declaration.
*
* @param name The name of the variable.
* @param value The value of the variable's initializer.
* @param location The source map location for the assignment.
* @param isExportedDeclaration A value indicating whether the variable is exported.
*/
function createVariableAssignment(name, value, location, isExportedDeclaration) {
hoistVariableDeclaration(ts.getSynthesizedClone(name));
return isExportedDeclaration
? createExportExpression(name, preventSubstitution(ts.createAssignment(name, value, location)))
: preventSubstitution(ts.createAssignment(name, value, location));
}
/**
* Visits a MergeDeclarationMarker used as a placeholder for the beginning of a merged
* and transformed declaration.
*
* @param node The node to visit.
*/
function visitMergeDeclarationMarker(node) {
// For an EnumDeclaration or ModuleDeclaration that merges with a preceeding
// declaration we do not emit a leading variable declaration. To preserve the
// begin/end semantics of the declararation and to properly handle exports
// we wrapped the leading variable declaration in a `MergeDeclarationMarker`.
//
// To balance the declaration, we defer the exports of the elided variable
// statement until we visit this declaration's `EndOfDeclarationMarker`.
if (hasAssociatedEndOfDeclarationMarker(node) && node.original.kind === 205 /* VariableStatement */) {
var id = ts.getOriginalNodeId(node);
var isExportedDeclaration = ts.hasModifier(node.original, 1 /* Export */);
deferredExports[id] = appendExportsOfVariableStatement(deferredExports[id], node.original, isExportedDeclaration);
}
return node;
}
/**
* Determines whether a node has an associated EndOfDeclarationMarker.
*
* @param node The node to test.
*/
function hasAssociatedEndOfDeclarationMarker(node) {
return (ts.getEmitFlags(node) & 33554432 /* HasEndOfDeclarationMarker */) !== 0;
}
/**
* Visits a DeclarationMarker used as a placeholder for the end of a transformed
* declaration.
*
* @param node The node to visit.
*/
function visitEndOfDeclarationMarker(node) {
// For some transformations we emit an `EndOfDeclarationMarker` to mark the actual
// end of the transformed declaration. We use this marker to emit any deferred exports
// of the declaration.
var id = ts.getOriginalNodeId(node);
var statements = deferredExports[id];
if (statements) {
delete deferredExports[id];
return ts.append(statements, node);
}
return node;
}
/**
* Appends the exports of an ImportDeclaration to a statement list, returning the
* statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
*/
function appendExportsOfImportDeclaration(statements, decl) {
if (moduleInfo.exportEquals) {
return statements;
}
var importClause = decl.importClause;
if (!importClause) {
return statements;
}
if (importClause.name) {
statements = appendExportsOfDeclaration(statements, importClause);
}
var namedBindings = importClause.namedBindings;
if (namedBindings) {
switch (namedBindings.kind) {
case 237 /* NamespaceImport */:
statements = appendExportsOfDeclaration(statements, namedBindings);
break;
case 238 /* NamedImports */:
for (var _i = 0, _a = namedBindings.elements; _i < _a.length; _i++) {
var importBinding = _a[_i];
statements = appendExportsOfDeclaration(statements, importBinding);
}
break;
}
}
return statements;
}
/**
* Appends the export of an ImportEqualsDeclaration to a statement list, returning the
* statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
*/
function appendExportsOfImportEqualsDeclaration(statements, decl) {
if (moduleInfo.exportEquals) {
return statements;
}
return appendExportsOfDeclaration(statements, decl);
}
/**
* Appends the exports of a VariableStatement to a statement list, returning the statement
* list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param node The VariableStatement whose exports are to be recorded.
* @param exportSelf A value indicating whether to also export each VariableDeclaration of
* `nodes` declaration list.
*/
function appendExportsOfVariableStatement(statements, node, exportSelf) {
if (moduleInfo.exportEquals) {
return statements;
}
for (var _i = 0, _a = node.declarationList.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
if (decl.initializer || exportSelf) {
statements = appendExportsOfBindingElement(statements, decl, exportSelf);
}
}
return statements;
}
/**
* Appends the exports of a VariableDeclaration or BindingElement to a statement list,
* returning the statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
* @param exportSelf A value indicating whether to also export the declaration itself.
*/
function appendExportsOfBindingElement(statements, decl, exportSelf) {
if (moduleInfo.exportEquals) {
return statements;
}
if (ts.isBindingPattern(decl.name)) {
for (var _i = 0, _a = decl.name.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (!ts.isOmittedExpression(element)) {
statements = appendExportsOfBindingElement(statements, element, exportSelf);
}
}
}
else if (!ts.isGeneratedIdentifier(decl.name)) {
var excludeName = void 0;
if (exportSelf) {
statements = appendExportStatement(statements, decl.name, ts.getLocalName(decl));
excludeName = decl.name.text;
}
statements = appendExportsOfDeclaration(statements, decl, excludeName);
}
return statements;
}
/**
* Appends the exports of a ClassDeclaration or FunctionDeclaration to a statement list,
* returning the statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
*/
function appendExportsOfHoistedDeclaration(statements, decl) {
if (moduleInfo.exportEquals) {
return statements;
}
var excludeName;
if (ts.hasModifier(decl, 1 /* Export */)) {
var exportName = ts.hasModifier(decl, 512 /* Default */) ? ts.createLiteral("default") : decl.name;
statements = appendExportStatement(statements, exportName, ts.getLocalName(decl));
excludeName = exportName.text;
}
if (decl.name) {
statements = appendExportsOfDeclaration(statements, decl, excludeName);
}
return statements;
}
/**
* Appends the exports of a declaration to a statement list, returning the statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration to export.
* @param excludeName An optional name to exclude from exports.
*/
function appendExportsOfDeclaration(statements, decl, excludeName) {
if (moduleInfo.exportEquals) {
return statements;
}
var name = ts.getDeclarationName(decl);
var exportSpecifiers = moduleInfo.exportSpecifiers[name.text];
if (exportSpecifiers) {
for (var _i = 0, exportSpecifiers_1 = exportSpecifiers; _i < exportSpecifiers_1.length; _i++) {
var exportSpecifier = exportSpecifiers_1[_i];
if (exportSpecifier.name.text !== excludeName) {
statements = appendExportStatement(statements, exportSpecifier.name, name);
}
}
}
return statements;
}
/**
* Appends the down-level representation of an export to a statement list, returning the
* statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param exportName The name of the export.
* @param expression The expression to export.
* @param allowComments Whether to allow comments on the export.
*/
function appendExportStatement(statements, exportName, expression, allowComments) {
statements = ts.append(statements, createExportStatement(exportName, expression, allowComments));
return statements;
}
/**
* Creates a call to the current file's export function to export a value.
*
* @param name The bound name of the export.
* @param value The exported value.
* @param allowComments An optional value indicating whether to emit comments for the statement.
*/
function createExportStatement(name, value, allowComments) {
var statement = ts.createStatement(createExportExpression(name, value));
ts.startOnNewLine(statement);
if (!allowComments) {
ts.setEmitFlags(statement, 49152 /* NoComments */);
}
return statement;
}
/**
* Creates a call to the current file's export function to export a value.
*
* @param name The bound name of the export.
* @param value The exported value.
*/
function createExportExpression(name, value) {
var exportName = ts.isIdentifier(name) ? ts.createLiteral(name) : name;
return ts.createCall(exportFunction, /*typeArguments*/ undefined, [exportName, value]);
}
//
// Top-Level or Nested Source Element Visitors
//
/**
* Visit nested elements at the top-level of a module.
*
* @param node The node to visit.
*/
function nestedElementVisitor(node) {
switch (node.kind) {
case 205 /* VariableStatement */:
return visitVariableStatement(node);
case 225 /* FunctionDeclaration */:
return visitFunctionDeclaration(node);
case 226 /* ClassDeclaration */:
return visitClassDeclaration(node);
case 211 /* ForStatement */:
return visitForStatement(node);
case 212 /* ForInStatement */:
return visitForInStatement(node);
case 213 /* ForOfStatement */:
return visitForOfStatement(node);
case 209 /* DoStatement */:
return visitDoStatement(node);
case 210 /* WhileStatement */:
return visitWhileStatement(node);
case 219 /* LabeledStatement */:
return visitLabeledStatement(node);
case 217 /* WithStatement */:
return visitWithStatement(node);
case 218 /* SwitchStatement */:
return visitSwitchStatement(node);
case 232 /* CaseBlock */:
return visitCaseBlock(node);
case 253 /* CaseClause */:
return visitCaseClause(node);
case 254 /* DefaultClause */:
return visitDefaultClause(node);
case 221 /* TryStatement */:
return visitTryStatement(node);
case 256 /* CatchClause */:
return visitCatchClause(node);
case 204 /* Block */:
return visitBlock(node);
case 294 /* MergeDeclarationMarker */:
return visitMergeDeclarationMarker(node);
case 295 /* EndOfDeclarationMarker */:
return visitEndOfDeclarationMarker(node);
default:
return destructuringVisitor(node);
}
}
/**
* Visits the body of a ForStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitForStatement(node) {
var savedEnclosingBlockScopedContainer = enclosingBlockScopedContainer;
enclosingBlockScopedContainer = node;
node = ts.updateFor(node, visitForInitializer(node.initializer), ts.visitNode(node.condition, destructuringVisitor, ts.isExpression, /*optional*/ true), ts.visitNode(node.incrementor, destructuringVisitor, ts.isExpression, /*optional*/ true), ts.visitNode(node.statement, nestedElementVisitor, ts.isStatement));
enclosingBlockScopedContainer = savedEnclosingBlockScopedContainer;
return node;
}
/**
* Visits the body of a ForInStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitForInStatement(node) {
var savedEnclosingBlockScopedContainer = enclosingBlockScopedContainer;
enclosingBlockScopedContainer = node;
node = ts.updateForIn(node, visitForInitializer(node.initializer), ts.visitNode(node.expression, destructuringVisitor, ts.isExpression), ts.visitNode(node.statement, nestedElementVisitor, ts.isStatement, /*optional*/ false, ts.liftToBlock));
enclosingBlockScopedContainer = savedEnclosingBlockScopedContainer;
return node;
}
/**
* Visits the body of a ForOfStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitForOfStatement(node) {
var savedEnclosingBlockScopedContainer = enclosingBlockScopedContainer;
enclosingBlockScopedContainer = node;
node = ts.updateForOf(node, visitForInitializer(node.initializer), ts.visitNode(node.expression, destructuringVisitor, ts.isExpression), ts.visitNode(node.statement, nestedElementVisitor, ts.isStatement, /*optional*/ false, ts.liftToBlock));
enclosingBlockScopedContainer = savedEnclosingBlockScopedContainer;
return node;
}
/**
* Determines whether to hoist the initializer of a ForStatement, ForInStatement, or
* ForOfStatement.
*
* @param node The node to test.
*/
function shouldHoistForInitializer(node) {
return ts.isVariableDeclarationList(node)
&& shouldHoistVariableDeclarationList(node);
}
/**
* Visits the initializer of a ForStatement, ForInStatement, or ForOfStatement
*
* @param node The node to visit.
*/
function visitForInitializer(node) {
if (shouldHoistForInitializer(node)) {
var expressions = void 0;
for (var _i = 0, _a = node.declarations; _i < _a.length; _i++) {
var variable = _a[_i];
expressions = ts.append(expressions, transformInitializedVariable(variable, /*isExportedDeclaration*/ false));
}
return expressions ? ts.inlineExpressions(expressions) : ts.createOmittedExpression();
}
else {
return ts.visitEachChild(node, nestedElementVisitor, context);
}
}
/**
* Visits the body of a DoStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitDoStatement(node) {
return ts.updateDo(node, ts.visitNode(node.statement, nestedElementVisitor, ts.isStatement, /*optional*/ false, ts.liftToBlock), ts.visitNode(node.expression, destructuringVisitor, ts.isExpression));
}
/**
* Visits the body of a WhileStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitWhileStatement(node) {
return ts.updateWhile(node, ts.visitNode(node.expression, destructuringVisitor, ts.isExpression), ts.visitNode(node.statement, nestedElementVisitor, ts.isStatement, /*optional*/ false, ts.liftToBlock));
}
/**
* Visits the body of a LabeledStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitLabeledStatement(node) {
return ts.updateLabel(node, node.label, ts.visitNode(node.statement, nestedElementVisitor, ts.isStatement, /*optional*/ false, ts.liftToBlock));
}
/**
* Visits the body of a WithStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitWithStatement(node) {
return ts.updateWith(node, ts.visitNode(node.expression, destructuringVisitor, ts.isExpression), ts.visitNode(node.statement, nestedElementVisitor, ts.isStatement, /*optional*/ false, ts.liftToBlock));
}
/**
* Visits the body of a SwitchStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitSwitchStatement(node) {
return ts.updateSwitch(node, ts.visitNode(node.expression, destructuringVisitor, ts.isExpression), ts.visitNode(node.caseBlock, nestedElementVisitor, ts.isCaseBlock));
}
/**
* Visits the body of a CaseBlock to hoist declarations.
*
* @param node The node to visit.
*/
function visitCaseBlock(node) {
var savedEnclosingBlockScopedContainer = enclosingBlockScopedContainer;
enclosingBlockScopedContainer = node;
node = ts.updateCaseBlock(node, ts.visitNodes(node.clauses, nestedElementVisitor, ts.isCaseOrDefaultClause));
enclosingBlockScopedContainer = savedEnclosingBlockScopedContainer;
return node;
}
/**
* Visits the body of a CaseClause to hoist declarations.
*
* @param node The node to visit.
*/
function visitCaseClause(node) {
return ts.updateCaseClause(node, ts.visitNode(node.expression, destructuringVisitor, ts.isExpression), ts.visitNodes(node.statements, nestedElementVisitor, ts.isStatement));
}
/**
* Visits the body of a DefaultClause to hoist declarations.
*
* @param node The node to visit.
*/
function visitDefaultClause(node) {
return ts.visitEachChild(node, nestedElementVisitor, context);
}
/**
* Visits the body of a TryStatement to hoist declarations.
*
* @param node The node to visit.
*/
function visitTryStatement(node) {
return ts.visitEachChild(node, nestedElementVisitor, context);
}
/**
* Visits the body of a CatchClause to hoist declarations.
*
* @param node The node to visit.
*/
function visitCatchClause(node) {
var savedEnclosingBlockScopedContainer = enclosingBlockScopedContainer;
enclosingBlockScopedContainer = node;
node = ts.updateCatchClause(node, node.variableDeclaration, ts.visitNode(node.block, nestedElementVisitor, ts.isBlock));
enclosingBlockScopedContainer = savedEnclosingBlockScopedContainer;
return node;
}
/**
* Visits the body of a Block to hoist declarations.
*
* @param node The node to visit.
*/
function visitBlock(node) {
var savedEnclosingBlockScopedContainer = enclosingBlockScopedContainer;
enclosingBlockScopedContainer = node;
node = ts.visitEachChild(node, nestedElementVisitor, context);
enclosingBlockScopedContainer = savedEnclosingBlockScopedContainer;
return node;
}
//
// Destructuring Assignment Visitors
//
/**
* Visit nodes to flatten destructuring assignments to exported symbols.
*
* @param node The node to visit.
*/
function destructuringVisitor(node) {
if (node.transformFlags & 16384 /* DestructuringAssignment */
&& node.kind === 192 /* BinaryExpression */) {
return visitDestructuringAssignment(node);
}
else if (node.transformFlags & 32768 /* ContainsDestructuringAssignment */) {
return ts.visitEachChild(node, destructuringVisitor, context);
}
else {
return node;
}
}
/**
* Visits a DestructuringAssignment to flatten destructuring to exported symbols.
*
* @param node The node to visit.
*/
function visitDestructuringAssignment(node) {
if (hasExportedReferenceInDestructuringTarget(node.left)) {
return ts.flattenDestructuringAssignment(context, node, /*needsValue*/ true, hoistVariableDeclaration, destructuringVisitor);
}
return ts.visitEachChild(node, destructuringVisitor, context);
}
/**
* Determines whether the target of a destructuring assigment refers to an exported symbol.
*
* @param node The destructuring target.
*/
function hasExportedReferenceInDestructuringTarget(node) {
if (ts.isAssignmentExpression(node)) {
return hasExportedReferenceInDestructuringTarget(node.left);
}
else if (ts.isSpreadExpression(node)) {
return hasExportedReferenceInDestructuringTarget(node.expression);
}
else if (ts.isObjectLiteralExpression(node)) {
return ts.some(node.properties, hasExportedReferenceInDestructuringTarget);
}
else if (ts.isArrayLiteralExpression(node)) {
return ts.some(node.elements, hasExportedReferenceInDestructuringTarget);
}
else if (ts.isShorthandPropertyAssignment(node)) {
return hasExportedReferenceInDestructuringTarget(node.name);
}
else if (ts.isPropertyAssignment(node)) {
return hasExportedReferenceInDestructuringTarget(node.initializer);
}
else if (ts.isIdentifier(node)) {
var container = resolver.getReferencedExportContainer(node);
return container !== undefined && container.kind === 261 /* SourceFile */;
}
else {
return false;
}
}
//
// Modifier Visitors
//
/**
* Visit nodes to elide module-specific modifiers.
*
* @param node The node to visit.
*/
function modifierVisitor(node) {
switch (node.kind) {
case 83 /* ExportKeyword */:
case 78 /* DefaultKeyword */:
return undefined;
}
return node;
}
//
// Emit Notification
//
/**
* Hook for node emit notifications.
*
* @param emitContext A context hint for the emitter.
* @param node The node to emit.
* @param emit A callback used to emit the node in the printer.
*/
function onEmitNode(emitContext, node, emitCallback) {
if (node.kind === 261 /* SourceFile */) {
var id = ts.getOriginalNodeId(node);
currentSourceFile = node;
moduleInfo = moduleInfoMap[id];
exportFunction = exportFunctionsMap[id];
noSubstitution = noSubstitutionMap[id];
if (noSubstitution) {
delete noSubstitutionMap[id];
}
previousOnEmitNode(emitContext, node, emitCallback);
currentSourceFile = undefined;
moduleInfo = undefined;
exportFunction = undefined;
noSubstitution = undefined;
}
else {
previousOnEmitNode(emitContext, node, emitCallback);
}
}
//
// Substitutions
//
/**
* Hooks node substitutions.
*
* @param emitContext A context hint for the emitter.
* @param node The node to substitute.
*/
function onSubstituteNode(emitContext, node) {
node = previousOnSubstituteNode(emitContext, node);
if (isSubstitutionPrevented(node)) {
return node;
}
if (emitContext === 1 /* Expression */) {
return substituteExpression(node);
}
return node;
}
/**
* Substitute the expression, if necessary.
*
* @param node The node to substitute.
*/
function substituteExpression(node) {
switch (node.kind) {
case 70 /* Identifier */:
return substituteExpressionIdentifier(node);
case 192 /* BinaryExpression */:
return substituteBinaryExpression(node);
case 190 /* PrefixUnaryExpression */:
case 191 /* PostfixUnaryExpression */:
return substituteUnaryExpression(node);
}
return node;
}
/**
* Substitution for an Identifier expression that may contain an imported or exported symbol.
*
* @param node The node to substitute.
*/
function substituteExpressionIdentifier(node) {
// When we see an identifier in an expression position that
// points to an imported symbol, we should substitute a qualified
// reference to the imported symbol if one is needed.
//
// - We do not substitute generated identifiers for any reason.
// - We do not substitute identifiers tagged with the LocalName flag.
if (!ts.isGeneratedIdentifier(node) && !ts.isLocalName(node)) {
var importDeclaration = resolver.getReferencedImportDeclaration(node);
if (importDeclaration) {
if (ts.isImportClause(importDeclaration)) {
return ts.createPropertyAccess(ts.getGeneratedNameForNode(importDeclaration.parent), ts.createIdentifier("default"),
/*location*/ node);
}
else if (ts.isImportSpecifier(importDeclaration)) {
return ts.createPropertyAccess(ts.getGeneratedNameForNode(importDeclaration.parent.parent.parent), ts.getSynthesizedClone(importDeclaration.propertyName || importDeclaration.name),
/*location*/ node);
}
}
}
return node;
}
/**
* Substitution for a BinaryExpression that may contain an imported or exported symbol.
*
* @param node The node to substitute.
*/
function substituteBinaryExpression(node) {
// When we see an assignment expression whose left-hand side is an exported symbol,
// we should ensure all exports of that symbol are updated with the correct value.
//
// - We do not substitute generated identifiers for any reason.
// - We do not substitute identifiers tagged with the LocalName flag.
// - We do not substitute identifiers that were originally the name of an enum or
// namespace due to how they are transformed in TypeScript.
// - We only substitute identifiers that are exported at the top level.
if (ts.isAssignmentOperator(node.operatorToken.kind)
&& ts.isIdentifier(node.left)
&& !ts.isGeneratedIdentifier(node.left)
&& !ts.isLocalName(node.left)
&& !ts.isDeclarationNameOfEnumOrNamespace(node.left)) {
var exportedNames = getExports(node.left);
if (exportedNames) {
// For each additional export of the declaration, apply an export assignment.
var expression = node;
for (var _i = 0, exportedNames_1 = exportedNames; _i < exportedNames_1.length; _i++) {
var exportName = exportedNames_1[_i];
expression = createExportExpression(exportName, preventSubstitution(expression));
}
return expression;
}
}
return node;
}
/**
* Substitution for a UnaryExpression that may contain an imported or exported symbol.
*
* @param node The node to substitute.
*/
function substituteUnaryExpression(node) {
// When we see a prefix or postfix increment expression whose operand is an exported
// symbol, we should ensure all exports of that symbol are updated with the correct
// value.
//
// - We do not substitute generated identifiers for any reason.
// - We do not substitute identifiers tagged with the LocalName flag.
// - We do not substitute identifiers that were originally the name of an enum or
// namespace due to how they are transformed in TypeScript.
// - We only substitute identifiers that are exported at the top level.
if ((node.operator === 42 /* PlusPlusToken */ || node.operator === 43 /* MinusMinusToken */)
&& ts.isIdentifier(node.operand)
&& !ts.isGeneratedIdentifier(node.operand)
&& !ts.isLocalName(node.operand)
&& !ts.isDeclarationNameOfEnumOrNamespace(node.operand)) {
var exportedNames = getExports(node.operand);
if (exportedNames) {
var expression = node.kind === 191 /* PostfixUnaryExpression */
? ts.createPrefix(node.operator, node.operand,
/*location*/ node)
: node;
for (var _i = 0, exportedNames_2 = exportedNames; _i < exportedNames_2.length; _i++) {
var exportName = exportedNames_2[_i];
expression = createExportExpression(exportName, preventSubstitution(expression));
}
if (node.kind === 191 /* PostfixUnaryExpression */) {
expression = node.operator === 42 /* PlusPlusToken */
? ts.createSubtract(preventSubstitution(expression), ts.createLiteral(1))
: ts.createAdd(preventSubstitution(expression), ts.createLiteral(1));
}
return expression;
}
}
return node;
}
/**
* Gets the exports of a name.
*
* @param name The name.
*/
function getExports(name) {
var exportedNames;
if (!ts.isGeneratedIdentifier(name)) {
var valueDeclaration = resolver.getReferencedImportDeclaration(name)
|| resolver.getReferencedValueDeclaration(name);
if (valueDeclaration) {
var exportContainer = resolver.getReferencedExportContainer(name, /*prefixLocals*/ false);
if (exportContainer && exportContainer.kind === 261 /* SourceFile */) {
exportedNames = ts.append(exportedNames, ts.getDeclarationName(valueDeclaration));
}
exportedNames = ts.addRange(exportedNames, moduleInfo && moduleInfo.exportedBindings[ts.getOriginalNodeId(valueDeclaration)]);
}
}
return exportedNames;
}
/**
* Prevent substitution of a node for this transformer.
*
* @param node The node which should not be substituted.
*/
function preventSubstitution(node) {
if (noSubstitution === undefined)
noSubstitution = ts.createMap();
noSubstitution[ts.getNodeId(node)] = true;
return node;
}
/**
* Determines whether a node should not be substituted.
*
* @param node The node to test.
*/
function isSubstitutionPrevented(node) {
return noSubstitution && node.id && noSubstitution[node.id];
}
}
ts.transformSystemModule = transformSystemModule;
})(ts || (ts = {}));
/// <reference path="../../factory.ts" />
/// <reference path="../../visitor.ts" />
/*@internal*/
var ts;
(function (ts) {
function transformModule(context) {
var transformModuleDelegates = ts.createMap((_a = {},
_a[ts.ModuleKind.None] = transformCommonJSModule,
_a[ts.ModuleKind.CommonJS] = transformCommonJSModule,
_a[ts.ModuleKind.AMD] = transformAMDModule,
_a[ts.ModuleKind.UMD] = transformUMDModule,
_a));
var startLexicalEnvironment = context.startLexicalEnvironment, endLexicalEnvironment = context.endLexicalEnvironment, hoistVariableDeclaration = context.hoistVariableDeclaration;
var compilerOptions = context.getCompilerOptions();
var resolver = context.getEmitResolver();
var host = context.getEmitHost();
var languageVersion = ts.getEmitScriptTarget(compilerOptions);
var moduleKind = ts.getEmitModuleKind(compilerOptions);
var previousOnSubstituteNode = context.onSubstituteNode;
var previousOnEmitNode = context.onEmitNode;
context.onSubstituteNode = onSubstituteNode;
context.onEmitNode = onEmitNode;
context.enableSubstitution(70 /* Identifier */); // Substitutes expression identifiers with imported/exported symbols.
context.enableSubstitution(192 /* BinaryExpression */); // Substitutes assignments to exported symbols.
context.enableSubstitution(190 /* PrefixUnaryExpression */); // Substitutes updates to exported symbols.
context.enableSubstitution(191 /* PostfixUnaryExpression */); // Substitutes updates to exported symbols.
context.enableSubstitution(258 /* ShorthandPropertyAssignment */); // Substitutes shorthand property assignments for imported/exported symbols.
context.enableEmitNotification(261 /* SourceFile */); // Restore state when substituting nodes in a file.
var moduleInfoMap = ts.createMap(); // The ExternalModuleInfo for each file.
var deferredExports = ts.createMap(); // Exports to defer until an EndOfDeclarationMarker is found.
var currentSourceFile; // The current file.
var currentModuleInfo; // The ExternalModuleInfo for the current file.
var noSubstitution; // Set of nodes for which substitution rules should be ignored.
return transformSourceFile;
/**
* Transforms the module aspects of a SourceFile.
*
* @param node The SourceFile node.
*/
function transformSourceFile(node) {
if (ts.isDeclarationFile(node)
|| !(ts.isExternalModule(node)
|| compilerOptions.isolatedModules)) {
return node;
}
currentSourceFile = node;
currentModuleInfo = moduleInfoMap[ts.getOriginalNodeId(node)] = ts.collectExternalModuleInfo(node, resolver);
// Perform the transformation.
var transformModule = transformModuleDelegates[moduleKind] || transformModuleDelegates[ts.ModuleKind.None];
var updated = transformModule(node);
currentSourceFile = undefined;
currentModuleInfo = undefined;
return ts.aggregateTransformFlags(updated);
}
/**
* Transforms a SourceFile into a CommonJS module.
*
* @param node The SourceFile node.
*/
function transformCommonJSModule(node) {
startLexicalEnvironment();
var statements = [];
var statementOffset = ts.addPrologueDirectives(statements, node.statements, /*ensureUseStrict*/ !compilerOptions.noImplicitUseStrict, sourceElementVisitor);
ts.addRange(statements, ts.visitNodes(node.statements, sourceElementVisitor, ts.isStatement, statementOffset));
ts.addRange(statements, endLexicalEnvironment());
addExportEqualsIfNeeded(statements, /*emitAsReturn*/ false);
var updated = ts.updateSourceFileNode(node, ts.createNodeArray(statements, node.statements));
if (currentModuleInfo.hasExportStarsToExportValues) {
ts.setEmitFlags(updated, 2 /* EmitExportStar */ | ts.getEmitFlags(node));
}
return updated;
}
/**
* Transforms a SourceFile into an AMD module.
*
* @param node The SourceFile node.
*/
function transformAMDModule(node) {
var define = ts.createIdentifier("define");
var moduleName = ts.tryGetModuleNameFromFile(node, host, compilerOptions);
return transformAsynchronousModule(node, define, moduleName, /*includeNonAmdDependencies*/ true);
}
/**
* Transforms a SourceFile into a UMD module.
*
* @param node The SourceFile node.
*/
function transformUMDModule(node) {
var define = ts.createIdentifier("define");
ts.setEmitFlags(define, 16 /* UMDDefine */);
return transformAsynchronousModule(node, define, /*moduleName*/ undefined, /*includeNonAmdDependencies*/ false);
}
/**
* Transforms a SourceFile into an AMD or UMD module.
*
* @param node The SourceFile node.
* @param define The expression used to define the module.
* @param moduleName An expression for the module name, if available.
* @param includeNonAmdDependencies A value indicating whether to incldue any non-AMD dependencies.
*/
function transformAsynchronousModule(node, define, moduleName, includeNonAmdDependencies) {
// An AMD define function has the following shape:
//
// define(id?, dependencies?, factory);
//
// This has the shape of the following:
//
// define(name, ["module1", "module2"], function (module1Alias) { ... }
//
// The location of the alias in the parameter list in the factory function needs to
// match the position of the module name in the dependency list.
//
// To ensure this is true in cases of modules with no aliases, e.g.:
//
// import "module"
//
// or
//
// /// <amd-dependency path= "a.css" />
//
// we need to add modules without alias names to the end of the dependencies list
var _a = collectAsynchronousDependencies(node, includeNonAmdDependencies), aliasedModuleNames = _a.aliasedModuleNames, unaliasedModuleNames = _a.unaliasedModuleNames, importAliasNames = _a.importAliasNames;
// Create an updated SourceFile:
//
// define(moduleName?, ["module1", "module2"], function ...
return ts.updateSourceFileNode(node, ts.createNodeArray([
ts.createStatement(ts.createCall(define,
/*typeArguments*/ undefined, (moduleName ? [moduleName] : []).concat([
// Add the dependency array argument:
//
// ["require", "exports", module1", "module2", ...]
ts.createArrayLiteral([
ts.createLiteral("require"),
ts.createLiteral("exports")
].concat(aliasedModuleNames, unaliasedModuleNames)),
// Add the module body function argument:
//
// function (require, exports, module1, module2) ...
ts.createFunctionExpression(
/*modifiers*/ undefined,
/*asteriskToken*/ undefined,
/*name*/ undefined,
/*typeParameters*/ undefined, [
ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "require"),
ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, "exports")
].concat(importAliasNames),
/*type*/ undefined, transformAsynchronousModuleBody(node))
])))
],
/*location*/ node.statements));
}
/**
* Collect the additional asynchronous dependencies for the module.
*
* @param node The source file.
* @param includeNonAmdDependencies A value indicating whether to include non-AMD dependencies.
*/
function collectAsynchronousDependencies(node, includeNonAmdDependencies) {
// names of modules with corresponding parameter in the factory function
var aliasedModuleNames = [];
// names of modules with no corresponding parameters in factory function
var unaliasedModuleNames = [];
// names of the parameters in the factory function; these
// parameters need to match the indexes of the corresponding
// module names in aliasedModuleNames.
var importAliasNames = [];
// Fill in amd-dependency tags
for (var _i = 0, _a = node.amdDependencies; _i < _a.length; _i++) {
var amdDependency = _a[_i];
if (amdDependency.name) {
aliasedModuleNames.push(ts.createLiteral(amdDependency.path));
importAliasNames.push(ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, amdDependency.name));
}
else {
unaliasedModuleNames.push(ts.createLiteral(amdDependency.path));
}
}
for (var _b = 0, _c = currentModuleInfo.externalImports; _b < _c.length; _b++) {
var importNode = _c[_b];
// Find the name of the external module
var externalModuleName = ts.getExternalModuleNameLiteral(importNode, currentSourceFile, host, resolver, compilerOptions);
// Find the name of the module alias, if there is one
var importAliasName = ts.getLocalNameForExternalImport(importNode, currentSourceFile);
if (includeNonAmdDependencies && importAliasName) {
// Set emitFlags on the name of the classDeclaration
// This is so that when printer will not substitute the identifier
ts.setEmitFlags(importAliasName, 128 /* NoSubstitution */);
aliasedModuleNames.push(externalModuleName);
importAliasNames.push(ts.createParameter(/*decorators*/ undefined, /*modifiers*/ undefined, /*dotDotDotToken*/ undefined, importAliasName));
}
else {
unaliasedModuleNames.push(externalModuleName);
}
}
return { aliasedModuleNames: aliasedModuleNames, unaliasedModuleNames: unaliasedModuleNames, importAliasNames: importAliasNames };
}
/**
* Transforms a SourceFile into an AMD or UMD module body.
*
* @param node The SourceFile node.
*/
function transformAsynchronousModuleBody(node) {
startLexicalEnvironment();
var statements = [];
var statementOffset = ts.addPrologueDirectives(statements, node.statements, /*ensureUseStrict*/ !compilerOptions.noImplicitUseStrict, sourceElementVisitor);
// Visit each statement of the module body.
ts.addRange(statements, ts.visitNodes(node.statements, sourceElementVisitor, ts.isStatement, statementOffset));
// End the lexical environment for the module body
// and merge any new lexical declarations.
ts.addRange(statements, endLexicalEnvironment());
// Append the 'export =' statement if provided.
addExportEqualsIfNeeded(statements, /*emitAsReturn*/ true);
var body = ts.createBlock(statements, /*location*/ undefined, /*multiLine*/ true);
if (currentModuleInfo.hasExportStarsToExportValues) {
// If we have any `export * from ...` declarations
// we need to inform the emitter to add the __export helper.
ts.setEmitFlags(body, 2 /* EmitExportStar */);
}
return body;
}
/**
* Adds the down-level representation of `export=` to the statement list if one exists
* in the source file.
*
* @param statements The Statement list to modify.
* @param emitAsReturn A value indicating whether to emit the `export=` statement as a
* return statement.
*/
function addExportEqualsIfNeeded(statements, emitAsReturn) {
if (currentModuleInfo.exportEquals) {
if (emitAsReturn) {
var statement = ts.createReturn(currentModuleInfo.exportEquals.expression,
/*location*/ currentModuleInfo.exportEquals);
ts.setEmitFlags(statement, 12288 /* NoTokenSourceMaps */ | 49152 /* NoComments */);
statements.push(statement);
}
else {
var statement = ts.createStatement(ts.createAssignment(ts.createPropertyAccess(ts.createIdentifier("module"), "exports"), currentModuleInfo.exportEquals.expression),
/*location*/ currentModuleInfo.exportEquals);
ts.setEmitFlags(statement, 49152 /* NoComments */);
statements.push(statement);
}
}
}
//
// Top-Level Source Element Visitors
//
/**
* Visits a node at the top level of the source file.
*
* @param node The node to visit.
*/
function sourceElementVisitor(node) {
switch (node.kind) {
case 235 /* ImportDeclaration */:
return visitImportDeclaration(node);
case 234 /* ImportEqualsDeclaration */:
return visitImportEqualsDeclaration(node);
case 241 /* ExportDeclaration */:
return visitExportDeclaration(node);
case 240 /* ExportAssignment */:
return visitExportAssignment(node);
case 205 /* VariableStatement */:
return visitVariableStatement(node);
case 225 /* FunctionDeclaration */:
return visitFunctionDeclaration(node);
case 226 /* ClassDeclaration */:
return visitClassDeclaration(node);
case 294 /* MergeDeclarationMarker */:
return visitMergeDeclarationMarker(node);
case 295 /* EndOfDeclarationMarker */:
return visitEndOfDeclarationMarker(node);
default:
// This visitor does not descend into the tree, as export/import statements
// are only transformed at the top level of a file.
return node;
}
}
/**
* Visits an ImportDeclaration node.
*
* @param node The node to visit.
*/
function visitImportDeclaration(node) {
var statements;
var namespaceDeclaration = ts.getNamespaceDeclarationNode(node);
if (moduleKind !== ts.ModuleKind.AMD) {
if (!node.importClause) {
// import "mod";
return ts.createStatement(createRequireCall(node), /*location*/ node);
}
else {
var variables = [];
if (namespaceDeclaration && !ts.isDefaultImport(node)) {
// import * as n from "mod";
variables.push(ts.createVariableDeclaration(ts.getSynthesizedClone(namespaceDeclaration.name),
/*type*/ undefined, createRequireCall(node)));
}
else {
// import d from "mod";
// import { x, y } from "mod";
// import d, { x, y } from "mod";
// import d, * as n from "mod";
variables.push(ts.createVariableDeclaration(ts.getGeneratedNameForNode(node),
/*type*/ undefined, createRequireCall(node)));
if (namespaceDeclaration && ts.isDefaultImport(node)) {
variables.push(ts.createVariableDeclaration(ts.getSynthesizedClone(namespaceDeclaration.name),
/*type*/ undefined, ts.getGeneratedNameForNode(node)));
}
}
statements = ts.append(statements, ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList(variables,
/*location*/ undefined, languageVersion >= 2 /* ES2015 */ ? 2 /* Const */ : 0 /* None */),
/*location*/ node));
}
}
else if (namespaceDeclaration && ts.isDefaultImport(node)) {
// import d, * as n from "mod";
statements = ts.append(statements, ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList([
ts.createVariableDeclaration(ts.getSynthesizedClone(namespaceDeclaration.name),
/*type*/ undefined, ts.getGeneratedNameForNode(node),
/*location*/ node)
],
/*location*/ undefined, languageVersion >= 2 /* ES2015 */ ? 2 /* Const */ : 0 /* None */)));
}
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfImportDeclaration(deferredExports[id], node);
}
else {
statements = appendExportsOfImportDeclaration(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Creates a `require()` call to import an external module.
*
* @param importNode The declararation to import.
*/
function createRequireCall(importNode) {
var moduleName = ts.getExternalModuleNameLiteral(importNode, currentSourceFile, host, resolver, compilerOptions);
var args = [];
if (moduleName) {
args.push(moduleName);
}
return ts.createCall(ts.createIdentifier("require"), /*typeArguments*/ undefined, args);
}
/**
* Visits an ImportEqualsDeclaration node.
*
* @param node The node to visit.
*/
function visitImportEqualsDeclaration(node) {
ts.Debug.assert(ts.isExternalModuleImportEqualsDeclaration(node), "import= for internal module references should be handled in an earlier transformer.");
var statements;
if (moduleKind !== ts.ModuleKind.AMD) {
if (ts.hasModifier(node, 1 /* Export */)) {
statements = ts.append(statements, ts.createStatement(createExportExpression(node.name, createRequireCall(node)),
/*location*/ node));
}
else {
statements = ts.append(statements, ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList([
ts.createVariableDeclaration(ts.getSynthesizedClone(node.name),
/*type*/ undefined, createRequireCall(node))
],
/*location*/ undefined,
/*flags*/ languageVersion >= 2 /* ES2015 */ ? 2 /* Const */ : 0 /* None */),
/*location*/ node));
}
}
else {
if (ts.hasModifier(node, 1 /* Export */)) {
statements = ts.append(statements, ts.createStatement(createExportExpression(ts.getExportName(node), ts.getLocalName(node)),
/*location*/ node));
}
}
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfImportEqualsDeclaration(deferredExports[id], node);
}
else {
statements = appendExportsOfImportEqualsDeclaration(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Visits an ExportDeclaration node.
*
* @param The node to visit.
*/
function visitExportDeclaration(node) {
if (!node.moduleSpecifier) {
// Elide export declarations with no module specifier as they are handled
// elsewhere.
return undefined;
}
var generatedName = ts.getGeneratedNameForNode(node);
if (node.exportClause) {
var statements = [];
// export { x, y } from "mod";
if (moduleKind !== ts.ModuleKind.AMD) {
statements.push(ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList([
ts.createVariableDeclaration(generatedName,
/*type*/ undefined, createRequireCall(node))
]),
/*location*/ node));
}
for (var _i = 0, _a = node.exportClause.elements; _i < _a.length; _i++) {
var specifier = _a[_i];
var exportedValue = ts.createPropertyAccess(generatedName, specifier.propertyName || specifier.name);
statements.push(ts.createStatement(createExportExpression(ts.getExportName(specifier), exportedValue),
/*location*/ specifier));
}
return ts.singleOrMany(statements);
}
else {
// export * from "mod";
return ts.createStatement(ts.createCall(ts.createIdentifier("__export"),
/*typeArguments*/ undefined, [
moduleKind !== ts.ModuleKind.AMD
? createRequireCall(node)
: generatedName
]),
/*location*/ node);
}
}
/**
* Visits an ExportAssignment node.
*
* @param node The node to visit.
*/
function visitExportAssignment(node) {
if (node.isExportEquals) {
return undefined;
}
var statements;
var original = node.original;
if (original && hasAssociatedEndOfDeclarationMarker(original)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportStatement(deferredExports[id], ts.createIdentifier("default"), node.expression, /*location*/ node, /*allowComments*/ true);
}
else {
statements = appendExportStatement(statements, ts.createIdentifier("default"), node.expression, /*location*/ node, /*allowComments*/ true);
}
return ts.singleOrMany(statements);
}
/**
* Visits a FunctionDeclaration node.
*
* @param node The node to visit.
*/
function visitFunctionDeclaration(node) {
var statements;
if (ts.hasModifier(node, 1 /* Export */)) {
statements = ts.append(statements, ts.setOriginalNode(ts.createFunctionDeclaration(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), node.asteriskToken, ts.getDeclarationName(node, /*allowComments*/ true, /*allowSourceMaps*/ true),
/*typeParameters*/ undefined, node.parameters,
/*type*/ undefined, node.body,
/*location*/ node),
/*original*/ node));
}
else {
statements = ts.append(statements, node);
}
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfHoistedDeclaration(deferredExports[id], node);
}
else {
statements = appendExportsOfHoistedDeclaration(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Visits a ClassDeclaration node.
*
* @param node The node to visit.
*/
function visitClassDeclaration(node) {
var statements;
if (ts.hasModifier(node, 1 /* Export */)) {
statements = ts.append(statements, ts.setOriginalNode(ts.createClassDeclaration(
/*decorators*/ undefined, ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier), ts.getDeclarationName(node, /*allowComments*/ true, /*allowSourceMaps*/ true),
/*typeParameters*/ undefined, node.heritageClauses, node.members,
/*location*/ node),
/*original*/ node));
}
else {
statements = ts.append(statements, node);
}
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfHoistedDeclaration(deferredExports[id], node);
}
else {
statements = appendExportsOfHoistedDeclaration(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Visits a VariableStatement node.
*
* @param node The node to visit.
*/
function visitVariableStatement(node) {
var statements;
var variables;
var expressions;
if (ts.hasModifier(node, 1 /* Export */)) {
var modifiers = void 0;
// If we're exporting these variables, then these just become assignments to 'exports.x'.
// We only want to emit assignments for variables with initializers.
for (var _i = 0, _a = node.declarationList.declarations; _i < _a.length; _i++) {
var variable = _a[_i];
if (ts.isIdentifier(variable.name) && ts.isLocalName(variable.name)) {
if (!modifiers) {
modifiers = ts.visitNodes(node.modifiers, modifierVisitor, ts.isModifier);
}
variables = ts.append(variables, variable);
}
else if (variable.initializer) {
expressions = ts.append(expressions, transformInitializedVariable(variable));
}
}
if (variables) {
statements = ts.append(statements, ts.updateVariableStatement(node, modifiers, ts.updateVariableDeclarationList(node.declarationList, variables)));
}
if (expressions) {
statements = ts.append(statements, ts.createStatement(ts.inlineExpressions(expressions), /*location*/ node));
}
}
else {
statements = ts.append(statements, node);
}
if (hasAssociatedEndOfDeclarationMarker(node)) {
// Defer exports until we encounter an EndOfDeclarationMarker node
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfVariableStatement(deferredExports[id], node);
}
else {
statements = appendExportsOfVariableStatement(statements, node);
}
return ts.singleOrMany(statements);
}
/**
* Transforms an exported variable with an initializer into an expression.
*
* @param node The node to transform.
*/
function transformInitializedVariable(node) {
if (ts.isBindingPattern(node.name)) {
return ts.flattenVariableDestructuringToExpression(node, hoistVariableDeclaration, createExportExpression);
}
else {
return ts.createAssignment(ts.createPropertyAccess(ts.createIdentifier("exports"), node.name,
/*location*/ node.name), node.initializer);
}
}
/**
* Visits a MergeDeclarationMarker used as a placeholder for the beginning of a merged
* and transformed declaration.
*
* @param node The node to visit.
*/
function visitMergeDeclarationMarker(node) {
// For an EnumDeclaration or ModuleDeclaration that merges with a preceeding
// declaration we do not emit a leading variable declaration. To preserve the
// begin/end semantics of the declararation and to properly handle exports
// we wrapped the leading variable declaration in a `MergeDeclarationMarker`.
//
// To balance the declaration, add the exports of the elided variable
// statement.
if (hasAssociatedEndOfDeclarationMarker(node) && node.original.kind === 205 /* VariableStatement */) {
var id = ts.getOriginalNodeId(node);
deferredExports[id] = appendExportsOfVariableStatement(deferredExports[id], node.original);
}
return node;
}
/**
* Determines whether a node has an associated EndOfDeclarationMarker.
*
* @param node The node to test.
*/
function hasAssociatedEndOfDeclarationMarker(node) {
return (ts.getEmitFlags(node) & 33554432 /* HasEndOfDeclarationMarker */) !== 0;
}
/**
* Visits a DeclarationMarker used as a placeholder for the end of a transformed
* declaration.
*
* @param node The node to visit.
*/
function visitEndOfDeclarationMarker(node) {
// For some transformations we emit an `EndOfDeclarationMarker` to mark the actual
// end of the transformed declaration. We use this marker to emit any deferred exports
// of the declaration.
var id = ts.getOriginalNodeId(node);
var statements = deferredExports[id];
if (statements) {
delete deferredExports[id];
return ts.append(statements, node);
}
return node;
}
/**
* Appends the exports of an ImportDeclaration to a statement list, returning the
* statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
*/
function appendExportsOfImportDeclaration(statements, decl) {
if (currentModuleInfo.exportEquals) {
return statements;
}
var importClause = decl.importClause;
if (!importClause) {
return statements;
}
if (importClause.name) {
statements = appendExportsOfDeclaration(statements, importClause);
}
var namedBindings = importClause.namedBindings;
if (namedBindings) {
switch (namedBindings.kind) {
case 237 /* NamespaceImport */:
statements = appendExportsOfDeclaration(statements, namedBindings);
break;
case 238 /* NamedImports */:
for (var _i = 0, _a = namedBindings.elements; _i < _a.length; _i++) {
var importBinding = _a[_i];
statements = appendExportsOfDeclaration(statements, importBinding);
}
break;
}
}
return statements;
}
/**
* Appends the exports of an ImportEqualsDeclaration to a statement list, returning the
* statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
*/
function appendExportsOfImportEqualsDeclaration(statements, decl) {
if (currentModuleInfo.exportEquals) {
return statements;
}
return appendExportsOfDeclaration(statements, decl);
}
/**
* Appends the exports of a VariableStatement to a statement list, returning the statement
* list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param node The VariableStatement whose exports are to be recorded.
*/
function appendExportsOfVariableStatement(statements, node) {
if (currentModuleInfo.exportEquals) {
return statements;
}
for (var _i = 0, _a = node.declarationList.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
statements = appendExportsOfBindingElement(statements, decl);
}
return statements;
}
/**
* Appends the exports of a VariableDeclaration or BindingElement to a statement list,
* returning the statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
*/
function appendExportsOfBindingElement(statements, decl) {
if (currentModuleInfo.exportEquals) {
return statements;
}
if (ts.isBindingPattern(decl.name)) {
for (var _i = 0, _a = decl.name.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (!ts.isOmittedExpression(element)) {
statements = appendExportsOfBindingElement(statements, element);
}
}
}
else if (!ts.isGeneratedIdentifier(decl.name)) {
statements = appendExportsOfDeclaration(statements, decl);
}
return statements;
}
/**
* Appends the exports of a ClassDeclaration or FunctionDeclaration to a statement list,
* returning the statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration whose exports are to be recorded.
*/
function appendExportsOfHoistedDeclaration(statements, decl) {
if (currentModuleInfo.exportEquals) {
return statements;
}
if (ts.hasModifier(decl, 1 /* Export */)) {
var exportName = ts.hasModifier(decl, 512 /* Default */) ? ts.createIdentifier("default") : decl.name;
statements = appendExportStatement(statements, exportName, ts.getLocalName(decl), /*location*/ decl);
}
if (decl.name) {
statements = appendExportsOfDeclaration(statements, decl);
}
return statements;
}
/**
* Appends the exports of a declaration to a statement list, returning the statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param decl The declaration to export.
*/
function appendExportsOfDeclaration(statements, decl) {
var name = ts.getDeclarationName(decl);
var exportSpecifiers = currentModuleInfo.exportSpecifiers[name.text];
if (exportSpecifiers) {
for (var _i = 0, exportSpecifiers_2 = exportSpecifiers; _i < exportSpecifiers_2.length; _i++) {
var exportSpecifier = exportSpecifiers_2[_i];
statements = appendExportStatement(statements, exportSpecifier.name, name, /*location*/ exportSpecifier.name);
}
}
return statements;
}
/**
* Appends the down-level representation of an export to a statement list, returning the
* statement list.
*
* @param statements A statement list to which the down-level export statements are to be
* appended. If `statements` is `undefined`, a new array is allocated if statements are
* appended.
* @param exportName The name of the export.
* @param expression The expression to export.
* @param location The location to use for source maps and comments for the export.
* @param allowComments Whether to allow comments on the export.
*/
function appendExportStatement(statements, exportName, expression, location, allowComments) {
if (exportName.text === "default") {
var sourceFile = ts.getOriginalNode(currentSourceFile, ts.isSourceFile);
if (sourceFile && !sourceFile.symbol.exports["___esModule"]) {
if (languageVersion === 0 /* ES3 */) {
statements = ts.append(statements, ts.createStatement(createExportExpression(ts.createIdentifier("__esModule"), ts.createLiteral(true))));
}
else {
statements = ts.append(statements, ts.createStatement(ts.createCall(ts.createPropertyAccess(ts.createIdentifier("Object"), "defineProperty"),
/*typeArguments*/ undefined, [
ts.createIdentifier("exports"),
ts.createLiteral("__esModule"),
ts.createObjectLiteral([
ts.createPropertyAssignment("value", ts.createLiteral(true))
])
])));
}
}
}
statements = ts.append(statements, createExportStatement(exportName, expression, location, allowComments));
return statements;
}
/**
* Creates a call to the current file's export function to export a value.
*
* @param name The bound name of the export.
* @param value The exported value.
* @param location The location to use for source maps and comments for the export.
* @param allowComments An optional value indicating whether to emit comments for the statement.
*/
function createExportStatement(name, value, location, allowComments) {
var statement = ts.createStatement(createExportExpression(name, value), location);
ts.startOnNewLine(statement);
if (!allowComments) {
ts.setEmitFlags(statement, 49152 /* NoComments */);
}
return statement;
}
/**
* Creates a call to the current file's export function to export a value.
*
* @param name The bound name of the export.
* @param value The exported value.
* @param location The location to use for source maps and comments for the export.
*/
function createExportExpression(name, value, location) {
return ts.createAssignment(ts.createPropertyAccess(ts.createIdentifier("exports"), ts.getSynthesizedClone(name)), value, location);
}
//
// Modifier Visitors
//
/**
* Visit nodes to elide module-specific modifiers.
*
* @param node The node to visit.
*/
function modifierVisitor(node) {
// Elide module-specific modifiers.
switch (node.kind) {
case 83 /* ExportKeyword */:
case 78 /* DefaultKeyword */:
return undefined;
}
return node;
}
//
// Emit Notification
//
/**
* Hook for node emit notifications.
*
* @param emitContext A context hint for the emitter.
* @param node The node to emit.
* @param emit A callback used to emit the node in the printer.
*/
function onEmitNode(emitContext, node, emitCallback) {
if (node.kind === 261 /* SourceFile */) {
currentSourceFile = node;
currentModuleInfo = moduleInfoMap[ts.getOriginalNodeId(currentSourceFile)];
noSubstitution = ts.createMap();
previousOnEmitNode(emitContext, node, emitCallback);
currentSourceFile = undefined;
currentModuleInfo = undefined;
noSubstitution = undefined;
}
else {
previousOnEmitNode(emitContext, node, emitCallback);
}
}
//
// Substitutions
//
/**
* Hooks node substitutions.
*
* @param emitContext A context hint for the emitter.
* @param node The node to substitute.
*/
function onSubstituteNode(emitContext, node) {
node = previousOnSubstituteNode(emitContext, node);
if (node.id && noSubstitution[node.id]) {
return node;
}
if (emitContext === 1 /* Expression */) {
return substituteExpression(node);
}
else if (ts.isShorthandPropertyAssignment(node)) {
return substituteShorthandPropertyAssignment(node);
}
return node;
}
/**
* Substitution for a ShorthandPropertyAssignment whose declaration name is an imported
* or exported symbol.
*
* @param node The node to substitute.
*/
function substituteShorthandPropertyAssignment(node) {
var name = node.name;
var exportedOrImportedName = substituteExpressionIdentifier(name);
if (exportedOrImportedName !== name) {
// A shorthand property with an assignment initializer is probably part of a
// destructuring assignment
if (node.objectAssignmentInitializer) {
var initializer = ts.createAssignment(exportedOrImportedName, node.objectAssignmentInitializer);
return ts.createPropertyAssignment(name, initializer, /*location*/ node);
}
return ts.createPropertyAssignment(name, exportedOrImportedName, /*location*/ node);
}
return node;
}
/**
* Substitution for an Expression that may contain an imported or exported symbol.
*
* @param node The node to substitute.
*/
function substituteExpression(node) {
switch (node.kind) {
case 70 /* Identifier */:
return substituteExpressionIdentifier(node);
case 192 /* BinaryExpression */:
return substituteBinaryExpression(node);
case 191 /* PostfixUnaryExpression */:
case 190 /* PrefixUnaryExpression */:
return substituteUnaryExpression(node);
}
return node;
}
/**
* Substitution for an Identifier expression that may contain an imported or exported
* symbol.
*
* @param node The node to substitute.
*/
function substituteExpressionIdentifier(node) {
if (!ts.isGeneratedIdentifier(node) && !ts.isLocalName(node)) {
var exportContainer = resolver.getReferencedExportContainer(node, ts.isExportName(node));
if (exportContainer && exportContainer.kind === 261 /* SourceFile */) {
return ts.createPropertyAccess(ts.createIdentifier("exports"), ts.getSynthesizedClone(node),
/*location*/ node);
}
var importDeclaration = resolver.getReferencedImportDeclaration(node);
if (importDeclaration) {
if (ts.isImportClause(importDeclaration)) {
return ts.createPropertyAccess(ts.getGeneratedNameForNode(importDeclaration.parent), ts.createIdentifier("default"),
/*location*/ node);
}
else if (ts.isImportSpecifier(importDeclaration)) {
var name_36 = importDeclaration.propertyName || importDeclaration.name;
return ts.createPropertyAccess(ts.getGeneratedNameForNode(importDeclaration.parent.parent.parent), ts.getSynthesizedClone(name_36),
/*location*/ node);
}
}
}
return node;
}
/**
* Substitution for a BinaryExpression that may contain an imported or exported symbol.
*
* @param node The node to substitute.
*/
function substituteBinaryExpression(node) {
// When we see an assignment expression whose left-hand side is an exported symbol,
// we should ensure all exports of that symbol are updated with the correct value.
//
// - We do not substitute generated identifiers for any reason.
// - We do not substitute identifiers tagged with the LocalName flag.
// - We do not substitute identifiers that were originally the name of an enum or
// namespace due to how they are transformed in TypeScript.
// - We only substitute identifiers that are exported at the top level.
if (ts.isAssignmentOperator(node.operatorToken.kind)
&& ts.isIdentifier(node.left)
&& !ts.isGeneratedIdentifier(node.left)
&& !ts.isLocalName(node.left)
&& !ts.isDeclarationNameOfEnumOrNamespace(node.left)) {
var exportedNames = getExports(node.left);
if (exportedNames) {
// For each additional export of the declaration, apply an export assignment.
var expression = node;
for (var _i = 0, exportedNames_3 = exportedNames; _i < exportedNames_3.length; _i++) {
var exportName = exportedNames_3[_i];
// Mark the node to prevent triggering this rule again.
noSubstitution[ts.getNodeId(expression)] = true;
expression = createExportExpression(exportName, expression, /*location*/ node);
}
return expression;
}
}
return node;
}
/**
* Substitution for a UnaryExpression that may contain an imported or exported symbol.
*
* @param node The node to substitute.
*/
function substituteUnaryExpression(node) {
// When we see a prefix or postfix increment expression whose operand is an exported
// symbol, we should ensure all exports of that symbol are updated with the correct
// value.
//
// - We do not substitute generated identifiers for any reason.
// - We do not substitute identifiers tagged with the LocalName flag.
// - We do not substitute identifiers that were originally the name of an enum or
// namespace due to how they are transformed in TypeScript.
// - We only substitute identifiers that are exported at the top level.
if ((node.operator === 42 /* PlusPlusToken */ || node.operator === 43 /* MinusMinusToken */)
&& ts.isIdentifier(node.operand)
&& !ts.isGeneratedIdentifier(node.operand)
&& !ts.isLocalName(node.operand)
&& !ts.isDeclarationNameOfEnumOrNamespace(node.operand)) {
var exportedNames = getExports(node.operand);
if (exportedNames) {
var expression = node.kind === 191 /* PostfixUnaryExpression */
? ts.createBinary(node.operand, ts.createToken(node.operator === 42 /* PlusPlusToken */ ? 58 /* PlusEqualsToken */ : 59 /* MinusEqualsToken */), ts.createLiteral(1),
/*location*/ node)
: node;
for (var _i = 0, exportedNames_4 = exportedNames; _i < exportedNames_4.length; _i++) {
var exportName = exportedNames_4[_i];
// Mark the node to prevent triggering this rule again.
noSubstitution[ts.getNodeId(expression)] = true;
expression = createExportExpression(exportName, expression);
}
return expression;
}
}
return node;
}
/**
* Gets the additional exports of a name.
*
* @param name The name.
*/
function getExports(name) {
if (!ts.isGeneratedIdentifier(name)) {
var valueDeclaration = resolver.getReferencedImportDeclaration(name)
|| resolver.getReferencedValueDeclaration(name);
if (valueDeclaration) {
return currentModuleInfo
&& currentModuleInfo.exportedBindings[ts.getOriginalNodeId(valueDeclaration)];
}
}
}
var _a;
}
ts.transformModule = transformModule;
})(ts || (ts = {}));
/// <reference path="visitor.ts" />
/// <reference path="transformers/ts.ts" />
/// <reference path="transformers/jsx.ts" />
/// <reference path="transformers/esnext.ts" />
/// <reference path="transformers/es2017.ts" />
/// <reference path="transformers/es2016.ts" />
/// <reference path="transformers/es2015.ts" />
/// <reference path="transformers/generators.ts" />
/// <reference path="transformers/es5.ts" />
/// <reference path="transformers/module/module.ts" />
/// <reference path="transformers/module/system.ts" />
/// <reference path="transformers/module/es2015.ts" />
/* @internal */
var ts;
(function (ts) {
var moduleTransformerMap = ts.createMap((_a = {},
_a[ts.ModuleKind.ES2015] = ts.transformES2015Module,
_a[ts.ModuleKind.System] = ts.transformSystemModule,
_a[ts.ModuleKind.AMD] = ts.transformModule,
_a[ts.ModuleKind.CommonJS] = ts.transformModule,
_a[ts.ModuleKind.UMD] = ts.transformModule,
_a[ts.ModuleKind.None] = ts.transformModule,
_a));
var SyntaxKindFeatureFlags;
(function (SyntaxKindFeatureFlags) {
SyntaxKindFeatureFlags[SyntaxKindFeatureFlags["Substitution"] = 1] = "Substitution";
SyntaxKindFeatureFlags[SyntaxKindFeatureFlags["EmitNotifications"] = 2] = "EmitNotifications";
})(SyntaxKindFeatureFlags || (SyntaxKindFeatureFlags = {}));
function getTransformers(compilerOptions) {
var jsx = compilerOptions.jsx;
var languageVersion = ts.getEmitScriptTarget(compilerOptions);
var moduleKind = ts.getEmitModuleKind(compilerOptions);
var transformers = [];
transformers.push(ts.transformTypeScript);
if (jsx === 2 /* React */) {
transformers.push(ts.transformJsx);
}
if (languageVersion < 5 /* ESNext */) {
transformers.push(ts.transformESNext);
}
if (languageVersion < 4 /* ES2017 */) {
transformers.push(ts.transformES2017);
}
if (languageVersion < 3 /* ES2016 */) {
transformers.push(ts.transformES2016);
}
if (languageVersion < 2 /* ES2015 */) {
transformers.push(ts.transformES2015);
transformers.push(ts.transformGenerators);
}
transformers.push(moduleTransformerMap[moduleKind] || moduleTransformerMap[ts.ModuleKind.None]);
// The ES5 transformer is last so that it can substitute expressions like `exports.default`
// for ES3.
if (languageVersion < 1 /* ES5 */) {
transformers.push(ts.transformES5);
}
return transformers;
}
ts.getTransformers = getTransformers;
/**
* Transforms an array of SourceFiles by passing them through each transformer.
*
* @param resolver The emit resolver provided by the checker.
* @param host The emit host.
* @param sourceFiles An array of source files
* @param transforms An array of Transformers.
*/
function transformFiles(resolver, host, sourceFiles, transformers) {
var lexicalEnvironmentVariableDeclarationsStack = [];
var lexicalEnvironmentFunctionDeclarationsStack = [];
var enabledSyntaxKindFeatures = new Array(296 /* Count */);
var lexicalEnvironmentStackOffset = 0;
var hoistedVariableDeclarations;
var hoistedFunctionDeclarations;
var lexicalEnvironmentDisabled;
// The transformation context is provided to each transformer as part of transformer
// initialization.
var context = {
getCompilerOptions: function () { return host.getCompilerOptions(); },
getEmitResolver: function () { return resolver; },
getEmitHost: function () { return host; },
hoistVariableDeclaration: hoistVariableDeclaration,
hoistFunctionDeclaration: hoistFunctionDeclaration,
startLexicalEnvironment: startLexicalEnvironment,
endLexicalEnvironment: endLexicalEnvironment,
onSubstituteNode: function (_emitContext, node) { return node; },
enableSubstitution: enableSubstitution,
isSubstitutionEnabled: isSubstitutionEnabled,
onEmitNode: function (node, emitContext, emitCallback) { return emitCallback(node, emitContext); },
enableEmitNotification: enableEmitNotification,
isEmitNotificationEnabled: isEmitNotificationEnabled
};
// Chain together and initialize each transformer.
var transformation = ts.chain.apply(void 0, transformers)(context);
// Transform each source file.
var transformed = ts.map(sourceFiles, transformSourceFile);
// Disable modification of the lexical environment.
lexicalEnvironmentDisabled = true;
return {
transformed: transformed,
emitNodeWithSubstitution: emitNodeWithSubstitution,
emitNodeWithNotification: emitNodeWithNotification
};
/**
* Transforms a source file.
*
* @param sourceFile The source file to transform.
*/
function transformSourceFile(sourceFile) {
if (ts.isDeclarationFile(sourceFile)) {
return sourceFile;
}
return transformation(sourceFile);
}
/**
* Enables expression substitutions in the pretty printer for the provided SyntaxKind.
*/
function enableSubstitution(kind) {
enabledSyntaxKindFeatures[kind] |= 1 /* Substitution */;
}
/**
* Determines whether expression substitutions are enabled for the provided node.
*/
function isSubstitutionEnabled(node) {
return (enabledSyntaxKindFeatures[node.kind] & 1 /* Substitution */) !== 0
&& (ts.getEmitFlags(node) & 128 /* NoSubstitution */) === 0;
}
/**
* Emits a node with possible substitution.
*
* @param emitContext The current emit context.
* @param node The node to emit.
* @param emitCallback The callback used to emit the node or its substitute.
*/
function emitNodeWithSubstitution(emitContext, node, emitCallback) {
if (node) {
if (isSubstitutionEnabled(node)) {
var substitute = context.onSubstituteNode(emitContext, node);
if (substitute && substitute !== node) {
emitCallback(emitContext, substitute);
return;
}
}
emitCallback(emitContext, node);
}
}
/**
* Enables before/after emit notifications in the pretty printer for the provided SyntaxKind.
*/
function enableEmitNotification(kind) {
enabledSyntaxKindFeatures[kind] |= 2 /* EmitNotifications */;
}
/**
* Determines whether before/after emit notifications should be raised in the pretty
* printer when it emits a node.
*/
function isEmitNotificationEnabled(node) {
return (enabledSyntaxKindFeatures[node.kind] & 2 /* EmitNotifications */) !== 0
|| (ts.getEmitFlags(node) & 64 /* AdviseOnEmitNode */) !== 0;
}
/**
* Emits a node with possible emit notification.
*
* @param emitContext The current emit context.
* @param node The node to emit.
* @param emitCallback The callback used to emit the node.
*/
function emitNodeWithNotification(emitContext, node, emitCallback) {
if (node) {
if (isEmitNotificationEnabled(node)) {
context.onEmitNode(emitContext, node, emitCallback);
}
else {
emitCallback(emitContext, node);
}
}
}
/**
* Records a hoisted variable declaration for the provided name within a lexical environment.
*/
function hoistVariableDeclaration(name) {
ts.Debug.assert(!lexicalEnvironmentDisabled, "Cannot modify the lexical environment during the print phase.");
var decl = ts.createVariableDeclaration(name);
if (!hoistedVariableDeclarations) {
hoistedVariableDeclarations = [decl];
}
else {
hoistedVariableDeclarations.push(decl);
}
}
/**
* Records a hoisted function declaration within a lexical environment.
*/
function hoistFunctionDeclaration(func) {
ts.Debug.assert(!lexicalEnvironmentDisabled, "Cannot modify the lexical environment during the print phase.");
if (!hoistedFunctionDeclarations) {
hoistedFunctionDeclarations = [func];
}
else {
hoistedFunctionDeclarations.push(func);
}
}
/**
* Starts a new lexical environment. Any existing hoisted variable or function declarations
* are pushed onto a stack, and the related storage variables are reset.
*/
function startLexicalEnvironment() {
ts.Debug.assert(!lexicalEnvironmentDisabled, "Cannot start a lexical environment during the print phase.");
// Save the current lexical environment. Rather than resizing the array we adjust the
// stack size variable. This allows us to reuse existing array slots we've
// already allocated between transformations to avoid allocation and GC overhead during
// transformation.
lexicalEnvironmentVariableDeclarationsStack[lexicalEnvironmentStackOffset] = hoistedVariableDeclarations;
lexicalEnvironmentFunctionDeclarationsStack[lexicalEnvironmentStackOffset] = hoistedFunctionDeclarations;
lexicalEnvironmentStackOffset++;
hoistedVariableDeclarations = undefined;
hoistedFunctionDeclarations = undefined;
}
/**
* Ends a lexical environment. The previous set of hoisted declarations are restored and
* any hoisted declarations added in this environment are returned.
*/
function endLexicalEnvironment() {
ts.Debug.assert(!lexicalEnvironmentDisabled, "Cannot end a lexical environment during the print phase.");
var statements;
if (hoistedVariableDeclarations || hoistedFunctionDeclarations) {
if (hoistedFunctionDeclarations) {
statements = hoistedFunctionDeclarations.slice();
}
if (hoistedVariableDeclarations) {
var statement = ts.createVariableStatement(
/*modifiers*/ undefined, ts.createVariableDeclarationList(hoistedVariableDeclarations));
if (!statements) {
statements = [statement];
}
else {
statements.push(statement);
}
}
}
// Restore the previous lexical environment.
lexicalEnvironmentStackOffset--;
hoistedVariableDeclarations = lexicalEnvironmentVariableDeclarationsStack[lexicalEnvironmentStackOffset];
hoistedFunctionDeclarations = lexicalEnvironmentFunctionDeclarationsStack[lexicalEnvironmentStackOffset];
return statements;
}
}
ts.transformFiles = transformFiles;
var _a;
})(ts || (ts = {}));
/// <reference path="checker.ts"/>
/* @internal */
var ts;
(function (ts) {
// Used for initialize lastEncodedSourceMapSpan and reset lastEncodedSourceMapSpan when updateLastEncodedAndRecordedSpans
var defaultLastEncodedSourceMapSpan = {
emittedLine: 1,
emittedColumn: 1,
sourceLine: 1,
sourceColumn: 1,
sourceIndex: 0
};
function createSourceMapWriter(host, writer) {
var compilerOptions = host.getCompilerOptions();
var extendedDiagnostics = compilerOptions.extendedDiagnostics;
var currentSourceFile;
var currentSourceText;
var sourceMapDir; // The directory in which sourcemap will be
// Current source map file and its index in the sources list
var sourceMapSourceIndex;
// Last recorded and encoded spans
var lastRecordedSourceMapSpan;
var lastEncodedSourceMapSpan;
var lastEncodedNameIndex;
// Source map data
var sourceMapData;
var disabled = !(compilerOptions.sourceMap || compilerOptions.inlineSourceMap);
return {
initialize: initialize,
reset: reset,
getSourceMapData: function () { return sourceMapData; },
setSourceFile: setSourceFile,
emitPos: emitPos,
emitNodeWithSourceMap: emitNodeWithSourceMap,
emitTokenWithSourceMap: emitTokenWithSourceMap,
getText: getText,
getSourceMappingURL: getSourceMappingURL,
};
/**
* Initialize the SourceMapWriter for a new output file.
*
* @param filePath The path to the generated output file.
* @param sourceMapFilePath The path to the output source map file.
* @param sourceFiles The input source files for the program.
* @param isBundledEmit A value indicating whether the generated output file is a bundle.
*/
function initialize(filePath, sourceMapFilePath, sourceFiles, isBundledEmit) {
if (disabled) {
return;
}
if (sourceMapData) {
reset();
}
currentSourceFile = undefined;
currentSourceText = undefined;
// Current source map file and its index in the sources list
sourceMapSourceIndex = -1;
// Last recorded and encoded spans
lastRecordedSourceMapSpan = undefined;
lastEncodedSourceMapSpan = defaultLastEncodedSourceMapSpan;
lastEncodedNameIndex = 0;
// Initialize source map data
sourceMapData = {
sourceMapFilePath: sourceMapFilePath,
jsSourceMappingURL: !compilerOptions.inlineSourceMap ? ts.getBaseFileName(ts.normalizeSlashes(sourceMapFilePath)) : undefined,
sourceMapFile: ts.getBaseFileName(ts.normalizeSlashes(filePath)),
sourceMapSourceRoot: compilerOptions.sourceRoot || "",
sourceMapSources: [],
inputSourceFileNames: [],
sourceMapNames: [],
sourceMapMappings: "",
sourceMapSourcesContent: compilerOptions.inlineSources ? [] : undefined,
sourceMapDecodedMappings: []
};
// Normalize source root and make sure it has trailing "/" so that it can be used to combine paths with the
// relative paths of the sources list in the sourcemap
sourceMapData.sourceMapSourceRoot = ts.normalizeSlashes(sourceMapData.sourceMapSourceRoot);
if (sourceMapData.sourceMapSourceRoot.length && sourceMapData.sourceMapSourceRoot.charCodeAt(sourceMapData.sourceMapSourceRoot.length - 1) !== 47 /* slash */) {
sourceMapData.sourceMapSourceRoot += ts.directorySeparator;
}
if (compilerOptions.mapRoot) {
sourceMapDir = ts.normalizeSlashes(compilerOptions.mapRoot);
if (!isBundledEmit) {
ts.Debug.assert(sourceFiles.length === 1);
// For modules or multiple emit files the mapRoot will have directory structure like the sources
// So if src\a.ts and src\lib\b.ts are compiled together user would be moving the maps into mapRoot\a.js.map and mapRoot\lib\b.js.map
sourceMapDir = ts.getDirectoryPath(ts.getSourceFilePathInNewDir(sourceFiles[0], host, sourceMapDir));
}
if (!ts.isRootedDiskPath(sourceMapDir) && !ts.isUrl(sourceMapDir)) {
// The relative paths are relative to the common directory
sourceMapDir = ts.combinePaths(host.getCommonSourceDirectory(), sourceMapDir);
sourceMapData.jsSourceMappingURL = ts.getRelativePathToDirectoryOrUrl(ts.getDirectoryPath(ts.normalizePath(filePath)), // get the relative sourceMapDir path based on jsFilePath
ts.combinePaths(sourceMapDir, sourceMapData.jsSourceMappingURL), // this is where user expects to see sourceMap
host.getCurrentDirectory(), host.getCanonicalFileName,
/*isAbsolutePathAnUrl*/ true);
}
else {
sourceMapData.jsSourceMappingURL = ts.combinePaths(sourceMapDir, sourceMapData.jsSourceMappingURL);
}
}
else {
sourceMapDir = ts.getDirectoryPath(ts.normalizePath(filePath));
}
}
/**
* Reset the SourceMapWriter to an empty state.
*/
function reset() {
if (disabled) {
return;
}
currentSourceFile = undefined;
sourceMapDir = undefined;
sourceMapSourceIndex = undefined;
lastRecordedSourceMapSpan = undefined;
lastEncodedSourceMapSpan = undefined;
lastEncodedNameIndex = undefined;
sourceMapData = undefined;
}
// Encoding for sourcemap span
function encodeLastRecordedSourceMapSpan() {
if (!lastRecordedSourceMapSpan || lastRecordedSourceMapSpan === lastEncodedSourceMapSpan) {
return;
}
var prevEncodedEmittedColumn = lastEncodedSourceMapSpan.emittedColumn;
// Line/Comma delimiters
if (lastEncodedSourceMapSpan.emittedLine === lastRecordedSourceMapSpan.emittedLine) {
// Emit comma to separate the entry
if (sourceMapData.sourceMapMappings) {
sourceMapData.sourceMapMappings += ",";
}
}
else {
// Emit line delimiters
for (var encodedLine = lastEncodedSourceMapSpan.emittedLine; encodedLine < lastRecordedSourceMapSpan.emittedLine; encodedLine++) {
sourceMapData.sourceMapMappings += ";";
}
prevEncodedEmittedColumn = 1;
}
// 1. Relative Column 0 based
sourceMapData.sourceMapMappings += base64VLQFormatEncode(lastRecordedSourceMapSpan.emittedColumn - prevEncodedEmittedColumn);
// 2. Relative sourceIndex
sourceMapData.sourceMapMappings += base64VLQFormatEncode(lastRecordedSourceMapSpan.sourceIndex - lastEncodedSourceMapSpan.sourceIndex);
// 3. Relative sourceLine 0 based
sourceMapData.sourceMapMappings += base64VLQFormatEncode(lastRecordedSourceMapSpan.sourceLine - lastEncodedSourceMapSpan.sourceLine);
// 4. Relative sourceColumn 0 based
sourceMapData.sourceMapMappings += base64VLQFormatEncode(lastRecordedSourceMapSpan.sourceColumn - lastEncodedSourceMapSpan.sourceColumn);
// 5. Relative namePosition 0 based
if (lastRecordedSourceMapSpan.nameIndex >= 0) {
ts.Debug.assert(false, "We do not support name index right now, Make sure to update updateLastEncodedAndRecordedSpans when we start using this");
sourceMapData.sourceMapMappings += base64VLQFormatEncode(lastRecordedSourceMapSpan.nameIndex - lastEncodedNameIndex);
lastEncodedNameIndex = lastRecordedSourceMapSpan.nameIndex;
}
lastEncodedSourceMapSpan = lastRecordedSourceMapSpan;
sourceMapData.sourceMapDecodedMappings.push(lastEncodedSourceMapSpan);
}
/**
* Emits a mapping.
*
* If the position is synthetic (undefined or a negative value), no mapping will be
* created.
*
* @param pos The position.
*/
function emitPos(pos) {
if (disabled || ts.positionIsSynthesized(pos)) {
return;
}
if (extendedDiagnostics) {
ts.performance.mark("beforeSourcemap");
}
var sourceLinePos = ts.getLineAndCharacterOfPosition(currentSourceFile, pos);
// Convert the location to be one-based.
sourceLinePos.line++;
sourceLinePos.character++;
var emittedLine = writer.getLine();
var emittedColumn = writer.getColumn();
// If this location wasn't recorded or the location in source is going backwards, record the span
if (!lastRecordedSourceMapSpan ||
lastRecordedSourceMapSpan.emittedLine !== emittedLine ||
lastRecordedSourceMapSpan.emittedColumn !== emittedColumn ||
(lastRecordedSourceMapSpan.sourceIndex === sourceMapSourceIndex &&
(lastRecordedSourceMapSpan.sourceLine > sourceLinePos.line ||
(lastRecordedSourceMapSpan.sourceLine === sourceLinePos.line && lastRecordedSourceMapSpan.sourceColumn > sourceLinePos.character)))) {
// Encode the last recordedSpan before assigning new
encodeLastRecordedSourceMapSpan();
// New span
lastRecordedSourceMapSpan = {
emittedLine: emittedLine,
emittedColumn: emittedColumn,
sourceLine: sourceLinePos.line,
sourceColumn: sourceLinePos.character,
sourceIndex: sourceMapSourceIndex
};
}
else {
// Take the new pos instead since there is no change in emittedLine and column since last location
lastRecordedSourceMapSpan.sourceLine = sourceLinePos.line;
lastRecordedSourceMapSpan.sourceColumn = sourceLinePos.character;
lastRecordedSourceMapSpan.sourceIndex = sourceMapSourceIndex;
}
if (extendedDiagnostics) {
ts.performance.mark("afterSourcemap");
ts.performance.measure("Source Map", "beforeSourcemap", "afterSourcemap");
}
}
/**
* Emits a node with possible leading and trailing source maps.
*
* @param node The node to emit.
* @param emitCallback The callback used to emit the node.
*/
function emitNodeWithSourceMap(emitContext, node, emitCallback) {
if (disabled) {
return emitCallback(emitContext, node);
}
if (node) {
var emitNode = node.emitNode;
var emitFlags = emitNode && emitNode.flags;
var _a = emitNode && emitNode.sourceMapRange || node, pos = _a.pos, end = _a.end;
if (node.kind !== 292 /* NotEmittedStatement */
&& (emitFlags & 512 /* NoLeadingSourceMap */) === 0
&& pos >= 0) {
emitPos(ts.skipTrivia(currentSourceText, pos));
}
if (emitFlags & 2048 /* NoNestedSourceMaps */) {
disabled = true;
emitCallback(emitContext, node);
disabled = false;
}
else {
emitCallback(emitContext, node);
}
if (node.kind !== 292 /* NotEmittedStatement */
&& (emitFlags & 1024 /* NoTrailingSourceMap */) === 0
&& end >= 0) {
emitPos(end);
}
}
}
/**
* Emits a token of a node with possible leading and trailing source maps.
*
* @param node The node containing the token.
* @param token The token to emit.
* @param tokenStartPos The start pos of the token.
* @param emitCallback The callback used to emit the token.
*/
function emitTokenWithSourceMap(node, token, tokenPos, emitCallback) {
if (disabled) {
return emitCallback(token, tokenPos);
}
var emitNode = node && node.emitNode;
var emitFlags = emitNode && emitNode.flags;
var range = emitNode && emitNode.tokenSourceMapRanges && emitNode.tokenSourceMapRanges[token];
tokenPos = ts.skipTrivia(currentSourceText, range ? range.pos : tokenPos);
if ((emitFlags & 4096 /* NoTokenLeadingSourceMaps */) === 0 && tokenPos >= 0) {
emitPos(tokenPos);
}
tokenPos = emitCallback(token, tokenPos);
if (range)
tokenPos = range.end;
if ((emitFlags & 8192 /* NoTokenTrailingSourceMaps */) === 0 && tokenPos >= 0) {
emitPos(tokenPos);
}
return tokenPos;
}
/**
* Set the current source file.
*
* @param sourceFile The source file.
*/
function setSourceFile(sourceFile) {
if (disabled) {
return;
}
currentSourceFile = sourceFile;
currentSourceText = currentSourceFile.text;
// Add the file to tsFilePaths
// If sourceroot option: Use the relative path corresponding to the common directory path
// otherwise source locations relative to map file location
var sourcesDirectoryPath = compilerOptions.sourceRoot ? host.getCommonSourceDirectory() : sourceMapDir;
var source = ts.getRelativePathToDirectoryOrUrl(sourcesDirectoryPath, currentSourceFile.fileName, host.getCurrentDirectory(), host.getCanonicalFileName,
/*isAbsolutePathAnUrl*/ true);
sourceMapSourceIndex = ts.indexOf(sourceMapData.sourceMapSources, source);
if (sourceMapSourceIndex === -1) {
sourceMapSourceIndex = sourceMapData.sourceMapSources.length;
sourceMapData.sourceMapSources.push(source);
// The one that can be used from program to get the actual source file
sourceMapData.inputSourceFileNames.push(currentSourceFile.fileName);
if (compilerOptions.inlineSources) {
sourceMapData.sourceMapSourcesContent.push(currentSourceFile.text);
}
}
}
/**
* Gets the text for the source map.
*/
function getText() {
if (disabled) {
return;
}
encodeLastRecordedSourceMapSpan();
return ts.stringify({
version: 3,
file: sourceMapData.sourceMapFile,
sourceRoot: sourceMapData.sourceMapSourceRoot,
sources: sourceMapData.sourceMapSources,
names: sourceMapData.sourceMapNames,
mappings: sourceMapData.sourceMapMappings,
sourcesContent: sourceMapData.sourceMapSourcesContent,
});
}
/**
* Gets the SourceMappingURL for the source map.
*/
function getSourceMappingURL() {
if (disabled) {
return;
}
if (compilerOptions.inlineSourceMap) {
// Encode the sourceMap into the sourceMap url
var base64SourceMapText = ts.convertToBase64(getText());
return sourceMapData.jsSourceMappingURL = "data:application/json;base64," + base64SourceMapText;
}
else {
return sourceMapData.jsSourceMappingURL;
}
}
}
ts.createSourceMapWriter = createSourceMapWriter;
var base64Chars = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/";
function base64FormatEncode(inValue) {
if (inValue < 64) {
return base64Chars.charAt(inValue);
}
throw TypeError(inValue + ": not a 64 based value");
}
function base64VLQFormatEncode(inValue) {
// Add a new least significant bit that has the sign of the value.
// if negative number the least significant bit that gets added to the number has value 1
// else least significant bit value that gets added is 0
// eg. -1 changes to binary : 01 [1] => 3
// +1 changes to binary : 01 [0] => 2
if (inValue < 0) {
inValue = ((-inValue) << 1) + 1;
}
else {
inValue = inValue << 1;
}
// Encode 5 bits at a time starting from least significant bits
var encodedStr = "";
do {
var currentDigit = inValue & 31; // 11111
inValue = inValue >> 5;
if (inValue > 0) {
// There are still more digits to decode, set the msb (6th bit)
currentDigit = currentDigit | 32;
}
encodedStr = encodedStr + base64FormatEncode(currentDigit);
} while (inValue > 0);
return encodedStr;
}
})(ts || (ts = {}));
/// <reference path="sourcemap.ts" />
/* @internal */
var ts;
(function (ts) {
function createCommentWriter(host, writer, sourceMap) {
var compilerOptions = host.getCompilerOptions();
var extendedDiagnostics = compilerOptions.extendedDiagnostics;
var newLine = host.getNewLine();
var emitPos = sourceMap.emitPos;
var containerPos = -1;
var containerEnd = -1;
var declarationListContainerEnd = -1;
var currentSourceFile;
var currentText;
var currentLineMap;
var detachedCommentsInfo;
var hasWrittenComment = false;
var disabled = compilerOptions.removeComments;
return {
reset: reset,
setSourceFile: setSourceFile,
emitNodeWithComments: emitNodeWithComments,
emitBodyWithDetachedComments: emitBodyWithDetachedComments,
emitTrailingCommentsOfPosition: emitTrailingCommentsOfPosition,
};
function emitNodeWithComments(emitContext, node, emitCallback) {
if (disabled) {
emitCallback(emitContext, node);
return;
}
if (node) {
var _a = ts.getCommentRange(node), pos = _a.pos, end = _a.end;
var emitFlags = ts.getEmitFlags(node);
if ((pos < 0 && end < 0) || (pos === end)) {
// Both pos and end are synthesized, so just emit the node without comments.
if (emitFlags & 65536 /* NoNestedComments */) {
disabled = true;
emitCallback(emitContext, node);
disabled = false;
}
else {
emitCallback(emitContext, node);
}
}
else {
if (extendedDiagnostics) {
ts.performance.mark("preEmitNodeWithComment");
}
var isEmittedNode = node.kind !== 292 /* NotEmittedStatement */;
var skipLeadingComments = pos < 0 || (emitFlags & 16384 /* NoLeadingComments */) !== 0;
var skipTrailingComments = end < 0 || (emitFlags & 32768 /* NoTrailingComments */) !== 0;
// Emit leading comments if the position is not synthesized and the node
// has not opted out from emitting leading comments.
if (!skipLeadingComments) {
emitLeadingComments(pos, isEmittedNode);
}
// Save current container state on the stack.
var savedContainerPos = containerPos;
var savedContainerEnd = containerEnd;
var savedDeclarationListContainerEnd = declarationListContainerEnd;
if (!skipLeadingComments) {
containerPos = pos;
}
if (!skipTrailingComments) {
containerEnd = end;
// To avoid invalid comment emit in a down-level binding pattern, we
// keep track of the last declaration list container's end
if (node.kind === 224 /* VariableDeclarationList */) {
declarationListContainerEnd = end;
}
}
if (extendedDiagnostics) {
ts.performance.measure("commentTime", "preEmitNodeWithComment");
}
if (emitFlags & 65536 /* NoNestedComments */) {
disabled = true;
emitCallback(emitContext, node);
disabled = false;
}
else {
emitCallback(emitContext, node);
}
if (extendedDiagnostics) {
ts.performance.mark("beginEmitNodeWithComment");
}
// Restore previous container state.
containerPos = savedContainerPos;
containerEnd = savedContainerEnd;
declarationListContainerEnd = savedDeclarationListContainerEnd;
// Emit trailing comments if the position is not synthesized and the node
// has not opted out from emitting leading comments and is an emitted node.
if (!skipTrailingComments && isEmittedNode) {
emitTrailingComments(end);
}
if (extendedDiagnostics) {
ts.performance.measure("commentTime", "beginEmitNodeWithComment");
}
}
}
}
function emitBodyWithDetachedComments(node, detachedRange, emitCallback) {
if (extendedDiagnostics) {
ts.performance.mark("preEmitBodyWithDetachedComments");
}
var pos = detachedRange.pos, end = detachedRange.end;
var emitFlags = ts.getEmitFlags(node);
var skipLeadingComments = pos < 0 || (emitFlags & 16384 /* NoLeadingComments */) !== 0;
var skipTrailingComments = disabled || end < 0 || (emitFlags & 32768 /* NoTrailingComments */) !== 0;
if (!skipLeadingComments) {
emitDetachedCommentsAndUpdateCommentsInfo(detachedRange);
}
if (extendedDiagnostics) {
ts.performance.measure("commentTime", "preEmitBodyWithDetachedComments");
}
if (emitFlags & 65536 /* NoNestedComments */ && !disabled) {
disabled = true;
emitCallback(node);
disabled = false;
}
else {
emitCallback(node);
}
if (extendedDiagnostics) {
ts.performance.mark("beginEmitBodyWithDetachedCommetns");
}
if (!skipTrailingComments) {
emitLeadingComments(detachedRange.end, /*isEmittedNode*/ true);
}
if (extendedDiagnostics) {
ts.performance.measure("commentTime", "beginEmitBodyWithDetachedCommetns");
}
}
function emitLeadingComments(pos, isEmittedNode) {
hasWrittenComment = false;
if (isEmittedNode) {
forEachLeadingCommentToEmit(pos, emitLeadingComment);
}
else if (pos === 0) {
// If the node will not be emitted in JS, remove all the comments(normal, pinned and ///) associated with the node,
// unless it is a triple slash comment at the top of the file.
// For Example:
// /// <reference-path ...>
// declare var x;
// /// <reference-path ...>
// interface F {}
// The first /// will NOT be removed while the second one will be removed even though both node will not be emitted
forEachLeadingCommentToEmit(pos, emitTripleSlashLeadingComment);
}
}
function emitTripleSlashLeadingComment(commentPos, commentEnd, kind, hasTrailingNewLine, rangePos) {
if (isTripleSlashComment(commentPos, commentEnd)) {
emitLeadingComment(commentPos, commentEnd, kind, hasTrailingNewLine, rangePos);
}
}
function emitLeadingComment(commentPos, commentEnd, _kind, hasTrailingNewLine, rangePos) {
if (!hasWrittenComment) {
ts.emitNewLineBeforeLeadingCommentOfPosition(currentLineMap, writer, rangePos, commentPos);
hasWrittenComment = true;
}
// Leading comments are emitted at /*leading comment1 */space/*leading comment*/space
emitPos(commentPos);
ts.writeCommentRange(currentText, currentLineMap, writer, commentPos, commentEnd, newLine);
emitPos(commentEnd);
if (hasTrailingNewLine) {
writer.writeLine();
}
else {
writer.write(" ");
}
}
function emitTrailingComments(pos) {
forEachTrailingCommentToEmit(pos, emitTrailingComment);
}
function emitTrailingComment(commentPos, commentEnd, _kind, hasTrailingNewLine) {
// trailing comments are emitted at space/*trailing comment1 */space/*trailing comment2*/
if (!writer.isAtStartOfLine()) {
writer.write(" ");
}
emitPos(commentPos);
ts.writeCommentRange(currentText, currentLineMap, writer, commentPos, commentEnd, newLine);
emitPos(commentEnd);
if (hasTrailingNewLine) {
writer.writeLine();
}
}
function emitTrailingCommentsOfPosition(pos) {
if (disabled) {
return;
}
if (extendedDiagnostics) {
ts.performance.mark("beforeEmitTrailingCommentsOfPosition");
}
forEachTrailingCommentToEmit(pos, emitTrailingCommentOfPosition);
if (extendedDiagnostics) {
ts.performance.measure("commentTime", "beforeEmitTrailingCommentsOfPosition");
}
}
function emitTrailingCommentOfPosition(commentPos, commentEnd, _kind, hasTrailingNewLine) {
// trailing comments of a position are emitted at /*trailing comment1 */space/*trailing comment*/space
emitPos(commentPos);
ts.writeCommentRange(currentText, currentLineMap, writer, commentPos, commentEnd, newLine);
emitPos(commentEnd);
if (hasTrailingNewLine) {
writer.writeLine();
}
else {
writer.write(" ");
}
}
function forEachLeadingCommentToEmit(pos, cb) {
// Emit the leading comments only if the container's pos doesn't match because the container should take care of emitting these comments
if (containerPos === -1 || pos !== containerPos) {
if (hasDetachedComments(pos)) {
forEachLeadingCommentWithoutDetachedComments(cb);
}
else {
ts.forEachLeadingCommentRange(currentText, pos, cb, /*state*/ pos);
}
}
}
function forEachTrailingCommentToEmit(end, cb) {
// Emit the trailing comments only if the container's end doesn't match because the container should take care of emitting these comments
if (containerEnd === -1 || (end !== containerEnd && end !== declarationListContainerEnd)) {
ts.forEachTrailingCommentRange(currentText, end, cb);
}
}
function reset() {
currentSourceFile = undefined;
currentText = undefined;
currentLineMap = undefined;
detachedCommentsInfo = undefined;
}
function setSourceFile(sourceFile) {
currentSourceFile = sourceFile;
currentText = currentSourceFile.text;
currentLineMap = ts.getLineStarts(currentSourceFile);
detachedCommentsInfo = undefined;
}
function hasDetachedComments(pos) {
return detachedCommentsInfo !== undefined && ts.lastOrUndefined(detachedCommentsInfo).nodePos === pos;
}
function forEachLeadingCommentWithoutDetachedComments(cb) {
// get the leading comments from detachedPos
var pos = ts.lastOrUndefined(detachedCommentsInfo).detachedCommentEndPos;
if (detachedCommentsInfo.length - 1) {
detachedCommentsInfo.pop();
}
else {
detachedCommentsInfo = undefined;
}
ts.forEachLeadingCommentRange(currentText, pos, cb, /*state*/ pos);
}
function emitDetachedCommentsAndUpdateCommentsInfo(range) {
var currentDetachedCommentInfo = ts.emitDetachedComments(currentText, currentLineMap, writer, writeComment, range, newLine, disabled);
if (currentDetachedCommentInfo) {
if (detachedCommentsInfo) {
detachedCommentsInfo.push(currentDetachedCommentInfo);
}
else {
detachedCommentsInfo = [currentDetachedCommentInfo];
}
}
}
function writeComment(text, lineMap, writer, commentPos, commentEnd, newLine) {
emitPos(commentPos);
ts.writeCommentRange(text, lineMap, writer, commentPos, commentEnd, newLine);
emitPos(commentEnd);
}
/**
* Determine if the given comment is a triple-slash
*
* @return true if the comment is a triple-slash comment else false
**/
function isTripleSlashComment(commentPos, commentEnd) {
// Verify this is /// comment, but do the regexp match only when we first can find /// in the comment text
// so that we don't end up computing comment string and doing match for all // comments
if (currentText.charCodeAt(commentPos + 1) === 47 /* slash */ &&
commentPos + 2 < commentEnd &&
currentText.charCodeAt(commentPos + 2) === 47 /* slash */) {
var textSubStr = currentText.substring(commentPos, commentEnd);
return textSubStr.match(ts.fullTripleSlashReferencePathRegEx) ||
textSubStr.match(ts.fullTripleSlashAMDReferencePathRegEx) ?
true : false;
}
return false;
}
}
ts.createCommentWriter = createCommentWriter;
})(ts || (ts = {}));
/// <reference path="checker.ts"/>
/* @internal */
var ts;
(function (ts) {
function getDeclarationDiagnostics(host, resolver, targetSourceFile) {
var declarationDiagnostics = ts.createDiagnosticCollection();
ts.forEachExpectedEmitFile(host, getDeclarationDiagnosticsFromFile, targetSourceFile);
return declarationDiagnostics.getDiagnostics(targetSourceFile ? targetSourceFile.fileName : undefined);
function getDeclarationDiagnosticsFromFile(_a, sources, isBundledEmit) {
var declarationFilePath = _a.declarationFilePath;
emitDeclarations(host, resolver, declarationDiagnostics, declarationFilePath, sources, isBundledEmit, /*emitOnlyDtsFiles*/ false);
}
}
ts.getDeclarationDiagnostics = getDeclarationDiagnostics;
function emitDeclarations(host, resolver, emitterDiagnostics, declarationFilePath, sourceFiles, isBundledEmit, emitOnlyDtsFiles) {
var newLine = host.getNewLine();
var compilerOptions = host.getCompilerOptions();
var write;
var writeLine;
var increaseIndent;
var decreaseIndent;
var writeTextOfNode;
var writer;
createAndSetNewTextWriterWithSymbolWriter();
var enclosingDeclaration;
var resultHasExternalModuleIndicator;
var currentText;
var currentLineMap;
var currentIdentifiers;
var isCurrentFileExternalModule;
var reportedDeclarationError = false;
var errorNameNode;
var emitJsDocComments = compilerOptions.removeComments ? ts.noop : writeJsDocComments;
var emit = compilerOptions.stripInternal ? stripInternal : emitNode;
var noDeclare;
var moduleElementDeclarationEmitInfo = [];
var asynchronousSubModuleDeclarationEmitInfo;
// Contains the reference paths that needs to go in the declaration file.
// Collecting this separately because reference paths need to be first thing in the declaration file
// and we could be collecting these paths from multiple files into single one with --out option
var referencesOutput = "";
var usedTypeDirectiveReferences;
// Emit references corresponding to each file
var emittedReferencedFiles = [];
var addedGlobalFileReference = false;
var allSourcesModuleElementDeclarationEmitInfo = [];
ts.forEach(sourceFiles, function (sourceFile) {
// Dont emit for javascript file
if (ts.isSourceFileJavaScript(sourceFile)) {
return;
}
// Check what references need to be added
if (!compilerOptions.noResolve) {
ts.forEach(sourceFile.referencedFiles, function (fileReference) {
var referencedFile = ts.tryResolveScriptReference(host, sourceFile, fileReference);
// Emit reference in dts, if the file reference was not already emitted
if (referencedFile && !ts.contains(emittedReferencedFiles, referencedFile)) {
// Add a reference to generated dts file,
// global file reference is added only
// - if it is not bundled emit (because otherwise it would be self reference)
// - and it is not already added
if (writeReferencePath(referencedFile, !isBundledEmit && !addedGlobalFileReference, emitOnlyDtsFiles)) {
addedGlobalFileReference = true;
}
emittedReferencedFiles.push(referencedFile);
}
});
}
resultHasExternalModuleIndicator = false;
if (!isBundledEmit || !ts.isExternalModule(sourceFile)) {
noDeclare = false;
emitSourceFile(sourceFile);
}
else if (ts.isExternalModule(sourceFile)) {
noDeclare = true;
write("declare module \"" + ts.getResolvedExternalModuleName(host, sourceFile) + "\" {");
writeLine();
increaseIndent();
emitSourceFile(sourceFile);
decreaseIndent();
write("}");
writeLine();
}
// create asynchronous output for the importDeclarations
if (moduleElementDeclarationEmitInfo.length) {
var oldWriter = writer;
ts.forEach(moduleElementDeclarationEmitInfo, function (aliasEmitInfo) {
if (aliasEmitInfo.isVisible && !aliasEmitInfo.asynchronousOutput) {
ts.Debug.assert(aliasEmitInfo.node.kind === 235 /* ImportDeclaration */);
createAndSetNewTextWriterWithSymbolWriter();
ts.Debug.assert(aliasEmitInfo.indent === 0 || (aliasEmitInfo.indent === 1 && isBundledEmit));
for (var i = 0; i < aliasEmitInfo.indent; i++) {
increaseIndent();
}
writeImportDeclaration(aliasEmitInfo.node);
aliasEmitInfo.asynchronousOutput = writer.getText();
for (var i = 0; i < aliasEmitInfo.indent; i++) {
decreaseIndent();
}
}
});
setWriter(oldWriter);
allSourcesModuleElementDeclarationEmitInfo = allSourcesModuleElementDeclarationEmitInfo.concat(moduleElementDeclarationEmitInfo);
moduleElementDeclarationEmitInfo = [];
}
if (!isBundledEmit && ts.isExternalModule(sourceFile) && sourceFile.moduleAugmentations.length && !resultHasExternalModuleIndicator) {
// if file was external module with augmentations - this fact should be preserved in .d.ts as well.
// in case if we didn't write any external module specifiers in .d.ts we need to emit something
// that will force compiler to think that this file is an external module - 'export {}' is a reasonable choice here.
write("export {};");
writeLine();
}
});
if (usedTypeDirectiveReferences) {
for (var directive in usedTypeDirectiveReferences) {
referencesOutput += "/// <reference types=\"" + directive + "\" />" + newLine;
}
}
return {
reportedDeclarationError: reportedDeclarationError,
moduleElementDeclarationEmitInfo: allSourcesModuleElementDeclarationEmitInfo,
synchronousDeclarationOutput: writer.getText(),
referencesOutput: referencesOutput,
};
function hasInternalAnnotation(range) {
var comment = currentText.substring(range.pos, range.end);
return comment.indexOf("@internal") >= 0;
}
function stripInternal(node) {
if (node) {
var leadingCommentRanges = ts.getLeadingCommentRanges(currentText, node.pos);
if (ts.forEach(leadingCommentRanges, hasInternalAnnotation)) {
return;
}
emitNode(node);
}
}
function createAndSetNewTextWriterWithSymbolWriter() {
var writer = ts.createTextWriter(newLine);
writer.trackSymbol = trackSymbol;
writer.reportInaccessibleThisError = reportInaccessibleThisError;
writer.writeKeyword = writer.write;
writer.writeOperator = writer.write;
writer.writePunctuation = writer.write;
writer.writeSpace = writer.write;
writer.writeStringLiteral = writer.writeLiteral;
writer.writeParameter = writer.write;
writer.writeSymbol = writer.write;
setWriter(writer);
}
function setWriter(newWriter) {
writer = newWriter;
write = newWriter.write;
writeTextOfNode = newWriter.writeTextOfNode;
writeLine = newWriter.writeLine;
increaseIndent = newWriter.increaseIndent;
decreaseIndent = newWriter.decreaseIndent;
}
function writeAsynchronousModuleElements(nodes) {
var oldWriter = writer;
ts.forEach(nodes, function (declaration) {
var nodeToCheck;
if (declaration.kind === 223 /* VariableDeclaration */) {
nodeToCheck = declaration.parent.parent;
}
else if (declaration.kind === 238 /* NamedImports */ || declaration.kind === 239 /* ImportSpecifier */ || declaration.kind === 236 /* ImportClause */) {
ts.Debug.fail("We should be getting ImportDeclaration instead to write");
}
else {
nodeToCheck = declaration;
}
var moduleElementEmitInfo = ts.forEach(moduleElementDeclarationEmitInfo, function (declEmitInfo) { return declEmitInfo.node === nodeToCheck ? declEmitInfo : undefined; });
if (!moduleElementEmitInfo && asynchronousSubModuleDeclarationEmitInfo) {
moduleElementEmitInfo = ts.forEach(asynchronousSubModuleDeclarationEmitInfo, function (declEmitInfo) { return declEmitInfo.node === nodeToCheck ? declEmitInfo : undefined; });
}
// If the alias was marked as not visible when we saw its declaration, we would have saved the aliasEmitInfo, but if we haven't yet visited the alias declaration
// then we don't need to write it at this point. We will write it when we actually see its declaration
// Eg.
// export function bar(a: foo.Foo) { }
// import foo = require("foo");
// Writing of function bar would mark alias declaration foo as visible but we haven't yet visited that declaration so do nothing,
// we would write alias foo declaration when we visit it since it would now be marked as visible
if (moduleElementEmitInfo) {
if (moduleElementEmitInfo.node.kind === 235 /* ImportDeclaration */) {
// we have to create asynchronous output only after we have collected complete information
// because it is possible to enable multiple bindings as asynchronously visible
moduleElementEmitInfo.isVisible = true;
}
else {
createAndSetNewTextWriterWithSymbolWriter();
for (var declarationIndent = moduleElementEmitInfo.indent; declarationIndent; declarationIndent--) {
increaseIndent();
}
if (nodeToCheck.kind === 230 /* ModuleDeclaration */) {
ts.Debug.assert(asynchronousSubModuleDeclarationEmitInfo === undefined);
asynchronousSubModuleDeclarationEmitInfo = [];
}
writeModuleElement(nodeToCheck);
if (nodeToCheck.kind === 230 /* ModuleDeclaration */) {
moduleElementEmitInfo.subModuleElementDeclarationEmitInfo = asynchronousSubModuleDeclarationEmitInfo;
asynchronousSubModuleDeclarationEmitInfo = undefined;
}
moduleElementEmitInfo.asynchronousOutput = writer.getText();
}
}
});
setWriter(oldWriter);
}
function recordTypeReferenceDirectivesIfNecessary(typeReferenceDirectives) {
if (!typeReferenceDirectives) {
return;
}
if (!usedTypeDirectiveReferences) {
usedTypeDirectiveReferences = ts.createMap();
}
for (var _i = 0, typeReferenceDirectives_1 = typeReferenceDirectives; _i < typeReferenceDirectives_1.length; _i++) {
var directive = typeReferenceDirectives_1[_i];
if (!(directive in usedTypeDirectiveReferences)) {
usedTypeDirectiveReferences[directive] = directive;
}
}
}
function handleSymbolAccessibilityError(symbolAccessibilityResult) {
if (symbolAccessibilityResult.accessibility === 0 /* Accessible */) {
// write the aliases
if (symbolAccessibilityResult && symbolAccessibilityResult.aliasesToMakeVisible) {
writeAsynchronousModuleElements(symbolAccessibilityResult.aliasesToMakeVisible);
}
}
else {
// Report error
reportedDeclarationError = true;
var errorInfo = writer.getSymbolAccessibilityDiagnostic(symbolAccessibilityResult);
if (errorInfo) {
if (errorInfo.typeName) {
emitterDiagnostics.add(ts.createDiagnosticForNode(symbolAccessibilityResult.errorNode || errorInfo.errorNode, errorInfo.diagnosticMessage, ts.getTextOfNodeFromSourceText(currentText, errorInfo.typeName), symbolAccessibilityResult.errorSymbolName, symbolAccessibilityResult.errorModuleName));
}
else {
emitterDiagnostics.add(ts.createDiagnosticForNode(symbolAccessibilityResult.errorNode || errorInfo.errorNode, errorInfo.diagnosticMessage, symbolAccessibilityResult.errorSymbolName, symbolAccessibilityResult.errorModuleName));
}
}
}
}
function trackSymbol(symbol, enclosingDeclaration, meaning) {
handleSymbolAccessibilityError(resolver.isSymbolAccessible(symbol, enclosingDeclaration, meaning, /*shouldComputeAliasesToMakeVisible*/ true));
recordTypeReferenceDirectivesIfNecessary(resolver.getTypeReferenceDirectivesForSymbol(symbol, meaning));
}
function reportInaccessibleThisError() {
if (errorNameNode) {
reportedDeclarationError = true;
emitterDiagnostics.add(ts.createDiagnosticForNode(errorNameNode, ts.Diagnostics.The_inferred_type_of_0_references_an_inaccessible_this_type_A_type_annotation_is_necessary, ts.declarationNameToString(errorNameNode)));
}
}
function writeTypeOfDeclaration(declaration, type, getSymbolAccessibilityDiagnostic) {
writer.getSymbolAccessibilityDiagnostic = getSymbolAccessibilityDiagnostic;
write(": ");
if (type) {
// Write the type
emitType(type);
}
else {
errorNameNode = declaration.name;
resolver.writeTypeOfDeclaration(declaration, enclosingDeclaration, 2 /* UseTypeOfFunction */ | 1024 /* UseTypeAliasValue */, writer);
errorNameNode = undefined;
}
}
function writeReturnTypeAtSignature(signature, getSymbolAccessibilityDiagnostic) {
writer.getSymbolAccessibilityDiagnostic = getSymbolAccessibilityDiagnostic;
write(": ");
if (signature.type) {
// Write the type
emitType(signature.type);
}
else {
errorNameNode = signature.name;
resolver.writeReturnTypeOfSignatureDeclaration(signature, enclosingDeclaration, 2 /* UseTypeOfFunction */ | 1024 /* UseTypeAliasValue */, writer);
errorNameNode = undefined;
}
}
function emitLines(nodes) {
for (var _i = 0, nodes_2 = nodes; _i < nodes_2.length; _i++) {
var node = nodes_2[_i];
emit(node);
}
}
function emitSeparatedList(nodes, separator, eachNodeEmitFn, canEmitFn) {
var currentWriterPos = writer.getTextPos();
for (var _i = 0, nodes_3 = nodes; _i < nodes_3.length; _i++) {
var node = nodes_3[_i];
if (!canEmitFn || canEmitFn(node)) {
if (currentWriterPos !== writer.getTextPos()) {
write(separator);
}
currentWriterPos = writer.getTextPos();
eachNodeEmitFn(node);
}
}
}
function emitCommaList(nodes, eachNodeEmitFn, canEmitFn) {
emitSeparatedList(nodes, ", ", eachNodeEmitFn, canEmitFn);
}
function writeJsDocComments(declaration) {
if (declaration) {
var jsDocComments = ts.getJsDocCommentsFromText(declaration, currentText);
ts.emitNewLineBeforeLeadingComments(currentLineMap, writer, declaration, jsDocComments);
// jsDoc comments are emitted at /*leading comment1 */space/*leading comment*/space
ts.emitComments(currentText, currentLineMap, writer, jsDocComments, /*leadingSeparator*/ false, /*trailingSeparator*/ true, newLine, ts.writeCommentRange);
}
}
function emitTypeWithNewGetSymbolAccessibilityDiagnostic(type, getSymbolAccessibilityDiagnostic) {
writer.getSymbolAccessibilityDiagnostic = getSymbolAccessibilityDiagnostic;
emitType(type);
}
function emitType(type) {
switch (type.kind) {
case 118 /* AnyKeyword */:
case 134 /* StringKeyword */:
case 132 /* NumberKeyword */:
case 121 /* BooleanKeyword */:
case 135 /* SymbolKeyword */:
case 104 /* VoidKeyword */:
case 137 /* UndefinedKeyword */:
case 94 /* NullKeyword */:
case 129 /* NeverKeyword */:
case 167 /* ThisType */:
case 171 /* LiteralType */:
return writeTextOfNode(currentText, type);
case 199 /* ExpressionWithTypeArguments */:
return emitExpressionWithTypeArguments(type);
case 157 /* TypeReference */:
return emitTypeReference(type);
case 160 /* TypeQuery */:
return emitTypeQuery(type);
case 162 /* ArrayType */:
return emitArrayType(type);
case 163 /* TupleType */:
return emitTupleType(type);
case 164 /* UnionType */:
return emitUnionType(type);
case 165 /* IntersectionType */:
return emitIntersectionType(type);
case 166 /* ParenthesizedType */:
return emitParenType(type);
case 168 /* TypeOperator */:
return emitTypeOperator(type);
case 169 /* IndexedAccessType */:
return emitIndexedAccessType(type);
case 170 /* MappedType */:
return emitMappedType(type);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
return emitSignatureDeclarationWithJsDocComments(type);
case 161 /* TypeLiteral */:
return emitTypeLiteral(type);
case 70 /* Identifier */:
return emitEntityName(type);
case 141 /* QualifiedName */:
return emitEntityName(type);
case 156 /* TypePredicate */:
return emitTypePredicate(type);
}
function writeEntityName(entityName) {
if (entityName.kind === 70 /* Identifier */) {
writeTextOfNode(currentText, entityName);
}
else {
var left = entityName.kind === 141 /* QualifiedName */ ? entityName.left : entityName.expression;
var right = entityName.kind === 141 /* QualifiedName */ ? entityName.right : entityName.name;
writeEntityName(left);
write(".");
writeTextOfNode(currentText, right);
}
}
function emitEntityName(entityName) {
var visibilityResult = resolver.isEntityNameVisible(entityName,
// Aliases can be written asynchronously so use correct enclosing declaration
entityName.parent.kind === 234 /* ImportEqualsDeclaration */ ? entityName.parent : enclosingDeclaration);
handleSymbolAccessibilityError(visibilityResult);
recordTypeReferenceDirectivesIfNecessary(resolver.getTypeReferenceDirectivesForEntityName(entityName));
writeEntityName(entityName);
}
function emitExpressionWithTypeArguments(node) {
if (ts.isEntityNameExpression(node.expression)) {
ts.Debug.assert(node.expression.kind === 70 /* Identifier */ || node.expression.kind === 177 /* PropertyAccessExpression */);
emitEntityName(node.expression);
if (node.typeArguments) {
write("<");
emitCommaList(node.typeArguments, emitType);
write(">");
}
}
}
function emitTypeReference(type) {
emitEntityName(type.typeName);
if (type.typeArguments) {
write("<");
emitCommaList(type.typeArguments, emitType);
write(">");
}
}
function emitTypePredicate(type) {
writeTextOfNode(currentText, type.parameterName);
write(" is ");
emitType(type.type);
}
function emitTypeQuery(type) {
write("typeof ");
emitEntityName(type.exprName);
}
function emitArrayType(type) {
emitType(type.elementType);
write("[]");
}
function emitTupleType(type) {
write("[");
emitCommaList(type.elementTypes, emitType);
write("]");
}
function emitUnionType(type) {
emitSeparatedList(type.types, " | ", emitType);
}
function emitIntersectionType(type) {
emitSeparatedList(type.types, " & ", emitType);
}
function emitParenType(type) {
write("(");
emitType(type.type);
write(")");
}
function emitTypeOperator(type) {
write(ts.tokenToString(type.operator));
write(" ");
emitType(type.type);
}
function emitIndexedAccessType(node) {
emitType(node.objectType);
write("[");
emitType(node.indexType);
write("]");
}
function emitMappedType(node) {
var prevEnclosingDeclaration = enclosingDeclaration;
enclosingDeclaration = node;
write("{");
writeLine();
increaseIndent();
if (node.readonlyToken) {
write("readonly ");
}
write("[");
writeEntityName(node.typeParameter.name);
write(" in ");
emitType(node.typeParameter.constraint);
write("]");
if (node.questionToken) {
write("?");
}
write(": ");
emitType(node.type);
write(";");
writeLine();
decreaseIndent();
write("}");
enclosingDeclaration = prevEnclosingDeclaration;
}
function emitTypeLiteral(type) {
write("{");
if (type.members.length) {
writeLine();
increaseIndent();
// write members
emitLines(type.members);
decreaseIndent();
}
write("}");
}
}
function emitSourceFile(node) {
currentText = node.text;
currentLineMap = ts.getLineStarts(node);
currentIdentifiers = node.identifiers;
isCurrentFileExternalModule = ts.isExternalModule(node);
enclosingDeclaration = node;
ts.emitDetachedComments(currentText, currentLineMap, writer, ts.writeCommentRange, node, newLine, true /* remove comments */);
emitLines(node.statements);
}
// Return a temp variable name to be used in `export default` statements.
// The temp name will be of the form _default_counter.
// Note that export default is only allowed at most once in a module, so we
// do not need to keep track of created temp names.
function getExportDefaultTempVariableName() {
var baseName = "_default";
if (!(baseName in currentIdentifiers)) {
return baseName;
}
var count = 0;
while (true) {
count++;
var name_37 = baseName + "_" + count;
if (!(name_37 in currentIdentifiers)) {
return name_37;
}
}
}
function emitExportAssignment(node) {
if (node.expression.kind === 70 /* Identifier */) {
write(node.isExportEquals ? "export = " : "export default ");
writeTextOfNode(currentText, node.expression);
}
else {
// Expression
var tempVarName = getExportDefaultTempVariableName();
if (!noDeclare) {
write("declare ");
}
write("var ");
write(tempVarName);
write(": ");
writer.getSymbolAccessibilityDiagnostic = getDefaultExportAccessibilityDiagnostic;
resolver.writeTypeOfExpression(node.expression, enclosingDeclaration, 2 /* UseTypeOfFunction */ | 1024 /* UseTypeAliasValue */, writer);
write(";");
writeLine();
write(node.isExportEquals ? "export = " : "export default ");
write(tempVarName);
}
write(";");
writeLine();
// Make all the declarations visible for the export name
if (node.expression.kind === 70 /* Identifier */) {
var nodes = resolver.collectLinkedAliases(node.expression);
// write each of these declarations asynchronously
writeAsynchronousModuleElements(nodes);
}
function getDefaultExportAccessibilityDiagnostic() {
return {
diagnosticMessage: ts.Diagnostics.Default_export_of_the_module_has_or_is_using_private_name_0,
errorNode: node
};
}
}
function isModuleElementVisible(node) {
return resolver.isDeclarationVisible(node);
}
function emitModuleElement(node, isModuleElementVisible) {
if (isModuleElementVisible) {
writeModuleElement(node);
}
else if (node.kind === 234 /* ImportEqualsDeclaration */ ||
(node.parent.kind === 261 /* SourceFile */ && isCurrentFileExternalModule)) {
var isVisible = void 0;
if (asynchronousSubModuleDeclarationEmitInfo && node.parent.kind !== 261 /* SourceFile */) {
// Import declaration of another module that is visited async so lets put it in right spot
asynchronousSubModuleDeclarationEmitInfo.push({
node: node,
outputPos: writer.getTextPos(),
indent: writer.getIndent(),
isVisible: isVisible
});
}
else {
if (node.kind === 235 /* ImportDeclaration */) {
var importDeclaration = node;
if (importDeclaration.importClause) {
isVisible = (importDeclaration.importClause.name && resolver.isDeclarationVisible(importDeclaration.importClause)) ||
isVisibleNamedBinding(importDeclaration.importClause.namedBindings);
}
}
moduleElementDeclarationEmitInfo.push({
node: node,
outputPos: writer.getTextPos(),
indent: writer.getIndent(),
isVisible: isVisible
});
}
}
}
function writeModuleElement(node) {
switch (node.kind) {
case 225 /* FunctionDeclaration */:
return writeFunctionDeclaration(node);
case 205 /* VariableStatement */:
return writeVariableStatement(node);
case 227 /* InterfaceDeclaration */:
return writeInterfaceDeclaration(node);
case 226 /* ClassDeclaration */:
return writeClassDeclaration(node);
case 228 /* TypeAliasDeclaration */:
return writeTypeAliasDeclaration(node);
case 229 /* EnumDeclaration */:
return writeEnumDeclaration(node);
case 230 /* ModuleDeclaration */:
return writeModuleDeclaration(node);
case 234 /* ImportEqualsDeclaration */:
return writeImportEqualsDeclaration(node);
case 235 /* ImportDeclaration */:
return writeImportDeclaration(node);
default:
ts.Debug.fail("Unknown symbol kind");
}
}
function emitModuleElementDeclarationFlags(node) {
// If the node is parented in the current source file we need to emit export declare or just export
if (node.parent.kind === 261 /* SourceFile */) {
var modifiers = ts.getModifierFlags(node);
// If the node is exported
if (modifiers & 1 /* Export */) {
write("export ");
}
if (modifiers & 512 /* Default */) {
write("default ");
}
else if (node.kind !== 227 /* InterfaceDeclaration */ && !noDeclare) {
write("declare ");
}
}
}
function emitClassMemberDeclarationFlags(flags) {
if (flags & 8 /* Private */) {
write("private ");
}
else if (flags & 16 /* Protected */) {
write("protected ");
}
if (flags & 32 /* Static */) {
write("static ");
}
if (flags & 64 /* Readonly */) {
write("readonly ");
}
if (flags & 128 /* Abstract */) {
write("abstract ");
}
}
function writeImportEqualsDeclaration(node) {
// note usage of writer. methods instead of aliases created, just to make sure we are using
// correct writer especially to handle asynchronous alias writing
emitJsDocComments(node);
if (ts.hasModifier(node, 1 /* Export */)) {
write("export ");
}
write("import ");
writeTextOfNode(currentText, node.name);
write(" = ");
if (ts.isInternalModuleImportEqualsDeclaration(node)) {
emitTypeWithNewGetSymbolAccessibilityDiagnostic(node.moduleReference, getImportEntityNameVisibilityError);
write(";");
}
else {
write("require(");
emitExternalModuleSpecifier(node);
write(");");
}
writer.writeLine();
function getImportEntityNameVisibilityError() {
return {
diagnosticMessage: ts.Diagnostics.Import_declaration_0_is_using_private_name_1,
errorNode: node,
typeName: node.name
};
}
}
function isVisibleNamedBinding(namedBindings) {
if (namedBindings) {
if (namedBindings.kind === 237 /* NamespaceImport */) {
return resolver.isDeclarationVisible(namedBindings);
}
else {
return ts.forEach(namedBindings.elements, function (namedImport) { return resolver.isDeclarationVisible(namedImport); });
}
}
}
function writeImportDeclaration(node) {
emitJsDocComments(node);
if (ts.hasModifier(node, 1 /* Export */)) {
write("export ");
}
write("import ");
if (node.importClause) {
var currentWriterPos = writer.getTextPos();
if (node.importClause.name && resolver.isDeclarationVisible(node.importClause)) {
writeTextOfNode(currentText, node.importClause.name);
}
if (node.importClause.namedBindings && isVisibleNamedBinding(node.importClause.namedBindings)) {
if (currentWriterPos !== writer.getTextPos()) {
// If the default binding was emitted, write the separated
write(", ");
}
if (node.importClause.namedBindings.kind === 237 /* NamespaceImport */) {
write("* as ");
writeTextOfNode(currentText, node.importClause.namedBindings.name);
}
else {
write("{ ");
emitCommaList(node.importClause.namedBindings.elements, emitImportOrExportSpecifier, resolver.isDeclarationVisible);
write(" }");
}
}
write(" from ");
}
emitExternalModuleSpecifier(node);
write(";");
writer.writeLine();
}
function emitExternalModuleSpecifier(parent) {
// emitExternalModuleSpecifier is usually called when we emit something in the.d.ts file that will make it an external module (i.e. import/export declarations).
// the only case when it is not true is when we call it to emit correct name for module augmentation - d.ts files with just module augmentations are not considered
// external modules since they are indistinguishable from script files with ambient modules. To fix this in such d.ts files we'll emit top level 'export {}'
// so compiler will treat them as external modules.
resultHasExternalModuleIndicator = resultHasExternalModuleIndicator || parent.kind !== 230 /* ModuleDeclaration */;
var moduleSpecifier;
if (parent.kind === 234 /* ImportEqualsDeclaration */) {
var node = parent;
moduleSpecifier = ts.getExternalModuleImportEqualsDeclarationExpression(node);
}
else if (parent.kind === 230 /* ModuleDeclaration */) {
moduleSpecifier = parent.name;
}
else {
var node = parent;
moduleSpecifier = node.moduleSpecifier;
}
if (moduleSpecifier.kind === 9 /* StringLiteral */ && isBundledEmit && (compilerOptions.out || compilerOptions.outFile)) {
var moduleName = ts.getExternalModuleNameFromDeclaration(host, resolver, parent);
if (moduleName) {
write('"');
write(moduleName);
write('"');
return;
}
}
writeTextOfNode(currentText, moduleSpecifier);
}
function emitImportOrExportSpecifier(node) {
if (node.propertyName) {
writeTextOfNode(currentText, node.propertyName);
write(" as ");
}
writeTextOfNode(currentText, node.name);
}
function emitExportSpecifier(node) {
emitImportOrExportSpecifier(node);
// Make all the declarations visible for the export name
var nodes = resolver.collectLinkedAliases(node.propertyName || node.name);
// write each of these declarations asynchronously
writeAsynchronousModuleElements(nodes);
}
function emitExportDeclaration(node) {
emitJsDocComments(node);
write("export ");
if (node.exportClause) {
write("{ ");
emitCommaList(node.exportClause.elements, emitExportSpecifier);
write(" }");
}
else {
write("*");
}
if (node.moduleSpecifier) {
write(" from ");
emitExternalModuleSpecifier(node);
}
write(";");
writer.writeLine();
}
function writeModuleDeclaration(node) {
emitJsDocComments(node);
emitModuleElementDeclarationFlags(node);
if (ts.isGlobalScopeAugmentation(node)) {
write("global ");
}
else {
if (node.flags & 16 /* Namespace */) {
write("namespace ");
}
else {
write("module ");
}
if (ts.isExternalModuleAugmentation(node)) {
emitExternalModuleSpecifier(node);
}
else {
writeTextOfNode(currentText, node.name);
}
}
while (node.body && node.body.kind !== 231 /* ModuleBlock */) {
node = node.body;
write(".");
writeTextOfNode(currentText, node.name);
}
var prevEnclosingDeclaration = enclosingDeclaration;
if (node.body) {
enclosingDeclaration = node;
write(" {");
writeLine();
increaseIndent();
emitLines(node.body.statements);
decreaseIndent();
write("}");
writeLine();
enclosingDeclaration = prevEnclosingDeclaration;
}
else {
write(";");
}
}
function writeTypeAliasDeclaration(node) {
var prevEnclosingDeclaration = enclosingDeclaration;
enclosingDeclaration = node;
emitJsDocComments(node);
emitModuleElementDeclarationFlags(node);
write("type ");
writeTextOfNode(currentText, node.name);
emitTypeParameters(node.typeParameters);
write(" = ");
emitTypeWithNewGetSymbolAccessibilityDiagnostic(node.type, getTypeAliasDeclarationVisibilityError);
write(";");
writeLine();
enclosingDeclaration = prevEnclosingDeclaration;
function getTypeAliasDeclarationVisibilityError() {
return {
diagnosticMessage: ts.Diagnostics.Exported_type_alias_0_has_or_is_using_private_name_1,
errorNode: node.type,
typeName: node.name
};
}
}
function writeEnumDeclaration(node) {
emitJsDocComments(node);
emitModuleElementDeclarationFlags(node);
if (ts.isConst(node)) {
write("const ");
}
write("enum ");
writeTextOfNode(currentText, node.name);
write(" {");
writeLine();
increaseIndent();
emitLines(node.members);
decreaseIndent();
write("}");
writeLine();
}
function emitEnumMemberDeclaration(node) {
emitJsDocComments(node);
writeTextOfNode(currentText, node.name);
var enumMemberValue = resolver.getConstantValue(node);
if (enumMemberValue !== undefined) {
write(" = ");
write(enumMemberValue.toString());
}
write(",");
writeLine();
}
function isPrivateMethodTypeParameter(node) {
return node.parent.kind === 149 /* MethodDeclaration */ && ts.hasModifier(node.parent, 8 /* Private */);
}
function emitTypeParameters(typeParameters) {
function emitTypeParameter(node) {
increaseIndent();
emitJsDocComments(node);
decreaseIndent();
writeTextOfNode(currentText, node.name);
// If there is constraint present and this is not a type parameter of the private method emit the constraint
if (node.constraint && !isPrivateMethodTypeParameter(node)) {
write(" extends ");
if (node.parent.kind === 158 /* FunctionType */ ||
node.parent.kind === 159 /* ConstructorType */ ||
(node.parent.parent && node.parent.parent.kind === 161 /* TypeLiteral */)) {
ts.Debug.assert(node.parent.kind === 149 /* MethodDeclaration */ ||
node.parent.kind === 148 /* MethodSignature */ ||
node.parent.kind === 158 /* FunctionType */ ||
node.parent.kind === 159 /* ConstructorType */ ||
node.parent.kind === 153 /* CallSignature */ ||
node.parent.kind === 154 /* ConstructSignature */);
emitType(node.constraint);
}
else {
emitTypeWithNewGetSymbolAccessibilityDiagnostic(node.constraint, getTypeParameterConstraintVisibilityError);
}
}
function getTypeParameterConstraintVisibilityError() {
// Type parameter constraints are named by user so we should always be able to name it
var diagnosticMessage;
switch (node.parent.kind) {
case 226 /* ClassDeclaration */:
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_exported_class_has_or_is_using_private_name_1;
break;
case 227 /* InterfaceDeclaration */:
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_exported_interface_has_or_is_using_private_name_1;
break;
case 154 /* ConstructSignature */:
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_1;
break;
case 153 /* CallSignature */:
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_call_signature_from_exported_interface_has_or_is_using_private_name_1;
break;
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
if (ts.hasModifier(node.parent, 32 /* Static */)) {
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_public_static_method_from_exported_class_has_or_is_using_private_name_1;
}
else if (node.parent.parent.kind === 226 /* ClassDeclaration */) {
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_public_method_from_exported_class_has_or_is_using_private_name_1;
}
else {
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_method_from_exported_interface_has_or_is_using_private_name_1;
}
break;
case 225 /* FunctionDeclaration */:
diagnosticMessage = ts.Diagnostics.Type_parameter_0_of_exported_function_has_or_is_using_private_name_1;
break;
default:
ts.Debug.fail("This is unknown parent for type parameter: " + node.parent.kind);
}
return {
diagnosticMessage: diagnosticMessage,
errorNode: node,
typeName: node.name
};
}
}
if (typeParameters) {
write("<");
emitCommaList(typeParameters, emitTypeParameter);
write(">");
}
}
function emitHeritageClause(typeReferences, isImplementsList) {
if (typeReferences) {
write(isImplementsList ? " implements " : " extends ");
emitCommaList(typeReferences, emitTypeOfTypeReference);
}
function emitTypeOfTypeReference(node) {
if (ts.isEntityNameExpression(node.expression)) {
emitTypeWithNewGetSymbolAccessibilityDiagnostic(node, getHeritageClauseVisibilityError);
}
else if (!isImplementsList && node.expression.kind === 94 /* NullKeyword */) {
write("null");
}
else {
writer.getSymbolAccessibilityDiagnostic = getHeritageClauseVisibilityError;
resolver.writeBaseConstructorTypeOfClass(enclosingDeclaration, enclosingDeclaration, 2 /* UseTypeOfFunction */ | 1024 /* UseTypeAliasValue */, writer);
}
function getHeritageClauseVisibilityError() {
var diagnosticMessage;
// Heritage clause is written by user so it can always be named
if (node.parent.parent.kind === 226 /* ClassDeclaration */) {
// Class or Interface implemented/extended is inaccessible
diagnosticMessage = isImplementsList ?
ts.Diagnostics.Implements_clause_of_exported_class_0_has_or_is_using_private_name_1 :
ts.Diagnostics.Extends_clause_of_exported_class_0_has_or_is_using_private_name_1;
}
else {
// interface is inaccessible
diagnosticMessage = ts.Diagnostics.Extends_clause_of_exported_interface_0_has_or_is_using_private_name_1;
}
return {
diagnosticMessage: diagnosticMessage,
errorNode: node,
typeName: node.parent.parent.name
};
}
}
}
function writeClassDeclaration(node) {
function emitParameterProperties(constructorDeclaration) {
if (constructorDeclaration) {
ts.forEach(constructorDeclaration.parameters, function (param) {
if (ts.hasModifier(param, 92 /* ParameterPropertyModifier */)) {
emitPropertyDeclaration(param);
}
});
}
}
emitJsDocComments(node);
emitModuleElementDeclarationFlags(node);
if (ts.hasModifier(node, 128 /* Abstract */)) {
write("abstract ");
}
write("class ");
writeTextOfNode(currentText, node.name);
var prevEnclosingDeclaration = enclosingDeclaration;
enclosingDeclaration = node;
emitTypeParameters(node.typeParameters);
var baseTypeNode = ts.getClassExtendsHeritageClauseElement(node);
if (baseTypeNode) {
emitHeritageClause([baseTypeNode], /*isImplementsList*/ false);
}
emitHeritageClause(ts.getClassImplementsHeritageClauseElements(node), /*isImplementsList*/ true);
write(" {");
writeLine();
increaseIndent();
emitParameterProperties(ts.getFirstConstructorWithBody(node));
emitLines(node.members);
decreaseIndent();
write("}");
writeLine();
enclosingDeclaration = prevEnclosingDeclaration;
}
function writeInterfaceDeclaration(node) {
emitJsDocComments(node);
emitModuleElementDeclarationFlags(node);
write("interface ");
writeTextOfNode(currentText, node.name);
var prevEnclosingDeclaration = enclosingDeclaration;
enclosingDeclaration = node;
emitTypeParameters(node.typeParameters);
emitHeritageClause(ts.getInterfaceBaseTypeNodes(node), /*isImplementsList*/ false);
write(" {");
writeLine();
increaseIndent();
emitLines(node.members);
decreaseIndent();
write("}");
writeLine();
enclosingDeclaration = prevEnclosingDeclaration;
}
function emitPropertyDeclaration(node) {
if (ts.hasDynamicName(node)) {
return;
}
emitJsDocComments(node);
emitClassMemberDeclarationFlags(ts.getModifierFlags(node));
emitVariableDeclaration(node);
write(";");
writeLine();
}
function emitVariableDeclaration(node) {
// If we are emitting property it isn't moduleElement and hence we already know it needs to be emitted
// so there is no check needed to see if declaration is visible
if (node.kind !== 223 /* VariableDeclaration */ || resolver.isDeclarationVisible(node)) {
if (ts.isBindingPattern(node.name)) {
emitBindingPattern(node.name);
}
else {
// If this node is a computed name, it can only be a symbol, because we've already skipped
// it if it's not a well known symbol. In that case, the text of the name will be exactly
// what we want, namely the name expression enclosed in brackets.
writeTextOfNode(currentText, node.name);
// If optional property emit ? but in the case of parameterProperty declaration with "?" indicating optional parameter for the constructor
// we don't want to emit property declaration with "?"
if ((node.kind === 147 /* PropertyDeclaration */ || node.kind === 146 /* PropertySignature */ ||
(node.kind === 144 /* Parameter */ && !ts.isParameterPropertyDeclaration(node))) && ts.hasQuestionToken(node)) {
write("?");
}
if ((node.kind === 147 /* PropertyDeclaration */ || node.kind === 146 /* PropertySignature */) && node.parent.kind === 161 /* TypeLiteral */) {
emitTypeOfVariableDeclarationFromTypeLiteral(node);
}
else if (resolver.isLiteralConstDeclaration(node)) {
write(" = ");
resolver.writeLiteralConstValue(node, writer);
}
else if (!ts.hasModifier(node, 8 /* Private */)) {
writeTypeOfDeclaration(node, node.type, getVariableDeclarationTypeVisibilityError);
}
}
}
function getVariableDeclarationTypeVisibilityDiagnosticMessage(symbolAccessibilityResult) {
if (node.kind === 223 /* VariableDeclaration */) {
return symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Exported_variable_0_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named :
ts.Diagnostics.Exported_variable_0_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Exported_variable_0_has_or_is_using_private_name_1;
}
else if (node.kind === 147 /* PropertyDeclaration */ || node.kind === 146 /* PropertySignature */) {
// TODO(jfreeman): Deal with computed properties in error reporting.
if (ts.hasModifier(node, 32 /* Static */)) {
return symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Public_static_property_0_of_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named :
ts.Diagnostics.Public_static_property_0_of_exported_class_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Public_static_property_0_of_exported_class_has_or_is_using_private_name_1;
}
else if (node.parent.kind === 226 /* ClassDeclaration */) {
return symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Public_property_0_of_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named :
ts.Diagnostics.Public_property_0_of_exported_class_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Public_property_0_of_exported_class_has_or_is_using_private_name_1;
}
else {
// Interfaces cannot have types that cannot be named
return symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Property_0_of_exported_interface_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Property_0_of_exported_interface_has_or_is_using_private_name_1;
}
}
}
function getVariableDeclarationTypeVisibilityError(symbolAccessibilityResult) {
var diagnosticMessage = getVariableDeclarationTypeVisibilityDiagnosticMessage(symbolAccessibilityResult);
return diagnosticMessage !== undefined ? {
diagnosticMessage: diagnosticMessage,
errorNode: node,
typeName: node.name
} : undefined;
}
function emitBindingPattern(bindingPattern) {
// Only select non-omitted expression from the bindingPattern's elements.
// We have to do this to avoid emitting trailing commas.
// For example:
// original: var [, c,,] = [ 2,3,4]
// emitted: declare var c: number; // instead of declare var c:number, ;
var elements = [];
for (var _i = 0, _a = bindingPattern.elements; _i < _a.length; _i++) {
var element = _a[_i];
if (element.kind !== 198 /* OmittedExpression */) {
elements.push(element);
}
}
emitCommaList(elements, emitBindingElement);
}
function emitBindingElement(bindingElement) {
function getBindingElementTypeVisibilityError(symbolAccessibilityResult) {
var diagnosticMessage = getVariableDeclarationTypeVisibilityDiagnosticMessage(symbolAccessibilityResult);
return diagnosticMessage !== undefined ? {
diagnosticMessage: diagnosticMessage,
errorNode: bindingElement,
typeName: bindingElement.name
} : undefined;
}
if (bindingElement.name) {
if (ts.isBindingPattern(bindingElement.name)) {
emitBindingPattern(bindingElement.name);
}
else {
writeTextOfNode(currentText, bindingElement.name);
writeTypeOfDeclaration(bindingElement, /*type*/ undefined, getBindingElementTypeVisibilityError);
}
}
}
}
function emitTypeOfVariableDeclarationFromTypeLiteral(node) {
// if this is property of type literal,
// or is parameter of method/call/construct/index signature of type literal
// emit only if type is specified
if (node.type) {
write(": ");
emitType(node.type);
}
}
function isVariableStatementVisible(node) {
return ts.forEach(node.declarationList.declarations, function (varDeclaration) { return resolver.isDeclarationVisible(varDeclaration); });
}
function writeVariableStatement(node) {
emitJsDocComments(node);
emitModuleElementDeclarationFlags(node);
if (ts.isLet(node.declarationList)) {
write("let ");
}
else if (ts.isConst(node.declarationList)) {
write("const ");
}
else {
write("var ");
}
emitCommaList(node.declarationList.declarations, emitVariableDeclaration, resolver.isDeclarationVisible);
write(";");
writeLine();
}
function emitAccessorDeclaration(node) {
if (ts.hasDynamicName(node)) {
return;
}
var accessors = ts.getAllAccessorDeclarations(node.parent.members, node);
var accessorWithTypeAnnotation;
if (node === accessors.firstAccessor) {
emitJsDocComments(accessors.getAccessor);
emitJsDocComments(accessors.setAccessor);
emitClassMemberDeclarationFlags(ts.getModifierFlags(node) | (accessors.setAccessor ? 0 : 64 /* Readonly */));
writeTextOfNode(currentText, node.name);
if (!ts.hasModifier(node, 8 /* Private */)) {
accessorWithTypeAnnotation = node;
var type = getTypeAnnotationFromAccessor(node);
if (!type) {
// couldn't get type for the first accessor, try the another one
var anotherAccessor = node.kind === 151 /* GetAccessor */ ? accessors.setAccessor : accessors.getAccessor;
type = getTypeAnnotationFromAccessor(anotherAccessor);
if (type) {
accessorWithTypeAnnotation = anotherAccessor;
}
}
writeTypeOfDeclaration(node, type, getAccessorDeclarationTypeVisibilityError);
}
write(";");
writeLine();
}
function getTypeAnnotationFromAccessor(accessor) {
if (accessor) {
return accessor.kind === 151 /* GetAccessor */
? accessor.type // Getter - return type
: accessor.parameters.length > 0
? accessor.parameters[0].type // Setter parameter type
: undefined;
}
}
function getAccessorDeclarationTypeVisibilityError(symbolAccessibilityResult) {
var diagnosticMessage;
if (accessorWithTypeAnnotation.kind === 152 /* SetAccessor */) {
// Setters have to have type named and cannot infer it so, the type should always be named
if (ts.hasModifier(accessorWithTypeAnnotation.parent, 32 /* Static */)) {
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Parameter_0_of_public_static_property_setter_from_exported_class_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_public_static_property_setter_from_exported_class_has_or_is_using_private_name_1;
}
else {
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Parameter_0_of_public_property_setter_from_exported_class_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_public_property_setter_from_exported_class_has_or_is_using_private_name_1;
}
return {
diagnosticMessage: diagnosticMessage,
errorNode: accessorWithTypeAnnotation.parameters[0],
// TODO(jfreeman): Investigate why we are passing node.name instead of node.parameters[0].name
typeName: accessorWithTypeAnnotation.name
};
}
else {
if (ts.hasModifier(accessorWithTypeAnnotation, 32 /* Static */)) {
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named :
ts.Diagnostics.Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_public_static_property_getter_from_exported_class_has_or_is_using_private_name_0;
}
else {
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Return_type_of_public_property_getter_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named :
ts.Diagnostics.Return_type_of_public_property_getter_from_exported_class_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_public_property_getter_from_exported_class_has_or_is_using_private_name_0;
}
return {
diagnosticMessage: diagnosticMessage,
errorNode: accessorWithTypeAnnotation.name,
typeName: undefined
};
}
}
}
function writeFunctionDeclaration(node) {
if (ts.hasDynamicName(node)) {
return;
}
// If we are emitting Method/Constructor it isn't moduleElement and hence already determined to be emitting
// so no need to verify if the declaration is visible
if (!resolver.isImplementationOfOverload(node)) {
emitJsDocComments(node);
if (node.kind === 225 /* FunctionDeclaration */) {
emitModuleElementDeclarationFlags(node);
}
else if (node.kind === 149 /* MethodDeclaration */ || node.kind === 150 /* Constructor */) {
emitClassMemberDeclarationFlags(ts.getModifierFlags(node));
}
if (node.kind === 225 /* FunctionDeclaration */) {
write("function ");
writeTextOfNode(currentText, node.name);
}
else if (node.kind === 150 /* Constructor */) {
write("constructor");
}
else {
writeTextOfNode(currentText, node.name);
if (ts.hasQuestionToken(node)) {
write("?");
}
}
emitSignatureDeclaration(node);
}
}
function emitSignatureDeclarationWithJsDocComments(node) {
emitJsDocComments(node);
emitSignatureDeclaration(node);
}
function emitSignatureDeclaration(node) {
var prevEnclosingDeclaration = enclosingDeclaration;
enclosingDeclaration = node;
var closeParenthesizedFunctionType = false;
if (node.kind === 155 /* IndexSignature */) {
// Index signature can have readonly modifier
emitClassMemberDeclarationFlags(ts.getModifierFlags(node));
write("[");
}
else {
// Construct signature or constructor type write new Signature
if (node.kind === 154 /* ConstructSignature */ || node.kind === 159 /* ConstructorType */) {
write("new ");
}
else if (node.kind === 158 /* FunctionType */) {
var currentOutput = writer.getText();
// Do not generate incorrect type when function type with type parameters is type argument
// This could happen if user used space between two '<' making it error free
// e.g var x: A< <Tany>(a: Tany)=>Tany>;
if (node.typeParameters && currentOutput.charAt(currentOutput.length - 1) === "<") {
closeParenthesizedFunctionType = true;
write("(");
}
}
emitTypeParameters(node.typeParameters);
write("(");
}
// Parameters
emitCommaList(node.parameters, emitParameterDeclaration);
if (node.kind === 155 /* IndexSignature */) {
write("]");
}
else {
write(")");
}
// If this is not a constructor and is not private, emit the return type
var isFunctionTypeOrConstructorType = node.kind === 158 /* FunctionType */ || node.kind === 159 /* ConstructorType */;
if (isFunctionTypeOrConstructorType || node.parent.kind === 161 /* TypeLiteral */) {
// Emit type literal signature return type only if specified
if (node.type) {
write(isFunctionTypeOrConstructorType ? " => " : ": ");
emitType(node.type);
}
}
else if (node.kind !== 150 /* Constructor */ && !ts.hasModifier(node, 8 /* Private */)) {
writeReturnTypeAtSignature(node, getReturnTypeVisibilityError);
}
enclosingDeclaration = prevEnclosingDeclaration;
if (!isFunctionTypeOrConstructorType) {
write(";");
writeLine();
}
else if (closeParenthesizedFunctionType) {
write(")");
}
function getReturnTypeVisibilityError(symbolAccessibilityResult) {
var diagnosticMessage;
switch (node.kind) {
case 154 /* ConstructSignature */:
// Interfaces cannot have return types that cannot be named
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Return_type_of_constructor_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_0;
break;
case 153 /* CallSignature */:
// Interfaces cannot have return types that cannot be named
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Return_type_of_call_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_call_signature_from_exported_interface_has_or_is_using_private_name_0;
break;
case 155 /* IndexSignature */:
// Interfaces cannot have return types that cannot be named
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Return_type_of_index_signature_from_exported_interface_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_index_signature_from_exported_interface_has_or_is_using_private_name_0;
break;
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
if (ts.hasModifier(node, 32 /* Static */)) {
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Return_type_of_public_static_method_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named :
ts.Diagnostics.Return_type_of_public_static_method_from_exported_class_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_public_static_method_from_exported_class_has_or_is_using_private_name_0;
}
else if (node.parent.kind === 226 /* ClassDeclaration */) {
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Return_type_of_public_method_from_exported_class_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named :
ts.Diagnostics.Return_type_of_public_method_from_exported_class_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_public_method_from_exported_class_has_or_is_using_private_name_0;
}
else {
// Interfaces cannot have return types that cannot be named
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Return_type_of_method_from_exported_interface_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_method_from_exported_interface_has_or_is_using_private_name_0;
}
break;
case 225 /* FunctionDeclaration */:
diagnosticMessage = symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Return_type_of_exported_function_has_or_is_using_name_0_from_external_module_1_but_cannot_be_named :
ts.Diagnostics.Return_type_of_exported_function_has_or_is_using_name_0_from_private_module_1 :
ts.Diagnostics.Return_type_of_exported_function_has_or_is_using_private_name_0;
break;
default:
ts.Debug.fail("This is unknown kind for signature: " + node.kind);
}
return {
diagnosticMessage: diagnosticMessage,
errorNode: node.name || node
};
}
}
function emitParameterDeclaration(node) {
increaseIndent();
emitJsDocComments(node);
if (node.dotDotDotToken) {
write("...");
}
if (ts.isBindingPattern(node.name)) {
// For bindingPattern, we can't simply writeTextOfNode from the source file
// because we want to omit the initializer and using writeTextOfNode will result in initializer get emitted.
// Therefore, we will have to recursively emit each element in the bindingPattern.
emitBindingPattern(node.name);
}
else {
writeTextOfNode(currentText, node.name);
}
if (resolver.isOptionalParameter(node)) {
write("?");
}
decreaseIndent();
if (node.parent.kind === 158 /* FunctionType */ ||
node.parent.kind === 159 /* ConstructorType */ ||
node.parent.parent.kind === 161 /* TypeLiteral */) {
emitTypeOfVariableDeclarationFromTypeLiteral(node);
}
else if (!ts.hasModifier(node.parent, 8 /* Private */)) {
writeTypeOfDeclaration(node, node.type, getParameterDeclarationTypeVisibilityError);
}
function getParameterDeclarationTypeVisibilityError(symbolAccessibilityResult) {
var diagnosticMessage = getParameterDeclarationTypeVisibilityDiagnosticMessage(symbolAccessibilityResult);
return diagnosticMessage !== undefined ? {
diagnosticMessage: diagnosticMessage,
errorNode: node,
typeName: node.name
} : undefined;
}
function getParameterDeclarationTypeVisibilityDiagnosticMessage(symbolAccessibilityResult) {
switch (node.parent.kind) {
case 150 /* Constructor */:
return symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Parameter_0_of_constructor_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named :
ts.Diagnostics.Parameter_0_of_constructor_from_exported_class_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_constructor_from_exported_class_has_or_is_using_private_name_1;
case 154 /* ConstructSignature */:
// Interfaces cannot have parameter types that cannot be named
return symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_constructor_signature_from_exported_interface_has_or_is_using_private_name_1;
case 153 /* CallSignature */:
// Interfaces cannot have parameter types that cannot be named
return symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Parameter_0_of_call_signature_from_exported_interface_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_call_signature_from_exported_interface_has_or_is_using_private_name_1;
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
if (ts.hasModifier(node.parent, 32 /* Static */)) {
return symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named :
ts.Diagnostics.Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_public_static_method_from_exported_class_has_or_is_using_private_name_1;
}
else if (node.parent.parent.kind === 226 /* ClassDeclaration */) {
return symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Parameter_0_of_public_method_from_exported_class_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named :
ts.Diagnostics.Parameter_0_of_public_method_from_exported_class_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_public_method_from_exported_class_has_or_is_using_private_name_1;
}
else {
// Interfaces cannot have parameter types that cannot be named
return symbolAccessibilityResult.errorModuleName ?
ts.Diagnostics.Parameter_0_of_method_from_exported_interface_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_method_from_exported_interface_has_or_is_using_private_name_1;
}
case 225 /* FunctionDeclaration */:
return symbolAccessibilityResult.errorModuleName ?
symbolAccessibilityResult.accessibility === 2 /* CannotBeNamed */ ?
ts.Diagnostics.Parameter_0_of_exported_function_has_or_is_using_name_1_from_external_module_2_but_cannot_be_named :
ts.Diagnostics.Parameter_0_of_exported_function_has_or_is_using_name_1_from_private_module_2 :
ts.Diagnostics.Parameter_0_of_exported_function_has_or_is_using_private_name_1;
default:
ts.Debug.fail("This is unknown parent for parameter: " + node.parent.kind);
}
}
function emitBindingPattern(bindingPattern) {
// We have to explicitly emit square bracket and bracket because these tokens are not store inside the node.
if (bindingPattern.kind === 172 /* ObjectBindingPattern */) {
write("{");
emitCommaList(bindingPattern.elements, emitBindingElement);
write("}");
}
else if (bindingPattern.kind === 173 /* ArrayBindingPattern */) {
write("[");
var elements = bindingPattern.elements;
emitCommaList(elements, emitBindingElement);
if (elements && elements.hasTrailingComma) {
write(", ");
}
write("]");
}
}
function emitBindingElement(bindingElement) {
if (bindingElement.kind === 198 /* OmittedExpression */) {
// If bindingElement is an omittedExpression (i.e. containing elision),
// we will emit blank space (although this may differ from users' original code,
// it allows emitSeparatedList to write separator appropriately)
// Example:
// original: function foo([, x, ,]) {}
// emit : function foo([ , x, , ]) {}
write(" ");
}
else if (bindingElement.kind === 174 /* BindingElement */) {
if (bindingElement.propertyName) {
// bindingElement has propertyName property in the following case:
// { y: [a,b,c] ...} -> bindingPattern will have a property called propertyName for "y"
// We have to explicitly emit the propertyName before descending into its binding elements.
// Example:
// original: function foo({y: [a,b,c]}) {}
// emit : declare function foo({y: [a, b, c]}: { y: [any, any, any] }) void;
writeTextOfNode(currentText, bindingElement.propertyName);
write(": ");
}
if (bindingElement.name) {
if (ts.isBindingPattern(bindingElement.name)) {
// If it is a nested binding pattern, we will recursively descend into each element and emit each one separately.
// In the case of rest element, we will omit rest element.
// Example:
// original: function foo([a, [[b]], c] = [1,[["string"]], 3]) {}
// emit : declare function foo([a, [[b]], c]: [number, [[string]], number]): void;
// original with rest: function foo([a, ...c]) {}
// emit : declare function foo([a, ...c]): void;
emitBindingPattern(bindingElement.name);
}
else {
ts.Debug.assert(bindingElement.name.kind === 70 /* Identifier */);
// If the node is just an identifier, we will simply emit the text associated with the node's name
// Example:
// original: function foo({y = 10, x}) {}
// emit : declare function foo({y, x}: {number, any}): void;
if (bindingElement.dotDotDotToken) {
write("...");
}
writeTextOfNode(currentText, bindingElement.name);
}
}
}
}
}
function emitNode(node) {
switch (node.kind) {
case 225 /* FunctionDeclaration */:
case 230 /* ModuleDeclaration */:
case 234 /* ImportEqualsDeclaration */:
case 227 /* InterfaceDeclaration */:
case 226 /* ClassDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 229 /* EnumDeclaration */:
return emitModuleElement(node, isModuleElementVisible(node));
case 205 /* VariableStatement */:
return emitModuleElement(node, isVariableStatementVisible(node));
case 235 /* ImportDeclaration */:
// Import declaration without import clause is visible, otherwise it is not visible
return emitModuleElement(node, /*isModuleElementVisible*/ !node.importClause);
case 241 /* ExportDeclaration */:
return emitExportDeclaration(node);
case 150 /* Constructor */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
return writeFunctionDeclaration(node);
case 154 /* ConstructSignature */:
case 153 /* CallSignature */:
case 155 /* IndexSignature */:
return emitSignatureDeclarationWithJsDocComments(node);
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return emitAccessorDeclaration(node);
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
return emitPropertyDeclaration(node);
case 260 /* EnumMember */:
return emitEnumMemberDeclaration(node);
case 240 /* ExportAssignment */:
return emitExportAssignment(node);
case 261 /* SourceFile */:
return emitSourceFile(node);
}
}
/**
* Adds the reference to referenced file, returns true if global file reference was emitted
* @param referencedFile
* @param addBundledFileReference Determines if global file reference corresponding to bundled file should be emitted or not
*/
function writeReferencePath(referencedFile, addBundledFileReference, emitOnlyDtsFiles) {
var declFileName;
var addedBundledEmitReference = false;
if (ts.isDeclarationFile(referencedFile)) {
// Declaration file, use declaration file name
declFileName = referencedFile.fileName;
}
else {
// Get the declaration file path
ts.forEachExpectedEmitFile(host, getDeclFileName, referencedFile, emitOnlyDtsFiles);
}
if (declFileName) {
declFileName = ts.getRelativePathToDirectoryOrUrl(ts.getDirectoryPath(ts.normalizeSlashes(declarationFilePath)), declFileName, host.getCurrentDirectory(), host.getCanonicalFileName,
/*isAbsolutePathAnUrl*/ false);
referencesOutput += "/// <reference path=\"" + declFileName + "\" />" + newLine;
}
return addedBundledEmitReference;
function getDeclFileName(emitFileNames, _sourceFiles, isBundledEmit) {
// Dont add reference path to this file if it is a bundled emit and caller asked not emit bundled file path
if (isBundledEmit && !addBundledFileReference) {
return;
}
ts.Debug.assert(!!emitFileNames.declarationFilePath || ts.isSourceFileJavaScript(referencedFile), "Declaration file is not present only for javascript files");
declFileName = emitFileNames.declarationFilePath || emitFileNames.jsFilePath;
addedBundledEmitReference = isBundledEmit;
}
}
}
/* @internal */
function writeDeclarationFile(declarationFilePath, sourceFiles, isBundledEmit, host, resolver, emitterDiagnostics, emitOnlyDtsFiles) {
var emitDeclarationResult = emitDeclarations(host, resolver, emitterDiagnostics, declarationFilePath, sourceFiles, isBundledEmit, emitOnlyDtsFiles);
var emitSkipped = emitDeclarationResult.reportedDeclarationError || host.isEmitBlocked(declarationFilePath) || host.getCompilerOptions().noEmit;
if (!emitSkipped) {
var declarationOutput = emitDeclarationResult.referencesOutput
+ getDeclarationOutput(emitDeclarationResult.synchronousDeclarationOutput, emitDeclarationResult.moduleElementDeclarationEmitInfo);
ts.writeFile(host, emitterDiagnostics, declarationFilePath, declarationOutput, host.getCompilerOptions().emitBOM, sourceFiles);
}
return emitSkipped;
function getDeclarationOutput(synchronousDeclarationOutput, moduleElementDeclarationEmitInfo) {
var appliedSyncOutputPos = 0;
var declarationOutput = "";
// apply asynchronous additions to the synchronous output
ts.forEach(moduleElementDeclarationEmitInfo, function (aliasEmitInfo) {
if (aliasEmitInfo.asynchronousOutput) {
declarationOutput += synchronousDeclarationOutput.substring(appliedSyncOutputPos, aliasEmitInfo.outputPos);
declarationOutput += getDeclarationOutput(aliasEmitInfo.asynchronousOutput, aliasEmitInfo.subModuleElementDeclarationEmitInfo);
appliedSyncOutputPos = aliasEmitInfo.outputPos;
}
});
declarationOutput += synchronousDeclarationOutput.substring(appliedSyncOutputPos);
return declarationOutput;
}
}
ts.writeDeclarationFile = writeDeclarationFile;
})(ts || (ts = {}));
/// <reference path="checker.ts"/>
/// <reference path="transformer.ts" />
/// <reference path="declarationEmitter.ts"/>
/// <reference path="sourcemap.ts"/>
/// <reference path="comments.ts" />
/* @internal */
var ts;
(function (ts) {
// Flags enum to track count of temp variables and a few dedicated names
var TempFlags;
(function (TempFlags) {
TempFlags[TempFlags["Auto"] = 0] = "Auto";
TempFlags[TempFlags["CountMask"] = 268435455] = "CountMask";
TempFlags[TempFlags["_i"] = 268435456] = "_i";
})(TempFlags || (TempFlags = {}));
var id = function (s) { return s; };
var nullTransformers = [function (_) { return id; }];
// targetSourceFile is when users only want one file in entire project to be emitted. This is used in compileOnSave feature
function emitFiles(resolver, host, targetSourceFile, emitOnlyDtsFiles) {
var delimiters = createDelimiterMap();
var brackets = createBracketsMap();
// emit output for the __extends helper function
var extendsHelper = "\nvar __extends = (this && this.__extends) || function (d, b) {\n for (var p in b) if (b.hasOwnProperty(p)) d[p] = b[p];\n function __() { this.constructor = d; }\n d.prototype = b === null ? Object.create(b) : (__.prototype = b.prototype, new __());\n};";
// Emit output for the __assign helper function.
// This is typically used for JSX spread attributes,
// and can be used for object literal spread properties.
var assignHelper = "\nvar __assign = (this && this.__assign) || Object.assign || function(t) {\n for (var s, i = 1, n = arguments.length; i < n; i++) {\n s = arguments[i];\n for (var p in s) if (Object.prototype.hasOwnProperty.call(s, p))\n t[p] = s[p];\n }\n return t;\n};";
var restHelper = "\nvar __rest = (this && this.__rest) || function (s, e) {\n var t = {};\n for (var p in s) if (Object.prototype.hasOwnProperty.call(s, p) && !e.indexOf(p))\n t[p] = s[p];\n return t;\n};";
// emit output for the __decorate helper function
var decorateHelper = "\nvar __decorate = (this && this.__decorate) || function (decorators, target, key, desc) {\n var c = arguments.length, r = c < 3 ? target : desc === null ? desc = Object.getOwnPropertyDescriptor(target, key) : desc, d;\n if (typeof Reflect === \"object\" && typeof Reflect.decorate === \"function\") r = Reflect.decorate(decorators, target, key, desc);\n else for (var i = decorators.length - 1; i >= 0; i--) if (d = decorators[i]) r = (c < 3 ? d(r) : c > 3 ? d(target, key, r) : d(target, key)) || r;\n return c > 3 && r && Object.defineProperty(target, key, r), r;\n};";
// emit output for the __metadata helper function
var metadataHelper = "\nvar __metadata = (this && this.__metadata) || function (k, v) {\n if (typeof Reflect === \"object\" && typeof Reflect.metadata === \"function\") return Reflect.metadata(k, v);\n};";
// emit output for the __param helper function
var paramHelper = "\nvar __param = (this && this.__param) || function (paramIndex, decorator) {\n return function (target, key) { decorator(target, key, paramIndex); }\n};";
// emit output for the __awaiter helper function
var awaiterHelper = "\nvar __awaiter = (this && this.__awaiter) || function (thisArg, _arguments, P, generator) {\n return new (P || (P = Promise))(function (resolve, reject) {\n function fulfilled(value) { try { step(generator.next(value)); } catch (e) { reject(e); } }\n function rejected(value) { try { step(generator[\"throw\"](value)); } catch (e) { reject(e); } }\n function step(result) { result.done ? resolve(result.value) : new P(function (resolve) { resolve(result.value); }).then(fulfilled, rejected); }\n step((generator = generator.apply(thisArg, _arguments)).next());\n });\n};";
// The __generator helper is used by down-level transformations to emulate the runtime
// semantics of an ES2015 generator function. When called, this helper returns an
// object that implements the Iterator protocol, in that it has `next`, `return`, and
// `throw` methods that step through the generator when invoked.
//
// parameters:
// thisArg The value to use as the `this` binding for the transformed generator body.
// body A function that acts as the transformed generator body.
//
// variables:
// _ Persistent state for the generator that is shared between the helper and the
// generator body. The state object has the following members:
// sent() - A method that returns or throws the current completion value.
// label - The next point at which to resume evaluation of the generator body.
// trys - A stack of protected regions (try/catch/finally blocks).
// ops - A stack of pending instructions when inside of a finally block.
// f A value indicating whether the generator is executing.
// y An iterator to delegate for a yield*.
// t A temporary variable that holds one of the following values (note that these
// cases do not overlap):
// - The completion value when resuming from a `yield` or `yield*`.
// - The error value for a catch block.
// - The current protected region (array of try/catch/finally/end labels).
// - The verb (`next`, `throw`, or `return` method) to delegate to the expression
// of a `yield*`.
// - The result of evaluating the verb delegated to the expression of a `yield*`.
//
// functions:
// verb(n) Creates a bound callback to the `step` function for opcode `n`.
// step(op) Evaluates opcodes in a generator body until execution is suspended or
// completed.
//
// The __generator helper understands a limited set of instructions:
// 0: next(value?) - Start or resume the generator with the specified value.
// 1: throw(error) - Resume the generator with an exception. If the generator is
// suspended inside of one or more protected regions, evaluates
// any intervening finally blocks between the current label and
// the nearest catch block or function boundary. If uncaught, the
// exception is thrown to the caller.
// 2: return(value?) - Resume the generator as if with a return. If the generator is
// suspended inside of one or more protected regions, evaluates any
// intervening finally blocks.
// 3: break(label) - Jump to the specified label. If the label is outside of the
// current protected region, evaluates any intervening finally
// blocks.
// 4: yield(value?) - Yield execution to the caller with an optional value. When
// resumed, the generator will continue at the next label.
// 5: yield*(value) - Delegates evaluation to the supplied iterator. When
// delegation completes, the generator will continue at the next
// label.
// 6: catch(error) - Handles an exception thrown from within the generator body. If
// the current label is inside of one or more protected regions,
// evaluates any intervening finally blocks between the current
// label and the nearest catch block or function boundary. If
// uncaught, the exception is thrown to the caller.
// 7: endfinally - Ends a finally block, resuming the last instruction prior to
// entering a finally block.
//
// For examples of how these are used, see the comments in ./transformers/generators.ts
var generatorHelper = "\nvar __generator = (this && this.__generator) || function (thisArg, body) {\n var _ = { label: 0, sent: function() { if (t[0] & 1) throw t[1]; return t[1]; }, trys: [], ops: [] }, f, y, t;\n return { next: verb(0), \"throw\": verb(1), \"return\": verb(2) };\n function verb(n) { return function (v) { return step([n, v]); }; }\n function step(op) {\n if (f) throw new TypeError(\"Generator is already executing.\");\n while (_) try {\n if (f = 1, y && (t = y[op[0] & 2 ? \"return\" : op[0] ? \"throw\" : \"next\"]) && !(t = t.call(y, op[1])).done) return t;\n if (y = 0, t) op = [0, t.value];\n switch (op[0]) {\n case 0: case 1: t = op; break;\n case 4: _.label++; return { value: op[1], done: false };\n case 5: _.label++; y = op[1]; op = [0]; continue;\n case 7: op = _.ops.pop(); _.trys.pop(); continue;\n default:\n if (!(t = _.trys, t = t.length > 0 && t[t.length - 1]) && (op[0] === 6 || op[0] === 2)) { _ = 0; continue; }\n if (op[0] === 3 && (!t || (op[1] > t[0] && op[1] < t[3]))) { _.label = op[1]; break; }\n if (op[0] === 6 && _.label < t[1]) { _.label = t[1]; t = op; break; }\n if (t && _.label < t[2]) { _.label = t[2]; _.ops.push(op); break; }\n if (t[2]) _.ops.pop();\n _.trys.pop(); continue;\n }\n op = body.call(thisArg, _);\n } catch (e) { op = [6, e]; y = 0; } finally { f = t = 0; }\n if (op[0] & 5) throw op[1]; return { value: op[0] ? op[1] : void 0, done: true };\n }\n};";
// emit output for the __export helper function
var exportStarHelper = "\nfunction __export(m) {\n for (var p in m) if (!exports.hasOwnProperty(p)) exports[p] = m[p];\n}";
// emit output for the UMD helper function.
var umdHelper = "\n(function (dependencies, factory) {\n if (typeof module === 'object' && typeof module.exports === 'object') {\n var v = factory(require, exports); if (v !== undefined) module.exports = v;\n }\n else if (typeof define === 'function' && define.amd) {\n define(dependencies, factory);\n }\n})";
var superHelper = "\nconst _super = name => super[name];";
var advancedSuperHelper = "\nconst _super = (function (geti, seti) {\n const cache = Object.create(null);\n return name => cache[name] || (cache[name] = { get value() { return geti(name); }, set value(v) { seti(name, v); } });\n})(name => super[name], (name, value) => super[name] = value);";
var compilerOptions = host.getCompilerOptions();
var languageVersion = ts.getEmitScriptTarget(compilerOptions);
var moduleKind = ts.getEmitModuleKind(compilerOptions);
var sourceMapDataList = compilerOptions.sourceMap || compilerOptions.inlineSourceMap ? [] : undefined;
var emittedFilesList = compilerOptions.listEmittedFiles ? [] : undefined;
var emitterDiagnostics = ts.createDiagnosticCollection();
var newLine = host.getNewLine();
var transformers = emitOnlyDtsFiles ? nullTransformers : ts.getTransformers(compilerOptions);
var writer = ts.createTextWriter(newLine);
var write = writer.write, writeLine = writer.writeLine, increaseIndent = writer.increaseIndent, decreaseIndent = writer.decreaseIndent;
var sourceMap = ts.createSourceMapWriter(host, writer);
var emitNodeWithSourceMap = sourceMap.emitNodeWithSourceMap, emitTokenWithSourceMap = sourceMap.emitTokenWithSourceMap;
var comments = ts.createCommentWriter(host, writer, sourceMap);
var emitNodeWithComments = comments.emitNodeWithComments, emitBodyWithDetachedComments = comments.emitBodyWithDetachedComments, emitTrailingCommentsOfPosition = comments.emitTrailingCommentsOfPosition;
var nodeIdToGeneratedName;
var autoGeneratedIdToGeneratedName;
var generatedNameSet;
var tempFlags;
var currentSourceFile;
var currentText;
var currentFileIdentifiers;
var extendsEmitted;
var assignEmitted;
var restEmitted;
var decorateEmitted;
var paramEmitted;
var awaiterEmitted;
var isOwnFileEmit;
var emitSkipped = false;
var sourceFiles = ts.getSourceFilesToEmit(host, targetSourceFile);
// Transform the source files
ts.performance.mark("beforeTransform");
var _a = ts.transformFiles(resolver, host, sourceFiles, transformers), transformed = _a.transformed, emitNodeWithSubstitution = _a.emitNodeWithSubstitution, emitNodeWithNotification = _a.emitNodeWithNotification;
ts.performance.measure("transformTime", "beforeTransform");
// Emit each output file
ts.performance.mark("beforePrint");
ts.forEachTransformedEmitFile(host, transformed, emitFile, emitOnlyDtsFiles);
ts.performance.measure("printTime", "beforePrint");
// Clean up emit nodes on parse tree
for (var _b = 0, sourceFiles_4 = sourceFiles; _b < sourceFiles_4.length; _b++) {
var sourceFile = sourceFiles_4[_b];
ts.disposeEmitNodes(sourceFile);
}
return {
emitSkipped: emitSkipped,
diagnostics: emitterDiagnostics.getDiagnostics(),
emittedFiles: emittedFilesList,
sourceMaps: sourceMapDataList
};
function emitFile(jsFilePath, sourceMapFilePath, declarationFilePath, sourceFiles, isBundledEmit) {
// Make sure not to write js file and source map file if any of them cannot be written
if (!host.isEmitBlocked(jsFilePath) && !compilerOptions.noEmit) {
if (!emitOnlyDtsFiles) {
printFile(jsFilePath, sourceMapFilePath, sourceFiles, isBundledEmit);
}
}
else {
emitSkipped = true;
}
if (declarationFilePath) {
emitSkipped = ts.writeDeclarationFile(declarationFilePath, ts.getOriginalSourceFiles(sourceFiles), isBundledEmit, host, resolver, emitterDiagnostics, emitOnlyDtsFiles) || emitSkipped;
}
if (!emitSkipped && emittedFilesList) {
if (!emitOnlyDtsFiles) {
emittedFilesList.push(jsFilePath);
}
if (sourceMapFilePath) {
emittedFilesList.push(sourceMapFilePath);
}
if (declarationFilePath) {
emittedFilesList.push(declarationFilePath);
}
}
}
function printFile(jsFilePath, sourceMapFilePath, sourceFiles, isBundledEmit) {
sourceMap.initialize(jsFilePath, sourceMapFilePath, sourceFiles, isBundledEmit);
nodeIdToGeneratedName = [];
autoGeneratedIdToGeneratedName = [];
generatedNameSet = ts.createMap();
isOwnFileEmit = !isBundledEmit;
// Emit helpers from all the files
if (isBundledEmit && moduleKind) {
for (var _a = 0, sourceFiles_5 = sourceFiles; _a < sourceFiles_5.length; _a++) {
var sourceFile = sourceFiles_5[_a];
emitEmitHelpers(sourceFile);
}
}
// Print each transformed source file.
ts.forEach(sourceFiles, printSourceFile);
writeLine();
var sourceMappingURL = sourceMap.getSourceMappingURL();
if (sourceMappingURL) {
write("//# " + "sourceMappingURL" + "=" + sourceMappingURL); // Sometimes tools can sometimes see this line as a source mapping url comment
}
// Write the source map
if (compilerOptions.sourceMap && !compilerOptions.inlineSourceMap) {
ts.writeFile(host, emitterDiagnostics, sourceMapFilePath, sourceMap.getText(), /*writeByteOrderMark*/ false);
}
// Record source map data for the test harness.
if (sourceMapDataList) {
sourceMapDataList.push(sourceMap.getSourceMapData());
}
// Write the output file
ts.writeFile(host, emitterDiagnostics, jsFilePath, writer.getText(), compilerOptions.emitBOM);
// Reset state
sourceMap.reset();
comments.reset();
writer.reset();
tempFlags = 0 /* Auto */;
currentSourceFile = undefined;
currentText = undefined;
extendsEmitted = false;
assignEmitted = false;
decorateEmitted = false;
paramEmitted = false;
awaiterEmitted = false;
isOwnFileEmit = false;
}
function printSourceFile(node) {
currentSourceFile = node;
currentText = node.text;
currentFileIdentifiers = node.identifiers;
sourceMap.setSourceFile(node);
comments.setSourceFile(node);
pipelineEmitWithNotification(0 /* SourceFile */, node);
}
/**
* Emits a node.
*/
function emit(node) {
pipelineEmitWithNotification(3 /* Unspecified */, node);
}
/**
* Emits an IdentifierName.
*/
function emitIdentifierName(node) {
pipelineEmitWithNotification(2 /* IdentifierName */, node);
}
/**
* Emits an expression node.
*/
function emitExpression(node) {
pipelineEmitWithNotification(1 /* Expression */, node);
}
/**
* Emits a node with possible notification.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called from printSourceFile, emit, emitExpression, or
* emitIdentifierName.
*/
function pipelineEmitWithNotification(emitContext, node) {
emitNodeWithNotification(emitContext, node, pipelineEmitWithComments);
}
/**
* Emits a node with comments.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitWithNotification.
*/
function pipelineEmitWithComments(emitContext, node) {
// Do not emit comments for SourceFile
if (emitContext === 0 /* SourceFile */) {
pipelineEmitWithSourceMap(emitContext, node);
return;
}
emitNodeWithComments(emitContext, node, pipelineEmitWithSourceMap);
}
/**
* Emits a node with source maps.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitWithComments.
*/
function pipelineEmitWithSourceMap(emitContext, node) {
// Do not emit source mappings for SourceFile or IdentifierName
if (emitContext === 0 /* SourceFile */
|| emitContext === 2 /* IdentifierName */) {
pipelineEmitWithSubstitution(emitContext, node);
return;
}
emitNodeWithSourceMap(emitContext, node, pipelineEmitWithSubstitution);
}
/**
* Emits a node with possible substitution.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitWithSourceMap or
* pipelineEmitInUnspecifiedContext (when picking a more specific context).
*/
function pipelineEmitWithSubstitution(emitContext, node) {
emitNodeWithSubstitution(emitContext, node, pipelineEmitForContext);
}
/**
* Emits a node.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitWithSubstitution.
*/
function pipelineEmitForContext(emitContext, node) {
switch (emitContext) {
case 0 /* SourceFile */: return pipelineEmitInSourceFileContext(node);
case 2 /* IdentifierName */: return pipelineEmitInIdentifierNameContext(node);
case 3 /* Unspecified */: return pipelineEmitInUnspecifiedContext(node);
case 1 /* Expression */: return pipelineEmitInExpressionContext(node);
}
}
/**
* Emits a node in the SourceFile EmitContext.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitForContext.
*/
function pipelineEmitInSourceFileContext(node) {
var kind = node.kind;
switch (kind) {
// Top-level nodes
case 261 /* SourceFile */:
return emitSourceFile(node);
}
}
/**
* Emits a node in the IdentifierName EmitContext.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitForContext.
*/
function pipelineEmitInIdentifierNameContext(node) {
var kind = node.kind;
switch (kind) {
// Identifiers
case 70 /* Identifier */:
return emitIdentifier(node);
}
}
/**
* Emits a node in the Unspecified EmitContext.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitForContext.
*/
function pipelineEmitInUnspecifiedContext(node) {
var kind = node.kind;
switch (kind) {
// Pseudo-literals
case 13 /* TemplateHead */:
case 14 /* TemplateMiddle */:
case 15 /* TemplateTail */:
return emitLiteral(node);
// Identifiers
case 70 /* Identifier */:
return emitIdentifier(node);
// Reserved words
case 75 /* ConstKeyword */:
case 78 /* DefaultKeyword */:
case 83 /* ExportKeyword */:
case 104 /* VoidKeyword */:
// Strict mode reserved words
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 113 /* PublicKeyword */:
case 114 /* StaticKeyword */:
// Contextual keywords
case 116 /* AbstractKeyword */:
case 117 /* AsKeyword */:
case 118 /* AnyKeyword */:
case 119 /* AsyncKeyword */:
case 120 /* AwaitKeyword */:
case 121 /* BooleanKeyword */:
case 122 /* ConstructorKeyword */:
case 123 /* DeclareKeyword */:
case 124 /* GetKeyword */:
case 125 /* IsKeyword */:
case 127 /* ModuleKeyword */:
case 128 /* NamespaceKeyword */:
case 129 /* NeverKeyword */:
case 130 /* ReadonlyKeyword */:
case 131 /* RequireKeyword */:
case 132 /* NumberKeyword */:
case 133 /* SetKeyword */:
case 134 /* StringKeyword */:
case 135 /* SymbolKeyword */:
case 136 /* TypeKeyword */:
case 137 /* UndefinedKeyword */:
case 138 /* FromKeyword */:
case 139 /* GlobalKeyword */:
case 140 /* OfKeyword */:
writeTokenText(kind);
return;
// Parse tree nodes
// Names
case 141 /* QualifiedName */:
return emitQualifiedName(node);
case 142 /* ComputedPropertyName */:
return emitComputedPropertyName(node);
// Signature elements
case 143 /* TypeParameter */:
return emitTypeParameter(node);
case 144 /* Parameter */:
return emitParameter(node);
case 145 /* Decorator */:
return emitDecorator(node);
// Type members
case 146 /* PropertySignature */:
return emitPropertySignature(node);
case 147 /* PropertyDeclaration */:
return emitPropertyDeclaration(node);
case 148 /* MethodSignature */:
return emitMethodSignature(node);
case 149 /* MethodDeclaration */:
return emitMethodDeclaration(node);
case 150 /* Constructor */:
return emitConstructor(node);
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return emitAccessorDeclaration(node);
case 153 /* CallSignature */:
return emitCallSignature(node);
case 154 /* ConstructSignature */:
return emitConstructSignature(node);
case 155 /* IndexSignature */:
return emitIndexSignature(node);
// Types
case 156 /* TypePredicate */:
return emitTypePredicate(node);
case 157 /* TypeReference */:
return emitTypeReference(node);
case 158 /* FunctionType */:
return emitFunctionType(node);
case 159 /* ConstructorType */:
return emitConstructorType(node);
case 160 /* TypeQuery */:
return emitTypeQuery(node);
case 161 /* TypeLiteral */:
return emitTypeLiteral(node);
case 162 /* ArrayType */:
return emitArrayType(node);
case 163 /* TupleType */:
return emitTupleType(node);
case 164 /* UnionType */:
return emitUnionType(node);
case 165 /* IntersectionType */:
return emitIntersectionType(node);
case 166 /* ParenthesizedType */:
return emitParenthesizedType(node);
case 199 /* ExpressionWithTypeArguments */:
return emitExpressionWithTypeArguments(node);
case 167 /* ThisType */:
return emitThisType();
case 168 /* TypeOperator */:
return emitTypeOperator(node);
case 169 /* IndexedAccessType */:
return emitIndexedAccessType(node);
case 170 /* MappedType */:
return emitMappedType(node);
case 171 /* LiteralType */:
return emitLiteralType(node);
// Binding patterns
case 172 /* ObjectBindingPattern */:
return emitObjectBindingPattern(node);
case 173 /* ArrayBindingPattern */:
return emitArrayBindingPattern(node);
case 174 /* BindingElement */:
return emitBindingElement(node);
// Misc
case 202 /* TemplateSpan */:
return emitTemplateSpan(node);
case 203 /* SemicolonClassElement */:
return emitSemicolonClassElement();
// Statements
case 204 /* Block */:
return emitBlock(node);
case 205 /* VariableStatement */:
return emitVariableStatement(node);
case 206 /* EmptyStatement */:
return emitEmptyStatement();
case 207 /* ExpressionStatement */:
return emitExpressionStatement(node);
case 208 /* IfStatement */:
return emitIfStatement(node);
case 209 /* DoStatement */:
return emitDoStatement(node);
case 210 /* WhileStatement */:
return emitWhileStatement(node);
case 211 /* ForStatement */:
return emitForStatement(node);
case 212 /* ForInStatement */:
return emitForInStatement(node);
case 213 /* ForOfStatement */:
return emitForOfStatement(node);
case 214 /* ContinueStatement */:
return emitContinueStatement(node);
case 215 /* BreakStatement */:
return emitBreakStatement(node);
case 216 /* ReturnStatement */:
return emitReturnStatement(node);
case 217 /* WithStatement */:
return emitWithStatement(node);
case 218 /* SwitchStatement */:
return emitSwitchStatement(node);
case 219 /* LabeledStatement */:
return emitLabeledStatement(node);
case 220 /* ThrowStatement */:
return emitThrowStatement(node);
case 221 /* TryStatement */:
return emitTryStatement(node);
case 222 /* DebuggerStatement */:
return emitDebuggerStatement(node);
// Declarations
case 223 /* VariableDeclaration */:
return emitVariableDeclaration(node);
case 224 /* VariableDeclarationList */:
return emitVariableDeclarationList(node);
case 225 /* FunctionDeclaration */:
return emitFunctionDeclaration(node);
case 226 /* ClassDeclaration */:
return emitClassDeclaration(node);
case 227 /* InterfaceDeclaration */:
return emitInterfaceDeclaration(node);
case 228 /* TypeAliasDeclaration */:
return emitTypeAliasDeclaration(node);
case 229 /* EnumDeclaration */:
return emitEnumDeclaration(node);
case 230 /* ModuleDeclaration */:
return emitModuleDeclaration(node);
case 231 /* ModuleBlock */:
return emitModuleBlock(node);
case 232 /* CaseBlock */:
return emitCaseBlock(node);
case 234 /* ImportEqualsDeclaration */:
return emitImportEqualsDeclaration(node);
case 235 /* ImportDeclaration */:
return emitImportDeclaration(node);
case 236 /* ImportClause */:
return emitImportClause(node);
case 237 /* NamespaceImport */:
return emitNamespaceImport(node);
case 238 /* NamedImports */:
return emitNamedImports(node);
case 239 /* ImportSpecifier */:
return emitImportSpecifier(node);
case 240 /* ExportAssignment */:
return emitExportAssignment(node);
case 241 /* ExportDeclaration */:
return emitExportDeclaration(node);
case 242 /* NamedExports */:
return emitNamedExports(node);
case 243 /* ExportSpecifier */:
return emitExportSpecifier(node);
case 244 /* MissingDeclaration */:
return;
// Module references
case 245 /* ExternalModuleReference */:
return emitExternalModuleReference(node);
// JSX (non-expression)
case 10 /* JsxText */:
return emitJsxText(node);
case 248 /* JsxOpeningElement */:
return emitJsxOpeningElement(node);
case 249 /* JsxClosingElement */:
return emitJsxClosingElement(node);
case 250 /* JsxAttribute */:
return emitJsxAttribute(node);
case 251 /* JsxSpreadAttribute */:
return emitJsxSpreadAttribute(node);
case 252 /* JsxExpression */:
return emitJsxExpression(node);
// Clauses
case 253 /* CaseClause */:
return emitCaseClause(node);
case 254 /* DefaultClause */:
return emitDefaultClause(node);
case 255 /* HeritageClause */:
return emitHeritageClause(node);
case 256 /* CatchClause */:
return emitCatchClause(node);
// Property assignments
case 257 /* PropertyAssignment */:
return emitPropertyAssignment(node);
case 258 /* ShorthandPropertyAssignment */:
return emitShorthandPropertyAssignment(node);
case 259 /* SpreadAssignment */:
return emitSpreadAssignment(node);
// Enum
case 260 /* EnumMember */:
return emitEnumMember(node);
}
// If the node is an expression, try to emit it as an expression with
// substitution.
if (ts.isExpression(node)) {
return pipelineEmitWithSubstitution(1 /* Expression */, node);
}
}
/**
* Emits a node in the Expression EmitContext.
*
* NOTE: Do not call this method directly. It is part of the emit pipeline
* and should only be called indirectly from pipelineEmitForContext.
*/
function pipelineEmitInExpressionContext(node) {
var kind = node.kind;
switch (kind) {
// Literals
case 8 /* NumericLiteral */:
return emitNumericLiteral(node);
case 9 /* StringLiteral */:
case 11 /* RegularExpressionLiteral */:
case 12 /* NoSubstitutionTemplateLiteral */:
return emitLiteral(node);
// Identifiers
case 70 /* Identifier */:
return emitIdentifier(node);
// Reserved words
case 85 /* FalseKeyword */:
case 94 /* NullKeyword */:
case 96 /* SuperKeyword */:
case 100 /* TrueKeyword */:
case 98 /* ThisKeyword */:
writeTokenText(kind);
return;
// Expressions
case 175 /* ArrayLiteralExpression */:
return emitArrayLiteralExpression(node);
case 176 /* ObjectLiteralExpression */:
return emitObjectLiteralExpression(node);
case 177 /* PropertyAccessExpression */:
return emitPropertyAccessExpression(node);
case 178 /* ElementAccessExpression */:
return emitElementAccessExpression(node);
case 179 /* CallExpression */:
return emitCallExpression(node);
case 180 /* NewExpression */:
return emitNewExpression(node);
case 181 /* TaggedTemplateExpression */:
return emitTaggedTemplateExpression(node);
case 182 /* TypeAssertionExpression */:
return emitTypeAssertionExpression(node);
case 183 /* ParenthesizedExpression */:
return emitParenthesizedExpression(node);
case 184 /* FunctionExpression */:
return emitFunctionExpression(node);
case 185 /* ArrowFunction */:
return emitArrowFunction(node);
case 186 /* DeleteExpression */:
return emitDeleteExpression(node);
case 187 /* TypeOfExpression */:
return emitTypeOfExpression(node);
case 188 /* VoidExpression */:
return emitVoidExpression(node);
case 189 /* AwaitExpression */:
return emitAwaitExpression(node);
case 190 /* PrefixUnaryExpression */:
return emitPrefixUnaryExpression(node);
case 191 /* PostfixUnaryExpression */:
return emitPostfixUnaryExpression(node);
case 192 /* BinaryExpression */:
return emitBinaryExpression(node);
case 193 /* ConditionalExpression */:
return emitConditionalExpression(node);
case 194 /* TemplateExpression */:
return emitTemplateExpression(node);
case 195 /* YieldExpression */:
return emitYieldExpression(node);
case 196 /* SpreadElement */:
return emitSpreadExpression(node);
case 197 /* ClassExpression */:
return emitClassExpression(node);
case 198 /* OmittedExpression */:
return;
case 200 /* AsExpression */:
return emitAsExpression(node);
case 201 /* NonNullExpression */:
return emitNonNullExpression(node);
// JSX
case 246 /* JsxElement */:
return emitJsxElement(node);
case 247 /* JsxSelfClosingElement */:
return emitJsxSelfClosingElement(node);
// Transformation nodes
case 293 /* PartiallyEmittedExpression */:
return emitPartiallyEmittedExpression(node);
}
}
//
// Literals/Pseudo-literals
//
// SyntaxKind.NumericLiteral
function emitNumericLiteral(node) {
emitLiteral(node);
if (node.trailingComment) {
write(" /*" + node.trailingComment + "*/");
}
}
// SyntaxKind.StringLiteral
// SyntaxKind.RegularExpressionLiteral
// SyntaxKind.NoSubstitutionTemplateLiteral
// SyntaxKind.TemplateHead
// SyntaxKind.TemplateMiddle
// SyntaxKind.TemplateTail
function emitLiteral(node) {
var text = getLiteralTextOfNode(node);
if ((compilerOptions.sourceMap || compilerOptions.inlineSourceMap)
&& (node.kind === 9 /* StringLiteral */ || ts.isTemplateLiteralKind(node.kind))) {
writer.writeLiteral(text);
}
else {
write(text);
}
}
//
// Identifiers
//
function emitIdentifier(node) {
if (ts.getEmitFlags(node) & 16 /* UMDDefine */) {
writeLines(umdHelper);
}
else {
write(getTextOfNode(node, /*includeTrivia*/ false));
}
}
//
// Names
//
function emitQualifiedName(node) {
emitEntityName(node.left);
write(".");
emit(node.right);
}
function emitEntityName(node) {
if (node.kind === 70 /* Identifier */) {
emitExpression(node);
}
else {
emit(node);
}
}
function emitComputedPropertyName(node) {
write("[");
emitExpression(node.expression);
write("]");
}
//
// Signature elements
//
function emitTypeParameter(node) {
emit(node.name);
emitWithPrefix(" extends ", node.constraint);
}
function emitParameter(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
writeIfPresent(node.dotDotDotToken, "...");
emit(node.name);
writeIfPresent(node.questionToken, "?");
emitExpressionWithPrefix(" = ", node.initializer);
emitWithPrefix(": ", node.type);
}
function emitDecorator(decorator) {
write("@");
emitExpression(decorator.expression);
}
//
// Type members
//
function emitPropertySignature(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
emit(node.name);
writeIfPresent(node.questionToken, "?");
emitWithPrefix(": ", node.type);
write(";");
}
function emitPropertyDeclaration(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
emit(node.name);
emitWithPrefix(": ", node.type);
emitExpressionWithPrefix(" = ", node.initializer);
write(";");
}
function emitMethodSignature(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
emit(node.name);
writeIfPresent(node.questionToken, "?");
emitTypeParameters(node, node.typeParameters);
emitParameters(node, node.parameters);
emitWithPrefix(": ", node.type);
write(";");
}
function emitMethodDeclaration(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
writeIfPresent(node.asteriskToken, "*");
emit(node.name);
emitSignatureAndBody(node, emitSignatureHead);
}
function emitConstructor(node) {
emitModifiers(node, node.modifiers);
write("constructor");
emitSignatureAndBody(node, emitSignatureHead);
}
function emitAccessorDeclaration(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
write(node.kind === 151 /* GetAccessor */ ? "get " : "set ");
emit(node.name);
emitSignatureAndBody(node, emitSignatureHead);
}
function emitCallSignature(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
emitTypeParameters(node, node.typeParameters);
emitParameters(node, node.parameters);
emitWithPrefix(": ", node.type);
write(";");
}
function emitConstructSignature(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
write("new ");
emitTypeParameters(node, node.typeParameters);
emitParameters(node, node.parameters);
emitWithPrefix(": ", node.type);
write(";");
}
function emitIndexSignature(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
emitParametersForIndexSignature(node, node.parameters);
emitWithPrefix(": ", node.type);
write(";");
}
function emitSemicolonClassElement() {
write(";");
}
//
// Types
//
function emitTypePredicate(node) {
emit(node.parameterName);
write(" is ");
emit(node.type);
}
function emitTypeReference(node) {
emit(node.typeName);
emitTypeArguments(node, node.typeArguments);
}
function emitFunctionType(node) {
emitTypeParameters(node, node.typeParameters);
emitParametersForArrow(node, node.parameters);
write(" => ");
emit(node.type);
}
function emitConstructorType(node) {
write("new ");
emitTypeParameters(node, node.typeParameters);
emitParametersForArrow(node, node.parameters);
write(" => ");
emit(node.type);
}
function emitTypeQuery(node) {
write("typeof ");
emit(node.exprName);
}
function emitTypeLiteral(node) {
write("{");
emitList(node, node.members, 65 /* TypeLiteralMembers */);
write("}");
}
function emitArrayType(node) {
emit(node.elementType);
write("[]");
}
function emitTupleType(node) {
write("[");
emitList(node, node.elementTypes, 336 /* TupleTypeElements */);
write("]");
}
function emitUnionType(node) {
emitList(node, node.types, 260 /* UnionTypeConstituents */);
}
function emitIntersectionType(node) {
emitList(node, node.types, 264 /* IntersectionTypeConstituents */);
}
function emitParenthesizedType(node) {
write("(");
emit(node.type);
write(")");
}
function emitThisType() {
write("this");
}
function emitTypeOperator(node) {
writeTokenText(node.operator);
write(" ");
emit(node.type);
}
function emitIndexedAccessType(node) {
emit(node.objectType);
write("[");
emit(node.indexType);
write("]");
}
function emitMappedType(node) {
write("{");
writeLine();
increaseIndent();
if (node.readonlyToken) {
write("readonly ");
}
write("[");
emit(node.typeParameter.name);
write(" in ");
emit(node.typeParameter.constraint);
write("]");
if (node.questionToken) {
write("?");
}
write(": ");
emit(node.type);
write(";");
writeLine();
decreaseIndent();
write("}");
}
function emitLiteralType(node) {
emitExpression(node.literal);
}
//
// Binding patterns
//
function emitObjectBindingPattern(node) {
var elements = node.elements;
if (elements.length === 0) {
write("{}");
}
else {
write("{");
emitList(node, elements, 432 /* ObjectBindingPatternElements */);
write("}");
}
}
function emitArrayBindingPattern(node) {
var elements = node.elements;
if (elements.length === 0) {
write("[]");
}
else {
write("[");
emitList(node, node.elements, 304 /* ArrayBindingPatternElements */);
write("]");
}
}
function emitBindingElement(node) {
emitWithSuffix(node.propertyName, ": ");
writeIfPresent(node.dotDotDotToken, "...");
emit(node.name);
emitExpressionWithPrefix(" = ", node.initializer);
}
//
// Expressions
//
function emitArrayLiteralExpression(node) {
var elements = node.elements;
if (elements.length === 0) {
write("[]");
}
else {
var preferNewLine = node.multiLine ? 32768 /* PreferNewLine */ : 0 /* None */;
emitExpressionList(node, elements, 4466 /* ArrayLiteralExpressionElements */ | preferNewLine);
}
}
function emitObjectLiteralExpression(node) {
var properties = node.properties;
if (properties.length === 0) {
write("{}");
}
else {
var indentedFlag = ts.getEmitFlags(node) & 524288 /* Indented */;
if (indentedFlag) {
increaseIndent();
}
var preferNewLine = node.multiLine ? 32768 /* PreferNewLine */ : 0 /* None */;
var allowTrailingComma = languageVersion >= 1 /* ES5 */ ? 32 /* AllowTrailingComma */ : 0 /* None */;
emitList(node, properties, 978 /* ObjectLiteralExpressionProperties */ | allowTrailingComma | preferNewLine);
if (indentedFlag) {
decreaseIndent();
}
}
}
function emitPropertyAccessExpression(node) {
var indentBeforeDot = false;
var indentAfterDot = false;
if (!(ts.getEmitFlags(node) & 1048576 /* NoIndentation */)) {
var dotRangeStart = node.expression.end;
var dotRangeEnd = ts.skipTrivia(currentText, node.expression.end) + 1;
var dotToken = { kind: 22 /* DotToken */, pos: dotRangeStart, end: dotRangeEnd };
indentBeforeDot = needsIndentation(node, node.expression, dotToken);
indentAfterDot = needsIndentation(node, dotToken, node.name);
}
emitExpression(node.expression);
increaseIndentIf(indentBeforeDot);
var shouldEmitDotDot = !indentBeforeDot && needsDotDotForPropertyAccess(node.expression);
write(shouldEmitDotDot ? ".." : ".");
increaseIndentIf(indentAfterDot);
emit(node.name);
decreaseIndentIf(indentBeforeDot, indentAfterDot);
}
// 1..toString is a valid property access, emit a dot after the literal
// Also emit a dot if expression is a integer const enum value - it will appear in generated code as numeric literal
function needsDotDotForPropertyAccess(expression) {
if (expression.kind === 8 /* NumericLiteral */) {
// check if numeric literal was originally written with a dot
var text = getLiteralTextOfNode(expression);
return text.indexOf(ts.tokenToString(22 /* DotToken */)) < 0;
}
else if (ts.isPropertyAccessExpression(expression) || ts.isElementAccessExpression(expression)) {
// check if constant enum value is integer
var constantValue = ts.getConstantValue(expression);
// isFinite handles cases when constantValue is undefined
return isFinite(constantValue)
&& Math.floor(constantValue) === constantValue
&& compilerOptions.removeComments;
}
}
function emitElementAccessExpression(node) {
emitExpression(node.expression);
write("[");
emitExpression(node.argumentExpression);
write("]");
}
function emitCallExpression(node) {
emitExpression(node.expression);
emitTypeArguments(node, node.typeArguments);
emitExpressionList(node, node.arguments, 1296 /* CallExpressionArguments */);
}
function emitNewExpression(node) {
write("new ");
emitExpression(node.expression);
emitTypeArguments(node, node.typeArguments);
emitExpressionList(node, node.arguments, 9488 /* NewExpressionArguments */);
}
function emitTaggedTemplateExpression(node) {
emitExpression(node.tag);
write(" ");
emitExpression(node.template);
}
function emitTypeAssertionExpression(node) {
if (node.type) {
write("<");
emit(node.type);
write(">");
}
emitExpression(node.expression);
}
function emitParenthesizedExpression(node) {
write("(");
emitExpression(node.expression);
write(")");
}
function emitFunctionExpression(node) {
emitFunctionDeclarationOrExpression(node);
}
function emitArrowFunction(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
emitSignatureAndBody(node, emitArrowFunctionHead);
}
function emitArrowFunctionHead(node) {
emitTypeParameters(node, node.typeParameters);
emitParametersForArrow(node, node.parameters);
emitWithPrefix(": ", node.type);
write(" =>");
}
function emitDeleteExpression(node) {
write("delete ");
emitExpression(node.expression);
}
function emitTypeOfExpression(node) {
write("typeof ");
emitExpression(node.expression);
}
function emitVoidExpression(node) {
write("void ");
emitExpression(node.expression);
}
function emitAwaitExpression(node) {
write("await ");
emitExpression(node.expression);
}
function emitPrefixUnaryExpression(node) {
writeTokenText(node.operator);
if (shouldEmitWhitespaceBeforeOperand(node)) {
write(" ");
}
emitExpression(node.operand);
}
function shouldEmitWhitespaceBeforeOperand(node) {
// In some cases, we need to emit a space between the operator and the operand. One obvious case
// is when the operator is an identifier, like delete or typeof. We also need to do this for plus
// and minus expressions in certain cases. Specifically, consider the following two cases (parens
// are just for clarity of exposition, and not part of the source code):
//
// (+(+1))
// (+(++1))
//
// We need to emit a space in both cases. In the first case, the absence of a space will make
// the resulting expression a prefix increment operation. And in the second, it will make the resulting
// expression a prefix increment whose operand is a plus expression - (++(+x))
// The same is true of minus of course.
var operand = node.operand;
return operand.kind === 190 /* PrefixUnaryExpression */
&& ((node.operator === 36 /* PlusToken */ && (operand.operator === 36 /* PlusToken */ || operand.operator === 42 /* PlusPlusToken */))
|| (node.operator === 37 /* MinusToken */ && (operand.operator === 37 /* MinusToken */ || operand.operator === 43 /* MinusMinusToken */)));
}
function emitPostfixUnaryExpression(node) {
emitExpression(node.operand);
writeTokenText(node.operator);
}
function emitBinaryExpression(node) {
var isCommaOperator = node.operatorToken.kind !== 25 /* CommaToken */;
var indentBeforeOperator = needsIndentation(node, node.left, node.operatorToken);
var indentAfterOperator = needsIndentation(node, node.operatorToken, node.right);
emitExpression(node.left);
increaseIndentIf(indentBeforeOperator, isCommaOperator ? " " : undefined);
writeTokenText(node.operatorToken.kind);
increaseIndentIf(indentAfterOperator, " ");
emitExpression(node.right);
decreaseIndentIf(indentBeforeOperator, indentAfterOperator);
}
function emitConditionalExpression(node) {
var indentBeforeQuestion = needsIndentation(node, node.condition, node.questionToken);
var indentAfterQuestion = needsIndentation(node, node.questionToken, node.whenTrue);
var indentBeforeColon = needsIndentation(node, node.whenTrue, node.colonToken);
var indentAfterColon = needsIndentation(node, node.colonToken, node.whenFalse);
emitExpression(node.condition);
increaseIndentIf(indentBeforeQuestion, " ");
write("?");
increaseIndentIf(indentAfterQuestion, " ");
emitExpression(node.whenTrue);
decreaseIndentIf(indentBeforeQuestion, indentAfterQuestion);
increaseIndentIf(indentBeforeColon, " ");
write(":");
increaseIndentIf(indentAfterColon, " ");
emitExpression(node.whenFalse);
decreaseIndentIf(indentBeforeColon, indentAfterColon);
}
function emitTemplateExpression(node) {
emit(node.head);
emitList(node, node.templateSpans, 131072 /* TemplateExpressionSpans */);
}
function emitYieldExpression(node) {
write(node.asteriskToken ? "yield*" : "yield");
emitExpressionWithPrefix(" ", node.expression);
}
function emitSpreadExpression(node) {
write("...");
emitExpression(node.expression);
}
function emitClassExpression(node) {
emitClassDeclarationOrExpression(node);
}
function emitExpressionWithTypeArguments(node) {
emitExpression(node.expression);
emitTypeArguments(node, node.typeArguments);
}
function emitAsExpression(node) {
emitExpression(node.expression);
if (node.type) {
write(" as ");
emit(node.type);
}
}
function emitNonNullExpression(node) {
emitExpression(node.expression);
write("!");
}
//
// Misc
//
function emitTemplateSpan(node) {
emitExpression(node.expression);
emit(node.literal);
}
//
// Statements
//
function emitBlock(node) {
if (isSingleLineEmptyBlock(node)) {
writeToken(16 /* OpenBraceToken */, node.pos, /*contextNode*/ node);
write(" ");
writeToken(17 /* CloseBraceToken */, node.statements.end, /*contextNode*/ node);
}
else {
writeToken(16 /* OpenBraceToken */, node.pos, /*contextNode*/ node);
emitBlockStatements(node);
writeToken(17 /* CloseBraceToken */, node.statements.end, /*contextNode*/ node);
}
}
function emitBlockStatements(node) {
if (ts.getEmitFlags(node) & 32 /* SingleLine */) {
emitList(node, node.statements, 384 /* SingleLineBlockStatements */);
}
else {
emitList(node, node.statements, 65 /* MultiLineBlockStatements */);
}
}
function emitVariableStatement(node) {
emitModifiers(node, node.modifiers);
emit(node.declarationList);
write(";");
}
function emitEmptyStatement() {
write(";");
}
function emitExpressionStatement(node) {
emitExpression(node.expression);
write(";");
}
function emitIfStatement(node) {
var openParenPos = writeToken(89 /* IfKeyword */, node.pos, node);
write(" ");
writeToken(18 /* OpenParenToken */, openParenPos, node);
emitExpression(node.expression);
writeToken(19 /* CloseParenToken */, node.expression.end, node);
emitEmbeddedStatement(node.thenStatement);
if (node.elseStatement) {
writeLine();
writeToken(81 /* ElseKeyword */, node.thenStatement.end, node);
if (node.elseStatement.kind === 208 /* IfStatement */) {
write(" ");
emit(node.elseStatement);
}
else {
emitEmbeddedStatement(node.elseStatement);
}
}
}
function emitDoStatement(node) {
write("do");
emitEmbeddedStatement(node.statement);
if (ts.isBlock(node.statement)) {
write(" ");
}
else {
writeLine();
}
write("while (");
emitExpression(node.expression);
write(");");
}
function emitWhileStatement(node) {
write("while (");
emitExpression(node.expression);
write(")");
emitEmbeddedStatement(node.statement);
}
function emitForStatement(node) {
var openParenPos = writeToken(87 /* ForKeyword */, node.pos);
write(" ");
writeToken(18 /* OpenParenToken */, openParenPos, /*contextNode*/ node);
emitForBinding(node.initializer);
write(";");
emitExpressionWithPrefix(" ", node.condition);
write(";");
emitExpressionWithPrefix(" ", node.incrementor);
write(")");
emitEmbeddedStatement(node.statement);
}
function emitForInStatement(node) {
var openParenPos = writeToken(87 /* ForKeyword */, node.pos);
write(" ");
writeToken(18 /* OpenParenToken */, openParenPos);
emitForBinding(node.initializer);
write(" in ");
emitExpression(node.expression);
writeToken(19 /* CloseParenToken */, node.expression.end);
emitEmbeddedStatement(node.statement);
}
function emitForOfStatement(node) {
var openParenPos = writeToken(87 /* ForKeyword */, node.pos);
write(" ");
writeToken(18 /* OpenParenToken */, openParenPos);
emitForBinding(node.initializer);
write(" of ");
emitExpression(node.expression);
writeToken(19 /* CloseParenToken */, node.expression.end);
emitEmbeddedStatement(node.statement);
}
function emitForBinding(node) {
if (node !== undefined) {
if (node.kind === 224 /* VariableDeclarationList */) {
emit(node);
}
else {
emitExpression(node);
}
}
}
function emitContinueStatement(node) {
writeToken(76 /* ContinueKeyword */, node.pos);
emitWithPrefix(" ", node.label);
write(";");
}
function emitBreakStatement(node) {
writeToken(71 /* BreakKeyword */, node.pos);
emitWithPrefix(" ", node.label);
write(";");
}
function emitReturnStatement(node) {
writeToken(95 /* ReturnKeyword */, node.pos, /*contextNode*/ node);
emitExpressionWithPrefix(" ", node.expression);
write(";");
}
function emitWithStatement(node) {
write("with (");
emitExpression(node.expression);
write(")");
emitEmbeddedStatement(node.statement);
}
function emitSwitchStatement(node) {
var openParenPos = writeToken(97 /* SwitchKeyword */, node.pos);
write(" ");
writeToken(18 /* OpenParenToken */, openParenPos);
emitExpression(node.expression);
writeToken(19 /* CloseParenToken */, node.expression.end);
write(" ");
emit(node.caseBlock);
}
function emitLabeledStatement(node) {
emit(node.label);
write(": ");
emit(node.statement);
}
function emitThrowStatement(node) {
write("throw");
emitExpressionWithPrefix(" ", node.expression);
write(";");
}
function emitTryStatement(node) {
write("try ");
emit(node.tryBlock);
emit(node.catchClause);
if (node.finallyBlock) {
writeLine();
write("finally ");
emit(node.finallyBlock);
}
}
function emitDebuggerStatement(node) {
writeToken(77 /* DebuggerKeyword */, node.pos);
write(";");
}
//
// Declarations
//
function emitVariableDeclaration(node) {
emit(node.name);
emitWithPrefix(": ", node.type);
emitExpressionWithPrefix(" = ", node.initializer);
}
function emitVariableDeclarationList(node) {
write(ts.isLet(node) ? "let " : ts.isConst(node) ? "const " : "var ");
emitList(node, node.declarations, 272 /* VariableDeclarationList */);
}
function emitFunctionDeclaration(node) {
emitFunctionDeclarationOrExpression(node);
}
function emitFunctionDeclarationOrExpression(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
write(node.asteriskToken ? "function* " : "function ");
emitIdentifierName(node.name);
emitSignatureAndBody(node, emitSignatureHead);
}
function emitSignatureAndBody(node, emitSignatureHead) {
var body = node.body;
if (body) {
if (ts.isBlock(body)) {
var indentedFlag = ts.getEmitFlags(node) & 524288 /* Indented */;
if (indentedFlag) {
increaseIndent();
}
if (ts.getEmitFlags(node) & 4194304 /* ReuseTempVariableScope */) {
emitSignatureHead(node);
emitBlockFunctionBody(body);
}
else {
var savedTempFlags = tempFlags;
tempFlags = 0;
emitSignatureHead(node);
emitBlockFunctionBody(body);
tempFlags = savedTempFlags;
}
if (indentedFlag) {
decreaseIndent();
}
}
else {
emitSignatureHead(node);
write(" ");
emitExpression(body);
}
}
else {
emitSignatureHead(node);
write(";");
}
}
function emitSignatureHead(node) {
emitTypeParameters(node, node.typeParameters);
emitParameters(node, node.parameters);
emitWithPrefix(": ", node.type);
}
function shouldEmitBlockFunctionBodyOnSingleLine(body) {
// We must emit a function body as a single-line body in the following case:
// * The body has NodeEmitFlags.SingleLine specified.
// We must emit a function body as a multi-line body in the following cases:
// * The body is explicitly marked as multi-line.
// * A non-synthesized body's start and end position are on different lines.
// * Any statement in the body starts on a new line.
if (ts.getEmitFlags(body) & 32 /* SingleLine */) {
return true;
}
if (body.multiLine) {
return false;
}
if (!ts.nodeIsSynthesized(body) && !ts.rangeIsOnSingleLine(body, currentSourceFile)) {
return false;
}
if (shouldWriteLeadingLineTerminator(body, body.statements, 2 /* PreserveLines */)
|| shouldWriteClosingLineTerminator(body, body.statements, 2 /* PreserveLines */)) {
return false;
}
var previousStatement;
for (var _a = 0, _b = body.statements; _a < _b.length; _a++) {
var statement = _b[_a];
if (shouldWriteSeparatingLineTerminator(previousStatement, statement, 2 /* PreserveLines */)) {
return false;
}
previousStatement = statement;
}
return true;
}
function emitBlockFunctionBody(body) {
write(" {");
increaseIndent();
emitBodyWithDetachedComments(body, body.statements, shouldEmitBlockFunctionBodyOnSingleLine(body)
? emitBlockFunctionBodyOnSingleLine
: emitBlockFunctionBodyWorker);
decreaseIndent();
writeToken(17 /* CloseBraceToken */, body.statements.end, body);
}
function emitBlockFunctionBodyOnSingleLine(body) {
emitBlockFunctionBodyWorker(body, /*emitBlockFunctionBodyOnSingleLine*/ true);
}
function emitBlockFunctionBodyWorker(body, emitBlockFunctionBodyOnSingleLine) {
// Emit all the prologue directives (like "use strict").
var statementOffset = emitPrologueDirectives(body.statements, /*startWithNewLine*/ true);
var helpersEmitted = emitHelpers(body);
if (statementOffset === 0 && !helpersEmitted && emitBlockFunctionBodyOnSingleLine) {
decreaseIndent();
emitList(body, body.statements, 384 /* SingleLineFunctionBodyStatements */);
increaseIndent();
}
else {
emitList(body, body.statements, 1 /* MultiLineFunctionBodyStatements */, statementOffset);
}
}
function emitClassDeclaration(node) {
emitClassDeclarationOrExpression(node);
}
function emitClassDeclarationOrExpression(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
write("class");
emitNodeWithPrefix(" ", node.name, emitIdentifierName);
var indentedFlag = ts.getEmitFlags(node) & 524288 /* Indented */;
if (indentedFlag) {
increaseIndent();
}
emitTypeParameters(node, node.typeParameters);
emitList(node, node.heritageClauses, 256 /* ClassHeritageClauses */);
var savedTempFlags = tempFlags;
tempFlags = 0;
write(" {");
emitList(node, node.members, 65 /* ClassMembers */);
write("}");
if (indentedFlag) {
decreaseIndent();
}
tempFlags = savedTempFlags;
}
function emitInterfaceDeclaration(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
write("interface ");
emit(node.name);
emitTypeParameters(node, node.typeParameters);
emitList(node, node.heritageClauses, 256 /* HeritageClauses */);
write(" {");
emitList(node, node.members, 65 /* InterfaceMembers */);
write("}");
}
function emitTypeAliasDeclaration(node) {
emitDecorators(node, node.decorators);
emitModifiers(node, node.modifiers);
write("type ");
emit(node.name);
emitTypeParameters(node, node.typeParameters);
write(" = ");
emit(node.type);
write(";");
}
function emitEnumDeclaration(node) {
emitModifiers(node, node.modifiers);
write("enum ");
emit(node.name);
var savedTempFlags = tempFlags;
tempFlags = 0;
write(" {");
emitList(node, node.members, 81 /* EnumMembers */);
write("}");
tempFlags = savedTempFlags;
}
function emitModuleDeclaration(node) {
emitModifiers(node, node.modifiers);
write(node.flags & 16 /* Namespace */ ? "namespace " : "module ");
emit(node.name);
var body = node.body;
while (body.kind === 230 /* ModuleDeclaration */) {
write(".");
emit(body.name);
body = body.body;
}
write(" ");
emit(body);
}
function emitModuleBlock(node) {
if (isEmptyBlock(node)) {
write("{ }");
}
else {
var savedTempFlags = tempFlags;
tempFlags = 0;
write("{");
increaseIndent();
emitBlockStatements(node);
write("}");
tempFlags = savedTempFlags;
}
}
function emitCaseBlock(node) {
writeToken(16 /* OpenBraceToken */, node.pos);
emitList(node, node.clauses, 65 /* CaseBlockClauses */);
writeToken(17 /* CloseBraceToken */, node.clauses.end);
}
function emitImportEqualsDeclaration(node) {
emitModifiers(node, node.modifiers);
write("import ");
emit(node.name);
write(" = ");
emitModuleReference(node.moduleReference);
write(";");
}
function emitModuleReference(node) {
if (node.kind === 70 /* Identifier */) {
emitExpression(node);
}
else {
emit(node);
}
}
function emitImportDeclaration(node) {
emitModifiers(node, node.modifiers);
write("import ");
if (node.importClause) {
emit(node.importClause);
write(" from ");
}
emitExpression(node.moduleSpecifier);
write(";");
}
function emitImportClause(node) {
emit(node.name);
if (node.name && node.namedBindings) {
write(", ");
}
emit(node.namedBindings);
}
function emitNamespaceImport(node) {
write("* as ");
emit(node.name);
}
function emitNamedImports(node) {
emitNamedImportsOrExports(node);
}
function emitImportSpecifier(node) {
emitImportOrExportSpecifier(node);
}
function emitExportAssignment(node) {
write(node.isExportEquals ? "export = " : "export default ");
emitExpression(node.expression);
write(";");
}
function emitExportDeclaration(node) {
write("export ");
if (node.exportClause) {
emit(node.exportClause);
}
else {
write("*");
}
if (node.moduleSpecifier) {
write(" from ");
emitExpression(node.moduleSpecifier);
}
write(";");
}
function emitNamedExports(node) {
emitNamedImportsOrExports(node);
}
function emitExportSpecifier(node) {
emitImportOrExportSpecifier(node);
}
function emitNamedImportsOrExports(node) {
write("{");
emitList(node, node.elements, 432 /* NamedImportsOrExportsElements */);
write("}");
}
function emitImportOrExportSpecifier(node) {
if (node.propertyName) {
emit(node.propertyName);
write(" as ");
}
emit(node.name);
}
//
// Module references
//
function emitExternalModuleReference(node) {
write("require(");
emitExpression(node.expression);
write(")");
}
//
// JSX
//
function emitJsxElement(node) {
emit(node.openingElement);
emitList(node, node.children, 131072 /* JsxElementChildren */);
emit(node.closingElement);
}
function emitJsxSelfClosingElement(node) {
write("<");
emitJsxTagName(node.tagName);
write(" ");
emitList(node, node.attributes, 131328 /* JsxElementAttributes */);
write("/>");
}
function emitJsxOpeningElement(node) {
write("<");
emitJsxTagName(node.tagName);
writeIfAny(node.attributes, " ");
emitList(node, node.attributes, 131328 /* JsxElementAttributes */);
write(">");
}
function emitJsxText(node) {
writer.writeLiteral(getTextOfNode(node, /*includeTrivia*/ true));
}
function emitJsxClosingElement(node) {
write("</");
emitJsxTagName(node.tagName);
write(">");
}
function emitJsxAttribute(node) {
emit(node.name);
emitWithPrefix("=", node.initializer);
}
function emitJsxSpreadAttribute(node) {
write("{...");
emitExpression(node.expression);
write("}");
}
function emitJsxExpression(node) {
if (node.expression) {
write("{");
emitExpression(node.expression);
write("}");
}
}
function emitJsxTagName(node) {
if (node.kind === 70 /* Identifier */) {
emitExpression(node);
}
else {
emit(node);
}
}
//
// Clauses
//
function emitCaseClause(node) {
write("case ");
emitExpression(node.expression);
write(":");
emitCaseOrDefaultClauseStatements(node, node.statements);
}
function emitDefaultClause(node) {
write("default:");
emitCaseOrDefaultClauseStatements(node, node.statements);
}
function emitCaseOrDefaultClauseStatements(parentNode, statements) {
var emitAsSingleStatement = statements.length === 1 &&
(
// treat synthesized nodes as located on the same line for emit purposes
ts.nodeIsSynthesized(parentNode) ||
ts.nodeIsSynthesized(statements[0]) ||
ts.rangeStartPositionsAreOnSameLine(parentNode, statements[0], currentSourceFile));
if (emitAsSingleStatement) {
write(" ");
emit(statements[0]);
}
else {
emitList(parentNode, statements, 81985 /* CaseOrDefaultClauseStatements */);
}
}
function emitHeritageClause(node) {
write(" ");
writeTokenText(node.token);
write(" ");
emitList(node, node.types, 272 /* HeritageClauseTypes */);
}
function emitCatchClause(node) {
writeLine();
var openParenPos = writeToken(73 /* CatchKeyword */, node.pos);
write(" ");
writeToken(18 /* OpenParenToken */, openParenPos);
emit(node.variableDeclaration);
writeToken(19 /* CloseParenToken */, node.variableDeclaration ? node.variableDeclaration.end : openParenPos);
write(" ");
emit(node.block);
}
//
// Property assignments
//
function emitPropertyAssignment(node) {
emit(node.name);
write(": ");
// This is to ensure that we emit comment in the following case:
// For example:
// obj = {
// id: /*comment1*/ ()=>void
// }
// "comment1" is not considered to be leading comment for node.initializer
// but rather a trailing comment on the previous node.
var initializer = node.initializer;
if ((ts.getEmitFlags(initializer) & 16384 /* NoLeadingComments */) === 0) {
var commentRange = ts.getCommentRange(initializer);
emitTrailingCommentsOfPosition(commentRange.pos);
}
emitExpression(initializer);
}
function emitShorthandPropertyAssignment(node) {
emit(node.name);
if (node.objectAssignmentInitializer) {
write(" = ");
emitExpression(node.objectAssignmentInitializer);
}
}
function emitSpreadAssignment(node) {
if (node.expression) {
write("...");
emitExpression(node.expression);
}
}
//
// Enum
//
function emitEnumMember(node) {
emit(node.name);
emitExpressionWithPrefix(" = ", node.initializer);
}
//
// Top-level nodes
//
function emitSourceFile(node) {
writeLine();
emitShebang();
emitBodyWithDetachedComments(node, node.statements, emitSourceFileWorker);
}
function emitSourceFileWorker(node) {
var statements = node.statements;
var statementOffset = emitPrologueDirectives(statements);
var savedTempFlags = tempFlags;
tempFlags = 0;
emitHelpers(node);
emitList(node, statements, 1 /* MultiLine */, statementOffset);
tempFlags = savedTempFlags;
}
// Transformation nodes
function emitPartiallyEmittedExpression(node) {
emitExpression(node.expression);
}
/**
* Emits any prologue directives at the start of a Statement list, returning the
* number of prologue directives written to the output.
*/
function emitPrologueDirectives(statements, startWithNewLine) {
for (var i = 0; i < statements.length; i++) {
if (ts.isPrologueDirective(statements[i])) {
if (startWithNewLine || i > 0) {
writeLine();
}
emit(statements[i]);
}
else {
// return index of the first non prologue directive
return i;
}
}
return statements.length;
}
function emitHelpers(node) {
var emitFlags = ts.getEmitFlags(node);
var helpersEmitted = false;
if (emitFlags & 1 /* EmitEmitHelpers */) {
helpersEmitted = emitEmitHelpers(currentSourceFile);
}
if (emitFlags & 2 /* EmitExportStar */) {
writeLines(exportStarHelper);
helpersEmitted = true;
}
if (emitFlags & 4 /* EmitSuperHelper */) {
writeLines(superHelper);
helpersEmitted = true;
}
if (emitFlags & 8 /* EmitAdvancedSuperHelper */) {
writeLines(advancedSuperHelper);
helpersEmitted = true;
}
return helpersEmitted;
}
function emitEmitHelpers(node) {
// Only emit helpers if the user did not say otherwise.
if (compilerOptions.noEmitHelpers) {
return false;
}
// Don't emit helpers if we can import them.
if (compilerOptions.importHelpers
&& (ts.isExternalModule(node) || compilerOptions.isolatedModules)) {
return false;
}
var helpersEmitted = false;
// Only Emit __extends function when target ES5.
// For target ES6 and above, we can emit classDeclaration as is.
if ((languageVersion < 2 /* ES2015 */) && (!extendsEmitted && node.flags & 1024 /* HasClassExtends */)) {
writeLines(extendsHelper);
extendsEmitted = true;
helpersEmitted = true;
}
if ((languageVersion < 5 /* ESNext */ || currentSourceFile.scriptKind === 2 /* JSX */ || currentSourceFile.scriptKind === 4 /* TSX */) &&
compilerOptions.jsx !== 1 /* Preserve */ &&
!assignEmitted &&
node.flags & 16384 /* HasSpreadAttribute */) {
writeLines(assignHelper);
assignEmitted = true;
}
if (languageVersion < 5 /* ESNext */ && !restEmitted && node.flags & 32768 /* HasRestAttribute */) {
writeLines(restHelper);
restEmitted = true;
}
if (!decorateEmitted && node.flags & 2048 /* HasDecorators */) {
writeLines(decorateHelper);
if (compilerOptions.emitDecoratorMetadata) {
writeLines(metadataHelper);
}
decorateEmitted = true;
helpersEmitted = true;
}
if (!paramEmitted && node.flags & 4096 /* HasParamDecorators */) {
writeLines(paramHelper);
paramEmitted = true;
helpersEmitted = true;
}
// Only emit __awaiter function when target ES5/ES6.
// Only emit __generator function when target ES5.
// For target ES2017 and above, we can emit async/await as is.
if ((languageVersion < 4 /* ES2017 */) && (!awaiterEmitted && node.flags & 8192 /* HasAsyncFunctions */)) {
writeLines(awaiterHelper);
if (languageVersion < 2 /* ES2015 */) {
writeLines(generatorHelper);
}
awaiterEmitted = true;
helpersEmitted = true;
}
if (helpersEmitted) {
writeLine();
}
return helpersEmitted;
}
function writeLines(text) {
var lines = text.split(/\r\n|\r|\n/g);
for (var i = 0; i < lines.length; i++) {
var line = lines[i];
if (line.length) {
if (i > 0) {
writeLine();
}
write(line);
}
}
}
//
// Helpers
//
function emitShebang() {
var shebang = ts.getShebang(currentText);
if (shebang) {
write(shebang);
writeLine();
}
}
function emitModifiers(node, modifiers) {
if (modifiers && modifiers.length) {
emitList(node, modifiers, 256 /* Modifiers */);
write(" ");
}
}
function emitWithPrefix(prefix, node) {
emitNodeWithPrefix(prefix, node, emit);
}
function emitExpressionWithPrefix(prefix, node) {
emitNodeWithPrefix(prefix, node, emitExpression);
}
function emitNodeWithPrefix(prefix, node, emit) {
if (node) {
write(prefix);
emit(node);
}
}
function emitWithSuffix(node, suffix) {
if (node) {
emit(node);
write(suffix);
}
}
function emitEmbeddedStatement(node) {
if (ts.isBlock(node)) {
write(" ");
emit(node);
}
else {
writeLine();
increaseIndent();
emit(node);
decreaseIndent();
}
}
function emitDecorators(parentNode, decorators) {
emitList(parentNode, decorators, 24577 /* Decorators */);
}
function emitTypeArguments(parentNode, typeArguments) {
emitList(parentNode, typeArguments, 26960 /* TypeArguments */);
}
function emitTypeParameters(parentNode, typeParameters) {
emitList(parentNode, typeParameters, 26960 /* TypeParameters */);
}
function emitParameters(parentNode, parameters) {
emitList(parentNode, parameters, 1360 /* Parameters */);
}
function emitParametersForArrow(parentNode, parameters) {
if (parameters &&
parameters.length === 1 &&
parameters[0].type === undefined &&
parameters[0].pos === parentNode.pos) {
emit(parameters[0]);
}
else {
emitParameters(parentNode, parameters);
}
}
function emitParametersForIndexSignature(parentNode, parameters) {
emitList(parentNode, parameters, 4432 /* IndexSignatureParameters */);
}
function emitList(parentNode, children, format, start, count) {
emitNodeList(emit, parentNode, children, format, start, count);
}
function emitExpressionList(parentNode, children, format, start, count) {
emitNodeList(emitExpression, parentNode, children, format, start, count);
}
function emitNodeList(emit, parentNode, children, format, start, count) {
if (start === void 0) { start = 0; }
if (count === void 0) { count = children ? children.length - start : 0; }
var isUndefined = children === undefined;
if (isUndefined && format & 8192 /* OptionalIfUndefined */) {
return;
}
var isEmpty = isUndefined || children.length === 0 || start >= children.length || count === 0;
if (isEmpty && format & 16384 /* OptionalIfEmpty */) {
return;
}
if (format & 7680 /* BracketsMask */) {
write(getOpeningBracket(format));
}
if (isEmpty) {
// Write a line terminator if the parent node was multi-line
if (format & 1 /* MultiLine */) {
writeLine();
}
else if (format & 128 /* SpaceBetweenBraces */) {
write(" ");
}
}
else {
// Write the opening line terminator or leading whitespace.
var mayEmitInterveningComments = (format & 131072 /* NoInterveningComments */) === 0;
var shouldEmitInterveningComments = mayEmitInterveningComments;
if (shouldWriteLeadingLineTerminator(parentNode, children, format)) {
writeLine();
shouldEmitInterveningComments = false;
}
else if (format & 128 /* SpaceBetweenBraces */) {
write(" ");
}
// Increase the indent, if requested.
if (format & 64 /* Indented */) {
increaseIndent();
}
// Emit each child.
var previousSibling = void 0;
var shouldDecreaseIndentAfterEmit = void 0;
var delimiter = getDelimiter(format);
for (var i = 0; i < count; i++) {
var child = children[start + i];
// Write the delimiter if this is not the first node.
if (previousSibling) {
write(delimiter);
// Write either a line terminator or whitespace to separate the elements.
if (shouldWriteSeparatingLineTerminator(previousSibling, child, format)) {
// If a synthesized node in a single-line list starts on a new
// line, we should increase the indent.
if ((format & (3 /* LinesMask */ | 64 /* Indented */)) === 0 /* SingleLine */) {
increaseIndent();
shouldDecreaseIndentAfterEmit = true;
}
writeLine();
shouldEmitInterveningComments = false;
}
else if (previousSibling && format & 256 /* SpaceBetweenSiblings */) {
write(" ");
}
}
if (shouldEmitInterveningComments) {
var commentRange = ts.getCommentRange(child);
emitTrailingCommentsOfPosition(commentRange.pos);
}
else {
shouldEmitInterveningComments = mayEmitInterveningComments;
}
// Emit this child.
emit(child);
if (shouldDecreaseIndentAfterEmit) {
decreaseIndent();
shouldDecreaseIndentAfterEmit = false;
}
previousSibling = child;
}
// Write a trailing comma, if requested.
var hasTrailingComma = (format & 32 /* AllowTrailingComma */) && children.hasTrailingComma;
if (format & 16 /* CommaDelimited */ && hasTrailingComma) {
write(",");
}
// Decrease the indent, if requested.
if (format & 64 /* Indented */) {
decreaseIndent();
}
// Write the closing line terminator or closing whitespace.
if (shouldWriteClosingLineTerminator(parentNode, children, format)) {
writeLine();
}
else if (format & 128 /* SpaceBetweenBraces */) {
write(" ");
}
}
if (format & 7680 /* BracketsMask */) {
write(getClosingBracket(format));
}
}
function writeIfAny(nodes, text) {
if (nodes && nodes.length > 0) {
write(text);
}
}
function writeIfPresent(node, text) {
if (node !== undefined) {
write(text);
}
}
function writeToken(token, pos, contextNode) {
return emitTokenWithSourceMap(contextNode, token, pos, writeTokenText);
}
function writeTokenText(token, pos) {
var tokenString = ts.tokenToString(token);
write(tokenString);
return pos < 0 ? pos : pos + tokenString.length;
}
function increaseIndentIf(value, valueToWriteWhenNotIndenting) {
if (value) {
increaseIndent();
writeLine();
}
else if (valueToWriteWhenNotIndenting) {
write(valueToWriteWhenNotIndenting);
}
}
// Helper function to decrease the indent if we previously indented. Allows multiple
// previous indent values to be considered at a time. This also allows caller to just
// call this once, passing in all their appropriate indent values, instead of needing
// to call this helper function multiple times.
function decreaseIndentIf(value1, value2) {
if (value1) {
decreaseIndent();
}
if (value2) {
decreaseIndent();
}
}
function shouldWriteLeadingLineTerminator(parentNode, children, format) {
if (format & 1 /* MultiLine */) {
return true;
}
if (format & 2 /* PreserveLines */) {
if (format & 32768 /* PreferNewLine */) {
return true;
}
var firstChild = children[0];
if (firstChild === undefined) {
return !ts.rangeIsOnSingleLine(parentNode, currentSourceFile);
}
else if (ts.positionIsSynthesized(parentNode.pos) || ts.nodeIsSynthesized(firstChild)) {
return synthesizedNodeStartsOnNewLine(firstChild, format);
}
else {
return !ts.rangeStartPositionsAreOnSameLine(parentNode, firstChild, currentSourceFile);
}
}
else {
return false;
}
}
function shouldWriteSeparatingLineTerminator(previousNode, nextNode, format) {
if (format & 1 /* MultiLine */) {
return true;
}
else if (format & 2 /* PreserveLines */) {
if (previousNode === undefined || nextNode === undefined) {
return false;
}
else if (ts.nodeIsSynthesized(previousNode) || ts.nodeIsSynthesized(nextNode)) {
return synthesizedNodeStartsOnNewLine(previousNode, format) || synthesizedNodeStartsOnNewLine(nextNode, format);
}
else {
return !ts.rangeEndIsOnSameLineAsRangeStart(previousNode, nextNode, currentSourceFile);
}
}
else {
return nextNode.startsOnNewLine;
}
}
function shouldWriteClosingLineTerminator(parentNode, children, format) {
if (format & 1 /* MultiLine */) {
return (format & 65536 /* NoTrailingNewLine */) === 0;
}
else if (format & 2 /* PreserveLines */) {
if (format & 32768 /* PreferNewLine */) {
return true;
}
var lastChild = ts.lastOrUndefined(children);
if (lastChild === undefined) {
return !ts.rangeIsOnSingleLine(parentNode, currentSourceFile);
}
else if (ts.positionIsSynthesized(parentNode.pos) || ts.nodeIsSynthesized(lastChild)) {
return synthesizedNodeStartsOnNewLine(lastChild, format);
}
else {
return !ts.rangeEndPositionsAreOnSameLine(parentNode, lastChild, currentSourceFile);
}
}
else {
return false;
}
}
function synthesizedNodeStartsOnNewLine(node, format) {
if (ts.nodeIsSynthesized(node)) {
var startsOnNewLine = node.startsOnNewLine;
if (startsOnNewLine === undefined) {
return (format & 32768 /* PreferNewLine */) !== 0;
}
return startsOnNewLine;
}
return (format & 32768 /* PreferNewLine */) !== 0;
}
function needsIndentation(parent, node1, node2) {
parent = skipSynthesizedParentheses(parent);
node1 = skipSynthesizedParentheses(node1);
node2 = skipSynthesizedParentheses(node2);
// Always use a newline for synthesized code if the synthesizer desires it.
if (node2.startsOnNewLine) {
return true;
}
return !ts.nodeIsSynthesized(parent)
&& !ts.nodeIsSynthesized(node1)
&& !ts.nodeIsSynthesized(node2)
&& !ts.rangeEndIsOnSameLineAsRangeStart(node1, node2, currentSourceFile);
}
function skipSynthesizedParentheses(node) {
while (node.kind === 183 /* ParenthesizedExpression */ && ts.nodeIsSynthesized(node)) {
node = node.expression;
}
return node;
}
function getTextOfNode(node, includeTrivia) {
if (ts.isGeneratedIdentifier(node)) {
return getGeneratedIdentifier(node);
}
else if (ts.isIdentifier(node) && (ts.nodeIsSynthesized(node) || !node.parent)) {
return ts.unescapeIdentifier(node.text);
}
else if (node.kind === 9 /* StringLiteral */ && node.textSourceNode) {
return getTextOfNode(node.textSourceNode, includeTrivia);
}
else if (ts.isLiteralExpression(node) && (ts.nodeIsSynthesized(node) || !node.parent)) {
return node.text;
}
return ts.getSourceTextOfNodeFromSourceFile(currentSourceFile, node, includeTrivia);
}
function getLiteralTextOfNode(node) {
if (node.kind === 9 /* StringLiteral */ && node.textSourceNode) {
var textSourceNode = node.textSourceNode;
if (ts.isIdentifier(textSourceNode)) {
return "\"" + ts.escapeNonAsciiCharacters(ts.escapeString(getTextOfNode(textSourceNode))) + "\"";
}
else {
return getLiteralTextOfNode(textSourceNode);
}
}
return ts.getLiteralText(node, currentSourceFile, languageVersion);
}
function isSingleLineEmptyBlock(block) {
return !block.multiLine
&& isEmptyBlock(block);
}
function isEmptyBlock(block) {
return block.statements.length === 0
&& ts.rangeEndIsOnSameLineAsRangeStart(block, block, currentSourceFile);
}
function isUniqueName(name) {
return !resolver.hasGlobalName(name) &&
!ts.hasProperty(currentFileIdentifiers, name) &&
!ts.hasProperty(generatedNameSet, name);
}
function isUniqueLocalName(name, container) {
for (var node = container; ts.isNodeDescendantOf(node, container); node = node.nextContainer) {
if (node.locals && ts.hasProperty(node.locals, name)) {
// We conservatively include alias symbols to cover cases where they're emitted as locals
if (node.locals[name].flags & (107455 /* Value */ | 1048576 /* ExportValue */ | 8388608 /* Alias */)) {
return false;
}
}
}
return true;
}
/**
* Return the next available name in the pattern _a ... _z, _0, _1, ...
* TempFlags._i or TempFlags._n may be used to express a preference for that dedicated name.
* Note that names generated by makeTempVariableName and makeUniqueName will never conflict.
*/
function makeTempVariableName(flags) {
if (flags && !(tempFlags & flags)) {
var name_38 = flags === 268435456 /* _i */ ? "_i" : "_n";
if (isUniqueName(name_38)) {
tempFlags |= flags;
return name_38;
}
}
while (true) {
var count = tempFlags & 268435455 /* CountMask */;
tempFlags++;
// Skip over 'i' and 'n'
if (count !== 8 && count !== 13) {
var name_39 = count < 26
? "_" + String.fromCharCode(97 /* a */ + count)
: "_" + (count - 26);
if (isUniqueName(name_39)) {
return name_39;
}
}
}
}
// Generate a name that is unique within the current file and doesn't conflict with any names
// in global scope. The name is formed by adding an '_n' suffix to the specified base name,
// where n is a positive integer. Note that names generated by makeTempVariableName and
// makeUniqueName are guaranteed to never conflict.
function makeUniqueName(baseName) {
// Find the first unique 'name_n', where n is a positive number
if (baseName.charCodeAt(baseName.length - 1) !== 95 /* _ */) {
baseName += "_";
}
var i = 1;
while (true) {
var generatedName = baseName + i;
if (isUniqueName(generatedName)) {
return generatedNameSet[generatedName] = generatedName;
}
i++;
}
}
function generateNameForModuleOrEnum(node) {
var name = getTextOfNode(node.name);
// Use module/enum name itself if it is unique, otherwise make a unique variation
return isUniqueLocalName(name, node) ? name : makeUniqueName(name);
}
function generateNameForImportOrExportDeclaration(node) {
var expr = ts.getExternalModuleName(node);
var baseName = expr.kind === 9 /* StringLiteral */ ?
ts.escapeIdentifier(ts.makeIdentifierFromModuleName(expr.text)) : "module";
return makeUniqueName(baseName);
}
function generateNameForExportDefault() {
return makeUniqueName("default");
}
function generateNameForClassExpression() {
return makeUniqueName("class");
}
/**
* Generates a unique name from a node.
*
* @param node A node.
*/
function generateNameForNode(node) {
switch (node.kind) {
case 70 /* Identifier */:
return makeUniqueName(getTextOfNode(node));
case 230 /* ModuleDeclaration */:
case 229 /* EnumDeclaration */:
return generateNameForModuleOrEnum(node);
case 235 /* ImportDeclaration */:
case 241 /* ExportDeclaration */:
return generateNameForImportOrExportDeclaration(node);
case 225 /* FunctionDeclaration */:
case 226 /* ClassDeclaration */:
case 240 /* ExportAssignment */:
return generateNameForExportDefault();
case 197 /* ClassExpression */:
return generateNameForClassExpression();
default:
return makeTempVariableName(0 /* Auto */);
}
}
/**
* Generates a unique identifier for a node.
*
* @param name A generated name.
*/
function generateName(name) {
switch (name.autoGenerateKind) {
case 1 /* Auto */:
return makeTempVariableName(0 /* Auto */);
case 2 /* Loop */:
return makeTempVariableName(268435456 /* _i */);
case 3 /* Unique */:
return makeUniqueName(name.text);
}
ts.Debug.fail("Unsupported GeneratedIdentifierKind.");
}
/**
* Gets the node from which a name should be generated.
*
* @param name A generated name wrapper.
*/
function getNodeForGeneratedName(name) {
var autoGenerateId = name.autoGenerateId;
var node = name;
var original = node.original;
while (original) {
node = original;
// if "node" is a different generated name (having a different
// "autoGenerateId"), use it and stop traversing.
if (ts.isIdentifier(node)
&& node.autoGenerateKind === 4 /* Node */
&& node.autoGenerateId !== autoGenerateId) {
break;
}
original = node.original;
}
// otherwise, return the original node for the source;
return node;
}
/**
* Gets the generated identifier text from a generated identifier.
*
* @param name The generated identifier.
*/
function getGeneratedIdentifier(name) {
if (name.autoGenerateKind === 4 /* Node */) {
// Generated names generate unique names based on their original node
// and are cached based on that node's id
var node = getNodeForGeneratedName(name);
var nodeId = ts.getNodeId(node);
return nodeIdToGeneratedName[nodeId] || (nodeIdToGeneratedName[nodeId] = ts.unescapeIdentifier(generateNameForNode(node)));
}
else {
// Auto, Loop, and Unique names are cached based on their unique
// autoGenerateId.
var autoGenerateId = name.autoGenerateId;
return autoGeneratedIdToGeneratedName[autoGenerateId] || (autoGeneratedIdToGeneratedName[autoGenerateId] = ts.unescapeIdentifier(generateName(name)));
}
}
function createDelimiterMap() {
var delimiters = [];
delimiters[0 /* None */] = "";
delimiters[16 /* CommaDelimited */] = ",";
delimiters[4 /* BarDelimited */] = " |";
delimiters[8 /* AmpersandDelimited */] = " &";
return delimiters;
}
function getDelimiter(format) {
return delimiters[format & 28 /* DelimitersMask */];
}
function createBracketsMap() {
var brackets = [];
brackets[512 /* Braces */] = ["{", "}"];
brackets[1024 /* Parenthesis */] = ["(", ")"];
brackets[2048 /* AngleBrackets */] = ["<", ">"];
brackets[4096 /* SquareBrackets */] = ["[", "]"];
return brackets;
}
function getOpeningBracket(format) {
return brackets[format & 7680 /* BracketsMask */][0];
}
function getClosingBracket(format) {
return brackets[format & 7680 /* BracketsMask */][1];
}
}
ts.emitFiles = emitFiles;
var ListFormat;
(function (ListFormat) {
ListFormat[ListFormat["None"] = 0] = "None";
// Line separators
ListFormat[ListFormat["SingleLine"] = 0] = "SingleLine";
ListFormat[ListFormat["MultiLine"] = 1] = "MultiLine";
ListFormat[ListFormat["PreserveLines"] = 2] = "PreserveLines";
ListFormat[ListFormat["LinesMask"] = 3] = "LinesMask";
// Delimiters
ListFormat[ListFormat["NotDelimited"] = 0] = "NotDelimited";
ListFormat[ListFormat["BarDelimited"] = 4] = "BarDelimited";
ListFormat[ListFormat["AmpersandDelimited"] = 8] = "AmpersandDelimited";
ListFormat[ListFormat["CommaDelimited"] = 16] = "CommaDelimited";
ListFormat[ListFormat["DelimitersMask"] = 28] = "DelimitersMask";
ListFormat[ListFormat["AllowTrailingComma"] = 32] = "AllowTrailingComma";
// Whitespace
ListFormat[ListFormat["Indented"] = 64] = "Indented";
ListFormat[ListFormat["SpaceBetweenBraces"] = 128] = "SpaceBetweenBraces";
ListFormat[ListFormat["SpaceBetweenSiblings"] = 256] = "SpaceBetweenSiblings";
// Brackets/Braces
ListFormat[ListFormat["Braces"] = 512] = "Braces";
ListFormat[ListFormat["Parenthesis"] = 1024] = "Parenthesis";
ListFormat[ListFormat["AngleBrackets"] = 2048] = "AngleBrackets";
ListFormat[ListFormat["SquareBrackets"] = 4096] = "SquareBrackets";
ListFormat[ListFormat["BracketsMask"] = 7680] = "BracketsMask";
ListFormat[ListFormat["OptionalIfUndefined"] = 8192] = "OptionalIfUndefined";
ListFormat[ListFormat["OptionalIfEmpty"] = 16384] = "OptionalIfEmpty";
ListFormat[ListFormat["Optional"] = 24576] = "Optional";
// Other
ListFormat[ListFormat["PreferNewLine"] = 32768] = "PreferNewLine";
ListFormat[ListFormat["NoTrailingNewLine"] = 65536] = "NoTrailingNewLine";
ListFormat[ListFormat["NoInterveningComments"] = 131072] = "NoInterveningComments";
// Precomputed Formats
ListFormat[ListFormat["Modifiers"] = 256] = "Modifiers";
ListFormat[ListFormat["HeritageClauses"] = 256] = "HeritageClauses";
ListFormat[ListFormat["TypeLiteralMembers"] = 65] = "TypeLiteralMembers";
ListFormat[ListFormat["TupleTypeElements"] = 336] = "TupleTypeElements";
ListFormat[ListFormat["UnionTypeConstituents"] = 260] = "UnionTypeConstituents";
ListFormat[ListFormat["IntersectionTypeConstituents"] = 264] = "IntersectionTypeConstituents";
ListFormat[ListFormat["ObjectBindingPatternElements"] = 432] = "ObjectBindingPatternElements";
ListFormat[ListFormat["ArrayBindingPatternElements"] = 304] = "ArrayBindingPatternElements";
ListFormat[ListFormat["ObjectLiteralExpressionProperties"] = 978] = "ObjectLiteralExpressionProperties";
ListFormat[ListFormat["ArrayLiteralExpressionElements"] = 4466] = "ArrayLiteralExpressionElements";
ListFormat[ListFormat["CallExpressionArguments"] = 1296] = "CallExpressionArguments";
ListFormat[ListFormat["NewExpressionArguments"] = 9488] = "NewExpressionArguments";
ListFormat[ListFormat["TemplateExpressionSpans"] = 131072] = "TemplateExpressionSpans";
ListFormat[ListFormat["SingleLineBlockStatements"] = 384] = "SingleLineBlockStatements";
ListFormat[ListFormat["MultiLineBlockStatements"] = 65] = "MultiLineBlockStatements";
ListFormat[ListFormat["VariableDeclarationList"] = 272] = "VariableDeclarationList";
ListFormat[ListFormat["SingleLineFunctionBodyStatements"] = 384] = "SingleLineFunctionBodyStatements";
ListFormat[ListFormat["MultiLineFunctionBodyStatements"] = 1] = "MultiLineFunctionBodyStatements";
ListFormat[ListFormat["ClassHeritageClauses"] = 256] = "ClassHeritageClauses";
ListFormat[ListFormat["ClassMembers"] = 65] = "ClassMembers";
ListFormat[ListFormat["InterfaceMembers"] = 65] = "InterfaceMembers";
ListFormat[ListFormat["EnumMembers"] = 81] = "EnumMembers";
ListFormat[ListFormat["CaseBlockClauses"] = 65] = "CaseBlockClauses";
ListFormat[ListFormat["NamedImportsOrExportsElements"] = 432] = "NamedImportsOrExportsElements";
ListFormat[ListFormat["JsxElementChildren"] = 131072] = "JsxElementChildren";
ListFormat[ListFormat["JsxElementAttributes"] = 131328] = "JsxElementAttributes";
ListFormat[ListFormat["CaseOrDefaultClauseStatements"] = 81985] = "CaseOrDefaultClauseStatements";
ListFormat[ListFormat["HeritageClauseTypes"] = 272] = "HeritageClauseTypes";
ListFormat[ListFormat["SourceFileStatements"] = 65537] = "SourceFileStatements";
ListFormat[ListFormat["Decorators"] = 24577] = "Decorators";
ListFormat[ListFormat["TypeArguments"] = 26960] = "TypeArguments";
ListFormat[ListFormat["TypeParameters"] = 26960] = "TypeParameters";
ListFormat[ListFormat["Parameters"] = 1360] = "Parameters";
ListFormat[ListFormat["IndexSignatureParameters"] = 4432] = "IndexSignatureParameters";
})(ListFormat || (ListFormat = {}));
})(ts || (ts = {}));
/// <reference path="sys.ts" />
/// <reference path="emitter.ts" />
/// <reference path="core.ts" />
var ts;
(function (ts) {
/** The version of the TypeScript compiler release */
ts.version = "2.2.0";
var emptyArray = [];
function findConfigFile(searchPath, fileExists, configName) {
if (configName === void 0) { configName = "tsconfig.json"; }
while (true) {
var fileName = ts.combinePaths(searchPath, configName);
if (fileExists(fileName)) {
return fileName;
}
var parentPath = ts.getDirectoryPath(searchPath);
if (parentPath === searchPath) {
break;
}
searchPath = parentPath;
}
return undefined;
}
ts.findConfigFile = findConfigFile;
function resolveTripleslashReference(moduleName, containingFile) {
var basePath = ts.getDirectoryPath(containingFile);
var referencedFileName = ts.isRootedDiskPath(moduleName) ? moduleName : ts.combinePaths(basePath, moduleName);
return ts.normalizePath(referencedFileName);
}
ts.resolveTripleslashReference = resolveTripleslashReference;
/* @internal */
function computeCommonSourceDirectoryOfFilenames(fileNames, currentDirectory, getCanonicalFileName) {
var commonPathComponents;
var failed = ts.forEach(fileNames, function (sourceFile) {
// Each file contributes into common source file path
var sourcePathComponents = ts.getNormalizedPathComponents(sourceFile, currentDirectory);
sourcePathComponents.pop(); // The base file name is not part of the common directory path
if (!commonPathComponents) {
// first file
commonPathComponents = sourcePathComponents;
return;
}
for (var i = 0, n = Math.min(commonPathComponents.length, sourcePathComponents.length); i < n; i++) {
if (getCanonicalFileName(commonPathComponents[i]) !== getCanonicalFileName(sourcePathComponents[i])) {
if (i === 0) {
// Failed to find any common path component
return true;
}
// New common path found that is 0 -> i-1
commonPathComponents.length = i;
break;
}
}
// If the sourcePathComponents was shorter than the commonPathComponents, truncate to the sourcePathComponents
if (sourcePathComponents.length < commonPathComponents.length) {
commonPathComponents.length = sourcePathComponents.length;
}
});
// A common path can not be found when paths span multiple drives on windows, for example
if (failed) {
return "";
}
if (!commonPathComponents) {
return currentDirectory;
}
return ts.getNormalizedPathFromPathComponents(commonPathComponents);
}
ts.computeCommonSourceDirectoryOfFilenames = computeCommonSourceDirectoryOfFilenames;
function createCompilerHost(options, setParentNodes) {
var existingDirectories = ts.createMap();
function getCanonicalFileName(fileName) {
// if underlying system can distinguish between two files whose names differs only in cases then file name already in canonical form.
// otherwise use toLowerCase as a canonical form.
return ts.sys.useCaseSensitiveFileNames ? fileName : fileName.toLowerCase();
}
// returned by CScript sys environment
var unsupportedFileEncodingErrorCode = -2147024809;
function getSourceFile(fileName, languageVersion, onError) {
var text;
try {
ts.performance.mark("beforeIORead");
text = ts.sys.readFile(fileName, options.charset);
ts.performance.mark("afterIORead");
ts.performance.measure("I/O Read", "beforeIORead", "afterIORead");
}
catch (e) {
if (onError) {
onError(e.number === unsupportedFileEncodingErrorCode
? ts.createCompilerDiagnostic(ts.Diagnostics.Unsupported_file_encoding).messageText
: e.message);
}
text = "";
}
return text !== undefined ? ts.createSourceFile(fileName, text, languageVersion, setParentNodes) : undefined;
}
function directoryExists(directoryPath) {
if (directoryPath in existingDirectories) {
return true;
}
if (ts.sys.directoryExists(directoryPath)) {
existingDirectories[directoryPath] = true;
return true;
}
return false;
}
function ensureDirectoriesExist(directoryPath) {
if (directoryPath.length > ts.getRootLength(directoryPath) && !directoryExists(directoryPath)) {
var parentDirectory = ts.getDirectoryPath(directoryPath);
ensureDirectoriesExist(parentDirectory);
ts.sys.createDirectory(directoryPath);
}
}
var outputFingerprints;
function writeFileIfUpdated(fileName, data, writeByteOrderMark) {
if (!outputFingerprints) {
outputFingerprints = ts.createMap();
}
var hash = ts.sys.createHash(data);
var mtimeBefore = ts.sys.getModifiedTime(fileName);
if (mtimeBefore && fileName in outputFingerprints) {
var fingerprint = outputFingerprints[fileName];
// If output has not been changed, and the file has no external modification
if (fingerprint.byteOrderMark === writeByteOrderMark &&
fingerprint.hash === hash &&
fingerprint.mtime.getTime() === mtimeBefore.getTime()) {
return;
}
}
ts.sys.writeFile(fileName, data, writeByteOrderMark);
var mtimeAfter = ts.sys.getModifiedTime(fileName);
outputFingerprints[fileName] = {
hash: hash,
byteOrderMark: writeByteOrderMark,
mtime: mtimeAfter
};
}
function writeFile(fileName, data, writeByteOrderMark, onError) {
try {
ts.performance.mark("beforeIOWrite");
ensureDirectoriesExist(ts.getDirectoryPath(ts.normalizePath(fileName)));
if (ts.isWatchSet(options) && ts.sys.createHash && ts.sys.getModifiedTime) {
writeFileIfUpdated(fileName, data, writeByteOrderMark);
}
else {
ts.sys.writeFile(fileName, data, writeByteOrderMark);
}
ts.performance.mark("afterIOWrite");
ts.performance.measure("I/O Write", "beforeIOWrite", "afterIOWrite");
}
catch (e) {
if (onError) {
onError(e.message);
}
}
}
function getDefaultLibLocation() {
return ts.getDirectoryPath(ts.normalizePath(ts.sys.getExecutingFilePath()));
}
var newLine = ts.getNewLineCharacter(options);
var realpath = ts.sys.realpath && (function (path) { return ts.sys.realpath(path); });
return {
getSourceFile: getSourceFile,
getDefaultLibLocation: getDefaultLibLocation,
getDefaultLibFileName: function (options) { return ts.combinePaths(getDefaultLibLocation(), ts.getDefaultLibFileName(options)); },
writeFile: writeFile,
getCurrentDirectory: ts.memoize(function () { return ts.sys.getCurrentDirectory(); }),
useCaseSensitiveFileNames: function () { return ts.sys.useCaseSensitiveFileNames; },
getCanonicalFileName: getCanonicalFileName,
getNewLine: function () { return newLine; },
fileExists: function (fileName) { return ts.sys.fileExists(fileName); },
readFile: function (fileName) { return ts.sys.readFile(fileName); },
trace: function (s) { return ts.sys.write(s + newLine); },
directoryExists: function (directoryName) { return ts.sys.directoryExists(directoryName); },
getEnvironmentVariable: function (name) { return ts.sys.getEnvironmentVariable ? ts.sys.getEnvironmentVariable(name) : ""; },
getDirectories: function (path) { return ts.sys.getDirectories(path); },
realpath: realpath
};
}
ts.createCompilerHost = createCompilerHost;
function getPreEmitDiagnostics(program, sourceFile, cancellationToken) {
var diagnostics = program.getOptionsDiagnostics(cancellationToken).concat(program.getSyntacticDiagnostics(sourceFile, cancellationToken), program.getGlobalDiagnostics(cancellationToken), program.getSemanticDiagnostics(sourceFile, cancellationToken));
if (program.getCompilerOptions().declaration) {
diagnostics = diagnostics.concat(program.getDeclarationDiagnostics(sourceFile, cancellationToken));
}
return ts.sortAndDeduplicateDiagnostics(diagnostics);
}
ts.getPreEmitDiagnostics = getPreEmitDiagnostics;
function formatDiagnostics(diagnostics, host) {
var output = "";
for (var _i = 0, diagnostics_1 = diagnostics; _i < diagnostics_1.length; _i++) {
var diagnostic = diagnostics_1[_i];
if (diagnostic.file) {
var _a = ts.getLineAndCharacterOfPosition(diagnostic.file, diagnostic.start), line = _a.line, character = _a.character;
var fileName = diagnostic.file.fileName;
var relativeFileName = ts.convertToRelativePath(fileName, host.getCurrentDirectory(), function (fileName) { return host.getCanonicalFileName(fileName); });
output += relativeFileName + "(" + (line + 1) + "," + (character + 1) + "): ";
}
var category = ts.DiagnosticCategory[diagnostic.category].toLowerCase();
output += category + " TS" + diagnostic.code + ": " + flattenDiagnosticMessageText(diagnostic.messageText, host.getNewLine()) + host.getNewLine();
}
return output;
}
ts.formatDiagnostics = formatDiagnostics;
function flattenDiagnosticMessageText(messageText, newLine) {
if (typeof messageText === "string") {
return messageText;
}
else {
var diagnosticChain = messageText;
var result = "";
var indent = 0;
while (diagnosticChain) {
if (indent) {
result += newLine;
for (var i = 0; i < indent; i++) {
result += " ";
}
}
result += diagnosticChain.messageText;
indent++;
diagnosticChain = diagnosticChain.next;
}
return result;
}
}
ts.flattenDiagnosticMessageText = flattenDiagnosticMessageText;
function loadWithLocalCache(names, containingFile, loader) {
if (names.length === 0) {
return [];
}
var resolutions = [];
var cache = ts.createMap();
for (var _i = 0, names_1 = names; _i < names_1.length; _i++) {
var name_40 = names_1[_i];
var result = name_40 in cache
? cache[name_40]
: cache[name_40] = loader(name_40, containingFile);
resolutions.push(result);
}
return resolutions;
}
function createProgram(rootNames, options, host, oldProgram) {
var program;
var files = [];
var commonSourceDirectory;
var diagnosticsProducingTypeChecker;
var noDiagnosticsTypeChecker;
var classifiableNames;
var resolvedTypeReferenceDirectives = ts.createMap();
var fileProcessingDiagnostics = ts.createDiagnosticCollection();
// The below settings are to track if a .js file should be add to the program if loaded via searching under node_modules.
// This works as imported modules are discovered recursively in a depth first manner, specifically:
// - For each root file, findSourceFile is called.
// - This calls processImportedModules for each module imported in the source file.
// - This calls resolveModuleNames, and then calls findSourceFile for each resolved module.
// As all these operations happen - and are nested - within the createProgram call, they close over the below variables.
// The current resolution depth is tracked by incrementing/decrementing as the depth first search progresses.
var maxNodeModuleJsDepth = typeof options.maxNodeModuleJsDepth === "number" ? options.maxNodeModuleJsDepth : 0;
var currentNodeModulesDepth = 0;
// If a module has some of its imports skipped due to being at the depth limit under node_modules, then track
// this, as it may be imported at a shallower depth later, and then it will need its skipped imports processed.
var modulesWithElidedImports = ts.createMap();
// Track source files that are source files found by searching under node_modules, as these shouldn't be compiled.
var sourceFilesFoundSearchingNodeModules = ts.createMap();
ts.performance.mark("beforeProgram");
host = host || createCompilerHost(options);
var skipDefaultLib = options.noLib;
var programDiagnostics = ts.createDiagnosticCollection();
var currentDirectory = host.getCurrentDirectory();
var supportedExtensions = ts.getSupportedExtensions(options);
// Map storing if there is emit blocking diagnostics for given input
var hasEmitBlockingDiagnostics = ts.createFileMap(getCanonicalFileName);
var resolveModuleNamesWorker;
if (host.resolveModuleNames) {
resolveModuleNamesWorker = function (moduleNames, containingFile) { return host.resolveModuleNames(moduleNames, containingFile).map(function (resolved) {
// An older host may have omitted extension, in which case we should infer it from the file extension of resolvedFileName.
if (!resolved || resolved.extension !== undefined) {
return resolved;
}
var withExtension = ts.clone(resolved);
withExtension.extension = ts.extensionFromPath(resolved.resolvedFileName);
return withExtension;
}); };
}
else {
var loader_1 = function (moduleName, containingFile) { return ts.resolveModuleName(moduleName, containingFile, options, host).resolvedModule; };
resolveModuleNamesWorker = function (moduleNames, containingFile) { return loadWithLocalCache(moduleNames, containingFile, loader_1); };
}
var resolveTypeReferenceDirectiveNamesWorker;
if (host.resolveTypeReferenceDirectives) {
resolveTypeReferenceDirectiveNamesWorker = function (typeDirectiveNames, containingFile) { return host.resolveTypeReferenceDirectives(typeDirectiveNames, containingFile); };
}
else {
var loader_2 = function (typesRef, containingFile) { return ts.resolveTypeReferenceDirective(typesRef, containingFile, options, host).resolvedTypeReferenceDirective; };
resolveTypeReferenceDirectiveNamesWorker = function (typeReferenceDirectiveNames, containingFile) { return loadWithLocalCache(typeReferenceDirectiveNames, containingFile, loader_2); };
}
var filesByName = ts.createFileMap();
// stores 'filename -> file association' ignoring case
// used to track cases when two file names differ only in casing
var filesByNameIgnoreCase = host.useCaseSensitiveFileNames() ? ts.createFileMap(function (fileName) { return fileName.toLowerCase(); }) : undefined;
if (!tryReuseStructureFromOldProgram()) {
ts.forEach(rootNames, function (name) { return processRootFile(name, /*isDefaultLib*/ false); });
// load type declarations specified via 'types' argument or implicitly from types/ and node_modules/@types folders
var typeReferences = ts.getAutomaticTypeDirectiveNames(options, host);
if (typeReferences.length) {
// This containingFilename needs to match with the one used in managed-side
var containingFilename = ts.combinePaths(host.getCurrentDirectory(), "__inferred type names__.ts");
var resolutions = resolveTypeReferenceDirectiveNamesWorker(typeReferences, containingFilename);
for (var i = 0; i < typeReferences.length; i++) {
processTypeReferenceDirective(typeReferences[i], resolutions[i]);
}
}
// Do not process the default library if:
// - The '--noLib' flag is used.
// - A 'no-default-lib' reference comment is encountered in
// processing the root files.
if (!skipDefaultLib) {
// If '--lib' is not specified, include default library file according to '--target'
// otherwise, using options specified in '--lib' instead of '--target' default library file
if (!options.lib) {
processRootFile(host.getDefaultLibFileName(options), /*isDefaultLib*/ true);
}
else {
var libDirectory_1 = host.getDefaultLibLocation ? host.getDefaultLibLocation() : ts.getDirectoryPath(host.getDefaultLibFileName(options));
ts.forEach(options.lib, function (libFileName) {
processRootFile(ts.combinePaths(libDirectory_1, libFileName), /*isDefaultLib*/ true);
});
}
}
}
// unconditionally set oldProgram to undefined to prevent it from being captured in closure
oldProgram = undefined;
program = {
getRootFileNames: function () { return rootNames; },
getSourceFile: getSourceFile,
getSourceFileByPath: getSourceFileByPath,
getSourceFiles: function () { return files; },
getCompilerOptions: function () { return options; },
getSyntacticDiagnostics: getSyntacticDiagnostics,
getOptionsDiagnostics: getOptionsDiagnostics,
getGlobalDiagnostics: getGlobalDiagnostics,
getSemanticDiagnostics: getSemanticDiagnostics,
getDeclarationDiagnostics: getDeclarationDiagnostics,
getTypeChecker: getTypeChecker,
getClassifiableNames: getClassifiableNames,
getDiagnosticsProducingTypeChecker: getDiagnosticsProducingTypeChecker,
getCommonSourceDirectory: getCommonSourceDirectory,
emit: emit,
getCurrentDirectory: function () { return currentDirectory; },
getNodeCount: function () { return getDiagnosticsProducingTypeChecker().getNodeCount(); },
getIdentifierCount: function () { return getDiagnosticsProducingTypeChecker().getIdentifierCount(); },
getSymbolCount: function () { return getDiagnosticsProducingTypeChecker().getSymbolCount(); },
getTypeCount: function () { return getDiagnosticsProducingTypeChecker().getTypeCount(); },
getFileProcessingDiagnostics: function () { return fileProcessingDiagnostics; },
getResolvedTypeReferenceDirectives: function () { return resolvedTypeReferenceDirectives; },
isSourceFileFromExternalLibrary: isSourceFileFromExternalLibrary,
dropDiagnosticsProducingTypeChecker: dropDiagnosticsProducingTypeChecker
};
verifyCompilerOptions();
ts.performance.mark("afterProgram");
ts.performance.measure("Program", "beforeProgram", "afterProgram");
return program;
function getCommonSourceDirectory() {
if (commonSourceDirectory === undefined) {
var emittedFiles = ts.filterSourceFilesInDirectory(files, isSourceFileFromExternalLibrary);
if (options.rootDir && checkSourceFilesBelongToPath(emittedFiles, options.rootDir)) {
// If a rootDir is specified and is valid use it as the commonSourceDirectory
commonSourceDirectory = ts.getNormalizedAbsolutePath(options.rootDir, currentDirectory);
}
else {
commonSourceDirectory = computeCommonSourceDirectory(emittedFiles);
}
if (commonSourceDirectory && commonSourceDirectory[commonSourceDirectory.length - 1] !== ts.directorySeparator) {
// Make sure directory path ends with directory separator so this string can directly
// used to replace with "" to get the relative path of the source file and the relative path doesn't
// start with / making it rooted path
commonSourceDirectory += ts.directorySeparator;
}
}
return commonSourceDirectory;
}
function getClassifiableNames() {
if (!classifiableNames) {
// Initialize a checker so that all our files are bound.
getTypeChecker();
classifiableNames = ts.createMap();
for (var _i = 0, files_2 = files; _i < files_2.length; _i++) {
var sourceFile = files_2[_i];
ts.copyProperties(sourceFile.classifiableNames, classifiableNames);
}
}
return classifiableNames;
}
function resolveModuleNamesReusingOldState(moduleNames, containingFile, file, oldProgramState) {
if (!oldProgramState && !file.ambientModuleNames.length) {
// if old program state is not supplied and file does not contain locally defined ambient modules
// then the best we can do is fallback to the default logic
return resolveModuleNamesWorker(moduleNames, containingFile);
}
// at this point we know that either
// - file has local declarations for ambient modules
// OR
// - old program state is available
// OR
// - both of items above
// With this it is possible that we can tell how some module names from the initial list will be resolved
// without doing actual resolution (in particular if some name was resolved to ambient module).
// Such names should be excluded from the list of module names that will be provided to `resolveModuleNamesWorker`
// since we don't want to resolve them again.
// this is a list of modules for which we cannot predict resolution so they should be actually resolved
var unknownModuleNames;
// this is a list of combined results assembles from predicted and resolved results.
// Order in this list matches the order in the original list of module names `moduleNames` which is important
// so later we can split results to resolutions of modules and resolutions of module augmentations.
var result;
// a transient placeholder that is used to mark predicted resolution in the result list
var predictedToResolveToAmbientModuleMarker = {};
for (var i = 0; i < moduleNames.length; i++) {
var moduleName = moduleNames[i];
// module name is known to be resolved to ambient module if
// - module name is contained in the list of ambient modules that are locally declared in the file
// - in the old program module name was resolved to ambient module whose declaration is in non-modified file
// (so the same module declaration will land in the new program)
var isKnownToResolveToAmbientModule = false;
if (ts.contains(file.ambientModuleNames, moduleName)) {
isKnownToResolveToAmbientModule = true;
if (ts.isTraceEnabled(options, host)) {
ts.trace(host, ts.Diagnostics.Module_0_was_resolved_as_locally_declared_ambient_module_in_file_1, moduleName, containingFile);
}
}
else {
isKnownToResolveToAmbientModule = checkModuleNameResolvedToAmbientModuleInNonModifiedFile(moduleName, oldProgramState);
}
if (isKnownToResolveToAmbientModule) {
if (!unknownModuleNames) {
// found a first module name for which result can be prediced
// this means that this module name should not be passed to `resolveModuleNamesWorker`.
// We'll use a separate list for module names that are definitely unknown.
result = new Array(moduleNames.length);
// copy all module names that appear before the current one in the list
// since they are known to be unknown
unknownModuleNames = moduleNames.slice(0, i);
}
// mark prediced resolution in the result list
result[i] = predictedToResolveToAmbientModuleMarker;
}
else if (unknownModuleNames) {
// found unknown module name and we are already using separate list for those - add it to the list
unknownModuleNames.push(moduleName);
}
}
if (!unknownModuleNames) {
// we've looked throught the list but have not seen any predicted resolution
// use default logic
return resolveModuleNamesWorker(moduleNames, containingFile);
}
var resolutions = unknownModuleNames.length
? resolveModuleNamesWorker(unknownModuleNames, containingFile)
: emptyArray;
// combine results of resolutions and predicted results
var j = 0;
for (var i = 0; i < result.length; i++) {
if (result[i] == predictedToResolveToAmbientModuleMarker) {
result[i] = undefined;
}
else {
result[i] = resolutions[j];
j++;
}
}
ts.Debug.assert(j === resolutions.length);
return result;
function checkModuleNameResolvedToAmbientModuleInNonModifiedFile(moduleName, oldProgramState) {
if (!oldProgramState) {
return false;
}
var resolutionToFile = ts.getResolvedModule(oldProgramState.file, moduleName);
if (resolutionToFile) {
// module used to be resolved to file - ignore it
return false;
}
var ambientModule = oldProgram.getTypeChecker().tryFindAmbientModuleWithoutAugmentations(moduleName);
if (!(ambientModule && ambientModule.declarations)) {
return false;
}
// at least one of declarations should come from non-modified source file
var firstUnmodifiedFile = ts.forEach(ambientModule.declarations, function (d) {
var f = ts.getSourceFileOfNode(d);
return !ts.contains(oldProgramState.modifiedFilePaths, f.path) && f;
});
if (!firstUnmodifiedFile) {
return false;
}
if (ts.isTraceEnabled(options, host)) {
ts.trace(host, ts.Diagnostics.Module_0_was_resolved_as_ambient_module_declared_in_1_since_this_file_was_not_modified, moduleName, firstUnmodifiedFile.fileName);
}
return true;
}
}
function tryReuseStructureFromOldProgram() {
if (!oldProgram) {
return false;
}
// check properties that can affect structure of the program or module resolution strategy
// if any of these properties has changed - structure cannot be reused
var oldOptions = oldProgram.getCompilerOptions();
if (ts.changesAffectModuleResolution(oldOptions, options)) {
return false;
}
ts.Debug.assert(!oldProgram.structureIsReused);
// there is an old program, check if we can reuse its structure
var oldRootNames = oldProgram.getRootFileNames();
if (!ts.arrayIsEqualTo(oldRootNames, rootNames)) {
return false;
}
if (!ts.arrayIsEqualTo(options.types, oldOptions.types)) {
return false;
}
// check if program source files has changed in the way that can affect structure of the program
var newSourceFiles = [];
var filePaths = [];
var modifiedSourceFiles = [];
for (var _i = 0, _a = oldProgram.getSourceFiles(); _i < _a.length; _i++) {
var oldSourceFile = _a[_i];
var newSourceFile = host.getSourceFileByPath
? host.getSourceFileByPath(oldSourceFile.fileName, oldSourceFile.path, options.target)
: host.getSourceFile(oldSourceFile.fileName, options.target);
if (!newSourceFile) {
return false;
}
newSourceFile.path = oldSourceFile.path;
filePaths.push(newSourceFile.path);
if (oldSourceFile !== newSourceFile) {
if (oldSourceFile.hasNoDefaultLib !== newSourceFile.hasNoDefaultLib) {
// value of no-default-lib has changed
// this will affect if default library is injected into the list of files
return false;
}
// check tripleslash references
if (!ts.arrayIsEqualTo(oldSourceFile.referencedFiles, newSourceFile.referencedFiles, fileReferenceIsEqualTo)) {
// tripleslash references has changed
return false;
}
// check imports and module augmentations
collectExternalModuleReferences(newSourceFile);
if (!ts.arrayIsEqualTo(oldSourceFile.imports, newSourceFile.imports, moduleNameIsEqualTo)) {
// imports has changed
return false;
}
if (!ts.arrayIsEqualTo(oldSourceFile.moduleAugmentations, newSourceFile.moduleAugmentations, moduleNameIsEqualTo)) {
// moduleAugmentations has changed
return false;
}
if (!ts.arrayIsEqualTo(oldSourceFile.typeReferenceDirectives, newSourceFile.typeReferenceDirectives, fileReferenceIsEqualTo)) {
// 'types' references has changed
return false;
}
// tentatively approve the file
modifiedSourceFiles.push({ oldFile: oldSourceFile, newFile: newSourceFile });
}
else {
// file has no changes - use it as is
newSourceFile = oldSourceFile;
}
// if file has passed all checks it should be safe to reuse it
newSourceFiles.push(newSourceFile);
}
var modifiedFilePaths = modifiedSourceFiles.map(function (f) { return f.newFile.path; });
// try to verify results of module resolution
for (var _b = 0, modifiedSourceFiles_1 = modifiedSourceFiles; _b < modifiedSourceFiles_1.length; _b++) {
var _c = modifiedSourceFiles_1[_b], oldSourceFile = _c.oldFile, newSourceFile = _c.newFile;
var newSourceFilePath = ts.getNormalizedAbsolutePath(newSourceFile.fileName, currentDirectory);
if (resolveModuleNamesWorker) {
var moduleNames = ts.map(ts.concatenate(newSourceFile.imports, newSourceFile.moduleAugmentations), getTextOfLiteral);
var resolutions = resolveModuleNamesReusingOldState(moduleNames, newSourceFilePath, newSourceFile, { file: oldSourceFile, program: oldProgram, modifiedFilePaths: modifiedFilePaths });
// ensure that module resolution results are still correct
var resolutionsChanged = ts.hasChangesInResolutions(moduleNames, resolutions, oldSourceFile.resolvedModules, ts.moduleResolutionIsEqualTo);
if (resolutionsChanged) {
return false;
}
}
if (resolveTypeReferenceDirectiveNamesWorker) {
var typesReferenceDirectives = ts.map(newSourceFile.typeReferenceDirectives, function (x) { return x.fileName; });
var resolutions = resolveTypeReferenceDirectiveNamesWorker(typesReferenceDirectives, newSourceFilePath);
// ensure that types resolutions are still correct
var resolutionsChanged = ts.hasChangesInResolutions(typesReferenceDirectives, resolutions, oldSourceFile.resolvedTypeReferenceDirectiveNames, ts.typeDirectiveIsEqualTo);
if (resolutionsChanged) {
return false;
}
}
// pass the cache of module/types resolutions from the old source file
newSourceFile.resolvedModules = oldSourceFile.resolvedModules;
newSourceFile.resolvedTypeReferenceDirectiveNames = oldSourceFile.resolvedTypeReferenceDirectiveNames;
}
// update fileName -> file mapping
for (var i = 0, len = newSourceFiles.length; i < len; i++) {
filesByName.set(filePaths[i], newSourceFiles[i]);
}
files = newSourceFiles;
fileProcessingDiagnostics = oldProgram.getFileProcessingDiagnostics();
for (var _d = 0, modifiedSourceFiles_2 = modifiedSourceFiles; _d < modifiedSourceFiles_2.length; _d++) {
var modifiedFile = modifiedSourceFiles_2[_d];
fileProcessingDiagnostics.reattachFileDiagnostics(modifiedFile.newFile);
}
resolvedTypeReferenceDirectives = oldProgram.getResolvedTypeReferenceDirectives();
oldProgram.structureIsReused = true;
return true;
}
function getEmitHost(writeFileCallback) {
return {
getCanonicalFileName: getCanonicalFileName,
getCommonSourceDirectory: program.getCommonSourceDirectory,
getCompilerOptions: program.getCompilerOptions,
getCurrentDirectory: function () { return currentDirectory; },
getNewLine: function () { return host.getNewLine(); },
getSourceFile: program.getSourceFile,
getSourceFileByPath: program.getSourceFileByPath,
getSourceFiles: program.getSourceFiles,
isSourceFileFromExternalLibrary: isSourceFileFromExternalLibrary,
writeFile: writeFileCallback || (function (fileName, data, writeByteOrderMark, onError, sourceFiles) { return host.writeFile(fileName, data, writeByteOrderMark, onError, sourceFiles); }),
isEmitBlocked: isEmitBlocked,
};
}
function isSourceFileFromExternalLibrary(file) {
return sourceFilesFoundSearchingNodeModules[file.path];
}
function getDiagnosticsProducingTypeChecker() {
return diagnosticsProducingTypeChecker || (diagnosticsProducingTypeChecker = ts.createTypeChecker(program, /*produceDiagnostics:*/ true));
}
function dropDiagnosticsProducingTypeChecker() {
diagnosticsProducingTypeChecker = undefined;
}
function getTypeChecker() {
return noDiagnosticsTypeChecker || (noDiagnosticsTypeChecker = ts.createTypeChecker(program, /*produceDiagnostics:*/ false));
}
function emit(sourceFile, writeFileCallback, cancellationToken, emitOnlyDtsFiles) {
return runWithCancellationToken(function () { return emitWorker(program, sourceFile, writeFileCallback, cancellationToken, emitOnlyDtsFiles); });
}
function isEmitBlocked(emitFileName) {
return hasEmitBlockingDiagnostics.contains(ts.toPath(emitFileName, currentDirectory, getCanonicalFileName));
}
function emitWorker(program, sourceFile, writeFileCallback, cancellationToken, emitOnlyDtsFiles) {
var declarationDiagnostics = [];
if (options.noEmit) {
return { diagnostics: declarationDiagnostics, sourceMaps: undefined, emittedFiles: undefined, emitSkipped: true };
}
// If the noEmitOnError flag is set, then check if we have any errors so far. If so,
// immediately bail out. Note that we pass 'undefined' for 'sourceFile' so that we
// get any preEmit diagnostics, not just the ones
if (options.noEmitOnError) {
var diagnostics = program.getOptionsDiagnostics(cancellationToken).concat(program.getSyntacticDiagnostics(sourceFile, cancellationToken), program.getGlobalDiagnostics(cancellationToken), program.getSemanticDiagnostics(sourceFile, cancellationToken));
if (diagnostics.length === 0 && program.getCompilerOptions().declaration) {
declarationDiagnostics = program.getDeclarationDiagnostics(/*sourceFile*/ undefined, cancellationToken);
}
if (diagnostics.length > 0 || declarationDiagnostics.length > 0) {
return {
diagnostics: ts.concatenate(diagnostics, declarationDiagnostics),
sourceMaps: undefined,
emittedFiles: undefined,
emitSkipped: true
};
}
}
// Create the emit resolver outside of the "emitTime" tracking code below. That way
// any cost associated with it (like type checking) are appropriate associated with
// the type-checking counter.
//
// If the -out option is specified, we should not pass the source file to getEmitResolver.
// This is because in the -out scenario all files need to be emitted, and therefore all
// files need to be type checked. And the way to specify that all files need to be type
// checked is to not pass the file to getEmitResolver.
var emitResolver = getDiagnosticsProducingTypeChecker().getEmitResolver((options.outFile || options.out) ? undefined : sourceFile);
ts.performance.mark("beforeEmit");
var emitResult = ts.emitFiles(emitResolver, getEmitHost(writeFileCallback), sourceFile, emitOnlyDtsFiles);
ts.performance.mark("afterEmit");
ts.performance.measure("Emit", "beforeEmit", "afterEmit");
return emitResult;
}
function getSourceFile(fileName) {
return getSourceFileByPath(ts.toPath(fileName, currentDirectory, getCanonicalFileName));
}
function getSourceFileByPath(path) {
return filesByName.get(path);
}
function getDiagnosticsHelper(sourceFile, getDiagnostics, cancellationToken) {
if (sourceFile) {
return getDiagnostics(sourceFile, cancellationToken);
}
var allDiagnostics = [];
ts.forEach(program.getSourceFiles(), function (sourceFile) {
if (cancellationToken) {
cancellationToken.throwIfCancellationRequested();
}
ts.addRange(allDiagnostics, getDiagnostics(sourceFile, cancellationToken));
});
return ts.sortAndDeduplicateDiagnostics(allDiagnostics);
}
function getSyntacticDiagnostics(sourceFile, cancellationToken) {
return getDiagnosticsHelper(sourceFile, getSyntacticDiagnosticsForFile, cancellationToken);
}
function getSemanticDiagnostics(sourceFile, cancellationToken) {
return getDiagnosticsHelper(sourceFile, getSemanticDiagnosticsForFile, cancellationToken);
}
function getDeclarationDiagnostics(sourceFile, cancellationToken) {
var options = program.getCompilerOptions();
// collect diagnostics from the program only once if either no source file was specified or out/outFile is set (bundled emit)
if (!sourceFile || options.out || options.outFile) {
return getDeclarationDiagnosticsWorker(sourceFile, cancellationToken);
}
else {
return getDiagnosticsHelper(sourceFile, getDeclarationDiagnosticsForFile, cancellationToken);
}
}
function getSyntacticDiagnosticsForFile(sourceFile) {
// For JavaScript files, we report semantic errors for using TypeScript-only
// constructs from within a JavaScript file as syntactic errors.
if (ts.isSourceFileJavaScript(sourceFile)) {
if (!sourceFile.additionalSyntacticDiagnostics) {
sourceFile.additionalSyntacticDiagnostics = getJavaScriptSyntacticDiagnosticsForFile(sourceFile);
}
return ts.concatenate(sourceFile.additionalSyntacticDiagnostics, sourceFile.parseDiagnostics);
}
return sourceFile.parseDiagnostics;
}
function runWithCancellationToken(func) {
try {
return func();
}
catch (e) {
if (e instanceof ts.OperationCanceledException) {
// We were canceled while performing the operation. Because our type checker
// might be a bad state, we need to throw it away.
//
// Note: we are overly aggressive here. We do not actually *have* to throw away
// the "noDiagnosticsTypeChecker". However, for simplicity, i'd like to keep
// the lifetimes of these two TypeCheckers the same. Also, we generally only
// cancel when the user has made a change anyways. And, in that case, we (the
// program instance) will get thrown away anyways. So trying to keep one of
// these type checkers alive doesn't serve much purpose.
noDiagnosticsTypeChecker = undefined;
diagnosticsProducingTypeChecker = undefined;
}
throw e;
}
}
function getSemanticDiagnosticsForFile(sourceFile, cancellationToken) {
return runWithCancellationToken(function () {
var typeChecker = getDiagnosticsProducingTypeChecker();
ts.Debug.assert(!!sourceFile.bindDiagnostics);
var bindDiagnostics = sourceFile.bindDiagnostics;
// For JavaScript files, we don't want to report semantic errors.
// Instead, we'll report errors for using TypeScript-only constructs from within a
// JavaScript file when we get syntactic diagnostics for the file.
var checkDiagnostics = ts.isSourceFileJavaScript(sourceFile) ? [] : typeChecker.getDiagnostics(sourceFile, cancellationToken);
var fileProcessingDiagnosticsInFile = fileProcessingDiagnostics.getDiagnostics(sourceFile.fileName);
var programDiagnosticsInFile = programDiagnostics.getDiagnostics(sourceFile.fileName);
return bindDiagnostics.concat(checkDiagnostics, fileProcessingDiagnosticsInFile, programDiagnosticsInFile);
});
}
function getJavaScriptSyntacticDiagnosticsForFile(sourceFile) {
return runWithCancellationToken(function () {
var diagnostics = [];
var parent = sourceFile;
walk(sourceFile);
return diagnostics;
function walk(node) {
// Return directly from the case if the given node doesnt want to visit each child
// Otherwise break to visit each child
switch (parent.kind) {
case 144 /* Parameter */:
case 147 /* PropertyDeclaration */:
if (parent.questionToken === node) {
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics._0_can_only_be_used_in_a_ts_file, "?"));
return;
}
// Pass through
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
case 185 /* ArrowFunction */:
case 225 /* FunctionDeclaration */:
case 223 /* VariableDeclaration */:
// type annotation
if (parent.type === node) {
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.types_can_only_be_used_in_a_ts_file));
return;
}
}
switch (node.kind) {
case 234 /* ImportEqualsDeclaration */:
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.import_can_only_be_used_in_a_ts_file));
return;
case 240 /* ExportAssignment */:
if (node.isExportEquals) {
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.export_can_only_be_used_in_a_ts_file));
return;
}
break;
case 255 /* HeritageClause */:
var heritageClause = node;
if (heritageClause.token === 107 /* ImplementsKeyword */) {
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.implements_clauses_can_only_be_used_in_a_ts_file));
return;
}
break;
case 227 /* InterfaceDeclaration */:
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.interface_declarations_can_only_be_used_in_a_ts_file));
return;
case 230 /* ModuleDeclaration */:
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.module_declarations_can_only_be_used_in_a_ts_file));
return;
case 228 /* TypeAliasDeclaration */:
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.type_aliases_can_only_be_used_in_a_ts_file));
return;
case 229 /* EnumDeclaration */:
diagnostics.push(createDiagnosticForNode(node, ts.Diagnostics.enum_declarations_can_only_be_used_in_a_ts_file));
return;
case 182 /* TypeAssertionExpression */:
var typeAssertionExpression = node;
diagnostics.push(createDiagnosticForNode(typeAssertionExpression.type, ts.Diagnostics.type_assertion_expressions_can_only_be_used_in_a_ts_file));
return;
}
var prevParent = parent;
parent = node;
ts.forEachChild(node, walk, walkArray);
parent = prevParent;
}
function walkArray(nodes) {
if (parent.decorators === nodes && !options.experimentalDecorators) {
diagnostics.push(createDiagnosticForNode(parent, ts.Diagnostics.Experimental_support_for_decorators_is_a_feature_that_is_subject_to_change_in_a_future_release_Set_the_experimentalDecorators_option_to_remove_this_warning));
}
switch (parent.kind) {
case 226 /* ClassDeclaration */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
case 185 /* ArrowFunction */:
case 225 /* FunctionDeclaration */:
// Check type parameters
if (nodes === parent.typeParameters) {
diagnostics.push(createDiagnosticForNodeArray(nodes, ts.Diagnostics.type_parameter_declarations_can_only_be_used_in_a_ts_file));
return;
}
// pass through
case 205 /* VariableStatement */:
// Check modifiers
if (nodes === parent.modifiers) {
return checkModifiers(nodes, parent.kind === 205 /* VariableStatement */);
}
break;
case 147 /* PropertyDeclaration */:
// Check modifiers of property declaration
if (nodes === parent.modifiers) {
for (var _i = 0, _a = nodes; _i < _a.length; _i++) {
var modifier = _a[_i];
if (modifier.kind !== 114 /* StaticKeyword */) {
diagnostics.push(createDiagnosticForNode(modifier, ts.Diagnostics._0_can_only_be_used_in_a_ts_file, ts.tokenToString(modifier.kind)));
}
}
return;
}
break;
case 144 /* Parameter */:
// Check modifiers of parameter declaration
if (nodes === parent.modifiers) {
diagnostics.push(createDiagnosticForNodeArray(nodes, ts.Diagnostics.parameter_modifiers_can_only_be_used_in_a_ts_file));
return;
}
break;
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 199 /* ExpressionWithTypeArguments */:
// Check type arguments
if (nodes === parent.typeArguments) {
diagnostics.push(createDiagnosticForNodeArray(nodes, ts.Diagnostics.type_arguments_can_only_be_used_in_a_ts_file));
return;
}
break;
}
for (var _b = 0, nodes_4 = nodes; _b < nodes_4.length; _b++) {
var node = nodes_4[_b];
walk(node);
}
}
function checkModifiers(modifiers, isConstValid) {
for (var _i = 0, modifiers_1 = modifiers; _i < modifiers_1.length; _i++) {
var modifier = modifiers_1[_i];
switch (modifier.kind) {
case 75 /* ConstKeyword */:
if (isConstValid) {
continue;
}
// Fallthrough to report error
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
case 130 /* ReadonlyKeyword */:
case 123 /* DeclareKeyword */:
case 116 /* AbstractKeyword */:
diagnostics.push(createDiagnosticForNode(modifier, ts.Diagnostics._0_can_only_be_used_in_a_ts_file, ts.tokenToString(modifier.kind)));
break;
// These are all legal modifiers.
case 114 /* StaticKeyword */:
case 83 /* ExportKeyword */:
case 78 /* DefaultKeyword */:
}
}
}
function createDiagnosticForNodeArray(nodes, message, arg0, arg1, arg2) {
var start = nodes.pos;
return ts.createFileDiagnostic(sourceFile, start, nodes.end - start, message, arg0, arg1, arg2);
}
// Since these are syntactic diagnostics, parent might not have been set
// this means the sourceFile cannot be infered from the node
function createDiagnosticForNode(node, message, arg0, arg1, arg2) {
return ts.createDiagnosticForNodeInSourceFile(sourceFile, node, message, arg0, arg1, arg2);
}
});
}
function getDeclarationDiagnosticsWorker(sourceFile, cancellationToken) {
return runWithCancellationToken(function () {
var resolver = getDiagnosticsProducingTypeChecker().getEmitResolver(sourceFile, cancellationToken);
// Don't actually write any files since we're just getting diagnostics.
return ts.getDeclarationDiagnostics(getEmitHost(ts.noop), resolver, sourceFile);
});
}
function getDeclarationDiagnosticsForFile(sourceFile, cancellationToken) {
return ts.isDeclarationFile(sourceFile) ? [] : getDeclarationDiagnosticsWorker(sourceFile, cancellationToken);
}
function getOptionsDiagnostics() {
var allDiagnostics = [];
ts.addRange(allDiagnostics, fileProcessingDiagnostics.getGlobalDiagnostics());
ts.addRange(allDiagnostics, programDiagnostics.getGlobalDiagnostics());
return ts.sortAndDeduplicateDiagnostics(allDiagnostics);
}
function getGlobalDiagnostics() {
var allDiagnostics = [];
ts.addRange(allDiagnostics, getDiagnosticsProducingTypeChecker().getGlobalDiagnostics());
return ts.sortAndDeduplicateDiagnostics(allDiagnostics);
}
function processRootFile(fileName, isDefaultLib) {
processSourceFile(ts.normalizePath(fileName), isDefaultLib);
}
function fileReferenceIsEqualTo(a, b) {
return a.fileName === b.fileName;
}
function moduleNameIsEqualTo(a, b) {
return a.text === b.text;
}
function getTextOfLiteral(literal) {
return literal.text;
}
function collectExternalModuleReferences(file) {
if (file.imports) {
return;
}
var isJavaScriptFile = ts.isSourceFileJavaScript(file);
var isExternalModuleFile = ts.isExternalModule(file);
var isDtsFile = ts.isDeclarationFile(file);
var imports;
var moduleAugmentations;
var ambientModules;
// If we are importing helpers, we need to add a synthetic reference to resolve the
// helpers library.
if (options.importHelpers
&& (options.isolatedModules || isExternalModuleFile)
&& !file.isDeclarationFile) {
// synthesize 'import "tslib"' declaration
var externalHelpersModuleReference = ts.createSynthesizedNode(9 /* StringLiteral */);
externalHelpersModuleReference.text = ts.externalHelpersModuleNameText;
var importDecl = ts.createSynthesizedNode(235 /* ImportDeclaration */);
importDecl.parent = file;
externalHelpersModuleReference.parent = importDecl;
imports = [externalHelpersModuleReference];
}
for (var _i = 0, _a = file.statements; _i < _a.length; _i++) {
var node = _a[_i];
collectModuleReferences(node, /*inAmbientModule*/ false);
if (isJavaScriptFile) {
collectRequireCalls(node);
}
}
file.imports = imports || emptyArray;
file.moduleAugmentations = moduleAugmentations || emptyArray;
file.ambientModuleNames = ambientModules || emptyArray;
return;
function collectModuleReferences(node, inAmbientModule) {
switch (node.kind) {
case 235 /* ImportDeclaration */:
case 234 /* ImportEqualsDeclaration */:
case 241 /* ExportDeclaration */:
var moduleNameExpr = ts.getExternalModuleName(node);
if (!moduleNameExpr || moduleNameExpr.kind !== 9 /* StringLiteral */) {
break;
}
if (!moduleNameExpr.text) {
break;
}
// TypeScript 1.0 spec (April 2014): 12.1.6
// An ExternalImportDeclaration in an AmbientExternalModuleDeclaration may reference other external modules
// only through top - level external module names. Relative external module names are not permitted.
if (!inAmbientModule || !ts.isExternalModuleNameRelative(moduleNameExpr.text)) {
(imports || (imports = [])).push(moduleNameExpr);
}
break;
case 230 /* ModuleDeclaration */:
if (ts.isAmbientModule(node) && (inAmbientModule || ts.hasModifier(node, 2 /* Ambient */) || ts.isDeclarationFile(file))) {
var moduleName = node.name;
// Ambient module declarations can be interpreted as augmentations for some existing external modules.
// This will happen in two cases:
// - if current file is external module then module augmentation is a ambient module declaration defined in the top level scope
// - if current file is not external module then module augmentation is an ambient module declaration with non-relative module name
// immediately nested in top level ambient module declaration .
if (isExternalModuleFile || (inAmbientModule && !ts.isExternalModuleNameRelative(moduleName.text))) {
(moduleAugmentations || (moduleAugmentations = [])).push(moduleName);
}
else if (!inAmbientModule) {
if (isDtsFile) {
// for global .d.ts files record name of ambient module
(ambientModules || (ambientModules = [])).push(moduleName.text);
}
// An AmbientExternalModuleDeclaration declares an external module.
// This type of declaration is permitted only in the global module.
// The StringLiteral must specify a top - level external module name.
// Relative external module names are not permitted
// NOTE: body of ambient module is always a module block, if it exists
var body = node.body;
if (body) {
for (var _i = 0, _a = body.statements; _i < _a.length; _i++) {
var statement = _a[_i];
collectModuleReferences(statement, /*inAmbientModule*/ true);
}
}
}
}
}
}
function collectRequireCalls(node) {
if (ts.isRequireCall(node, /*checkArgumentIsStringLiteral*/ true)) {
(imports || (imports = [])).push(node.arguments[0]);
}
else {
ts.forEachChild(node, collectRequireCalls);
}
}
}
function processSourceFile(fileName, isDefaultLib, refFile, refPos, refEnd) {
var diagnosticArgument;
var diagnostic;
if (ts.hasExtension(fileName)) {
if (!options.allowNonTsExtensions && !ts.forEach(supportedExtensions, function (extension) { return ts.fileExtensionIs(host.getCanonicalFileName(fileName), extension); })) {
diagnostic = ts.Diagnostics.File_0_has_unsupported_extension_The_only_supported_extensions_are_1;
diagnosticArgument = [fileName, "'" + supportedExtensions.join("', '") + "'"];
}
else if (!findSourceFile(fileName, ts.toPath(fileName, currentDirectory, getCanonicalFileName), isDefaultLib, refFile, refPos, refEnd)) {
diagnostic = ts.Diagnostics.File_0_not_found;
diagnosticArgument = [fileName];
}
else if (refFile && host.getCanonicalFileName(fileName) === host.getCanonicalFileName(refFile.fileName)) {
diagnostic = ts.Diagnostics.A_file_cannot_have_a_reference_to_itself;
diagnosticArgument = [fileName];
}
}
else {
var nonTsFile = options.allowNonTsExtensions && findSourceFile(fileName, ts.toPath(fileName, currentDirectory, getCanonicalFileName), isDefaultLib, refFile, refPos, refEnd);
if (!nonTsFile) {
if (options.allowNonTsExtensions) {
diagnostic = ts.Diagnostics.File_0_not_found;
diagnosticArgument = [fileName];
}
else if (!ts.forEach(supportedExtensions, function (extension) { return findSourceFile(fileName + extension, ts.toPath(fileName + extension, currentDirectory, getCanonicalFileName), isDefaultLib, refFile, refPos, refEnd); })) {
diagnostic = ts.Diagnostics.File_0_not_found;
fileName += ".ts";
diagnosticArgument = [fileName];
}
}
}
if (diagnostic) {
if (refFile !== undefined && refEnd !== undefined && refPos !== undefined) {
fileProcessingDiagnostics.add(ts.createFileDiagnostic.apply(void 0, [refFile, refPos, refEnd - refPos, diagnostic].concat(diagnosticArgument)));
}
else {
fileProcessingDiagnostics.add(ts.createCompilerDiagnostic.apply(void 0, [diagnostic].concat(diagnosticArgument)));
}
}
}
function reportFileNamesDifferOnlyInCasingError(fileName, existingFileName, refFile, refPos, refEnd) {
if (refFile !== undefined && refPos !== undefined && refEnd !== undefined) {
fileProcessingDiagnostics.add(ts.createFileDiagnostic(refFile, refPos, refEnd - refPos, ts.Diagnostics.File_name_0_differs_from_already_included_file_name_1_only_in_casing, fileName, existingFileName));
}
else {
fileProcessingDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.File_name_0_differs_from_already_included_file_name_1_only_in_casing, fileName, existingFileName));
}
}
// Get source file from normalized fileName
function findSourceFile(fileName, path, isDefaultLib, refFile, refPos, refEnd) {
if (filesByName.contains(path)) {
var file_1 = filesByName.get(path);
// try to check if we've already seen this file but with a different casing in path
// NOTE: this only makes sense for case-insensitive file systems
if (file_1 && options.forceConsistentCasingInFileNames && ts.getNormalizedAbsolutePath(file_1.fileName, currentDirectory) !== ts.getNormalizedAbsolutePath(fileName, currentDirectory)) {
reportFileNamesDifferOnlyInCasingError(fileName, file_1.fileName, refFile, refPos, refEnd);
}
// If the file was previously found via a node_modules search, but is now being processed as a root file,
// then everything it sucks in may also be marked incorrectly, and needs to be checked again.
if (file_1 && sourceFilesFoundSearchingNodeModules[file_1.path] && currentNodeModulesDepth == 0) {
sourceFilesFoundSearchingNodeModules[file_1.path] = false;
if (!options.noResolve) {
processReferencedFiles(file_1, isDefaultLib);
processTypeReferenceDirectives(file_1);
}
modulesWithElidedImports[file_1.path] = false;
processImportedModules(file_1);
}
else if (file_1 && modulesWithElidedImports[file_1.path]) {
if (currentNodeModulesDepth < maxNodeModuleJsDepth) {
modulesWithElidedImports[file_1.path] = false;
processImportedModules(file_1);
}
}
return file_1;
}
// We haven't looked for this file, do so now and cache result
var file = host.getSourceFile(fileName, options.target, function (hostErrorMessage) {
if (refFile !== undefined && refPos !== undefined && refEnd !== undefined) {
fileProcessingDiagnostics.add(ts.createFileDiagnostic(refFile, refPos, refEnd - refPos, ts.Diagnostics.Cannot_read_file_0_Colon_1, fileName, hostErrorMessage));
}
else {
fileProcessingDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Cannot_read_file_0_Colon_1, fileName, hostErrorMessage));
}
});
filesByName.set(path, file);
if (file) {
sourceFilesFoundSearchingNodeModules[path] = (currentNodeModulesDepth > 0);
file.path = path;
if (host.useCaseSensitiveFileNames()) {
// for case-sensitive file systems check if we've already seen some file with similar filename ignoring case
var existingFile = filesByNameIgnoreCase.get(path);
if (existingFile) {
reportFileNamesDifferOnlyInCasingError(fileName, existingFile.fileName, refFile, refPos, refEnd);
}
else {
filesByNameIgnoreCase.set(path, file);
}
}
skipDefaultLib = skipDefaultLib || file.hasNoDefaultLib;
if (!options.noResolve) {
processReferencedFiles(file, isDefaultLib);
processTypeReferenceDirectives(file);
}
// always process imported modules to record module name resolutions
processImportedModules(file);
if (isDefaultLib) {
files.unshift(file);
}
else {
files.push(file);
}
}
return file;
}
function processReferencedFiles(file, isDefaultLib) {
ts.forEach(file.referencedFiles, function (ref) {
var referencedFileName = resolveTripleslashReference(ref.fileName, file.fileName);
processSourceFile(referencedFileName, isDefaultLib, file, ref.pos, ref.end);
});
}
function processTypeReferenceDirectives(file) {
// We lower-case all type references because npm automatically lowercases all packages. See GH#9824.
var typeDirectives = ts.map(file.typeReferenceDirectives, function (ref) { return ref.fileName.toLocaleLowerCase(); });
var resolutions = resolveTypeReferenceDirectiveNamesWorker(typeDirectives, file.fileName);
for (var i = 0; i < typeDirectives.length; i++) {
var ref = file.typeReferenceDirectives[i];
var resolvedTypeReferenceDirective = resolutions[i];
// store resolved type directive on the file
var fileName = ref.fileName.toLocaleLowerCase();
ts.setResolvedTypeReferenceDirective(file, fileName, resolvedTypeReferenceDirective);
processTypeReferenceDirective(fileName, resolvedTypeReferenceDirective, file, ref.pos, ref.end);
}
}
function processTypeReferenceDirective(typeReferenceDirective, resolvedTypeReferenceDirective, refFile, refPos, refEnd) {
// If we already found this library as a primary reference - nothing to do
var previousResolution = resolvedTypeReferenceDirectives[typeReferenceDirective];
if (previousResolution && previousResolution.primary) {
return;
}
var saveResolution = true;
if (resolvedTypeReferenceDirective) {
if (resolvedTypeReferenceDirective.primary) {
// resolved from the primary path
processSourceFile(resolvedTypeReferenceDirective.resolvedFileName, /*isDefaultLib*/ false, refFile, refPos, refEnd);
}
else {
// If we already resolved to this file, it must have been a secondary reference. Check file contents
// for sameness and possibly issue an error
if (previousResolution) {
// Don't bother reading the file again if it's the same file.
if (resolvedTypeReferenceDirective.resolvedFileName !== previousResolution.resolvedFileName) {
var otherFileText = host.readFile(resolvedTypeReferenceDirective.resolvedFileName);
if (otherFileText !== getSourceFile(previousResolution.resolvedFileName).text) {
fileProcessingDiagnostics.add(createDiagnostic(refFile, refPos, refEnd, ts.Diagnostics.Conflicting_definitions_for_0_found_at_1_and_2_Consider_installing_a_specific_version_of_this_library_to_resolve_the_conflict, typeReferenceDirective, resolvedTypeReferenceDirective.resolvedFileName, previousResolution.resolvedFileName));
}
}
// don't overwrite previous resolution result
saveResolution = false;
}
else {
// First resolution of this library
processSourceFile(resolvedTypeReferenceDirective.resolvedFileName, /*isDefaultLib*/ false, refFile, refPos, refEnd);
}
}
}
else {
fileProcessingDiagnostics.add(createDiagnostic(refFile, refPos, refEnd, ts.Diagnostics.Cannot_find_type_definition_file_for_0, typeReferenceDirective));
}
if (saveResolution) {
resolvedTypeReferenceDirectives[typeReferenceDirective] = resolvedTypeReferenceDirective;
}
}
function createDiagnostic(refFile, refPos, refEnd, message) {
var args = [];
for (var _i = 4; _i < arguments.length; _i++) {
args[_i - 4] = arguments[_i];
}
if (refFile === undefined || refPos === undefined || refEnd === undefined) {
return ts.createCompilerDiagnostic.apply(void 0, [message].concat(args));
}
else {
return ts.createFileDiagnostic.apply(void 0, [refFile, refPos, refEnd - refPos, message].concat(args));
}
}
function getCanonicalFileName(fileName) {
return host.getCanonicalFileName(fileName);
}
function processImportedModules(file) {
collectExternalModuleReferences(file);
if (file.imports.length || file.moduleAugmentations.length) {
file.resolvedModules = ts.createMap();
// Because global augmentation doesn't have string literal name, we can check for global augmentation as such.
var nonGlobalAugmentation = ts.filter(file.moduleAugmentations, function (moduleAugmentation) { return moduleAugmentation.kind === 9 /* StringLiteral */; });
var moduleNames = ts.map(ts.concatenate(file.imports, nonGlobalAugmentation), getTextOfLiteral);
var resolutions = resolveModuleNamesReusingOldState(moduleNames, ts.getNormalizedAbsolutePath(file.fileName, currentDirectory), file);
ts.Debug.assert(resolutions.length === moduleNames.length);
for (var i = 0; i < moduleNames.length; i++) {
var resolution = resolutions[i];
ts.setResolvedModule(file, moduleNames[i], resolution);
if (!resolution) {
continue;
}
var isFromNodeModulesSearch = resolution.isExternalLibraryImport;
var isJsFileFromNodeModules = isFromNodeModulesSearch && !ts.extensionIsTypeScript(resolution.extension);
var resolvedFileName = resolution.resolvedFileName;
if (isFromNodeModulesSearch) {
currentNodeModulesDepth++;
}
// add file to program only if:
// - resolution was successful
// - noResolve is falsy
// - module name comes from the list of imports
// - it's not a top level JavaScript module that exceeded the search max
var elideImport = isJsFileFromNodeModules && currentNodeModulesDepth > maxNodeModuleJsDepth;
// Don't add the file if it has a bad extension (e.g. 'tsx' if we don't have '--allowJs')
// This may still end up being an untyped module -- the file won't be included but imports will be allowed.
var shouldAddFile = resolvedFileName && !getResolutionDiagnostic(options, resolution) && !options.noResolve && i < file.imports.length && !elideImport;
if (elideImport) {
modulesWithElidedImports[file.path] = true;
}
else if (shouldAddFile) {
var path = ts.toPath(resolvedFileName, currentDirectory, getCanonicalFileName);
var pos = ts.skipTrivia(file.text, file.imports[i].pos);
findSourceFile(resolvedFileName, path, /*isDefaultLib*/ false, file, pos, file.imports[i].end);
}
if (isFromNodeModulesSearch) {
currentNodeModulesDepth--;
}
}
}
else {
// no imports - drop cached module resolutions
file.resolvedModules = undefined;
}
}
function computeCommonSourceDirectory(sourceFiles) {
var fileNames = [];
for (var _i = 0, sourceFiles_6 = sourceFiles; _i < sourceFiles_6.length; _i++) {
var file = sourceFiles_6[_i];
if (!file.isDeclarationFile) {
fileNames.push(file.fileName);
}
}
return computeCommonSourceDirectoryOfFilenames(fileNames, currentDirectory, getCanonicalFileName);
}
function checkSourceFilesBelongToPath(sourceFiles, rootDirectory) {
var allFilesBelongToPath = true;
if (sourceFiles) {
var absoluteRootDirectoryPath = host.getCanonicalFileName(ts.getNormalizedAbsolutePath(rootDirectory, currentDirectory));
for (var _i = 0, sourceFiles_7 = sourceFiles; _i < sourceFiles_7.length; _i++) {
var sourceFile = sourceFiles_7[_i];
if (!ts.isDeclarationFile(sourceFile)) {
var absoluteSourceFilePath = host.getCanonicalFileName(ts.getNormalizedAbsolutePath(sourceFile.fileName, currentDirectory));
if (absoluteSourceFilePath.indexOf(absoluteRootDirectoryPath) !== 0) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.File_0_is_not_under_rootDir_1_rootDir_is_expected_to_contain_all_source_files, sourceFile.fileName, options.rootDir));
allFilesBelongToPath = false;
}
}
}
}
return allFilesBelongToPath;
}
function verifyCompilerOptions() {
if (options.isolatedModules) {
if (options.declaration) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "declaration", "isolatedModules"));
}
if (options.noEmitOnError) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "noEmitOnError", "isolatedModules"));
}
if (options.out) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "out", "isolatedModules"));
}
if (options.outFile) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "outFile", "isolatedModules"));
}
}
if (options.inlineSourceMap) {
if (options.sourceMap) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "sourceMap", "inlineSourceMap"));
}
if (options.mapRoot) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "mapRoot", "inlineSourceMap"));
}
}
if (options.paths && options.baseUrl === undefined) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_paths_cannot_be_used_without_specifying_baseUrl_option));
}
if (options.paths) {
for (var key in options.paths) {
if (!ts.hasProperty(options.paths, key)) {
continue;
}
if (!ts.hasZeroOrOneAsteriskCharacter(key)) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Pattern_0_can_have_at_most_one_Asterisk_character, key));
}
if (ts.isArray(options.paths[key])) {
if (options.paths[key].length === 0) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Substitutions_for_pattern_0_shouldn_t_be_an_empty_array, key));
}
for (var _i = 0, _a = options.paths[key]; _i < _a.length; _i++) {
var subst = _a[_i];
var typeOfSubst = typeof subst;
if (typeOfSubst === "string") {
if (!ts.hasZeroOrOneAsteriskCharacter(subst)) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Substitution_0_in_pattern_1_in_can_have_at_most_one_Asterisk_character, subst, key));
}
}
else {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Substitution_0_for_pattern_1_has_incorrect_type_expected_string_got_2, subst, key, typeOfSubst));
}
}
}
else {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Substitutions_for_pattern_0_should_be_an_array, key));
}
}
}
if (!options.sourceMap && !options.inlineSourceMap) {
if (options.inlineSources) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_can_only_be_used_when_either_option_inlineSourceMap_or_option_sourceMap_is_provided, "inlineSources"));
}
if (options.sourceRoot) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_can_only_be_used_when_either_option_inlineSourceMap_or_option_sourceMap_is_provided, "sourceRoot"));
}
}
if (options.out && options.outFile) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "out", "outFile"));
}
if (options.mapRoot && !options.sourceMap) {
// Error to specify --mapRoot without --sourcemap
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_without_specifying_option_1, "mapRoot", "sourceMap"));
}
if (options.declarationDir) {
if (!options.declaration) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_without_specifying_option_1, "declarationDir", "declaration"));
}
if (options.out || options.outFile) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "declarationDir", options.out ? "out" : "outFile"));
}
}
if (options.lib && options.noLib) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "lib", "noLib"));
}
if (options.noImplicitUseStrict && options.alwaysStrict) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "noImplicitUseStrict", "alwaysStrict"));
}
var languageVersion = options.target || 0 /* ES3 */;
var outFile = options.outFile || options.out;
var firstNonAmbientExternalModuleSourceFile = ts.forEach(files, function (f) { return ts.isExternalModule(f) && !ts.isDeclarationFile(f) ? f : undefined; });
if (options.isolatedModules) {
if (options.module === ts.ModuleKind.None && languageVersion < 2 /* ES2015 */) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_isolatedModules_can_only_be_used_when_either_option_module_is_provided_or_option_target_is_ES2015_or_higher));
}
var firstNonExternalModuleSourceFile = ts.forEach(files, function (f) { return !ts.isExternalModule(f) && !ts.isDeclarationFile(f) ? f : undefined; });
if (firstNonExternalModuleSourceFile) {
var span_7 = ts.getErrorSpanForNode(firstNonExternalModuleSourceFile, firstNonExternalModuleSourceFile);
programDiagnostics.add(ts.createFileDiagnostic(firstNonExternalModuleSourceFile, span_7.start, span_7.length, ts.Diagnostics.Cannot_compile_namespaces_when_the_isolatedModules_flag_is_provided));
}
}
else if (firstNonAmbientExternalModuleSourceFile && languageVersion < 2 /* ES2015 */ && options.module === ts.ModuleKind.None) {
// We cannot use createDiagnosticFromNode because nodes do not have parents yet
var span_8 = ts.getErrorSpanForNode(firstNonAmbientExternalModuleSourceFile, firstNonAmbientExternalModuleSourceFile.externalModuleIndicator);
programDiagnostics.add(ts.createFileDiagnostic(firstNonAmbientExternalModuleSourceFile, span_8.start, span_8.length, ts.Diagnostics.Cannot_use_imports_exports_or_module_augmentations_when_module_is_none));
}
// Cannot specify module gen that isn't amd or system with --out
if (outFile) {
if (options.module && !(options.module === ts.ModuleKind.AMD || options.module === ts.ModuleKind.System)) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Only_amd_and_system_modules_are_supported_alongside_0, options.out ? "out" : "outFile"));
}
else if (options.module === undefined && firstNonAmbientExternalModuleSourceFile) {
var span_9 = ts.getErrorSpanForNode(firstNonAmbientExternalModuleSourceFile, firstNonAmbientExternalModuleSourceFile.externalModuleIndicator);
programDiagnostics.add(ts.createFileDiagnostic(firstNonAmbientExternalModuleSourceFile, span_9.start, span_9.length, ts.Diagnostics.Cannot_compile_modules_using_option_0_unless_the_module_flag_is_amd_or_system, options.out ? "out" : "outFile"));
}
}
// there has to be common source directory if user specified --outdir || --sourceRoot
// if user specified --mapRoot, there needs to be common source directory if there would be multiple files being emitted
if (options.outDir ||
options.sourceRoot ||
options.mapRoot) {
// Precalculate and cache the common source directory
var dir = getCommonSourceDirectory();
// If we failed to find a good common directory, but outDir is specified and at least one of our files is on a windows drive/URL/other resource, add a failure
if (options.outDir && dir === "" && ts.forEach(files, function (file) { return ts.getRootLength(file.fileName) > 1; })) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Cannot_find_the_common_subdirectory_path_for_the_input_files));
}
}
if (!options.noEmit && options.allowJs && options.declaration) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "allowJs", "declaration"));
}
if (options.emitDecoratorMetadata &&
!options.experimentalDecorators) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_without_specifying_option_1, "emitDecoratorMetadata", "experimentalDecorators"));
}
if (options.jsxFactory) {
if (options.reactNamespace) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_cannot_be_specified_with_option_1, "reactNamespace", "jsxFactory"));
}
if (!ts.parseIsolatedEntityName(options.jsxFactory, languageVersion)) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Invalid_value_for_jsxFactory_0_is_not_a_valid_identifier_or_qualified_name, options.jsxFactory));
}
}
else if (options.reactNamespace && !ts.isIdentifierText(options.reactNamespace, languageVersion)) {
programDiagnostics.add(ts.createCompilerDiagnostic(ts.Diagnostics.Invalid_value_for_reactNamespace_0_is_not_a_valid_identifier, options.reactNamespace));
}
// If the emit is enabled make sure that every output file is unique and not overwriting any of the input files
if (!options.noEmit && !options.suppressOutputPathCheck) {
var emitHost = getEmitHost();
var emitFilesSeen_1 = ts.createFileMap(!host.useCaseSensitiveFileNames() ? function (key) { return key.toLocaleLowerCase(); } : undefined);
ts.forEachExpectedEmitFile(emitHost, function (emitFileNames) {
verifyEmitFilePath(emitFileNames.jsFilePath, emitFilesSeen_1);
verifyEmitFilePath(emitFileNames.declarationFilePath, emitFilesSeen_1);
});
}
// Verify that all the emit files are unique and don't overwrite input files
function verifyEmitFilePath(emitFileName, emitFilesSeen) {
if (emitFileName) {
var emitFilePath = ts.toPath(emitFileName, currentDirectory, getCanonicalFileName);
// Report error if the output overwrites input file
if (filesByName.contains(emitFilePath)) {
var chain_1;
if (!options.configFilePath) {
// The program is from either an inferred project or an external project
chain_1 = ts.chainDiagnosticMessages(/*details*/ undefined, ts.Diagnostics.Adding_a_tsconfig_json_file_will_help_organize_projects_that_contain_both_TypeScript_and_JavaScript_files_Learn_more_at_https_Colon_Slash_Slashaka_ms_Slashtsconfig);
}
chain_1 = ts.chainDiagnosticMessages(chain_1, ts.Diagnostics.Cannot_write_file_0_because_it_would_overwrite_input_file, emitFileName);
blockEmittingOfFile(emitFileName, ts.createCompilerDiagnosticFromMessageChain(chain_1));
}
// Report error if multiple files write into same file
if (emitFilesSeen.contains(emitFilePath)) {
// Already seen the same emit file - report error
blockEmittingOfFile(emitFileName, ts.createCompilerDiagnostic(ts.Diagnostics.Cannot_write_file_0_because_it_would_be_overwritten_by_multiple_input_files, emitFileName));
}
else {
emitFilesSeen.set(emitFilePath, true);
}
}
}
}
function blockEmittingOfFile(emitFileName, diag) {
hasEmitBlockingDiagnostics.set(ts.toPath(emitFileName, currentDirectory, getCanonicalFileName), true);
programDiagnostics.add(diag);
}
}
ts.createProgram = createProgram;
/* @internal */
/**
* Returns a DiagnosticMessage if we won't include a resolved module due to its extension.
* The DiagnosticMessage's parameters are the imported module name, and the filename it resolved to.
* This returns a diagnostic even if the module will be an untyped module.
*/
function getResolutionDiagnostic(options, _a) {
var extension = _a.extension;
switch (extension) {
case ts.Extension.Ts:
case ts.Extension.Dts:
// These are always allowed.
return undefined;
case ts.Extension.Tsx:
return needJsx();
case ts.Extension.Jsx:
return needJsx() || needAllowJs();
case ts.Extension.Js:
return needAllowJs();
}
function needJsx() {
return options.jsx ? undefined : ts.Diagnostics.Module_0_was_resolved_to_1_but_jsx_is_not_set;
}
function needAllowJs() {
return options.allowJs ? undefined : ts.Diagnostics.Module_0_was_resolved_to_1_but_allowJs_is_not_set;
}
}
ts.getResolutionDiagnostic = getResolutionDiagnostic;
})(ts || (ts = {}));
/// <reference path="sys.ts"/>
/// <reference path="types.ts"/>
/// <reference path="core.ts"/>
/// <reference path="diagnosticInformationMap.generated.ts"/>
/// <reference path="scanner.ts"/>
var ts;
(function (ts) {
/* @internal */
ts.compileOnSaveCommandLineOption = { name: "compileOnSave", type: "boolean" };
/* @internal */
ts.optionDeclarations = [
{
name: "charset",
type: "string",
},
ts.compileOnSaveCommandLineOption,
{
name: "declaration",
shortName: "d",
type: "boolean",
description: ts.Diagnostics.Generates_corresponding_d_ts_file,
},
{
name: "declarationDir",
type: "string",
isFilePath: true,
paramType: ts.Diagnostics.DIRECTORY,
},
{
name: "diagnostics",
type: "boolean",
},
{
name: "extendedDiagnostics",
type: "boolean",
experimental: true
},
{
name: "emitBOM",
type: "boolean"
},
{
name: "help",
shortName: "h",
type: "boolean",
description: ts.Diagnostics.Print_this_message,
},
{
name: "help",
shortName: "?",
type: "boolean"
},
{
name: "init",
type: "boolean",
description: ts.Diagnostics.Initializes_a_TypeScript_project_and_creates_a_tsconfig_json_file,
},
{
name: "inlineSourceMap",
type: "boolean",
},
{
name: "inlineSources",
type: "boolean",
},
{
name: "jsx",
type: ts.createMap({
"preserve": 1 /* Preserve */,
"react": 2 /* React */
}),
paramType: ts.Diagnostics.KIND,
description: ts.Diagnostics.Specify_JSX_code_generation_Colon_preserve_or_react,
},
{
name: "reactNamespace",
type: "string",
description: ts.Diagnostics.Specify_the_object_invoked_for_createElement_and_spread_when_targeting_react_JSX_emit
},
{
name: "jsxFactory",
type: "string",
description: ts.Diagnostics.Specify_the_JSX_factory_function_to_use_when_targeting_react_JSX_emit_e_g_React_createElement_or_h
},
{
name: "listFiles",
type: "boolean",
},
{
name: "locale",
type: "string",
},
{
name: "mapRoot",
type: "string",
isFilePath: true,
description: ts.Diagnostics.Specify_the_location_where_debugger_should_locate_map_files_instead_of_generated_locations,
paramType: ts.Diagnostics.LOCATION,
},
{
name: "module",
shortName: "m",
type: ts.createMap({
"none": ts.ModuleKind.None,
"commonjs": ts.ModuleKind.CommonJS,
"amd": ts.ModuleKind.AMD,
"system": ts.ModuleKind.System,
"umd": ts.ModuleKind.UMD,
"es6": ts.ModuleKind.ES2015,
"es2015": ts.ModuleKind.ES2015,
}),
description: ts.Diagnostics.Specify_module_code_generation_Colon_commonjs_amd_system_umd_or_es2015,
paramType: ts.Diagnostics.KIND,
},
{
name: "newLine",
type: ts.createMap({
"crlf": 0 /* CarriageReturnLineFeed */,
"lf": 1 /* LineFeed */
}),
description: ts.Diagnostics.Specify_the_end_of_line_sequence_to_be_used_when_emitting_files_Colon_CRLF_dos_or_LF_unix,
paramType: ts.Diagnostics.NEWLINE,
},
{
name: "noEmit",
type: "boolean",
description: ts.Diagnostics.Do_not_emit_outputs,
},
{
name: "noEmitHelpers",
type: "boolean"
},
{
name: "noEmitOnError",
type: "boolean",
description: ts.Diagnostics.Do_not_emit_outputs_if_any_errors_were_reported,
},
{
name: "noErrorTruncation",
type: "boolean"
},
{
name: "noImplicitAny",
type: "boolean",
description: ts.Diagnostics.Raise_error_on_expressions_and_declarations_with_an_implied_any_type,
},
{
name: "noImplicitThis",
type: "boolean",
description: ts.Diagnostics.Raise_error_on_this_expressions_with_an_implied_any_type,
},
{
name: "noUnusedLocals",
type: "boolean",
description: ts.Diagnostics.Report_errors_on_unused_locals,
},
{
name: "noUnusedParameters",
type: "boolean",
description: ts.Diagnostics.Report_errors_on_unused_parameters,
},
{
name: "noLib",
type: "boolean",
},
{
name: "noResolve",
type: "boolean",
},
{
name: "skipDefaultLibCheck",
type: "boolean",
},
{
name: "skipLibCheck",
type: "boolean",
description: ts.Diagnostics.Skip_type_checking_of_declaration_files,
},
{
name: "out",
type: "string",
isFilePath: false,
// for correct behaviour, please use outFile
paramType: ts.Diagnostics.FILE,
},
{
name: "outFile",
type: "string",
isFilePath: true,
description: ts.Diagnostics.Concatenate_and_emit_output_to_single_file,
paramType: ts.Diagnostics.FILE,
},
{
name: "outDir",
type: "string",
isFilePath: true,
description: ts.Diagnostics.Redirect_output_structure_to_the_directory,
paramType: ts.Diagnostics.DIRECTORY,
},
{
name: "preserveConstEnums",
type: "boolean",
description: ts.Diagnostics.Do_not_erase_const_enum_declarations_in_generated_code
},
{
name: "pretty",
description: ts.Diagnostics.Stylize_errors_and_messages_using_color_and_context_experimental,
type: "boolean"
},
{
name: "project",
shortName: "p",
type: "string",
isFilePath: true,
description: ts.Diagnostics.Compile_the_project_in_the_given_directory,
paramType: ts.Diagnostics.DIRECTORY
},
{
name: "removeComments",
type: "boolean",
description: ts.Diagnostics.Do_not_emit_comments_to_output,
},
{
name: "rootDir",
type: "string",
isFilePath: true,
paramType: ts.Diagnostics.LOCATION,
description: ts.Diagnostics.Specify_the_root_directory_of_input_files_Use_to_control_the_output_directory_structure_with_outDir,
},
{
name: "isolatedModules",
type: "boolean",
},
{
name: "sourceMap",
type: "boolean",
description: ts.Diagnostics.Generates_corresponding_map_file,
},
{
name: "sourceRoot",
type: "string",
isFilePath: true,
description: ts.Diagnostics.Specify_the_location_where_debugger_should_locate_TypeScript_files_instead_of_source_locations,
paramType: ts.Diagnostics.LOCATION,
},
{
name: "suppressExcessPropertyErrors",
type: "boolean",
description: ts.Diagnostics.Suppress_excess_property_checks_for_object_literals,
experimental: true
},
{
name: "suppressImplicitAnyIndexErrors",
type: "boolean",
description: ts.Diagnostics.Suppress_noImplicitAny_errors_for_indexing_objects_lacking_index_signatures,
},
{
name: "stripInternal",
type: "boolean",
description: ts.Diagnostics.Do_not_emit_declarations_for_code_that_has_an_internal_annotation,
experimental: true
},
{
name: "target",
shortName: "t",
type: ts.createMap({
"es3": 0 /* ES3 */,
"es5": 1 /* ES5 */,
"es6": 2 /* ES2015 */,
"es2015": 2 /* ES2015 */,
"es2016": 3 /* ES2016 */,
"es2017": 4 /* ES2017 */,
"esnext": 5 /* ESNext */,
}),
description: ts.Diagnostics.Specify_ECMAScript_target_version_Colon_ES3_default_ES5_or_ES2015,
paramType: ts.Diagnostics.VERSION,
},
{
name: "version",
shortName: "v",
type: "boolean",
description: ts.Diagnostics.Print_the_compiler_s_version,
},
{
name: "watch",
shortName: "w",
type: "boolean",
description: ts.Diagnostics.Watch_input_files,
},
{
name: "experimentalDecorators",
type: "boolean",
description: ts.Diagnostics.Enables_experimental_support_for_ES7_decorators
},
{
name: "emitDecoratorMetadata",
type: "boolean",
experimental: true,
description: ts.Diagnostics.Enables_experimental_support_for_emitting_type_metadata_for_decorators
},
{
name: "moduleResolution",
type: ts.createMap({
"node": ts.ModuleResolutionKind.NodeJs,
"classic": ts.ModuleResolutionKind.Classic,
}),
description: ts.Diagnostics.Specify_module_resolution_strategy_Colon_node_Node_js_or_classic_TypeScript_pre_1_6,
paramType: ts.Diagnostics.STRATEGY,
},
{
name: "allowUnusedLabels",
type: "boolean",
description: ts.Diagnostics.Do_not_report_errors_on_unused_labels
},
{
name: "noImplicitReturns",
type: "boolean",
description: ts.Diagnostics.Report_error_when_not_all_code_paths_in_function_return_a_value
},
{
name: "noFallthroughCasesInSwitch",
type: "boolean",
description: ts.Diagnostics.Report_errors_for_fallthrough_cases_in_switch_statement
},
{
name: "allowUnreachableCode",
type: "boolean",
description: ts.Diagnostics.Do_not_report_errors_on_unreachable_code
},
{
name: "forceConsistentCasingInFileNames",
type: "boolean",
description: ts.Diagnostics.Disallow_inconsistently_cased_references_to_the_same_file
},
{
name: "baseUrl",
type: "string",
isFilePath: true,
description: ts.Diagnostics.Base_directory_to_resolve_non_absolute_module_names
},
{
// this option can only be specified in tsconfig.json
// use type = object to copy the value as-is
name: "paths",
type: "object",
isTSConfigOnly: true
},
{
// this option can only be specified in tsconfig.json
// use type = object to copy the value as-is
name: "rootDirs",
type: "list",
isTSConfigOnly: true,
element: {
name: "rootDirs",
type: "string",
isFilePath: true
}
},
{
name: "typeRoots",
type: "list",
element: {
name: "typeRoots",
type: "string",
isFilePath: true
}
},
{
name: "types",
type: "list",
element: {
name: "types",
type: "string"
},
description: ts.Diagnostics.Type_declaration_files_to_be_included_in_compilation
},
{
name: "traceResolution",
type: "boolean",
description: ts.Diagnostics.Enable_tracing_of_the_name_resolution_process
},
{
name: "allowJs",
type: "boolean",
description: ts.Diagnostics.Allow_javascript_files_to_be_compiled
},
{
name: "allowSyntheticDefaultImports",
type: "boolean",
description: ts.Diagnostics.Allow_default_imports_from_modules_with_no_default_export_This_does_not_affect_code_emit_just_typechecking
},
{
name: "noImplicitUseStrict",
type: "boolean",
description: ts.Diagnostics.Do_not_emit_use_strict_directives_in_module_output
},
{
name: "maxNodeModuleJsDepth",
type: "number",
description: ts.Diagnostics.The_maximum_dependency_depth_to_search_under_node_modules_and_load_JavaScript_files
},
{
name: "listEmittedFiles",
type: "boolean"
},
{
name: "lib",
type: "list",
element: {
name: "lib",
type: ts.createMap({
// JavaScript only
"es5": "lib.es5.d.ts",
"es6": "lib.es2015.d.ts",
"es2015": "lib.es2015.d.ts",
"es7": "lib.es2016.d.ts",
"es2016": "lib.es2016.d.ts",
"es2017": "lib.es2017.d.ts",
// Host only
"dom": "lib.dom.d.ts",
"dom.iterable": "lib.dom.iterable.d.ts",
"webworker": "lib.webworker.d.ts",
"scripthost": "lib.scripthost.d.ts",
// ES2015 Or ESNext By-feature options
"es2015.core": "lib.es2015.core.d.ts",
"es2015.collection": "lib.es2015.collection.d.ts",
"es2015.generator": "lib.es2015.generator.d.ts",
"es2015.iterable": "lib.es2015.iterable.d.ts",
"es2015.promise": "lib.es2015.promise.d.ts",
"es2015.proxy": "lib.es2015.proxy.d.ts",
"es2015.reflect": "lib.es2015.reflect.d.ts",
"es2015.symbol": "lib.es2015.symbol.d.ts",
"es2015.symbol.wellknown": "lib.es2015.symbol.wellknown.d.ts",
"es2016.array.include": "lib.es2016.array.include.d.ts",
"es2017.object": "lib.es2017.object.d.ts",
"es2017.sharedmemory": "lib.es2017.sharedmemory.d.ts",
"es2017.string": "lib.es2017.string.d.ts",
}),
},
description: ts.Diagnostics.Specify_library_files_to_be_included_in_the_compilation_Colon
},
{
name: "disableSizeLimit",
type: "boolean"
},
{
name: "strictNullChecks",
type: "boolean",
description: ts.Diagnostics.Enable_strict_null_checks
},
{
name: "importHelpers",
type: "boolean",
description: ts.Diagnostics.Import_emit_helpers_from_tslib
},
{
name: "alwaysStrict",
type: "boolean",
description: ts.Diagnostics.Parse_in_strict_mode_and_emit_use_strict_for_each_source_file
}
];
/* @internal */
ts.typingOptionDeclarations = [
{
name: "enableAutoDiscovery",
type: "boolean",
},
{
name: "include",
type: "list",
element: {
name: "include",
type: "string"
}
},
{
name: "exclude",
type: "list",
element: {
name: "exclude",
type: "string"
}
}
];
/* @internal */
ts.defaultInitCompilerOptions = {
module: ts.ModuleKind.CommonJS,
target: 1 /* ES5 */,
noImplicitAny: false,
sourceMap: false,
};
var optionNameMapCache;
/* @internal */
function getOptionNameMap() {
if (optionNameMapCache) {
return optionNameMapCache;
}
var optionNameMap = ts.createMap();
var shortOptionNames = ts.createMap();
ts.forEach(ts.optionDeclarations, function (option) {
optionNameMap[option.name.toLowerCase()] = option;
if (option.shortName) {
shortOptionNames[option.shortName] = option.name;
}
});
optionNameMapCache = { optionNameMap: optionNameMap, shortOptionNames: shortOptionNames };
return optionNameMapCache;
}
ts.getOptionNameMap = getOptionNameMap;
/* @internal */
function createCompilerDiagnosticForInvalidCustomType(opt) {
var namesOfType = Object.keys(opt.type).map(function (key) { return "'" + key + "'"; }).join(", ");
return ts.createCompilerDiagnostic(ts.Diagnostics.Argument_for_0_option_must_be_Colon_1, "--" + opt.name, namesOfType);
}
ts.createCompilerDiagnosticForInvalidCustomType = createCompilerDiagnosticForInvalidCustomType;
/* @internal */
function parseCustomTypeOption(opt, value, errors) {
var key = trimString((value || "")).toLowerCase();
var map = opt.type;
if (key in map) {
return map[key];
}
else {
errors.push(createCompilerDiagnosticForInvalidCustomType(opt));
}
}
ts.parseCustomTypeOption = parseCustomTypeOption;
/* @internal */
function parseListTypeOption(opt, value, errors) {
if (value === void 0) { value = ""; }
value = trimString(value);
if (ts.startsWith(value, "-")) {
return undefined;
}
if (value === "") {
return [];
}
var values = value.split(",");
switch (opt.element.type) {
case "number":
return ts.map(values, parseInt);
case "string":
return ts.map(values, function (v) { return v || ""; });
default:
return ts.filter(ts.map(values, function (v) { return parseCustomTypeOption(opt.element, v, errors); }), function (v) { return !!v; });
}
}
ts.parseListTypeOption = parseListTypeOption;
/* @internal */
function parseCommandLine(commandLine, readFile) {
var options = {};
var fileNames = [];
var errors = [];
var _a = getOptionNameMap(), optionNameMap = _a.optionNameMap, shortOptionNames = _a.shortOptionNames;
parseStrings(commandLine);
return {
options: options,
fileNames: fileNames,
errors: errors
};
function parseStrings(args) {
var i = 0;
while (i < args.length) {
var s = args[i];
i++;
if (s.charCodeAt(0) === 64 /* at */) {
parseResponseFile(s.slice(1));
}
else if (s.charCodeAt(0) === 45 /* minus */) {
s = s.slice(s.charCodeAt(1) === 45 /* minus */ ? 2 : 1).toLowerCase();
// Try to translate short option names to their full equivalents.
if (s in shortOptionNames) {
s = shortOptionNames[s];
}
if (s in optionNameMap) {
var opt = optionNameMap[s];
if (opt.isTSConfigOnly) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Option_0_can_only_be_specified_in_tsconfig_json_file, opt.name));
}
else {
// Check to see if no argument was provided (e.g. "--locale" is the last command-line argument).
if (!args[i] && opt.type !== "boolean") {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Compiler_option_0_expects_an_argument, opt.name));
}
switch (opt.type) {
case "number":
options[opt.name] = parseInt(args[i]);
i++;
break;
case "boolean":
// boolean flag has optional value true, false, others
var optValue = args[i];
options[opt.name] = optValue !== "false";
// consume next argument as boolean flag value
if (optValue === "false" || optValue === "true") {
i++;
}
break;
case "string":
options[opt.name] = args[i] || "";
i++;
break;
case "list":
var result = parseListTypeOption(opt, args[i], errors);
options[opt.name] = result || [];
if (result) {
i++;
}
break;
// If not a primitive, the possible types are specified in what is effectively a map of options.
default:
options[opt.name] = parseCustomTypeOption(opt, args[i], errors);
i++;
break;
}
}
}
else {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Unknown_compiler_option_0, s));
}
}
else {
fileNames.push(s);
}
}
}
function parseResponseFile(fileName) {
var text = readFile ? readFile(fileName) : ts.sys.readFile(fileName);
if (!text) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.File_0_not_found, fileName));
return;
}
var args = [];
var pos = 0;
while (true) {
while (pos < text.length && text.charCodeAt(pos) <= 32 /* space */)
pos++;
if (pos >= text.length)
break;
var start = pos;
if (text.charCodeAt(start) === 34 /* doubleQuote */) {
pos++;
while (pos < text.length && text.charCodeAt(pos) !== 34 /* doubleQuote */)
pos++;
if (pos < text.length) {
args.push(text.substring(start + 1, pos));
pos++;
}
else {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Unterminated_quoted_string_in_response_file_0, fileName));
}
}
else {
while (text.charCodeAt(pos) > 32 /* space */)
pos++;
args.push(text.substring(start, pos));
}
}
parseStrings(args);
}
}
ts.parseCommandLine = parseCommandLine;
/**
* Read tsconfig.json file
* @param fileName The path to the config file
*/
function readConfigFile(fileName, readFile) {
var text = "";
try {
text = readFile(fileName);
}
catch (e) {
return { error: ts.createCompilerDiagnostic(ts.Diagnostics.Cannot_read_file_0_Colon_1, fileName, e.message) };
}
return parseConfigFileTextToJson(fileName, text);
}
ts.readConfigFile = readConfigFile;
/**
* Parse the text of the tsconfig.json file
* @param fileName The path to the config file
* @param jsonText The text of the config file
*/
function parseConfigFileTextToJson(fileName, jsonText, stripComments) {
if (stripComments === void 0) { stripComments = true; }
try {
var jsonTextToParse = stripComments ? removeComments(jsonText) : jsonText;
return { config: /\S/.test(jsonTextToParse) ? JSON.parse(jsonTextToParse) : {} };
}
catch (e) {
return { error: ts.createCompilerDiagnostic(ts.Diagnostics.Failed_to_parse_file_0_Colon_1, fileName, e.message) };
}
}
ts.parseConfigFileTextToJson = parseConfigFileTextToJson;
/**
* Generate tsconfig configuration when running command line "--init"
* @param options commandlineOptions to be generated into tsconfig.json
* @param fileNames array of filenames to be generated into tsconfig.json
*/
/* @internal */
function generateTSConfig(options, fileNames) {
var compilerOptions = ts.extend(options, ts.defaultInitCompilerOptions);
var configurations = {
compilerOptions: serializeCompilerOptions(compilerOptions)
};
if (fileNames && fileNames.length) {
// only set the files property if we have at least one file
configurations.files = fileNames;
}
return configurations;
function getCustomTypeMapOfCommandLineOption(optionDefinition) {
if (optionDefinition.type === "string" || optionDefinition.type === "number" || optionDefinition.type === "boolean") {
// this is of a type CommandLineOptionOfPrimitiveType
return undefined;
}
else if (optionDefinition.type === "list") {
return getCustomTypeMapOfCommandLineOption(optionDefinition.element);
}
else {
return optionDefinition.type;
}
}
function getNameOfCompilerOptionValue(value, customTypeMap) {
// There is a typeMap associated with this command-line option so use it to map value back to its name
for (var key in customTypeMap) {
if (customTypeMap[key] === value) {
return key;
}
}
return undefined;
}
function serializeCompilerOptions(options) {
var result = ts.createMap();
var optionsNameMap = getOptionNameMap().optionNameMap;
for (var name_41 in options) {
if (ts.hasProperty(options, name_41)) {
// tsconfig only options cannot be specified via command line,
// so we can assume that only types that can appear here string | number | boolean
switch (name_41) {
case "init":
case "watch":
case "version":
case "help":
case "project":
break;
default:
var value = options[name_41];
var optionDefinition = optionsNameMap[name_41.toLowerCase()];
if (optionDefinition) {
var customTypeMap = getCustomTypeMapOfCommandLineOption(optionDefinition);
if (!customTypeMap) {
// There is no map associated with this compiler option then use the value as-is
// This is the case if the value is expect to be string, number, boolean or list of string
result[name_41] = value;
}
else {
if (optionDefinition.type === "list") {
var convertedValue = [];
for (var _i = 0, _a = value; _i < _a.length; _i++) {
var element = _a[_i];
convertedValue.push(getNameOfCompilerOptionValue(element, customTypeMap));
}
result[name_41] = convertedValue;
}
else {
// There is a typeMap associated with this command-line option so use it to map value back to its name
result[name_41] = getNameOfCompilerOptionValue(value, customTypeMap);
}
}
}
break;
}
}
}
return result;
}
}
ts.generateTSConfig = generateTSConfig;
/**
* Remove the comments from a json like text.
* Comments can be single line comments (starting with # or //) or multiline comments using / * * /
*
* This method replace comment content by whitespace rather than completely remove them to keep positions in json parsing error reporting accurate.
*/
function removeComments(jsonText) {
var output = "";
var scanner = ts.createScanner(1 /* ES5 */, /* skipTrivia */ false, 0 /* Standard */, jsonText);
var token;
while ((token = scanner.scan()) !== 1 /* EndOfFileToken */) {
switch (token) {
case 2 /* SingleLineCommentTrivia */:
case 3 /* MultiLineCommentTrivia */:
// replace comments with whitespace to preserve original character positions
output += scanner.getTokenText().replace(/\S/g, " ");
break;
default:
output += scanner.getTokenText();
break;
}
}
return output;
}
/**
* Parse the contents of a config file (tsconfig.json).
* @param json The contents of the config file to parse
* @param host Instance of ParseConfigHost used to enumerate files in folder.
* @param basePath A root directory to resolve relative path entries in the config
* file to. e.g. outDir
*/
function parseJsonConfigFileContent(json, host, basePath, existingOptions, configFileName, resolutionStack) {
if (existingOptions === void 0) { existingOptions = {}; }
if (resolutionStack === void 0) { resolutionStack = []; }
var errors = [];
var getCanonicalFileName = ts.createGetCanonicalFileName(host.useCaseSensitiveFileNames);
var resolvedPath = ts.toPath(configFileName || "", basePath, getCanonicalFileName);
if (resolutionStack.indexOf(resolvedPath) >= 0) {
return {
options: {},
fileNames: [],
typingOptions: {},
raw: json,
errors: [ts.createCompilerDiagnostic(ts.Diagnostics.Circularity_detected_while_resolving_configuration_Colon_0, resolutionStack.concat([resolvedPath]).join(" -> "))],
wildcardDirectories: {}
};
}
var options = convertCompilerOptionsFromJsonWorker(json["compilerOptions"], basePath, errors, configFileName);
var typingOptions = convertTypingOptionsFromJsonWorker(json["typingOptions"], basePath, errors, configFileName);
if (json["extends"]) {
var _a = [undefined, undefined, undefined, {}], include = _a[0], exclude = _a[1], files = _a[2], baseOptions = _a[3];
if (typeof json["extends"] === "string") {
_b = (tryExtendsName(json["extends"]) || [include, exclude, files, baseOptions]), include = _b[0], exclude = _b[1], files = _b[2], baseOptions = _b[3];
}
else {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Compiler_option_0_requires_a_value_of_type_1, "extends", "string"));
}
if (include && !json["include"]) {
json["include"] = include;
}
if (exclude && !json["exclude"]) {
json["exclude"] = exclude;
}
if (files && !json["files"]) {
json["files"] = files;
}
options = ts.assign({}, baseOptions, options);
}
options = ts.extend(existingOptions, options);
options.configFilePath = configFileName;
var _c = getFileNames(errors), fileNames = _c.fileNames, wildcardDirectories = _c.wildcardDirectories;
var compileOnSave = convertCompileOnSaveOptionFromJson(json, basePath, errors);
return {
options: options,
fileNames: fileNames,
typingOptions: typingOptions,
raw: json,
errors: errors,
wildcardDirectories: wildcardDirectories,
compileOnSave: compileOnSave
};
function tryExtendsName(extendedConfig) {
// If the path isn't a rooted or relative path, don't try to resolve it (we reserve the right to special case module-id like paths in the future)
if (!(ts.isRootedDiskPath(extendedConfig) || ts.startsWith(ts.normalizeSlashes(extendedConfig), "./") || ts.startsWith(ts.normalizeSlashes(extendedConfig), "../"))) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.The_path_in_an_extends_options_must_be_relative_or_rooted));
return;
}
var extendedConfigPath = ts.toPath(extendedConfig, basePath, getCanonicalFileName);
if (!host.fileExists(extendedConfigPath) && !ts.endsWith(extendedConfigPath, ".json")) {
extendedConfigPath = extendedConfigPath + ".json";
if (!host.fileExists(extendedConfigPath)) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.File_0_does_not_exist, extendedConfig));
return;
}
}
var extendedResult = readConfigFile(extendedConfigPath, function (path) { return host.readFile(path); });
if (extendedResult.error) {
errors.push(extendedResult.error);
return;
}
var extendedDirname = ts.getDirectoryPath(extendedConfigPath);
var relativeDifference = ts.convertToRelativePath(extendedDirname, basePath, getCanonicalFileName);
var updatePath = function (path) { return ts.isRootedDiskPath(path) ? path : ts.combinePaths(relativeDifference, path); };
// Merge configs (copy the resolution stack so it is never reused between branches in potential diamond-problem scenarios)
var result = parseJsonConfigFileContent(extendedResult.config, host, extendedDirname, /*existingOptions*/ undefined, ts.getBaseFileName(extendedConfigPath), resolutionStack.concat([resolvedPath]));
errors.push.apply(errors, result.errors);
var _a = ts.map(["include", "exclude", "files"], function (key) {
if (!json[key] && extendedResult.config[key]) {
return ts.map(extendedResult.config[key], updatePath);
}
}), include = _a[0], exclude = _a[1], files = _a[2];
return [include, exclude, files, result.options];
}
function getFileNames(errors) {
var fileNames;
if (ts.hasProperty(json, "files")) {
if (ts.isArray(json["files"])) {
fileNames = json["files"];
if (fileNames.length === 0) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.The_files_list_in_config_file_0_is_empty, configFileName || "tsconfig.json"));
}
}
else {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Compiler_option_0_requires_a_value_of_type_1, "files", "Array"));
}
}
var includeSpecs;
if (ts.hasProperty(json, "include")) {
if (ts.isArray(json["include"])) {
includeSpecs = json["include"];
}
else {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Compiler_option_0_requires_a_value_of_type_1, "include", "Array"));
}
}
var excludeSpecs;
if (ts.hasProperty(json, "exclude")) {
if (ts.isArray(json["exclude"])) {
excludeSpecs = json["exclude"];
}
else {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Compiler_option_0_requires_a_value_of_type_1, "exclude", "Array"));
}
}
else if (ts.hasProperty(json, "excludes")) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Unknown_option_excludes_Did_you_mean_exclude));
}
else {
// By default, exclude common package folders and the outDir
excludeSpecs = ["node_modules", "bower_components", "jspm_packages"];
var outDir = json["compilerOptions"] && json["compilerOptions"]["outDir"];
if (outDir) {
excludeSpecs.push(outDir);
}
}
if (fileNames === undefined && includeSpecs === undefined) {
includeSpecs = ["**/*"];
}
var result = matchFileNames(fileNames, includeSpecs, excludeSpecs, basePath, options, host, errors);
if (result.fileNames.length === 0 && !ts.hasProperty(json, "files") && resolutionStack.length === 0) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.No_inputs_were_found_in_config_file_0_Specified_include_paths_were_1_and_exclude_paths_were_2, configFileName || "tsconfig.json", JSON.stringify(includeSpecs || []), JSON.stringify(excludeSpecs || [])));
}
return result;
}
var _b;
}
ts.parseJsonConfigFileContent = parseJsonConfigFileContent;
function convertCompileOnSaveOptionFromJson(jsonOption, basePath, errors) {
if (!ts.hasProperty(jsonOption, ts.compileOnSaveCommandLineOption.name)) {
return false;
}
var result = convertJsonOption(ts.compileOnSaveCommandLineOption, jsonOption["compileOnSave"], basePath, errors);
if (typeof result === "boolean" && result) {
return result;
}
return false;
}
ts.convertCompileOnSaveOptionFromJson = convertCompileOnSaveOptionFromJson;
function convertCompilerOptionsFromJson(jsonOptions, basePath, configFileName) {
var errors = [];
var options = convertCompilerOptionsFromJsonWorker(jsonOptions, basePath, errors, configFileName);
return { options: options, errors: errors };
}
ts.convertCompilerOptionsFromJson = convertCompilerOptionsFromJson;
function convertTypingOptionsFromJson(jsonOptions, basePath, configFileName) {
var errors = [];
var options = convertTypingOptionsFromJsonWorker(jsonOptions, basePath, errors, configFileName);
return { options: options, errors: errors };
}
ts.convertTypingOptionsFromJson = convertTypingOptionsFromJson;
function convertCompilerOptionsFromJsonWorker(jsonOptions, basePath, errors, configFileName) {
var options = ts.getBaseFileName(configFileName) === "jsconfig.json"
? { allowJs: true, maxNodeModuleJsDepth: 2, allowSyntheticDefaultImports: true, skipLibCheck: true }
: {};
convertOptionsFromJson(ts.optionDeclarations, jsonOptions, basePath, options, ts.Diagnostics.Unknown_compiler_option_0, errors);
return options;
}
function convertTypingOptionsFromJsonWorker(jsonOptions, basePath, errors, configFileName) {
var options = { enableAutoDiscovery: ts.getBaseFileName(configFileName) === "jsconfig.json", include: [], exclude: [] };
convertOptionsFromJson(ts.typingOptionDeclarations, jsonOptions, basePath, options, ts.Diagnostics.Unknown_typing_option_0, errors);
return options;
}
function convertOptionsFromJson(optionDeclarations, jsonOptions, basePath, defaultOptions, diagnosticMessage, errors) {
if (!jsonOptions) {
return;
}
var optionNameMap = ts.arrayToMap(optionDeclarations, function (opt) { return opt.name; });
for (var id in jsonOptions) {
if (id in optionNameMap) {
var opt = optionNameMap[id];
defaultOptions[opt.name] = convertJsonOption(opt, jsonOptions[id], basePath, errors);
}
else {
errors.push(ts.createCompilerDiagnostic(diagnosticMessage, id));
}
}
}
function convertJsonOption(opt, value, basePath, errors) {
var optType = opt.type;
var expectedType = typeof optType === "string" ? optType : "string";
if (optType === "list" && ts.isArray(value)) {
return convertJsonOptionOfListType(opt, value, basePath, errors);
}
else if (typeof value === expectedType) {
if (typeof optType !== "string") {
return convertJsonOptionOfCustomType(opt, value, errors);
}
else {
if (opt.isFilePath) {
value = ts.normalizePath(ts.combinePaths(basePath, value));
if (value === "") {
value = ".";
}
}
}
return value;
}
else {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.Compiler_option_0_requires_a_value_of_type_1, opt.name, expectedType));
}
}
function convertJsonOptionOfCustomType(opt, value, errors) {
var key = value.toLowerCase();
if (key in opt.type) {
return opt.type[key];
}
else {
errors.push(createCompilerDiagnosticForInvalidCustomType(opt));
}
}
function convertJsonOptionOfListType(option, values, basePath, errors) {
return ts.filter(ts.map(values, function (v) { return convertJsonOption(option.element, v, basePath, errors); }), function (v) { return !!v; });
}
function trimString(s) {
return typeof s.trim === "function" ? s.trim() : s.replace(/^[\s]+|[\s]+$/g, "");
}
/**
* Tests for a path that ends in a recursive directory wildcard.
* Matches **, \**, **\, and \**\, but not a**b.
*
* NOTE: used \ in place of / above to avoid issues with multiline comments.
*
* Breakdown:
* (^|\/) # matches either the beginning of the string or a directory separator.
* \*\* # matches the recursive directory wildcard "**".
* \/?$ # matches an optional trailing directory separator at the end of the string.
*/
var invalidTrailingRecursionPattern = /(^|\/)\*\*\/?$/;
/**
* Tests for a path with multiple recursive directory wildcards.
* Matches **\** and **\a\**, but not **\a**b.
*
* NOTE: used \ in place of / above to avoid issues with multiline comments.
*
* Breakdown:
* (^|\/) # matches either the beginning of the string or a directory separator.
* \*\*\/ # matches a recursive directory wildcard "**" followed by a directory separator.
* (.*\/)? # optionally matches any number of characters followed by a directory separator.
* \*\* # matches a recursive directory wildcard "**"
* ($|\/) # matches either the end of the string or a directory separator.
*/
var invalidMultipleRecursionPatterns = /(^|\/)\*\*\/(.*\/)?\*\*($|\/)/;
/**
* Tests for a path where .. appears after a recursive directory wildcard.
* Matches **\..\*, **\a\..\*, and **\.., but not ..\**\*
*
* NOTE: used \ in place of / above to avoid issues with multiline comments.
*
* Breakdown:
* (^|\/) # matches either the beginning of the string or a directory separator.
* \*\*\/ # matches a recursive directory wildcard "**" followed by a directory separator.
* (.*\/)? # optionally matches any number of characters followed by a directory separator.
* \.\. # matches a parent directory path component ".."
* ($|\/) # matches either the end of the string or a directory separator.
*/
var invalidDotDotAfterRecursiveWildcardPattern = /(^|\/)\*\*\/(.*\/)?\.\.($|\/)/;
/**
* Tests for a path containing a wildcard character in a directory component of the path.
* Matches \*\, \?\, and \a*b\, but not \a\ or \a\*.
*
* NOTE: used \ in place of / above to avoid issues with multiline comments.
*
* Breakdown:
* \/ # matches a directory separator.
* [^/]*? # matches any number of characters excluding directory separators (non-greedy).
* [*?] # matches either a wildcard character (* or ?)
* [^/]* # matches any number of characters excluding directory separators (greedy).
* \/ # matches a directory separator.
*/
var watchRecursivePattern = /\/[^/]*?[*?][^/]*\//;
/**
* Matches the portion of a wildcard path that does not contain wildcards.
* Matches \a of \a\*, or \a\b\c of \a\b\c\?\d.
*
* NOTE: used \ in place of / above to avoid issues with multiline comments.
*
* Breakdown:
* ^ # matches the beginning of the string
* [^*?]* # matches any number of non-wildcard characters
* (?=\/[^/]*[*?]) # lookahead that matches a directory separator followed by
* # a path component that contains at least one wildcard character (* or ?).
*/
var wildcardDirectoryPattern = /^[^*?]*(?=\/[^/]*[*?])/;
/**
* Expands an array of file specifications.
*
* @param fileNames The literal file names to include.
* @param include The wildcard file specifications to include.
* @param exclude The wildcard file specifications to exclude.
* @param basePath The base path for any relative file specifications.
* @param options Compiler options.
* @param host The host used to resolve files and directories.
* @param errors An array for diagnostic reporting.
*/
function matchFileNames(fileNames, include, exclude, basePath, options, host, errors) {
basePath = ts.normalizePath(basePath);
// The exclude spec list is converted into a regular expression, which allows us to quickly
// test whether a file or directory should be excluded before recursively traversing the
// file system.
var keyMapper = host.useCaseSensitiveFileNames ? caseSensitiveKeyMapper : caseInsensitiveKeyMapper;
// Literal file names (provided via the "files" array in tsconfig.json) are stored in a
// file map with a possibly case insensitive key. We use this map later when when including
// wildcard paths.
var literalFileMap = ts.createMap();
// Wildcard paths (provided via the "includes" array in tsconfig.json) are stored in a
// file map with a possibly case insensitive key. We use this map to store paths matched
// via wildcard, and to handle extension priority.
var wildcardFileMap = ts.createMap();
if (include) {
include = validateSpecs(include, errors, /*allowTrailingRecursion*/ false);
}
if (exclude) {
exclude = validateSpecs(exclude, errors, /*allowTrailingRecursion*/ true);
}
// Wildcard directories (provided as part of a wildcard path) are stored in a
// file map that marks whether it was a regular wildcard match (with a `*` or `?` token),
// or a recursive directory. This information is used by filesystem watchers to monitor for
// new entries in these paths.
var wildcardDirectories = getWildcardDirectories(include, exclude, basePath, host.useCaseSensitiveFileNames);
// Rather than requery this for each file and filespec, we query the supported extensions
// once and store it on the expansion context.
var supportedExtensions = ts.getSupportedExtensions(options);
// Literal files are always included verbatim. An "include" or "exclude" specification cannot
// remove a literal file.
if (fileNames) {
for (var _i = 0, fileNames_1 = fileNames; _i < fileNames_1.length; _i++) {
var fileName = fileNames_1[_i];
var file = ts.combinePaths(basePath, fileName);
literalFileMap[keyMapper(file)] = file;
}
}
if (include && include.length > 0) {
for (var _a = 0, _b = host.readDirectory(basePath, supportedExtensions, exclude, include); _a < _b.length; _a++) {
var file = _b[_a];
// If we have already included a literal or wildcard path with a
// higher priority extension, we should skip this file.
//
// This handles cases where we may encounter both <file>.ts and
// <file>.d.ts (or <file>.js if "allowJs" is enabled) in the same
// directory when they are compilation outputs.
if (hasFileWithHigherPriorityExtension(file, literalFileMap, wildcardFileMap, supportedExtensions, keyMapper)) {
continue;
}
// We may have included a wildcard path with a lower priority
// extension due to the user-defined order of entries in the
// "include" array. If there is a lower priority extension in the
// same directory, we should remove it.
removeWildcardFilesWithLowerPriorityExtension(file, wildcardFileMap, supportedExtensions, keyMapper);
var key = keyMapper(file);
if (!(key in literalFileMap) && !(key in wildcardFileMap)) {
wildcardFileMap[key] = file;
}
}
}
var literalFiles = ts.reduceProperties(literalFileMap, addFileToOutput, []);
var wildcardFiles = ts.reduceProperties(wildcardFileMap, addFileToOutput, []);
wildcardFiles.sort(host.useCaseSensitiveFileNames ? ts.compareStrings : ts.compareStringsCaseInsensitive);
return {
fileNames: literalFiles.concat(wildcardFiles),
wildcardDirectories: wildcardDirectories
};
}
function validateSpecs(specs, errors, allowTrailingRecursion) {
var validSpecs = [];
for (var _i = 0, specs_2 = specs; _i < specs_2.length; _i++) {
var spec = specs_2[_i];
if (!allowTrailingRecursion && invalidTrailingRecursionPattern.test(spec)) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.File_specification_cannot_end_in_a_recursive_directory_wildcard_Asterisk_Asterisk_Colon_0, spec));
}
else if (invalidMultipleRecursionPatterns.test(spec)) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.File_specification_cannot_contain_multiple_recursive_directory_wildcards_Asterisk_Asterisk_Colon_0, spec));
}
else if (invalidDotDotAfterRecursiveWildcardPattern.test(spec)) {
errors.push(ts.createCompilerDiagnostic(ts.Diagnostics.File_specification_cannot_contain_a_parent_directory_that_appears_after_a_recursive_directory_wildcard_Asterisk_Asterisk_Colon_0, spec));
}
else {
validSpecs.push(spec);
}
}
return validSpecs;
}
/**
* Gets directories in a set of include patterns that should be watched for changes.
*/
function getWildcardDirectories(include, exclude, path, useCaseSensitiveFileNames) {
// We watch a directory recursively if it contains a wildcard anywhere in a directory segment
// of the pattern:
//
// /a/b/**/d - Watch /a/b recursively to catch changes to any d in any subfolder recursively
// /a/b/*/d - Watch /a/b recursively to catch any d in any immediate subfolder, even if a new subfolder is added
// /a/b - Watch /a/b recursively to catch changes to anything in any recursive subfoler
//
// We watch a directory without recursion if it contains a wildcard in the file segment of
// the pattern:
//
// /a/b/* - Watch /a/b directly to catch any new file
// /a/b/a?z - Watch /a/b directly to catch any new file matching a?z
var rawExcludeRegex = ts.getRegularExpressionForWildcard(exclude, path, "exclude");
var excludeRegex = rawExcludeRegex && new RegExp(rawExcludeRegex, useCaseSensitiveFileNames ? "" : "i");
var wildcardDirectories = ts.createMap();
if (include !== undefined) {
var recursiveKeys = [];
for (var _i = 0, include_1 = include; _i < include_1.length; _i++) {
var file = include_1[_i];
var spec = ts.normalizePath(ts.combinePaths(path, file));
if (excludeRegex && excludeRegex.test(spec)) {
continue;
}
var match = getWildcardDirectoryFromSpec(spec, useCaseSensitiveFileNames);
if (match) {
var key = match.key, flags = match.flags;
var existingFlags = wildcardDirectories[key];
if (existingFlags === undefined || existingFlags < flags) {
wildcardDirectories[key] = flags;
if (flags === 1 /* Recursive */) {
recursiveKeys.push(key);
}
}
}
}
// Remove any subpaths under an existing recursively watched directory.
for (var key in wildcardDirectories) {
for (var _a = 0, recursiveKeys_1 = recursiveKeys; _a < recursiveKeys_1.length; _a++) {
var recursiveKey = recursiveKeys_1[_a];
if (key !== recursiveKey && ts.containsPath(recursiveKey, key, path, !useCaseSensitiveFileNames)) {
delete wildcardDirectories[key];
}
}
}
}
return wildcardDirectories;
}
function getWildcardDirectoryFromSpec(spec, useCaseSensitiveFileNames) {
var match = wildcardDirectoryPattern.exec(spec);
if (match) {
return {
key: useCaseSensitiveFileNames ? match[0] : match[0].toLowerCase(),
flags: watchRecursivePattern.test(spec) ? 1 /* Recursive */ : 0 /* None */
};
}
if (ts.isImplicitGlob(spec)) {
return { key: spec, flags: 1 /* Recursive */ };
}
return undefined;
}
/**
* Determines whether a literal or wildcard file has already been included that has a higher
* extension priority.
*
* @param file The path to the file.
* @param extensionPriority The priority of the extension.
* @param context The expansion context.
*/
function hasFileWithHigherPriorityExtension(file, literalFiles, wildcardFiles, extensions, keyMapper) {
var extensionPriority = ts.getExtensionPriority(file, extensions);
var adjustedExtensionPriority = ts.adjustExtensionPriority(extensionPriority);
for (var i = 0 /* Highest */; i < adjustedExtensionPriority; i++) {
var higherPriorityExtension = extensions[i];
var higherPriorityPath = keyMapper(ts.changeExtension(file, higherPriorityExtension));
if (higherPriorityPath in literalFiles || higherPriorityPath in wildcardFiles) {
return true;
}
}
return false;
}
/**
* Removes files included via wildcard expansion with a lower extension priority that have
* already been included.
*
* @param file The path to the file.
* @param extensionPriority The priority of the extension.
* @param context The expansion context.
*/
function removeWildcardFilesWithLowerPriorityExtension(file, wildcardFiles, extensions, keyMapper) {
var extensionPriority = ts.getExtensionPriority(file, extensions);
var nextExtensionPriority = ts.getNextLowestExtensionPriority(extensionPriority);
for (var i = nextExtensionPriority; i < extensions.length; i++) {
var lowerPriorityExtension = extensions[i];
var lowerPriorityPath = keyMapper(ts.changeExtension(file, lowerPriorityExtension));
delete wildcardFiles[lowerPriorityPath];
}
}
/**
* Adds a file to an array of files.
*
* @param output The output array.
* @param file The file path.
*/
function addFileToOutput(output, file) {
output.push(file);
return output;
}
/**
* Gets a case sensitive key.
*
* @param key The original key.
*/
function caseSensitiveKeyMapper(key) {
return key;
}
/**
* Gets a case insensitive key.
*
* @param key The original key.
*/
function caseInsensitiveKeyMapper(key) {
return key.toLowerCase();
}
})(ts || (ts = {}));
var ts;
(function (ts) {
var ScriptSnapshot;
(function (ScriptSnapshot) {
var StringScriptSnapshot = (function () {
function StringScriptSnapshot(text) {
this.text = text;
}
StringScriptSnapshot.prototype.getText = function (start, end) {
return this.text.substring(start, end);
};
StringScriptSnapshot.prototype.getLength = function () {
return this.text.length;
};
StringScriptSnapshot.prototype.getChangeRange = function () {
// Text-based snapshots do not support incremental parsing. Return undefined
// to signal that to the caller.
return undefined;
};
return StringScriptSnapshot;
}());
function fromString(text) {
return new StringScriptSnapshot(text);
}
ScriptSnapshot.fromString = fromString;
})(ScriptSnapshot = ts.ScriptSnapshot || (ts.ScriptSnapshot = {}));
var TextChange = (function () {
function TextChange() {
}
return TextChange;
}());
ts.TextChange = TextChange;
var HighlightSpanKind;
(function (HighlightSpanKind) {
HighlightSpanKind.none = "none";
HighlightSpanKind.definition = "definition";
HighlightSpanKind.reference = "reference";
HighlightSpanKind.writtenReference = "writtenReference";
})(HighlightSpanKind = ts.HighlightSpanKind || (ts.HighlightSpanKind = {}));
var IndentStyle;
(function (IndentStyle) {
IndentStyle[IndentStyle["None"] = 0] = "None";
IndentStyle[IndentStyle["Block"] = 1] = "Block";
IndentStyle[IndentStyle["Smart"] = 2] = "Smart";
})(IndentStyle = ts.IndentStyle || (ts.IndentStyle = {}));
var SymbolDisplayPartKind;
(function (SymbolDisplayPartKind) {
SymbolDisplayPartKind[SymbolDisplayPartKind["aliasName"] = 0] = "aliasName";
SymbolDisplayPartKind[SymbolDisplayPartKind["className"] = 1] = "className";
SymbolDisplayPartKind[SymbolDisplayPartKind["enumName"] = 2] = "enumName";
SymbolDisplayPartKind[SymbolDisplayPartKind["fieldName"] = 3] = "fieldName";
SymbolDisplayPartKind[SymbolDisplayPartKind["interfaceName"] = 4] = "interfaceName";
SymbolDisplayPartKind[SymbolDisplayPartKind["keyword"] = 5] = "keyword";
SymbolDisplayPartKind[SymbolDisplayPartKind["lineBreak"] = 6] = "lineBreak";
SymbolDisplayPartKind[SymbolDisplayPartKind["numericLiteral"] = 7] = "numericLiteral";
SymbolDisplayPartKind[SymbolDisplayPartKind["stringLiteral"] = 8] = "stringLiteral";
SymbolDisplayPartKind[SymbolDisplayPartKind["localName"] = 9] = "localName";
SymbolDisplayPartKind[SymbolDisplayPartKind["methodName"] = 10] = "methodName";
SymbolDisplayPartKind[SymbolDisplayPartKind["moduleName"] = 11] = "moduleName";
SymbolDisplayPartKind[SymbolDisplayPartKind["operator"] = 12] = "operator";
SymbolDisplayPartKind[SymbolDisplayPartKind["parameterName"] = 13] = "parameterName";
SymbolDisplayPartKind[SymbolDisplayPartKind["propertyName"] = 14] = "propertyName";
SymbolDisplayPartKind[SymbolDisplayPartKind["punctuation"] = 15] = "punctuation";
SymbolDisplayPartKind[SymbolDisplayPartKind["space"] = 16] = "space";
SymbolDisplayPartKind[SymbolDisplayPartKind["text"] = 17] = "text";
SymbolDisplayPartKind[SymbolDisplayPartKind["typeParameterName"] = 18] = "typeParameterName";
SymbolDisplayPartKind[SymbolDisplayPartKind["enumMemberName"] = 19] = "enumMemberName";
SymbolDisplayPartKind[SymbolDisplayPartKind["functionName"] = 20] = "functionName";
SymbolDisplayPartKind[SymbolDisplayPartKind["regularExpressionLiteral"] = 21] = "regularExpressionLiteral";
})(SymbolDisplayPartKind = ts.SymbolDisplayPartKind || (ts.SymbolDisplayPartKind = {}));
var OutputFileType;
(function (OutputFileType) {
OutputFileType[OutputFileType["JavaScript"] = 0] = "JavaScript";
OutputFileType[OutputFileType["SourceMap"] = 1] = "SourceMap";
OutputFileType[OutputFileType["Declaration"] = 2] = "Declaration";
})(OutputFileType = ts.OutputFileType || (ts.OutputFileType = {}));
var EndOfLineState;
(function (EndOfLineState) {
EndOfLineState[EndOfLineState["None"] = 0] = "None";
EndOfLineState[EndOfLineState["InMultiLineCommentTrivia"] = 1] = "InMultiLineCommentTrivia";
EndOfLineState[EndOfLineState["InSingleQuoteStringLiteral"] = 2] = "InSingleQuoteStringLiteral";
EndOfLineState[EndOfLineState["InDoubleQuoteStringLiteral"] = 3] = "InDoubleQuoteStringLiteral";
EndOfLineState[EndOfLineState["InTemplateHeadOrNoSubstitutionTemplate"] = 4] = "InTemplateHeadOrNoSubstitutionTemplate";
EndOfLineState[EndOfLineState["InTemplateMiddleOrTail"] = 5] = "InTemplateMiddleOrTail";
EndOfLineState[EndOfLineState["InTemplateSubstitutionPosition"] = 6] = "InTemplateSubstitutionPosition";
})(EndOfLineState = ts.EndOfLineState || (ts.EndOfLineState = {}));
var TokenClass;
(function (TokenClass) {
TokenClass[TokenClass["Punctuation"] = 0] = "Punctuation";
TokenClass[TokenClass["Keyword"] = 1] = "Keyword";
TokenClass[TokenClass["Operator"] = 2] = "Operator";
TokenClass[TokenClass["Comment"] = 3] = "Comment";
TokenClass[TokenClass["Whitespace"] = 4] = "Whitespace";
TokenClass[TokenClass["Identifier"] = 5] = "Identifier";
TokenClass[TokenClass["NumberLiteral"] = 6] = "NumberLiteral";
TokenClass[TokenClass["StringLiteral"] = 7] = "StringLiteral";
TokenClass[TokenClass["RegExpLiteral"] = 8] = "RegExpLiteral";
})(TokenClass = ts.TokenClass || (ts.TokenClass = {}));
// TODO: move these to enums
var ScriptElementKind;
(function (ScriptElementKind) {
ScriptElementKind.unknown = "";
ScriptElementKind.warning = "warning";
/** predefined type (void) or keyword (class) */
ScriptElementKind.keyword = "keyword";
/** top level script node */
ScriptElementKind.scriptElement = "script";
/** module foo {} */
ScriptElementKind.moduleElement = "module";
/** class X {} */
ScriptElementKind.classElement = "class";
/** var x = class X {} */
ScriptElementKind.localClassElement = "local class";
/** interface Y {} */
ScriptElementKind.interfaceElement = "interface";
/** type T = ... */
ScriptElementKind.typeElement = "type";
/** enum E */
ScriptElementKind.enumElement = "enum";
// TODO: GH#9983
ScriptElementKind.enumMemberElement = "const";
/**
* Inside module and script only
* const v = ..
*/
ScriptElementKind.variableElement = "var";
/** Inside function */
ScriptElementKind.localVariableElement = "local var";
/**
* Inside module and script only
* function f() { }
*/
ScriptElementKind.functionElement = "function";
/** Inside function */
ScriptElementKind.localFunctionElement = "local function";
/** class X { [public|private]* foo() {} } */
ScriptElementKind.memberFunctionElement = "method";
/** class X { [public|private]* [get|set] foo:number; } */
ScriptElementKind.memberGetAccessorElement = "getter";
ScriptElementKind.memberSetAccessorElement = "setter";
/**
* class X { [public|private]* foo:number; }
* interface Y { foo:number; }
*/
ScriptElementKind.memberVariableElement = "property";
/** class X { constructor() { } } */
ScriptElementKind.constructorImplementationElement = "constructor";
/** interface Y { ():number; } */
ScriptElementKind.callSignatureElement = "call";
/** interface Y { []:number; } */
ScriptElementKind.indexSignatureElement = "index";
/** interface Y { new():Y; } */
ScriptElementKind.constructSignatureElement = "construct";
/** function foo(*Y*: string) */
ScriptElementKind.parameterElement = "parameter";
ScriptElementKind.typeParameterElement = "type parameter";
ScriptElementKind.primitiveType = "primitive type";
ScriptElementKind.label = "label";
ScriptElementKind.alias = "alias";
ScriptElementKind.constElement = "const";
ScriptElementKind.letElement = "let";
ScriptElementKind.directory = "directory";
ScriptElementKind.externalModuleName = "external module name";
})(ScriptElementKind = ts.ScriptElementKind || (ts.ScriptElementKind = {}));
var ScriptElementKindModifier;
(function (ScriptElementKindModifier) {
ScriptElementKindModifier.none = "";
ScriptElementKindModifier.publicMemberModifier = "public";
ScriptElementKindModifier.privateMemberModifier = "private";
ScriptElementKindModifier.protectedMemberModifier = "protected";
ScriptElementKindModifier.exportedModifier = "export";
ScriptElementKindModifier.ambientModifier = "declare";
ScriptElementKindModifier.staticModifier = "static";
ScriptElementKindModifier.abstractModifier = "abstract";
})(ScriptElementKindModifier = ts.ScriptElementKindModifier || (ts.ScriptElementKindModifier = {}));
var ClassificationTypeNames = (function () {
function ClassificationTypeNames() {
}
return ClassificationTypeNames;
}());
ClassificationTypeNames.comment = "comment";
ClassificationTypeNames.identifier = "identifier";
ClassificationTypeNames.keyword = "keyword";
ClassificationTypeNames.numericLiteral = "number";
ClassificationTypeNames.operator = "operator";
ClassificationTypeNames.stringLiteral = "string";
ClassificationTypeNames.whiteSpace = "whitespace";
ClassificationTypeNames.text = "text";
ClassificationTypeNames.punctuation = "punctuation";
ClassificationTypeNames.className = "class name";
ClassificationTypeNames.enumName = "enum name";
ClassificationTypeNames.interfaceName = "interface name";
ClassificationTypeNames.moduleName = "module name";
ClassificationTypeNames.typeParameterName = "type parameter name";
ClassificationTypeNames.typeAliasName = "type alias name";
ClassificationTypeNames.parameterName = "parameter name";
ClassificationTypeNames.docCommentTagName = "doc comment tag name";
ClassificationTypeNames.jsxOpenTagName = "jsx open tag name";
ClassificationTypeNames.jsxCloseTagName = "jsx close tag name";
ClassificationTypeNames.jsxSelfClosingTagName = "jsx self closing tag name";
ClassificationTypeNames.jsxAttribute = "jsx attribute";
ClassificationTypeNames.jsxText = "jsx text";
ClassificationTypeNames.jsxAttributeStringLiteralValue = "jsx attribute string literal value";
ts.ClassificationTypeNames = ClassificationTypeNames;
var ClassificationType;
(function (ClassificationType) {
ClassificationType[ClassificationType["comment"] = 1] = "comment";
ClassificationType[ClassificationType["identifier"] = 2] = "identifier";
ClassificationType[ClassificationType["keyword"] = 3] = "keyword";
ClassificationType[ClassificationType["numericLiteral"] = 4] = "numericLiteral";
ClassificationType[ClassificationType["operator"] = 5] = "operator";
ClassificationType[ClassificationType["stringLiteral"] = 6] = "stringLiteral";
ClassificationType[ClassificationType["regularExpressionLiteral"] = 7] = "regularExpressionLiteral";
ClassificationType[ClassificationType["whiteSpace"] = 8] = "whiteSpace";
ClassificationType[ClassificationType["text"] = 9] = "text";
ClassificationType[ClassificationType["punctuation"] = 10] = "punctuation";
ClassificationType[ClassificationType["className"] = 11] = "className";
ClassificationType[ClassificationType["enumName"] = 12] = "enumName";
ClassificationType[ClassificationType["interfaceName"] = 13] = "interfaceName";
ClassificationType[ClassificationType["moduleName"] = 14] = "moduleName";
ClassificationType[ClassificationType["typeParameterName"] = 15] = "typeParameterName";
ClassificationType[ClassificationType["typeAliasName"] = 16] = "typeAliasName";
ClassificationType[ClassificationType["parameterName"] = 17] = "parameterName";
ClassificationType[ClassificationType["docCommentTagName"] = 18] = "docCommentTagName";
ClassificationType[ClassificationType["jsxOpenTagName"] = 19] = "jsxOpenTagName";
ClassificationType[ClassificationType["jsxCloseTagName"] = 20] = "jsxCloseTagName";
ClassificationType[ClassificationType["jsxSelfClosingTagName"] = 21] = "jsxSelfClosingTagName";
ClassificationType[ClassificationType["jsxAttribute"] = 22] = "jsxAttribute";
ClassificationType[ClassificationType["jsxText"] = 23] = "jsxText";
ClassificationType[ClassificationType["jsxAttributeStringLiteralValue"] = 24] = "jsxAttributeStringLiteralValue";
})(ClassificationType = ts.ClassificationType || (ts.ClassificationType = {}));
})(ts || (ts = {}));
// These utilities are common to multiple language service features.
/* @internal */
var ts;
(function (ts) {
ts.scanner = ts.createScanner(5 /* Latest */, /*skipTrivia*/ true);
ts.emptyArray = [];
var SemanticMeaning;
(function (SemanticMeaning) {
SemanticMeaning[SemanticMeaning["None"] = 0] = "None";
SemanticMeaning[SemanticMeaning["Value"] = 1] = "Value";
SemanticMeaning[SemanticMeaning["Type"] = 2] = "Type";
SemanticMeaning[SemanticMeaning["Namespace"] = 4] = "Namespace";
SemanticMeaning[SemanticMeaning["All"] = 7] = "All";
})(SemanticMeaning = ts.SemanticMeaning || (ts.SemanticMeaning = {}));
function getMeaningFromDeclaration(node) {
switch (node.kind) {
case 144 /* Parameter */:
case 223 /* VariableDeclaration */:
case 174 /* BindingElement */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 257 /* PropertyAssignment */:
case 258 /* ShorthandPropertyAssignment */:
case 260 /* EnumMember */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 256 /* CatchClause */:
return 1 /* Value */;
case 143 /* TypeParameter */:
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 161 /* TypeLiteral */:
return 2 /* Type */;
case 226 /* ClassDeclaration */:
case 229 /* EnumDeclaration */:
return 1 /* Value */ | 2 /* Type */;
case 230 /* ModuleDeclaration */:
if (ts.isAmbientModule(node)) {
return 4 /* Namespace */ | 1 /* Value */;
}
else if (ts.getModuleInstanceState(node) === 1 /* Instantiated */) {
return 4 /* Namespace */ | 1 /* Value */;
}
else {
return 4 /* Namespace */;
}
case 238 /* NamedImports */:
case 239 /* ImportSpecifier */:
case 234 /* ImportEqualsDeclaration */:
case 235 /* ImportDeclaration */:
case 240 /* ExportAssignment */:
case 241 /* ExportDeclaration */:
return 1 /* Value */ | 2 /* Type */ | 4 /* Namespace */;
// An external module can be a Value
case 261 /* SourceFile */:
return 4 /* Namespace */ | 1 /* Value */;
}
return 1 /* Value */ | 2 /* Type */ | 4 /* Namespace */;
}
ts.getMeaningFromDeclaration = getMeaningFromDeclaration;
function getMeaningFromLocation(node) {
if (node.parent.kind === 240 /* ExportAssignment */) {
return 1 /* Value */ | 2 /* Type */ | 4 /* Namespace */;
}
else if (isInRightSideOfImport(node)) {
return getMeaningFromRightHandSideOfImportEquals(node);
}
else if (ts.isDeclarationName(node)) {
return getMeaningFromDeclaration(node.parent);
}
else if (isTypeReference(node)) {
return 2 /* Type */;
}
else if (isNamespaceReference(node)) {
return 4 /* Namespace */;
}
else {
return 1 /* Value */;
}
}
ts.getMeaningFromLocation = getMeaningFromLocation;
function getMeaningFromRightHandSideOfImportEquals(node) {
ts.Debug.assert(node.kind === 70 /* Identifier */);
// import a = |b|; // Namespace
// import a = |b.c|; // Value, type, namespace
// import a = |b.c|.d; // Namespace
if (node.parent.kind === 141 /* QualifiedName */ &&
node.parent.right === node &&
node.parent.parent.kind === 234 /* ImportEqualsDeclaration */) {
return 1 /* Value */ | 2 /* Type */ | 4 /* Namespace */;
}
return 4 /* Namespace */;
}
function isInRightSideOfImport(node) {
while (node.parent.kind === 141 /* QualifiedName */) {
node = node.parent;
}
return ts.isInternalModuleImportEqualsDeclaration(node.parent) && node.parent.moduleReference === node;
}
function isNamespaceReference(node) {
return isQualifiedNameNamespaceReference(node) || isPropertyAccessNamespaceReference(node);
}
function isQualifiedNameNamespaceReference(node) {
var root = node;
var isLastClause = true;
if (root.parent.kind === 141 /* QualifiedName */) {
while (root.parent && root.parent.kind === 141 /* QualifiedName */) {
root = root.parent;
}
isLastClause = root.right === node;
}
return root.parent.kind === 157 /* TypeReference */ && !isLastClause;
}
function isPropertyAccessNamespaceReference(node) {
var root = node;
var isLastClause = true;
if (root.parent.kind === 177 /* PropertyAccessExpression */) {
while (root.parent && root.parent.kind === 177 /* PropertyAccessExpression */) {
root = root.parent;
}
isLastClause = root.name === node;
}
if (!isLastClause && root.parent.kind === 199 /* ExpressionWithTypeArguments */ && root.parent.parent.kind === 255 /* HeritageClause */) {
var decl = root.parent.parent.parent;
return (decl.kind === 226 /* ClassDeclaration */ && root.parent.parent.token === 107 /* ImplementsKeyword */) ||
(decl.kind === 227 /* InterfaceDeclaration */ && root.parent.parent.token === 84 /* ExtendsKeyword */);
}
return false;
}
function isTypeReference(node) {
if (ts.isRightSideOfQualifiedNameOrPropertyAccess(node)) {
node = node.parent;
}
return node.parent.kind === 157 /* TypeReference */ ||
(node.parent.kind === 199 /* ExpressionWithTypeArguments */ && !ts.isExpressionWithTypeArgumentsInClassExtendsClause(node.parent)) ||
(node.kind === 98 /* ThisKeyword */ && !ts.isPartOfExpression(node)) ||
node.kind === 167 /* ThisType */;
}
function isCallExpressionTarget(node) {
return isCallOrNewExpressionTarget(node, 179 /* CallExpression */);
}
ts.isCallExpressionTarget = isCallExpressionTarget;
function isNewExpressionTarget(node) {
return isCallOrNewExpressionTarget(node, 180 /* NewExpression */);
}
ts.isNewExpressionTarget = isNewExpressionTarget;
function isCallOrNewExpressionTarget(node, kind) {
var target = climbPastPropertyAccess(node);
return target && target.parent && target.parent.kind === kind && target.parent.expression === target;
}
function climbPastPropertyAccess(node) {
return isRightSideOfPropertyAccess(node) ? node.parent : node;
}
ts.climbPastPropertyAccess = climbPastPropertyAccess;
function getTargetLabel(referenceNode, labelName) {
while (referenceNode) {
if (referenceNode.kind === 219 /* LabeledStatement */ && referenceNode.label.text === labelName) {
return referenceNode.label;
}
referenceNode = referenceNode.parent;
}
return undefined;
}
ts.getTargetLabel = getTargetLabel;
function isJumpStatementTarget(node) {
return node.kind === 70 /* Identifier */ &&
(node.parent.kind === 215 /* BreakStatement */ || node.parent.kind === 214 /* ContinueStatement */) &&
node.parent.label === node;
}
ts.isJumpStatementTarget = isJumpStatementTarget;
function isLabelOfLabeledStatement(node) {
return node.kind === 70 /* Identifier */ &&
node.parent.kind === 219 /* LabeledStatement */ &&
node.parent.label === node;
}
function isLabelName(node) {
return isLabelOfLabeledStatement(node) || isJumpStatementTarget(node);
}
ts.isLabelName = isLabelName;
function isRightSideOfQualifiedName(node) {
return node.parent.kind === 141 /* QualifiedName */ && node.parent.right === node;
}
ts.isRightSideOfQualifiedName = isRightSideOfQualifiedName;
function isRightSideOfPropertyAccess(node) {
return node && node.parent && node.parent.kind === 177 /* PropertyAccessExpression */ && node.parent.name === node;
}
ts.isRightSideOfPropertyAccess = isRightSideOfPropertyAccess;
function isNameOfModuleDeclaration(node) {
return node.parent.kind === 230 /* ModuleDeclaration */ && node.parent.name === node;
}
ts.isNameOfModuleDeclaration = isNameOfModuleDeclaration;
function isNameOfFunctionDeclaration(node) {
return node.kind === 70 /* Identifier */ &&
ts.isFunctionLike(node.parent) && node.parent.name === node;
}
ts.isNameOfFunctionDeclaration = isNameOfFunctionDeclaration;
function isLiteralNameOfPropertyDeclarationOrIndexAccess(node) {
if (node.kind === 9 /* StringLiteral */ || node.kind === 8 /* NumericLiteral */) {
switch (node.parent.kind) {
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 257 /* PropertyAssignment */:
case 260 /* EnumMember */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 230 /* ModuleDeclaration */:
return node.parent.name === node;
case 178 /* ElementAccessExpression */:
return node.parent.argumentExpression === node;
case 142 /* ComputedPropertyName */:
return true;
}
}
return false;
}
ts.isLiteralNameOfPropertyDeclarationOrIndexAccess = isLiteralNameOfPropertyDeclarationOrIndexAccess;
function isExpressionOfExternalModuleImportEqualsDeclaration(node) {
return ts.isExternalModuleImportEqualsDeclaration(node.parent.parent) &&
ts.getExternalModuleImportEqualsDeclarationExpression(node.parent.parent) === node;
}
ts.isExpressionOfExternalModuleImportEqualsDeclaration = isExpressionOfExternalModuleImportEqualsDeclaration;
/** Returns true if the position is within a comment */
function isInsideComment(sourceFile, token, position) {
// The position has to be: 1. in the leading trivia (before token.getStart()), and 2. within a comment
return position <= token.getStart(sourceFile) &&
(isInsideCommentRange(ts.getTrailingCommentRanges(sourceFile.text, token.getFullStart())) ||
isInsideCommentRange(ts.getLeadingCommentRanges(sourceFile.text, token.getFullStart())));
function isInsideCommentRange(comments) {
return ts.forEach(comments, function (comment) {
// either we are 1. completely inside the comment, or 2. at the end of the comment
if (comment.pos < position && position < comment.end) {
return true;
}
else if (position === comment.end) {
var text = sourceFile.text;
var width = comment.end - comment.pos;
// is single line comment or just /*
if (width <= 2 || text.charCodeAt(comment.pos + 1) === 47 /* slash */) {
return true;
}
else {
// is unterminated multi-line comment
return !(text.charCodeAt(comment.end - 1) === 47 /* slash */ &&
text.charCodeAt(comment.end - 2) === 42 /* asterisk */);
}
}
return false;
});
}
}
ts.isInsideComment = isInsideComment;
function getContainerNode(node) {
while (true) {
node = node.parent;
if (!node) {
return undefined;
}
switch (node.kind) {
case 261 /* SourceFile */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 229 /* EnumDeclaration */:
case 230 /* ModuleDeclaration */:
return node;
}
}
}
ts.getContainerNode = getContainerNode;
function getNodeKind(node) {
switch (node.kind) {
case 261 /* SourceFile */:
return ts.isExternalModule(node) ? ts.ScriptElementKind.moduleElement : ts.ScriptElementKind.scriptElement;
case 230 /* ModuleDeclaration */:
return ts.ScriptElementKind.moduleElement;
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
return ts.ScriptElementKind.classElement;
case 227 /* InterfaceDeclaration */: return ts.ScriptElementKind.interfaceElement;
case 228 /* TypeAliasDeclaration */: return ts.ScriptElementKind.typeElement;
case 229 /* EnumDeclaration */: return ts.ScriptElementKind.enumElement;
case 223 /* VariableDeclaration */:
return getKindOfVariableDeclaration(node);
case 174 /* BindingElement */:
return getKindOfVariableDeclaration(ts.getRootDeclaration(node));
case 185 /* ArrowFunction */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
return ts.ScriptElementKind.functionElement;
case 151 /* GetAccessor */: return ts.ScriptElementKind.memberGetAccessorElement;
case 152 /* SetAccessor */: return ts.ScriptElementKind.memberSetAccessorElement;
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
return ts.ScriptElementKind.memberFunctionElement;
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
return ts.ScriptElementKind.memberVariableElement;
case 155 /* IndexSignature */: return ts.ScriptElementKind.indexSignatureElement;
case 154 /* ConstructSignature */: return ts.ScriptElementKind.constructSignatureElement;
case 153 /* CallSignature */: return ts.ScriptElementKind.callSignatureElement;
case 150 /* Constructor */: return ts.ScriptElementKind.constructorImplementationElement;
case 143 /* TypeParameter */: return ts.ScriptElementKind.typeParameterElement;
case 260 /* EnumMember */: return ts.ScriptElementKind.enumMemberElement;
case 144 /* Parameter */: return ts.hasModifier(node, 92 /* ParameterPropertyModifier */) ? ts.ScriptElementKind.memberVariableElement : ts.ScriptElementKind.parameterElement;
case 234 /* ImportEqualsDeclaration */:
case 239 /* ImportSpecifier */:
case 236 /* ImportClause */:
case 243 /* ExportSpecifier */:
case 237 /* NamespaceImport */:
return ts.ScriptElementKind.alias;
case 284 /* JSDocTypedefTag */:
return ts.ScriptElementKind.typeElement;
default:
return ts.ScriptElementKind.unknown;
}
function getKindOfVariableDeclaration(v) {
return ts.isConst(v)
? ts.ScriptElementKind.constElement
: ts.isLet(v)
? ts.ScriptElementKind.letElement
: ts.ScriptElementKind.variableElement;
}
}
ts.getNodeKind = getNodeKind;
function getStringLiteralTypeForNode(node, typeChecker) {
var searchNode = node.parent.kind === 171 /* LiteralType */ ? node.parent : node;
var type = typeChecker.getTypeAtLocation(searchNode);
if (type && type.flags & 32 /* StringLiteral */) {
return type;
}
return undefined;
}
ts.getStringLiteralTypeForNode = getStringLiteralTypeForNode;
function isThis(node) {
switch (node.kind) {
case 98 /* ThisKeyword */:
// case SyntaxKind.ThisType: TODO: GH#9267
return true;
case 70 /* Identifier */:
// 'this' as a parameter
return ts.identifierIsThisKeyword(node) && node.parent.kind === 144 /* Parameter */;
default:
return false;
}
}
ts.isThis = isThis;
// Matches the beginning of a triple slash directive
var tripleSlashDirectivePrefixRegex = /^\/\/\/\s*</;
function getLineStartPositionForPosition(position, sourceFile) {
var lineStarts = sourceFile.getLineStarts();
var line = sourceFile.getLineAndCharacterOfPosition(position).line;
return lineStarts[line];
}
ts.getLineStartPositionForPosition = getLineStartPositionForPosition;
function rangeContainsRange(r1, r2) {
return startEndContainsRange(r1.pos, r1.end, r2);
}
ts.rangeContainsRange = rangeContainsRange;
function startEndContainsRange(start, end, range) {
return start <= range.pos && end >= range.end;
}
ts.startEndContainsRange = startEndContainsRange;
function rangeContainsStartEnd(range, start, end) {
return range.pos <= start && range.end >= end;
}
ts.rangeContainsStartEnd = rangeContainsStartEnd;
function rangeOverlapsWithStartEnd(r1, start, end) {
return startEndOverlapsWithStartEnd(r1.pos, r1.end, start, end);
}
ts.rangeOverlapsWithStartEnd = rangeOverlapsWithStartEnd;
function startEndOverlapsWithStartEnd(start1, end1, start2, end2) {
var start = Math.max(start1, start2);
var end = Math.min(end1, end2);
return start < end;
}
ts.startEndOverlapsWithStartEnd = startEndOverlapsWithStartEnd;
function positionBelongsToNode(candidate, position, sourceFile) {
return candidate.end > position || !isCompletedNode(candidate, sourceFile);
}
ts.positionBelongsToNode = positionBelongsToNode;
function isCompletedNode(n, sourceFile) {
if (ts.nodeIsMissing(n)) {
return false;
}
switch (n.kind) {
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 229 /* EnumDeclaration */:
case 176 /* ObjectLiteralExpression */:
case 172 /* ObjectBindingPattern */:
case 161 /* TypeLiteral */:
case 204 /* Block */:
case 231 /* ModuleBlock */:
case 232 /* CaseBlock */:
case 238 /* NamedImports */:
case 242 /* NamedExports */:
return nodeEndsWith(n, 17 /* CloseBraceToken */, sourceFile);
case 256 /* CatchClause */:
return isCompletedNode(n.block, sourceFile);
case 180 /* NewExpression */:
if (!n.arguments) {
return true;
}
// fall through
case 179 /* CallExpression */:
case 183 /* ParenthesizedExpression */:
case 166 /* ParenthesizedType */:
return nodeEndsWith(n, 19 /* CloseParenToken */, sourceFile);
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
return isCompletedNode(n.type, sourceFile);
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 154 /* ConstructSignature */:
case 153 /* CallSignature */:
case 185 /* ArrowFunction */:
if (n.body) {
return isCompletedNode(n.body, sourceFile);
}
if (n.type) {
return isCompletedNode(n.type, sourceFile);
}
// Even though type parameters can be unclosed, we can get away with
// having at least a closing paren.
return hasChildOfKind(n, 19 /* CloseParenToken */, sourceFile);
case 230 /* ModuleDeclaration */:
return n.body && isCompletedNode(n.body, sourceFile);
case 208 /* IfStatement */:
if (n.elseStatement) {
return isCompletedNode(n.elseStatement, sourceFile);
}
return isCompletedNode(n.thenStatement, sourceFile);
case 207 /* ExpressionStatement */:
return isCompletedNode(n.expression, sourceFile) ||
hasChildOfKind(n, 24 /* SemicolonToken */);
case 175 /* ArrayLiteralExpression */:
case 173 /* ArrayBindingPattern */:
case 178 /* ElementAccessExpression */:
case 142 /* ComputedPropertyName */:
case 163 /* TupleType */:
return nodeEndsWith(n, 21 /* CloseBracketToken */, sourceFile);
case 155 /* IndexSignature */:
if (n.type) {
return isCompletedNode(n.type, sourceFile);
}
return hasChildOfKind(n, 21 /* CloseBracketToken */, sourceFile);
case 253 /* CaseClause */:
case 254 /* DefaultClause */:
// there is no such thing as terminator token for CaseClause/DefaultClause so for simplicity always consider them non-completed
return false;
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 210 /* WhileStatement */:
return isCompletedNode(n.statement, sourceFile);
case 209 /* DoStatement */:
// rough approximation: if DoStatement has While keyword - then if node is completed is checking the presence of ')';
var hasWhileKeyword = findChildOfKind(n, 105 /* WhileKeyword */, sourceFile);
if (hasWhileKeyword) {
return nodeEndsWith(n, 19 /* CloseParenToken */, sourceFile);
}
return isCompletedNode(n.statement, sourceFile);
case 160 /* TypeQuery */:
return isCompletedNode(n.exprName, sourceFile);
case 187 /* TypeOfExpression */:
case 186 /* DeleteExpression */:
case 188 /* VoidExpression */:
case 195 /* YieldExpression */:
case 196 /* SpreadElement */:
var unaryWordExpression = n;
return isCompletedNode(unaryWordExpression.expression, sourceFile);
case 181 /* TaggedTemplateExpression */:
return isCompletedNode(n.template, sourceFile);
case 194 /* TemplateExpression */:
var lastSpan = ts.lastOrUndefined(n.templateSpans);
return isCompletedNode(lastSpan, sourceFile);
case 202 /* TemplateSpan */:
return ts.nodeIsPresent(n.literal);
case 241 /* ExportDeclaration */:
case 235 /* ImportDeclaration */:
return ts.nodeIsPresent(n.moduleSpecifier);
case 190 /* PrefixUnaryExpression */:
return isCompletedNode(n.operand, sourceFile);
case 192 /* BinaryExpression */:
return isCompletedNode(n.right, sourceFile);
case 193 /* ConditionalExpression */:
return isCompletedNode(n.whenFalse, sourceFile);
default:
return true;
}
}
ts.isCompletedNode = isCompletedNode;
/*
* Checks if node ends with 'expectedLastToken'.
* If child at position 'length - 1' is 'SemicolonToken' it is skipped and 'expectedLastToken' is compared with child at position 'length - 2'.
*/
function nodeEndsWith(n, expectedLastToken, sourceFile) {
var children = n.getChildren(sourceFile);
if (children.length) {
var last = ts.lastOrUndefined(children);
if (last.kind === expectedLastToken) {
return true;
}
else if (last.kind === 24 /* SemicolonToken */ && children.length !== 1) {
return children[children.length - 2].kind === expectedLastToken;
}
}
return false;
}
function findListItemInfo(node) {
var list = findContainingList(node);
// It is possible at this point for syntaxList to be undefined, either if
// node.parent had no list child, or if none of its list children contained
// the span of node. If this happens, return undefined. The caller should
// handle this case.
if (!list) {
return undefined;
}
var children = list.getChildren();
var listItemIndex = ts.indexOf(children, node);
return {
listItemIndex: listItemIndex,
list: list
};
}
ts.findListItemInfo = findListItemInfo;
function hasChildOfKind(n, kind, sourceFile) {
return !!findChildOfKind(n, kind, sourceFile);
}
ts.hasChildOfKind = hasChildOfKind;
function findChildOfKind(n, kind, sourceFile) {
return ts.forEach(n.getChildren(sourceFile), function (c) { return c.kind === kind && c; });
}
ts.findChildOfKind = findChildOfKind;
function findContainingList(node) {
// The node might be a list element (nonsynthetic) or a comma (synthetic). Either way, it will
// be parented by the container of the SyntaxList, not the SyntaxList itself.
// In order to find the list item index, we first need to locate SyntaxList itself and then search
// for the position of the relevant node (or comma).
var syntaxList = ts.forEach(node.parent.getChildren(), function (c) {
// find syntax list that covers the span of the node
if (c.kind === 291 /* SyntaxList */ && c.pos <= node.pos && c.end >= node.end) {
return c;
}
});
// Either we didn't find an appropriate list, or the list must contain us.
ts.Debug.assert(!syntaxList || ts.contains(syntaxList.getChildren(), node));
return syntaxList;
}
ts.findContainingList = findContainingList;
/* Gets the token whose text has range [start, end) and
* position >= start and (position < end or (position === end && token is keyword or identifier))
*/
function getTouchingWord(sourceFile, position, includeJsDocComment) {
if (includeJsDocComment === void 0) { includeJsDocComment = false; }
return getTouchingToken(sourceFile, position, function (n) { return isWord(n.kind); }, includeJsDocComment);
}
ts.getTouchingWord = getTouchingWord;
/* Gets the token whose text has range [start, end) and position >= start
* and (position < end or (position === end && token is keyword or identifier or numeric/string literal))
*/
function getTouchingPropertyName(sourceFile, position, includeJsDocComment) {
if (includeJsDocComment === void 0) { includeJsDocComment = false; }
return getTouchingToken(sourceFile, position, function (n) { return isPropertyName(n.kind); }, includeJsDocComment);
}
ts.getTouchingPropertyName = getTouchingPropertyName;
/** Returns the token if position is in [start, end) or if position === end and includeItemAtEndPosition(token) === true */
function getTouchingToken(sourceFile, position, includeItemAtEndPosition, includeJsDocComment) {
if (includeJsDocComment === void 0) { includeJsDocComment = false; }
return getTokenAtPositionWorker(sourceFile, position, /*allowPositionInLeadingTrivia*/ false, includeItemAtEndPosition, includeJsDocComment);
}
ts.getTouchingToken = getTouchingToken;
/** Returns a token if position is in [start-of-leading-trivia, end) */
function getTokenAtPosition(sourceFile, position, includeJsDocComment) {
if (includeJsDocComment === void 0) { includeJsDocComment = false; }
return getTokenAtPositionWorker(sourceFile, position, /*allowPositionInLeadingTrivia*/ true, /*includeItemAtEndPosition*/ undefined, includeJsDocComment);
}
ts.getTokenAtPosition = getTokenAtPosition;
/** Get the token whose text contains the position */
function getTokenAtPositionWorker(sourceFile, position, allowPositionInLeadingTrivia, includeItemAtEndPosition, includeJsDocComment) {
if (includeJsDocComment === void 0) { includeJsDocComment = false; }
var current = sourceFile;
outer: while (true) {
if (isToken(current)) {
// exit early
return current;
}
if (includeJsDocComment) {
var jsDocChildren = ts.filter(current.getChildren(), ts.isJSDocNode);
for (var _i = 0, jsDocChildren_1 = jsDocChildren; _i < jsDocChildren_1.length; _i++) {
var jsDocChild = jsDocChildren_1[_i];
var start = allowPositionInLeadingTrivia ? jsDocChild.getFullStart() : jsDocChild.getStart(sourceFile, includeJsDocComment);
if (start <= position) {
var end = jsDocChild.getEnd();
if (position < end || (position === end && jsDocChild.kind === 1 /* EndOfFileToken */)) {
current = jsDocChild;
continue outer;
}
else if (includeItemAtEndPosition && end === position) {
var previousToken = findPrecedingToken(position, sourceFile, jsDocChild);
if (previousToken && includeItemAtEndPosition(previousToken)) {
return previousToken;
}
}
}
}
}
// find the child that contains 'position'
for (var i = 0, n = current.getChildCount(sourceFile); i < n; i++) {
var child = current.getChildAt(i);
// all jsDocComment nodes were already visited
if (ts.isJSDocNode(child)) {
continue;
}
var start = allowPositionInLeadingTrivia ? child.getFullStart() : child.getStart(sourceFile, includeJsDocComment);
if (start <= position) {
var end = child.getEnd();
if (position < end || (position === end && child.kind === 1 /* EndOfFileToken */)) {
current = child;
continue outer;
}
else if (includeItemAtEndPosition && end === position) {
var previousToken = findPrecedingToken(position, sourceFile, child);
if (previousToken && includeItemAtEndPosition(previousToken)) {
return previousToken;
}
}
}
}
return current;
}
}
/**
* The token on the left of the position is the token that strictly includes the position
* or sits to the left of the cursor if it is on a boundary. For example
*
* fo|o -> will return foo
* foo <comment> |bar -> will return foo
*
*/
function findTokenOnLeftOfPosition(file, position) {
// Ideally, getTokenAtPosition should return a token. However, it is currently
// broken, so we do a check to make sure the result was indeed a token.
var tokenAtPosition = getTokenAtPosition(file, position);
if (isToken(tokenAtPosition) && position > tokenAtPosition.getStart(file) && position < tokenAtPosition.getEnd()) {
return tokenAtPosition;
}
return findPrecedingToken(position, file);
}
ts.findTokenOnLeftOfPosition = findTokenOnLeftOfPosition;
function findNextToken(previousToken, parent) {
return find(parent);
function find(n) {
if (isToken(n) && n.pos === previousToken.end) {
// this is token that starts at the end of previous token - return it
return n;
}
var children = n.getChildren();
for (var _i = 0, children_2 = children; _i < children_2.length; _i++) {
var child = children_2[_i];
var shouldDiveInChildNode =
// previous token is enclosed somewhere in the child
(child.pos <= previousToken.pos && child.end > previousToken.end) ||
// previous token ends exactly at the beginning of child
(child.pos === previousToken.end);
if (shouldDiveInChildNode && nodeHasTokens(child)) {
return find(child);
}
}
return undefined;
}
}
ts.findNextToken = findNextToken;
function findPrecedingToken(position, sourceFile, startNode) {
return find(startNode || sourceFile);
function findRightmostToken(n) {
if (isToken(n)) {
return n;
}
var children = n.getChildren();
var candidate = findRightmostChildNodeWithTokens(children, /*exclusiveStartPosition*/ children.length);
return candidate && findRightmostToken(candidate);
}
function find(n) {
if (isToken(n)) {
return n;
}
var children = n.getChildren();
for (var i = 0, len = children.length; i < len; i++) {
var child = children[i];
// condition 'position < child.end' checks if child node end after the position
// in the example below this condition will be false for 'aaaa' and 'bbbb' and true for 'ccc'
// aaaa___bbbb___$__ccc
// after we found child node with end after the position we check if start of the node is after the position.
// if yes - then position is in the trivia and we need to look into the previous child to find the token in question.
// if no - position is in the node itself so we should recurse in it.
// NOTE: JsxText is a weird kind of node that can contain only whitespaces (since they are not counted as trivia).
// if this is the case - then we should assume that token in question is located in previous child.
if (position < child.end && (nodeHasTokens(child) || child.kind === 10 /* JsxText */)) {
var start = child.getStart(sourceFile);
var lookInPreviousChild = (start >= position) ||
(child.kind === 10 /* JsxText */ && start === child.end); // whitespace only JsxText
if (lookInPreviousChild) {
// actual start of the node is past the position - previous token should be at the end of previous child
var candidate = findRightmostChildNodeWithTokens(children, /*exclusiveStartPosition*/ i);
return candidate && findRightmostToken(candidate);
}
else {
// candidate should be in this node
return find(child);
}
}
}
ts.Debug.assert(startNode !== undefined || n.kind === 261 /* SourceFile */);
// Here we know that none of child token nodes embrace the position,
// the only known case is when position is at the end of the file.
// Try to find the rightmost token in the file without filtering.
// Namely we are skipping the check: 'position < node.end'
if (children.length) {
var candidate = findRightmostChildNodeWithTokens(children, /*exclusiveStartPosition*/ children.length);
return candidate && findRightmostToken(candidate);
}
}
/// finds last node that is considered as candidate for search (isCandidate(node) === true) starting from 'exclusiveStartPosition'
function findRightmostChildNodeWithTokens(children, exclusiveStartPosition) {
for (var i = exclusiveStartPosition - 1; i >= 0; i--) {
if (nodeHasTokens(children[i])) {
return children[i];
}
}
}
}
ts.findPrecedingToken = findPrecedingToken;
function isInString(sourceFile, position) {
var previousToken = findPrecedingToken(position, sourceFile);
if (previousToken && previousToken.kind === 9 /* StringLiteral */) {
var start = previousToken.getStart();
var end = previousToken.getEnd();
// To be "in" one of these literals, the position has to be:
// 1. entirely within the token text.
// 2. at the end position of an unterminated token.
// 3. at the end of a regular expression (due to trailing flags like '/foo/g').
if (start < position && position < end) {
return true;
}
if (position === end) {
return !!previousToken.isUnterminated;
}
}
return false;
}
ts.isInString = isInString;
function isInComment(sourceFile, position) {
return isInCommentHelper(sourceFile, position, /*predicate*/ undefined);
}
ts.isInComment = isInComment;
/**
* returns true if the position is in between the open and close elements of an JSX expression.
*/
function isInsideJsxElementOrAttribute(sourceFile, position) {
var token = getTokenAtPosition(sourceFile, position);
if (!token) {
return false;
}
if (token.kind === 10 /* JsxText */) {
return true;
}
// <div>Hello |</div>
if (token.kind === 26 /* LessThanToken */ && token.parent.kind === 10 /* JsxText */) {
return true;
}
// <div> { | </div> or <div a={| </div>
if (token.kind === 26 /* LessThanToken */ && token.parent.kind === 252 /* JsxExpression */) {
return true;
}
// <div> {
// |
// } < /div>
if (token && token.kind === 17 /* CloseBraceToken */ && token.parent.kind === 252 /* JsxExpression */) {
return true;
}
// <div>|</div>
if (token.kind === 26 /* LessThanToken */ && token.parent.kind === 249 /* JsxClosingElement */) {
return true;
}
return false;
}
ts.isInsideJsxElementOrAttribute = isInsideJsxElementOrAttribute;
function isInTemplateString(sourceFile, position) {
var token = getTokenAtPosition(sourceFile, position);
return ts.isTemplateLiteralKind(token.kind) && position > token.getStart(sourceFile);
}
ts.isInTemplateString = isInTemplateString;
/**
* Returns true if the cursor at position in sourceFile is within a comment that additionally
* satisfies predicate, and false otherwise.
*/
function isInCommentHelper(sourceFile, position, predicate) {
var token = getTokenAtPosition(sourceFile, position);
if (token && position <= token.getStart(sourceFile)) {
var commentRanges = ts.getLeadingCommentRanges(sourceFile.text, token.pos);
// The end marker of a single-line comment does not include the newline character.
// In the following case, we are inside a comment (^ denotes the cursor position):
//
// // asdf ^\n
//
// But for multi-line comments, we don't want to be inside the comment in the following case:
//
// /* asdf */^
//
// Internally, we represent the end of the comment at the newline and closing '/', respectively.
return predicate ?
ts.forEach(commentRanges, function (c) { return c.pos < position &&
(c.kind == 2 /* SingleLineCommentTrivia */ ? position <= c.end : position < c.end) &&
predicate(c); }) :
ts.forEach(commentRanges, function (c) { return c.pos < position &&
(c.kind == 2 /* SingleLineCommentTrivia */ ? position <= c.end : position < c.end); });
}
return false;
}
ts.isInCommentHelper = isInCommentHelper;
function hasDocComment(sourceFile, position) {
var token = getTokenAtPosition(sourceFile, position);
// First, we have to see if this position actually landed in a comment.
var commentRanges = ts.getLeadingCommentRanges(sourceFile.text, token.pos);
return ts.forEach(commentRanges, jsDocPrefix);
function jsDocPrefix(c) {
var text = sourceFile.text;
return text.length >= c.pos + 3 && text[c.pos] === "/" && text[c.pos + 1] === "*" && text[c.pos + 2] === "*";
}
}
ts.hasDocComment = hasDocComment;
/**
* Get the corresponding JSDocTag node if the position is in a jsDoc comment
*/
function getJsDocTagAtPosition(sourceFile, position) {
var node = ts.getTokenAtPosition(sourceFile, position);
if (isToken(node)) {
switch (node.kind) {
case 103 /* VarKeyword */:
case 109 /* LetKeyword */:
case 75 /* ConstKeyword */:
// if the current token is var, let or const, skip the VariableDeclarationList
node = node.parent === undefined ? undefined : node.parent.parent;
break;
default:
node = node.parent;
break;
}
}
if (node) {
if (node.jsDocComments) {
for (var _i = 0, _a = node.jsDocComments; _i < _a.length; _i++) {
var jsDocComment = _a[_i];
if (jsDocComment.tags) {
for (var _b = 0, _c = jsDocComment.tags; _b < _c.length; _b++) {
var tag = _c[_b];
if (tag.pos <= position && position <= tag.end) {
return tag;
}
}
}
}
}
}
return undefined;
}
ts.getJsDocTagAtPosition = getJsDocTagAtPosition;
function nodeHasTokens(n) {
// If we have a token or node that has a non-zero width, it must have tokens.
// Note, that getWidth() does not take trivia into account.
return n.getWidth() !== 0;
}
function getNodeModifiers(node) {
var flags = ts.getCombinedModifierFlags(node);
var result = [];
if (flags & 8 /* Private */)
result.push(ts.ScriptElementKindModifier.privateMemberModifier);
if (flags & 16 /* Protected */)
result.push(ts.ScriptElementKindModifier.protectedMemberModifier);
if (flags & 4 /* Public */)
result.push(ts.ScriptElementKindModifier.publicMemberModifier);
if (flags & 32 /* Static */)
result.push(ts.ScriptElementKindModifier.staticModifier);
if (flags & 128 /* Abstract */)
result.push(ts.ScriptElementKindModifier.abstractModifier);
if (flags & 1 /* Export */)
result.push(ts.ScriptElementKindModifier.exportedModifier);
if (ts.isInAmbientContext(node))
result.push(ts.ScriptElementKindModifier.ambientModifier);
return result.length > 0 ? result.join(",") : ts.ScriptElementKindModifier.none;
}
ts.getNodeModifiers = getNodeModifiers;
function getTypeArgumentOrTypeParameterList(node) {
if (node.kind === 157 /* TypeReference */ || node.kind === 179 /* CallExpression */) {
return node.typeArguments;
}
if (ts.isFunctionLike(node) || node.kind === 226 /* ClassDeclaration */ || node.kind === 227 /* InterfaceDeclaration */) {
return node.typeParameters;
}
return undefined;
}
ts.getTypeArgumentOrTypeParameterList = getTypeArgumentOrTypeParameterList;
function isToken(n) {
return n.kind >= 0 /* FirstToken */ && n.kind <= 140 /* LastToken */;
}
ts.isToken = isToken;
function isWord(kind) {
return kind === 70 /* Identifier */ || ts.isKeyword(kind);
}
ts.isWord = isWord;
function isPropertyName(kind) {
return kind === 9 /* StringLiteral */ || kind === 8 /* NumericLiteral */ || isWord(kind);
}
function isComment(kind) {
return kind === 2 /* SingleLineCommentTrivia */ || kind === 3 /* MultiLineCommentTrivia */;
}
ts.isComment = isComment;
function isStringOrRegularExpressionOrTemplateLiteral(kind) {
if (kind === 9 /* StringLiteral */
|| kind === 11 /* RegularExpressionLiteral */
|| ts.isTemplateLiteralKind(kind)) {
return true;
}
return false;
}
ts.isStringOrRegularExpressionOrTemplateLiteral = isStringOrRegularExpressionOrTemplateLiteral;
function isPunctuation(kind) {
return 16 /* FirstPunctuation */ <= kind && kind <= 69 /* LastPunctuation */;
}
ts.isPunctuation = isPunctuation;
function isInsideTemplateLiteral(node, position) {
return ts.isTemplateLiteralKind(node.kind)
&& (node.getStart() < position && position < node.getEnd()) || (!!node.isUnterminated && position === node.getEnd());
}
ts.isInsideTemplateLiteral = isInsideTemplateLiteral;
function isAccessibilityModifier(kind) {
switch (kind) {
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
return true;
}
return false;
}
ts.isAccessibilityModifier = isAccessibilityModifier;
function compareDataObjects(dst, src) {
for (var e in dst) {
if (typeof dst[e] === "object") {
if (!compareDataObjects(dst[e], src[e])) {
return false;
}
}
else if (typeof dst[e] !== "function") {
if (dst[e] !== src[e]) {
return false;
}
}
}
return true;
}
ts.compareDataObjects = compareDataObjects;
function isArrayLiteralOrObjectLiteralDestructuringPattern(node) {
if (node.kind === 175 /* ArrayLiteralExpression */ ||
node.kind === 176 /* ObjectLiteralExpression */) {
// [a,b,c] from:
// [a, b, c] = someExpression;
if (node.parent.kind === 192 /* BinaryExpression */ &&
node.parent.left === node &&
node.parent.operatorToken.kind === 57 /* EqualsToken */) {
return true;
}
// [a, b, c] from:
// for([a, b, c] of expression)
if (node.parent.kind === 213 /* ForOfStatement */ &&
node.parent.initializer === node) {
return true;
}
// [a, b, c] of
// [x, [a, b, c] ] = someExpression
// or
// {x, a: {a, b, c} } = someExpression
if (isArrayLiteralOrObjectLiteralDestructuringPattern(node.parent.kind === 257 /* PropertyAssignment */ ? node.parent.parent : node.parent)) {
return true;
}
}
return false;
}
ts.isArrayLiteralOrObjectLiteralDestructuringPattern = isArrayLiteralOrObjectLiteralDestructuringPattern;
function hasTrailingDirectorySeparator(path) {
var lastCharacter = path.charAt(path.length - 1);
return lastCharacter === "/" || lastCharacter === "\\";
}
ts.hasTrailingDirectorySeparator = hasTrailingDirectorySeparator;
function isInReferenceComment(sourceFile, position) {
return isInCommentHelper(sourceFile, position, isReferenceComment);
function isReferenceComment(c) {
var commentText = sourceFile.text.substring(c.pos, c.end);
return tripleSlashDirectivePrefixRegex.test(commentText);
}
}
ts.isInReferenceComment = isInReferenceComment;
function isInNonReferenceComment(sourceFile, position) {
return isInCommentHelper(sourceFile, position, isNonReferenceComment);
function isNonReferenceComment(c) {
var commentText = sourceFile.text.substring(c.pos, c.end);
return !tripleSlashDirectivePrefixRegex.test(commentText);
}
}
ts.isInNonReferenceComment = isInNonReferenceComment;
})(ts || (ts = {}));
// Display-part writer helpers
/* @internal */
(function (ts) {
function isFirstDeclarationOfSymbolParameter(symbol) {
return symbol.declarations && symbol.declarations.length > 0 && symbol.declarations[0].kind === 144 /* Parameter */;
}
ts.isFirstDeclarationOfSymbolParameter = isFirstDeclarationOfSymbolParameter;
var displayPartWriter = getDisplayPartWriter();
function getDisplayPartWriter() {
var displayParts;
var lineStart;
var indent;
resetWriter();
return {
displayParts: function () { return displayParts; },
writeKeyword: function (text) { return writeKind(text, ts.SymbolDisplayPartKind.keyword); },
writeOperator: function (text) { return writeKind(text, ts.SymbolDisplayPartKind.operator); },
writePunctuation: function (text) { return writeKind(text, ts.SymbolDisplayPartKind.punctuation); },
writeSpace: function (text) { return writeKind(text, ts.SymbolDisplayPartKind.space); },
writeStringLiteral: function (text) { return writeKind(text, ts.SymbolDisplayPartKind.stringLiteral); },
writeParameter: function (text) { return writeKind(text, ts.SymbolDisplayPartKind.parameterName); },
writeSymbol: writeSymbol,
writeLine: writeLine,
increaseIndent: function () { indent++; },
decreaseIndent: function () { indent--; },
clear: resetWriter,
trackSymbol: ts.noop,
reportInaccessibleThisError: ts.noop
};
function writeIndent() {
if (lineStart) {
var indentString = ts.getIndentString(indent);
if (indentString) {
displayParts.push(displayPart(indentString, ts.SymbolDisplayPartKind.space));
}
lineStart = false;
}
}
function writeKind(text, kind) {
writeIndent();
displayParts.push(displayPart(text, kind));
}
function writeSymbol(text, symbol) {
writeIndent();
displayParts.push(symbolPart(text, symbol));
}
function writeLine() {
displayParts.push(lineBreakPart());
lineStart = true;
}
function resetWriter() {
displayParts = [];
lineStart = true;
indent = 0;
}
}
function symbolPart(text, symbol) {
return displayPart(text, displayPartKind(symbol));
function displayPartKind(symbol) {
var flags = symbol.flags;
if (flags & 3 /* Variable */) {
return isFirstDeclarationOfSymbolParameter(symbol) ? ts.SymbolDisplayPartKind.parameterName : ts.SymbolDisplayPartKind.localName;
}
else if (flags & 4 /* Property */) {
return ts.SymbolDisplayPartKind.propertyName;
}
else if (flags & 32768 /* GetAccessor */) {
return ts.SymbolDisplayPartKind.propertyName;
}
else if (flags & 65536 /* SetAccessor */) {
return ts.SymbolDisplayPartKind.propertyName;
}
else if (flags & 8 /* EnumMember */) {
return ts.SymbolDisplayPartKind.enumMemberName;
}
else if (flags & 16 /* Function */) {
return ts.SymbolDisplayPartKind.functionName;
}
else if (flags & 32 /* Class */) {
return ts.SymbolDisplayPartKind.className;
}
else if (flags & 64 /* Interface */) {
return ts.SymbolDisplayPartKind.interfaceName;
}
else if (flags & 384 /* Enum */) {
return ts.SymbolDisplayPartKind.enumName;
}
else if (flags & 1536 /* Module */) {
return ts.SymbolDisplayPartKind.moduleName;
}
else if (flags & 8192 /* Method */) {
return ts.SymbolDisplayPartKind.methodName;
}
else if (flags & 262144 /* TypeParameter */) {
return ts.SymbolDisplayPartKind.typeParameterName;
}
else if (flags & 524288 /* TypeAlias */) {
return ts.SymbolDisplayPartKind.aliasName;
}
else if (flags & 8388608 /* Alias */) {
return ts.SymbolDisplayPartKind.aliasName;
}
return ts.SymbolDisplayPartKind.text;
}
}
ts.symbolPart = symbolPart;
function displayPart(text, kind) {
return {
text: text,
kind: ts.SymbolDisplayPartKind[kind]
};
}
ts.displayPart = displayPart;
function spacePart() {
return displayPart(" ", ts.SymbolDisplayPartKind.space);
}
ts.spacePart = spacePart;
function keywordPart(kind) {
return displayPart(ts.tokenToString(kind), ts.SymbolDisplayPartKind.keyword);
}
ts.keywordPart = keywordPart;
function punctuationPart(kind) {
return displayPart(ts.tokenToString(kind), ts.SymbolDisplayPartKind.punctuation);
}
ts.punctuationPart = punctuationPart;
function operatorPart(kind) {
return displayPart(ts.tokenToString(kind), ts.SymbolDisplayPartKind.operator);
}
ts.operatorPart = operatorPart;
function textOrKeywordPart(text) {
var kind = ts.stringToToken(text);
return kind === undefined
? textPart(text)
: keywordPart(kind);
}
ts.textOrKeywordPart = textOrKeywordPart;
function textPart(text) {
return displayPart(text, ts.SymbolDisplayPartKind.text);
}
ts.textPart = textPart;
var carriageReturnLineFeed = "\r\n";
/**
* The default is CRLF.
*/
function getNewLineOrDefaultFromHost(host) {
return host.getNewLine ? host.getNewLine() : carriageReturnLineFeed;
}
ts.getNewLineOrDefaultFromHost = getNewLineOrDefaultFromHost;
function lineBreakPart() {
return displayPart("\n", ts.SymbolDisplayPartKind.lineBreak);
}
ts.lineBreakPart = lineBreakPart;
function mapToDisplayParts(writeDisplayParts) {
writeDisplayParts(displayPartWriter);
var result = displayPartWriter.displayParts();
displayPartWriter.clear();
return result;
}
ts.mapToDisplayParts = mapToDisplayParts;
function typeToDisplayParts(typechecker, type, enclosingDeclaration, flags) {
return mapToDisplayParts(function (writer) {
typechecker.getSymbolDisplayBuilder().buildTypeDisplay(type, writer, enclosingDeclaration, flags);
});
}
ts.typeToDisplayParts = typeToDisplayParts;
function symbolToDisplayParts(typeChecker, symbol, enclosingDeclaration, meaning, flags) {
return mapToDisplayParts(function (writer) {
typeChecker.getSymbolDisplayBuilder().buildSymbolDisplay(symbol, writer, enclosingDeclaration, meaning, flags);
});
}
ts.symbolToDisplayParts = symbolToDisplayParts;
function signatureToDisplayParts(typechecker, signature, enclosingDeclaration, flags) {
return mapToDisplayParts(function (writer) {
typechecker.getSymbolDisplayBuilder().buildSignatureDisplay(signature, writer, enclosingDeclaration, flags);
});
}
ts.signatureToDisplayParts = signatureToDisplayParts;
function getDeclaredName(typeChecker, symbol, location) {
// If this is an export or import specifier it could have been renamed using the 'as' syntax.
// If so we want to search for whatever is under the cursor.
if (isImportOrExportSpecifierName(location)) {
return location.getText();
}
else if (ts.isStringOrNumericLiteral(location.kind) &&
location.parent.kind === 142 /* ComputedPropertyName */) {
return location.text;
}
// Try to get the local symbol if we're dealing with an 'export default'
// since that symbol has the "true" name.
var localExportDefaultSymbol = ts.getLocalSymbolForExportDefault(symbol);
var name = typeChecker.symbolToString(localExportDefaultSymbol || symbol);
return name;
}
ts.getDeclaredName = getDeclaredName;
function isImportOrExportSpecifierName(location) {
return location.parent &&
(location.parent.kind === 239 /* ImportSpecifier */ || location.parent.kind === 243 /* ExportSpecifier */) &&
location.parent.propertyName === location;
}
ts.isImportOrExportSpecifierName = isImportOrExportSpecifierName;
/**
* Strip off existed single quotes or double quotes from a given string
*
* @return non-quoted string
*/
function stripQuotes(name) {
var length = name.length;
if (length >= 2 &&
name.charCodeAt(0) === name.charCodeAt(length - 1) &&
(name.charCodeAt(0) === 34 /* doubleQuote */ || name.charCodeAt(0) === 39 /* singleQuote */)) {
return name.substring(1, length - 1);
}
;
return name;
}
ts.stripQuotes = stripQuotes;
function scriptKindIs(fileName, host) {
var scriptKinds = [];
for (var _i = 2; _i < arguments.length; _i++) {
scriptKinds[_i - 2] = arguments[_i];
}
var scriptKind = getScriptKind(fileName, host);
return ts.forEach(scriptKinds, function (k) { return k === scriptKind; });
}
ts.scriptKindIs = scriptKindIs;
function getScriptKind(fileName, host) {
// First check to see if the script kind was specified by the host. Chances are the host
// may override the default script kind for the file extension.
var scriptKind;
if (host && host.getScriptKind) {
scriptKind = host.getScriptKind(fileName);
}
if (!scriptKind) {
scriptKind = ts.getScriptKindFromFileName(fileName);
}
return ts.ensureScriptKind(fileName, scriptKind);
}
ts.getScriptKind = getScriptKind;
function sanitizeConfigFile(configFileName, content) {
var options = {
fileName: "config.js",
compilerOptions: {
target: 2 /* ES2015 */,
removeComments: true
},
reportDiagnostics: true
};
var _a = ts.transpileModule("(" + content + ")", options), outputText = _a.outputText, diagnostics = _a.diagnostics;
// Becasue the content was wrapped in "()", the start position of diagnostics needs to be subtract by 1
// also, the emitted result will have "(" in the beginning and ");" in the end. We need to strip these
// as well
var trimmedOutput = outputText.trim();
for (var _i = 0, diagnostics_2 = diagnostics; _i < diagnostics_2.length; _i++) {
var diagnostic = diagnostics_2[_i];
diagnostic.start = diagnostic.start - 1;
}
var _b = ts.parseConfigFileTextToJson(configFileName, trimmedOutput.substring(1, trimmedOutput.length - 2), /*stripComments*/ false), config = _b.config, error = _b.error;
return {
configJsonObject: config || {},
diagnostics: error ? ts.concatenate(diagnostics, [error]) : diagnostics
};
}
ts.sanitizeConfigFile = sanitizeConfigFile;
})(ts || (ts = {}));
var ts;
(function (ts) {
/// Classifier
function createClassifier() {
var scanner = ts.createScanner(5 /* Latest */, /*skipTrivia*/ false);
/// We do not have a full parser support to know when we should parse a regex or not
/// If we consider every slash token to be a regex, we could be missing cases like "1/2/3", where
/// we have a series of divide operator. this list allows us to be more accurate by ruling out
/// locations where a regexp cannot exist.
var noRegexTable = [];
noRegexTable[70 /* Identifier */] = true;
noRegexTable[9 /* StringLiteral */] = true;
noRegexTable[8 /* NumericLiteral */] = true;
noRegexTable[11 /* RegularExpressionLiteral */] = true;
noRegexTable[98 /* ThisKeyword */] = true;
noRegexTable[42 /* PlusPlusToken */] = true;
noRegexTable[43 /* MinusMinusToken */] = true;
noRegexTable[19 /* CloseParenToken */] = true;
noRegexTable[21 /* CloseBracketToken */] = true;
noRegexTable[17 /* CloseBraceToken */] = true;
noRegexTable[100 /* TrueKeyword */] = true;
noRegexTable[85 /* FalseKeyword */] = true;
// Just a stack of TemplateHeads and OpenCurlyBraces, used to perform rudimentary (inexact)
// classification on template strings. Because of the context free nature of templates,
// the only precise way to classify a template portion would be by propagating the stack across
// lines, just as we do with the end-of-line state. However, this is a burden for implementers,
// and the behavior is entirely subsumed by the syntactic classifier anyway, so we instead
// flatten any nesting when the template stack is non-empty and encode it in the end-of-line state.
// Situations in which this fails are
// 1) When template strings are nested across different lines:
// `hello ${ `world
// ` }`
//
// Where on the second line, you will get the closing of a template,
// a closing curly, and a new template.
//
// 2) When substitution expressions have curly braces and the curly brace falls on the next line:
// `hello ${ () => {
// return "world" } } `
//
// Where on the second line, you will get the 'return' keyword,
// a string literal, and a template end consisting of '} } `'.
var templateStack = [];
/** Returns true if 'keyword2' can legally follow 'keyword1' in any language construct. */
function canFollow(keyword1, keyword2) {
if (ts.isAccessibilityModifier(keyword1)) {
if (keyword2 === 124 /* GetKeyword */ ||
keyword2 === 133 /* SetKeyword */ ||
keyword2 === 122 /* ConstructorKeyword */ ||
keyword2 === 114 /* StaticKeyword */) {
// Allow things like "public get", "public constructor" and "public static".
// These are all legal.
return true;
}
// Any other keyword following "public" is actually an identifier an not a real
// keyword.
return false;
}
// Assume any other keyword combination is legal. This can be refined in the future
// if there are more cases we want the classifier to be better at.
return true;
}
function convertClassifications(classifications, text) {
var entries = [];
var dense = classifications.spans;
var lastEnd = 0;
for (var i = 0, n = dense.length; i < n; i += 3) {
var start = dense[i];
var length_4 = dense[i + 1];
var type = dense[i + 2];
// Make a whitespace entry between the last item and this one.
if (lastEnd >= 0) {
var whitespaceLength_1 = start - lastEnd;
if (whitespaceLength_1 > 0) {
entries.push({ length: whitespaceLength_1, classification: ts.TokenClass.Whitespace });
}
}
entries.push({ length: length_4, classification: convertClassification(type) });
lastEnd = start + length_4;
}
var whitespaceLength = text.length - lastEnd;
if (whitespaceLength > 0) {
entries.push({ length: whitespaceLength, classification: ts.TokenClass.Whitespace });
}
return { entries: entries, finalLexState: classifications.endOfLineState };
}
function convertClassification(type) {
switch (type) {
case 1 /* comment */: return ts.TokenClass.Comment;
case 3 /* keyword */: return ts.TokenClass.Keyword;
case 4 /* numericLiteral */: return ts.TokenClass.NumberLiteral;
case 5 /* operator */: return ts.TokenClass.Operator;
case 6 /* stringLiteral */: return ts.TokenClass.StringLiteral;
case 8 /* whiteSpace */: return ts.TokenClass.Whitespace;
case 10 /* punctuation */: return ts.TokenClass.Punctuation;
case 2 /* identifier */:
case 11 /* className */:
case 12 /* enumName */:
case 13 /* interfaceName */:
case 14 /* moduleName */:
case 15 /* typeParameterName */:
case 16 /* typeAliasName */:
case 9 /* text */:
case 17 /* parameterName */:
default:
return ts.TokenClass.Identifier;
}
}
function getClassificationsForLine(text, lexState, syntacticClassifierAbsent) {
return convertClassifications(getEncodedLexicalClassifications(text, lexState, syntacticClassifierAbsent), text);
}
// If there is a syntactic classifier ('syntacticClassifierAbsent' is false),
// we will be more conservative in order to avoid conflicting with the syntactic classifier.
function getEncodedLexicalClassifications(text, lexState, syntacticClassifierAbsent) {
var offset = 0;
var token = 0 /* Unknown */;
var lastNonTriviaToken = 0 /* Unknown */;
// Empty out the template stack for reuse.
while (templateStack.length > 0) {
templateStack.pop();
}
// If we're in a string literal, then prepend: "\
// (and a newline). That way when we lex we'll think we're still in a string literal.
//
// If we're in a multiline comment, then prepend: /*
// (and a newline). That way when we lex we'll think we're still in a multiline comment.
switch (lexState) {
case 3 /* InDoubleQuoteStringLiteral */:
text = "\"\\\n" + text;
offset = 3;
break;
case 2 /* InSingleQuoteStringLiteral */:
text = "'\\\n" + text;
offset = 3;
break;
case 1 /* InMultiLineCommentTrivia */:
text = "/*\n" + text;
offset = 3;
break;
case 4 /* InTemplateHeadOrNoSubstitutionTemplate */:
text = "`\n" + text;
offset = 2;
break;
case 5 /* InTemplateMiddleOrTail */:
text = "}\n" + text;
offset = 2;
// fallthrough
case 6 /* InTemplateSubstitutionPosition */:
templateStack.push(13 /* TemplateHead */);
break;
}
scanner.setText(text);
var result = {
endOfLineState: 0 /* None */,
spans: []
};
// We can run into an unfortunate interaction between the lexical and syntactic classifier
// when the user is typing something generic. Consider the case where the user types:
//
// Foo<number
//
// From the lexical classifier's perspective, 'number' is a keyword, and so the word will
// be classified as such. However, from the syntactic classifier's tree-based perspective
// this is simply an expression with the identifier 'number' on the RHS of the less than
// token. So the classification will go back to being an identifier. The moment the user
// types again, number will become a keyword, then an identifier, etc. etc.
//
// To try to avoid this problem, we avoid classifying contextual keywords as keywords
// when the user is potentially typing something generic. We just can't do a good enough
// job at the lexical level, and so well leave it up to the syntactic classifier to make
// the determination.
//
// In order to determine if the user is potentially typing something generic, we use a
// weak heuristic where we track < and > tokens. It's a weak heuristic, but should
// work well enough in practice.
var angleBracketStack = 0;
do {
token = scanner.scan();
if (!ts.isTrivia(token)) {
if ((token === 40 /* SlashToken */ || token === 62 /* SlashEqualsToken */) && !noRegexTable[lastNonTriviaToken]) {
if (scanner.reScanSlashToken() === 11 /* RegularExpressionLiteral */) {
token = 11 /* RegularExpressionLiteral */;
}
}
else if (lastNonTriviaToken === 22 /* DotToken */ && isKeyword(token)) {
token = 70 /* Identifier */;
}
else if (isKeyword(lastNonTriviaToken) && isKeyword(token) && !canFollow(lastNonTriviaToken, token)) {
// We have two keywords in a row. Only treat the second as a keyword if
// it's a sequence that could legally occur in the language. Otherwise
// treat it as an identifier. This way, if someone writes "private var"
// we recognize that 'var' is actually an identifier here.
token = 70 /* Identifier */;
}
else if (lastNonTriviaToken === 70 /* Identifier */ &&
token === 26 /* LessThanToken */) {
// Could be the start of something generic. Keep track of that by bumping
// up the current count of generic contexts we may be in.
angleBracketStack++;
}
else if (token === 28 /* GreaterThanToken */ && angleBracketStack > 0) {
// If we think we're currently in something generic, then mark that that
// generic entity is complete.
angleBracketStack--;
}
else if (token === 118 /* AnyKeyword */ ||
token === 134 /* StringKeyword */ ||
token === 132 /* NumberKeyword */ ||
token === 121 /* BooleanKeyword */ ||
token === 135 /* SymbolKeyword */) {
if (angleBracketStack > 0 && !syntacticClassifierAbsent) {
// If it looks like we're could be in something generic, don't classify this
// as a keyword. We may just get overwritten by the syntactic classifier,
// causing a noisy experience for the user.
token = 70 /* Identifier */;
}
}
else if (token === 13 /* TemplateHead */) {
templateStack.push(token);
}
else if (token === 16 /* OpenBraceToken */) {
// If we don't have anything on the template stack,
// then we aren't trying to keep track of a previously scanned template head.
if (templateStack.length > 0) {
templateStack.push(token);
}
}
else if (token === 17 /* CloseBraceToken */) {
// If we don't have anything on the template stack,
// then we aren't trying to keep track of a previously scanned template head.
if (templateStack.length > 0) {
var lastTemplateStackToken = ts.lastOrUndefined(templateStack);
if (lastTemplateStackToken === 13 /* TemplateHead */) {
token = scanner.reScanTemplateToken();
// Only pop on a TemplateTail; a TemplateMiddle indicates there is more for us.
if (token === 15 /* TemplateTail */) {
templateStack.pop();
}
else {
ts.Debug.assert(token === 14 /* TemplateMiddle */, "Should have been a template middle. Was " + token);
}
}
else {
ts.Debug.assert(lastTemplateStackToken === 16 /* OpenBraceToken */, "Should have been an open brace. Was: " + token);
templateStack.pop();
}
}
}
lastNonTriviaToken = token;
}
processToken();
} while (token !== 1 /* EndOfFileToken */);
return result;
function processToken() {
var start = scanner.getTokenPos();
var end = scanner.getTextPos();
addResult(start, end, classFromKind(token));
if (end >= text.length) {
if (token === 9 /* StringLiteral */) {
// Check to see if we finished up on a multiline string literal.
var tokenText = scanner.getTokenText();
if (scanner.isUnterminated()) {
var lastCharIndex = tokenText.length - 1;
var numBackslashes = 0;
while (tokenText.charCodeAt(lastCharIndex - numBackslashes) === 92 /* backslash */) {
numBackslashes++;
}
// If we have an odd number of backslashes, then the multiline string is unclosed
if (numBackslashes & 1) {
var quoteChar = tokenText.charCodeAt(0);
result.endOfLineState = quoteChar === 34 /* doubleQuote */
? 3 /* InDoubleQuoteStringLiteral */
: 2 /* InSingleQuoteStringLiteral */;
}
}
}
else if (token === 3 /* MultiLineCommentTrivia */) {
// Check to see if the multiline comment was unclosed.
if (scanner.isUnterminated()) {
result.endOfLineState = 1 /* InMultiLineCommentTrivia */;
}
}
else if (ts.isTemplateLiteralKind(token)) {
if (scanner.isUnterminated()) {
if (token === 15 /* TemplateTail */) {
result.endOfLineState = 5 /* InTemplateMiddleOrTail */;
}
else if (token === 12 /* NoSubstitutionTemplateLiteral */) {
result.endOfLineState = 4 /* InTemplateHeadOrNoSubstitutionTemplate */;
}
else {
ts.Debug.fail("Only 'NoSubstitutionTemplateLiteral's and 'TemplateTail's can be unterminated; got SyntaxKind #" + token);
}
}
}
else if (templateStack.length > 0 && ts.lastOrUndefined(templateStack) === 13 /* TemplateHead */) {
result.endOfLineState = 6 /* InTemplateSubstitutionPosition */;
}
}
}
function addResult(start, end, classification) {
if (classification === 8 /* whiteSpace */) {
// Don't bother with whitespace classifications. They're not needed.
return;
}
if (start === 0 && offset > 0) {
// We're classifying the first token, and this was a case where we prepended
// text. We should consider the start of this token to be at the start of
// the original text.
start += offset;
}
// All our tokens are in relation to the augmented text. Move them back to be
// relative to the original text.
start -= offset;
end -= offset;
var length = end - start;
if (length > 0) {
result.spans.push(start);
result.spans.push(length);
result.spans.push(classification);
}
}
}
function isBinaryExpressionOperatorToken(token) {
switch (token) {
case 38 /* AsteriskToken */:
case 40 /* SlashToken */:
case 41 /* PercentToken */:
case 36 /* PlusToken */:
case 37 /* MinusToken */:
case 44 /* LessThanLessThanToken */:
case 45 /* GreaterThanGreaterThanToken */:
case 46 /* GreaterThanGreaterThanGreaterThanToken */:
case 26 /* LessThanToken */:
case 28 /* GreaterThanToken */:
case 29 /* LessThanEqualsToken */:
case 30 /* GreaterThanEqualsToken */:
case 92 /* InstanceOfKeyword */:
case 91 /* InKeyword */:
case 117 /* AsKeyword */:
case 31 /* EqualsEqualsToken */:
case 32 /* ExclamationEqualsToken */:
case 33 /* EqualsEqualsEqualsToken */:
case 34 /* ExclamationEqualsEqualsToken */:
case 47 /* AmpersandToken */:
case 49 /* CaretToken */:
case 48 /* BarToken */:
case 52 /* AmpersandAmpersandToken */:
case 53 /* BarBarToken */:
case 68 /* BarEqualsToken */:
case 67 /* AmpersandEqualsToken */:
case 69 /* CaretEqualsToken */:
case 64 /* LessThanLessThanEqualsToken */:
case 65 /* GreaterThanGreaterThanEqualsToken */:
case 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */:
case 58 /* PlusEqualsToken */:
case 59 /* MinusEqualsToken */:
case 60 /* AsteriskEqualsToken */:
case 62 /* SlashEqualsToken */:
case 63 /* PercentEqualsToken */:
case 57 /* EqualsToken */:
case 25 /* CommaToken */:
return true;
default:
return false;
}
}
function isPrefixUnaryExpressionOperatorToken(token) {
switch (token) {
case 36 /* PlusToken */:
case 37 /* MinusToken */:
case 51 /* TildeToken */:
case 50 /* ExclamationToken */:
case 42 /* PlusPlusToken */:
case 43 /* MinusMinusToken */:
return true;
default:
return false;
}
}
function isKeyword(token) {
return token >= 71 /* FirstKeyword */ && token <= 140 /* LastKeyword */;
}
function classFromKind(token) {
if (isKeyword(token)) {
return 3 /* keyword */;
}
else if (isBinaryExpressionOperatorToken(token) || isPrefixUnaryExpressionOperatorToken(token)) {
return 5 /* operator */;
}
else if (token >= 16 /* FirstPunctuation */ && token <= 69 /* LastPunctuation */) {
return 10 /* punctuation */;
}
switch (token) {
case 8 /* NumericLiteral */:
return 4 /* numericLiteral */;
case 9 /* StringLiteral */:
return 6 /* stringLiteral */;
case 11 /* RegularExpressionLiteral */:
return 7 /* regularExpressionLiteral */;
case 7 /* ConflictMarkerTrivia */:
case 3 /* MultiLineCommentTrivia */:
case 2 /* SingleLineCommentTrivia */:
return 1 /* comment */;
case 5 /* WhitespaceTrivia */:
case 4 /* NewLineTrivia */:
return 8 /* whiteSpace */;
case 70 /* Identifier */:
default:
if (ts.isTemplateLiteralKind(token)) {
return 6 /* stringLiteral */;
}
return 2 /* identifier */;
}
}
return {
getClassificationsForLine: getClassificationsForLine,
getEncodedLexicalClassifications: getEncodedLexicalClassifications
};
}
ts.createClassifier = createClassifier;
/* @internal */
function getSemanticClassifications(typeChecker, cancellationToken, sourceFile, classifiableNames, span) {
return convertClassifications(getEncodedSemanticClassifications(typeChecker, cancellationToken, sourceFile, classifiableNames, span));
}
ts.getSemanticClassifications = getSemanticClassifications;
function checkForClassificationCancellation(cancellationToken, kind) {
// We don't want to actually call back into our host on every node to find out if we've
// been canceled. That would be an enormous amount of chattyness, along with the all
// the overhead of marshalling the data to/from the host. So instead we pick a few
// reasonable node kinds to bother checking on. These node kinds represent high level
// constructs that we would expect to see commonly, but just at a far less frequent
// interval.
//
// For example, in checker.ts (around 750k) we only have around 600 of these constructs.
// That means we're calling back into the host around every 1.2k of the file we process.
// Lib.d.ts has similar numbers.
switch (kind) {
case 230 /* ModuleDeclaration */:
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 225 /* FunctionDeclaration */:
cancellationToken.throwIfCancellationRequested();
}
}
/* @internal */
function getEncodedSemanticClassifications(typeChecker, cancellationToken, sourceFile, classifiableNames, span) {
var result = [];
processNode(sourceFile);
return { spans: result, endOfLineState: 0 /* None */ };
function pushClassification(start, length, type) {
result.push(start);
result.push(length);
result.push(type);
}
function classifySymbol(symbol, meaningAtPosition) {
var flags = symbol.getFlags();
if ((flags & 788448 /* Classifiable */) === 0 /* None */) {
return;
}
if (flags & 32 /* Class */) {
return 11 /* className */;
}
else if (flags & 384 /* Enum */) {
return 12 /* enumName */;
}
else if (flags & 524288 /* TypeAlias */) {
return 16 /* typeAliasName */;
}
else if (meaningAtPosition & 2 /* Type */) {
if (flags & 64 /* Interface */) {
return 13 /* interfaceName */;
}
else if (flags & 262144 /* TypeParameter */) {
return 15 /* typeParameterName */;
}
}
else if (flags & 1536 /* Module */) {
// Only classify a module as such if
// - It appears in a namespace context.
// - There exists a module declaration which actually impacts the value side.
if (meaningAtPosition & 4 /* Namespace */ ||
(meaningAtPosition & 1 /* Value */ && hasValueSideModule(symbol))) {
return 14 /* moduleName */;
}
}
return undefined;
/**
* Returns true if there exists a module that introduces entities on the value side.
*/
function hasValueSideModule(symbol) {
return ts.forEach(symbol.declarations, function (declaration) {
return declaration.kind === 230 /* ModuleDeclaration */ &&
ts.getModuleInstanceState(declaration) === 1 /* Instantiated */;
});
}
}
function processNode(node) {
// Only walk into nodes that intersect the requested span.
if (node && ts.textSpanIntersectsWith(span, node.getFullStart(), node.getFullWidth())) {
var kind = node.kind;
checkForClassificationCancellation(cancellationToken, kind);
if (kind === 70 /* Identifier */ && !ts.nodeIsMissing(node)) {
var identifier = node;
// Only bother calling into the typechecker if this is an identifier that
// could possibly resolve to a type name. This makes classification run
// in a third of the time it would normally take.
if (classifiableNames[identifier.text]) {
var symbol = typeChecker.getSymbolAtLocation(node);
if (symbol) {
var type = classifySymbol(symbol, ts.getMeaningFromLocation(node));
if (type) {
pushClassification(node.getStart(), node.getWidth(), type);
}
}
}
}
ts.forEachChild(node, processNode);
}
}
}
ts.getEncodedSemanticClassifications = getEncodedSemanticClassifications;
function getClassificationTypeName(type) {
switch (type) {
case 1 /* comment */: return ts.ClassificationTypeNames.comment;
case 2 /* identifier */: return ts.ClassificationTypeNames.identifier;
case 3 /* keyword */: return ts.ClassificationTypeNames.keyword;
case 4 /* numericLiteral */: return ts.ClassificationTypeNames.numericLiteral;
case 5 /* operator */: return ts.ClassificationTypeNames.operator;
case 6 /* stringLiteral */: return ts.ClassificationTypeNames.stringLiteral;
case 8 /* whiteSpace */: return ts.ClassificationTypeNames.whiteSpace;
case 9 /* text */: return ts.ClassificationTypeNames.text;
case 10 /* punctuation */: return ts.ClassificationTypeNames.punctuation;
case 11 /* className */: return ts.ClassificationTypeNames.className;
case 12 /* enumName */: return ts.ClassificationTypeNames.enumName;
case 13 /* interfaceName */: return ts.ClassificationTypeNames.interfaceName;
case 14 /* moduleName */: return ts.ClassificationTypeNames.moduleName;
case 15 /* typeParameterName */: return ts.ClassificationTypeNames.typeParameterName;
case 16 /* typeAliasName */: return ts.ClassificationTypeNames.typeAliasName;
case 17 /* parameterName */: return ts.ClassificationTypeNames.parameterName;
case 18 /* docCommentTagName */: return ts.ClassificationTypeNames.docCommentTagName;
case 19 /* jsxOpenTagName */: return ts.ClassificationTypeNames.jsxOpenTagName;
case 20 /* jsxCloseTagName */: return ts.ClassificationTypeNames.jsxCloseTagName;
case 21 /* jsxSelfClosingTagName */: return ts.ClassificationTypeNames.jsxSelfClosingTagName;
case 22 /* jsxAttribute */: return ts.ClassificationTypeNames.jsxAttribute;
case 23 /* jsxText */: return ts.ClassificationTypeNames.jsxText;
case 24 /* jsxAttributeStringLiteralValue */: return ts.ClassificationTypeNames.jsxAttributeStringLiteralValue;
}
}
function convertClassifications(classifications) {
ts.Debug.assert(classifications.spans.length % 3 === 0);
var dense = classifications.spans;
var result = [];
for (var i = 0, n = dense.length; i < n; i += 3) {
result.push({
textSpan: ts.createTextSpan(dense[i], dense[i + 1]),
classificationType: getClassificationTypeName(dense[i + 2])
});
}
return result;
}
/* @internal */
function getSyntacticClassifications(cancellationToken, sourceFile, span) {
return convertClassifications(getEncodedSyntacticClassifications(cancellationToken, sourceFile, span));
}
ts.getSyntacticClassifications = getSyntacticClassifications;
/* @internal */
function getEncodedSyntacticClassifications(cancellationToken, sourceFile, span) {
var spanStart = span.start;
var spanLength = span.length;
// Make a scanner we can get trivia from.
var triviaScanner = ts.createScanner(5 /* Latest */, /*skipTrivia*/ false, sourceFile.languageVariant, sourceFile.text);
var mergeConflictScanner = ts.createScanner(5 /* Latest */, /*skipTrivia*/ false, sourceFile.languageVariant, sourceFile.text);
var result = [];
processElement(sourceFile);
return { spans: result, endOfLineState: 0 /* None */ };
function pushClassification(start, length, type) {
result.push(start);
result.push(length);
result.push(type);
}
function classifyLeadingTriviaAndGetTokenStart(token) {
triviaScanner.setTextPos(token.pos);
while (true) {
var start = triviaScanner.getTextPos();
// only bother scanning if we have something that could be trivia.
if (!ts.couldStartTrivia(sourceFile.text, start)) {
return start;
}
var kind = triviaScanner.scan();
var end = triviaScanner.getTextPos();
var width = end - start;
// The moment we get something that isn't trivia, then stop processing.
if (!ts.isTrivia(kind)) {
return start;
}
// Don't bother with newlines/whitespace.
if (kind === 4 /* NewLineTrivia */ || kind === 5 /* WhitespaceTrivia */) {
continue;
}
// Only bother with the trivia if it at least intersects the span of interest.
if (ts.isComment(kind)) {
classifyComment(token, kind, start, width);
// Classifying a comment might cause us to reuse the trivia scanner
// (because of jsdoc comments). So after we classify the comment make
// sure we set the scanner position back to where it needs to be.
triviaScanner.setTextPos(end);
continue;
}
if (kind === 7 /* ConflictMarkerTrivia */) {
var text = sourceFile.text;
var ch = text.charCodeAt(start);
// for the <<<<<<< and >>>>>>> markers, we just add them in as comments
// in the classification stream.
if (ch === 60 /* lessThan */ || ch === 62 /* greaterThan */) {
pushClassification(start, width, 1 /* comment */);
continue;
}
// for the ======== add a comment for the first line, and then lex all
// subsequent lines up until the end of the conflict marker.
ts.Debug.assert(ch === 61 /* equals */);
classifyDisabledMergeCode(text, start, end);
}
}
}
function classifyComment(token, kind, start, width) {
if (kind === 3 /* MultiLineCommentTrivia */) {
// See if this is a doc comment. If so, we'll classify certain portions of it
// specially.
var docCommentAndDiagnostics = ts.parseIsolatedJSDocComment(sourceFile.text, start, width);
if (docCommentAndDiagnostics && docCommentAndDiagnostics.jsDoc) {
docCommentAndDiagnostics.jsDoc.parent = token;
classifyJSDocComment(docCommentAndDiagnostics.jsDoc);
return;
}
}
// Simple comment. Just add as is.
pushCommentRange(start, width);
}
function pushCommentRange(start, width) {
pushClassification(start, width, 1 /* comment */);
}
function classifyJSDocComment(docComment) {
var pos = docComment.pos;
if (docComment.tags) {
for (var _i = 0, _a = docComment.tags; _i < _a.length; _i++) {
var tag = _a[_i];
// As we walk through each tag, classify the portion of text from the end of
// the last tag (or the start of the entire doc comment) as 'comment'.
if (tag.pos !== pos) {
pushCommentRange(pos, tag.pos - pos);
}
pushClassification(tag.atToken.pos, tag.atToken.end - tag.atToken.pos, 10 /* punctuation */);
pushClassification(tag.tagName.pos, tag.tagName.end - tag.tagName.pos, 18 /* docCommentTagName */);
pos = tag.tagName.end;
switch (tag.kind) {
case 280 /* JSDocParameterTag */:
processJSDocParameterTag(tag);
break;
case 283 /* JSDocTemplateTag */:
processJSDocTemplateTag(tag);
break;
case 282 /* JSDocTypeTag */:
processElement(tag.typeExpression);
break;
case 281 /* JSDocReturnTag */:
processElement(tag.typeExpression);
break;
}
pos = tag.end;
}
}
if (pos !== docComment.end) {
pushCommentRange(pos, docComment.end - pos);
}
return;
function processJSDocParameterTag(tag) {
if (tag.preParameterName) {
pushCommentRange(pos, tag.preParameterName.pos - pos);
pushClassification(tag.preParameterName.pos, tag.preParameterName.end - tag.preParameterName.pos, 17 /* parameterName */);
pos = tag.preParameterName.end;
}
if (tag.typeExpression) {
pushCommentRange(pos, tag.typeExpression.pos - pos);
processElement(tag.typeExpression);
pos = tag.typeExpression.end;
}
if (tag.postParameterName) {
pushCommentRange(pos, tag.postParameterName.pos - pos);
pushClassification(tag.postParameterName.pos, tag.postParameterName.end - tag.postParameterName.pos, 17 /* parameterName */);
pos = tag.postParameterName.end;
}
}
}
function processJSDocTemplateTag(tag) {
for (var _i = 0, _a = tag.getChildren(); _i < _a.length; _i++) {
var child = _a[_i];
processElement(child);
}
}
function classifyDisabledMergeCode(text, start, end) {
// Classify the line that the ======= marker is on as a comment. Then just lex
// all further tokens and add them to the result.
var i;
for (i = start; i < end; i++) {
if (ts.isLineBreak(text.charCodeAt(i))) {
break;
}
}
pushClassification(start, i - start, 1 /* comment */);
mergeConflictScanner.setTextPos(i);
while (mergeConflictScanner.getTextPos() < end) {
classifyDisabledCodeToken();
}
}
function classifyDisabledCodeToken() {
var start = mergeConflictScanner.getTextPos();
var tokenKind = mergeConflictScanner.scan();
var end = mergeConflictScanner.getTextPos();
var type = classifyTokenType(tokenKind);
if (type) {
pushClassification(start, end - start, type);
}
}
/**
* Returns true if node should be treated as classified and no further processing is required.
* False will mean that node is not classified and traverse routine should recurse into node contents.
*/
function tryClassifyNode(node) {
if (ts.isJSDocTag(node)) {
return true;
}
if (ts.nodeIsMissing(node)) {
return true;
}
var classifiedElementName = tryClassifyJsxElementName(node);
if (!ts.isToken(node) && node.kind !== 10 /* JsxText */ && classifiedElementName === undefined) {
return false;
}
var tokenStart = node.kind === 10 /* JsxText */ ? node.pos : classifyLeadingTriviaAndGetTokenStart(node);
var tokenWidth = node.end - tokenStart;
ts.Debug.assert(tokenWidth >= 0);
if (tokenWidth > 0) {
var type = classifiedElementName || classifyTokenType(node.kind, node);
if (type) {
pushClassification(tokenStart, tokenWidth, type);
}
}
return true;
}
function tryClassifyJsxElementName(token) {
switch (token.parent && token.parent.kind) {
case 248 /* JsxOpeningElement */:
if (token.parent.tagName === token) {
return 19 /* jsxOpenTagName */;
}
break;
case 249 /* JsxClosingElement */:
if (token.parent.tagName === token) {
return 20 /* jsxCloseTagName */;
}
break;
case 247 /* JsxSelfClosingElement */:
if (token.parent.tagName === token) {
return 21 /* jsxSelfClosingTagName */;
}
break;
case 250 /* JsxAttribute */:
if (token.parent.name === token) {
return 22 /* jsxAttribute */;
}
break;
}
return undefined;
}
// for accurate classification, the actual token should be passed in. however, for
// cases like 'disabled merge code' classification, we just get the token kind and
// classify based on that instead.
function classifyTokenType(tokenKind, token) {
if (ts.isKeyword(tokenKind)) {
return 3 /* keyword */;
}
// Special case < and > If they appear in a generic context they are punctuation,
// not operators.
if (tokenKind === 26 /* LessThanToken */ || tokenKind === 28 /* GreaterThanToken */) {
// If the node owning the token has a type argument list or type parameter list, then
// we can effectively assume that a '<' and '>' belong to those lists.
if (token && ts.getTypeArgumentOrTypeParameterList(token.parent)) {
return 10 /* punctuation */;
}
}
if (ts.isPunctuation(tokenKind)) {
if (token) {
if (tokenKind === 57 /* EqualsToken */) {
// the '=' in a variable declaration is special cased here.
if (token.parent.kind === 223 /* VariableDeclaration */ ||
token.parent.kind === 147 /* PropertyDeclaration */ ||
token.parent.kind === 144 /* Parameter */ ||
token.parent.kind === 250 /* JsxAttribute */) {
return 5 /* operator */;
}
}
if (token.parent.kind === 192 /* BinaryExpression */ ||
token.parent.kind === 190 /* PrefixUnaryExpression */ ||
token.parent.kind === 191 /* PostfixUnaryExpression */ ||
token.parent.kind === 193 /* ConditionalExpression */) {
return 5 /* operator */;
}
}
return 10 /* punctuation */;
}
else if (tokenKind === 8 /* NumericLiteral */) {
return 4 /* numericLiteral */;
}
else if (tokenKind === 9 /* StringLiteral */) {
return token.parent.kind === 250 /* JsxAttribute */ ? 24 /* jsxAttributeStringLiteralValue */ : 6 /* stringLiteral */;
}
else if (tokenKind === 11 /* RegularExpressionLiteral */) {
// TODO: we should get another classification type for these literals.
return 6 /* stringLiteral */;
}
else if (ts.isTemplateLiteralKind(tokenKind)) {
// TODO (drosen): we should *also* get another classification type for these literals.
return 6 /* stringLiteral */;
}
else if (tokenKind === 10 /* JsxText */) {
return 23 /* jsxText */;
}
else if (tokenKind === 70 /* Identifier */) {
if (token) {
switch (token.parent.kind) {
case 226 /* ClassDeclaration */:
if (token.parent.name === token) {
return 11 /* className */;
}
return;
case 143 /* TypeParameter */:
if (token.parent.name === token) {
return 15 /* typeParameterName */;
}
return;
case 227 /* InterfaceDeclaration */:
if (token.parent.name === token) {
return 13 /* interfaceName */;
}
return;
case 229 /* EnumDeclaration */:
if (token.parent.name === token) {
return 12 /* enumName */;
}
return;
case 230 /* ModuleDeclaration */:
if (token.parent.name === token) {
return 14 /* moduleName */;
}
return;
case 144 /* Parameter */:
if (token.parent.name === token) {
return ts.isThisIdentifier(token) ? 3 /* keyword */ : 17 /* parameterName */;
}
return;
}
}
return 2 /* identifier */;
}
}
function processElement(element) {
if (!element) {
return;
}
// Ignore nodes that don't intersect the original span to classify.
if (ts.decodedTextSpanIntersectsWith(spanStart, spanLength, element.pos, element.getFullWidth())) {
checkForClassificationCancellation(cancellationToken, element.kind);
var children = element.getChildren(sourceFile);
for (var i = 0, n = children.length; i < n; i++) {
var child = children[i];
if (!tryClassifyNode(child)) {
// Recurse into our child nodes.
processElement(child);
}
}
}
}
}
ts.getEncodedSyntacticClassifications = getEncodedSyntacticClassifications;
})(ts || (ts = {}));
/// <reference path='../compiler/utilities.ts' />
/* @internal */
var ts;
(function (ts) {
var Completions;
(function (Completions) {
function getCompletionsAtPosition(host, typeChecker, log, compilerOptions, sourceFile, position) {
if (ts.isInReferenceComment(sourceFile, position)) {
return getTripleSlashReferenceCompletion(sourceFile, position);
}
if (ts.isInString(sourceFile, position)) {
return getStringLiteralCompletionEntries(sourceFile, position);
}
var completionData = getCompletionData(typeChecker, log, sourceFile, position);
if (!completionData) {
return undefined;
}
var symbols = completionData.symbols, isGlobalCompletion = completionData.isGlobalCompletion, isMemberCompletion = completionData.isMemberCompletion, isNewIdentifierLocation = completionData.isNewIdentifierLocation, location = completionData.location, isJsDocTagName = completionData.isJsDocTagName;
if (isJsDocTagName) {
// If the current position is a jsDoc tag name, only tag names should be provided for completion
return { isGlobalCompletion: false, isMemberCompletion: false, isNewIdentifierLocation: false, entries: ts.JsDoc.getAllJsDocCompletionEntries() };
}
var entries = [];
if (ts.isSourceFileJavaScript(sourceFile)) {
var uniqueNames = getCompletionEntriesFromSymbols(symbols, entries, location, /*performCharacterChecks*/ true);
ts.addRange(entries, getJavaScriptCompletionEntries(sourceFile, location.pos, uniqueNames));
}
else {
if (!symbols || symbols.length === 0) {
if (sourceFile.languageVariant === 1 /* JSX */ &&
location.parent && location.parent.kind === 249 /* JsxClosingElement */) {
// In the TypeScript JSX element, if such element is not defined. When users query for completion at closing tag,
// instead of simply giving unknown value, the completion will return the tag-name of an associated opening-element.
// For example:
// var x = <div> </ /*1*/> completion list at "1" will contain "div" with type any
var tagName = location.parent.parent.openingElement.tagName;
entries.push({
name: tagName.text,
kind: undefined,
kindModifiers: undefined,
sortText: "0",
});
}
else {
return undefined;
}
}
getCompletionEntriesFromSymbols(symbols, entries, location, /*performCharacterChecks*/ true);
}
// Add keywords if this is not a member completion list
if (!isMemberCompletion && !isJsDocTagName) {
ts.addRange(entries, keywordCompletions);
}
return { isGlobalCompletion: isGlobalCompletion, isMemberCompletion: isMemberCompletion, isNewIdentifierLocation: isNewIdentifierLocation, entries: entries };
function getJavaScriptCompletionEntries(sourceFile, position, uniqueNames) {
var entries = [];
var nameTable = ts.getNameTable(sourceFile);
for (var name_42 in nameTable) {
// Skip identifiers produced only from the current location
if (nameTable[name_42] === position) {
continue;
}
if (!uniqueNames[name_42]) {
uniqueNames[name_42] = name_42;
var displayName = getCompletionEntryDisplayName(ts.unescapeIdentifier(name_42), compilerOptions.target, /*performCharacterChecks*/ true);
if (displayName) {
var entry = {
name: displayName,
kind: ts.ScriptElementKind.warning,
kindModifiers: "",
sortText: "1"
};
entries.push(entry);
}
}
}
return entries;
}
function createCompletionEntry(symbol, location, performCharacterChecks) {
// Try to get a valid display name for this symbol, if we could not find one, then ignore it.
// We would like to only show things that can be added after a dot, so for instance numeric properties can
// not be accessed with a dot (a.1 <- invalid)
var displayName = getCompletionEntryDisplayNameForSymbol(typeChecker, symbol, compilerOptions.target, performCharacterChecks, location);
if (!displayName) {
return undefined;
}
// TODO(drosen): Right now we just permit *all* semantic meanings when calling
// 'getSymbolKind' which is permissible given that it is backwards compatible; but
// really we should consider passing the meaning for the node so that we don't report
// that a suggestion for a value is an interface. We COULD also just do what
// 'getSymbolModifiers' does, which is to use the first declaration.
// Use a 'sortText' of 0' so that all symbol completion entries come before any other
// entries (like JavaScript identifier entries).
return {
name: displayName,
kind: ts.SymbolDisplay.getSymbolKind(typeChecker, symbol, location),
kindModifiers: ts.SymbolDisplay.getSymbolModifiers(symbol),
sortText: "0",
};
}
function getCompletionEntriesFromSymbols(symbols, entries, location, performCharacterChecks) {
var start = ts.timestamp();
var uniqueNames = ts.createMap();
if (symbols) {
for (var _i = 0, symbols_4 = symbols; _i < symbols_4.length; _i++) {
var symbol = symbols_4[_i];
var entry = createCompletionEntry(symbol, location, performCharacterChecks);
if (entry) {
var id = ts.escapeIdentifier(entry.name);
if (!uniqueNames[id]) {
entries.push(entry);
uniqueNames[id] = id;
}
}
}
}
log("getCompletionsAtPosition: getCompletionEntriesFromSymbols: " + (ts.timestamp() - start));
return uniqueNames;
}
function getStringLiteralCompletionEntries(sourceFile, position) {
var node = ts.findPrecedingToken(position, sourceFile);
if (!node || node.kind !== 9 /* StringLiteral */) {
return undefined;
}
if (node.parent.kind === 257 /* PropertyAssignment */ &&
node.parent.parent.kind === 176 /* ObjectLiteralExpression */ &&
node.parent.name === node) {
// Get quoted name of properties of the object literal expression
// i.e. interface ConfigFiles {
// 'jspm:dev': string
// }
// let files: ConfigFiles = {
// '/*completion position*/'
// }
//
// function foo(c: ConfigFiles) {}
// foo({
// '/*completion position*/'
// });
return getStringLiteralCompletionEntriesFromPropertyAssignment(node.parent);
}
else if (ts.isElementAccessExpression(node.parent) && node.parent.argumentExpression === node) {
// Get all names of properties on the expression
// i.e. interface A {
// 'prop1': string
// }
// let a: A;
// a['/*completion position*/']
return getStringLiteralCompletionEntriesFromElementAccess(node.parent);
}
else if (node.parent.kind === 235 /* ImportDeclaration */ || ts.isExpressionOfExternalModuleImportEqualsDeclaration(node) || ts.isRequireCall(node.parent, false)) {
// Get all known external module names or complete a path to a module
// i.e. import * as ns from "/*completion position*/";
// import x = require("/*completion position*/");
// var y = require("/*completion position*/");
return getStringLiteralCompletionEntriesFromModuleNames(node);
}
else {
var argumentInfo = ts.SignatureHelp.getContainingArgumentInfo(node, position, sourceFile);
if (argumentInfo) {
// Get string literal completions from specialized signatures of the target
// i.e. declare function f(a: 'A');
// f("/*completion position*/")
return getStringLiteralCompletionEntriesFromCallExpression(argumentInfo);
}
// Get completion for string literal from string literal type
// i.e. var x: "hi" | "hello" = "/*completion position*/"
return getStringLiteralCompletionEntriesFromContextualType(node);
}
}
function getStringLiteralCompletionEntriesFromPropertyAssignment(element) {
var type = typeChecker.getContextualType(element.parent);
var entries = [];
if (type) {
getCompletionEntriesFromSymbols(type.getApparentProperties(), entries, element, /*performCharacterChecks*/ false);
if (entries.length) {
return { isGlobalCompletion: false, isMemberCompletion: true, isNewIdentifierLocation: true, entries: entries };
}
}
}
function getStringLiteralCompletionEntriesFromCallExpression(argumentInfo) {
var candidates = [];
var entries = [];
typeChecker.getResolvedSignature(argumentInfo.invocation, candidates);
for (var _i = 0, candidates_3 = candidates; _i < candidates_3.length; _i++) {
var candidate = candidates_3[_i];
if (candidate.parameters.length > argumentInfo.argumentIndex) {
var parameter = candidate.parameters[argumentInfo.argumentIndex];
addStringLiteralCompletionsFromType(typeChecker.getTypeAtLocation(parameter.valueDeclaration), entries);
}
}
if (entries.length) {
return { isGlobalCompletion: false, isMemberCompletion: false, isNewIdentifierLocation: true, entries: entries };
}
return undefined;
}
function getStringLiteralCompletionEntriesFromElementAccess(node) {
var type = typeChecker.getTypeAtLocation(node.expression);
var entries = [];
if (type) {
getCompletionEntriesFromSymbols(type.getApparentProperties(), entries, node, /*performCharacterChecks*/ false);
if (entries.length) {
return { isGlobalCompletion: false, isMemberCompletion: true, isNewIdentifierLocation: true, entries: entries };
}
}
return undefined;
}
function getStringLiteralCompletionEntriesFromContextualType(node) {
var type = typeChecker.getContextualType(node);
if (type) {
var entries_2 = [];
addStringLiteralCompletionsFromType(type, entries_2);
if (entries_2.length) {
return { isGlobalCompletion: false, isMemberCompletion: false, isNewIdentifierLocation: false, entries: entries_2 };
}
}
return undefined;
}
function addStringLiteralCompletionsFromType(type, result) {
if (!type) {
return;
}
if (type.flags & 65536 /* Union */) {
ts.forEach(type.types, function (t) { return addStringLiteralCompletionsFromType(t, result); });
}
else {
if (type.flags & 32 /* StringLiteral */) {
result.push({
name: type.text,
kindModifiers: ts.ScriptElementKindModifier.none,
kind: ts.ScriptElementKind.variableElement,
sortText: "0"
});
}
}
}
function getStringLiteralCompletionEntriesFromModuleNames(node) {
var literalValue = ts.normalizeSlashes(node.text);
var scriptPath = node.getSourceFile().path;
var scriptDirectory = ts.getDirectoryPath(scriptPath);
var span = getDirectoryFragmentTextSpan(node.text, node.getStart() + 1);
var entries;
if (isPathRelativeToScript(literalValue) || ts.isRootedDiskPath(literalValue)) {
if (compilerOptions.rootDirs) {
entries = getCompletionEntriesForDirectoryFragmentWithRootDirs(compilerOptions.rootDirs, literalValue, scriptDirectory, ts.getSupportedExtensions(compilerOptions), /*includeExtensions*/ false, span, scriptPath);
}
else {
entries = getCompletionEntriesForDirectoryFragment(literalValue, scriptDirectory, ts.getSupportedExtensions(compilerOptions), /*includeExtensions*/ false, span, scriptPath);
}
}
else {
// Check for node modules
entries = getCompletionEntriesForNonRelativeModules(literalValue, scriptDirectory, span);
}
return {
isGlobalCompletion: false,
isMemberCompletion: false,
isNewIdentifierLocation: true,
entries: entries
};
}
/**
* Takes a script path and returns paths for all potential folders that could be merged with its
* containing folder via the "rootDirs" compiler option
*/
function getBaseDirectoriesFromRootDirs(rootDirs, basePath, scriptPath, ignoreCase) {
// Make all paths absolute/normalized if they are not already
rootDirs = ts.map(rootDirs, function (rootDirectory) { return ts.normalizePath(ts.isRootedDiskPath(rootDirectory) ? rootDirectory : ts.combinePaths(basePath, rootDirectory)); });
// Determine the path to the directory containing the script relative to the root directory it is contained within
var relativeDirectory;
for (var _i = 0, rootDirs_1 = rootDirs; _i < rootDirs_1.length; _i++) {
var rootDirectory = rootDirs_1[_i];
if (ts.containsPath(rootDirectory, scriptPath, basePath, ignoreCase)) {
relativeDirectory = scriptPath.substr(rootDirectory.length);
break;
}
}
// Now find a path for each potential directory that is to be merged with the one containing the script
return ts.deduplicate(ts.map(rootDirs, function (rootDirectory) { return ts.combinePaths(rootDirectory, relativeDirectory); }));
}
function getCompletionEntriesForDirectoryFragmentWithRootDirs(rootDirs, fragment, scriptPath, extensions, includeExtensions, span, exclude) {
var basePath = compilerOptions.project || host.getCurrentDirectory();
var ignoreCase = !(host.useCaseSensitiveFileNames && host.useCaseSensitiveFileNames());
var baseDirectories = getBaseDirectoriesFromRootDirs(rootDirs, basePath, scriptPath, ignoreCase);
var result = [];
for (var _i = 0, baseDirectories_1 = baseDirectories; _i < baseDirectories_1.length; _i++) {
var baseDirectory = baseDirectories_1[_i];
getCompletionEntriesForDirectoryFragment(fragment, baseDirectory, extensions, includeExtensions, span, exclude, result);
}
return result;
}
/**
* Given a path ending at a directory, gets the completions for the path, and filters for those entries containing the basename.
*/
function getCompletionEntriesForDirectoryFragment(fragment, scriptPath, extensions, includeExtensions, span, exclude, result) {
if (result === void 0) { result = []; }
if (fragment === undefined) {
fragment = "";
}
fragment = ts.normalizeSlashes(fragment);
/**
* Remove the basename from the path. Note that we don't use the basename to filter completions;
* the client is responsible for refining completions.
*/
fragment = ts.getDirectoryPath(fragment);
if (fragment === "") {
fragment = "." + ts.directorySeparator;
}
fragment = ts.ensureTrailingDirectorySeparator(fragment);
var absolutePath = normalizeAndPreserveTrailingSlash(ts.isRootedDiskPath(fragment) ? fragment : ts.combinePaths(scriptPath, fragment));
var baseDirectory = ts.getDirectoryPath(absolutePath);
var ignoreCase = !(host.useCaseSensitiveFileNames && host.useCaseSensitiveFileNames());
if (tryDirectoryExists(host, baseDirectory)) {
// Enumerate the available files if possible
var files = tryReadDirectory(host, baseDirectory, extensions, /*exclude*/ undefined, /*include*/ ["./*"]);
if (files) {
/**
* Multiple file entries might map to the same truncated name once we remove extensions
* (happens iff includeExtensions === false)so we use a set-like data structure. Eg:
*
* both foo.ts and foo.tsx become foo
*/
var foundFiles = ts.createMap();
for (var _i = 0, files_3 = files; _i < files_3.length; _i++) {
var filePath = files_3[_i];
filePath = ts.normalizePath(filePath);
if (exclude && ts.comparePaths(filePath, exclude, scriptPath, ignoreCase) === 0 /* EqualTo */) {
continue;
}
var foundFileName = includeExtensions ? ts.getBaseFileName(filePath) : ts.removeFileExtension(ts.getBaseFileName(filePath));
if (!foundFiles[foundFileName]) {
foundFiles[foundFileName] = true;
}
}
for (var foundFile in foundFiles) {
result.push(createCompletionEntryForModule(foundFile, ts.ScriptElementKind.scriptElement, span));
}
}
// If possible, get folder completion as well
var directories = tryGetDirectories(host, baseDirectory);
if (directories) {
for (var _a = 0, directories_2 = directories; _a < directories_2.length; _a++) {
var directory = directories_2[_a];
var directoryName = ts.getBaseFileName(ts.normalizePath(directory));
result.push(createCompletionEntryForModule(directoryName, ts.ScriptElementKind.directory, span));
}
}
}
return result;
}
/**
* Check all of the declared modules and those in node modules. Possible sources of modules:
* Modules that are found by the type checker
* Modules found relative to "baseUrl" compliler options (including patterns from "paths" compiler option)
* Modules from node_modules (i.e. those listed in package.json)
* This includes all files that are found in node_modules/moduleName/ with acceptable file extensions
*/
function getCompletionEntriesForNonRelativeModules(fragment, scriptPath, span) {
var baseUrl = compilerOptions.baseUrl, paths = compilerOptions.paths;
var result;
if (baseUrl) {
var fileExtensions = ts.getSupportedExtensions(compilerOptions);
var projectDir = compilerOptions.project || host.getCurrentDirectory();
var absolute = ts.isRootedDiskPath(baseUrl) ? baseUrl : ts.combinePaths(projectDir, baseUrl);
result = getCompletionEntriesForDirectoryFragment(fragment, ts.normalizePath(absolute), fileExtensions, /*includeExtensions*/ false, span);
if (paths) {
for (var path in paths) {
if (paths.hasOwnProperty(path)) {
if (path === "*") {
if (paths[path]) {
for (var _i = 0, _a = paths[path]; _i < _a.length; _i++) {
var pattern = _a[_i];
for (var _b = 0, _c = getModulesForPathsPattern(fragment, baseUrl, pattern, fileExtensions); _b < _c.length; _b++) {
var match = _c[_b];
result.push(createCompletionEntryForModule(match, ts.ScriptElementKind.externalModuleName, span));
}
}
}
}
else if (ts.startsWith(path, fragment)) {
var entry = paths[path] && paths[path].length === 1 && paths[path][0];
if (entry) {
result.push(createCompletionEntryForModule(path, ts.ScriptElementKind.externalModuleName, span));
}
}
}
}
}
}
else {
result = [];
}
getCompletionEntriesFromTypings(host, compilerOptions, scriptPath, span, result);
for (var _d = 0, _e = enumeratePotentialNonRelativeModules(fragment, scriptPath, compilerOptions); _d < _e.length; _d++) {
var moduleName = _e[_d];
result.push(createCompletionEntryForModule(moduleName, ts.ScriptElementKind.externalModuleName, span));
}
return result;
}
function getModulesForPathsPattern(fragment, baseUrl, pattern, fileExtensions) {
if (host.readDirectory) {
var parsed = ts.hasZeroOrOneAsteriskCharacter(pattern) ? ts.tryParsePattern(pattern) : undefined;
if (parsed) {
// The prefix has two effective parts: the directory path and the base component after the filepath that is not a
// full directory component. For example: directory/path/of/prefix/base*
var normalizedPrefix = normalizeAndPreserveTrailingSlash(parsed.prefix);
var normalizedPrefixDirectory = ts.getDirectoryPath(normalizedPrefix);
var normalizedPrefixBase = ts.getBaseFileName(normalizedPrefix);
var fragmentHasPath = fragment.indexOf(ts.directorySeparator) !== -1;
// Try and expand the prefix to include any path from the fragment so that we can limit the readDirectory call
var expandedPrefixDirectory = fragmentHasPath ? ts.combinePaths(normalizedPrefixDirectory, normalizedPrefixBase + ts.getDirectoryPath(fragment)) : normalizedPrefixDirectory;
var normalizedSuffix = ts.normalizePath(parsed.suffix);
var baseDirectory = ts.combinePaths(baseUrl, expandedPrefixDirectory);
var completePrefix = fragmentHasPath ? baseDirectory : ts.ensureTrailingDirectorySeparator(baseDirectory) + normalizedPrefixBase;
// If we have a suffix, then we need to read the directory all the way down. We could create a glob
// that encodes the suffix, but we would have to escape the character "?" which readDirectory
// doesn't support. For now, this is safer but slower
var includeGlob = normalizedSuffix ? "**/*" : "./*";
var matches = tryReadDirectory(host, baseDirectory, fileExtensions, undefined, [includeGlob]);
if (matches) {
var result = [];
// Trim away prefix and suffix
for (var _i = 0, matches_1 = matches; _i < matches_1.length; _i++) {
var match = matches_1[_i];
var normalizedMatch = ts.normalizePath(match);
if (!ts.endsWith(normalizedMatch, normalizedSuffix) || !ts.startsWith(normalizedMatch, completePrefix)) {
continue;
}
var start = completePrefix.length;
var length_5 = normalizedMatch.length - start - normalizedSuffix.length;
result.push(ts.removeFileExtension(normalizedMatch.substr(start, length_5)));
}
return result;
}
}
}
return undefined;
}
function enumeratePotentialNonRelativeModules(fragment, scriptPath, options) {
// Check If this is a nested module
var isNestedModule = fragment.indexOf(ts.directorySeparator) !== -1;
var moduleNameFragment = isNestedModule ? fragment.substr(0, fragment.lastIndexOf(ts.directorySeparator)) : undefined;
// Get modules that the type checker picked up
var ambientModules = ts.map(typeChecker.getAmbientModules(), function (sym) { return ts.stripQuotes(sym.name); });
var nonRelativeModules = ts.filter(ambientModules, function (moduleName) { return ts.startsWith(moduleName, fragment); });
// Nested modules of the form "module-name/sub" need to be adjusted to only return the string
// after the last '/' that appears in the fragment because that's where the replacement span
// starts
if (isNestedModule) {
var moduleNameWithSeperator_1 = ts.ensureTrailingDirectorySeparator(moduleNameFragment);
nonRelativeModules = ts.map(nonRelativeModules, function (moduleName) {
if (ts.startsWith(fragment, moduleNameWithSeperator_1)) {
return moduleName.substr(moduleNameWithSeperator_1.length);
}
return moduleName;
});
}
if (!options.moduleResolution || options.moduleResolution === ts.ModuleResolutionKind.NodeJs) {
for (var _i = 0, _a = enumerateNodeModulesVisibleToScript(host, scriptPath); _i < _a.length; _i++) {
var visibleModule = _a[_i];
if (!isNestedModule) {
nonRelativeModules.push(visibleModule.moduleName);
}
else if (ts.startsWith(visibleModule.moduleName, moduleNameFragment)) {
var nestedFiles = tryReadDirectory(host, visibleModule.moduleDir, ts.supportedTypeScriptExtensions, /*exclude*/ undefined, /*include*/ ["./*"]);
if (nestedFiles) {
for (var _b = 0, nestedFiles_1 = nestedFiles; _b < nestedFiles_1.length; _b++) {
var f = nestedFiles_1[_b];
f = ts.normalizePath(f);
var nestedModule = ts.removeFileExtension(ts.getBaseFileName(f));
nonRelativeModules.push(nestedModule);
}
}
}
}
}
return ts.deduplicate(nonRelativeModules);
}
function getTripleSlashReferenceCompletion(sourceFile, position) {
var token = ts.getTokenAtPosition(sourceFile, position);
if (!token) {
return undefined;
}
var commentRanges = ts.getLeadingCommentRanges(sourceFile.text, token.pos);
if (!commentRanges || !commentRanges.length) {
return undefined;
}
var range = ts.forEach(commentRanges, function (commentRange) { return position >= commentRange.pos && position <= commentRange.end && commentRange; });
if (!range) {
return undefined;
}
var completionInfo = {
/**
* We don't want the editor to offer any other completions, such as snippets, inside a comment.
*/
isGlobalCompletion: false,
isMemberCompletion: false,
/**
* The user may type in a path that doesn't yet exist, creating a "new identifier"
* with respect to the collection of identifiers the server is aware of.
*/
isNewIdentifierLocation: true,
entries: []
};
var text = sourceFile.text.substr(range.pos, position - range.pos);
var match = tripleSlashDirectiveFragmentRegex.exec(text);
if (match) {
var prefix = match[1];
var kind = match[2];
var toComplete = match[3];
var scriptPath = ts.getDirectoryPath(sourceFile.path);
if (kind === "path") {
// Give completions for a relative path
var span_10 = getDirectoryFragmentTextSpan(toComplete, range.pos + prefix.length);
completionInfo.entries = getCompletionEntriesForDirectoryFragment(toComplete, scriptPath, ts.getSupportedExtensions(compilerOptions), /*includeExtensions*/ true, span_10, sourceFile.path);
}
else {
// Give completions based on the typings available
var span_11 = { start: range.pos + prefix.length, length: match[0].length - prefix.length };
completionInfo.entries = getCompletionEntriesFromTypings(host, compilerOptions, scriptPath, span_11);
}
}
return completionInfo;
}
function getCompletionEntriesFromTypings(host, options, scriptPath, span, result) {
if (result === void 0) { result = []; }
// Check for typings specified in compiler options
if (options.types) {
for (var _i = 0, _a = options.types; _i < _a.length; _i++) {
var moduleName = _a[_i];
result.push(createCompletionEntryForModule(moduleName, ts.ScriptElementKind.externalModuleName, span));
}
}
else if (host.getDirectories) {
var typeRoots = void 0;
try {
// Wrap in try catch because getEffectiveTypeRoots touches the filesystem
typeRoots = ts.getEffectiveTypeRoots(options, host);
}
catch (e) { }
if (typeRoots) {
for (var _b = 0, typeRoots_2 = typeRoots; _b < typeRoots_2.length; _b++) {
var root = typeRoots_2[_b];
getCompletionEntriesFromDirectories(host, root, span, result);
}
}
}
if (host.getDirectories) {
// Also get all @types typings installed in visible node_modules directories
for (var _c = 0, _d = findPackageJsons(scriptPath); _c < _d.length; _c++) {
var packageJson = _d[_c];
var typesDir = ts.combinePaths(ts.getDirectoryPath(packageJson), "node_modules/@types");
getCompletionEntriesFromDirectories(host, typesDir, span, result);
}
}
return result;
}
function getCompletionEntriesFromDirectories(host, directory, span, result) {
if (host.getDirectories && tryDirectoryExists(host, directory)) {
var directories = tryGetDirectories(host, directory);
if (directories) {
for (var _i = 0, directories_3 = directories; _i < directories_3.length; _i++) {
var typeDirectory = directories_3[_i];
typeDirectory = ts.normalizePath(typeDirectory);
result.push(createCompletionEntryForModule(ts.getBaseFileName(typeDirectory), ts.ScriptElementKind.externalModuleName, span));
}
}
}
}
function findPackageJsons(currentDir) {
var paths = [];
var currentConfigPath;
while (true) {
currentConfigPath = ts.findConfigFile(currentDir, function (f) { return tryFileExists(host, f); }, "package.json");
if (currentConfigPath) {
paths.push(currentConfigPath);
currentDir = ts.getDirectoryPath(currentConfigPath);
var parent_14 = ts.getDirectoryPath(currentDir);
if (currentDir === parent_14) {
break;
}
currentDir = parent_14;
}
else {
break;
}
}
return paths;
}
function enumerateNodeModulesVisibleToScript(host, scriptPath) {
var result = [];
if (host.readFile && host.fileExists) {
for (var _i = 0, _a = findPackageJsons(scriptPath); _i < _a.length; _i++) {
var packageJson = _a[_i];
var contents = tryReadingPackageJson(packageJson);
if (!contents) {
return;
}
var nodeModulesDir = ts.combinePaths(ts.getDirectoryPath(packageJson), "node_modules");
var foundModuleNames = [];
// Provide completions for all non @types dependencies
for (var _b = 0, nodeModulesDependencyKeys_1 = nodeModulesDependencyKeys; _b < nodeModulesDependencyKeys_1.length; _b++) {
var key = nodeModulesDependencyKeys_1[_b];
addPotentialPackageNames(contents[key], foundModuleNames);
}
for (var _c = 0, foundModuleNames_1 = foundModuleNames; _c < foundModuleNames_1.length; _c++) {
var moduleName = foundModuleNames_1[_c];
var moduleDir = ts.combinePaths(nodeModulesDir, moduleName);
result.push({
moduleName: moduleName,
moduleDir: moduleDir
});
}
}
}
return result;
function tryReadingPackageJson(filePath) {
try {
var fileText = tryReadFile(host, filePath);
return fileText ? JSON.parse(fileText) : undefined;
}
catch (e) {
return undefined;
}
}
function addPotentialPackageNames(dependencies, result) {
if (dependencies) {
for (var dep in dependencies) {
if (dependencies.hasOwnProperty(dep) && !ts.startsWith(dep, "@types/")) {
result.push(dep);
}
}
}
}
}
function createCompletionEntryForModule(name, kind, replacementSpan) {
return { name: name, kind: kind, kindModifiers: ts.ScriptElementKindModifier.none, sortText: name, replacementSpan: replacementSpan };
}
// Replace everything after the last directory seperator that appears
function getDirectoryFragmentTextSpan(text, textStart) {
var index = text.lastIndexOf(ts.directorySeparator);
var offset = index !== -1 ? index + 1 : 0;
return { start: textStart + offset, length: text.length - offset };
}
// Returns true if the path is explicitly relative to the script (i.e. relative to . or ..)
function isPathRelativeToScript(path) {
if (path && path.length >= 2 && path.charCodeAt(0) === 46 /* dot */) {
var slashIndex = path.length >= 3 && path.charCodeAt(1) === 46 /* dot */ ? 2 : 1;
var slashCharCode = path.charCodeAt(slashIndex);
return slashCharCode === 47 /* slash */ || slashCharCode === 92 /* backslash */;
}
return false;
}
function normalizeAndPreserveTrailingSlash(path) {
return ts.hasTrailingDirectorySeparator(path) ? ts.ensureTrailingDirectorySeparator(ts.normalizePath(path)) : ts.normalizePath(path);
}
}
Completions.getCompletionsAtPosition = getCompletionsAtPosition;
function getCompletionEntryDetails(typeChecker, log, compilerOptions, sourceFile, position, entryName) {
// Compute all the completion symbols again.
var completionData = getCompletionData(typeChecker, log, sourceFile, position);
if (completionData) {
var symbols = completionData.symbols, location_2 = completionData.location;
// Find the symbol with the matching entry name.
// We don't need to perform character checks here because we're only comparing the
// name against 'entryName' (which is known to be good), not building a new
// completion entry.
var symbol = ts.forEach(symbols, function (s) { return getCompletionEntryDisplayNameForSymbol(typeChecker, s, compilerOptions.target, /*performCharacterChecks*/ false, location_2) === entryName ? s : undefined; });
if (symbol) {
var _a = ts.SymbolDisplay.getSymbolDisplayPartsDocumentationAndSymbolKind(typeChecker, symbol, sourceFile, location_2, location_2, 7 /* All */), displayParts = _a.displayParts, documentation = _a.documentation, symbolKind = _a.symbolKind;
return {
name: entryName,
kindModifiers: ts.SymbolDisplay.getSymbolModifiers(symbol),
kind: symbolKind,
displayParts: displayParts,
documentation: documentation
};
}
}
// Didn't find a symbol with this name. See if we can find a keyword instead.
var keywordCompletion = ts.forEach(keywordCompletions, function (c) { return c.name === entryName; });
if (keywordCompletion) {
return {
name: entryName,
kind: ts.ScriptElementKind.keyword,
kindModifiers: ts.ScriptElementKindModifier.none,
displayParts: [ts.displayPart(entryName, ts.SymbolDisplayPartKind.keyword)],
documentation: undefined
};
}
return undefined;
}
Completions.getCompletionEntryDetails = getCompletionEntryDetails;
function getCompletionEntrySymbol(typeChecker, log, compilerOptions, sourceFile, position, entryName) {
// Compute all the completion symbols again.
var completionData = getCompletionData(typeChecker, log, sourceFile, position);
if (completionData) {
var symbols = completionData.symbols, location_3 = completionData.location;
// Find the symbol with the matching entry name.
// We don't need to perform character checks here because we're only comparing the
// name against 'entryName' (which is known to be good), not building a new
// completion entry.
return ts.forEach(symbols, function (s) { return getCompletionEntryDisplayNameForSymbol(typeChecker, s, compilerOptions.target, /*performCharacterChecks*/ false, location_3) === entryName ? s : undefined; });
}
return undefined;
}
Completions.getCompletionEntrySymbol = getCompletionEntrySymbol;
function getCompletionData(typeChecker, log, sourceFile, position) {
var isJavaScriptFile = ts.isSourceFileJavaScript(sourceFile);
var isJsDocTagName = false;
var start = ts.timestamp();
var currentToken = ts.getTokenAtPosition(sourceFile, position);
log("getCompletionData: Get current token: " + (ts.timestamp() - start));
start = ts.timestamp();
// Completion not allowed inside comments, bail out if this is the case
var insideComment = ts.isInsideComment(sourceFile, currentToken, position);
log("getCompletionData: Is inside comment: " + (ts.timestamp() - start));
if (insideComment) {
// The current position is next to the '@' sign, when no tag name being provided yet.
// Provide a full list of tag names
if (ts.hasDocComment(sourceFile, position) && sourceFile.text.charCodeAt(position - 1) === 64 /* at */) {
isJsDocTagName = true;
}
// Completion should work inside certain JsDoc tags. For example:
// /** @type {number | string} */
// Completion should work in the brackets
var insideJsDocTagExpression = false;
var tag = ts.getJsDocTagAtPosition(sourceFile, position);
if (tag) {
if (tag.tagName.pos <= position && position <= tag.tagName.end) {
isJsDocTagName = true;
}
switch (tag.kind) {
case 282 /* JSDocTypeTag */:
case 280 /* JSDocParameterTag */:
case 281 /* JSDocReturnTag */:
var tagWithExpression = tag;
if (tagWithExpression.typeExpression) {
insideJsDocTagExpression = tagWithExpression.typeExpression.pos < position && position < tagWithExpression.typeExpression.end;
}
break;
}
}
if (isJsDocTagName) {
return { symbols: undefined, isGlobalCompletion: false, isMemberCompletion: false, isNewIdentifierLocation: false, location: undefined, isRightOfDot: false, isJsDocTagName: isJsDocTagName };
}
if (!insideJsDocTagExpression) {
// Proceed if the current position is in jsDoc tag expression; otherwise it is a normal
// comment or the plain text part of a jsDoc comment, so no completion should be available
log("Returning an empty list because completion was inside a regular comment or plain text part of a JsDoc comment.");
return undefined;
}
}
start = ts.timestamp();
var previousToken = ts.findPrecedingToken(position, sourceFile);
log("getCompletionData: Get previous token 1: " + (ts.timestamp() - start));
// The decision to provide completion depends on the contextToken, which is determined through the previousToken.
// Note: 'previousToken' (and thus 'contextToken') can be undefined if we are the beginning of the file
var contextToken = previousToken;
// Check if the caret is at the end of an identifier; this is a partial identifier that we want to complete: e.g. a.toS|
// Skip this partial identifier and adjust the contextToken to the token that precedes it.
if (contextToken && position <= contextToken.end && ts.isWord(contextToken.kind)) {
var start_2 = ts.timestamp();
contextToken = ts.findPrecedingToken(contextToken.getFullStart(), sourceFile);
log("getCompletionData: Get previous token 2: " + (ts.timestamp() - start_2));
}
// Find the node where completion is requested on.
// Also determine whether we are trying to complete with members of that node
// or attributes of a JSX tag.
var node = currentToken;
var isRightOfDot = false;
var isRightOfOpenTag = false;
var isStartingCloseTag = false;
var location = ts.getTouchingPropertyName(sourceFile, position);
if (contextToken) {
// Bail out if this is a known invalid completion location
if (isCompletionListBlocker(contextToken)) {
log("Returning an empty list because completion was requested in an invalid position.");
return undefined;
}
var parent_15 = contextToken.parent, kind = contextToken.kind;
if (kind === 22 /* DotToken */) {
if (parent_15.kind === 177 /* PropertyAccessExpression */) {
node = contextToken.parent.expression;
isRightOfDot = true;
}
else if (parent_15.kind === 141 /* QualifiedName */) {
node = contextToken.parent.left;
isRightOfDot = true;
}
else {
// There is nothing that precedes the dot, so this likely just a stray character
// or leading into a '...' token. Just bail out instead.
return undefined;
}
}
else if (sourceFile.languageVariant === 1 /* JSX */) {
if (kind === 26 /* LessThanToken */) {
isRightOfOpenTag = true;
location = contextToken;
}
else if (kind === 40 /* SlashToken */ && contextToken.parent.kind === 249 /* JsxClosingElement */) {
isStartingCloseTag = true;
location = contextToken;
}
}
}
var semanticStart = ts.timestamp();
var isGlobalCompletion = false;
var isMemberCompletion;
var isNewIdentifierLocation;
var symbols = [];
if (isRightOfDot) {
getTypeScriptMemberSymbols();
}
else if (isRightOfOpenTag) {
var tagSymbols = typeChecker.getJsxIntrinsicTagNames();
if (tryGetGlobalSymbols()) {
symbols = tagSymbols.concat(symbols.filter(function (s) { return !!(s.flags & (107455 /* Value */ | 8388608 /* Alias */)); }));
}
else {
symbols = tagSymbols;
}
isMemberCompletion = true;
isNewIdentifierLocation = false;
}
else if (isStartingCloseTag) {
var tagName = contextToken.parent.parent.openingElement.tagName;
var tagSymbol = typeChecker.getSymbolAtLocation(tagName);
if (!typeChecker.isUnknownSymbol(tagSymbol)) {
symbols = [tagSymbol];
}
isMemberCompletion = true;
isNewIdentifierLocation = false;
}
else {
// For JavaScript or TypeScript, if we're not after a dot, then just try to get the
// global symbols in scope. These results should be valid for either language as
// the set of symbols that can be referenced from this location.
if (!tryGetGlobalSymbols()) {
return undefined;
}
}
log("getCompletionData: Semantic work: " + (ts.timestamp() - semanticStart));
return { symbols: symbols, isGlobalCompletion: isGlobalCompletion, isMemberCompletion: isMemberCompletion, isNewIdentifierLocation: isNewIdentifierLocation, location: location, isRightOfDot: (isRightOfDot || isRightOfOpenTag), isJsDocTagName: isJsDocTagName };
function getTypeScriptMemberSymbols() {
// Right of dot member completion list
isGlobalCompletion = false;
isMemberCompletion = true;
isNewIdentifierLocation = false;
if (node.kind === 70 /* Identifier */ || node.kind === 141 /* QualifiedName */ || node.kind === 177 /* PropertyAccessExpression */) {
var symbol = typeChecker.getSymbolAtLocation(node);
// This is an alias, follow what it aliases
if (symbol && symbol.flags & 8388608 /* Alias */) {
symbol = typeChecker.getAliasedSymbol(symbol);
}
if (symbol && symbol.flags & 1952 /* HasExports */) {
// Extract module or enum members
var exportedSymbols = typeChecker.getExportsOfModule(symbol);
ts.forEach(exportedSymbols, function (symbol) {
if (typeChecker.isValidPropertyAccess((node.parent), symbol.name)) {
symbols.push(symbol);
}
});
}
}
var type = typeChecker.getTypeAtLocation(node);
addTypeProperties(type);
}
function addTypeProperties(type) {
if (type) {
// Filter private properties
for (var _i = 0, _a = type.getApparentProperties(); _i < _a.length; _i++) {
var symbol = _a[_i];
if (typeChecker.isValidPropertyAccess((node.parent), symbol.name)) {
symbols.push(symbol);
}
}
if (isJavaScriptFile && type.flags & 65536 /* Union */) {
// In javascript files, for union types, we don't just get the members that
// the individual types have in common, we also include all the members that
// each individual type has. This is because we're going to add all identifiers
// anyways. So we might as well elevate the members that were at least part
// of the individual types to a higher status since we know what they are.
var unionType = type;
for (var _b = 0, _c = unionType.types; _b < _c.length; _b++) {
var elementType = _c[_b];
addTypeProperties(elementType);
}
}
}
}
function tryGetGlobalSymbols() {
var objectLikeContainer;
var namedImportsOrExports;
var jsxContainer;
if (objectLikeContainer = tryGetObjectLikeCompletionContainer(contextToken)) {
return tryGetObjectLikeCompletionSymbols(objectLikeContainer);
}
if (namedImportsOrExports = tryGetNamedImportsOrExportsForCompletion(contextToken)) {
// cursor is in an import clause
// try to show exported member for imported module
return tryGetImportOrExportClauseCompletionSymbols(namedImportsOrExports);
}
if (jsxContainer = tryGetContainingJsxElement(contextToken)) {
var attrsType = void 0;
if ((jsxContainer.kind === 247 /* JsxSelfClosingElement */) || (jsxContainer.kind === 248 /* JsxOpeningElement */)) {
// Cursor is inside a JSX self-closing element or opening element
attrsType = typeChecker.getJsxElementAttributesType(jsxContainer);
if (attrsType) {
symbols = filterJsxAttributes(typeChecker.getPropertiesOfType(attrsType), jsxContainer.attributes);
isMemberCompletion = true;
isNewIdentifierLocation = false;
return true;
}
}
}
// Get all entities in the current scope.
isMemberCompletion = false;
isNewIdentifierLocation = isNewIdentifierDefinitionLocation(contextToken);
if (previousToken !== contextToken) {
ts.Debug.assert(!!previousToken, "Expected 'contextToken' to be defined when different from 'previousToken'.");
}
// We need to find the node that will give us an appropriate scope to begin
// aggregating completion candidates. This is achieved in 'getScopeNode'
// by finding the first node that encompasses a position, accounting for whether a node
// is "complete" to decide whether a position belongs to the node.
//
// However, at the end of an identifier, we are interested in the scope of the identifier
// itself, but fall outside of the identifier. For instance:
//
// xyz => x$
//
// the cursor is outside of both the 'x' and the arrow function 'xyz => x',
// so 'xyz' is not returned in our results.
//
// We define 'adjustedPosition' so that we may appropriately account for
// being at the end of an identifier. The intention is that if requesting completion
// at the end of an identifier, it should be effectively equivalent to requesting completion
// anywhere inside/at the beginning of the identifier. So in the previous case, the
// 'adjustedPosition' will work as if requesting completion in the following:
//
// xyz => $x
//
// If previousToken !== contextToken, then
// - 'contextToken' was adjusted to the token prior to 'previousToken'
// because we were at the end of an identifier.
// - 'previousToken' is defined.
var adjustedPosition = previousToken !== contextToken ?
previousToken.getStart() :
position;
var scopeNode = getScopeNode(contextToken, adjustedPosition, sourceFile) || sourceFile;
if (scopeNode) {
isGlobalCompletion =
scopeNode.kind === 261 /* SourceFile */ ||
scopeNode.kind === 194 /* TemplateExpression */ ||
scopeNode.kind === 252 /* JsxExpression */ ||
ts.isStatement(scopeNode);
}
/// TODO filter meaning based on the current context
var symbolMeanings = 793064 /* Type */ | 107455 /* Value */ | 1920 /* Namespace */ | 8388608 /* Alias */;
symbols = typeChecker.getSymbolsInScope(scopeNode, symbolMeanings);
return true;
}
/**
* Finds the first node that "embraces" the position, so that one may
* accurately aggregate locals from the closest containing scope.
*/
function getScopeNode(initialToken, position, sourceFile) {
var scope = initialToken;
while (scope && !ts.positionBelongsToNode(scope, position, sourceFile)) {
scope = scope.parent;
}
return scope;
}
function isCompletionListBlocker(contextToken) {
var start = ts.timestamp();
var result = isInStringOrRegularExpressionOrTemplateLiteral(contextToken) ||
isSolelyIdentifierDefinitionLocation(contextToken) ||
isDotOfNumericLiteral(contextToken) ||
isInJsxText(contextToken);
log("getCompletionsAtPosition: isCompletionListBlocker: " + (ts.timestamp() - start));
return result;
}
function isInJsxText(contextToken) {
if (contextToken.kind === 10 /* JsxText */) {
return true;
}
if (contextToken.kind === 28 /* GreaterThanToken */ && contextToken.parent) {
if (contextToken.parent.kind === 248 /* JsxOpeningElement */) {
return true;
}
if (contextToken.parent.kind === 249 /* JsxClosingElement */ || contextToken.parent.kind === 247 /* JsxSelfClosingElement */) {
return contextToken.parent.parent && contextToken.parent.parent.kind === 246 /* JsxElement */;
}
}
return false;
}
function isNewIdentifierDefinitionLocation(previousToken) {
if (previousToken) {
var containingNodeKind = previousToken.parent.kind;
switch (previousToken.kind) {
case 25 /* CommaToken */:
return containingNodeKind === 179 /* CallExpression */ // func( a, |
|| containingNodeKind === 150 /* Constructor */ // constructor( a, | /* public, protected, private keywords are allowed here, so show completion */
|| containingNodeKind === 180 /* NewExpression */ // new C(a, |
|| containingNodeKind === 175 /* ArrayLiteralExpression */ // [a, |
|| containingNodeKind === 192 /* BinaryExpression */ // const x = (a, |
|| containingNodeKind === 158 /* FunctionType */; // var x: (s: string, list|
case 18 /* OpenParenToken */:
return containingNodeKind === 179 /* CallExpression */ // func( |
|| containingNodeKind === 150 /* Constructor */ // constructor( |
|| containingNodeKind === 180 /* NewExpression */ // new C(a|
|| containingNodeKind === 183 /* ParenthesizedExpression */ // const x = (a|
|| containingNodeKind === 166 /* ParenthesizedType */; // function F(pred: (a| /* this can become an arrow function, where 'a' is the argument */
case 20 /* OpenBracketToken */:
return containingNodeKind === 175 /* ArrayLiteralExpression */ // [ |
|| containingNodeKind === 155 /* IndexSignature */ // [ | : string ]
|| containingNodeKind === 142 /* ComputedPropertyName */; // [ | /* this can become an index signature */
case 127 /* ModuleKeyword */: // module |
case 128 /* NamespaceKeyword */:
return true;
case 22 /* DotToken */:
return containingNodeKind === 230 /* ModuleDeclaration */; // module A.|
case 16 /* OpenBraceToken */:
return containingNodeKind === 226 /* ClassDeclaration */; // class A{ |
case 57 /* EqualsToken */:
return containingNodeKind === 223 /* VariableDeclaration */ // const x = a|
|| containingNodeKind === 192 /* BinaryExpression */; // x = a|
case 13 /* TemplateHead */:
return containingNodeKind === 194 /* TemplateExpression */; // `aa ${|
case 14 /* TemplateMiddle */:
return containingNodeKind === 202 /* TemplateSpan */; // `aa ${10} dd ${|
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
return containingNodeKind === 147 /* PropertyDeclaration */; // class A{ public |
}
// Previous token may have been a keyword that was converted to an identifier.
switch (previousToken.getText()) {
case "public":
case "protected":
case "private":
return true;
}
}
return false;
}
function isInStringOrRegularExpressionOrTemplateLiteral(contextToken) {
if (contextToken.kind === 9 /* StringLiteral */
|| contextToken.kind === 11 /* RegularExpressionLiteral */
|| ts.isTemplateLiteralKind(contextToken.kind)) {
var start_3 = contextToken.getStart();
var end = contextToken.getEnd();
// To be "in" one of these literals, the position has to be:
// 1. entirely within the token text.
// 2. at the end position of an unterminated token.
// 3. at the end of a regular expression (due to trailing flags like '/foo/g').
if (start_3 < position && position < end) {
return true;
}
if (position === end) {
return !!contextToken.isUnterminated
|| contextToken.kind === 11 /* RegularExpressionLiteral */;
}
}
return false;
}
/**
* Aggregates relevant symbols for completion in object literals and object binding patterns.
* Relevant symbols are stored in the captured 'symbols' variable.
*
* @returns true if 'symbols' was successfully populated; false otherwise.
*/
function tryGetObjectLikeCompletionSymbols(objectLikeContainer) {
// We're looking up possible property names from contextual/inferred/declared type.
isMemberCompletion = true;
var typeForObject;
var existingMembers;
if (objectLikeContainer.kind === 176 /* ObjectLiteralExpression */) {
// We are completing on contextual types, but may also include properties
// other than those within the declared type.
isNewIdentifierLocation = true;
// If the object literal is being assigned to something of type 'null | { hello: string }',
// it clearly isn't trying to satisfy the 'null' type. So we grab the non-nullable type if possible.
typeForObject = typeChecker.getContextualType(objectLikeContainer);
typeForObject = typeForObject && typeForObject.getNonNullableType();
existingMembers = objectLikeContainer.properties;
}
else if (objectLikeContainer.kind === 172 /* ObjectBindingPattern */) {
// We are *only* completing on properties from the type being destructured.
isNewIdentifierLocation = false;
var rootDeclaration = ts.getRootDeclaration(objectLikeContainer.parent);
if (ts.isVariableLike(rootDeclaration)) {
// We don't want to complete using the type acquired by the shape
// of the binding pattern; we are only interested in types acquired
// through type declaration or inference.
// Also proceed if rootDeclaration is a parameter and if its containing function expression/arrow function is contextually typed -
// type of parameter will flow in from the contextual type of the function
var canGetType = !!(rootDeclaration.initializer || rootDeclaration.type);
if (!canGetType && rootDeclaration.kind === 144 /* Parameter */) {
if (ts.isExpression(rootDeclaration.parent)) {
canGetType = !!typeChecker.getContextualType(rootDeclaration.parent);
}
else if (rootDeclaration.parent.kind === 149 /* MethodDeclaration */ || rootDeclaration.parent.kind === 152 /* SetAccessor */) {
canGetType = ts.isExpression(rootDeclaration.parent.parent) && !!typeChecker.getContextualType(rootDeclaration.parent.parent);
}
}
if (canGetType) {
typeForObject = typeChecker.getTypeAtLocation(objectLikeContainer);
existingMembers = objectLikeContainer.elements;
}
}
else {
ts.Debug.fail("Root declaration is not variable-like.");
}
}
else {
ts.Debug.fail("Expected object literal or binding pattern, got " + objectLikeContainer.kind);
}
if (!typeForObject) {
return false;
}
var typeMembers = typeChecker.getPropertiesOfType(typeForObject);
if (typeMembers && typeMembers.length > 0) {
// Add filtered items to the completion list
symbols = filterObjectMembersList(typeMembers, existingMembers);
}
return true;
}
/**
* Aggregates relevant symbols for completion in import clauses and export clauses
* whose declarations have a module specifier; for instance, symbols will be aggregated for
*
* import { | } from "moduleName";
* export { a as foo, | } from "moduleName";
*
* but not for
*
* export { | };
*
* Relevant symbols are stored in the captured 'symbols' variable.
*
* @returns true if 'symbols' was successfully populated; false otherwise.
*/
function tryGetImportOrExportClauseCompletionSymbols(namedImportsOrExports) {
var declarationKind = namedImportsOrExports.kind === 238 /* NamedImports */ ?
235 /* ImportDeclaration */ :
241 /* ExportDeclaration */;
var importOrExportDeclaration = ts.getAncestor(namedImportsOrExports, declarationKind);
var moduleSpecifier = importOrExportDeclaration.moduleSpecifier;
if (!moduleSpecifier) {
return false;
}
isMemberCompletion = true;
isNewIdentifierLocation = false;
var exports;
var moduleSpecifierSymbol = typeChecker.getSymbolAtLocation(importOrExportDeclaration.moduleSpecifier);
if (moduleSpecifierSymbol) {
exports = typeChecker.getExportsOfModule(moduleSpecifierSymbol);
}
symbols = exports ? filterNamedImportOrExportCompletionItems(exports, namedImportsOrExports.elements) : ts.emptyArray;
return true;
}
/**
* Returns the immediate owning object literal or binding pattern of a context token,
* on the condition that one exists and that the context implies completion should be given.
*/
function tryGetObjectLikeCompletionContainer(contextToken) {
if (contextToken) {
switch (contextToken.kind) {
case 16 /* OpenBraceToken */: // const x = { |
case 25 /* CommaToken */:
var parent_16 = contextToken.parent;
if (parent_16 && (parent_16.kind === 176 /* ObjectLiteralExpression */ || parent_16.kind === 172 /* ObjectBindingPattern */)) {
return parent_16;
}
break;
}
}
return undefined;
}
/**
* Returns the containing list of named imports or exports of a context token,
* on the condition that one exists and that the context implies completion should be given.
*/
function tryGetNamedImportsOrExportsForCompletion(contextToken) {
if (contextToken) {
switch (contextToken.kind) {
case 16 /* OpenBraceToken */: // import { |
case 25 /* CommaToken */:
switch (contextToken.parent.kind) {
case 238 /* NamedImports */:
case 242 /* NamedExports */:
return contextToken.parent;
}
}
}
return undefined;
}
function tryGetContainingJsxElement(contextToken) {
if (contextToken) {
var parent_17 = contextToken.parent;
switch (contextToken.kind) {
case 27 /* LessThanSlashToken */:
case 40 /* SlashToken */:
case 70 /* Identifier */:
case 250 /* JsxAttribute */:
case 251 /* JsxSpreadAttribute */:
if (parent_17 && (parent_17.kind === 247 /* JsxSelfClosingElement */ || parent_17.kind === 248 /* JsxOpeningElement */)) {
return parent_17;
}
else if (parent_17.kind === 250 /* JsxAttribute */) {
return parent_17.parent;
}
break;
// The context token is the closing } or " of an attribute, which means
// its parent is a JsxExpression, whose parent is a JsxAttribute,
// whose parent is a JsxOpeningLikeElement
case 9 /* StringLiteral */:
if (parent_17 && ((parent_17.kind === 250 /* JsxAttribute */) || (parent_17.kind === 251 /* JsxSpreadAttribute */))) {
return parent_17.parent;
}
break;
case 17 /* CloseBraceToken */:
if (parent_17 &&
parent_17.kind === 252 /* JsxExpression */ &&
parent_17.parent &&
(parent_17.parent.kind === 250 /* JsxAttribute */)) {
return parent_17.parent.parent;
}
if (parent_17 && parent_17.kind === 251 /* JsxSpreadAttribute */) {
return parent_17.parent;
}
break;
}
}
return undefined;
}
function isFunction(kind) {
switch (kind) {
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 225 /* FunctionDeclaration */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 155 /* IndexSignature */:
return true;
}
return false;
}
/**
* @returns true if we are certain that the currently edited location must define a new location; false otherwise.
*/
function isSolelyIdentifierDefinitionLocation(contextToken) {
var containingNodeKind = contextToken.parent.kind;
switch (contextToken.kind) {
case 25 /* CommaToken */:
return containingNodeKind === 223 /* VariableDeclaration */ ||
containingNodeKind === 224 /* VariableDeclarationList */ ||
containingNodeKind === 205 /* VariableStatement */ ||
containingNodeKind === 229 /* EnumDeclaration */ ||
isFunction(containingNodeKind) ||
containingNodeKind === 226 /* ClassDeclaration */ ||
containingNodeKind === 197 /* ClassExpression */ ||
containingNodeKind === 227 /* InterfaceDeclaration */ ||
containingNodeKind === 173 /* ArrayBindingPattern */ ||
containingNodeKind === 228 /* TypeAliasDeclaration */; // type Map, K, |
case 22 /* DotToken */:
return containingNodeKind === 173 /* ArrayBindingPattern */; // var [.|
case 55 /* ColonToken */:
return containingNodeKind === 174 /* BindingElement */; // var {x :html|
case 20 /* OpenBracketToken */:
return containingNodeKind === 173 /* ArrayBindingPattern */; // var [x|
case 18 /* OpenParenToken */:
return containingNodeKind === 256 /* CatchClause */ ||
isFunction(containingNodeKind);
case 16 /* OpenBraceToken */:
return containingNodeKind === 229 /* EnumDeclaration */ ||
containingNodeKind === 227 /* InterfaceDeclaration */ ||
containingNodeKind === 161 /* TypeLiteral */; // const x : { |
case 24 /* SemicolonToken */:
return containingNodeKind === 146 /* PropertySignature */ &&
contextToken.parent && contextToken.parent.parent &&
(contextToken.parent.parent.kind === 227 /* InterfaceDeclaration */ ||
contextToken.parent.parent.kind === 161 /* TypeLiteral */); // const x : { a; |
case 26 /* LessThanToken */:
return containingNodeKind === 226 /* ClassDeclaration */ ||
containingNodeKind === 197 /* ClassExpression */ ||
containingNodeKind === 227 /* InterfaceDeclaration */ ||
containingNodeKind === 228 /* TypeAliasDeclaration */ ||
isFunction(containingNodeKind);
case 114 /* StaticKeyword */:
return containingNodeKind === 147 /* PropertyDeclaration */;
case 23 /* DotDotDotToken */:
return containingNodeKind === 144 /* Parameter */ ||
(contextToken.parent && contextToken.parent.parent &&
contextToken.parent.parent.kind === 173 /* ArrayBindingPattern */); // var [...z|
case 113 /* PublicKeyword */:
case 111 /* PrivateKeyword */:
case 112 /* ProtectedKeyword */:
return containingNodeKind === 144 /* Parameter */;
case 117 /* AsKeyword */:
return containingNodeKind === 239 /* ImportSpecifier */ ||
containingNodeKind === 243 /* ExportSpecifier */ ||
containingNodeKind === 237 /* NamespaceImport */;
case 74 /* ClassKeyword */:
case 82 /* EnumKeyword */:
case 108 /* InterfaceKeyword */:
case 88 /* FunctionKeyword */:
case 103 /* VarKeyword */:
case 124 /* GetKeyword */:
case 133 /* SetKeyword */:
case 90 /* ImportKeyword */:
case 109 /* LetKeyword */:
case 75 /* ConstKeyword */:
case 115 /* YieldKeyword */:
case 136 /* TypeKeyword */:
return true;
}
// Previous token may have been a keyword that was converted to an identifier.
switch (contextToken.getText()) {
case "abstract":
case "async":
case "class":
case "const":
case "declare":
case "enum":
case "function":
case "interface":
case "let":
case "private":
case "protected":
case "public":
case "static":
case "var":
case "yield":
return true;
}
return false;
}
function isDotOfNumericLiteral(contextToken) {
if (contextToken.kind === 8 /* NumericLiteral */) {
var text = contextToken.getFullText();
return text.charAt(text.length - 1) === ".";
}
return false;
}
/**
* Filters out completion suggestions for named imports or exports.
*
* @param exportsOfModule The list of symbols which a module exposes.
* @param namedImportsOrExports The list of existing import/export specifiers in the import/export clause.
*
* @returns Symbols to be suggested at an import/export clause, barring those whose named imports/exports
* do not occur at the current position and have not otherwise been typed.
*/
function filterNamedImportOrExportCompletionItems(exportsOfModule, namedImportsOrExports) {
var existingImportsOrExports = ts.createMap();
for (var _i = 0, namedImportsOrExports_1 = namedImportsOrExports; _i < namedImportsOrExports_1.length; _i++) {
var element = namedImportsOrExports_1[_i];
// If this is the current item we are editing right now, do not filter it out
if (element.getStart() <= position && position <= element.getEnd()) {
continue;
}
var name_43 = element.propertyName || element.name;
existingImportsOrExports[name_43.text] = true;
}
if (!ts.someProperties(existingImportsOrExports)) {
return ts.filter(exportsOfModule, function (e) { return e.name !== "default"; });
}
return ts.filter(exportsOfModule, function (e) { return e.name !== "default" && !existingImportsOrExports[e.name]; });
}
/**
* Filters out completion suggestions for named imports or exports.
*
* @returns Symbols to be suggested in an object binding pattern or object literal expression, barring those whose declarations
* do not occur at the current position and have not otherwise been typed.
*/
function filterObjectMembersList(contextualMemberSymbols, existingMembers) {
if (!existingMembers || existingMembers.length === 0) {
return contextualMemberSymbols;
}
var existingMemberNames = ts.createMap();
for (var _i = 0, existingMembers_1 = existingMembers; _i < existingMembers_1.length; _i++) {
var m = existingMembers_1[_i];
// Ignore omitted expressions for missing members
if (m.kind !== 257 /* PropertyAssignment */ &&
m.kind !== 258 /* ShorthandPropertyAssignment */ &&
m.kind !== 174 /* BindingElement */ &&
m.kind !== 149 /* MethodDeclaration */ &&
m.kind !== 151 /* GetAccessor */ &&
m.kind !== 152 /* SetAccessor */) {
continue;
}
// If this is the current item we are editing right now, do not filter it out
if (m.getStart() <= position && position <= m.getEnd()) {
continue;
}
var existingName = void 0;
if (m.kind === 174 /* BindingElement */ && m.propertyName) {
// include only identifiers in completion list
if (m.propertyName.kind === 70 /* Identifier */) {
existingName = m.propertyName.text;
}
}
else {
// TODO(jfreeman): Account for computed property name
// NOTE: if one only performs this step when m.name is an identifier,
// things like '__proto__' are not filtered out.
existingName = m.name.text;
}
existingMemberNames[existingName] = true;
}
return ts.filter(contextualMemberSymbols, function (m) { return !existingMemberNames[m.name]; });
}
/**
* Filters out completion suggestions from 'symbols' according to existing JSX attributes.
*
* @returns Symbols to be suggested in a JSX element, barring those whose attributes
* do not occur at the current position and have not otherwise been typed.
*/
function filterJsxAttributes(symbols, attributes) {
var seenNames = ts.createMap();
for (var _i = 0, attributes_1 = attributes; _i < attributes_1.length; _i++) {
var attr = attributes_1[_i];
// If this is the current item we are editing right now, do not filter it out
if (attr.getStart() <= position && position <= attr.getEnd()) {
continue;
}
if (attr.kind === 250 /* JsxAttribute */) {
seenNames[attr.name.text] = true;
}
}
return ts.filter(symbols, function (a) { return !seenNames[a.name]; });
}
}
/**
* Get the name to be display in completion from a given symbol.
*
* @return undefined if the name is of external module otherwise a name with striped of any quote
*/
function getCompletionEntryDisplayNameForSymbol(typeChecker, symbol, target, performCharacterChecks, location) {
var displayName = ts.getDeclaredName(typeChecker, symbol, location);
if (displayName) {
var firstCharCode = displayName.charCodeAt(0);
// First check of the displayName is not external module; if it is an external module, it is not valid entry
if ((symbol.flags & 1920 /* Namespace */) && (firstCharCode === 39 /* singleQuote */ || firstCharCode === 34 /* doubleQuote */)) {
// If the symbol is external module, don't show it in the completion list
// (i.e declare module "http" { const x; } | // <= request completion here, "http" should not be there)
return undefined;
}
}
return getCompletionEntryDisplayName(displayName, target, performCharacterChecks);
}
/**
* Get a displayName from a given for completion list, performing any necessary quotes stripping
* and checking whether the name is valid identifier name.
*/
function getCompletionEntryDisplayName(name, target, performCharacterChecks) {
if (!name) {
return undefined;
}
name = ts.stripQuotes(name);
if (!name) {
return undefined;
}
// If the user entered name for the symbol was quoted, removing the quotes is not enough, as the name could be an
// invalid identifier name. We need to check if whatever was inside the quotes is actually a valid identifier name.
// e.g "b a" is valid quoted name but when we strip off the quotes, it is invalid.
// We, thus, need to check if whatever was inside the quotes is actually a valid identifier name.
if (performCharacterChecks) {
if (!ts.isIdentifierText(name, target)) {
return undefined;
}
}
return name;
}
// A cache of completion entries for keywords, these do not change between sessions
var keywordCompletions = [];
for (var i = 71 /* FirstKeyword */; i <= 140 /* LastKeyword */; i++) {
keywordCompletions.push({
name: ts.tokenToString(i),
kind: ts.ScriptElementKind.keyword,
kindModifiers: ts.ScriptElementKindModifier.none,
sortText: "0"
});
}
/**
* Matches a triple slash reference directive with an incomplete string literal for its path. Used
* to determine if the caret is currently within the string literal and capture the literal fragment
* for completions.
* For example, this matches
*
* /// <reference path="fragment
*
* but not
*
* /// <reference path="fragment"
*/
var tripleSlashDirectiveFragmentRegex = /^(\/\/\/\s*<reference\s+(path|types)\s*=\s*(?:'|"))([^\3"]*)$/;
var nodeModulesDependencyKeys = ["dependencies", "devDependencies", "peerDependencies", "optionalDependencies"];
function tryGetDirectories(host, directoryName) {
return tryIOAndConsumeErrors(host, host.getDirectories, directoryName);
}
function tryReadDirectory(host, path, extensions, exclude, include) {
return tryIOAndConsumeErrors(host, host.readDirectory, path, extensions, exclude, include);
}
function tryReadFile(host, path) {
return tryIOAndConsumeErrors(host, host.readFile, path);
}
function tryFileExists(host, path) {
return tryIOAndConsumeErrors(host, host.fileExists, path);
}
function tryDirectoryExists(host, path) {
try {
return ts.directoryProbablyExists(path, host);
}
catch (e) { }
return undefined;
}
function tryIOAndConsumeErrors(host, toApply) {
var args = [];
for (var _i = 2; _i < arguments.length; _i++) {
args[_i - 2] = arguments[_i];
}
try {
return toApply && toApply.apply(host, args);
}
catch (e) { }
return undefined;
}
})(Completions = ts.Completions || (ts.Completions = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var DocumentHighlights;
(function (DocumentHighlights) {
function getDocumentHighlights(typeChecker, cancellationToken, sourceFile, position, sourceFilesToSearch) {
var node = ts.getTouchingWord(sourceFile, position);
if (!node) {
return undefined;
}
return getSemanticDocumentHighlights(node) || getSyntacticDocumentHighlights(node);
function getHighlightSpanForNode(node) {
var start = node.getStart();
var end = node.getEnd();
return {
fileName: sourceFile.fileName,
textSpan: ts.createTextSpanFromBounds(start, end),
kind: ts.HighlightSpanKind.none
};
}
function getSemanticDocumentHighlights(node) {
if (node.kind === 70 /* Identifier */ ||
node.kind === 98 /* ThisKeyword */ ||
node.kind === 167 /* ThisType */ ||
node.kind === 96 /* SuperKeyword */ ||
node.kind === 9 /* StringLiteral */ ||
ts.isLiteralNameOfPropertyDeclarationOrIndexAccess(node)) {
var referencedSymbols = ts.FindAllReferences.getReferencedSymbolsForNode(typeChecker, cancellationToken, node, sourceFilesToSearch, /*findInStrings*/ false, /*findInComments*/ false, /*implementations*/ false);
return convertReferencedSymbols(referencedSymbols);
}
return undefined;
function convertReferencedSymbols(referencedSymbols) {
if (!referencedSymbols) {
return undefined;
}
var fileNameToDocumentHighlights = ts.createMap();
var result = [];
for (var _i = 0, referencedSymbols_1 = referencedSymbols; _i < referencedSymbols_1.length; _i++) {
var referencedSymbol = referencedSymbols_1[_i];
for (var _a = 0, _b = referencedSymbol.references; _a < _b.length; _a++) {
var referenceEntry = _b[_a];
var fileName = referenceEntry.fileName;
var documentHighlights = fileNameToDocumentHighlights[fileName];
if (!documentHighlights) {
documentHighlights = { fileName: fileName, highlightSpans: [] };
fileNameToDocumentHighlights[fileName] = documentHighlights;
result.push(documentHighlights);
}
documentHighlights.highlightSpans.push({
textSpan: referenceEntry.textSpan,
kind: referenceEntry.isWriteAccess ? ts.HighlightSpanKind.writtenReference : ts.HighlightSpanKind.reference
});
}
}
return result;
}
}
function getSyntacticDocumentHighlights(node) {
var fileName = sourceFile.fileName;
var highlightSpans = getHighlightSpans(node);
if (!highlightSpans || highlightSpans.length === 0) {
return undefined;
}
return [{ fileName: fileName, highlightSpans: highlightSpans }];
// returns true if 'node' is defined and has a matching 'kind'.
function hasKind(node, kind) {
return node !== undefined && node.kind === kind;
}
// Null-propagating 'parent' function.
function parent(node) {
return node && node.parent;
}
function getHighlightSpans(node) {
if (node) {
switch (node.kind) {
case 89 /* IfKeyword */:
case 81 /* ElseKeyword */:
if (hasKind(node.parent, 208 /* IfStatement */)) {
return getIfElseOccurrences(node.parent);
}
break;
case 95 /* ReturnKeyword */:
if (hasKind(node.parent, 216 /* ReturnStatement */)) {
return getReturnOccurrences(node.parent);
}
break;
case 99 /* ThrowKeyword */:
if (hasKind(node.parent, 220 /* ThrowStatement */)) {
return getThrowOccurrences(node.parent);
}
break;
case 73 /* CatchKeyword */:
if (hasKind(parent(parent(node)), 221 /* TryStatement */)) {
return getTryCatchFinallyOccurrences(node.parent.parent);
}
break;
case 101 /* TryKeyword */:
case 86 /* FinallyKeyword */:
if (hasKind(parent(node), 221 /* TryStatement */)) {
return getTryCatchFinallyOccurrences(node.parent);
}
break;
case 97 /* SwitchKeyword */:
if (hasKind(node.parent, 218 /* SwitchStatement */)) {
return getSwitchCaseDefaultOccurrences(node.parent);
}
break;
case 72 /* CaseKeyword */:
case 78 /* DefaultKeyword */:
if (hasKind(parent(parent(parent(node))), 218 /* SwitchStatement */)) {
return getSwitchCaseDefaultOccurrences(node.parent.parent.parent);
}
break;
case 71 /* BreakKeyword */:
case 76 /* ContinueKeyword */:
if (hasKind(node.parent, 215 /* BreakStatement */) || hasKind(node.parent, 214 /* ContinueStatement */)) {
return getBreakOrContinueStatementOccurrences(node.parent);
}
break;
case 87 /* ForKeyword */:
if (hasKind(node.parent, 211 /* ForStatement */) ||
hasKind(node.parent, 212 /* ForInStatement */) ||
hasKind(node.parent, 213 /* ForOfStatement */)) {
return getLoopBreakContinueOccurrences(node.parent);
}
break;
case 105 /* WhileKeyword */:
case 80 /* DoKeyword */:
if (hasKind(node.parent, 210 /* WhileStatement */) || hasKind(node.parent, 209 /* DoStatement */)) {
return getLoopBreakContinueOccurrences(node.parent);
}
break;
case 122 /* ConstructorKeyword */:
if (hasKind(node.parent, 150 /* Constructor */)) {
return getConstructorOccurrences(node.parent);
}
break;
case 124 /* GetKeyword */:
case 133 /* SetKeyword */:
if (hasKind(node.parent, 151 /* GetAccessor */) || hasKind(node.parent, 152 /* SetAccessor */)) {
return getGetAndSetOccurrences(node.parent);
}
break;
default:
if (ts.isModifierKind(node.kind) && node.parent &&
(ts.isDeclaration(node.parent) || node.parent.kind === 205 /* VariableStatement */)) {
return getModifierOccurrences(node.kind, node.parent);
}
}
}
return undefined;
}
/**
* Aggregates all throw-statements within this node *without* crossing
* into function boundaries and try-blocks with catch-clauses.
*/
function aggregateOwnedThrowStatements(node) {
var statementAccumulator = [];
aggregate(node);
return statementAccumulator;
function aggregate(node) {
if (node.kind === 220 /* ThrowStatement */) {
statementAccumulator.push(node);
}
else if (node.kind === 221 /* TryStatement */) {
var tryStatement = node;
if (tryStatement.catchClause) {
aggregate(tryStatement.catchClause);
}
else {
// Exceptions thrown within a try block lacking a catch clause
// are "owned" in the current context.
aggregate(tryStatement.tryBlock);
}
if (tryStatement.finallyBlock) {
aggregate(tryStatement.finallyBlock);
}
}
else if (!ts.isFunctionLike(node)) {
ts.forEachChild(node, aggregate);
}
}
}
/**
* For lack of a better name, this function takes a throw statement and returns the
* nearest ancestor that is a try-block (whose try statement has a catch clause),
* function-block, or source file.
*/
function getThrowStatementOwner(throwStatement) {
var child = throwStatement;
while (child.parent) {
var parent_18 = child.parent;
if (ts.isFunctionBlock(parent_18) || parent_18.kind === 261 /* SourceFile */) {
return parent_18;
}
// A throw-statement is only owned by a try-statement if the try-statement has
// a catch clause, and if the throw-statement occurs within the try block.
if (parent_18.kind === 221 /* TryStatement */) {
var tryStatement = parent_18;
if (tryStatement.tryBlock === child && tryStatement.catchClause) {
return child;
}
}
child = parent_18;
}
return undefined;
}
function aggregateAllBreakAndContinueStatements(node) {
var statementAccumulator = [];
aggregate(node);
return statementAccumulator;
function aggregate(node) {
if (node.kind === 215 /* BreakStatement */ || node.kind === 214 /* ContinueStatement */) {
statementAccumulator.push(node);
}
else if (!ts.isFunctionLike(node)) {
ts.forEachChild(node, aggregate);
}
}
}
function ownsBreakOrContinueStatement(owner, statement) {
var actualOwner = getBreakOrContinueOwner(statement);
return actualOwner && actualOwner === owner;
}
function getBreakOrContinueOwner(statement) {
for (var node_1 = statement.parent; node_1; node_1 = node_1.parent) {
switch (node_1.kind) {
case 218 /* SwitchStatement */:
if (statement.kind === 214 /* ContinueStatement */) {
continue;
}
// Fall through.
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 210 /* WhileStatement */:
case 209 /* DoStatement */:
if (!statement.label || isLabeledBy(node_1, statement.label.text)) {
return node_1;
}
break;
default:
// Don't cross function boundaries.
if (ts.isFunctionLike(node_1)) {
return undefined;
}
break;
}
}
return undefined;
}
function getModifierOccurrences(modifier, declaration) {
var container = declaration.parent;
// Make sure we only highlight the keyword when it makes sense to do so.
if (ts.isAccessibilityModifier(modifier)) {
if (!(container.kind === 226 /* ClassDeclaration */ ||
container.kind === 197 /* ClassExpression */ ||
(declaration.kind === 144 /* Parameter */ && hasKind(container, 150 /* Constructor */)))) {
return undefined;
}
}
else if (modifier === 114 /* StaticKeyword */) {
if (!(container.kind === 226 /* ClassDeclaration */ || container.kind === 197 /* ClassExpression */)) {
return undefined;
}
}
else if (modifier === 83 /* ExportKeyword */ || modifier === 123 /* DeclareKeyword */) {
if (!(container.kind === 231 /* ModuleBlock */ || container.kind === 261 /* SourceFile */)) {
return undefined;
}
}
else if (modifier === 116 /* AbstractKeyword */) {
if (!(container.kind === 226 /* ClassDeclaration */ || declaration.kind === 226 /* ClassDeclaration */)) {
return undefined;
}
}
else {
// unsupported modifier
return undefined;
}
var keywords = [];
var modifierFlag = getFlagFromModifier(modifier);
var nodes;
switch (container.kind) {
case 231 /* ModuleBlock */:
case 261 /* SourceFile */:
// Container is either a class declaration or the declaration is a classDeclaration
if (modifierFlag & 128 /* Abstract */) {
nodes = declaration.members.concat(declaration);
}
else {
nodes = container.statements;
}
break;
case 150 /* Constructor */:
nodes = container.parameters.concat(container.parent.members);
break;
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
nodes = container.members;
// If we're an accessibility modifier, we're in an instance member and should search
// the constructor's parameter list for instance members as well.
if (modifierFlag & 28 /* AccessibilityModifier */) {
var constructor = ts.forEach(container.members, function (member) {
return member.kind === 150 /* Constructor */ && member;
});
if (constructor) {
nodes = nodes.concat(constructor.parameters);
}
}
else if (modifierFlag & 128 /* Abstract */) {
nodes = nodes.concat(container);
}
break;
default:
ts.Debug.fail("Invalid container kind.");
}
ts.forEach(nodes, function (node) {
if (ts.getModifierFlags(node) & modifierFlag) {
ts.forEach(node.modifiers, function (child) { return pushKeywordIf(keywords, child, modifier); });
}
});
return ts.map(keywords, getHighlightSpanForNode);
function getFlagFromModifier(modifier) {
switch (modifier) {
case 113 /* PublicKeyword */:
return 4 /* Public */;
case 111 /* PrivateKeyword */:
return 8 /* Private */;
case 112 /* ProtectedKeyword */:
return 16 /* Protected */;
case 114 /* StaticKeyword */:
return 32 /* Static */;
case 83 /* ExportKeyword */:
return 1 /* Export */;
case 123 /* DeclareKeyword */:
return 2 /* Ambient */;
case 116 /* AbstractKeyword */:
return 128 /* Abstract */;
default:
ts.Debug.fail();
}
}
}
function pushKeywordIf(keywordList, token) {
var expected = [];
for (var _i = 2; _i < arguments.length; _i++) {
expected[_i - 2] = arguments[_i];
}
if (token && ts.contains(expected, token.kind)) {
keywordList.push(token);
return true;
}
return false;
}
function getGetAndSetOccurrences(accessorDeclaration) {
var keywords = [];
tryPushAccessorKeyword(accessorDeclaration.symbol, 151 /* GetAccessor */);
tryPushAccessorKeyword(accessorDeclaration.symbol, 152 /* SetAccessor */);
return ts.map(keywords, getHighlightSpanForNode);
function tryPushAccessorKeyword(accessorSymbol, accessorKind) {
var accessor = ts.getDeclarationOfKind(accessorSymbol, accessorKind);
if (accessor) {
ts.forEach(accessor.getChildren(), function (child) { return pushKeywordIf(keywords, child, 124 /* GetKeyword */, 133 /* SetKeyword */); });
}
}
}
function getConstructorOccurrences(constructorDeclaration) {
var declarations = constructorDeclaration.symbol.getDeclarations();
var keywords = [];
ts.forEach(declarations, function (declaration) {
ts.forEach(declaration.getChildren(), function (token) {
return pushKeywordIf(keywords, token, 122 /* ConstructorKeyword */);
});
});
return ts.map(keywords, getHighlightSpanForNode);
}
function getLoopBreakContinueOccurrences(loopNode) {
var keywords = [];
if (pushKeywordIf(keywords, loopNode.getFirstToken(), 87 /* ForKeyword */, 105 /* WhileKeyword */, 80 /* DoKeyword */)) {
// If we succeeded and got a do-while loop, then start looking for a 'while' keyword.
if (loopNode.kind === 209 /* DoStatement */) {
var loopTokens = loopNode.getChildren();
for (var i = loopTokens.length - 1; i >= 0; i--) {
if (pushKeywordIf(keywords, loopTokens[i], 105 /* WhileKeyword */)) {
break;
}
}
}
}
var breaksAndContinues = aggregateAllBreakAndContinueStatements(loopNode.statement);
ts.forEach(breaksAndContinues, function (statement) {
if (ownsBreakOrContinueStatement(loopNode, statement)) {
pushKeywordIf(keywords, statement.getFirstToken(), 71 /* BreakKeyword */, 76 /* ContinueKeyword */);
}
});
return ts.map(keywords, getHighlightSpanForNode);
}
function getBreakOrContinueStatementOccurrences(breakOrContinueStatement) {
var owner = getBreakOrContinueOwner(breakOrContinueStatement);
if (owner) {
switch (owner.kind) {
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 209 /* DoStatement */:
case 210 /* WhileStatement */:
return getLoopBreakContinueOccurrences(owner);
case 218 /* SwitchStatement */:
return getSwitchCaseDefaultOccurrences(owner);
}
}
return undefined;
}
function getSwitchCaseDefaultOccurrences(switchStatement) {
var keywords = [];
pushKeywordIf(keywords, switchStatement.getFirstToken(), 97 /* SwitchKeyword */);
// Go through each clause in the switch statement, collecting the 'case'/'default' keywords.
ts.forEach(switchStatement.caseBlock.clauses, function (clause) {
pushKeywordIf(keywords, clause.getFirstToken(), 72 /* CaseKeyword */, 78 /* DefaultKeyword */);
var breaksAndContinues = aggregateAllBreakAndContinueStatements(clause);
ts.forEach(breaksAndContinues, function (statement) {
if (ownsBreakOrContinueStatement(switchStatement, statement)) {
pushKeywordIf(keywords, statement.getFirstToken(), 71 /* BreakKeyword */);
}
});
});
return ts.map(keywords, getHighlightSpanForNode);
}
function getTryCatchFinallyOccurrences(tryStatement) {
var keywords = [];
pushKeywordIf(keywords, tryStatement.getFirstToken(), 101 /* TryKeyword */);
if (tryStatement.catchClause) {
pushKeywordIf(keywords, tryStatement.catchClause.getFirstToken(), 73 /* CatchKeyword */);
}
if (tryStatement.finallyBlock) {
var finallyKeyword = ts.findChildOfKind(tryStatement, 86 /* FinallyKeyword */, sourceFile);
pushKeywordIf(keywords, finallyKeyword, 86 /* FinallyKeyword */);
}
return ts.map(keywords, getHighlightSpanForNode);
}
function getThrowOccurrences(throwStatement) {
var owner = getThrowStatementOwner(throwStatement);
if (!owner) {
return undefined;
}
var keywords = [];
ts.forEach(aggregateOwnedThrowStatements(owner), function (throwStatement) {
pushKeywordIf(keywords, throwStatement.getFirstToken(), 99 /* ThrowKeyword */);
});
// If the "owner" is a function, then we equate 'return' and 'throw' statements in their
// ability to "jump out" of the function, and include occurrences for both.
if (ts.isFunctionBlock(owner)) {
ts.forEachReturnStatement(owner, function (returnStatement) {
pushKeywordIf(keywords, returnStatement.getFirstToken(), 95 /* ReturnKeyword */);
});
}
return ts.map(keywords, getHighlightSpanForNode);
}
function getReturnOccurrences(returnStatement) {
var func = ts.getContainingFunction(returnStatement);
// If we didn't find a containing function with a block body, bail out.
if (!(func && hasKind(func.body, 204 /* Block */))) {
return undefined;
}
var keywords = [];
ts.forEachReturnStatement(func.body, function (returnStatement) {
pushKeywordIf(keywords, returnStatement.getFirstToken(), 95 /* ReturnKeyword */);
});
// Include 'throw' statements that do not occur within a try block.
ts.forEach(aggregateOwnedThrowStatements(func.body), function (throwStatement) {
pushKeywordIf(keywords, throwStatement.getFirstToken(), 99 /* ThrowKeyword */);
});
return ts.map(keywords, getHighlightSpanForNode);
}
function getIfElseOccurrences(ifStatement) {
var keywords = [];
// Traverse upwards through all parent if-statements linked by their else-branches.
while (hasKind(ifStatement.parent, 208 /* IfStatement */) && ifStatement.parent.elseStatement === ifStatement) {
ifStatement = ifStatement.parent;
}
// Now traverse back down through the else branches, aggregating if/else keywords of if-statements.
while (ifStatement) {
var children = ifStatement.getChildren();
pushKeywordIf(keywords, children[0], 89 /* IfKeyword */);
// Generally the 'else' keyword is second-to-last, so we traverse backwards.
for (var i = children.length - 1; i >= 0; i--) {
if (pushKeywordIf(keywords, children[i], 81 /* ElseKeyword */)) {
break;
}
}
if (!hasKind(ifStatement.elseStatement, 208 /* IfStatement */)) {
break;
}
ifStatement = ifStatement.elseStatement;
}
var result = [];
// We'd like to highlight else/ifs together if they are only separated by whitespace
// (i.e. the keywords are separated by no comments, no newlines).
for (var i = 0; i < keywords.length; i++) {
if (keywords[i].kind === 81 /* ElseKeyword */ && i < keywords.length - 1) {
var elseKeyword = keywords[i];
var ifKeyword = keywords[i + 1]; // this *should* always be an 'if' keyword.
var shouldCombindElseAndIf = true;
// Avoid recalculating getStart() by iterating backwards.
for (var j = ifKeyword.getStart() - 1; j >= elseKeyword.end; j--) {
if (!ts.isWhiteSpaceSingleLine(sourceFile.text.charCodeAt(j))) {
shouldCombindElseAndIf = false;
break;
}
}
if (shouldCombindElseAndIf) {
result.push({
fileName: fileName,
textSpan: ts.createTextSpanFromBounds(elseKeyword.getStart(), ifKeyword.end),
kind: ts.HighlightSpanKind.reference
});
i++; // skip the next keyword
continue;
}
}
// Ordinary case: just highlight the keyword.
result.push(getHighlightSpanForNode(keywords[i]));
}
return result;
}
}
}
DocumentHighlights.getDocumentHighlights = getDocumentHighlights;
/**
* Whether or not a 'node' is preceded by a label of the given string.
* Note: 'node' cannot be a SourceFile.
*/
function isLabeledBy(node, labelName) {
for (var owner = node.parent; owner.kind === 219 /* LabeledStatement */; owner = owner.parent) {
if (owner.label.text === labelName) {
return true;
}
}
return false;
}
})(DocumentHighlights = ts.DocumentHighlights || (ts.DocumentHighlights = {}));
})(ts || (ts = {}));
var ts;
(function (ts) {
function createDocumentRegistry(useCaseSensitiveFileNames, currentDirectory) {
if (currentDirectory === void 0) { currentDirectory = ""; }
// Maps from compiler setting target (ES3, ES5, etc.) to all the cached documents we have
// for those settings.
var buckets = ts.createMap();
var getCanonicalFileName = ts.createGetCanonicalFileName(!!useCaseSensitiveFileNames);
function getKeyForCompilationSettings(settings) {
return "_" + settings.target + "|" + settings.module + "|" + settings.noResolve + "|" + settings.jsx + "|" + settings.allowJs + "|" + settings.baseUrl + "|" + JSON.stringify(settings.typeRoots) + "|" + JSON.stringify(settings.rootDirs) + "|" + JSON.stringify(settings.paths);
}
function getBucketForCompilationSettings(key, createIfMissing) {
var bucket = buckets[key];
if (!bucket && createIfMissing) {
buckets[key] = bucket = ts.createFileMap();
}
return bucket;
}
function reportStats() {
var bucketInfoArray = Object.keys(buckets).filter(function (name) { return name && name.charAt(0) === "_"; }).map(function (name) {
var entries = buckets[name];
var sourceFiles = [];
entries.forEachValue(function (key, entry) {
sourceFiles.push({
name: key,
refCount: entry.languageServiceRefCount,
references: entry.owners.slice(0)
});
});
sourceFiles.sort(function (x, y) { return y.refCount - x.refCount; });
return {
bucket: name,
sourceFiles: sourceFiles
};
});
return JSON.stringify(bucketInfoArray, undefined, 2);
}
function acquireDocument(fileName, compilationSettings, scriptSnapshot, version, scriptKind) {
var path = ts.toPath(fileName, currentDirectory, getCanonicalFileName);
var key = getKeyForCompilationSettings(compilationSettings);
return acquireDocumentWithKey(fileName, path, compilationSettings, key, scriptSnapshot, version, scriptKind);
}
function acquireDocumentWithKey(fileName, path, compilationSettings, key, scriptSnapshot, version, scriptKind) {
return acquireOrUpdateDocument(fileName, path, compilationSettings, key, scriptSnapshot, version, /*acquiring*/ true, scriptKind);
}
function updateDocument(fileName, compilationSettings, scriptSnapshot, version, scriptKind) {
var path = ts.toPath(fileName, currentDirectory, getCanonicalFileName);
var key = getKeyForCompilationSettings(compilationSettings);
return updateDocumentWithKey(fileName, path, compilationSettings, key, scriptSnapshot, version, scriptKind);
}
function updateDocumentWithKey(fileName, path, compilationSettings, key, scriptSnapshot, version, scriptKind) {
return acquireOrUpdateDocument(fileName, path, compilationSettings, key, scriptSnapshot, version, /*acquiring*/ false, scriptKind);
}
function acquireOrUpdateDocument(fileName, path, compilationSettings, key, scriptSnapshot, version, acquiring, scriptKind) {
var bucket = getBucketForCompilationSettings(key, /*createIfMissing*/ true);
var entry = bucket.get(path);
if (!entry) {
ts.Debug.assert(acquiring, "How could we be trying to update a document that the registry doesn't have?");
// Have never seen this file with these settings. Create a new source file for it.
var sourceFile = ts.createLanguageServiceSourceFile(fileName, scriptSnapshot, compilationSettings.target, version, /*setNodeParents*/ false, scriptKind);
entry = {
sourceFile: sourceFile,
languageServiceRefCount: 0,
owners: []
};
bucket.set(path, entry);
}
else {
// We have an entry for this file. However, it may be for a different version of
// the script snapshot. If so, update it appropriately. Otherwise, we can just
// return it as is.
if (entry.sourceFile.version !== version) {
entry.sourceFile = ts.updateLanguageServiceSourceFile(entry.sourceFile, scriptSnapshot, version, scriptSnapshot.getChangeRange(entry.sourceFile.scriptSnapshot));
}
}
// If we're acquiring, then this is the first time this LS is asking for this document.
// Increase our ref count so we know there's another LS using the document. If we're
// not acquiring, then that means the LS is 'updating' the file instead, and that means
// it has already acquired the document previously. As such, we do not need to increase
// the ref count.
if (acquiring) {
entry.languageServiceRefCount++;
}
return entry.sourceFile;
}
function releaseDocument(fileName, compilationSettings) {
var path = ts.toPath(fileName, currentDirectory, getCanonicalFileName);
var key = getKeyForCompilationSettings(compilationSettings);
return releaseDocumentWithKey(path, key);
}
function releaseDocumentWithKey(path, key) {
var bucket = getBucketForCompilationSettings(key, /*createIfMissing*/ false);
ts.Debug.assert(bucket !== undefined);
var entry = bucket.get(path);
entry.languageServiceRefCount--;
ts.Debug.assert(entry.languageServiceRefCount >= 0);
if (entry.languageServiceRefCount === 0) {
bucket.remove(path);
}
}
return {
acquireDocument: acquireDocument,
acquireDocumentWithKey: acquireDocumentWithKey,
updateDocument: updateDocument,
updateDocumentWithKey: updateDocumentWithKey,
releaseDocument: releaseDocument,
releaseDocumentWithKey: releaseDocumentWithKey,
reportStats: reportStats,
getKeyForCompilationSettings: getKeyForCompilationSettings
};
}
ts.createDocumentRegistry = createDocumentRegistry;
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var FindAllReferences;
(function (FindAllReferences) {
function findReferencedSymbols(typeChecker, cancellationToken, sourceFiles, sourceFile, position, findInStrings, findInComments) {
var node = ts.getTouchingPropertyName(sourceFile, position, /*includeJsDocComment*/ true);
if (node === sourceFile) {
return undefined;
}
switch (node.kind) {
case 8 /* NumericLiteral */:
if (!ts.isLiteralNameOfPropertyDeclarationOrIndexAccess(node)) {
break;
}
// Fallthrough
case 70 /* Identifier */:
case 98 /* ThisKeyword */:
// case SyntaxKind.SuperKeyword: TODO:GH#9268
case 122 /* ConstructorKeyword */:
case 9 /* StringLiteral */:
return getReferencedSymbolsForNode(typeChecker, cancellationToken, node, sourceFiles, findInStrings, findInComments, /*implementations*/ false);
}
return undefined;
}
FindAllReferences.findReferencedSymbols = findReferencedSymbols;
function getReferencedSymbolsForNode(typeChecker, cancellationToken, node, sourceFiles, findInStrings, findInComments, implementations) {
if (!implementations) {
// Labels
if (ts.isLabelName(node)) {
if (ts.isJumpStatementTarget(node)) {
var labelDefinition = ts.getTargetLabel(node.parent, node.text);
// if we have a label definition, look within its statement for references, if not, then
// the label is undefined and we have no results..
return labelDefinition ? getLabelReferencesInNode(labelDefinition.parent, labelDefinition) : undefined;
}
else {
// it is a label definition and not a target, search within the parent labeledStatement
return getLabelReferencesInNode(node.parent, node);
}
}
if (ts.isThis(node)) {
return getReferencesForThisKeyword(node, sourceFiles);
}
if (node.kind === 96 /* SuperKeyword */) {
return getReferencesForSuperKeyword(node);
}
}
// `getSymbolAtLocation` normally returns the symbol of the class when given the constructor keyword,
// so we have to specify that we want the constructor symbol.
var symbol = typeChecker.getSymbolAtLocation(node);
if (!implementations && !symbol && node.kind === 9 /* StringLiteral */) {
return getReferencesForStringLiteral(node, sourceFiles);
}
// Could not find a symbol e.g. unknown identifier
if (!symbol) {
// Can't have references to something that we have no symbol for.
return undefined;
}
var declarations = symbol.declarations;
// The symbol was an internal symbol and does not have a declaration e.g. undefined symbol
if (!declarations || !declarations.length) {
return undefined;
}
var result;
// Compute the meaning from the location and the symbol it references
var searchMeaning = getIntersectingMeaningFromDeclarations(ts.getMeaningFromLocation(node), declarations);
// Get the text to search for.
// Note: if this is an external module symbol, the name doesn't include quotes.
var declaredName = ts.stripQuotes(ts.getDeclaredName(typeChecker, symbol, node));
// Try to get the smallest valid scope that we can limit our search to;
// otherwise we'll need to search globally (i.e. include each file).
var scope = getSymbolScope(symbol);
// Maps from a symbol ID to the ReferencedSymbol entry in 'result'.
var symbolToIndex = [];
if (scope) {
result = [];
getReferencesInNode(scope, symbol, declaredName, node, searchMeaning, findInStrings, findInComments, result, symbolToIndex);
}
else {
var internedName = getInternedName(symbol, node);
for (var _i = 0, sourceFiles_8 = sourceFiles; _i < sourceFiles_8.length; _i++) {
var sourceFile = sourceFiles_8[_i];
cancellationToken.throwIfCancellationRequested();
var nameTable = ts.getNameTable(sourceFile);
if (nameTable[internedName] !== undefined) {
result = result || [];
getReferencesInNode(sourceFile, symbol, declaredName, node, searchMeaning, findInStrings, findInComments, result, symbolToIndex);
}
}
}
return result;
function getDefinition(symbol) {
var info = ts.SymbolDisplay.getSymbolDisplayPartsDocumentationAndSymbolKind(typeChecker, symbol, node.getSourceFile(), ts.getContainerNode(node), node);
var name = ts.map(info.displayParts, function (p) { return p.text; }).join("");
var declarations = symbol.declarations;
if (!declarations || declarations.length === 0) {
return undefined;
}
return {
containerKind: "",
containerName: "",
name: name,
kind: info.symbolKind,
fileName: declarations[0].getSourceFile().fileName,
textSpan: ts.createTextSpan(declarations[0].getStart(), 0),
displayParts: info.displayParts
};
}
function getAliasSymbolForPropertyNameSymbol(symbol, location) {
if (symbol.flags & 8388608 /* Alias */) {
// Default import get alias
var defaultImport = ts.getDeclarationOfKind(symbol, 236 /* ImportClause */);
if (defaultImport) {
return typeChecker.getAliasedSymbol(symbol);
}
var importOrExportSpecifier = ts.forEach(symbol.declarations, function (declaration) { return (declaration.kind === 239 /* ImportSpecifier */ ||
declaration.kind === 243 /* ExportSpecifier */) ? declaration : undefined; });
if (importOrExportSpecifier &&
// export { a }
(!importOrExportSpecifier.propertyName ||
// export {a as class } where a is location
importOrExportSpecifier.propertyName === location)) {
// If Import specifier -> get alias
// else Export specifier -> get local target
return importOrExportSpecifier.kind === 239 /* ImportSpecifier */ ?
typeChecker.getAliasedSymbol(symbol) :
typeChecker.getExportSpecifierLocalTargetSymbol(importOrExportSpecifier);
}
}
return undefined;
}
function followAliasIfNecessary(symbol, location) {
return getAliasSymbolForPropertyNameSymbol(symbol, location) || symbol;
}
function getPropertySymbolOfDestructuringAssignment(location) {
return ts.isArrayLiteralOrObjectLiteralDestructuringPattern(location.parent.parent) &&
typeChecker.getPropertySymbolOfDestructuringAssignment(location);
}
function isObjectBindingPatternElementWithoutPropertyName(symbol) {
var bindingElement = ts.getDeclarationOfKind(symbol, 174 /* BindingElement */);
return bindingElement &&
bindingElement.parent.kind === 172 /* ObjectBindingPattern */ &&
!bindingElement.propertyName;
}
function getPropertySymbolOfObjectBindingPatternWithoutPropertyName(symbol) {
if (isObjectBindingPatternElementWithoutPropertyName(symbol)) {
var bindingElement = ts.getDeclarationOfKind(symbol, 174 /* BindingElement */);
var typeOfPattern = typeChecker.getTypeAtLocation(bindingElement.parent);
return typeOfPattern && typeChecker.getPropertyOfType(typeOfPattern, bindingElement.name.text);
}
return undefined;
}
function getInternedName(symbol, location) {
// If this is an export or import specifier it could have been renamed using the 'as' syntax.
// If so we want to search for whatever under the cursor.
if (ts.isImportOrExportSpecifierName(location)) {
return location.getText();
}
// Try to get the local symbol if we're dealing with an 'export default'
// since that symbol has the "true" name.
var localExportDefaultSymbol = ts.getLocalSymbolForExportDefault(symbol);
symbol = localExportDefaultSymbol || symbol;
return ts.stripQuotes(symbol.name);
}
/**
* Determines the smallest scope in which a symbol may have named references.
* Note that not every construct has been accounted for. This function can
* probably be improved.
*
* @returns undefined if the scope cannot be determined, implying that
* a reference to a symbol can occur anywhere.
*/
function getSymbolScope(symbol) {
// If this is the symbol of a named function expression or named class expression,
// then named references are limited to its own scope.
var valueDeclaration = symbol.valueDeclaration;
if (valueDeclaration && (valueDeclaration.kind === 184 /* FunctionExpression */ || valueDeclaration.kind === 197 /* ClassExpression */)) {
return valueDeclaration;
}
// If this is private property or method, the scope is the containing class
if (symbol.flags & (4 /* Property */ | 8192 /* Method */)) {
var privateDeclaration = ts.forEach(symbol.getDeclarations(), function (d) { return (ts.getModifierFlags(d) & 8 /* Private */) ? d : undefined; });
if (privateDeclaration) {
return ts.getAncestor(privateDeclaration, 226 /* ClassDeclaration */);
}
}
// If the symbol is an import we would like to find it if we are looking for what it imports.
// So consider it visible outside its declaration scope.
if (symbol.flags & 8388608 /* Alias */) {
return undefined;
}
// If symbol is of object binding pattern element without property name we would want to
// look for property too and that could be anywhere
if (isObjectBindingPatternElementWithoutPropertyName(symbol)) {
return undefined;
}
// if this symbol is visible from its parent container, e.g. exported, then bail out
// if symbol correspond to the union property - bail out
if (symbol.parent || (symbol.flags & 268435456 /* SyntheticProperty */)) {
return undefined;
}
var scope;
var declarations = symbol.getDeclarations();
if (declarations) {
for (var _i = 0, declarations_7 = declarations; _i < declarations_7.length; _i++) {
var declaration = declarations_7[_i];
var container = ts.getContainerNode(declaration);
if (!container) {
return undefined;
}
if (scope && scope !== container) {
// Different declarations have different containers, bail out
return undefined;
}
if (container.kind === 261 /* SourceFile */ && !ts.isExternalModule(container)) {
// This is a global variable and not an external module, any declaration defined
// within this scope is visible outside the file
return undefined;
}
// The search scope is the container node
scope = container;
}
}
return scope;
}
function getPossibleSymbolReferencePositions(sourceFile, symbolName, start, end) {
var positions = [];
/// TODO: Cache symbol existence for files to save text search
// Also, need to make this work for unicode escapes.
// Be resilient in the face of a symbol with no name or zero length name
if (!symbolName || !symbolName.length) {
return positions;
}
var text = sourceFile.text;
var sourceLength = text.length;
var symbolNameLength = symbolName.length;
var position = text.indexOf(symbolName, start);
while (position >= 0) {
cancellationToken.throwIfCancellationRequested();
// If we are past the end, stop looking
if (position > end)
break;
// We found a match. Make sure it's not part of a larger word (i.e. the char
// before and after it have to be a non-identifier char).
var endPosition = position + symbolNameLength;
if ((position === 0 || !ts.isIdentifierPart(text.charCodeAt(position - 1), 5 /* Latest */)) &&
(endPosition === sourceLength || !ts.isIdentifierPart(text.charCodeAt(endPosition), 5 /* Latest */))) {
// Found a real match. Keep searching.
positions.push(position);
}
position = text.indexOf(symbolName, position + symbolNameLength + 1);
}
return positions;
}
function getLabelReferencesInNode(container, targetLabel) {
var references = [];
var sourceFile = container.getSourceFile();
var labelName = targetLabel.text;
var possiblePositions = getPossibleSymbolReferencePositions(sourceFile, labelName, container.getStart(), container.getEnd());
ts.forEach(possiblePositions, function (position) {
cancellationToken.throwIfCancellationRequested();
var node = ts.getTouchingWord(sourceFile, position);
if (!node || node.getWidth() !== labelName.length) {
return;
}
// Only pick labels that are either the target label, or have a target that is the target label
if (node === targetLabel ||
(ts.isJumpStatementTarget(node) && ts.getTargetLabel(node, labelName) === targetLabel)) {
references.push(getReferenceEntryFromNode(node));
}
});
var definition = {
containerKind: "",
containerName: "",
fileName: targetLabel.getSourceFile().fileName,
kind: ts.ScriptElementKind.label,
name: labelName,
textSpan: ts.createTextSpanFromBounds(targetLabel.getStart(), targetLabel.getEnd()),
displayParts: [ts.displayPart(labelName, ts.SymbolDisplayPartKind.text)]
};
return [{ definition: definition, references: references }];
}
function isValidReferencePosition(node, searchSymbolName) {
if (node) {
// Compare the length so we filter out strict superstrings of the symbol we are looking for
switch (node.kind) {
case 70 /* Identifier */:
return node.getWidth() === searchSymbolName.length;
case 9 /* StringLiteral */:
if (ts.isLiteralNameOfPropertyDeclarationOrIndexAccess(node) ||
isNameOfExternalModuleImportOrDeclaration(node)) {
// For string literals we have two additional chars for the quotes
return node.getWidth() === searchSymbolName.length + 2;
}
break;
case 8 /* NumericLiteral */:
if (ts.isLiteralNameOfPropertyDeclarationOrIndexAccess(node)) {
return node.getWidth() === searchSymbolName.length;
}
break;
}
}
return false;
}
/** Search within node "container" for references for a search value, where the search value is defined as a
* tuple of(searchSymbol, searchText, searchLocation, and searchMeaning).
* searchLocation: a node where the search value
*/
function getReferencesInNode(container, searchSymbol, searchText, searchLocation, searchMeaning, findInStrings, findInComments, result, symbolToIndex) {
var sourceFile = container.getSourceFile();
var start = findInComments ? container.getFullStart() : container.getStart();
var possiblePositions = getPossibleSymbolReferencePositions(sourceFile, searchText, start, container.getEnd());
var parents = getParentSymbolsOfPropertyAccess();
var inheritsFromCache = ts.createMap();
if (possiblePositions.length) {
// Build the set of symbols to search for, initially it has only the current symbol
var searchSymbols_1 = populateSearchSymbolSet(searchSymbol, searchLocation);
ts.forEach(possiblePositions, function (position) {
cancellationToken.throwIfCancellationRequested();
var referenceLocation = ts.getTouchingPropertyName(sourceFile, position);
if (!isValidReferencePosition(referenceLocation, searchText)) {
// This wasn't the start of a token. Check to see if it might be a
// match in a comment or string if that's what the caller is asking
// for.
if (!implementations && ((findInStrings && ts.isInString(sourceFile, position)) ||
(findInComments && ts.isInNonReferenceComment(sourceFile, position)))) {
// In the case where we're looking inside comments/strings, we don't have
// an actual definition. So just use 'undefined' here. Features like
// 'Rename' won't care (as they ignore the definitions), and features like
// 'FindReferences' will just filter out these results.
result.push({
definition: undefined,
references: [{
fileName: sourceFile.fileName,
textSpan: ts.createTextSpan(position, searchText.length),
isWriteAccess: false,
isDefinition: false
}]
});
}
return;
}
if (!(ts.getMeaningFromLocation(referenceLocation) & searchMeaning)) {
return;
}
var referenceSymbol = typeChecker.getSymbolAtLocation(referenceLocation);
if (referenceSymbol) {
var referenceSymbolDeclaration = referenceSymbol.valueDeclaration;
var shorthandValueSymbol = typeChecker.getShorthandAssignmentValueSymbol(referenceSymbolDeclaration);
var relatedSymbol = getRelatedSymbol(searchSymbols_1, referenceSymbol, referenceLocation,
/*searchLocationIsConstructor*/ searchLocation.kind === 122 /* ConstructorKeyword */, parents, inheritsFromCache);
if (relatedSymbol) {
addReferenceToRelatedSymbol(referenceLocation, relatedSymbol);
}
else if (!(referenceSymbol.flags & 67108864 /* Transient */) && searchSymbols_1.indexOf(shorthandValueSymbol) >= 0) {
addReferenceToRelatedSymbol(referenceSymbolDeclaration.name, shorthandValueSymbol);
}
else if (searchLocation.kind === 122 /* ConstructorKeyword */) {
findAdditionalConstructorReferences(referenceSymbol, referenceLocation);
}
}
});
}
return;
/* If we are just looking for implementations and this is a property access expression, we need to get the
* symbol of the local type of the symbol the property is being accessed on. This is because our search
* symbol may have a different parent symbol if the local type's symbol does not declare the property
* being accessed (i.e. it is declared in some parent class or interface)
*/
function getParentSymbolsOfPropertyAccess() {
if (implementations) {
var propertyAccessExpression = getPropertyAccessExpressionFromRightHandSide(searchLocation);
if (propertyAccessExpression) {
var localParentType = typeChecker.getTypeAtLocation(propertyAccessExpression.expression);
if (localParentType) {
if (localParentType.symbol && localParentType.symbol.flags & (32 /* Class */ | 64 /* Interface */) && localParentType.symbol !== searchSymbol.parent) {
return [localParentType.symbol];
}
else if (localParentType.flags & 196608 /* UnionOrIntersection */) {
return getSymbolsForClassAndInterfaceComponents(localParentType);
}
}
}
}
}
function getPropertyAccessExpressionFromRightHandSide(node) {
return ts.isRightSideOfPropertyAccess(node) && node.parent;
}
/** Adds references when a constructor is used with `new this()` in its own class and `super()` calls in subclasses. */
function findAdditionalConstructorReferences(referenceSymbol, referenceLocation) {
ts.Debug.assert(ts.isClassLike(searchSymbol.valueDeclaration));
var referenceClass = referenceLocation.parent;
if (referenceSymbol === searchSymbol && ts.isClassLike(referenceClass)) {
ts.Debug.assert(referenceClass.name === referenceLocation);
// This is the class declaration containing the constructor.
addReferences(findOwnConstructorCalls(searchSymbol));
}
else {
// If this class appears in `extends C`, then the extending class' "super" calls are references.
var classExtending = tryGetClassByExtendingIdentifier(referenceLocation);
if (classExtending && ts.isClassLike(classExtending) && followAliasIfNecessary(referenceSymbol, referenceLocation) === searchSymbol) {
addReferences(superConstructorAccesses(classExtending));
}
}
}
function addReferences(references) {
if (references.length) {
var referencedSymbol = getReferencedSymbol(searchSymbol);
ts.addRange(referencedSymbol.references, ts.map(references, getReferenceEntryFromNode));
}
}
/** `classSymbol` is the class where the constructor was defined.
* Reference the constructor and all calls to `new this()`.
*/
function findOwnConstructorCalls(classSymbol) {
var result = [];
for (var _i = 0, _a = classSymbol.members["__constructor"].declarations; _i < _a.length; _i++) {
var decl = _a[_i];
ts.Debug.assert(decl.kind === 150 /* Constructor */);
var ctrKeyword = decl.getChildAt(0);
ts.Debug.assert(ctrKeyword.kind === 122 /* ConstructorKeyword */);
result.push(ctrKeyword);
}
ts.forEachProperty(classSymbol.exports, function (member) {
var decl = member.valueDeclaration;
if (decl && decl.kind === 149 /* MethodDeclaration */) {
var body = decl.body;
if (body) {
forEachDescendantOfKind(body, 98 /* ThisKeyword */, function (thisKeyword) {
if (ts.isNewExpressionTarget(thisKeyword)) {
result.push(thisKeyword);
}
});
}
}
});
return result;
}
/** Find references to `super` in the constructor of an extending class. */
function superConstructorAccesses(cls) {
var symbol = cls.symbol;
var ctr = symbol.members["__constructor"];
if (!ctr) {
return [];
}
var result = [];
for (var _i = 0, _a = ctr.declarations; _i < _a.length; _i++) {
var decl = _a[_i];
ts.Debug.assert(decl.kind === 150 /* Constructor */);
var body = decl.body;
if (body) {
forEachDescendantOfKind(body, 96 /* SuperKeyword */, function (node) {
if (ts.isCallExpressionTarget(node)) {
result.push(node);
}
});
}
}
;
return result;
}
function getReferencedSymbol(symbol) {
var symbolId = ts.getSymbolId(symbol);
var index = symbolToIndex[symbolId];
if (index === undefined) {
index = result.length;
symbolToIndex[symbolId] = index;
result.push({
definition: getDefinition(symbol),
references: []
});
}
return result[index];
}
function addReferenceToRelatedSymbol(node, relatedSymbol) {
var references = getReferencedSymbol(relatedSymbol).references;
if (implementations) {
getImplementationReferenceEntryForNode(node, references);
}
else {
references.push(getReferenceEntryFromNode(node));
}
}
}
function getImplementationReferenceEntryForNode(refNode, result) {
// Check if we found a function/propertyAssignment/method with an implementation or initializer
if (ts.isDeclarationName(refNode) && isImplementation(refNode.parent)) {
result.push(getReferenceEntryFromNode(refNode.parent));
}
else if (refNode.kind === 70 /* Identifier */) {
if (refNode.parent.kind === 258 /* ShorthandPropertyAssignment */) {
// Go ahead and dereference the shorthand assignment by going to its definition
getReferenceEntriesForShorthandPropertyAssignment(refNode, typeChecker, result);
}
// Check if the node is within an extends or implements clause
var containingClass = getContainingClassIfInHeritageClause(refNode);
if (containingClass) {
result.push(getReferenceEntryFromNode(containingClass));
return;
}
// If we got a type reference, try and see if the reference applies to any expressions that can implement an interface
var containingTypeReference = getContainingTypeReference(refNode);
if (containingTypeReference) {
var parent_19 = containingTypeReference.parent;
if (ts.isVariableLike(parent_19) && parent_19.type === containingTypeReference && parent_19.initializer && isImplementationExpression(parent_19.initializer)) {
maybeAdd(getReferenceEntryFromNode(parent_19.initializer));
}
else if (ts.isFunctionLike(parent_19) && parent_19.type === containingTypeReference && parent_19.body) {
if (parent_19.body.kind === 204 /* Block */) {
ts.forEachReturnStatement(parent_19.body, function (returnStatement) {
if (returnStatement.expression && isImplementationExpression(returnStatement.expression)) {
maybeAdd(getReferenceEntryFromNode(returnStatement.expression));
}
});
}
else if (isImplementationExpression(parent_19.body)) {
maybeAdd(getReferenceEntryFromNode(parent_19.body));
}
}
else if (ts.isAssertionExpression(parent_19) && isImplementationExpression(parent_19.expression)) {
maybeAdd(getReferenceEntryFromNode(parent_19.expression));
}
}
}
// Type nodes can contain multiple references to the same type. For example:
// let x: Foo & (Foo & Bar) = ...
// Because we are returning the implementation locations and not the identifier locations,
// duplicate entries would be returned here as each of the type references is part of
// the same implementation. For that reason, check before we add a new entry
function maybeAdd(a) {
if (!ts.forEach(result, function (b) { return a.fileName === b.fileName && a.textSpan.start === b.textSpan.start && a.textSpan.length === b.textSpan.length; })) {
result.push(a);
}
}
}
function getSymbolsForClassAndInterfaceComponents(type, result) {
if (result === void 0) { result = []; }
for (var _i = 0, _a = type.types; _i < _a.length; _i++) {
var componentType = _a[_i];
if (componentType.symbol && componentType.symbol.getFlags() & (32 /* Class */ | 64 /* Interface */)) {
result.push(componentType.symbol);
}
if (componentType.getFlags() & 196608 /* UnionOrIntersection */) {
getSymbolsForClassAndInterfaceComponents(componentType, result);
}
}
return result;
}
function getContainingTypeReference(node) {
var topLevelTypeReference = undefined;
while (node) {
if (ts.isTypeNode(node)) {
topLevelTypeReference = node;
}
node = node.parent;
}
return topLevelTypeReference;
}
function getContainingClassIfInHeritageClause(node) {
if (node && node.parent) {
if (node.kind === 199 /* ExpressionWithTypeArguments */
&& node.parent.kind === 255 /* HeritageClause */
&& ts.isClassLike(node.parent.parent)) {
return node.parent.parent;
}
else if (node.kind === 70 /* Identifier */ || node.kind === 177 /* PropertyAccessExpression */) {
return getContainingClassIfInHeritageClause(node.parent);
}
}
return undefined;
}
/**
* Returns true if this is an expression that can be considered an implementation
*/
function isImplementationExpression(node) {
// Unwrap parentheses
if (node.kind === 183 /* ParenthesizedExpression */) {
return isImplementationExpression(node.expression);
}
return node.kind === 185 /* ArrowFunction */ ||
node.kind === 184 /* FunctionExpression */ ||
node.kind === 176 /* ObjectLiteralExpression */ ||
node.kind === 197 /* ClassExpression */ ||
node.kind === 175 /* ArrayLiteralExpression */;
}
/**
* Determines if the parent symbol occurs somewhere in the child's ancestry. If the parent symbol
* is an interface, determines if some ancestor of the child symbol extends or inherits from it.
* Also takes in a cache of previous results which makes this slightly more efficient and is
* necessary to avoid potential loops like so:
* class A extends B { }
* class B extends A { }
*
* We traverse the AST rather than using the type checker because users are typically only interested
* in explicit implementations of an interface/class when calling "Go to Implementation". Sibling
* implementations of types that share a common ancestor with the type whose implementation we are
* searching for need to be filtered out of the results. The type checker doesn't let us make the
* distinction between structurally compatible implementations and explicit implementations, so we
* must use the AST.
*
* @param child A class or interface Symbol
* @param parent Another class or interface Symbol
* @param cachedResults A map of symbol id pairs (i.e. "child,parent") to booleans indicating previous results
*/
function explicitlyInheritsFrom(child, parent, cachedResults) {
var parentIsInterface = parent.getFlags() & 64 /* Interface */;
return searchHierarchy(child);
function searchHierarchy(symbol) {
if (symbol === parent) {
return true;
}
var key = ts.getSymbolId(symbol) + "," + ts.getSymbolId(parent);
if (key in cachedResults) {
return cachedResults[key];
}
// Set the key so that we don't infinitely recurse
cachedResults[key] = false;
var inherits = ts.forEach(symbol.getDeclarations(), function (declaration) {
if (ts.isClassLike(declaration)) {
if (parentIsInterface) {
var interfaceReferences = ts.getClassImplementsHeritageClauseElements(declaration);
if (interfaceReferences) {
for (var _i = 0, interfaceReferences_1 = interfaceReferences; _i < interfaceReferences_1.length; _i++) {
var typeReference = interfaceReferences_1[_i];
if (searchTypeReference(typeReference)) {
return true;
}
}
}
}
return searchTypeReference(ts.getClassExtendsHeritageClauseElement(declaration));
}
else if (declaration.kind === 227 /* InterfaceDeclaration */) {
if (parentIsInterface) {
return ts.forEach(ts.getInterfaceBaseTypeNodes(declaration), searchTypeReference);
}
}
return false;
});
cachedResults[key] = inherits;
return inherits;
}
function searchTypeReference(typeReference) {
if (typeReference) {
var type = typeChecker.getTypeAtLocation(typeReference);
if (type && type.symbol) {
return searchHierarchy(type.symbol);
}
}
return false;
}
}
function getReferencesForSuperKeyword(superKeyword) {
var searchSpaceNode = ts.getSuperContainer(superKeyword, /*stopOnFunctions*/ false);
if (!searchSpaceNode) {
return undefined;
}
// Whether 'super' occurs in a static context within a class.
var staticFlag = 32 /* Static */;
switch (searchSpaceNode.kind) {
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
staticFlag &= ts.getModifierFlags(searchSpaceNode);
searchSpaceNode = searchSpaceNode.parent; // re-assign to be the owning class
break;
default:
return undefined;
}
var references = [];
var sourceFile = searchSpaceNode.getSourceFile();
var possiblePositions = getPossibleSymbolReferencePositions(sourceFile, "super", searchSpaceNode.getStart(), searchSpaceNode.getEnd());
ts.forEach(possiblePositions, function (position) {
cancellationToken.throwIfCancellationRequested();
var node = ts.getTouchingWord(sourceFile, position);
if (!node || node.kind !== 96 /* SuperKeyword */) {
return;
}
var container = ts.getSuperContainer(node, /*stopOnFunctions*/ false);
// If we have a 'super' container, we must have an enclosing class.
// Now make sure the owning class is the same as the search-space
// and has the same static qualifier as the original 'super's owner.
if (container && (32 /* Static */ & ts.getModifierFlags(container)) === staticFlag && container.parent.symbol === searchSpaceNode.symbol) {
references.push(getReferenceEntryFromNode(node));
}
});
var definition = getDefinition(searchSpaceNode.symbol);
return [{ definition: definition, references: references }];
}
function getReferencesForThisKeyword(thisOrSuperKeyword, sourceFiles) {
var searchSpaceNode = ts.getThisContainer(thisOrSuperKeyword, /* includeArrowFunctions */ false);
// Whether 'this' occurs in a static context within a class.
var staticFlag = 32 /* Static */;
switch (searchSpaceNode.kind) {
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
if (ts.isObjectLiteralMethod(searchSpaceNode)) {
break;
}
// fall through
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
staticFlag &= ts.getModifierFlags(searchSpaceNode);
searchSpaceNode = searchSpaceNode.parent; // re-assign to be the owning class
break;
case 261 /* SourceFile */:
if (ts.isExternalModule(searchSpaceNode)) {
return undefined;
}
// Fall through
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
break;
// Computed properties in classes are not handled here because references to this are illegal,
// so there is no point finding references to them.
default:
return undefined;
}
var references = [];
var possiblePositions;
if (searchSpaceNode.kind === 261 /* SourceFile */) {
ts.forEach(sourceFiles, function (sourceFile) {
possiblePositions = getPossibleSymbolReferencePositions(sourceFile, "this", sourceFile.getStart(), sourceFile.getEnd());
getThisReferencesInFile(sourceFile, sourceFile, possiblePositions, references);
});
}
else {
var sourceFile = searchSpaceNode.getSourceFile();
possiblePositions = getPossibleSymbolReferencePositions(sourceFile, "this", searchSpaceNode.getStart(), searchSpaceNode.getEnd());
getThisReferencesInFile(sourceFile, searchSpaceNode, possiblePositions, references);
}
var thisOrSuperSymbol = typeChecker.getSymbolAtLocation(thisOrSuperKeyword);
var displayParts = thisOrSuperSymbol && ts.SymbolDisplay.getSymbolDisplayPartsDocumentationAndSymbolKind(typeChecker, thisOrSuperSymbol, thisOrSuperKeyword.getSourceFile(), ts.getContainerNode(thisOrSuperKeyword), thisOrSuperKeyword).displayParts;
return [{
definition: {
containerKind: "",
containerName: "",
fileName: node.getSourceFile().fileName,
kind: ts.ScriptElementKind.variableElement,
name: "this",
textSpan: ts.createTextSpanFromBounds(node.getStart(), node.getEnd()),
displayParts: displayParts
},
references: references
}];
function getThisReferencesInFile(sourceFile, searchSpaceNode, possiblePositions, result) {
ts.forEach(possiblePositions, function (position) {
cancellationToken.throwIfCancellationRequested();
var node = ts.getTouchingWord(sourceFile, position);
if (!node || !ts.isThis(node)) {
return;
}
var container = ts.getThisContainer(node, /* includeArrowFunctions */ false);
switch (searchSpaceNode.kind) {
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
if (searchSpaceNode.symbol === container.symbol) {
result.push(getReferenceEntryFromNode(node));
}
break;
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
if (ts.isObjectLiteralMethod(searchSpaceNode) && searchSpaceNode.symbol === container.symbol) {
result.push(getReferenceEntryFromNode(node));
}
break;
case 197 /* ClassExpression */:
case 226 /* ClassDeclaration */:
// Make sure the container belongs to the same class
// and has the appropriate static modifier from the original container.
if (container.parent && searchSpaceNode.symbol === container.parent.symbol && (ts.getModifierFlags(container) & 32 /* Static */) === staticFlag) {
result.push(getReferenceEntryFromNode(node));
}
break;
case 261 /* SourceFile */:
if (container.kind === 261 /* SourceFile */ && !ts.isExternalModule(container)) {
result.push(getReferenceEntryFromNode(node));
}
break;
}
});
}
}
function getReferencesForStringLiteral(node, sourceFiles) {
var type = ts.getStringLiteralTypeForNode(node, typeChecker);
if (!type) {
// nothing to do here. moving on
return undefined;
}
var references = [];
for (var _i = 0, sourceFiles_9 = sourceFiles; _i < sourceFiles_9.length; _i++) {
var sourceFile = sourceFiles_9[_i];
var possiblePositions = getPossibleSymbolReferencePositions(sourceFile, type.text, sourceFile.getStart(), sourceFile.getEnd());
getReferencesForStringLiteralInFile(sourceFile, type, possiblePositions, references);
}
return [{
definition: {
containerKind: "",
containerName: "",
fileName: node.getSourceFile().fileName,
kind: ts.ScriptElementKind.variableElement,
name: type.text,
textSpan: ts.createTextSpanFromBounds(node.getStart(), node.getEnd()),
displayParts: [ts.displayPart(ts.getTextOfNode(node), ts.SymbolDisplayPartKind.stringLiteral)]
},
references: references
}];
function getReferencesForStringLiteralInFile(sourceFile, searchType, possiblePositions, references) {
for (var _i = 0, possiblePositions_1 = possiblePositions; _i < possiblePositions_1.length; _i++) {
var position = possiblePositions_1[_i];
cancellationToken.throwIfCancellationRequested();
var node_2 = ts.getTouchingWord(sourceFile, position);
if (!node_2 || node_2.kind !== 9 /* StringLiteral */) {
return;
}
var type_2 = ts.getStringLiteralTypeForNode(node_2, typeChecker);
if (type_2 === searchType) {
references.push(getReferenceEntryFromNode(node_2));
}
}
}
}
function populateSearchSymbolSet(symbol, location) {
// The search set contains at least the current symbol
var result = [symbol];
// If the location is name of property symbol from object literal destructuring pattern
// Search the property symbol
// for ( { property: p2 } of elems) { }
var containingObjectLiteralElement = getContainingObjectLiteralElement(location);
if (containingObjectLiteralElement && containingObjectLiteralElement.kind !== 258 /* ShorthandPropertyAssignment */) {
var propertySymbol = getPropertySymbolOfDestructuringAssignment(location);
if (propertySymbol) {
result.push(propertySymbol);
}
}
// If the symbol is an alias, add what it aliases to the list
// import {a} from "mod";
// export {a}
// If the symbol is an alias to default declaration, add what it aliases to the list
// declare "mod" { export default class B { } }
// import B from "mod";
//// For export specifiers, the exported name can be referring to a local symbol, e.g.:
//// import {a} from "mod";
//// export {a as somethingElse}
//// We want the *local* declaration of 'a' as declared in the import,
//// *not* as declared within "mod" (or farther)
var aliasSymbol = getAliasSymbolForPropertyNameSymbol(symbol, location);
if (aliasSymbol) {
result = result.concat(populateSearchSymbolSet(aliasSymbol, location));
}
// If the location is in a context sensitive location (i.e. in an object literal) try
// to get a contextual type for it, and add the property symbol from the contextual
// type to the search set
if (containingObjectLiteralElement) {
ts.forEach(getPropertySymbolsFromContextualType(containingObjectLiteralElement), function (contextualSymbol) {
ts.addRange(result, typeChecker.getRootSymbols(contextualSymbol));
});
/* Because in short-hand property assignment, location has two meaning : property name and as value of the property
* When we do findAllReference at the position of the short-hand property assignment, we would want to have references to position of
* property name and variable declaration of the identifier.
* Like in below example, when querying for all references for an identifier 'name', of the property assignment, the language service
* should show both 'name' in 'obj' and 'name' in variable declaration
* const name = "Foo";
* const obj = { name };
* In order to do that, we will populate the search set with the value symbol of the identifier as a value of the property assignment
* so that when matching with potential reference symbol, both symbols from property declaration and variable declaration
* will be included correctly.
*/
var shorthandValueSymbol = typeChecker.getShorthandAssignmentValueSymbol(location.parent);
if (shorthandValueSymbol) {
result.push(shorthandValueSymbol);
}
}
// If the symbol.valueDeclaration is a property parameter declaration,
// we should include both parameter declaration symbol and property declaration symbol
// Parameter Declaration symbol is only visible within function scope, so the symbol is stored in constructor.locals.
// Property Declaration symbol is a member of the class, so the symbol is stored in its class Declaration.symbol.members
if (symbol.valueDeclaration && symbol.valueDeclaration.kind === 144 /* Parameter */ &&
ts.isParameterPropertyDeclaration(symbol.valueDeclaration)) {
result = result.concat(typeChecker.getSymbolsOfParameterPropertyDeclaration(symbol.valueDeclaration, symbol.name));
}
// If this is symbol of binding element without propertyName declaration in Object binding pattern
// Include the property in the search
var bindingElementPropertySymbol = getPropertySymbolOfObjectBindingPatternWithoutPropertyName(symbol);
if (bindingElementPropertySymbol) {
result.push(bindingElementPropertySymbol);
}
// If this is a union property, add all the symbols from all its source symbols in all unioned types.
// If the symbol is an instantiation from a another symbol (e.g. widened symbol) , add the root the list
ts.forEach(typeChecker.getRootSymbols(symbol), function (rootSymbol) {
if (rootSymbol !== symbol) {
result.push(rootSymbol);
}
// Add symbol of properties/methods of the same name in base classes and implemented interfaces definitions
if (!implementations && rootSymbol.parent && rootSymbol.parent.flags & (32 /* Class */ | 64 /* Interface */)) {
getPropertySymbolsFromBaseTypes(rootSymbol.parent, rootSymbol.getName(), result, /*previousIterationSymbolsCache*/ ts.createMap());
}
});
return result;
}
/**
* Find symbol of the given property-name and add the symbol to the given result array
* @param symbol a symbol to start searching for the given propertyName
* @param propertyName a name of property to search for
* @param result an array of symbol of found property symbols
* @param previousIterationSymbolsCache a cache of symbol from previous iterations of calling this function to prevent infinite revisiting of the same symbol.
* The value of previousIterationSymbol is undefined when the function is first called.
*/
function getPropertySymbolsFromBaseTypes(symbol, propertyName, result, previousIterationSymbolsCache) {
if (!symbol) {
return;
}
// If the current symbol is the same as the previous-iteration symbol, we can just return the symbol that has already been visited
// This is particularly important for the following cases, so that we do not infinitely visit the same symbol.
// For example:
// interface C extends C {
// /*findRef*/propName: string;
// }
// The first time getPropertySymbolsFromBaseTypes is called when finding-all-references at propName,
// the symbol argument will be the symbol of an interface "C" and previousIterationSymbol is undefined,
// the function will add any found symbol of the property-name, then its sub-routine will call
// getPropertySymbolsFromBaseTypes again to walk up any base types to prevent revisiting already
// visited symbol, interface "C", the sub-routine will pass the current symbol as previousIterationSymbol.
if (symbol.name in previousIterationSymbolsCache) {
return;
}
if (symbol.flags & (32 /* Class */ | 64 /* Interface */)) {
ts.forEach(symbol.getDeclarations(), function (declaration) {
if (ts.isClassLike(declaration)) {
getPropertySymbolFromTypeReference(ts.getClassExtendsHeritageClauseElement(declaration));
ts.forEach(ts.getClassImplementsHeritageClauseElements(declaration), getPropertySymbolFromTypeReference);
}
else if (declaration.kind === 227 /* InterfaceDeclaration */) {
ts.forEach(ts.getInterfaceBaseTypeNodes(declaration), getPropertySymbolFromTypeReference);
}
});
}
return;
function getPropertySymbolFromTypeReference(typeReference) {
if (typeReference) {
var type = typeChecker.getTypeAtLocation(typeReference);
if (type) {
var propertySymbol = typeChecker.getPropertyOfType(type, propertyName);
if (propertySymbol) {
result.push.apply(result, typeChecker.getRootSymbols(propertySymbol));
}
// Visit the typeReference as well to see if it directly or indirectly use that property
previousIterationSymbolsCache[symbol.name] = symbol;
getPropertySymbolsFromBaseTypes(type.symbol, propertyName, result, previousIterationSymbolsCache);
}
}
}
}
function getRelatedSymbol(searchSymbols, referenceSymbol, referenceLocation, searchLocationIsConstructor, parents, cache) {
if (ts.contains(searchSymbols, referenceSymbol)) {
// If we are searching for constructor uses, they must be 'new' expressions.
return (!searchLocationIsConstructor || ts.isNewExpressionTarget(referenceLocation)) && referenceSymbol;
}
// If the reference symbol is an alias, check if what it is aliasing is one of the search
// symbols but by looking up for related symbol of this alias so it can handle multiple level of indirectness.
var aliasSymbol = getAliasSymbolForPropertyNameSymbol(referenceSymbol, referenceLocation);
if (aliasSymbol) {
return getRelatedSymbol(searchSymbols, aliasSymbol, referenceLocation, searchLocationIsConstructor, parents, cache);
}
// If the reference location is in an object literal, try to get the contextual type for the
// object literal, lookup the property symbol in the contextual type, and use this symbol to
// compare to our searchSymbol
var containingObjectLiteralElement = getContainingObjectLiteralElement(referenceLocation);
if (containingObjectLiteralElement) {
var contextualSymbol = ts.forEach(getPropertySymbolsFromContextualType(containingObjectLiteralElement), function (contextualSymbol) {
return ts.forEach(typeChecker.getRootSymbols(contextualSymbol), function (s) { return searchSymbols.indexOf(s) >= 0 ? s : undefined; });
});
if (contextualSymbol) {
return contextualSymbol;
}
// If the reference location is the name of property from object literal destructuring pattern
// Get the property symbol from the object literal's type and look if thats the search symbol
// In below eg. get 'property' from type of elems iterating type
// for ( { property: p2 } of elems) { }
var propertySymbol = getPropertySymbolOfDestructuringAssignment(referenceLocation);
if (propertySymbol && searchSymbols.indexOf(propertySymbol) >= 0) {
return propertySymbol;
}
}
// If the reference location is the binding element and doesn't have property name
// then include the binding element in the related symbols
// let { a } : { a };
var bindingElementPropertySymbol = getPropertySymbolOfObjectBindingPatternWithoutPropertyName(referenceSymbol);
if (bindingElementPropertySymbol && searchSymbols.indexOf(bindingElementPropertySymbol) >= 0) {
return bindingElementPropertySymbol;
}
// Unwrap symbols to get to the root (e.g. transient symbols as a result of widening)
// Or a union property, use its underlying unioned symbols
return ts.forEach(typeChecker.getRootSymbols(referenceSymbol), function (rootSymbol) {
// if it is in the list, then we are done
if (searchSymbols.indexOf(rootSymbol) >= 0) {
return rootSymbol;
}
// Finally, try all properties with the same name in any type the containing type extended or implemented, and
// see if any is in the list. If we were passed a parent symbol, only include types that are subtypes of the
// parent symbol
if (rootSymbol.parent && rootSymbol.parent.flags & (32 /* Class */ | 64 /* Interface */)) {
// Parents will only be defined if implementations is true
if (parents) {
if (!ts.forEach(parents, function (parent) { return explicitlyInheritsFrom(rootSymbol.parent, parent, cache); })) {
return undefined;
}
}
var result_3 = [];
getPropertySymbolsFromBaseTypes(rootSymbol.parent, rootSymbol.getName(), result_3, /*previousIterationSymbolsCache*/ ts.createMap());
return ts.forEach(result_3, function (s) { return searchSymbols.indexOf(s) >= 0 ? s : undefined; });
}
return undefined;
});
}
function getNameFromObjectLiteralElement(node) {
if (node.name.kind === 142 /* ComputedPropertyName */) {
var nameExpression = node.name.expression;
// treat computed property names where expression is string/numeric literal as just string/numeric literal
if (ts.isStringOrNumericLiteral(nameExpression.kind)) {
return nameExpression.text;
}
return undefined;
}
return node.name.text;
}
function getPropertySymbolsFromContextualType(node) {
var objectLiteral = node.parent;
var contextualType = typeChecker.getContextualType(objectLiteral);
var name = getNameFromObjectLiteralElement(node);
if (name && contextualType) {
var result_4 = [];
var symbol_2 = contextualType.getProperty(name);
if (symbol_2) {
result_4.push(symbol_2);
}
if (contextualType.flags & 65536 /* Union */) {
ts.forEach(contextualType.types, function (t) {
var symbol = t.getProperty(name);
if (symbol) {
result_4.push(symbol);
}
});
}
return result_4;
}
return undefined;
}
/** Given an initial searchMeaning, extracted from a location, widen the search scope based on the declarations
* of the corresponding symbol. e.g. if we are searching for "Foo" in value position, but "Foo" references a class
* then we need to widen the search to include type positions as well.
* On the contrary, if we are searching for "Bar" in type position and we trace bar to an interface, and an uninstantiated
* module, we want to keep the search limited to only types, as the two declarations (interface and uninstantiated module)
* do not intersect in any of the three spaces.
*/
function getIntersectingMeaningFromDeclarations(meaning, declarations) {
if (declarations) {
var lastIterationMeaning = void 0;
do {
// The result is order-sensitive, for instance if initialMeaning === Namespace, and declarations = [class, instantiated module]
// we need to consider both as they initialMeaning intersects with the module in the namespace space, and the module
// intersects with the class in the value space.
// To achieve that we will keep iterating until the result stabilizes.
// Remember the last meaning
lastIterationMeaning = meaning;
for (var _i = 0, declarations_8 = declarations; _i < declarations_8.length; _i++) {
var declaration = declarations_8[_i];
var declarationMeaning = ts.getMeaningFromDeclaration(declaration);
if (declarationMeaning & meaning) {
meaning |= declarationMeaning;
}
}
} while (meaning !== lastIterationMeaning);
}
return meaning;
}
}
FindAllReferences.getReferencedSymbolsForNode = getReferencedSymbolsForNode;
function convertReferences(referenceSymbols) {
if (!referenceSymbols) {
return undefined;
}
var referenceEntries = [];
for (var _i = 0, referenceSymbols_1 = referenceSymbols; _i < referenceSymbols_1.length; _i++) {
var referenceSymbol = referenceSymbols_1[_i];
ts.addRange(referenceEntries, referenceSymbol.references);
}
return referenceEntries;
}
FindAllReferences.convertReferences = convertReferences;
function isImplementation(node) {
if (!node) {
return false;
}
else if (ts.isVariableLike(node)) {
if (node.initializer) {
return true;
}
else if (node.kind === 223 /* VariableDeclaration */) {
var parentStatement = getParentStatementOfVariableDeclaration(node);
return parentStatement && ts.hasModifier(parentStatement, 2 /* Ambient */);
}
}
else if (ts.isFunctionLike(node)) {
return !!node.body || ts.hasModifier(node, 2 /* Ambient */);
}
else {
switch (node.kind) {
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 229 /* EnumDeclaration */:
case 230 /* ModuleDeclaration */:
return true;
}
}
return false;
}
function getParentStatementOfVariableDeclaration(node) {
if (node.parent && node.parent.parent && node.parent.parent.kind === 205 /* VariableStatement */) {
ts.Debug.assert(node.parent.kind === 224 /* VariableDeclarationList */);
return node.parent.parent;
}
}
function getReferenceEntriesForShorthandPropertyAssignment(node, typeChecker, result) {
var refSymbol = typeChecker.getSymbolAtLocation(node);
var shorthandSymbol = typeChecker.getShorthandAssignmentValueSymbol(refSymbol.valueDeclaration);
if (shorthandSymbol) {
for (var _i = 0, _a = shorthandSymbol.getDeclarations(); _i < _a.length; _i++) {
var declaration = _a[_i];
if (ts.getMeaningFromDeclaration(declaration) & 1 /* Value */) {
result.push(getReferenceEntryFromNode(declaration));
}
}
}
}
FindAllReferences.getReferenceEntriesForShorthandPropertyAssignment = getReferenceEntriesForShorthandPropertyAssignment;
function getReferenceEntryFromNode(node) {
var start = node.getStart();
var end = node.getEnd();
if (node.kind === 9 /* StringLiteral */) {
start += 1;
end -= 1;
}
return {
fileName: node.getSourceFile().fileName,
textSpan: ts.createTextSpanFromBounds(start, end),
isWriteAccess: isWriteAccess(node),
isDefinition: ts.isDeclarationName(node) || ts.isLiteralComputedPropertyDeclarationName(node)
};
}
FindAllReferences.getReferenceEntryFromNode = getReferenceEntryFromNode;
/** A node is considered a writeAccess iff it is a name of a declaration or a target of an assignment */
function isWriteAccess(node) {
if (node.kind === 70 /* Identifier */ && ts.isDeclarationName(node)) {
return true;
}
var parent = node.parent;
if (parent) {
if (parent.kind === 191 /* PostfixUnaryExpression */ || parent.kind === 190 /* PrefixUnaryExpression */) {
return true;
}
else if (parent.kind === 192 /* BinaryExpression */ && parent.left === node) {
var operator = parent.operatorToken.kind;
return 57 /* FirstAssignment */ <= operator && operator <= 69 /* LastAssignment */;
}
}
return false;
}
function forEachDescendantOfKind(node, kind, action) {
ts.forEachChild(node, function (child) {
if (child.kind === kind) {
action(child);
}
forEachDescendantOfKind(child, kind, action);
});
}
/**
* Returns the containing object literal property declaration given a possible name node, e.g. "a" in x = { "a": 1 }
*/
function getContainingObjectLiteralElement(node) {
switch (node.kind) {
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
if (node.parent.kind === 142 /* ComputedPropertyName */) {
return isObjectLiteralPropertyDeclaration(node.parent.parent) ? node.parent.parent : undefined;
}
// intential fall through
case 70 /* Identifier */:
return isObjectLiteralPropertyDeclaration(node.parent) && node.parent.name === node ? node.parent : undefined;
}
return undefined;
}
function isObjectLiteralPropertyDeclaration(node) {
switch (node.kind) {
case 257 /* PropertyAssignment */:
case 258 /* ShorthandPropertyAssignment */:
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return true;
}
return false;
}
/** Get `C` given `N` if `N` is in the position `class C extends N` or `class C extends foo.N` where `N` is an identifier. */
function tryGetClassByExtendingIdentifier(node) {
return ts.tryGetClassExtendingExpressionWithTypeArguments(ts.climbPastPropertyAccess(node).parent);
}
function isNameOfExternalModuleImportOrDeclaration(node) {
if (node.kind === 9 /* StringLiteral */) {
return ts.isNameOfModuleDeclaration(node) || ts.isExpressionOfExternalModuleImportEqualsDeclaration(node);
}
return false;
}
})(FindAllReferences = ts.FindAllReferences || (ts.FindAllReferences = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var GoToDefinition;
(function (GoToDefinition) {
function getDefinitionAtPosition(program, sourceFile, position) {
/// Triple slash reference comments
var comment = findReferenceInPosition(sourceFile.referencedFiles, position);
if (comment) {
var referenceFile = ts.tryResolveScriptReference(program, sourceFile, comment);
if (referenceFile) {
return [getDefinitionInfoForFileReference(comment.fileName, referenceFile.fileName)];
}
return undefined;
}
// Type reference directives
var typeReferenceDirective = findReferenceInPosition(sourceFile.typeReferenceDirectives, position);
if (typeReferenceDirective) {
var referenceFile = program.getResolvedTypeReferenceDirectives()[typeReferenceDirective.fileName];
if (referenceFile && referenceFile.resolvedFileName) {
return [getDefinitionInfoForFileReference(typeReferenceDirective.fileName, referenceFile.resolvedFileName)];
}
return undefined;
}
var node = ts.getTouchingPropertyName(sourceFile, position);
if (node === sourceFile) {
return undefined;
}
// Labels
if (ts.isJumpStatementTarget(node)) {
var labelName = node.text;
var label = ts.getTargetLabel(node.parent, node.text);
return label ? [createDefinitionInfo(label, ts.ScriptElementKind.label, labelName, /*containerName*/ undefined)] : undefined;
}
var typeChecker = program.getTypeChecker();
var calledDeclaration = tryGetSignatureDeclaration(typeChecker, node);
if (calledDeclaration) {
return [createDefinitionFromSignatureDeclaration(typeChecker, calledDeclaration)];
}
var symbol = typeChecker.getSymbolAtLocation(node);
// Could not find a symbol e.g. node is string or number keyword,
// or the symbol was an internal symbol and does not have a declaration e.g. undefined symbol
if (!symbol) {
return undefined;
}
// If this is an alias, and the request came at the declaration location
// get the aliased symbol instead. This allows for goto def on an import e.g.
// import {A, B} from "mod";
// to jump to the implementation directly.
if (symbol.flags & 8388608 /* Alias */) {
var declaration = symbol.declarations[0];
// Go to the original declaration for cases:
//
// (1) when the aliased symbol was declared in the location(parent).
// (2) when the aliased symbol is originating from a named import.
//
if (node.kind === 70 /* Identifier */ &&
(node.parent === declaration ||
(declaration.kind === 239 /* ImportSpecifier */ && declaration.parent && declaration.parent.kind === 238 /* NamedImports */))) {
symbol = typeChecker.getAliasedSymbol(symbol);
}
}
// Because name in short-hand property assignment has two different meanings: property name and property value,
// using go-to-definition at such position should go to the variable declaration of the property value rather than
// go to the declaration of the property name (in this case stay at the same position). However, if go-to-definition
// is performed at the location of property access, we would like to go to definition of the property in the short-hand
// assignment. This case and others are handled by the following code.
if (node.parent.kind === 258 /* ShorthandPropertyAssignment */) {
var shorthandSymbol = typeChecker.getShorthandAssignmentValueSymbol(symbol.valueDeclaration);
if (!shorthandSymbol) {
return [];
}
var shorthandDeclarations = shorthandSymbol.getDeclarations();
var shorthandSymbolKind_1 = ts.SymbolDisplay.getSymbolKind(typeChecker, shorthandSymbol, node);
var shorthandSymbolName_1 = typeChecker.symbolToString(shorthandSymbol);
var shorthandContainerName_1 = typeChecker.symbolToString(symbol.parent, node);
return ts.map(shorthandDeclarations, function (declaration) { return createDefinitionInfo(declaration, shorthandSymbolKind_1, shorthandSymbolName_1, shorthandContainerName_1); });
}
return getDefinitionFromSymbol(typeChecker, symbol, node);
}
GoToDefinition.getDefinitionAtPosition = getDefinitionAtPosition;
/// Goto type
function getTypeDefinitionAtPosition(typeChecker, sourceFile, position) {
var node = ts.getTouchingPropertyName(sourceFile, position);
if (node === sourceFile) {
return undefined;
}
var symbol = typeChecker.getSymbolAtLocation(node);
if (!symbol) {
return undefined;
}
var type = typeChecker.getTypeOfSymbolAtLocation(symbol, node);
if (!type) {
return undefined;
}
if (type.flags & 65536 /* Union */ && !(type.flags & 16 /* Enum */)) {
var result_5 = [];
ts.forEach(type.types, function (t) {
if (t.symbol) {
ts.addRange(/*to*/ result_5, /*from*/ getDefinitionFromSymbol(typeChecker, t.symbol, node));
}
});
return result_5;
}
if (!type.symbol) {
return undefined;
}
return getDefinitionFromSymbol(typeChecker, type.symbol, node);
}
GoToDefinition.getTypeDefinitionAtPosition = getTypeDefinitionAtPosition;
function getDefinitionFromSymbol(typeChecker, symbol, node) {
var result = [];
var declarations = symbol.getDeclarations();
var _a = getSymbolInfo(typeChecker, symbol, node), symbolName = _a.symbolName, symbolKind = _a.symbolKind, containerName = _a.containerName;
if (!tryAddConstructSignature(symbol, node, symbolKind, symbolName, containerName, result) &&
!tryAddCallSignature(symbol, node, symbolKind, symbolName, containerName, result)) {
// Just add all the declarations.
ts.forEach(declarations, function (declaration) {
result.push(createDefinitionInfo(declaration, symbolKind, symbolName, containerName));
});
}
return result;
function tryAddConstructSignature(symbol, location, symbolKind, symbolName, containerName, result) {
// Applicable only if we are in a new expression, or we are on a constructor declaration
// and in either case the symbol has a construct signature definition, i.e. class
if (ts.isNewExpressionTarget(location) || location.kind === 122 /* ConstructorKeyword */) {
if (symbol.flags & 32 /* Class */) {
// Find the first class-like declaration and try to get the construct signature.
for (var _i = 0, _a = symbol.getDeclarations(); _i < _a.length; _i++) {
var declaration = _a[_i];
if (ts.isClassLike(declaration)) {
return tryAddSignature(declaration.members,
/*selectConstructors*/ true, symbolKind, symbolName, containerName, result);
}
}
ts.Debug.fail("Expected declaration to have at least one class-like declaration");
}
}
return false;
}
function tryAddCallSignature(symbol, location, symbolKind, symbolName, containerName, result) {
if (ts.isCallExpressionTarget(location) || ts.isNewExpressionTarget(location) || ts.isNameOfFunctionDeclaration(location)) {
return tryAddSignature(symbol.declarations, /*selectConstructors*/ false, symbolKind, symbolName, containerName, result);
}
return false;
}
function tryAddSignature(signatureDeclarations, selectConstructors, symbolKind, symbolName, containerName, result) {
var declarations = [];
var definition;
ts.forEach(signatureDeclarations, function (d) {
if ((selectConstructors && d.kind === 150 /* Constructor */) ||
(!selectConstructors && (d.kind === 225 /* FunctionDeclaration */ || d.kind === 149 /* MethodDeclaration */ || d.kind === 148 /* MethodSignature */))) {
declarations.push(d);
if (d.body)
definition = d;
}
});
if (definition) {
result.push(createDefinitionInfo(definition, symbolKind, symbolName, containerName));
return true;
}
else if (declarations.length) {
result.push(createDefinitionInfo(ts.lastOrUndefined(declarations), symbolKind, symbolName, containerName));
return true;
}
return false;
}
}
function createDefinitionInfo(node, symbolKind, symbolName, containerName) {
return {
fileName: node.getSourceFile().fileName,
textSpan: ts.createTextSpanFromBounds(node.getStart(), node.getEnd()),
kind: symbolKind,
name: symbolName,
containerKind: undefined,
containerName: containerName
};
}
function getSymbolInfo(typeChecker, symbol, node) {
return {
symbolName: typeChecker.symbolToString(symbol),
symbolKind: ts.SymbolDisplay.getSymbolKind(typeChecker, symbol, node),
containerName: symbol.parent ? typeChecker.symbolToString(symbol.parent, node) : ""
};
}
function createDefinitionFromSignatureDeclaration(typeChecker, decl) {
var _a = getSymbolInfo(typeChecker, decl.symbol, decl), symbolName = _a.symbolName, symbolKind = _a.symbolKind, containerName = _a.containerName;
return createDefinitionInfo(decl, symbolKind, symbolName, containerName);
}
function findReferenceInPosition(refs, pos) {
for (var _i = 0, refs_1 = refs; _i < refs_1.length; _i++) {
var ref = refs_1[_i];
if (ref.pos <= pos && pos < ref.end) {
return ref;
}
}
return undefined;
}
function getDefinitionInfoForFileReference(name, targetFileName) {
return {
fileName: targetFileName,
textSpan: ts.createTextSpanFromBounds(0, 0),
kind: ts.ScriptElementKind.scriptElement,
name: name,
containerName: undefined,
containerKind: undefined
};
}
/** Returns a CallLikeExpression where `node` is the target being invoked. */
function getAncestorCallLikeExpression(node) {
var target = climbPastManyPropertyAccesses(node);
var callLike = target.parent;
return callLike && ts.isCallLikeExpression(callLike) && ts.getInvokedExpression(callLike) === target && callLike;
}
function climbPastManyPropertyAccesses(node) {
return ts.isRightSideOfPropertyAccess(node) ? climbPastManyPropertyAccesses(node.parent) : node;
}
function tryGetSignatureDeclaration(typeChecker, node) {
var callLike = getAncestorCallLikeExpression(node);
return callLike && typeChecker.getResolvedSignature(callLike).declaration;
}
})(GoToDefinition = ts.GoToDefinition || (ts.GoToDefinition = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var GoToImplementation;
(function (GoToImplementation) {
function getImplementationAtPosition(typeChecker, cancellationToken, sourceFiles, node) {
// If invoked directly on a shorthand property assignment, then return
// the declaration of the symbol being assigned (not the symbol being assigned to).
if (node.parent.kind === 258 /* ShorthandPropertyAssignment */) {
var result = [];
ts.FindAllReferences.getReferenceEntriesForShorthandPropertyAssignment(node, typeChecker, result);
return result.length > 0 ? result : undefined;
}
else if (node.kind === 96 /* SuperKeyword */ || ts.isSuperProperty(node.parent)) {
// References to and accesses on the super keyword only have one possible implementation, so no
// need to "Find all References"
var symbol = typeChecker.getSymbolAtLocation(node);
return symbol.valueDeclaration && [ts.FindAllReferences.getReferenceEntryFromNode(symbol.valueDeclaration)];
}
else {
// Perform "Find all References" and retrieve only those that are implementations
var referencedSymbols = ts.FindAllReferences.getReferencedSymbolsForNode(typeChecker, cancellationToken, node, sourceFiles, /*findInStrings*/ false, /*findInComments*/ false, /*implementations*/ true);
var result = ts.flatMap(referencedSymbols, function (symbol) {
return ts.map(symbol.references, function (_a) {
var textSpan = _a.textSpan, fileName = _a.fileName;
return ({ textSpan: textSpan, fileName: fileName });
});
});
return result && result.length > 0 ? result : undefined;
}
}
GoToImplementation.getImplementationAtPosition = getImplementationAtPosition;
})(GoToImplementation = ts.GoToImplementation || (ts.GoToImplementation = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var JsDoc;
(function (JsDoc) {
var jsDocTagNames = [
"augments",
"author",
"argument",
"borrows",
"class",
"constant",
"constructor",
"constructs",
"default",
"deprecated",
"description",
"event",
"example",
"extends",
"field",
"fileOverview",
"function",
"ignore",
"inner",
"lends",
"link",
"memberOf",
"name",
"namespace",
"param",
"private",
"property",
"public",
"requires",
"returns",
"see",
"since",
"static",
"throws",
"type",
"typedef",
"property",
"prop",
"version"
];
var jsDocCompletionEntries;
function getJsDocCommentsFromDeclarations(declarations) {
// Only collect doc comments from duplicate declarations once:
// In case of a union property there might be same declaration multiple times
// which only varies in type parameter
// Eg. const a: Array<string> | Array<number>; a.length
// The property length will have two declarations of property length coming
// from Array<T> - Array<string> and Array<number>
var documentationComment = [];
forEachUnique(declarations, function (declaration) {
var comments = ts.getJSDocComments(declaration, /*checkParentVariableStatement*/ true);
if (!comments) {
return;
}
for (var _i = 0, comments_3 = comments; _i < comments_3.length; _i++) {
var comment = comments_3[_i];
if (comment) {
if (documentationComment.length) {
documentationComment.push(ts.lineBreakPart());
}
documentationComment.push(ts.textPart(comment));
}
}
});
return documentationComment;
}
JsDoc.getJsDocCommentsFromDeclarations = getJsDocCommentsFromDeclarations;
/**
* Iterates through 'array' by index and performs the callback on each element of array until the callback
* returns a truthy value, then returns that value.
* If no such value is found, the callback is applied to each element of array and undefined is returned.
*/
function forEachUnique(array, callback) {
if (array) {
for (var i = 0, len = array.length; i < len; i++) {
if (ts.indexOf(array, array[i]) === i) {
var result = callback(array[i], i);
if (result) {
return result;
}
}
}
}
return undefined;
}
function getAllJsDocCompletionEntries() {
return jsDocCompletionEntries || (jsDocCompletionEntries = ts.map(jsDocTagNames, function (tagName) {
return {
name: tagName,
kind: ts.ScriptElementKind.keyword,
kindModifiers: "",
sortText: "0",
};
}));
}
JsDoc.getAllJsDocCompletionEntries = getAllJsDocCompletionEntries;
/**
* Checks if position points to a valid position to add JSDoc comments, and if so,
* returns the appropriate template. Otherwise returns an empty string.
* Valid positions are
* - outside of comments, statements, and expressions, and
* - preceding a:
* - function/constructor/method declaration
* - class declarations
* - variable statements
* - namespace declarations
*
* Hosts should ideally check that:
* - The line is all whitespace up to 'position' before performing the insertion.
* - If the keystroke sequence "/\*\*" induced the call, we also check that the next
* non-whitespace character is '*', which (approximately) indicates whether we added
* the second '*' to complete an existing (JSDoc) comment.
* @param fileName The file in which to perform the check.
* @param position The (character-indexed) position in the file where the check should
* be performed.
*/
function getDocCommentTemplateAtPosition(newLine, sourceFile, position) {
// Check if in a context where we don't want to perform any insertion
if (ts.isInString(sourceFile, position) || ts.isInComment(sourceFile, position) || ts.hasDocComment(sourceFile, position)) {
return undefined;
}
var tokenAtPos = ts.getTokenAtPosition(sourceFile, position);
var tokenStart = tokenAtPos.getStart();
if (!tokenAtPos || tokenStart < position) {
return undefined;
}
// TODO: add support for:
// - enums/enum members
// - interfaces
// - property declarations
// - potentially property assignments
var commentOwner;
findOwner: for (commentOwner = tokenAtPos; commentOwner; commentOwner = commentOwner.parent) {
switch (commentOwner.kind) {
case 225 /* FunctionDeclaration */:
case 149 /* MethodDeclaration */:
case 150 /* Constructor */:
case 226 /* ClassDeclaration */:
case 205 /* VariableStatement */:
break findOwner;
case 261 /* SourceFile */:
return undefined;
case 230 /* ModuleDeclaration */:
// If in walking up the tree, we hit a a nested namespace declaration,
// then we must be somewhere within a dotted namespace name; however we don't
// want to give back a JSDoc template for the 'b' or 'c' in 'namespace a.b.c { }'.
if (commentOwner.parent.kind === 230 /* ModuleDeclaration */) {
return undefined;
}
break findOwner;
}
}
if (!commentOwner || commentOwner.getStart() < position) {
return undefined;
}
var parameters = getParametersForJsDocOwningNode(commentOwner);
var posLineAndChar = sourceFile.getLineAndCharacterOfPosition(position);
var lineStart = sourceFile.getLineStarts()[posLineAndChar.line];
var indentationStr = sourceFile.text.substr(lineStart, posLineAndChar.character);
var docParams = "";
for (var i = 0, numParams = parameters.length; i < numParams; i++) {
var currentName = parameters[i].name;
var paramName = currentName.kind === 70 /* Identifier */ ?
currentName.text :
"param" + i;
docParams += indentationStr + " * @param " + paramName + newLine;
}
// A doc comment consists of the following
// * The opening comment line
// * the first line (without a param) for the object's untagged info (this is also where the caret ends up)
// * the '@param'-tagged lines
// * TODO: other tags.
// * the closing comment line
// * if the caret was directly in front of the object, then we add an extra line and indentation.
var preamble = "/**" + newLine +
indentationStr + " * ";
var result = preamble + newLine +
docParams +
indentationStr + " */" +
(tokenStart === position ? newLine + indentationStr : "");
return { newText: result, caretOffset: preamble.length };
}
JsDoc.getDocCommentTemplateAtPosition = getDocCommentTemplateAtPosition;
function getParametersForJsDocOwningNode(commentOwner) {
if (ts.isFunctionLike(commentOwner)) {
return commentOwner.parameters;
}
if (commentOwner.kind === 205 /* VariableStatement */) {
var varStatement = commentOwner;
var varDeclarations = varStatement.declarationList.declarations;
if (varDeclarations.length === 1 && varDeclarations[0].initializer) {
return getParametersFromRightHandSideOfAssignment(varDeclarations[0].initializer);
}
}
return ts.emptyArray;
}
/**
* Digs into an an initializer or RHS operand of an assignment operation
* to get the parameters of an apt signature corresponding to a
* function expression or a class expression.
*
* @param rightHandSide the expression which may contain an appropriate set of parameters
* @returns the parameters of a signature found on the RHS if one exists; otherwise 'emptyArray'.
*/
function getParametersFromRightHandSideOfAssignment(rightHandSide) {
while (rightHandSide.kind === 183 /* ParenthesizedExpression */) {
rightHandSide = rightHandSide.expression;
}
switch (rightHandSide.kind) {
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return rightHandSide.parameters;
case 197 /* ClassExpression */:
for (var _i = 0, _a = rightHandSide.members; _i < _a.length; _i++) {
var member = _a[_i];
if (member.kind === 150 /* Constructor */) {
return member.parameters;
}
}
break;
}
return ts.emptyArray;
}
})(JsDoc = ts.JsDoc || (ts.JsDoc = {}));
})(ts || (ts = {}));
// Copyright (c) Microsoft. All rights reserved. Licensed under the Apache License, Version 2.0.
// See LICENSE.txt in the project root for complete license information.
/// <reference path='../compiler/types.ts' />
/// <reference path='../compiler/core.ts' />
/// <reference path='../compiler/commandLineParser.ts' />
/* @internal */
var ts;
(function (ts) {
var JsTyping;
(function (JsTyping) {
;
;
// A map of loose file names to library names
// that we are confident require typings
var safeList;
var EmptySafeList = ts.createMap();
/* @internal */
JsTyping.nodeCoreModuleList = [
"buffer", "querystring", "events", "http", "cluster",
"zlib", "os", "https", "punycode", "repl", "readline",
"vm", "child_process", "url", "dns", "net",
"dgram", "fs", "path", "string_decoder", "tls",
"crypto", "stream", "util", "assert", "tty", "domain",
"constants", "process", "v8", "timers", "console"
];
var nodeCoreModules = ts.arrayToMap(JsTyping.nodeCoreModuleList, function (x) { return x; });
/**
* @param host is the object providing I/O related operations.
* @param fileNames are the file names that belong to the same project
* @param projectRootPath is the path to the project root directory
* @param safeListPath is the path used to retrieve the safe list
* @param packageNameToTypingLocation is the map of package names to their cached typing locations
* @param typingOptions are used to customize the typing inference process
* @param compilerOptions are used as a source for typing inference
*/
function discoverTypings(host, fileNames, projectRootPath, safeListPath, packageNameToTypingLocation, typingOptions, unresolvedImports) {
// A typing name to typing file path mapping
var inferredTypings = ts.createMap();
if (!typingOptions || !typingOptions.enableAutoDiscovery) {
return { cachedTypingPaths: [], newTypingNames: [], filesToWatch: [] };
}
// Only infer typings for .js and .jsx files
fileNames = ts.filter(ts.map(fileNames, ts.normalizePath), function (f) {
var kind = ts.ensureScriptKind(f, ts.getScriptKindFromFileName(f));
return kind === 1 /* JS */ || kind === 2 /* JSX */;
});
if (!safeList) {
var result = ts.readConfigFile(safeListPath, function (path) { return host.readFile(path); });
safeList = result.config ? ts.createMap(result.config) : EmptySafeList;
}
var filesToWatch = [];
// Directories to search for package.json, bower.json and other typing information
var searchDirs = [];
var exclude = [];
mergeTypings(typingOptions.include);
exclude = typingOptions.exclude || [];
var possibleSearchDirs = ts.map(fileNames, ts.getDirectoryPath);
if (projectRootPath) {
possibleSearchDirs.push(projectRootPath);
}
searchDirs = ts.deduplicate(possibleSearchDirs);
for (var _i = 0, searchDirs_1 = searchDirs; _i < searchDirs_1.length; _i++) {
var searchDir = searchDirs_1[_i];
var packageJsonPath = ts.combinePaths(searchDir, "package.json");
getTypingNamesFromJson(packageJsonPath, filesToWatch);
var bowerJsonPath = ts.combinePaths(searchDir, "bower.json");
getTypingNamesFromJson(bowerJsonPath, filesToWatch);
var nodeModulesPath = ts.combinePaths(searchDir, "node_modules");
getTypingNamesFromNodeModuleFolder(nodeModulesPath);
}
getTypingNamesFromSourceFileNames(fileNames);
// add typings for unresolved imports
if (unresolvedImports) {
for (var _a = 0, unresolvedImports_1 = unresolvedImports; _a < unresolvedImports_1.length; _a++) {
var moduleId = unresolvedImports_1[_a];
var typingName = moduleId in nodeCoreModules ? "node" : moduleId;
if (!(typingName in inferredTypings)) {
inferredTypings[typingName] = undefined;
}
}
}
// Add the cached typing locations for inferred typings that are already installed
for (var name_44 in packageNameToTypingLocation) {
if (name_44 in inferredTypings && !inferredTypings[name_44]) {
inferredTypings[name_44] = packageNameToTypingLocation[name_44];
}
}
// Remove typings that the user has added to the exclude list
for (var _b = 0, exclude_1 = exclude; _b < exclude_1.length; _b++) {
var excludeTypingName = exclude_1[_b];
delete inferredTypings[excludeTypingName];
}
var newTypingNames = [];
var cachedTypingPaths = [];
for (var typing in inferredTypings) {
if (inferredTypings[typing] !== undefined) {
cachedTypingPaths.push(inferredTypings[typing]);
}
else {
newTypingNames.push(typing);
}
}
return { cachedTypingPaths: cachedTypingPaths, newTypingNames: newTypingNames, filesToWatch: filesToWatch };
/**
* Merge a given list of typingNames to the inferredTypings map
*/
function mergeTypings(typingNames) {
if (!typingNames) {
return;
}
for (var _i = 0, typingNames_1 = typingNames; _i < typingNames_1.length; _i++) {
var typing = typingNames_1[_i];
if (!(typing in inferredTypings)) {
inferredTypings[typing] = undefined;
}
}
}
/**
* Get the typing info from common package manager json files like package.json or bower.json
*/
function getTypingNamesFromJson(jsonPath, filesToWatch) {
if (host.fileExists(jsonPath)) {
filesToWatch.push(jsonPath);
}
var result = ts.readConfigFile(jsonPath, function (path) { return host.readFile(path); });
if (result.config) {
var jsonConfig = result.config;
if (jsonConfig.dependencies) {
mergeTypings(ts.getOwnKeys(jsonConfig.dependencies));
}
if (jsonConfig.devDependencies) {
mergeTypings(ts.getOwnKeys(jsonConfig.devDependencies));
}
if (jsonConfig.optionalDependencies) {
mergeTypings(ts.getOwnKeys(jsonConfig.optionalDependencies));
}
if (jsonConfig.peerDependencies) {
mergeTypings(ts.getOwnKeys(jsonConfig.peerDependencies));
}
}
}
/**
* Infer typing names from given file names. For example, the file name "jquery-min.2.3.4.js"
* should be inferred to the 'jquery' typing name; and "angular-route.1.2.3.js" should be inferred
* to the 'angular-route' typing name.
* @param fileNames are the names for source files in the project
*/
function getTypingNamesFromSourceFileNames(fileNames) {
var jsFileNames = ts.filter(fileNames, ts.hasJavaScriptFileExtension);
var inferredTypingNames = ts.map(jsFileNames, function (f) { return ts.removeFileExtension(ts.getBaseFileName(f.toLowerCase())); });
var cleanedTypingNames = ts.map(inferredTypingNames, function (f) { return f.replace(/((?:\.|-)min(?=\.|$))|((?:-|\.)\d+)/g, ""); });
if (safeList !== EmptySafeList) {
mergeTypings(ts.filter(cleanedTypingNames, function (f) { return f in safeList; }));
}
var hasJsxFile = ts.forEach(fileNames, function (f) { return ts.ensureScriptKind(f, ts.getScriptKindFromFileName(f)) === 2 /* JSX */; });
if (hasJsxFile) {
mergeTypings(["react"]);
}
}
/**
* Infer typing names from node_module folder
* @param nodeModulesPath is the path to the "node_modules" folder
*/
function getTypingNamesFromNodeModuleFolder(nodeModulesPath) {
// Todo: add support for ModuleResolutionHost too
if (!host.directoryExists(nodeModulesPath)) {
return;
}
var typingNames = [];
var fileNames = host.readDirectory(nodeModulesPath, [".json"], /*excludes*/ undefined, /*includes*/ undefined, /*depth*/ 2);
for (var _i = 0, fileNames_2 = fileNames; _i < fileNames_2.length; _i++) {
var fileName = fileNames_2[_i];
var normalizedFileName = ts.normalizePath(fileName);
if (ts.getBaseFileName(normalizedFileName) !== "package.json") {
continue;
}
var result = ts.readConfigFile(normalizedFileName, function (path) { return host.readFile(path); });
if (!result.config) {
continue;
}
var packageJson = result.config;
// npm 3's package.json contains a "_requiredBy" field
// we should include all the top level module names for npm 2, and only module names whose
// "_requiredBy" field starts with "#" or equals "/" for npm 3.
if (packageJson._requiredBy &&
ts.filter(packageJson._requiredBy, function (r) { return r[0] === "#" || r === "/"; }).length === 0) {
continue;
}
// If the package has its own d.ts typings, those will take precedence. Otherwise the package name will be used
// to download d.ts files from DefinitelyTyped
if (!packageJson.name) {
continue;
}
if (packageJson.typings) {
var absolutePath = ts.getNormalizedAbsolutePath(packageJson.typings, ts.getDirectoryPath(normalizedFileName));
inferredTypings[packageJson.name] = absolutePath;
}
else {
typingNames.push(packageJson.name);
}
}
mergeTypings(typingNames);
}
}
JsTyping.discoverTypings = discoverTypings;
})(JsTyping = ts.JsTyping || (ts.JsTyping = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var NavigateTo;
(function (NavigateTo) {
function getNavigateToItems(sourceFiles, checker, cancellationToken, searchValue, maxResultCount, excludeDtsFiles) {
var patternMatcher = ts.createPatternMatcher(searchValue);
var rawItems = [];
// Search the declarations in all files and output matched NavigateToItem into array of NavigateToItem[]
ts.forEach(sourceFiles, function (sourceFile) {
cancellationToken.throwIfCancellationRequested();
if (excludeDtsFiles && ts.fileExtensionIs(sourceFile.fileName, ".d.ts")) {
return;
}
var nameToDeclarations = sourceFile.getNamedDeclarations();
for (var name_45 in nameToDeclarations) {
var declarations = nameToDeclarations[name_45];
if (declarations) {
// First do a quick check to see if the name of the declaration matches the
// last portion of the (possibly) dotted name they're searching for.
var matches = patternMatcher.getMatchesForLastSegmentOfPattern(name_45);
if (!matches) {
continue;
}
for (var _i = 0, declarations_9 = declarations; _i < declarations_9.length; _i++) {
var declaration = declarations_9[_i];
// It was a match! If the pattern has dots in it, then also see if the
// declaration container matches as well.
if (patternMatcher.patternContainsDots) {
var containers = getContainers(declaration);
if (!containers) {
return undefined;
}
matches = patternMatcher.getMatches(containers, name_45);
if (!matches) {
continue;
}
}
var fileName = sourceFile.fileName;
var matchKind = bestMatchKind(matches);
rawItems.push({ name: name_45, fileName: fileName, matchKind: matchKind, isCaseSensitive: allMatchesAreCaseSensitive(matches), declaration: declaration });
}
}
}
});
// Remove imports when the imported declaration is already in the list and has the same name.
rawItems = ts.filter(rawItems, function (item) {
var decl = item.declaration;
if (decl.kind === 236 /* ImportClause */ || decl.kind === 239 /* ImportSpecifier */ || decl.kind === 234 /* ImportEqualsDeclaration */) {
var importer = checker.getSymbolAtLocation(decl.name);
var imported = checker.getAliasedSymbol(importer);
return importer.name !== imported.name;
}
else {
return true;
}
});
rawItems.sort(compareNavigateToItems);
if (maxResultCount !== undefined) {
rawItems = rawItems.slice(0, maxResultCount);
}
var items = ts.map(rawItems, createNavigateToItem);
return items;
function allMatchesAreCaseSensitive(matches) {
ts.Debug.assert(matches.length > 0);
// This is a case sensitive match, only if all the submatches were case sensitive.
for (var _i = 0, matches_2 = matches; _i < matches_2.length; _i++) {
var match = matches_2[_i];
if (!match.isCaseSensitive) {
return false;
}
}
return true;
}
function getTextOfIdentifierOrLiteral(node) {
if (node) {
if (node.kind === 70 /* Identifier */ ||
node.kind === 9 /* StringLiteral */ ||
node.kind === 8 /* NumericLiteral */) {
return node.text;
}
}
return undefined;
}
function tryAddSingleDeclarationName(declaration, containers) {
if (declaration && declaration.name) {
var text = getTextOfIdentifierOrLiteral(declaration.name);
if (text !== undefined) {
containers.unshift(text);
}
else if (declaration.name.kind === 142 /* ComputedPropertyName */) {
return tryAddComputedPropertyName(declaration.name.expression, containers, /*includeLastPortion*/ true);
}
else {
// Don't know how to add this.
return false;
}
}
return true;
}
// Only added the names of computed properties if they're simple dotted expressions, like:
//
// [X.Y.Z]() { }
function tryAddComputedPropertyName(expression, containers, includeLastPortion) {
var text = getTextOfIdentifierOrLiteral(expression);
if (text !== undefined) {
if (includeLastPortion) {
containers.unshift(text);
}
return true;
}
if (expression.kind === 177 /* PropertyAccessExpression */) {
var propertyAccess = expression;
if (includeLastPortion) {
containers.unshift(propertyAccess.name.text);
}
return tryAddComputedPropertyName(propertyAccess.expression, containers, /*includeLastPortion*/ true);
}
return false;
}
function getContainers(declaration) {
var containers = [];
// First, if we started with a computed property name, then add all but the last
// portion into the container array.
if (declaration.name.kind === 142 /* ComputedPropertyName */) {
if (!tryAddComputedPropertyName(declaration.name.expression, containers, /*includeLastPortion*/ false)) {
return undefined;
}
}
// Now, walk up our containers, adding all their names to the container array.
declaration = ts.getContainerNode(declaration);
while (declaration) {
if (!tryAddSingleDeclarationName(declaration, containers)) {
return undefined;
}
declaration = ts.getContainerNode(declaration);
}
return containers;
}
function bestMatchKind(matches) {
ts.Debug.assert(matches.length > 0);
var bestMatchKind = ts.PatternMatchKind.camelCase;
for (var _i = 0, matches_3 = matches; _i < matches_3.length; _i++) {
var match = matches_3[_i];
var kind = match.kind;
if (kind < bestMatchKind) {
bestMatchKind = kind;
}
}
return bestMatchKind;
}
function compareNavigateToItems(i1, i2) {
// TODO(cyrusn): get the gamut of comparisons that VS already uses here.
// Right now we just sort by kind first, and then by name of the item.
// We first sort case insensitively. So "Aaa" will come before "bar".
// Then we sort case sensitively, so "aaa" will come before "Aaa".
return i1.matchKind - i2.matchKind ||
ts.compareStringsCaseInsensitive(i1.name, i2.name) ||
ts.compareStrings(i1.name, i2.name);
}
function createNavigateToItem(rawItem) {
var declaration = rawItem.declaration;
var container = ts.getContainerNode(declaration);
return {
name: rawItem.name,
kind: ts.getNodeKind(declaration),
kindModifiers: ts.getNodeModifiers(declaration),
matchKind: ts.PatternMatchKind[rawItem.matchKind],
isCaseSensitive: rawItem.isCaseSensitive,
fileName: rawItem.fileName,
textSpan: ts.createTextSpanFromBounds(declaration.getStart(), declaration.getEnd()),
// TODO(jfreeman): What should be the containerName when the container has a computed name?
containerName: container && container.name ? container.name.text : "",
containerKind: container && container.name ? ts.getNodeKind(container) : ""
};
}
}
NavigateTo.getNavigateToItems = getNavigateToItems;
})(NavigateTo = ts.NavigateTo || (ts.NavigateTo = {}));
})(ts || (ts = {}));
/// <reference path='services.ts' />
/* @internal */
var ts;
(function (ts) {
var NavigationBar;
(function (NavigationBar) {
function getNavigationBarItems(sourceFile) {
curSourceFile = sourceFile;
var result = ts.map(topLevelItems(rootNavigationBarNode(sourceFile)), convertToTopLevelItem);
curSourceFile = undefined;
return result;
}
NavigationBar.getNavigationBarItems = getNavigationBarItems;
function getNavigationTree(sourceFile) {
curSourceFile = sourceFile;
var result = convertToTree(rootNavigationBarNode(sourceFile));
curSourceFile = undefined;
return result;
}
NavigationBar.getNavigationTree = getNavigationTree;
// Keep sourceFile handy so we don't have to search for it every time we need to call `getText`.
var curSourceFile;
function nodeText(node) {
return node.getText(curSourceFile);
}
function navigationBarNodeKind(n) {
return n.node.kind;
}
function pushChild(parent, child) {
if (parent.children) {
parent.children.push(child);
}
else {
parent.children = [child];
}
}
/*
For performance, we keep navigation bar parents on a stack rather than passing them through each recursion.
`parent` is the current parent and is *not* stored in parentsStack.
`startNode` sets a new parent and `endNode` returns to the previous parent.
*/
var parentsStack = [];
var parent;
function rootNavigationBarNode(sourceFile) {
ts.Debug.assert(!parentsStack.length);
var root = { node: sourceFile, additionalNodes: undefined, parent: undefined, children: undefined, indent: 0 };
parent = root;
for (var _i = 0, _a = sourceFile.statements; _i < _a.length; _i++) {
var statement = _a[_i];
addChildrenRecursively(statement);
}
endNode();
ts.Debug.assert(!parent && !parentsStack.length);
return root;
}
function addLeafNode(node) {
pushChild(parent, emptyNavigationBarNode(node));
}
function emptyNavigationBarNode(node) {
return {
node: node,
additionalNodes: undefined,
parent: parent,
children: undefined,
indent: parent.indent + 1
};
}
/**
* Add a new level of NavigationBarNodes.
* This pushes to the stack, so you must call `endNode` when you are done adding to this node.
*/
function startNode(node) {
var navNode = emptyNavigationBarNode(node);
pushChild(parent, navNode);
// Save the old parent
parentsStack.push(parent);
parent = navNode;
}
/** Call after calling `startNode` and adding children to it. */
function endNode() {
if (parent.children) {
mergeChildren(parent.children);
sortChildren(parent.children);
}
parent = parentsStack.pop();
}
function addNodeWithRecursiveChild(node, child) {
startNode(node);
addChildrenRecursively(child);
endNode();
}
/** Look for navigation bar items in node's subtree, adding them to the current `parent`. */
function addChildrenRecursively(node) {
if (!node || ts.isToken(node)) {
return;
}
switch (node.kind) {
case 150 /* Constructor */:
// Get parameter properties, and treat them as being on the *same* level as the constructor, not under it.
var ctr = node;
addNodeWithRecursiveChild(ctr, ctr.body);
// Parameter properties are children of the class, not the constructor.
for (var _i = 0, _a = ctr.parameters; _i < _a.length; _i++) {
var param = _a[_i];
if (ts.isParameterPropertyDeclaration(param)) {
addLeafNode(param);
}
}
break;
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 148 /* MethodSignature */:
if (!ts.hasDynamicName(node)) {
addNodeWithRecursiveChild(node, node.body);
}
break;
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
if (!ts.hasDynamicName(node)) {
addLeafNode(node);
}
break;
case 236 /* ImportClause */:
var importClause = node;
// Handle default import case e.g.:
// import d from "mod";
if (importClause.name) {
addLeafNode(importClause);
}
// Handle named bindings in imports e.g.:
// import * as NS from "mod";
// import {a, b as B} from "mod";
var namedBindings = importClause.namedBindings;
if (namedBindings) {
if (namedBindings.kind === 237 /* NamespaceImport */) {
addLeafNode(namedBindings);
}
else {
for (var _b = 0, _c = namedBindings.elements; _b < _c.length; _b++) {
var element = _c[_b];
addLeafNode(element);
}
}
}
break;
case 174 /* BindingElement */:
case 223 /* VariableDeclaration */:
var decl = node;
var name_46 = decl.name;
if (ts.isBindingPattern(name_46)) {
addChildrenRecursively(name_46);
}
else if (decl.initializer && isFunctionOrClassExpression(decl.initializer)) {
// For `const x = function() {}`, just use the function node, not the const.
addChildrenRecursively(decl.initializer);
}
else {
addNodeWithRecursiveChild(decl, decl.initializer);
}
break;
case 185 /* ArrowFunction */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
addNodeWithRecursiveChild(node, node.body);
break;
case 229 /* EnumDeclaration */:
startNode(node);
for (var _d = 0, _e = node.members; _d < _e.length; _d++) {
var member = _e[_d];
if (!isComputedProperty(member)) {
addLeafNode(member);
}
}
endNode();
break;
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
startNode(node);
for (var _f = 0, _g = node.members; _f < _g.length; _f++) {
var member = _g[_f];
addChildrenRecursively(member);
}
endNode();
break;
case 230 /* ModuleDeclaration */:
addNodeWithRecursiveChild(node, getInteriorModule(node).body);
break;
case 243 /* ExportSpecifier */:
case 234 /* ImportEqualsDeclaration */:
case 155 /* IndexSignature */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 228 /* TypeAliasDeclaration */:
addLeafNode(node);
break;
default:
ts.forEach(node.jsDocComments, function (jsDocComment) {
ts.forEach(jsDocComment.tags, function (tag) {
if (tag.kind === 284 /* JSDocTypedefTag */) {
addLeafNode(tag);
}
});
});
ts.forEachChild(node, addChildrenRecursively);
}
}
/** Merge declarations of the same kind. */
function mergeChildren(children) {
var nameToItems = ts.createMap();
ts.filterMutate(children, function (child) {
var decl = child.node;
var name = decl.name && nodeText(decl.name);
if (!name) {
// Anonymous items are never merged.
return true;
}
var itemsWithSameName = nameToItems[name];
if (!itemsWithSameName) {
nameToItems[name] = child;
return true;
}
if (itemsWithSameName instanceof Array) {
for (var _i = 0, itemsWithSameName_1 = itemsWithSameName; _i < itemsWithSameName_1.length; _i++) {
var itemWithSameName = itemsWithSameName_1[_i];
if (tryMerge(itemWithSameName, child)) {
return false;
}
}
itemsWithSameName.push(child);
return true;
}
else {
var itemWithSameName = itemsWithSameName;
if (tryMerge(itemWithSameName, child)) {
return false;
}
nameToItems[name] = [itemWithSameName, child];
return true;
}
function tryMerge(a, b) {
if (shouldReallyMerge(a.node, b.node)) {
merge(a, b);
return true;
}
return false;
}
});
/** a and b have the same name, but they may not be mergeable. */
function shouldReallyMerge(a, b) {
return a.kind === b.kind && (a.kind !== 230 /* ModuleDeclaration */ || areSameModule(a, b));
// We use 1 NavNode to represent 'A.B.C', but there are multiple source nodes.
// Only merge module nodes that have the same chain. Don't merge 'A.B.C' with 'A'!
function areSameModule(a, b) {
if (a.body.kind !== b.body.kind) {
return false;
}
if (a.body.kind !== 230 /* ModuleDeclaration */) {
return true;
}
return areSameModule(a.body, b.body);
}
}
/** Merge source into target. Source should be thrown away after this is called. */
function merge(target, source) {
target.additionalNodes = target.additionalNodes || [];
target.additionalNodes.push(source.node);
if (source.additionalNodes) {
(_a = target.additionalNodes).push.apply(_a, source.additionalNodes);
}
target.children = ts.concatenate(target.children, source.children);
if (target.children) {
mergeChildren(target.children);
sortChildren(target.children);
}
var _a;
}
}
/** Recursively ensure that each NavNode's children are in sorted order. */
function sortChildren(children) {
children.sort(compareChildren);
}
function compareChildren(child1, child2) {
var name1 = tryGetName(child1.node), name2 = tryGetName(child2.node);
if (name1 && name2) {
var cmp = localeCompareFix(name1, name2);
return cmp !== 0 ? cmp : navigationBarNodeKind(child1) - navigationBarNodeKind(child2);
}
else {
return name1 ? 1 : name2 ? -1 : navigationBarNodeKind(child1) - navigationBarNodeKind(child2);
}
}
// Intl is missing in Safari, and node 0.10 treats "a" as greater than "B".
var localeCompareIsCorrect = ts.collator && ts.collator.compare("a", "B") < 0;
var localeCompareFix = localeCompareIsCorrect ? ts.collator.compare : function (a, b) {
// This isn't perfect, but it passes all of our tests.
for (var i = 0; i < Math.min(a.length, b.length); i++) {
var chA = a.charAt(i), chB = b.charAt(i);
if (chA === "\"" && chB === "'") {
return 1;
}
if (chA === "'" && chB === "\"") {
return -1;
}
var cmp = ts.compareStrings(chA.toLocaleLowerCase(), chB.toLocaleLowerCase());
if (cmp !== 0) {
return cmp;
}
}
return a.length - b.length;
};
/**
* This differs from getItemName because this is just used for sorting.
* We only sort nodes by name that have a more-or-less "direct" name, as opposed to `new()` and the like.
* So `new()` can still come before an `aardvark` method.
*/
function tryGetName(node) {
if (node.kind === 230 /* ModuleDeclaration */) {
return getModuleName(node);
}
var decl = node;
if (decl.name) {
return ts.getPropertyNameForPropertyNameNode(decl.name);
}
switch (node.kind) {
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 197 /* ClassExpression */:
return getFunctionOrClassName(node);
case 284 /* JSDocTypedefTag */:
return getJSDocTypedefTagName(node);
default:
return undefined;
}
}
function getItemName(node) {
if (node.kind === 230 /* ModuleDeclaration */) {
return getModuleName(node);
}
var name = node.name;
if (name) {
var text = nodeText(name);
if (text.length > 0) {
return text;
}
}
switch (node.kind) {
case 261 /* SourceFile */:
var sourceFile = node;
return ts.isExternalModule(sourceFile)
? "\"" + ts.escapeString(ts.getBaseFileName(ts.removeFileExtension(ts.normalizePath(sourceFile.fileName)))) + "\""
: "<global>";
case 185 /* ArrowFunction */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
if (ts.getModifierFlags(node) & 512 /* Default */) {
return "default";
}
// We may get a string with newlines or other whitespace in the case of an object dereference
// (eg: "app\n.onactivated"), so we should remove the whitespace for readabiltiy in the
// navigation bar.
return getFunctionOrClassName(node);
case 150 /* Constructor */:
return "constructor";
case 154 /* ConstructSignature */:
return "new()";
case 153 /* CallSignature */:
return "()";
case 155 /* IndexSignature */:
return "[]";
case 284 /* JSDocTypedefTag */:
return getJSDocTypedefTagName(node);
default:
return "<unknown>";
}
}
function getJSDocTypedefTagName(node) {
if (node.name) {
return node.name.text;
}
else {
var parentNode = node.parent && node.parent.parent;
if (parentNode && parentNode.kind === 205 /* VariableStatement */) {
if (parentNode.declarationList.declarations.length > 0) {
var nameIdentifier = parentNode.declarationList.declarations[0].name;
if (nameIdentifier.kind === 70 /* Identifier */) {
return nameIdentifier.text;
}
}
}
return "<typedef>";
}
}
/** Flattens the NavNode tree to a list, keeping only the top-level items. */
function topLevelItems(root) {
var topLevel = [];
function recur(item) {
if (isTopLevel(item)) {
topLevel.push(item);
if (item.children) {
for (var _i = 0, _a = item.children; _i < _a.length; _i++) {
var child = _a[_i];
recur(child);
}
}
}
}
recur(root);
return topLevel;
function isTopLevel(item) {
switch (navigationBarNodeKind(item)) {
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 229 /* EnumDeclaration */:
case 227 /* InterfaceDeclaration */:
case 230 /* ModuleDeclaration */:
case 261 /* SourceFile */:
case 228 /* TypeAliasDeclaration */:
case 284 /* JSDocTypedefTag */:
return true;
case 150 /* Constructor */:
case 149 /* MethodDeclaration */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 223 /* VariableDeclaration */:
return hasSomeImportantChild(item);
case 185 /* ArrowFunction */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
return isTopLevelFunctionDeclaration(item);
default:
return false;
}
function isTopLevelFunctionDeclaration(item) {
if (!item.node.body) {
return false;
}
switch (navigationBarNodeKind(item.parent)) {
case 231 /* ModuleBlock */:
case 261 /* SourceFile */:
case 149 /* MethodDeclaration */:
case 150 /* Constructor */:
return true;
default:
return hasSomeImportantChild(item);
}
}
function hasSomeImportantChild(item) {
return ts.forEach(item.children, function (child) {
var childKind = navigationBarNodeKind(child);
return childKind !== 223 /* VariableDeclaration */ && childKind !== 174 /* BindingElement */;
});
}
}
}
// NavigationBarItem requires an array, but will not mutate it, so just give it this for performance.
var emptyChildItemArray = [];
function convertToTree(n) {
return {
text: getItemName(n.node),
kind: ts.getNodeKind(n.node),
kindModifiers: ts.getNodeModifiers(n.node),
spans: getSpans(n),
childItems: ts.map(n.children, convertToTree)
};
}
function convertToTopLevelItem(n) {
return {
text: getItemName(n.node),
kind: ts.getNodeKind(n.node),
kindModifiers: ts.getNodeModifiers(n.node),
spans: getSpans(n),
childItems: ts.map(n.children, convertToChildItem) || emptyChildItemArray,
indent: n.indent,
bolded: false,
grayed: false
};
function convertToChildItem(n) {
return {
text: getItemName(n.node),
kind: ts.getNodeKind(n.node),
kindModifiers: ts.getNodeModifiers(n.node),
spans: getSpans(n),
childItems: emptyChildItemArray,
indent: 0,
bolded: false,
grayed: false
};
}
}
function getSpans(n) {
var spans = [getNodeSpan(n.node)];
if (n.additionalNodes) {
for (var _i = 0, _a = n.additionalNodes; _i < _a.length; _i++) {
var node = _a[_i];
spans.push(getNodeSpan(node));
}
}
return spans;
}
function getModuleName(moduleDeclaration) {
// We want to maintain quotation marks.
if (ts.isAmbientModule(moduleDeclaration)) {
return ts.getTextOfNode(moduleDeclaration.name);
}
// Otherwise, we need to aggregate each identifier to build up the qualified name.
var result = [];
result.push(moduleDeclaration.name.text);
while (moduleDeclaration.body && moduleDeclaration.body.kind === 230 /* ModuleDeclaration */) {
moduleDeclaration = moduleDeclaration.body;
result.push(moduleDeclaration.name.text);
}
return result.join(".");
}
/**
* For 'module A.B.C', we want to get the node for 'C'.
* We store 'A' as associated with a NavNode, and use getModuleName to traverse down again.
*/
function getInteriorModule(decl) {
return decl.body.kind === 230 /* ModuleDeclaration */ ? getInteriorModule(decl.body) : decl;
}
function isComputedProperty(member) {
return !member.name || member.name.kind === 142 /* ComputedPropertyName */;
}
function getNodeSpan(node) {
return node.kind === 261 /* SourceFile */
? ts.createTextSpanFromBounds(node.getFullStart(), node.getEnd())
: ts.createTextSpanFromBounds(node.getStart(curSourceFile), node.getEnd());
}
function getFunctionOrClassName(node) {
if (node.name && ts.getFullWidth(node.name) > 0) {
return ts.declarationNameToString(node.name);
}
else if (node.parent.kind === 223 /* VariableDeclaration */) {
return ts.declarationNameToString(node.parent.name);
}
else if (node.parent.kind === 192 /* BinaryExpression */ &&
node.parent.operatorToken.kind === 57 /* EqualsToken */) {
return nodeText(node.parent.left).replace(whiteSpaceRegex, "");
}
else if (node.parent.kind === 257 /* PropertyAssignment */ && node.parent.name) {
return nodeText(node.parent.name);
}
else if (ts.getModifierFlags(node) & 512 /* Default */) {
return "default";
}
else {
return ts.isClassLike(node) ? "<class>" : "<function>";
}
}
function isFunctionOrClassExpression(node) {
return node.kind === 184 /* FunctionExpression */ || node.kind === 185 /* ArrowFunction */ || node.kind === 197 /* ClassExpression */;
}
/**
* Matches all whitespace characters in a string. Eg:
*
* "app.
*
* onactivated"
*
* matches because of the newline, whereas
*
* "app.onactivated"
*
* does not match.
*/
var whiteSpaceRegex = /\s+/g;
})(NavigationBar = ts.NavigationBar || (ts.NavigationBar = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var OutliningElementsCollector;
(function (OutliningElementsCollector) {
function collectElements(sourceFile) {
var elements = [];
var collapseText = "...";
function addOutliningSpan(hintSpanNode, startElement, endElement, autoCollapse) {
if (hintSpanNode && startElement && endElement) {
var span_12 = {
textSpan: ts.createTextSpanFromBounds(startElement.pos, endElement.end),
hintSpan: ts.createTextSpanFromBounds(hintSpanNode.getStart(), hintSpanNode.end),
bannerText: collapseText,
autoCollapse: autoCollapse
};
elements.push(span_12);
}
}
function addOutliningSpanComments(commentSpan, autoCollapse) {
if (commentSpan) {
var span_13 = {
textSpan: ts.createTextSpanFromBounds(commentSpan.pos, commentSpan.end),
hintSpan: ts.createTextSpanFromBounds(commentSpan.pos, commentSpan.end),
bannerText: collapseText,
autoCollapse: autoCollapse
};
elements.push(span_13);
}
}
function addOutliningForLeadingCommentsForNode(n) {
var comments = ts.getLeadingCommentRangesOfNode(n, sourceFile);
if (comments) {
var firstSingleLineCommentStart = -1;
var lastSingleLineCommentEnd = -1;
var isFirstSingleLineComment = true;
var singleLineCommentCount = 0;
for (var _i = 0, comments_4 = comments; _i < comments_4.length; _i++) {
var currentComment = comments_4[_i];
// For single line comments, combine consecutive ones (2 or more) into
// a single span from the start of the first till the end of the last
if (currentComment.kind === 2 /* SingleLineCommentTrivia */) {
if (isFirstSingleLineComment) {
firstSingleLineCommentStart = currentComment.pos;
}
isFirstSingleLineComment = false;
lastSingleLineCommentEnd = currentComment.end;
singleLineCommentCount++;
}
else if (currentComment.kind === 3 /* MultiLineCommentTrivia */) {
combineAndAddMultipleSingleLineComments(singleLineCommentCount, firstSingleLineCommentStart, lastSingleLineCommentEnd);
addOutliningSpanComments(currentComment, /*autoCollapse*/ false);
singleLineCommentCount = 0;
lastSingleLineCommentEnd = -1;
isFirstSingleLineComment = true;
}
}
combineAndAddMultipleSingleLineComments(singleLineCommentCount, firstSingleLineCommentStart, lastSingleLineCommentEnd);
}
}
function combineAndAddMultipleSingleLineComments(count, start, end) {
// Only outline spans of two or more consecutive single line comments
if (count > 1) {
var multipleSingleLineComments = {
pos: start,
end: end,
kind: 2 /* SingleLineCommentTrivia */
};
addOutliningSpanComments(multipleSingleLineComments, /*autoCollapse*/ false);
}
}
function autoCollapse(node) {
return ts.isFunctionBlock(node) && node.parent.kind !== 185 /* ArrowFunction */;
}
var depth = 0;
var maxDepth = 20;
function walk(n) {
if (depth > maxDepth) {
return;
}
if (ts.isDeclaration(n)) {
addOutliningForLeadingCommentsForNode(n);
}
switch (n.kind) {
case 204 /* Block */:
if (!ts.isFunctionBlock(n)) {
var parent_20 = n.parent;
var openBrace = ts.findChildOfKind(n, 16 /* OpenBraceToken */, sourceFile);
var closeBrace = ts.findChildOfKind(n, 17 /* CloseBraceToken */, sourceFile);
// Check if the block is standalone, or 'attached' to some parent statement.
// If the latter, we want to collapse the block, but consider its hint span
// to be the entire span of the parent.
if (parent_20.kind === 209 /* DoStatement */ ||
parent_20.kind === 212 /* ForInStatement */ ||
parent_20.kind === 213 /* ForOfStatement */ ||
parent_20.kind === 211 /* ForStatement */ ||
parent_20.kind === 208 /* IfStatement */ ||
parent_20.kind === 210 /* WhileStatement */ ||
parent_20.kind === 217 /* WithStatement */ ||
parent_20.kind === 256 /* CatchClause */) {
addOutliningSpan(parent_20, openBrace, closeBrace, autoCollapse(n));
break;
}
if (parent_20.kind === 221 /* TryStatement */) {
// Could be the try-block, or the finally-block.
var tryStatement = parent_20;
if (tryStatement.tryBlock === n) {
addOutliningSpan(parent_20, openBrace, closeBrace, autoCollapse(n));
break;
}
else if (tryStatement.finallyBlock === n) {
var finallyKeyword = ts.findChildOfKind(tryStatement, 86 /* FinallyKeyword */, sourceFile);
if (finallyKeyword) {
addOutliningSpan(finallyKeyword, openBrace, closeBrace, autoCollapse(n));
break;
}
}
}
// Block was a standalone block. In this case we want to only collapse
// the span of the block, independent of any parent span.
var span_14 = ts.createTextSpanFromBounds(n.getStart(), n.end);
elements.push({
textSpan: span_14,
hintSpan: span_14,
bannerText: collapseText,
autoCollapse: autoCollapse(n)
});
break;
}
// Fallthrough.
case 231 /* ModuleBlock */: {
var openBrace = ts.findChildOfKind(n, 16 /* OpenBraceToken */, sourceFile);
var closeBrace = ts.findChildOfKind(n, 17 /* CloseBraceToken */, sourceFile);
addOutliningSpan(n.parent, openBrace, closeBrace, autoCollapse(n));
break;
}
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
case 229 /* EnumDeclaration */:
case 176 /* ObjectLiteralExpression */:
case 232 /* CaseBlock */: {
var openBrace = ts.findChildOfKind(n, 16 /* OpenBraceToken */, sourceFile);
var closeBrace = ts.findChildOfKind(n, 17 /* CloseBraceToken */, sourceFile);
addOutliningSpan(n, openBrace, closeBrace, autoCollapse(n));
break;
}
case 175 /* ArrayLiteralExpression */:
var openBracket = ts.findChildOfKind(n, 20 /* OpenBracketToken */, sourceFile);
var closeBracket = ts.findChildOfKind(n, 21 /* CloseBracketToken */, sourceFile);
addOutliningSpan(n, openBracket, closeBracket, autoCollapse(n));
break;
}
depth++;
ts.forEachChild(n, walk);
depth--;
}
walk(sourceFile);
return elements;
}
OutliningElementsCollector.collectElements = collectElements;
})(OutliningElementsCollector = ts.OutliningElementsCollector || (ts.OutliningElementsCollector = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
// Note(cyrusn): this enum is ordered from strongest match type to weakest match type.
var PatternMatchKind;
(function (PatternMatchKind) {
PatternMatchKind[PatternMatchKind["exact"] = 0] = "exact";
PatternMatchKind[PatternMatchKind["prefix"] = 1] = "prefix";
PatternMatchKind[PatternMatchKind["substring"] = 2] = "substring";
PatternMatchKind[PatternMatchKind["camelCase"] = 3] = "camelCase";
})(PatternMatchKind = ts.PatternMatchKind || (ts.PatternMatchKind = {}));
function createPatternMatch(kind, punctuationStripped, isCaseSensitive, camelCaseWeight) {
return {
kind: kind,
punctuationStripped: punctuationStripped,
isCaseSensitive: isCaseSensitive,
camelCaseWeight: camelCaseWeight
};
}
function createPatternMatcher(pattern) {
// We'll often see the same candidate string many times when searching (For example, when
// we see the name of a module that is used everywhere, or the name of an overload). As
// such, we cache the information we compute about the candidate for the life of this
// pattern matcher so we don't have to compute it multiple times.
var stringToWordSpans = ts.createMap();
pattern = pattern.trim();
var dotSeparatedSegments = pattern.split(".").map(function (p) { return createSegment(p.trim()); });
var invalidPattern = dotSeparatedSegments.length === 0 || ts.forEach(dotSeparatedSegments, segmentIsInvalid);
return {
getMatches: getMatches,
getMatchesForLastSegmentOfPattern: getMatchesForLastSegmentOfPattern,
patternContainsDots: dotSeparatedSegments.length > 1
};
// Quick checks so we can bail out when asked to match a candidate.
function skipMatch(candidate) {
return invalidPattern || !candidate;
}
function getMatchesForLastSegmentOfPattern(candidate) {
if (skipMatch(candidate)) {
return undefined;
}
return matchSegment(candidate, ts.lastOrUndefined(dotSeparatedSegments));
}
function getMatches(candidateContainers, candidate) {
if (skipMatch(candidate)) {
return undefined;
}
// First, check that the last part of the dot separated pattern matches the name of the
// candidate. If not, then there's no point in proceeding and doing the more
// expensive work.
var candidateMatch = matchSegment(candidate, ts.lastOrUndefined(dotSeparatedSegments));
if (!candidateMatch) {
return undefined;
}
candidateContainers = candidateContainers || [];
// -1 because the last part was checked against the name, and only the rest
// of the parts are checked against the container.
if (dotSeparatedSegments.length - 1 > candidateContainers.length) {
// There weren't enough container parts to match against the pattern parts.
// So this definitely doesn't match.
return undefined;
}
// So far so good. Now break up the container for the candidate and check if all
// the dotted parts match up correctly.
var totalMatch = candidateMatch;
for (var i = dotSeparatedSegments.length - 2, j = candidateContainers.length - 1; i >= 0; i -= 1, j -= 1) {
var segment = dotSeparatedSegments[i];
var containerName = candidateContainers[j];
var containerMatch = matchSegment(containerName, segment);
if (!containerMatch) {
// This container didn't match the pattern piece. So there's no match at all.
return undefined;
}
ts.addRange(totalMatch, containerMatch);
}
// Success, this symbol's full name matched against the dotted name the user was asking
// about.
return totalMatch;
}
function getWordSpans(word) {
if (!(word in stringToWordSpans)) {
stringToWordSpans[word] = breakIntoWordSpans(word);
}
return stringToWordSpans[word];
}
function matchTextChunk(candidate, chunk, punctuationStripped) {
var index = indexOfIgnoringCase(candidate, chunk.textLowerCase);
if (index === 0) {
if (chunk.text.length === candidate.length) {
// a) Check if the part matches the candidate entirely, in an case insensitive or
// sensitive manner. If it does, return that there was an exact match.
return createPatternMatch(PatternMatchKind.exact, punctuationStripped, /*isCaseSensitive:*/ candidate === chunk.text);
}
else {
// b) Check if the part is a prefix of the candidate, in a case insensitive or sensitive
// manner. If it does, return that there was a prefix match.
return createPatternMatch(PatternMatchKind.prefix, punctuationStripped, /*isCaseSensitive:*/ ts.startsWith(candidate, chunk.text));
}
}
var isLowercase = chunk.isLowerCase;
if (isLowercase) {
if (index > 0) {
// c) If the part is entirely lowercase, then check if it is contained anywhere in the
// candidate in a case insensitive manner. If so, return that there was a substring
// match.
//
// Note: We only have a substring match if the lowercase part is prefix match of some
// word part. That way we don't match something like 'Class' when the user types 'a'.
// But we would match 'FooAttribute' (since 'Attribute' starts with 'a').
var wordSpans = getWordSpans(candidate);
for (var _i = 0, wordSpans_1 = wordSpans; _i < wordSpans_1.length; _i++) {
var span_15 = wordSpans_1[_i];
if (partStartsWith(candidate, span_15, chunk.text, /*ignoreCase:*/ true)) {
return createPatternMatch(PatternMatchKind.substring, punctuationStripped,
/*isCaseSensitive:*/ partStartsWith(candidate, span_15, chunk.text, /*ignoreCase:*/ false));
}
}
}
}
else {
// d) If the part was not entirely lowercase, then check if it is contained in the
// candidate in a case *sensitive* manner. If so, return that there was a substring
// match.
if (candidate.indexOf(chunk.text) > 0) {
return createPatternMatch(PatternMatchKind.substring, punctuationStripped, /*isCaseSensitive:*/ true);
}
}
if (!isLowercase) {
// e) If the part was not entirely lowercase, then attempt a camel cased match as well.
if (chunk.characterSpans.length > 0) {
var candidateParts = getWordSpans(candidate);
var camelCaseWeight = tryCamelCaseMatch(candidate, candidateParts, chunk, /*ignoreCase:*/ false);
if (camelCaseWeight !== undefined) {
return createPatternMatch(PatternMatchKind.camelCase, punctuationStripped, /*isCaseSensitive:*/ true, /*camelCaseWeight:*/ camelCaseWeight);
}
camelCaseWeight = tryCamelCaseMatch(candidate, candidateParts, chunk, /*ignoreCase:*/ true);
if (camelCaseWeight !== undefined) {
return createPatternMatch(PatternMatchKind.camelCase, punctuationStripped, /*isCaseSensitive:*/ false, /*camelCaseWeight:*/ camelCaseWeight);
}
}
}
if (isLowercase) {
// f) Is the pattern a substring of the candidate starting on one of the candidate's word boundaries?
// We could check every character boundary start of the candidate for the pattern. However, that's
// an m * n operation in the wost case. Instead, find the first instance of the pattern
// substring, and see if it starts on a capital letter. It seems unlikely that the user will try to
// filter the list based on a substring that starts on a capital letter and also with a lowercase one.
// (Pattern: fogbar, Candidate: quuxfogbarFogBar).
if (chunk.text.length < candidate.length) {
if (index > 0 && isUpperCaseLetter(candidate.charCodeAt(index))) {
return createPatternMatch(PatternMatchKind.substring, punctuationStripped, /*isCaseSensitive:*/ false);
}
}
}
return undefined;
}
function containsSpaceOrAsterisk(text) {
for (var i = 0; i < text.length; i++) {
var ch = text.charCodeAt(i);
if (ch === 32 /* space */ || ch === 42 /* asterisk */) {
return true;
}
}
return false;
}
function matchSegment(candidate, segment) {
// First check if the segment matches as is. This is also useful if the segment contains
// characters we would normally strip when splitting into parts that we also may want to
// match in the candidate. For example if the segment is "@int" and the candidate is
// "@int", then that will show up as an exact match here.
//
// Note: if the segment contains a space or an asterisk then we must assume that it's a
// multi-word segment.
if (!containsSpaceOrAsterisk(segment.totalTextChunk.text)) {
var match = matchTextChunk(candidate, segment.totalTextChunk, /*punctuationStripped:*/ false);
if (match) {
return [match];
}
}
// The logic for pattern matching is now as follows:
//
// 1) Break the segment passed in into words. Breaking is rather simple and a
// good way to think about it that if gives you all the individual alphanumeric words
// of the pattern.
//
// 2) For each word try to match the word against the candidate value.
//
// 3) Matching is as follows:
//
// a) Check if the word matches the candidate entirely, in an case insensitive or
// sensitive manner. If it does, return that there was an exact match.
//
// b) Check if the word is a prefix of the candidate, in a case insensitive or
// sensitive manner. If it does, return that there was a prefix match.
//
// c) If the word is entirely lowercase, then check if it is contained anywhere in the
// candidate in a case insensitive manner. If so, return that there was a substring
// match.
//
// Note: We only have a substring match if the lowercase part is prefix match of
// some word part. That way we don't match something like 'Class' when the user
// types 'a'. But we would match 'FooAttribute' (since 'Attribute' starts with
// 'a').
//
// d) If the word was not entirely lowercase, then check if it is contained in the
// candidate in a case *sensitive* manner. If so, return that there was a substring
// match.
//
// e) If the word was not entirely lowercase, then attempt a camel cased match as
// well.
//
// f) The word is all lower case. Is it a case insensitive substring of the candidate starting
// on a part boundary of the candidate?
//
// Only if all words have some sort of match is the pattern considered matched.
var subWordTextChunks = segment.subWordTextChunks;
var matches = undefined;
for (var _i = 0, subWordTextChunks_1 = subWordTextChunks; _i < subWordTextChunks_1.length; _i++) {
var subWordTextChunk = subWordTextChunks_1[_i];
// Try to match the candidate with this word
var result = matchTextChunk(candidate, subWordTextChunk, /*punctuationStripped:*/ true);
if (!result) {
return undefined;
}
matches = matches || [];
matches.push(result);
}
return matches;
}
function partStartsWith(candidate, candidateSpan, pattern, ignoreCase, patternSpan) {
var patternPartStart = patternSpan ? patternSpan.start : 0;
var patternPartLength = patternSpan ? patternSpan.length : pattern.length;
if (patternPartLength > candidateSpan.length) {
// Pattern part is longer than the candidate part. There can never be a match.
return false;
}
if (ignoreCase) {
for (var i = 0; i < patternPartLength; i++) {
var ch1 = pattern.charCodeAt(patternPartStart + i);
var ch2 = candidate.charCodeAt(candidateSpan.start + i);
if (toLowerCase(ch1) !== toLowerCase(ch2)) {
return false;
}
}
}
else {
for (var i = 0; i < patternPartLength; i++) {
var ch1 = pattern.charCodeAt(patternPartStart + i);
var ch2 = candidate.charCodeAt(candidateSpan.start + i);
if (ch1 !== ch2) {
return false;
}
}
}
return true;
}
function tryCamelCaseMatch(candidate, candidateParts, chunk, ignoreCase) {
var chunkCharacterSpans = chunk.characterSpans;
// Note: we may have more pattern parts than candidate parts. This is because multiple
// pattern parts may match a candidate part. For example "SiUI" against "SimpleUI".
// We'll have 3 pattern parts Si/U/I against two candidate parts Simple/UI. However, U
// and I will both match in UI.
var currentCandidate = 0;
var currentChunkSpan = 0;
var firstMatch = undefined;
var contiguous = undefined;
while (true) {
// Let's consider our termination cases
if (currentChunkSpan === chunkCharacterSpans.length) {
// We did match! We shall assign a weight to this
var weight = 0;
// Was this contiguous?
if (contiguous) {
weight += 1;
}
// Did we start at the beginning of the candidate?
if (firstMatch === 0) {
weight += 2;
}
return weight;
}
else if (currentCandidate === candidateParts.length) {
// No match, since we still have more of the pattern to hit
return undefined;
}
var candidatePart = candidateParts[currentCandidate];
var gotOneMatchThisCandidate = false;
// Consider the case of matching SiUI against SimpleUIElement. The candidate parts
// will be Simple/UI/Element, and the pattern parts will be Si/U/I. We'll match 'Si'
// against 'Simple' first. Then we'll match 'U' against 'UI'. However, we want to
// still keep matching pattern parts against that candidate part.
for (; currentChunkSpan < chunkCharacterSpans.length; currentChunkSpan++) {
var chunkCharacterSpan = chunkCharacterSpans[currentChunkSpan];
if (gotOneMatchThisCandidate) {
// We've already gotten one pattern part match in this candidate. We will
// only continue trying to consumer pattern parts if the last part and this
// part are both upper case.
if (!isUpperCaseLetter(chunk.text.charCodeAt(chunkCharacterSpans[currentChunkSpan - 1].start)) ||
!isUpperCaseLetter(chunk.text.charCodeAt(chunkCharacterSpans[currentChunkSpan].start))) {
break;
}
}
if (!partStartsWith(candidate, candidatePart, chunk.text, ignoreCase, chunkCharacterSpan)) {
break;
}
gotOneMatchThisCandidate = true;
firstMatch = firstMatch === undefined ? currentCandidate : firstMatch;
// If we were contiguous, then keep that value. If we weren't, then keep that
// value. If we don't know, then set the value to 'true' as an initial match is
// obviously contiguous.
contiguous = contiguous === undefined ? true : contiguous;
candidatePart = ts.createTextSpan(candidatePart.start + chunkCharacterSpan.length, candidatePart.length - chunkCharacterSpan.length);
}
// Check if we matched anything at all. If we didn't, then we need to unset the
// contiguous bit if we currently had it set.
// If we haven't set the bit yet, then that means we haven't matched anything so
// far, and we don't want to change that.
if (!gotOneMatchThisCandidate && contiguous !== undefined) {
contiguous = false;
}
// Move onto the next candidate.
currentCandidate++;
}
}
}
ts.createPatternMatcher = createPatternMatcher;
function createSegment(text) {
return {
totalTextChunk: createTextChunk(text),
subWordTextChunks: breakPatternIntoTextChunks(text)
};
}
// A segment is considered invalid if we couldn't find any words in it.
function segmentIsInvalid(segment) {
return segment.subWordTextChunks.length === 0;
}
function isUpperCaseLetter(ch) {
// Fast check for the ascii range.
if (ch >= 65 /* A */ && ch <= 90 /* Z */) {
return true;
}
if (ch < 127 /* maxAsciiCharacter */ || !ts.isUnicodeIdentifierStart(ch, 5 /* Latest */)) {
return false;
}
// TODO: find a way to determine this for any unicode characters in a
// non-allocating manner.
var str = String.fromCharCode(ch);
return str === str.toUpperCase();
}
function isLowerCaseLetter(ch) {
// Fast check for the ascii range.
if (ch >= 97 /* a */ && ch <= 122 /* z */) {
return true;
}
if (ch < 127 /* maxAsciiCharacter */ || !ts.isUnicodeIdentifierStart(ch, 5 /* Latest */)) {
return false;
}
// TODO: find a way to determine this for any unicode characters in a
// non-allocating manner.
var str = String.fromCharCode(ch);
return str === str.toLowerCase();
}
// Assumes 'value' is already lowercase.
function indexOfIgnoringCase(string, value) {
for (var i = 0, n = string.length - value.length; i <= n; i++) {
if (startsWithIgnoringCase(string, value, i)) {
return i;
}
}
return -1;
}
// Assumes 'value' is already lowercase.
function startsWithIgnoringCase(string, value, start) {
for (var i = 0, n = value.length; i < n; i++) {
var ch1 = toLowerCase(string.charCodeAt(i + start));
var ch2 = value.charCodeAt(i);
if (ch1 !== ch2) {
return false;
}
}
return true;
}
function toLowerCase(ch) {
// Fast convert for the ascii range.
if (ch >= 65 /* A */ && ch <= 90 /* Z */) {
return 97 /* a */ + (ch - 65 /* A */);
}
if (ch < 127 /* maxAsciiCharacter */) {
return ch;
}
// TODO: find a way to compute this for any unicode characters in a
// non-allocating manner.
return String.fromCharCode(ch).toLowerCase().charCodeAt(0);
}
function isDigit(ch) {
// TODO(cyrusn): Find a way to support this for unicode digits.
return ch >= 48 /* _0 */ && ch <= 57 /* _9 */;
}
function isWordChar(ch) {
return isUpperCaseLetter(ch) || isLowerCaseLetter(ch) || isDigit(ch) || ch === 95 /* _ */ || ch === 36 /* $ */;
}
function breakPatternIntoTextChunks(pattern) {
var result = [];
var wordStart = 0;
var wordLength = 0;
for (var i = 0; i < pattern.length; i++) {
var ch = pattern.charCodeAt(i);
if (isWordChar(ch)) {
if (wordLength === 0) {
wordStart = i;
}
wordLength++;
}
else {
if (wordLength > 0) {
result.push(createTextChunk(pattern.substr(wordStart, wordLength)));
wordLength = 0;
}
}
}
if (wordLength > 0) {
result.push(createTextChunk(pattern.substr(wordStart, wordLength)));
}
return result;
}
function createTextChunk(text) {
var textLowerCase = text.toLowerCase();
return {
text: text,
textLowerCase: textLowerCase,
isLowerCase: text === textLowerCase,
characterSpans: breakIntoCharacterSpans(text)
};
}
/* @internal */ function breakIntoCharacterSpans(identifier) {
return breakIntoSpans(identifier, /*word:*/ false);
}
ts.breakIntoCharacterSpans = breakIntoCharacterSpans;
/* @internal */ function breakIntoWordSpans(identifier) {
return breakIntoSpans(identifier, /*word:*/ true);
}
ts.breakIntoWordSpans = breakIntoWordSpans;
function breakIntoSpans(identifier, word) {
var result = [];
var wordStart = 0;
for (var i = 1, n = identifier.length; i < n; i++) {
var lastIsDigit = isDigit(identifier.charCodeAt(i - 1));
var currentIsDigit = isDigit(identifier.charCodeAt(i));
var hasTransitionFromLowerToUpper = transitionFromLowerToUpper(identifier, word, i);
var hasTransitionFromUpperToLower = transitionFromUpperToLower(identifier, word, i, wordStart);
if (charIsPunctuation(identifier.charCodeAt(i - 1)) ||
charIsPunctuation(identifier.charCodeAt(i)) ||
lastIsDigit !== currentIsDigit ||
hasTransitionFromLowerToUpper ||
hasTransitionFromUpperToLower) {
if (!isAllPunctuation(identifier, wordStart, i)) {
result.push(ts.createTextSpan(wordStart, i - wordStart));
}
wordStart = i;
}
}
if (!isAllPunctuation(identifier, wordStart, identifier.length)) {
result.push(ts.createTextSpan(wordStart, identifier.length - wordStart));
}
return result;
}
function charIsPunctuation(ch) {
switch (ch) {
case 33 /* exclamation */:
case 34 /* doubleQuote */:
case 35 /* hash */:
case 37 /* percent */:
case 38 /* ampersand */:
case 39 /* singleQuote */:
case 40 /* openParen */:
case 41 /* closeParen */:
case 42 /* asterisk */:
case 44 /* comma */:
case 45 /* minus */:
case 46 /* dot */:
case 47 /* slash */:
case 58 /* colon */:
case 59 /* semicolon */:
case 63 /* question */:
case 64 /* at */:
case 91 /* openBracket */:
case 92 /* backslash */:
case 93 /* closeBracket */:
case 95 /* _ */:
case 123 /* openBrace */:
case 125 /* closeBrace */:
return true;
}
return false;
}
function isAllPunctuation(identifier, start, end) {
for (var i = start; i < end; i++) {
var ch = identifier.charCodeAt(i);
// We don't consider _ or $ as punctuation as there may be things with that name.
if (!charIsPunctuation(ch) || ch === 95 /* _ */ || ch === 36 /* $ */) {
return false;
}
}
return true;
}
function transitionFromUpperToLower(identifier, word, index, wordStart) {
if (word) {
// Cases this supports:
// 1) IDisposable -> I, Disposable
// 2) UIElement -> UI, Element
// 3) HTMLDocument -> HTML, Document
//
// etc.
if (index !== wordStart &&
index + 1 < identifier.length) {
var currentIsUpper = isUpperCaseLetter(identifier.charCodeAt(index));
var nextIsLower = isLowerCaseLetter(identifier.charCodeAt(index + 1));
if (currentIsUpper && nextIsLower) {
// We have a transition from an upper to a lower letter here. But we only
// want to break if all the letters that preceded are uppercase. i.e. if we
// have "Foo" we don't want to break that into "F, oo". But if we have
// "IFoo" or "UIFoo", then we want to break that into "I, Foo" and "UI,
// Foo". i.e. the last uppercase letter belongs to the lowercase letters
// that follows. Note: this will make the following not split properly:
// "HELLOthere". However, these sorts of names do not show up in .Net
// programs.
for (var i = wordStart; i < index; i++) {
if (!isUpperCaseLetter(identifier.charCodeAt(i))) {
return false;
}
}
return true;
}
}
}
return false;
}
function transitionFromLowerToUpper(identifier, word, index) {
var lastIsUpper = isUpperCaseLetter(identifier.charCodeAt(index - 1));
var currentIsUpper = isUpperCaseLetter(identifier.charCodeAt(index));
// See if the casing indicates we're starting a new word. Note: if we're breaking on
// words, then just seeing an upper case character isn't enough. Instead, it has to
// be uppercase and the previous character can't be uppercase.
//
// For example, breaking "AddMetadata" on words would make: Add Metadata
//
// on characters would be: A dd M etadata
//
// Break "AM" on words would be: AM
//
// on characters would be: A M
//
// We break the search string on characters. But we break the symbol name on words.
var transition = word
? (currentIsUpper && !lastIsUpper)
: currentIsUpper;
return transition;
}
})(ts || (ts = {}));
var ts;
(function (ts) {
function preProcessFile(sourceText, readImportFiles, detectJavaScriptImports) {
if (readImportFiles === void 0) { readImportFiles = true; }
if (detectJavaScriptImports === void 0) { detectJavaScriptImports = false; }
var referencedFiles = [];
var typeReferenceDirectives = [];
var importedFiles = [];
var ambientExternalModules;
var isNoDefaultLib = false;
var braceNesting = 0;
// assume that text represent an external module if it contains at least one top level import/export
// ambient modules that are found inside external modules are interpreted as module augmentations
var externalModule = false;
function nextToken() {
var token = ts.scanner.scan();
if (token === 16 /* OpenBraceToken */) {
braceNesting++;
}
else if (token === 17 /* CloseBraceToken */) {
braceNesting--;
}
return token;
}
function processTripleSlashDirectives() {
var commentRanges = ts.getLeadingCommentRanges(sourceText, 0);
ts.forEach(commentRanges, function (commentRange) {
var comment = sourceText.substring(commentRange.pos, commentRange.end);
var referencePathMatchResult = ts.getFileReferenceFromReferencePath(comment, commentRange);
if (referencePathMatchResult) {
isNoDefaultLib = referencePathMatchResult.isNoDefaultLib;
var fileReference = referencePathMatchResult.fileReference;
if (fileReference) {
var collection = referencePathMatchResult.isTypeReferenceDirective
? typeReferenceDirectives
: referencedFiles;
collection.push(fileReference);
}
}
});
}
function getFileReference() {
var file = ts.scanner.getTokenValue();
var pos = ts.scanner.getTokenPos();
return {
fileName: file,
pos: pos,
end: pos + file.length
};
}
function recordAmbientExternalModule() {
if (!ambientExternalModules) {
ambientExternalModules = [];
}
ambientExternalModules.push({ ref: getFileReference(), depth: braceNesting });
}
function recordModuleName() {
importedFiles.push(getFileReference());
markAsExternalModuleIfTopLevel();
}
function markAsExternalModuleIfTopLevel() {
if (braceNesting === 0) {
externalModule = true;
}
}
/**
* Returns true if at least one token was consumed from the stream
*/
function tryConsumeDeclare() {
var token = ts.scanner.getToken();
if (token === 123 /* DeclareKeyword */) {
// declare module "mod"
token = nextToken();
if (token === 127 /* ModuleKeyword */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
recordAmbientExternalModule();
}
}
return true;
}
return false;
}
/**
* Returns true if at least one token was consumed from the stream
*/
function tryConsumeImport() {
var token = ts.scanner.getToken();
if (token === 90 /* ImportKeyword */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
// import "mod";
recordModuleName();
return true;
}
else {
if (token === 70 /* Identifier */ || ts.isKeyword(token)) {
token = nextToken();
if (token === 138 /* FromKeyword */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
// import d from "mod";
recordModuleName();
return true;
}
}
else if (token === 57 /* EqualsToken */) {
if (tryConsumeRequireCall(/*skipCurrentToken*/ true)) {
return true;
}
}
else if (token === 25 /* CommaToken */) {
// consume comma and keep going
token = nextToken();
}
else {
// unknown syntax
return true;
}
}
if (token === 16 /* OpenBraceToken */) {
token = nextToken();
// consume "{ a as B, c, d as D}" clauses
// make sure that it stops on EOF
while (token !== 17 /* CloseBraceToken */ && token !== 1 /* EndOfFileToken */) {
token = nextToken();
}
if (token === 17 /* CloseBraceToken */) {
token = nextToken();
if (token === 138 /* FromKeyword */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
// import {a as A} from "mod";
// import d, {a, b as B} from "mod"
recordModuleName();
}
}
}
}
else if (token === 38 /* AsteriskToken */) {
token = nextToken();
if (token === 117 /* AsKeyword */) {
token = nextToken();
if (token === 70 /* Identifier */ || ts.isKeyword(token)) {
token = nextToken();
if (token === 138 /* FromKeyword */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
// import * as NS from "mod"
// import d, * as NS from "mod"
recordModuleName();
}
}
}
}
}
}
return true;
}
return false;
}
function tryConsumeExport() {
var token = ts.scanner.getToken();
if (token === 83 /* ExportKeyword */) {
markAsExternalModuleIfTopLevel();
token = nextToken();
if (token === 16 /* OpenBraceToken */) {
token = nextToken();
// consume "{ a as B, c, d as D}" clauses
// make sure it stops on EOF
while (token !== 17 /* CloseBraceToken */ && token !== 1 /* EndOfFileToken */) {
token = nextToken();
}
if (token === 17 /* CloseBraceToken */) {
token = nextToken();
if (token === 138 /* FromKeyword */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
// export {a as A} from "mod";
// export {a, b as B} from "mod"
recordModuleName();
}
}
}
}
else if (token === 38 /* AsteriskToken */) {
token = nextToken();
if (token === 138 /* FromKeyword */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
// export * from "mod"
recordModuleName();
}
}
}
else if (token === 90 /* ImportKeyword */) {
token = nextToken();
if (token === 70 /* Identifier */ || ts.isKeyword(token)) {
token = nextToken();
if (token === 57 /* EqualsToken */) {
if (tryConsumeRequireCall(/*skipCurrentToken*/ true)) {
return true;
}
}
}
}
return true;
}
return false;
}
function tryConsumeRequireCall(skipCurrentToken) {
var token = skipCurrentToken ? nextToken() : ts.scanner.getToken();
if (token === 131 /* RequireKeyword */) {
token = nextToken();
if (token === 18 /* OpenParenToken */) {
token = nextToken();
if (token === 9 /* StringLiteral */) {
// require("mod");
recordModuleName();
}
}
return true;
}
return false;
}
function tryConsumeDefine() {
var token = ts.scanner.getToken();
if (token === 70 /* Identifier */ && ts.scanner.getTokenValue() === "define") {
token = nextToken();
if (token !== 18 /* OpenParenToken */) {
return true;
}
token = nextToken();
if (token === 9 /* StringLiteral */) {
// looks like define ("modname", ... - skip string literal and comma
token = nextToken();
if (token === 25 /* CommaToken */) {
token = nextToken();
}
else {
// unexpected token
return true;
}
}
// should be start of dependency list
if (token !== 20 /* OpenBracketToken */) {
return true;
}
// skip open bracket
token = nextToken();
var i = 0;
// scan until ']' or EOF
while (token !== 21 /* CloseBracketToken */ && token !== 1 /* EndOfFileToken */) {
// record string literals as module names
if (token === 9 /* StringLiteral */) {
recordModuleName();
i++;
}
token = nextToken();
}
return true;
}
return false;
}
function processImports() {
ts.scanner.setText(sourceText);
nextToken();
// Look for:
// import "mod";
// import d from "mod"
// import {a as A } from "mod";
// import * as NS from "mod"
// import d, {a, b as B} from "mod"
// import i = require("mod");
//
// export * from "mod"
// export {a as b} from "mod"
// export import i = require("mod")
// (for JavaScript files) require("mod")
while (true) {
if (ts.scanner.getToken() === 1 /* EndOfFileToken */) {
break;
}
// check if at least one of alternative have moved scanner forward
if (tryConsumeDeclare() ||
tryConsumeImport() ||
tryConsumeExport() ||
(detectJavaScriptImports && (tryConsumeRequireCall(/*skipCurrentToken*/ false) || tryConsumeDefine()))) {
continue;
}
else {
nextToken();
}
}
ts.scanner.setText(undefined);
}
if (readImportFiles) {
processImports();
}
processTripleSlashDirectives();
if (externalModule) {
// for external modules module all nested ambient modules are augmentations
if (ambientExternalModules) {
// move all detected ambient modules to imported files since they need to be resolved
for (var _i = 0, ambientExternalModules_1 = ambientExternalModules; _i < ambientExternalModules_1.length; _i++) {
var decl = ambientExternalModules_1[_i];
importedFiles.push(decl.ref);
}
}
return { referencedFiles: referencedFiles, typeReferenceDirectives: typeReferenceDirectives, importedFiles: importedFiles, isLibFile: isNoDefaultLib, ambientExternalModules: undefined };
}
else {
// for global scripts ambient modules still can have augmentations - look for ambient modules with depth > 0
var ambientModuleNames = void 0;
if (ambientExternalModules) {
for (var _a = 0, ambientExternalModules_2 = ambientExternalModules; _a < ambientExternalModules_2.length; _a++) {
var decl = ambientExternalModules_2[_a];
if (decl.depth === 0) {
if (!ambientModuleNames) {
ambientModuleNames = [];
}
ambientModuleNames.push(decl.ref.fileName);
}
else {
importedFiles.push(decl.ref);
}
}
}
return { referencedFiles: referencedFiles, typeReferenceDirectives: typeReferenceDirectives, importedFiles: importedFiles, isLibFile: isNoDefaultLib, ambientExternalModules: ambientModuleNames };
}
}
ts.preProcessFile = preProcessFile;
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var Rename;
(function (Rename) {
function getRenameInfo(typeChecker, defaultLibFileName, getCanonicalFileName, sourceFile, position) {
var canonicalDefaultLibName = getCanonicalFileName(ts.normalizePath(defaultLibFileName));
var node = ts.getTouchingWord(sourceFile, position, /*includeJsDocComment*/ true);
if (node) {
if (node.kind === 70 /* Identifier */ ||
node.kind === 9 /* StringLiteral */ ||
ts.isLiteralNameOfPropertyDeclarationOrIndexAccess(node) ||
ts.isThis(node)) {
var symbol = typeChecker.getSymbolAtLocation(node);
// Only allow a symbol to be renamed if it actually has at least one declaration.
if (symbol) {
var declarations = symbol.getDeclarations();
if (declarations && declarations.length > 0) {
// Disallow rename for elements that are defined in the standard TypeScript library.
if (ts.forEach(declarations, isDefinedInLibraryFile)) {
return getRenameInfoError(ts.getLocaleSpecificMessage(ts.Diagnostics.You_cannot_rename_elements_that_are_defined_in_the_standard_TypeScript_library));
}
var displayName = ts.stripQuotes(ts.getDeclaredName(typeChecker, symbol, node));
var kind = ts.SymbolDisplay.getSymbolKind(typeChecker, symbol, node);
if (kind) {
return {
canRename: true,
kind: kind,
displayName: displayName,
localizedErrorMessage: undefined,
fullDisplayName: typeChecker.getFullyQualifiedName(symbol),
kindModifiers: ts.SymbolDisplay.getSymbolModifiers(symbol),
triggerSpan: createTriggerSpanForNode(node, sourceFile)
};
}
}
}
else if (node.kind === 9 /* StringLiteral */) {
var type = ts.getStringLiteralTypeForNode(node, typeChecker);
if (type) {
if (isDefinedInLibraryFile(node)) {
return getRenameInfoError(ts.getLocaleSpecificMessage(ts.Diagnostics.You_cannot_rename_elements_that_are_defined_in_the_standard_TypeScript_library));
}
else {
var displayName = ts.stripQuotes(type.text);
return {
canRename: true,
kind: ts.ScriptElementKind.variableElement,
displayName: displayName,
localizedErrorMessage: undefined,
fullDisplayName: displayName,
kindModifiers: ts.ScriptElementKindModifier.none,
triggerSpan: createTriggerSpanForNode(node, sourceFile)
};
}
}
}
}
}
return getRenameInfoError(ts.getLocaleSpecificMessage(ts.Diagnostics.You_cannot_rename_this_element));
function getRenameInfoError(localizedErrorMessage) {
return {
canRename: false,
localizedErrorMessage: localizedErrorMessage,
displayName: undefined,
fullDisplayName: undefined,
kind: undefined,
kindModifiers: undefined,
triggerSpan: undefined
};
}
function isDefinedInLibraryFile(declaration) {
if (defaultLibFileName) {
var sourceFile_1 = declaration.getSourceFile();
var canonicalName = getCanonicalFileName(ts.normalizePath(sourceFile_1.fileName));
if (canonicalName === canonicalDefaultLibName) {
return true;
}
}
return false;
}
function createTriggerSpanForNode(node, sourceFile) {
var start = node.getStart(sourceFile);
var width = node.getWidth(sourceFile);
if (node.kind === 9 /* StringLiteral */) {
// Exclude the quotes
start += 1;
width -= 2;
}
return ts.createTextSpan(start, width);
}
}
Rename.getRenameInfo = getRenameInfo;
})(Rename = ts.Rename || (ts.Rename = {}));
})(ts || (ts = {}));
///<reference path='services.ts' />
/* @internal */
var ts;
(function (ts) {
var SignatureHelp;
(function (SignatureHelp) {
// A partially written generic type expression is not guaranteed to have the correct syntax tree. the expression could be parsed as less than/greater than expression or a comma expression
// or some other combination depending on what the user has typed so far. For the purposes of signature help we need to consider any location after "<" as a possible generic type reference.
// To do this, the method will back parse the expression starting at the position required. it will try to parse the current expression as a generic type expression, if it did succeed it
// will return the generic identifier that started the expression (e.g. "foo" in "foo<any, |"). It is then up to the caller to ensure that this is a valid generic expression through
// looking up the type. The method will also keep track of the parameter index inside the expression.
// public static isInPartiallyWrittenTypeArgumentList(syntaxTree: TypeScript.SyntaxTree, position: number): any {
// let token = Syntax.findTokenOnLeft(syntaxTree.sourceUnit(), position, /*includeSkippedTokens*/ true);
// if (token && TypeScript.Syntax.hasAncestorOfKind(token, TypeScript.SyntaxKind.TypeParameterList)) {
// // We are in the wrong generic list. bail out
// return null;
// }
// let stack = 0;
// let argumentIndex = 0;
// whileLoop:
// while (token) {
// switch (token.kind()) {
// case TypeScript.SyntaxKind.LessThanToken:
// if (stack === 0) {
// // Found the beginning of the generic argument expression
// let lessThanToken = token;
// token = previousToken(token, /*includeSkippedTokens*/ true);
// if (!token || token.kind() !== TypeScript.SyntaxKind.IdentifierName) {
// break whileLoop;
// }
// // Found the name, return the data
// return {
// genericIdentifer: token,
// lessThanToken: lessThanToken,
// argumentIndex: argumentIndex
// };
// }
// else if (stack < 0) {
// // Seen one too many less than tokens, bail out
// break whileLoop;
// }
// else {
// stack--;
// }
// break;
// case TypeScript.SyntaxKind.GreaterThanGreaterThanGreaterThanToken:
// stack++;
// // Intentional fall through
// case TypeScript.SyntaxKind.GreaterThanToken:
// stack++;
// break;
// case TypeScript.SyntaxKind.CommaToken:
// if (stack == 0) {
// argumentIndex++;
// }
// break;
// case TypeScript.SyntaxKind.CloseBraceToken:
// // This can be object type, skip untill we find the matching open brace token
// let unmatchedOpenBraceTokens = 0;
// // Skip untill the matching open brace token
// token = SignatureInfoHelpers.moveBackUpTillMatchingTokenKind(token, TypeScript.SyntaxKind.CloseBraceToken, TypeScript.SyntaxKind.OpenBraceToken);
// if (!token) {
// // No matching token was found. bail out
// break whileLoop;
// }
// break;
// case TypeScript.SyntaxKind.EqualsGreaterThanToken:
// // This can be a function type or a constructor type. In either case, we want to skip the function definition
// token = previousToken(token, /*includeSkippedTokens*/ true);
// if (token && token.kind() === TypeScript.SyntaxKind.CloseParenToken) {
// // Skip untill the matching open paren token
// token = SignatureInfoHelpers.moveBackUpTillMatchingTokenKind(token, TypeScript.SyntaxKind.CloseParenToken, TypeScript.SyntaxKind.OpenParenToken);
// if (token && token.kind() === TypeScript.SyntaxKind.GreaterThanToken) {
// // Another generic type argument list, skip it\
// token = SignatureInfoHelpers.moveBackUpTillMatchingTokenKind(token, TypeScript.SyntaxKind.GreaterThanToken, TypeScript.SyntaxKind.LessThanToken);
// }
// if (token && token.kind() === TypeScript.SyntaxKind.NewKeyword) {
// // In case this was a constructor type, skip the new keyword
// token = previousToken(token, /*includeSkippedTokens*/ true);
// }
// if (!token) {
// // No matching token was found. bail out
// break whileLoop;
// }
// }
// else {
// // This is not a function type. exit the main loop
// break whileLoop;
// }
// break;
// case TypeScript.SyntaxKind.IdentifierName:
// case TypeScript.SyntaxKind.AnyKeyword:
// case TypeScript.SyntaxKind.NumberKeyword:
// case TypeScript.SyntaxKind.StringKeyword:
// case TypeScript.SyntaxKind.VoidKeyword:
// case TypeScript.SyntaxKind.BooleanKeyword:
// case TypeScript.SyntaxKind.DotToken:
// case TypeScript.SyntaxKind.OpenBracketToken:
// case TypeScript.SyntaxKind.CloseBracketToken:
// // Valid tokens in a type name. Skip.
// break;
// default:
// break whileLoop;
// }
// token = previousToken(token, /*includeSkippedTokens*/ true);
// }
// return null;
// }
// private static moveBackUpTillMatchingTokenKind(token: TypeScript.ISyntaxToken, tokenKind: TypeScript.SyntaxKind, matchingTokenKind: TypeScript.SyntaxKind): TypeScript.ISyntaxToken {
// if (!token || token.kind() !== tokenKind) {
// throw TypeScript.Errors.invalidOperation();
// }
// // Skip the current token
// token = previousToken(token, /*includeSkippedTokens*/ true);
// let stack = 0;
// while (token) {
// if (token.kind() === matchingTokenKind) {
// if (stack === 0) {
// // Found the matching token, return
// return token;
// }
// else if (stack < 0) {
// // tokens overlapped.. bail out.
// break;
// }
// else {
// stack--;
// }
// }
// else if (token.kind() === tokenKind) {
// stack++;
// }
// // Move back
// token = previousToken(token, /*includeSkippedTokens*/ true);
// }
// // Did not find matching token
// return null;
// }
var emptyArray = [];
var ArgumentListKind;
(function (ArgumentListKind) {
ArgumentListKind[ArgumentListKind["TypeArguments"] = 0] = "TypeArguments";
ArgumentListKind[ArgumentListKind["CallArguments"] = 1] = "CallArguments";
ArgumentListKind[ArgumentListKind["TaggedTemplateArguments"] = 2] = "TaggedTemplateArguments";
})(ArgumentListKind = SignatureHelp.ArgumentListKind || (SignatureHelp.ArgumentListKind = {}));
function getSignatureHelpItems(program, sourceFile, position, cancellationToken) {
var typeChecker = program.getTypeChecker();
// Decide whether to show signature help
var startingToken = ts.findTokenOnLeftOfPosition(sourceFile, position);
if (!startingToken) {
// We are at the beginning of the file
return undefined;
}
var argumentInfo = getContainingArgumentInfo(startingToken, position, sourceFile);
cancellationToken.throwIfCancellationRequested();
// Semantic filtering of signature help
if (!argumentInfo) {
return undefined;
}
var call = argumentInfo.invocation;
var candidates = [];
var resolvedSignature = typeChecker.getResolvedSignature(call, candidates);
cancellationToken.throwIfCancellationRequested();
if (!candidates.length) {
// We didn't have any sig help items produced by the TS compiler. If this is a JS
// file, then see if we can figure out anything better.
if (ts.isSourceFileJavaScript(sourceFile)) {
return createJavaScriptSignatureHelpItems(argumentInfo, program);
}
return undefined;
}
return createSignatureHelpItems(candidates, resolvedSignature, argumentInfo, typeChecker);
}
SignatureHelp.getSignatureHelpItems = getSignatureHelpItems;
function createJavaScriptSignatureHelpItems(argumentInfo, program) {
if (argumentInfo.invocation.kind !== 179 /* CallExpression */) {
return undefined;
}
// See if we can find some symbol with the call expression name that has call signatures.
var callExpression = argumentInfo.invocation;
var expression = callExpression.expression;
var name = expression.kind === 70 /* Identifier */
? expression
: expression.kind === 177 /* PropertyAccessExpression */
? expression.name
: undefined;
if (!name || !name.text) {
return undefined;
}
var typeChecker = program.getTypeChecker();
for (var _i = 0, _a = program.getSourceFiles(); _i < _a.length; _i++) {
var sourceFile = _a[_i];
var nameToDeclarations = sourceFile.getNamedDeclarations();
var declarations = nameToDeclarations[name.text];
if (declarations) {
for (var _b = 0, declarations_10 = declarations; _b < declarations_10.length; _b++) {
var declaration = declarations_10[_b];
var symbol = declaration.symbol;
if (symbol) {
var type = typeChecker.getTypeOfSymbolAtLocation(symbol, declaration);
if (type) {
var callSignatures = type.getCallSignatures();
if (callSignatures && callSignatures.length) {
return createSignatureHelpItems(callSignatures, callSignatures[0], argumentInfo, typeChecker);
}
}
}
}
}
}
}
/**
* Returns relevant information for the argument list and the current argument if we are
* in the argument of an invocation; returns undefined otherwise.
*/
function getImmediatelyContainingArgumentInfo(node, position, sourceFile) {
if (node.parent.kind === 179 /* CallExpression */ || node.parent.kind === 180 /* NewExpression */) {
var callExpression = node.parent;
// There are 3 cases to handle:
// 1. The token introduces a list, and should begin a sig help session
// 2. The token is either not associated with a list, or ends a list, so the session should end
// 3. The token is buried inside a list, and should give sig help
//
// The following are examples of each:
//
// Case 1:
// foo<#T, U>(#a, b) -> The token introduces a list, and should begin a sig help session
// Case 2:
// fo#o<T, U>#(a, b)# -> The token is either not associated with a list, or ends a list, so the session should end
// Case 3:
// foo<T#, U#>(a#, #b#) -> The token is buried inside a list, and should give sig help
// Find out if 'node' is an argument, a type argument, or neither
if (node.kind === 26 /* LessThanToken */ ||
node.kind === 18 /* OpenParenToken */) {
// Find the list that starts right *after* the < or ( token.
// If the user has just opened a list, consider this item 0.
var list = getChildListThatStartsWithOpenerToken(callExpression, node, sourceFile);
var isTypeArgList = callExpression.typeArguments && callExpression.typeArguments.pos === list.pos;
ts.Debug.assert(list !== undefined);
return {
kind: isTypeArgList ? 0 /* TypeArguments */ : 1 /* CallArguments */,
invocation: callExpression,
argumentsSpan: getApplicableSpanForArguments(list, sourceFile),
argumentIndex: 0,
argumentCount: getArgumentCount(list)
};
}
// findListItemInfo can return undefined if we are not in parent's argument list
// or type argument list. This includes cases where the cursor is:
// - To the right of the closing paren, non-substitution template, or template tail.
// - Between the type arguments and the arguments (greater than token)
// - On the target of the call (parent.func)
// - On the 'new' keyword in a 'new' expression
var listItemInfo = ts.findListItemInfo(node);
if (listItemInfo) {
var list = listItemInfo.list;
var isTypeArgList = callExpression.typeArguments && callExpression.typeArguments.pos === list.pos;
var argumentIndex = getArgumentIndex(list, node);
var argumentCount = getArgumentCount(list);
ts.Debug.assert(argumentIndex === 0 || argumentIndex < argumentCount, "argumentCount < argumentIndex, " + argumentCount + " < " + argumentIndex);
return {
kind: isTypeArgList ? 0 /* TypeArguments */ : 1 /* CallArguments */,
invocation: callExpression,
argumentsSpan: getApplicableSpanForArguments(list, sourceFile),
argumentIndex: argumentIndex,
argumentCount: argumentCount
};
}
return undefined;
}
else if (node.kind === 12 /* NoSubstitutionTemplateLiteral */ && node.parent.kind === 181 /* TaggedTemplateExpression */) {
// Check if we're actually inside the template;
// otherwise we'll fall out and return undefined.
if (ts.isInsideTemplateLiteral(node, position)) {
return getArgumentListInfoForTemplate(node.parent, /*argumentIndex*/ 0, sourceFile);
}
}
else if (node.kind === 13 /* TemplateHead */ && node.parent.parent.kind === 181 /* TaggedTemplateExpression */) {
var templateExpression = node.parent;
var tagExpression = templateExpression.parent;
ts.Debug.assert(templateExpression.kind === 194 /* TemplateExpression */);
var argumentIndex = ts.isInsideTemplateLiteral(node, position) ? 0 : 1;
return getArgumentListInfoForTemplate(tagExpression, argumentIndex, sourceFile);
}
else if (node.parent.kind === 202 /* TemplateSpan */ && node.parent.parent.parent.kind === 181 /* TaggedTemplateExpression */) {
var templateSpan = node.parent;
var templateExpression = templateSpan.parent;
var tagExpression = templateExpression.parent;
ts.Debug.assert(templateExpression.kind === 194 /* TemplateExpression */);
// If we're just after a template tail, don't show signature help.
if (node.kind === 15 /* TemplateTail */ && !ts.isInsideTemplateLiteral(node, position)) {
return undefined;
}
var spanIndex = templateExpression.templateSpans.indexOf(templateSpan);
var argumentIndex = getArgumentIndexForTemplatePiece(spanIndex, node, position);
return getArgumentListInfoForTemplate(tagExpression, argumentIndex, sourceFile);
}
return undefined;
}
function getArgumentIndex(argumentsList, node) {
// The list we got back can include commas. In the presence of errors it may
// also just have nodes without commas. For example "Foo(a b c)" will have 3
// args without commas. We want to find what index we're at. So we count
// forward until we hit ourselves, only incrementing the index if it isn't a
// comma.
//
// Note: the subtlety around trailing commas (in getArgumentCount) does not apply
// here. That's because we're only walking forward until we hit the node we're
// on. In that case, even if we're after the trailing comma, we'll still see
// that trailing comma in the list, and we'll have generated the appropriate
// arg index.
var argumentIndex = 0;
var listChildren = argumentsList.getChildren();
for (var _i = 0, listChildren_1 = listChildren; _i < listChildren_1.length; _i++) {
var child = listChildren_1[_i];
if (child === node) {
break;
}
if (child.kind !== 25 /* CommaToken */) {
argumentIndex++;
}
}
return argumentIndex;
}
function getArgumentCount(argumentsList) {
// The argument count for a list is normally the number of non-comma children it has.
// For example, if you have "Foo(a,b)" then there will be three children of the arg
// list 'a' '<comma>' 'b'. So, in this case the arg count will be 2. However, there
// is a small subtlety. If you have "Foo(a,)", then the child list will just have
// 'a' '<comma>'. So, in the case where the last child is a comma, we increase the
// arg count by one to compensate.
//
// Note: this subtlety only applies to the last comma. If you had "Foo(a,," then
// we'll have: 'a' '<comma>' '<missing>'
// That will give us 2 non-commas. We then add one for the last comma, givin us an
// arg count of 3.
var listChildren = argumentsList.getChildren();
var argumentCount = ts.countWhere(listChildren, function (arg) { return arg.kind !== 25 /* CommaToken */; });
if (listChildren.length > 0 && ts.lastOrUndefined(listChildren).kind === 25 /* CommaToken */) {
argumentCount++;
}
return argumentCount;
}
// spanIndex is either the index for a given template span.
// This does not give appropriate results for a NoSubstitutionTemplateLiteral
function getArgumentIndexForTemplatePiece(spanIndex, node, position) {
// Because the TemplateStringsArray is the first argument, we have to offset each substitution expression by 1.
// There are three cases we can encounter:
// 1. We are precisely in the template literal (argIndex = 0).
// 2. We are in or to the right of the substitution expression (argIndex = spanIndex + 1).
// 3. We are directly to the right of the template literal, but because we look for the token on the left,
// not enough to put us in the substitution expression; we should consider ourselves part of
// the *next* span's expression by offsetting the index (argIndex = (spanIndex + 1) + 1).
//
// Example: f `# abcd $#{# 1 + 1# }# efghi ${ #"#hello"# } # `
// ^ ^ ^ ^ ^ ^ ^ ^ ^
// Case: 1 1 3 2 1 3 2 2 1
ts.Debug.assert(position >= node.getStart(), "Assumed 'position' could not occur before node.");
if (ts.isTemplateLiteralKind(node.kind)) {
if (ts.isInsideTemplateLiteral(node, position)) {
return 0;
}
return spanIndex + 2;
}
return spanIndex + 1;
}
function getArgumentListInfoForTemplate(tagExpression, argumentIndex, sourceFile) {
// argumentCount is either 1 or (numSpans + 1) to account for the template strings array argument.
var argumentCount = tagExpression.template.kind === 12 /* NoSubstitutionTemplateLiteral */
? 1
: tagExpression.template.templateSpans.length + 1;
ts.Debug.assert(argumentIndex === 0 || argumentIndex < argumentCount, "argumentCount < argumentIndex, " + argumentCount + " < " + argumentIndex);
return {
kind: 2 /* TaggedTemplateArguments */,
invocation: tagExpression,
argumentsSpan: getApplicableSpanForTaggedTemplate(tagExpression, sourceFile),
argumentIndex: argumentIndex,
argumentCount: argumentCount
};
}
function getApplicableSpanForArguments(argumentsList, sourceFile) {
// We use full start and skip trivia on the end because we want to include trivia on
// both sides. For example,
//
// foo( /*comment */ a, b, c /*comment*/ )
// | |
//
// The applicable span is from the first bar to the second bar (inclusive,
// but not including parentheses)
var applicableSpanStart = argumentsList.getFullStart();
var applicableSpanEnd = ts.skipTrivia(sourceFile.text, argumentsList.getEnd(), /*stopAfterLineBreak*/ false);
return ts.createTextSpan(applicableSpanStart, applicableSpanEnd - applicableSpanStart);
}
function getApplicableSpanForTaggedTemplate(taggedTemplate, sourceFile) {
var template = taggedTemplate.template;
var applicableSpanStart = template.getStart();
var applicableSpanEnd = template.getEnd();
// We need to adjust the end position for the case where the template does not have a tail.
// Otherwise, we will not show signature help past the expression.
// For example,
//
// ` ${ 1 + 1 foo(10)
// | |
//
// This is because a Missing node has no width. However, what we actually want is to include trivia
// leading up to the next token in case the user is about to type in a TemplateMiddle or TemplateTail.
if (template.kind === 194 /* TemplateExpression */) {
var lastSpan = ts.lastOrUndefined(template.templateSpans);
if (lastSpan.literal.getFullWidth() === 0) {
applicableSpanEnd = ts.skipTrivia(sourceFile.text, applicableSpanEnd, /*stopAfterLineBreak*/ false);
}
}
return ts.createTextSpan(applicableSpanStart, applicableSpanEnd - applicableSpanStart);
}
function getContainingArgumentInfo(node, position, sourceFile) {
for (var n = node; n.kind !== 261 /* SourceFile */; n = n.parent) {
if (ts.isFunctionBlock(n)) {
return undefined;
}
// If the node is not a subspan of its parent, this is a big problem.
// There have been crashes that might be caused by this violation.
if (n.pos < n.parent.pos || n.end > n.parent.end) {
ts.Debug.fail("Node of kind " + n.kind + " is not a subspan of its parent of kind " + n.parent.kind);
}
var argumentInfo = getImmediatelyContainingArgumentInfo(n, position, sourceFile);
if (argumentInfo) {
return argumentInfo;
}
}
return undefined;
}
SignatureHelp.getContainingArgumentInfo = getContainingArgumentInfo;
function getChildListThatStartsWithOpenerToken(parent, openerToken, sourceFile) {
var children = parent.getChildren(sourceFile);
var indexOfOpenerToken = children.indexOf(openerToken);
ts.Debug.assert(indexOfOpenerToken >= 0 && children.length > indexOfOpenerToken + 1);
return children[indexOfOpenerToken + 1];
}
/**
* The selectedItemIndex could be negative for several reasons.
* 1. There are too many arguments for all of the overloads
* 2. None of the overloads were type compatible
* The solution here is to try to pick the best overload by picking
* either the first one that has an appropriate number of parameters,
* or the one with the most parameters.
*/
function selectBestInvalidOverloadIndex(candidates, argumentCount) {
var maxParamsSignatureIndex = -1;
var maxParams = -1;
for (var i = 0; i < candidates.length; i++) {
var candidate = candidates[i];
if (candidate.hasRestParameter || candidate.parameters.length >= argumentCount) {
return i;
}
if (candidate.parameters.length > maxParams) {
maxParams = candidate.parameters.length;
maxParamsSignatureIndex = i;
}
}
return maxParamsSignatureIndex;
}
function createSignatureHelpItems(candidates, bestSignature, argumentListInfo, typeChecker) {
var applicableSpan = argumentListInfo.argumentsSpan;
var isTypeParameterList = argumentListInfo.kind === 0 /* TypeArguments */;
var invocation = argumentListInfo.invocation;
var callTarget = ts.getInvokedExpression(invocation);
var callTargetSymbol = typeChecker.getSymbolAtLocation(callTarget);
var callTargetDisplayParts = callTargetSymbol && ts.symbolToDisplayParts(typeChecker, callTargetSymbol, /*enclosingDeclaration*/ undefined, /*meaning*/ undefined);
var items = ts.map(candidates, function (candidateSignature) {
var signatureHelpParameters;
var prefixDisplayParts = [];
var suffixDisplayParts = [];
if (callTargetDisplayParts) {
ts.addRange(prefixDisplayParts, callTargetDisplayParts);
}
var isVariadic;
if (isTypeParameterList) {
isVariadic = false; // type parameter lists are not variadic
prefixDisplayParts.push(ts.punctuationPart(26 /* LessThanToken */));
var typeParameters = candidateSignature.typeParameters;
signatureHelpParameters = typeParameters && typeParameters.length > 0 ? ts.map(typeParameters, createSignatureHelpParameterForTypeParameter) : emptyArray;
suffixDisplayParts.push(ts.punctuationPart(28 /* GreaterThanToken */));
var parameterParts = ts.mapToDisplayParts(function (writer) {
return typeChecker.getSymbolDisplayBuilder().buildDisplayForParametersAndDelimiters(candidateSignature.thisParameter, candidateSignature.parameters, writer, invocation);
});
ts.addRange(suffixDisplayParts, parameterParts);
}
else {
isVariadic = candidateSignature.hasRestParameter;
var typeParameterParts = ts.mapToDisplayParts(function (writer) {
return typeChecker.getSymbolDisplayBuilder().buildDisplayForTypeParametersAndDelimiters(candidateSignature.typeParameters, writer, invocation);
});
ts.addRange(prefixDisplayParts, typeParameterParts);
prefixDisplayParts.push(ts.punctuationPart(18 /* OpenParenToken */));
var parameters = candidateSignature.parameters;
signatureHelpParameters = parameters.length > 0 ? ts.map(parameters, createSignatureHelpParameterForParameter) : emptyArray;
suffixDisplayParts.push(ts.punctuationPart(19 /* CloseParenToken */));
}
var returnTypeParts = ts.mapToDisplayParts(function (writer) {
return typeChecker.getSymbolDisplayBuilder().buildReturnTypeDisplay(candidateSignature, writer, invocation);
});
ts.addRange(suffixDisplayParts, returnTypeParts);
return {
isVariadic: isVariadic,
prefixDisplayParts: prefixDisplayParts,
suffixDisplayParts: suffixDisplayParts,
separatorDisplayParts: [ts.punctuationPart(25 /* CommaToken */), ts.spacePart()],
parameters: signatureHelpParameters,
documentation: candidateSignature.getDocumentationComment()
};
});
var argumentIndex = argumentListInfo.argumentIndex;
// argumentCount is the *apparent* number of arguments.
var argumentCount = argumentListInfo.argumentCount;
var selectedItemIndex = candidates.indexOf(bestSignature);
if (selectedItemIndex < 0) {
selectedItemIndex = selectBestInvalidOverloadIndex(candidates, argumentCount);
}
ts.Debug.assert(argumentIndex === 0 || argumentIndex < argumentCount, "argumentCount < argumentIndex, " + argumentCount + " < " + argumentIndex);
return {
items: items,
applicableSpan: applicableSpan,
selectedItemIndex: selectedItemIndex,
argumentIndex: argumentIndex,
argumentCount: argumentCount
};
function createSignatureHelpParameterForParameter(parameter) {
var displayParts = ts.mapToDisplayParts(function (writer) {
return typeChecker.getSymbolDisplayBuilder().buildParameterDisplay(parameter, writer, invocation);
});
return {
name: parameter.name,
documentation: parameter.getDocumentationComment(),
displayParts: displayParts,
isOptional: typeChecker.isOptionalParameter(parameter.valueDeclaration)
};
}
function createSignatureHelpParameterForTypeParameter(typeParameter) {
var displayParts = ts.mapToDisplayParts(function (writer) {
return typeChecker.getSymbolDisplayBuilder().buildTypeParameterDisplay(typeParameter, writer, invocation);
});
return {
name: typeParameter.symbol.name,
documentation: emptyArray,
displayParts: displayParts,
isOptional: false
};
}
}
})(SignatureHelp = ts.SignatureHelp || (ts.SignatureHelp = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var SymbolDisplay;
(function (SymbolDisplay) {
// TODO(drosen): use contextual SemanticMeaning.
function getSymbolKind(typeChecker, symbol, location) {
var flags = symbol.getFlags();
if (flags & 32 /* Class */)
return ts.getDeclarationOfKind(symbol, 197 /* ClassExpression */) ?
ts.ScriptElementKind.localClassElement : ts.ScriptElementKind.classElement;
if (flags & 384 /* Enum */)
return ts.ScriptElementKind.enumElement;
if (flags & 524288 /* TypeAlias */)
return ts.ScriptElementKind.typeElement;
if (flags & 64 /* Interface */)
return ts.ScriptElementKind.interfaceElement;
if (flags & 262144 /* TypeParameter */)
return ts.ScriptElementKind.typeParameterElement;
var result = getSymbolKindOfConstructorPropertyMethodAccessorFunctionOrVar(typeChecker, symbol, flags, location);
if (result === ts.ScriptElementKind.unknown) {
if (flags & 262144 /* TypeParameter */)
return ts.ScriptElementKind.typeParameterElement;
if (flags & 8 /* EnumMember */)
return ts.ScriptElementKind.variableElement;
if (flags & 8388608 /* Alias */)
return ts.ScriptElementKind.alias;
if (flags & 1536 /* Module */)
return ts.ScriptElementKind.moduleElement;
}
return result;
}
SymbolDisplay.getSymbolKind = getSymbolKind;
function getSymbolKindOfConstructorPropertyMethodAccessorFunctionOrVar(typeChecker, symbol, flags, location) {
if (typeChecker.isUndefinedSymbol(symbol)) {
return ts.ScriptElementKind.variableElement;
}
if (typeChecker.isArgumentsSymbol(symbol)) {
return ts.ScriptElementKind.localVariableElement;
}
if (location.kind === 98 /* ThisKeyword */ && ts.isExpression(location)) {
return ts.ScriptElementKind.parameterElement;
}
if (flags & 3 /* Variable */) {
if (ts.isFirstDeclarationOfSymbolParameter(symbol)) {
return ts.ScriptElementKind.parameterElement;
}
else if (symbol.valueDeclaration && ts.isConst(symbol.valueDeclaration)) {
return ts.ScriptElementKind.constElement;
}
else if (ts.forEach(symbol.declarations, ts.isLet)) {
return ts.ScriptElementKind.letElement;
}
return isLocalVariableOrFunction(symbol) ? ts.ScriptElementKind.localVariableElement : ts.ScriptElementKind.variableElement;
}
if (flags & 16 /* Function */)
return isLocalVariableOrFunction(symbol) ? ts.ScriptElementKind.localFunctionElement : ts.ScriptElementKind.functionElement;
if (flags & 32768 /* GetAccessor */)
return ts.ScriptElementKind.memberGetAccessorElement;
if (flags & 65536 /* SetAccessor */)
return ts.ScriptElementKind.memberSetAccessorElement;
if (flags & 8192 /* Method */)
return ts.ScriptElementKind.memberFunctionElement;
if (flags & 16384 /* Constructor */)
return ts.ScriptElementKind.constructorImplementationElement;
if (flags & 4 /* Property */) {
if (flags & 268435456 /* SyntheticProperty */) {
// If union property is result of union of non method (property/accessors/variables), it is labeled as property
var unionPropertyKind = ts.forEach(typeChecker.getRootSymbols(symbol), function (rootSymbol) {
var rootSymbolFlags = rootSymbol.getFlags();
if (rootSymbolFlags & (98308 /* PropertyOrAccessor */ | 3 /* Variable */)) {
return ts.ScriptElementKind.memberVariableElement;
}
ts.Debug.assert(!!(rootSymbolFlags & 8192 /* Method */));
});
if (!unionPropertyKind) {
// If this was union of all methods,
// make sure it has call signatures before we can label it as method
var typeOfUnionProperty = typeChecker.getTypeOfSymbolAtLocation(symbol, location);
if (typeOfUnionProperty.getCallSignatures().length) {
return ts.ScriptElementKind.memberFunctionElement;
}
return ts.ScriptElementKind.memberVariableElement;
}
return unionPropertyKind;
}
return ts.ScriptElementKind.memberVariableElement;
}
return ts.ScriptElementKind.unknown;
}
function getSymbolModifiers(symbol) {
return symbol && symbol.declarations && symbol.declarations.length > 0
? ts.getNodeModifiers(symbol.declarations[0])
: ts.ScriptElementKindModifier.none;
}
SymbolDisplay.getSymbolModifiers = getSymbolModifiers;
// TODO(drosen): Currently completion entry details passes the SemanticMeaning.All instead of using semanticMeaning of location
function getSymbolDisplayPartsDocumentationAndSymbolKind(typeChecker, symbol, sourceFile, enclosingDeclaration, location, semanticMeaning) {
if (semanticMeaning === void 0) { semanticMeaning = ts.getMeaningFromLocation(location); }
var displayParts = [];
var documentation;
var symbolFlags = symbol.flags;
var symbolKind = getSymbolKindOfConstructorPropertyMethodAccessorFunctionOrVar(typeChecker, symbol, symbolFlags, location);
var hasAddedSymbolInfo;
var isThisExpression = location.kind === 98 /* ThisKeyword */ && ts.isExpression(location);
var type;
// Class at constructor site need to be shown as constructor apart from property,method, vars
if (symbolKind !== ts.ScriptElementKind.unknown || symbolFlags & 32 /* Class */ || symbolFlags & 8388608 /* Alias */) {
// If it is accessor they are allowed only if location is at name of the accessor
if (symbolKind === ts.ScriptElementKind.memberGetAccessorElement || symbolKind === ts.ScriptElementKind.memberSetAccessorElement) {
symbolKind = ts.ScriptElementKind.memberVariableElement;
}
var signature = void 0;
type = isThisExpression ? typeChecker.getTypeAtLocation(location) : typeChecker.getTypeOfSymbolAtLocation(symbol, location);
if (type) {
if (location.parent && location.parent.kind === 177 /* PropertyAccessExpression */) {
var right = location.parent.name;
// Either the location is on the right of a property access, or on the left and the right is missing
if (right === location || (right && right.getFullWidth() === 0)) {
location = location.parent;
}
}
// try get the call/construct signature from the type if it matches
var callExpression = void 0;
if (location.kind === 179 /* CallExpression */ || location.kind === 180 /* NewExpression */) {
callExpression = location;
}
else if (ts.isCallExpressionTarget(location) || ts.isNewExpressionTarget(location)) {
callExpression = location.parent;
}
if (callExpression) {
var candidateSignatures = [];
signature = typeChecker.getResolvedSignature(callExpression, candidateSignatures);
if (!signature && candidateSignatures.length) {
// Use the first candidate:
signature = candidateSignatures[0];
}
var useConstructSignatures = callExpression.kind === 180 /* NewExpression */ || callExpression.expression.kind === 96 /* SuperKeyword */;
var allSignatures = useConstructSignatures ? type.getConstructSignatures() : type.getCallSignatures();
if (!ts.contains(allSignatures, signature.target) && !ts.contains(allSignatures, signature)) {
// Get the first signature if there is one -- allSignatures may contain
// either the original signature or its target, so check for either
signature = allSignatures.length ? allSignatures[0] : undefined;
}
if (signature) {
if (useConstructSignatures && (symbolFlags & 32 /* Class */)) {
// Constructor
symbolKind = ts.ScriptElementKind.constructorImplementationElement;
addPrefixForAnyFunctionOrVar(type.symbol, symbolKind);
}
else if (symbolFlags & 8388608 /* Alias */) {
symbolKind = ts.ScriptElementKind.alias;
pushTypePart(symbolKind);
displayParts.push(ts.spacePart());
if (useConstructSignatures) {
displayParts.push(ts.keywordPart(93 /* NewKeyword */));
displayParts.push(ts.spacePart());
}
addFullSymbolName(symbol);
}
else {
addPrefixForAnyFunctionOrVar(symbol, symbolKind);
}
switch (symbolKind) {
case ts.ScriptElementKind.memberVariableElement:
case ts.ScriptElementKind.variableElement:
case ts.ScriptElementKind.constElement:
case ts.ScriptElementKind.letElement:
case ts.ScriptElementKind.parameterElement:
case ts.ScriptElementKind.localVariableElement:
// If it is call or construct signature of lambda's write type name
displayParts.push(ts.punctuationPart(55 /* ColonToken */));
displayParts.push(ts.spacePart());
if (useConstructSignatures) {
displayParts.push(ts.keywordPart(93 /* NewKeyword */));
displayParts.push(ts.spacePart());
}
if (!(type.flags & 32768 /* Object */ && type.objectFlags & 16 /* Anonymous */) && type.symbol) {
ts.addRange(displayParts, ts.symbolToDisplayParts(typeChecker, type.symbol, enclosingDeclaration, /*meaning*/ undefined, 1 /* WriteTypeParametersOrArguments */));
}
addSignatureDisplayParts(signature, allSignatures, 8 /* WriteArrowStyleSignature */);
break;
default:
// Just signature
addSignatureDisplayParts(signature, allSignatures);
}
hasAddedSymbolInfo = true;
}
}
else if ((ts.isNameOfFunctionDeclaration(location) && !(symbol.flags & 98304 /* Accessor */)) ||
(location.kind === 122 /* ConstructorKeyword */ && location.parent.kind === 150 /* Constructor */)) {
// get the signature from the declaration and write it
var functionDeclaration = location.parent;
var allSignatures = functionDeclaration.kind === 150 /* Constructor */ ? type.getNonNullableType().getConstructSignatures() : type.getNonNullableType().getCallSignatures();
if (!typeChecker.isImplementationOfOverload(functionDeclaration)) {
signature = typeChecker.getSignatureFromDeclaration(functionDeclaration);
}
else {
signature = allSignatures[0];
}
if (functionDeclaration.kind === 150 /* Constructor */) {
// show (constructor) Type(...) signature
symbolKind = ts.ScriptElementKind.constructorImplementationElement;
addPrefixForAnyFunctionOrVar(type.symbol, symbolKind);
}
else {
// (function/method) symbol(..signature)
addPrefixForAnyFunctionOrVar(functionDeclaration.kind === 153 /* CallSignature */ &&
!(type.symbol.flags & 2048 /* TypeLiteral */ || type.symbol.flags & 4096 /* ObjectLiteral */) ? type.symbol : symbol, symbolKind);
}
addSignatureDisplayParts(signature, allSignatures);
hasAddedSymbolInfo = true;
}
}
}
if (symbolFlags & 32 /* Class */ && !hasAddedSymbolInfo && !isThisExpression) {
if (ts.getDeclarationOfKind(symbol, 197 /* ClassExpression */)) {
// Special case for class expressions because we would like to indicate that
// the class name is local to the class body (similar to function expression)
// (local class) class <className>
pushTypePart(ts.ScriptElementKind.localClassElement);
}
else {
// Class declaration has name which is not local.
displayParts.push(ts.keywordPart(74 /* ClassKeyword */));
}
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
writeTypeParametersOfSymbol(symbol, sourceFile);
}
if ((symbolFlags & 64 /* Interface */) && (semanticMeaning & 2 /* Type */)) {
addNewLineIfDisplayPartsExist();
displayParts.push(ts.keywordPart(108 /* InterfaceKeyword */));
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
writeTypeParametersOfSymbol(symbol, sourceFile);
}
if (symbolFlags & 524288 /* TypeAlias */) {
addNewLineIfDisplayPartsExist();
displayParts.push(ts.keywordPart(136 /* TypeKeyword */));
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
writeTypeParametersOfSymbol(symbol, sourceFile);
displayParts.push(ts.spacePart());
displayParts.push(ts.operatorPart(57 /* EqualsToken */));
displayParts.push(ts.spacePart());
ts.addRange(displayParts, ts.typeToDisplayParts(typeChecker, typeChecker.getDeclaredTypeOfSymbol(symbol), enclosingDeclaration, 512 /* InTypeAlias */));
}
if (symbolFlags & 384 /* Enum */) {
addNewLineIfDisplayPartsExist();
if (ts.forEach(symbol.declarations, ts.isConstEnumDeclaration)) {
displayParts.push(ts.keywordPart(75 /* ConstKeyword */));
displayParts.push(ts.spacePart());
}
displayParts.push(ts.keywordPart(82 /* EnumKeyword */));
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
}
if (symbolFlags & 1536 /* Module */) {
addNewLineIfDisplayPartsExist();
var declaration = ts.getDeclarationOfKind(symbol, 230 /* ModuleDeclaration */);
var isNamespace = declaration && declaration.name && declaration.name.kind === 70 /* Identifier */;
displayParts.push(ts.keywordPart(isNamespace ? 128 /* NamespaceKeyword */ : 127 /* ModuleKeyword */));
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
}
if ((symbolFlags & 262144 /* TypeParameter */) && (semanticMeaning & 2 /* Type */)) {
addNewLineIfDisplayPartsExist();
displayParts.push(ts.punctuationPart(18 /* OpenParenToken */));
displayParts.push(ts.textPart("type parameter"));
displayParts.push(ts.punctuationPart(19 /* CloseParenToken */));
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
if (symbol.parent) {
// Class/Interface type parameter
addInPrefix();
addFullSymbolName(symbol.parent, enclosingDeclaration);
writeTypeParametersOfSymbol(symbol.parent, enclosingDeclaration);
}
else {
// Method/function type parameter
var declaration = ts.getDeclarationOfKind(symbol, 143 /* TypeParameter */);
ts.Debug.assert(declaration !== undefined);
declaration = declaration.parent;
if (declaration) {
if (ts.isFunctionLikeKind(declaration.kind)) {
addInPrefix();
var signature = typeChecker.getSignatureFromDeclaration(declaration);
if (declaration.kind === 154 /* ConstructSignature */) {
displayParts.push(ts.keywordPart(93 /* NewKeyword */));
displayParts.push(ts.spacePart());
}
else if (declaration.kind !== 153 /* CallSignature */ && declaration.name) {
addFullSymbolName(declaration.symbol);
}
ts.addRange(displayParts, ts.signatureToDisplayParts(typeChecker, signature, sourceFile, 32 /* WriteTypeArgumentsOfSignature */));
}
else if (declaration.kind === 228 /* TypeAliasDeclaration */) {
// Type alias type parameter
// For example
// type list<T> = T[]; // Both T will go through same code path
addInPrefix();
displayParts.push(ts.keywordPart(136 /* TypeKeyword */));
displayParts.push(ts.spacePart());
addFullSymbolName(declaration.symbol);
writeTypeParametersOfSymbol(declaration.symbol, sourceFile);
}
}
}
}
if (symbolFlags & 8 /* EnumMember */) {
addPrefixForAnyFunctionOrVar(symbol, "enum member");
var declaration = symbol.declarations[0];
if (declaration.kind === 260 /* EnumMember */) {
var constantValue = typeChecker.getConstantValue(declaration);
if (constantValue !== undefined) {
displayParts.push(ts.spacePart());
displayParts.push(ts.operatorPart(57 /* EqualsToken */));
displayParts.push(ts.spacePart());
displayParts.push(ts.displayPart(constantValue.toString(), ts.SymbolDisplayPartKind.numericLiteral));
}
}
}
if (symbolFlags & 8388608 /* Alias */) {
addNewLineIfDisplayPartsExist();
if (symbol.declarations[0].kind === 233 /* NamespaceExportDeclaration */) {
displayParts.push(ts.keywordPart(83 /* ExportKeyword */));
displayParts.push(ts.spacePart());
displayParts.push(ts.keywordPart(128 /* NamespaceKeyword */));
}
else {
displayParts.push(ts.keywordPart(90 /* ImportKeyword */));
}
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
ts.forEach(symbol.declarations, function (declaration) {
if (declaration.kind === 234 /* ImportEqualsDeclaration */) {
var importEqualsDeclaration = declaration;
if (ts.isExternalModuleImportEqualsDeclaration(importEqualsDeclaration)) {
displayParts.push(ts.spacePart());
displayParts.push(ts.operatorPart(57 /* EqualsToken */));
displayParts.push(ts.spacePart());
displayParts.push(ts.keywordPart(131 /* RequireKeyword */));
displayParts.push(ts.punctuationPart(18 /* OpenParenToken */));
displayParts.push(ts.displayPart(ts.getTextOfNode(ts.getExternalModuleImportEqualsDeclarationExpression(importEqualsDeclaration)), ts.SymbolDisplayPartKind.stringLiteral));
displayParts.push(ts.punctuationPart(19 /* CloseParenToken */));
}
else {
var internalAliasSymbol = typeChecker.getSymbolAtLocation(importEqualsDeclaration.moduleReference);
if (internalAliasSymbol) {
displayParts.push(ts.spacePart());
displayParts.push(ts.operatorPart(57 /* EqualsToken */));
displayParts.push(ts.spacePart());
addFullSymbolName(internalAliasSymbol, enclosingDeclaration);
}
}
return true;
}
});
}
if (!hasAddedSymbolInfo) {
if (symbolKind !== ts.ScriptElementKind.unknown) {
if (type) {
if (isThisExpression) {
addNewLineIfDisplayPartsExist();
displayParts.push(ts.keywordPart(98 /* ThisKeyword */));
}
else {
addPrefixForAnyFunctionOrVar(symbol, symbolKind);
}
// For properties, variables and local vars: show the type
if (symbolKind === ts.ScriptElementKind.memberVariableElement ||
symbolFlags & 3 /* Variable */ ||
symbolKind === ts.ScriptElementKind.localVariableElement ||
isThisExpression) {
displayParts.push(ts.punctuationPart(55 /* ColonToken */));
displayParts.push(ts.spacePart());
// If the type is type parameter, format it specially
if (type.symbol && type.symbol.flags & 262144 /* TypeParameter */) {
var typeParameterParts = ts.mapToDisplayParts(function (writer) {
typeChecker.getSymbolDisplayBuilder().buildTypeParameterDisplay(type, writer, enclosingDeclaration);
});
ts.addRange(displayParts, typeParameterParts);
}
else {
ts.addRange(displayParts, ts.typeToDisplayParts(typeChecker, type, enclosingDeclaration));
}
}
else if (symbolFlags & 16 /* Function */ ||
symbolFlags & 8192 /* Method */ ||
symbolFlags & 16384 /* Constructor */ ||
symbolFlags & 131072 /* Signature */ ||
symbolFlags & 98304 /* Accessor */ ||
symbolKind === ts.ScriptElementKind.memberFunctionElement) {
var allSignatures = type.getNonNullableType().getCallSignatures();
addSignatureDisplayParts(allSignatures[0], allSignatures);
}
}
}
else {
symbolKind = getSymbolKind(typeChecker, symbol, location);
}
}
if (!documentation) {
documentation = symbol.getDocumentationComment();
if (documentation.length === 0 && symbol.flags & 4 /* Property */) {
// For some special property access expressions like `experts.foo = foo` or `module.exports.foo = foo`
// there documentation comments might be attached to the right hand side symbol of their declarations.
// The pattern of such special property access is that the parent symbol is the symbol of the file.
if (symbol.parent && ts.forEach(symbol.parent.declarations, function (declaration) { return declaration.kind === 261 /* SourceFile */; })) {
for (var _i = 0, _a = symbol.declarations; _i < _a.length; _i++) {
var declaration = _a[_i];
if (!declaration.parent || declaration.parent.kind !== 192 /* BinaryExpression */) {
continue;
}
var rhsSymbol = typeChecker.getSymbolAtLocation(declaration.parent.right);
if (!rhsSymbol) {
continue;
}
documentation = rhsSymbol.getDocumentationComment();
if (documentation.length > 0) {
break;
}
}
}
}
}
return { displayParts: displayParts, documentation: documentation, symbolKind: symbolKind };
function addNewLineIfDisplayPartsExist() {
if (displayParts.length) {
displayParts.push(ts.lineBreakPart());
}
}
function addInPrefix() {
displayParts.push(ts.spacePart());
displayParts.push(ts.keywordPart(91 /* InKeyword */));
displayParts.push(ts.spacePart());
}
function addFullSymbolName(symbol, enclosingDeclaration) {
var fullSymbolDisplayParts = ts.symbolToDisplayParts(typeChecker, symbol, enclosingDeclaration || sourceFile, /*meaning*/ undefined, 1 /* WriteTypeParametersOrArguments */ | 2 /* UseOnlyExternalAliasing */);
ts.addRange(displayParts, fullSymbolDisplayParts);
}
function addPrefixForAnyFunctionOrVar(symbol, symbolKind) {
addNewLineIfDisplayPartsExist();
if (symbolKind) {
pushTypePart(symbolKind);
displayParts.push(ts.spacePart());
addFullSymbolName(symbol);
}
}
function pushTypePart(symbolKind) {
switch (symbolKind) {
case ts.ScriptElementKind.variableElement:
case ts.ScriptElementKind.functionElement:
case ts.ScriptElementKind.letElement:
case ts.ScriptElementKind.constElement:
case ts.ScriptElementKind.constructorImplementationElement:
displayParts.push(ts.textOrKeywordPart(symbolKind));
return;
default:
displayParts.push(ts.punctuationPart(18 /* OpenParenToken */));
displayParts.push(ts.textOrKeywordPart(symbolKind));
displayParts.push(ts.punctuationPart(19 /* CloseParenToken */));
return;
}
}
function addSignatureDisplayParts(signature, allSignatures, flags) {
ts.addRange(displayParts, ts.signatureToDisplayParts(typeChecker, signature, enclosingDeclaration, flags | 32 /* WriteTypeArgumentsOfSignature */));
if (allSignatures.length > 1) {
displayParts.push(ts.spacePart());
displayParts.push(ts.punctuationPart(18 /* OpenParenToken */));
displayParts.push(ts.operatorPart(36 /* PlusToken */));
displayParts.push(ts.displayPart((allSignatures.length - 1).toString(), ts.SymbolDisplayPartKind.numericLiteral));
displayParts.push(ts.spacePart());
displayParts.push(ts.textPart(allSignatures.length === 2 ? "overload" : "overloads"));
displayParts.push(ts.punctuationPart(19 /* CloseParenToken */));
}
documentation = signature.getDocumentationComment();
}
function writeTypeParametersOfSymbol(symbol, enclosingDeclaration) {
var typeParameterParts = ts.mapToDisplayParts(function (writer) {
typeChecker.getSymbolDisplayBuilder().buildTypeParameterDisplayFromSymbol(symbol, writer, enclosingDeclaration);
});
ts.addRange(displayParts, typeParameterParts);
}
}
SymbolDisplay.getSymbolDisplayPartsDocumentationAndSymbolKind = getSymbolDisplayPartsDocumentationAndSymbolKind;
function isLocalVariableOrFunction(symbol) {
if (symbol.parent) {
return false; // This is exported symbol
}
return ts.forEach(symbol.declarations, function (declaration) {
// Function expressions are local
if (declaration.kind === 184 /* FunctionExpression */) {
return true;
}
if (declaration.kind !== 223 /* VariableDeclaration */ && declaration.kind !== 225 /* FunctionDeclaration */) {
return false;
}
// If the parent is not sourceFile or module block it is local variable
for (var parent_21 = declaration.parent; !ts.isFunctionBlock(parent_21); parent_21 = parent_21.parent) {
// Reached source file or module block
if (parent_21.kind === 261 /* SourceFile */ || parent_21.kind === 231 /* ModuleBlock */) {
return false;
}
}
// parent is in function block
return true;
});
}
})(SymbolDisplay = ts.SymbolDisplay || (ts.SymbolDisplay = {}));
})(ts || (ts = {}));
var ts;
(function (ts) {
/*
* This function will compile source text from 'input' argument using specified compiler options.
* If not options are provided - it will use a set of default compiler options.
* Extra compiler options that will unconditionally be used by this function are:
* - isolatedModules = true
* - allowNonTsExtensions = true
* - noLib = true
* - noResolve = true
*/
function transpileModule(input, transpileOptions) {
var diagnostics = [];
var options = transpileOptions.compilerOptions ? fixupCompilerOptions(transpileOptions.compilerOptions, diagnostics) : ts.getDefaultCompilerOptions();
options.isolatedModules = true;
// transpileModule does not write anything to disk so there is no need to verify that there are no conflicts between input and output paths.
options.suppressOutputPathCheck = true;
// Filename can be non-ts file.
options.allowNonTsExtensions = true;
// We are not returning a sourceFile for lib file when asked by the program,
// so pass --noLib to avoid reporting a file not found error.
options.noLib = true;
// Clear out other settings that would not be used in transpiling this module
options.lib = undefined;
options.types = undefined;
options.noEmit = undefined;
options.noEmitOnError = undefined;
options.paths = undefined;
options.rootDirs = undefined;
options.declaration = undefined;
options.declarationDir = undefined;
options.out = undefined;
options.outFile = undefined;
// We are not doing a full typecheck, we are not resolving the whole context,
// so pass --noResolve to avoid reporting missing file errors.
options.noResolve = true;
// if jsx is specified then treat file as .tsx
var inputFileName = transpileOptions.fileName || (options.jsx ? "module.tsx" : "module.ts");
var sourceFile = ts.createSourceFile(inputFileName, input, options.target);
if (transpileOptions.moduleName) {
sourceFile.moduleName = transpileOptions.moduleName;
}
if (transpileOptions.renamedDependencies) {
sourceFile.renamedDependencies = ts.createMap(transpileOptions.renamedDependencies);
}
var newLine = ts.getNewLineCharacter(options);
// Output
var outputText;
var sourceMapText;
// Create a compilerHost object to allow the compiler to read and write files
var compilerHost = {
getSourceFile: function (fileName) { return fileName === ts.normalizePath(inputFileName) ? sourceFile : undefined; },
writeFile: function (name, text) {
if (ts.fileExtensionIs(name, ".map")) {
ts.Debug.assert(sourceMapText === undefined, "Unexpected multiple source map outputs for the file '" + name + "'");
sourceMapText = text;
}
else {
ts.Debug.assert(outputText === undefined, "Unexpected multiple outputs for the file: '" + name + "'");
outputText = text;
}
},
getDefaultLibFileName: function () { return "lib.d.ts"; },
useCaseSensitiveFileNames: function () { return false; },
getCanonicalFileName: function (fileName) { return fileName; },
getCurrentDirectory: function () { return ""; },
getNewLine: function () { return newLine; },
fileExists: function (fileName) { return fileName === inputFileName; },
readFile: function () { return ""; },
directoryExists: function () { return true; },
getDirectories: function () { return []; }
};
var program = ts.createProgram([inputFileName], options, compilerHost);
if (transpileOptions.reportDiagnostics) {
ts.addRange(/*to*/ diagnostics, /*from*/ program.getSyntacticDiagnostics(sourceFile));
ts.addRange(/*to*/ diagnostics, /*from*/ program.getOptionsDiagnostics());
}
// Emit
program.emit();
ts.Debug.assert(outputText !== undefined, "Output generation failed");
return { outputText: outputText, diagnostics: diagnostics, sourceMapText: sourceMapText };
}
ts.transpileModule = transpileModule;
/*
* This is a shortcut function for transpileModule - it accepts transpileOptions as parameters and returns only outputText part of the result.
*/
function transpile(input, compilerOptions, fileName, diagnostics, moduleName) {
var output = transpileModule(input, { compilerOptions: compilerOptions, fileName: fileName, reportDiagnostics: !!diagnostics, moduleName: moduleName });
// addRange correctly handles cases when wither 'from' or 'to' argument is missing
ts.addRange(diagnostics, output.diagnostics);
return output.outputText;
}
ts.transpile = transpile;
var commandLineOptionsStringToEnum;
/** JS users may pass in string values for enum compiler options (such as ModuleKind), so convert. */
function fixupCompilerOptions(options, diagnostics) {
// Lazily create this value to fix module loading errors.
commandLineOptionsStringToEnum = commandLineOptionsStringToEnum || ts.filter(ts.optionDeclarations, function (o) {
return typeof o.type === "object" && !ts.forEachProperty(o.type, function (v) { return typeof v !== "number"; });
});
options = ts.clone(options);
var _loop_4 = function (opt) {
if (!ts.hasProperty(options, opt.name)) {
return "continue";
}
var value = options[opt.name];
// Value should be a key of opt.type
if (typeof value === "string") {
// If value is not a string, this will fail
options[opt.name] = ts.parseCustomTypeOption(opt, value, diagnostics);
}
else {
if (!ts.forEachProperty(opt.type, function (v) { return v === value; })) {
// Supplied value isn't a valid enum value.
diagnostics.push(ts.createCompilerDiagnosticForInvalidCustomType(opt));
}
}
};
for (var _i = 0, commandLineOptionsStringToEnum_1 = commandLineOptionsStringToEnum; _i < commandLineOptionsStringToEnum_1.length; _i++) {
var opt = commandLineOptionsStringToEnum_1[_i];
_loop_4(opt);
}
return options;
}
})(ts || (ts = {}));
/// <reference path="formatting.ts"/>
/// <reference path="..\..\compiler\scanner.ts"/>
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var standardScanner = ts.createScanner(5 /* Latest */, /*skipTrivia*/ false, 0 /* Standard */);
var jsxScanner = ts.createScanner(5 /* Latest */, /*skipTrivia*/ false, 1 /* JSX */);
/**
* Scanner that is currently used for formatting
*/
var scanner;
var ScanAction;
(function (ScanAction) {
ScanAction[ScanAction["Scan"] = 0] = "Scan";
ScanAction[ScanAction["RescanGreaterThanToken"] = 1] = "RescanGreaterThanToken";
ScanAction[ScanAction["RescanSlashToken"] = 2] = "RescanSlashToken";
ScanAction[ScanAction["RescanTemplateToken"] = 3] = "RescanTemplateToken";
ScanAction[ScanAction["RescanJsxIdentifier"] = 4] = "RescanJsxIdentifier";
ScanAction[ScanAction["RescanJsxText"] = 5] = "RescanJsxText";
})(ScanAction || (ScanAction = {}));
function getFormattingScanner(sourceFile, startPos, endPos) {
ts.Debug.assert(scanner === undefined, "Scanner should be undefined");
scanner = sourceFile.languageVariant === 1 /* JSX */ ? jsxScanner : standardScanner;
scanner.setText(sourceFile.text);
scanner.setTextPos(startPos);
var wasNewLine = true;
var leadingTrivia;
var trailingTrivia;
var savedPos;
var lastScanAction;
var lastTokenInfo;
return {
advance: advance,
readTokenInfo: readTokenInfo,
isOnToken: isOnToken,
getCurrentLeadingTrivia: function () { return leadingTrivia; },
lastTrailingTriviaWasNewLine: function () { return wasNewLine; },
skipToEndOf: skipToEndOf,
close: function () {
ts.Debug.assert(scanner !== undefined);
lastTokenInfo = undefined;
scanner.setText(undefined);
scanner = undefined;
}
};
function advance() {
ts.Debug.assert(scanner !== undefined, "Scanner should be present");
lastTokenInfo = undefined;
var isStarted = scanner.getStartPos() !== startPos;
if (isStarted) {
if (trailingTrivia) {
ts.Debug.assert(trailingTrivia.length !== 0);
wasNewLine = ts.lastOrUndefined(trailingTrivia).kind === 4 /* NewLineTrivia */;
}
else {
wasNewLine = false;
}
}
leadingTrivia = undefined;
trailingTrivia = undefined;
if (!isStarted) {
scanner.scan();
}
var pos = scanner.getStartPos();
// Read leading trivia and token
while (pos < endPos) {
var t = scanner.getToken();
if (!ts.isTrivia(t)) {
break;
}
// consume leading trivia
scanner.scan();
var item = {
pos: pos,
end: scanner.getStartPos(),
kind: t
};
pos = scanner.getStartPos();
if (!leadingTrivia) {
leadingTrivia = [];
}
leadingTrivia.push(item);
}
savedPos = scanner.getStartPos();
}
function shouldRescanGreaterThanToken(node) {
if (node) {
switch (node.kind) {
case 30 /* GreaterThanEqualsToken */:
case 65 /* GreaterThanGreaterThanEqualsToken */:
case 66 /* GreaterThanGreaterThanGreaterThanEqualsToken */:
case 46 /* GreaterThanGreaterThanGreaterThanToken */:
case 45 /* GreaterThanGreaterThanToken */:
return true;
}
}
return false;
}
function shouldRescanJsxIdentifier(node) {
if (node.parent) {
switch (node.parent.kind) {
case 250 /* JsxAttribute */:
case 248 /* JsxOpeningElement */:
case 249 /* JsxClosingElement */:
case 247 /* JsxSelfClosingElement */:
return node.kind === 70 /* Identifier */;
}
}
return false;
}
function shouldRescanJsxText(node) {
return node && node.kind === 10 /* JsxText */;
}
function shouldRescanSlashToken(container) {
return container.kind === 11 /* RegularExpressionLiteral */;
}
function shouldRescanTemplateToken(container) {
return container.kind === 14 /* TemplateMiddle */ ||
container.kind === 15 /* TemplateTail */;
}
function startsWithSlashToken(t) {
return t === 40 /* SlashToken */ || t === 62 /* SlashEqualsToken */;
}
function readTokenInfo(n) {
ts.Debug.assert(scanner !== undefined);
if (!isOnToken()) {
// scanner is not on the token (either advance was not called yet or scanner is already past the end position)
return {
leadingTrivia: leadingTrivia,
trailingTrivia: undefined,
token: undefined
};
}
// normally scanner returns the smallest available token
// check the kind of context node to determine if scanner should have more greedy behavior and consume more text.
var expectedScanAction = shouldRescanGreaterThanToken(n)
? 1 /* RescanGreaterThanToken */
: shouldRescanSlashToken(n)
? 2 /* RescanSlashToken */
: shouldRescanTemplateToken(n)
? 3 /* RescanTemplateToken */
: shouldRescanJsxIdentifier(n)
? 4 /* RescanJsxIdentifier */
: shouldRescanJsxText(n)
? 5 /* RescanJsxText */
: 0 /* Scan */;
if (lastTokenInfo && expectedScanAction === lastScanAction) {
// readTokenInfo was called before with the same expected scan action.
// No need to re-scan text, return existing 'lastTokenInfo'
// it is ok to call fixTokenKind here since it does not affect
// what portion of text is consumed. In contrast rescanning can change it,
// i.e. for '>=' when originally scanner eats just one character
// and rescanning forces it to consume more.
return fixTokenKind(lastTokenInfo, n);
}
if (scanner.getStartPos() !== savedPos) {
ts.Debug.assert(lastTokenInfo !== undefined);
// readTokenInfo was called before but scan action differs - rescan text
scanner.setTextPos(savedPos);
scanner.scan();
}
var currentToken = scanner.getToken();
if (expectedScanAction === 1 /* RescanGreaterThanToken */ && currentToken === 28 /* GreaterThanToken */) {
currentToken = scanner.reScanGreaterToken();
ts.Debug.assert(n.kind === currentToken);
lastScanAction = 1 /* RescanGreaterThanToken */;
}
else if (expectedScanAction === 2 /* RescanSlashToken */ && startsWithSlashToken(currentToken)) {
currentToken = scanner.reScanSlashToken();
ts.Debug.assert(n.kind === currentToken);
lastScanAction = 2 /* RescanSlashToken */;
}
else if (expectedScanAction === 3 /* RescanTemplateToken */ && currentToken === 17 /* CloseBraceToken */) {
currentToken = scanner.reScanTemplateToken();
lastScanAction = 3 /* RescanTemplateToken */;
}
else if (expectedScanAction === 4 /* RescanJsxIdentifier */ && currentToken === 70 /* Identifier */) {
currentToken = scanner.scanJsxIdentifier();
lastScanAction = 4 /* RescanJsxIdentifier */;
}
else if (expectedScanAction === 5 /* RescanJsxText */) {
currentToken = scanner.reScanJsxToken();
lastScanAction = 5 /* RescanJsxText */;
}
else {
lastScanAction = 0 /* Scan */;
}
var token = {
pos: scanner.getStartPos(),
end: scanner.getTextPos(),
kind: currentToken
};
// consume trailing trivia
if (trailingTrivia) {
trailingTrivia = undefined;
}
while (scanner.getStartPos() < endPos) {
currentToken = scanner.scan();
if (!ts.isTrivia(currentToken)) {
break;
}
var trivia = {
pos: scanner.getStartPos(),
end: scanner.getTextPos(),
kind: currentToken
};
if (!trailingTrivia) {
trailingTrivia = [];
}
trailingTrivia.push(trivia);
if (currentToken === 4 /* NewLineTrivia */) {
// move past new line
scanner.scan();
break;
}
}
lastTokenInfo = {
leadingTrivia: leadingTrivia,
trailingTrivia: trailingTrivia,
token: token
};
return fixTokenKind(lastTokenInfo, n);
}
function isOnToken() {
ts.Debug.assert(scanner !== undefined);
var current = (lastTokenInfo && lastTokenInfo.token.kind) || scanner.getToken();
var startPos = (lastTokenInfo && lastTokenInfo.token.pos) || scanner.getStartPos();
return startPos < endPos && current !== 1 /* EndOfFileToken */ && !ts.isTrivia(current);
}
// when containing node in the tree is token
// but its kind differs from the kind that was returned by the scanner,
// then kind needs to be fixed. This might happen in cases
// when parser interprets token differently, i.e keyword treated as identifier
function fixTokenKind(tokenInfo, container) {
if (ts.isToken(container) && tokenInfo.token.kind !== container.kind) {
tokenInfo.token.kind = container.kind;
}
return tokenInfo;
}
function skipToEndOf(node) {
scanner.setTextPos(node.end);
savedPos = scanner.getStartPos();
lastScanAction = undefined;
lastTokenInfo = undefined;
wasNewLine = false;
leadingTrivia = undefined;
trailingTrivia = undefined;
}
}
formatting.getFormattingScanner = getFormattingScanner;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
/// <reference path="references.ts"/>
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var FormattingContext = (function () {
function FormattingContext(sourceFile, formattingRequestKind) {
this.sourceFile = sourceFile;
this.formattingRequestKind = formattingRequestKind;
}
FormattingContext.prototype.updateContext = function (currentRange, currentTokenParent, nextRange, nextTokenParent, commonParent) {
ts.Debug.assert(currentRange !== undefined, "currentTokenSpan is null");
ts.Debug.assert(currentTokenParent !== undefined, "currentTokenParent is null");
ts.Debug.assert(nextRange !== undefined, "nextTokenSpan is null");
ts.Debug.assert(nextTokenParent !== undefined, "nextTokenParent is null");
ts.Debug.assert(commonParent !== undefined, "commonParent is null");
this.currentTokenSpan = currentRange;
this.currentTokenParent = currentTokenParent;
this.nextTokenSpan = nextRange;
this.nextTokenParent = nextTokenParent;
this.contextNode = commonParent;
// drop cached results
this.contextNodeAllOnSameLine = undefined;
this.nextNodeAllOnSameLine = undefined;
this.tokensAreOnSameLine = undefined;
this.contextNodeBlockIsOnOneLine = undefined;
this.nextNodeBlockIsOnOneLine = undefined;
};
FormattingContext.prototype.ContextNodeAllOnSameLine = function () {
if (this.contextNodeAllOnSameLine === undefined) {
this.contextNodeAllOnSameLine = this.NodeIsOnOneLine(this.contextNode);
}
return this.contextNodeAllOnSameLine;
};
FormattingContext.prototype.NextNodeAllOnSameLine = function () {
if (this.nextNodeAllOnSameLine === undefined) {
this.nextNodeAllOnSameLine = this.NodeIsOnOneLine(this.nextTokenParent);
}
return this.nextNodeAllOnSameLine;
};
FormattingContext.prototype.TokensAreOnSameLine = function () {
if (this.tokensAreOnSameLine === undefined) {
var startLine = this.sourceFile.getLineAndCharacterOfPosition(this.currentTokenSpan.pos).line;
var endLine = this.sourceFile.getLineAndCharacterOfPosition(this.nextTokenSpan.pos).line;
this.tokensAreOnSameLine = (startLine === endLine);
}
return this.tokensAreOnSameLine;
};
FormattingContext.prototype.ContextNodeBlockIsOnOneLine = function () {
if (this.contextNodeBlockIsOnOneLine === undefined) {
this.contextNodeBlockIsOnOneLine = this.BlockIsOnOneLine(this.contextNode);
}
return this.contextNodeBlockIsOnOneLine;
};
FormattingContext.prototype.NextNodeBlockIsOnOneLine = function () {
if (this.nextNodeBlockIsOnOneLine === undefined) {
this.nextNodeBlockIsOnOneLine = this.BlockIsOnOneLine(this.nextTokenParent);
}
return this.nextNodeBlockIsOnOneLine;
};
FormattingContext.prototype.NodeIsOnOneLine = function (node) {
var startLine = this.sourceFile.getLineAndCharacterOfPosition(node.getStart(this.sourceFile)).line;
var endLine = this.sourceFile.getLineAndCharacterOfPosition(node.getEnd()).line;
return startLine === endLine;
};
FormattingContext.prototype.BlockIsOnOneLine = function (node) {
var openBrace = ts.findChildOfKind(node, 16 /* OpenBraceToken */, this.sourceFile);
var closeBrace = ts.findChildOfKind(node, 17 /* CloseBraceToken */, this.sourceFile);
if (openBrace && closeBrace) {
var startLine = this.sourceFile.getLineAndCharacterOfPosition(openBrace.getEnd()).line;
var endLine = this.sourceFile.getLineAndCharacterOfPosition(closeBrace.getStart(this.sourceFile)).line;
return startLine === endLine;
}
return false;
};
return FormattingContext;
}());
formatting.FormattingContext = FormattingContext;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
/// <reference path="references.ts"/>
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var FormattingRequestKind;
(function (FormattingRequestKind) {
FormattingRequestKind[FormattingRequestKind["FormatDocument"] = 0] = "FormatDocument";
FormattingRequestKind[FormattingRequestKind["FormatSelection"] = 1] = "FormatSelection";
FormattingRequestKind[FormattingRequestKind["FormatOnEnter"] = 2] = "FormatOnEnter";
FormattingRequestKind[FormattingRequestKind["FormatOnSemicolon"] = 3] = "FormatOnSemicolon";
FormattingRequestKind[FormattingRequestKind["FormatOnClosingCurlyBrace"] = 4] = "FormatOnClosingCurlyBrace";
})(FormattingRequestKind = formatting.FormattingRequestKind || (formatting.FormattingRequestKind = {}));
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var Rule = (function () {
function Rule(Descriptor, Operation, Flag) {
if (Flag === void 0) { Flag = 0 /* None */; }
this.Descriptor = Descriptor;
this.Operation = Operation;
this.Flag = Flag;
}
Rule.prototype.toString = function () {
return "[desc=" + this.Descriptor + "," +
"operation=" + this.Operation + "," +
"flag=" + this.Flag + "]";
};
return Rule;
}());
formatting.Rule = Rule;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var RuleAction;
(function (RuleAction) {
RuleAction[RuleAction["Ignore"] = 1] = "Ignore";
RuleAction[RuleAction["Space"] = 2] = "Space";
RuleAction[RuleAction["NewLine"] = 4] = "NewLine";
RuleAction[RuleAction["Delete"] = 8] = "Delete";
})(RuleAction = formatting.RuleAction || (formatting.RuleAction = {}));
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var RuleDescriptor = (function () {
function RuleDescriptor(LeftTokenRange, RightTokenRange) {
this.LeftTokenRange = LeftTokenRange;
this.RightTokenRange = RightTokenRange;
}
RuleDescriptor.prototype.toString = function () {
return "[leftRange=" + this.LeftTokenRange + "," +
"rightRange=" + this.RightTokenRange + "]";
};
RuleDescriptor.create1 = function (left, right) {
return RuleDescriptor.create4(formatting.Shared.TokenRange.FromToken(left), formatting.Shared.TokenRange.FromToken(right));
};
RuleDescriptor.create2 = function (left, right) {
return RuleDescriptor.create4(left, formatting.Shared.TokenRange.FromToken(right));
};
RuleDescriptor.create3 = function (left, right) {
return RuleDescriptor.create4(formatting.Shared.TokenRange.FromToken(left), right);
};
RuleDescriptor.create4 = function (left, right) {
return new RuleDescriptor(left, right);
};
return RuleDescriptor;
}());
formatting.RuleDescriptor = RuleDescriptor;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var RuleFlags;
(function (RuleFlags) {
RuleFlags[RuleFlags["None"] = 0] = "None";
RuleFlags[RuleFlags["CanDeleteNewLines"] = 1] = "CanDeleteNewLines";
})(RuleFlags = formatting.RuleFlags || (formatting.RuleFlags = {}));
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var RuleOperation = (function () {
function RuleOperation(Context, Action) {
this.Context = Context;
this.Action = Action;
}
RuleOperation.prototype.toString = function () {
return "[context=" + this.Context + "," +
"action=" + this.Action + "]";
};
RuleOperation.create1 = function (action) {
return RuleOperation.create2(formatting.RuleOperationContext.Any, action);
};
RuleOperation.create2 = function (context, action) {
return new RuleOperation(context, action);
};
return RuleOperation;
}());
formatting.RuleOperation = RuleOperation;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var RuleOperationContext = (function () {
function RuleOperationContext() {
var funcs = [];
for (var _i = 0; _i < arguments.length; _i++) {
funcs[_i - 0] = arguments[_i];
}
this.customContextChecks = funcs;
}
RuleOperationContext.prototype.IsAny = function () {
return this === RuleOperationContext.Any;
};
RuleOperationContext.prototype.InContext = function (context) {
if (this.IsAny()) {
return true;
}
for (var _i = 0, _a = this.customContextChecks; _i < _a.length; _i++) {
var check = _a[_i];
if (!check(context)) {
return false;
}
}
return true;
};
return RuleOperationContext;
}());
RuleOperationContext.Any = new RuleOperationContext();
formatting.RuleOperationContext = RuleOperationContext;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var Rules = (function () {
function Rules() {
///
/// Common Rules
///
// Leave comments alone
this.IgnoreBeforeComment = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.Comments), formatting.RuleOperation.create1(1 /* Ignore */));
this.IgnoreAfterLineComment = new formatting.Rule(formatting.RuleDescriptor.create3(2 /* SingleLineCommentTrivia */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create1(1 /* Ignore */));
// Space after keyword but not before ; or : or ?
this.NoSpaceBeforeSemicolon = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 24 /* SemicolonToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceBeforeColon = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 55 /* ColonToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNotBinaryOpContext), 8 /* Delete */));
this.NoSpaceBeforeQuestionMark = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 54 /* QuestionToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNotBinaryOpContext), 8 /* Delete */));
this.SpaceAfterColon = new formatting.Rule(formatting.RuleDescriptor.create3(55 /* ColonToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNotBinaryOpContext), 2 /* Space */));
this.SpaceAfterQuestionMarkInConditionalOperator = new formatting.Rule(formatting.RuleDescriptor.create3(54 /* QuestionToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsConditionalOperatorContext), 2 /* Space */));
this.NoSpaceAfterQuestionMark = new formatting.Rule(formatting.RuleDescriptor.create3(54 /* QuestionToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.SpaceAfterSemicolon = new formatting.Rule(formatting.RuleDescriptor.create3(24 /* SemicolonToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
// Space after }.
this.SpaceAfterCloseBrace = new formatting.Rule(formatting.RuleDescriptor.create3(17 /* CloseBraceToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsAfterCodeBlockContext), 2 /* Space */));
// Special case for (}, else) and (}, while) since else & while tokens are not part of the tree which makes SpaceAfterCloseBrace rule not applied
this.SpaceBetweenCloseBraceAndElse = new formatting.Rule(formatting.RuleDescriptor.create1(17 /* CloseBraceToken */, 81 /* ElseKeyword */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceBetweenCloseBraceAndWhile = new formatting.Rule(formatting.RuleDescriptor.create1(17 /* CloseBraceToken */, 105 /* WhileKeyword */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.NoSpaceAfterCloseBrace = new formatting.Rule(formatting.RuleDescriptor.create3(17 /* CloseBraceToken */, formatting.Shared.TokenRange.FromTokens([19 /* CloseParenToken */, 21 /* CloseBracketToken */, 25 /* CommaToken */, 24 /* SemicolonToken */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// No space for dot
this.NoSpaceBeforeDot = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 22 /* DotToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceAfterDot = new formatting.Rule(formatting.RuleDescriptor.create3(22 /* DotToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// No space before and after indexer
this.NoSpaceBeforeOpenBracket = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 20 /* OpenBracketToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceAfterCloseBracket = new formatting.Rule(formatting.RuleDescriptor.create3(21 /* CloseBracketToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNotBeforeBlockInFunctionDeclarationContext), 8 /* Delete */));
// Place a space before open brace in a function declaration
this.FunctionOpenBraceLeftTokenRange = formatting.Shared.TokenRange.AnyIncludingMultilineComments;
this.SpaceBeforeOpenBraceInFunction = new formatting.Rule(formatting.RuleDescriptor.create2(this.FunctionOpenBraceLeftTokenRange, 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclContext, Rules.IsBeforeBlockContext, Rules.IsNotFormatOnEnter, Rules.IsSameLineTokenOrBeforeMultilineBlockContext), 2 /* Space */), 1 /* CanDeleteNewLines */);
// Place a space before open brace in a TypeScript declaration that has braces as children (class, module, enum, etc)
this.TypeScriptOpenBraceLeftTokenRange = formatting.Shared.TokenRange.FromTokens([70 /* Identifier */, 3 /* MultiLineCommentTrivia */, 74 /* ClassKeyword */, 83 /* ExportKeyword */, 90 /* ImportKeyword */]);
this.SpaceBeforeOpenBraceInTypeScriptDeclWithBlock = new formatting.Rule(formatting.RuleDescriptor.create2(this.TypeScriptOpenBraceLeftTokenRange, 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsTypeScriptDeclWithBlockContext, Rules.IsNotFormatOnEnter, Rules.IsSameLineTokenOrBeforeMultilineBlockContext), 2 /* Space */), 1 /* CanDeleteNewLines */);
// Place a space before open brace in a control flow construct
this.ControlOpenBraceLeftTokenRange = formatting.Shared.TokenRange.FromTokens([19 /* CloseParenToken */, 3 /* MultiLineCommentTrivia */, 80 /* DoKeyword */, 101 /* TryKeyword */, 86 /* FinallyKeyword */, 81 /* ElseKeyword */]);
this.SpaceBeforeOpenBraceInControl = new formatting.Rule(formatting.RuleDescriptor.create2(this.ControlOpenBraceLeftTokenRange, 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsControlDeclContext, Rules.IsNotFormatOnEnter, Rules.IsSameLineTokenOrBeforeMultilineBlockContext), 2 /* Space */), 1 /* CanDeleteNewLines */);
// Insert a space after { and before } in single-line contexts, but remove space from empty object literals {}.
this.SpaceAfterOpenBrace = new formatting.Rule(formatting.RuleDescriptor.create3(16 /* OpenBraceToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsSingleLineBlockContext), 2 /* Space */));
this.SpaceBeforeCloseBrace = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 17 /* CloseBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsSingleLineBlockContext), 2 /* Space */));
this.NoSpaceAfterOpenBrace = new formatting.Rule(formatting.RuleDescriptor.create3(16 /* OpenBraceToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsSingleLineBlockContext), 8 /* Delete */));
this.NoSpaceBeforeCloseBrace = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 17 /* CloseBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsSingleLineBlockContext), 8 /* Delete */));
this.NoSpaceBetweenEmptyBraceBrackets = new formatting.Rule(formatting.RuleDescriptor.create1(16 /* OpenBraceToken */, 17 /* CloseBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsObjectContext), 8 /* Delete */));
// Insert new line after { and before } in multi-line contexts.
this.NewLineAfterOpenBraceInBlockContext = new formatting.Rule(formatting.RuleDescriptor.create3(16 /* OpenBraceToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsMultilineBlockContext), 4 /* NewLine */));
// For functions and control block place } on a new line [multi-line rule]
this.NewLineBeforeCloseBraceInBlockContext = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.AnyIncludingMultilineComments, 17 /* CloseBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsMultilineBlockContext), 4 /* NewLine */));
// Special handling of unary operators.
// Prefix operators generally shouldn't have a space between
// them and their target unary expression.
this.NoSpaceAfterUnaryPrefixOperator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.UnaryPrefixOperators, formatting.Shared.TokenRange.UnaryPrefixExpressions), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNotBinaryOpContext), 8 /* Delete */));
this.NoSpaceAfterUnaryPreincrementOperator = new formatting.Rule(formatting.RuleDescriptor.create3(42 /* PlusPlusToken */, formatting.Shared.TokenRange.UnaryPreincrementExpressions), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceAfterUnaryPredecrementOperator = new formatting.Rule(formatting.RuleDescriptor.create3(43 /* MinusMinusToken */, formatting.Shared.TokenRange.UnaryPredecrementExpressions), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceBeforeUnaryPostincrementOperator = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.UnaryPostincrementExpressions, 42 /* PlusPlusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceBeforeUnaryPostdecrementOperator = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.UnaryPostdecrementExpressions, 43 /* MinusMinusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// More unary operator special-casing.
// DevDiv 181814: Be careful when removing leading whitespace
// around unary operators. Examples:
// 1 - -2 --X--> 1--2
// a + ++b --X--> a+++b
this.SpaceAfterPostincrementWhenFollowedByAdd = new formatting.Rule(formatting.RuleDescriptor.create1(42 /* PlusPlusToken */, 36 /* PlusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.SpaceAfterAddWhenFollowedByUnaryPlus = new formatting.Rule(formatting.RuleDescriptor.create1(36 /* PlusToken */, 36 /* PlusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.SpaceAfterAddWhenFollowedByPreincrement = new formatting.Rule(formatting.RuleDescriptor.create1(36 /* PlusToken */, 42 /* PlusPlusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.SpaceAfterPostdecrementWhenFollowedBySubtract = new formatting.Rule(formatting.RuleDescriptor.create1(43 /* MinusMinusToken */, 37 /* MinusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.SpaceAfterSubtractWhenFollowedByUnaryMinus = new formatting.Rule(formatting.RuleDescriptor.create1(37 /* MinusToken */, 37 /* MinusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.SpaceAfterSubtractWhenFollowedByPredecrement = new formatting.Rule(formatting.RuleDescriptor.create1(37 /* MinusToken */, 43 /* MinusMinusToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.NoSpaceBeforeComma = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 25 /* CommaToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.SpaceAfterCertainKeywords = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.FromTokens([103 /* VarKeyword */, 99 /* ThrowKeyword */, 93 /* NewKeyword */, 79 /* DeleteKeyword */, 95 /* ReturnKeyword */, 102 /* TypeOfKeyword */, 120 /* AwaitKeyword */]), formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceAfterLetConstInVariableDeclaration = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.FromTokens([109 /* LetKeyword */, 75 /* ConstKeyword */]), formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsStartOfVariableDeclarationList), 2 /* Space */));
this.NoSpaceBeforeOpenParenInFuncCall = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsFunctionCallOrNewContext, Rules.IsPreviousTokenNotComma), 8 /* Delete */));
this.SpaceAfterFunctionInFuncDecl = new formatting.Rule(formatting.RuleDescriptor.create3(88 /* FunctionKeyword */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclContext), 2 /* Space */));
this.NoSpaceBeforeOpenParenInFuncDecl = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsFunctionDeclContext), 8 /* Delete */));
this.SpaceAfterVoidOperator = new formatting.Rule(formatting.RuleDescriptor.create3(104 /* VoidKeyword */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsVoidOpContext), 2 /* Space */));
this.NoSpaceBetweenReturnAndSemicolon = new formatting.Rule(formatting.RuleDescriptor.create1(95 /* ReturnKeyword */, 24 /* SemicolonToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// Add a space between statements. All keywords except (do,else,case) has open/close parens after them.
// So, we have a rule to add a space for [),Any], [do,Any], [else,Any], and [case,Any]
this.SpaceBetweenStatements = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.FromTokens([19 /* CloseParenToken */, 80 /* DoKeyword */, 81 /* ElseKeyword */, 72 /* CaseKeyword */]), formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNonJsxElementContext, Rules.IsNotForContext), 2 /* Space */));
// This low-pri rule takes care of "try {" and "finally {" in case the rule SpaceBeforeOpenBraceInControl didn't execute on FormatOnEnter.
this.SpaceAfterTryFinally = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.FromTokens([101 /* TryKeyword */, 86 /* FinallyKeyword */]), 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
// get x() {}
// set x(val) {}
this.SpaceAfterGetSetInMember = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.FromTokens([124 /* GetKeyword */, 133 /* SetKeyword */]), 70 /* Identifier */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclContext), 2 /* Space */));
// Special case for binary operators (that are keywords). For these we have to add a space and shouldn't follow any user options.
this.SpaceBeforeBinaryKeywordOperator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.BinaryKeywordOperators), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.SpaceAfterBinaryKeywordOperator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.BinaryKeywordOperators, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
// TypeScript-specific higher priority rules
// Treat constructor as an identifier in a function declaration, and remove spaces between constructor and following left parentheses
this.NoSpaceAfterConstructor = new formatting.Rule(formatting.RuleDescriptor.create1(122 /* ConstructorKeyword */, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// Use of module as a function call. e.g.: import m2 = module("m2");
this.NoSpaceAfterModuleImport = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.FromTokens([127 /* ModuleKeyword */, 131 /* RequireKeyword */]), 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// Add a space around certain TypeScript keywords
this.SpaceAfterCertainTypeScriptKeywords = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.FromTokens([116 /* AbstractKeyword */, 74 /* ClassKeyword */, 123 /* DeclareKeyword */, 78 /* DefaultKeyword */, 82 /* EnumKeyword */, 83 /* ExportKeyword */, 84 /* ExtendsKeyword */, 124 /* GetKeyword */, 107 /* ImplementsKeyword */, 90 /* ImportKeyword */, 108 /* InterfaceKeyword */, 127 /* ModuleKeyword */, 128 /* NamespaceKeyword */, 111 /* PrivateKeyword */, 113 /* PublicKeyword */, 112 /* ProtectedKeyword */, 133 /* SetKeyword */, 114 /* StaticKeyword */, 136 /* TypeKeyword */, 138 /* FromKeyword */]), formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceBeforeCertainTypeScriptKeywords = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.FromTokens([84 /* ExtendsKeyword */, 107 /* ImplementsKeyword */, 138 /* FromKeyword */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
// Treat string literals in module names as identifiers, and add a space between the literal and the opening Brace braces, e.g.: module "m2" {
this.SpaceAfterModuleName = new formatting.Rule(formatting.RuleDescriptor.create1(9 /* StringLiteral */, 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsModuleDeclContext), 2 /* Space */));
// Lambda expressions
this.SpaceBeforeArrow = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 35 /* EqualsGreaterThanToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceAfterArrow = new formatting.Rule(formatting.RuleDescriptor.create3(35 /* EqualsGreaterThanToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
// Optional parameters and let args
this.NoSpaceAfterEllipsis = new formatting.Rule(formatting.RuleDescriptor.create1(23 /* DotDotDotToken */, 70 /* Identifier */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceAfterOptionalParameters = new formatting.Rule(formatting.RuleDescriptor.create3(54 /* QuestionToken */, formatting.Shared.TokenRange.FromTokens([19 /* CloseParenToken */, 25 /* CommaToken */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNotBinaryOpContext), 8 /* Delete */));
// generics and type assertions
this.NoSpaceBeforeOpenAngularBracket = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.TypeNames, 26 /* LessThanToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsTypeArgumentOrParameterOrAssertionContext), 8 /* Delete */));
this.NoSpaceBetweenCloseParenAndAngularBracket = new formatting.Rule(formatting.RuleDescriptor.create1(19 /* CloseParenToken */, 26 /* LessThanToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsTypeArgumentOrParameterOrAssertionContext), 8 /* Delete */));
this.NoSpaceAfterOpenAngularBracket = new formatting.Rule(formatting.RuleDescriptor.create3(26 /* LessThanToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsTypeArgumentOrParameterOrAssertionContext), 8 /* Delete */));
this.NoSpaceBeforeCloseAngularBracket = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 28 /* GreaterThanToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsTypeArgumentOrParameterOrAssertionContext), 8 /* Delete */));
this.NoSpaceAfterCloseAngularBracket = new formatting.Rule(formatting.RuleDescriptor.create3(28 /* GreaterThanToken */, formatting.Shared.TokenRange.FromTokens([18 /* OpenParenToken */, 20 /* OpenBracketToken */, 28 /* GreaterThanToken */, 25 /* CommaToken */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsTypeArgumentOrParameterOrAssertionContext), 8 /* Delete */));
// Remove spaces in empty interface literals. e.g.: x: {}
this.NoSpaceBetweenEmptyInterfaceBraceBrackets = new formatting.Rule(formatting.RuleDescriptor.create1(16 /* OpenBraceToken */, 17 /* CloseBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsObjectTypeContext), 8 /* Delete */));
// decorators
this.SpaceBeforeAt = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 56 /* AtToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.NoSpaceAfterAt = new formatting.Rule(formatting.RuleDescriptor.create3(56 /* AtToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.SpaceAfterDecorator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.FromTokens([116 /* AbstractKeyword */, 70 /* Identifier */, 83 /* ExportKeyword */, 78 /* DefaultKeyword */, 74 /* ClassKeyword */, 114 /* StaticKeyword */, 113 /* PublicKeyword */, 111 /* PrivateKeyword */, 112 /* ProtectedKeyword */, 124 /* GetKeyword */, 133 /* SetKeyword */, 20 /* OpenBracketToken */, 38 /* AsteriskToken */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsEndOfDecoratorContextOnSameLine), 2 /* Space */));
this.NoSpaceBetweenFunctionKeywordAndStar = new formatting.Rule(formatting.RuleDescriptor.create1(88 /* FunctionKeyword */, 38 /* AsteriskToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclarationOrFunctionExpressionContext), 8 /* Delete */));
this.SpaceAfterStarInGeneratorDeclaration = new formatting.Rule(formatting.RuleDescriptor.create3(38 /* AsteriskToken */, formatting.Shared.TokenRange.FromTokens([70 /* Identifier */, 18 /* OpenParenToken */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclarationOrFunctionExpressionContext), 2 /* Space */));
this.NoSpaceBetweenYieldKeywordAndStar = new formatting.Rule(formatting.RuleDescriptor.create1(115 /* YieldKeyword */, 38 /* AsteriskToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsYieldOrYieldStarWithOperand), 8 /* Delete */));
this.SpaceBetweenYieldOrYieldStarAndOperand = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.FromTokens([115 /* YieldKeyword */, 38 /* AsteriskToken */]), formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsYieldOrYieldStarWithOperand), 2 /* Space */));
// Async-await
this.SpaceBetweenAsyncAndOpenParen = new formatting.Rule(formatting.RuleDescriptor.create1(119 /* AsyncKeyword */, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsArrowFunctionContext, Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceBetweenAsyncAndFunctionKeyword = new formatting.Rule(formatting.RuleDescriptor.create1(119 /* AsyncKeyword */, 88 /* FunctionKeyword */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
// template string
this.NoSpaceBetweenTagAndTemplateString = new formatting.Rule(formatting.RuleDescriptor.create3(70 /* Identifier */, formatting.Shared.TokenRange.FromTokens([12 /* NoSubstitutionTemplateLiteral */, 13 /* TemplateHead */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// jsx opening element
this.SpaceBeforeJsxAttribute = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 70 /* Identifier */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNextTokenParentJsxAttribute, Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceBeforeSlashInJsxOpeningElement = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 40 /* SlashToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsJsxSelfClosingElementContext, Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.NoSpaceBeforeGreaterThanTokenInJsxOpeningElement = new formatting.Rule(formatting.RuleDescriptor.create1(40 /* SlashToken */, 28 /* GreaterThanToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsJsxSelfClosingElementContext, Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceBeforeEqualInJsxAttribute = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 57 /* EqualsToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsJsxAttributeContext, Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceAfterEqualInJsxAttribute = new formatting.Rule(formatting.RuleDescriptor.create3(57 /* EqualsToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsJsxAttributeContext, Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// These rules are higher in priority than user-configurable rules.
this.HighPriorityCommonRules = [
this.IgnoreBeforeComment, this.IgnoreAfterLineComment,
this.NoSpaceBeforeColon, this.SpaceAfterColon, this.NoSpaceBeforeQuestionMark, this.SpaceAfterQuestionMarkInConditionalOperator,
this.NoSpaceAfterQuestionMark,
this.NoSpaceBeforeDot, this.NoSpaceAfterDot,
this.NoSpaceAfterUnaryPrefixOperator,
this.NoSpaceAfterUnaryPreincrementOperator, this.NoSpaceAfterUnaryPredecrementOperator,
this.NoSpaceBeforeUnaryPostincrementOperator, this.NoSpaceBeforeUnaryPostdecrementOperator,
this.SpaceAfterPostincrementWhenFollowedByAdd,
this.SpaceAfterAddWhenFollowedByUnaryPlus, this.SpaceAfterAddWhenFollowedByPreincrement,
this.SpaceAfterPostdecrementWhenFollowedBySubtract,
this.SpaceAfterSubtractWhenFollowedByUnaryMinus, this.SpaceAfterSubtractWhenFollowedByPredecrement,
this.NoSpaceAfterCloseBrace,
this.NewLineBeforeCloseBraceInBlockContext,
this.SpaceAfterCloseBrace, this.SpaceBetweenCloseBraceAndElse, this.SpaceBetweenCloseBraceAndWhile, this.NoSpaceBetweenEmptyBraceBrackets,
this.NoSpaceBetweenFunctionKeywordAndStar, this.SpaceAfterStarInGeneratorDeclaration,
this.SpaceAfterFunctionInFuncDecl, this.NewLineAfterOpenBraceInBlockContext, this.SpaceAfterGetSetInMember,
this.NoSpaceBetweenYieldKeywordAndStar, this.SpaceBetweenYieldOrYieldStarAndOperand,
this.NoSpaceBetweenReturnAndSemicolon,
this.SpaceAfterCertainKeywords,
this.SpaceAfterLetConstInVariableDeclaration,
this.NoSpaceBeforeOpenParenInFuncCall,
this.SpaceBeforeBinaryKeywordOperator, this.SpaceAfterBinaryKeywordOperator,
this.SpaceAfterVoidOperator,
this.SpaceBetweenAsyncAndOpenParen, this.SpaceBetweenAsyncAndFunctionKeyword,
this.NoSpaceBetweenTagAndTemplateString,
this.SpaceBeforeJsxAttribute, this.SpaceBeforeSlashInJsxOpeningElement, this.NoSpaceBeforeGreaterThanTokenInJsxOpeningElement,
this.NoSpaceBeforeEqualInJsxAttribute, this.NoSpaceAfterEqualInJsxAttribute,
// TypeScript-specific rules
this.NoSpaceAfterConstructor, this.NoSpaceAfterModuleImport,
this.SpaceAfterCertainTypeScriptKeywords, this.SpaceBeforeCertainTypeScriptKeywords,
this.SpaceAfterModuleName,
this.SpaceBeforeArrow, this.SpaceAfterArrow,
this.NoSpaceAfterEllipsis,
this.NoSpaceAfterOptionalParameters,
this.NoSpaceBetweenEmptyInterfaceBraceBrackets,
this.NoSpaceBeforeOpenAngularBracket,
this.NoSpaceBetweenCloseParenAndAngularBracket,
this.NoSpaceAfterOpenAngularBracket,
this.NoSpaceBeforeCloseAngularBracket,
this.NoSpaceAfterCloseAngularBracket,
this.SpaceBeforeAt,
this.NoSpaceAfterAt,
this.SpaceAfterDecorator,
];
// These rules are lower in priority than user-configurable rules.
this.LowPriorityCommonRules = [
this.NoSpaceBeforeSemicolon,
this.SpaceBeforeOpenBraceInControl, this.SpaceBeforeOpenBraceInFunction, this.SpaceBeforeOpenBraceInTypeScriptDeclWithBlock,
this.NoSpaceBeforeComma,
this.NoSpaceBeforeOpenBracket,
this.NoSpaceAfterCloseBracket,
this.SpaceAfterSemicolon,
this.NoSpaceBeforeOpenParenInFuncDecl,
this.SpaceBetweenStatements, this.SpaceAfterTryFinally
];
///
/// Rules controlled by user options
///
// Insert space after comma delimiter
this.SpaceAfterComma = new formatting.Rule(formatting.RuleDescriptor.create3(25 /* CommaToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNonJsxElementContext, Rules.IsNextTokenNotCloseBracket), 2 /* Space */));
this.NoSpaceAfterComma = new formatting.Rule(formatting.RuleDescriptor.create3(25 /* CommaToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsNonJsxElementContext), 8 /* Delete */));
// Insert space before and after binary operators
this.SpaceBeforeBinaryOperator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.BinaryOperators), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.SpaceAfterBinaryOperator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.BinaryOperators, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 2 /* Space */));
this.NoSpaceBeforeBinaryOperator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.BinaryOperators), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 8 /* Delete */));
this.NoSpaceAfterBinaryOperator = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.BinaryOperators, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsBinaryOpContext), 8 /* Delete */));
// Insert space after keywords in control flow statements
this.SpaceAfterKeywordInControl = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Keywords, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsControlDeclContext), 2 /* Space */));
this.NoSpaceAfterKeywordInControl = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Keywords, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsControlDeclContext), 8 /* Delete */));
// Open Brace braces after function
// TypeScript: Function can have return types, which can be made of tons of different token kinds
this.NewLineBeforeOpenBraceInFunction = new formatting.Rule(formatting.RuleDescriptor.create2(this.FunctionOpenBraceLeftTokenRange, 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclContext, Rules.IsBeforeMultilineBlockContext), 4 /* NewLine */), 1 /* CanDeleteNewLines */);
// Open Brace braces after TypeScript module/class/interface
this.NewLineBeforeOpenBraceInTypeScriptDeclWithBlock = new formatting.Rule(formatting.RuleDescriptor.create2(this.TypeScriptOpenBraceLeftTokenRange, 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsTypeScriptDeclWithBlockContext, Rules.IsBeforeMultilineBlockContext), 4 /* NewLine */), 1 /* CanDeleteNewLines */);
// Open Brace braces after control block
this.NewLineBeforeOpenBraceInControl = new formatting.Rule(formatting.RuleDescriptor.create2(this.ControlOpenBraceLeftTokenRange, 16 /* OpenBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsControlDeclContext, Rules.IsBeforeMultilineBlockContext), 4 /* NewLine */), 1 /* CanDeleteNewLines */);
// Insert space after semicolon in for statement
this.SpaceAfterSemicolonInFor = new formatting.Rule(formatting.RuleDescriptor.create3(24 /* SemicolonToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsForContext), 2 /* Space */));
this.NoSpaceAfterSemicolonInFor = new formatting.Rule(formatting.RuleDescriptor.create3(24 /* SemicolonToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsForContext), 8 /* Delete */));
// Insert space after opening and before closing nonempty parenthesis
this.SpaceAfterOpenParen = new formatting.Rule(formatting.RuleDescriptor.create3(18 /* OpenParenToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceBeforeCloseParen = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 19 /* CloseParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.NoSpaceBetweenParens = new formatting.Rule(formatting.RuleDescriptor.create1(18 /* OpenParenToken */, 19 /* CloseParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceAfterOpenParen = new formatting.Rule(formatting.RuleDescriptor.create3(18 /* OpenParenToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceBeforeCloseParen = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 19 /* CloseParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// Insert space after opening and before closing nonempty brackets
this.SpaceAfterOpenBracket = new formatting.Rule(formatting.RuleDescriptor.create3(20 /* OpenBracketToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.SpaceBeforeCloseBracket = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 21 /* CloseBracketToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.NoSpaceBetweenBrackets = new formatting.Rule(formatting.RuleDescriptor.create1(20 /* OpenBracketToken */, 21 /* CloseBracketToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceAfterOpenBracket = new formatting.Rule(formatting.RuleDescriptor.create3(20 /* OpenBracketToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.NoSpaceBeforeCloseBracket = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 21 /* CloseBracketToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
// Insert space after opening and before closing template string braces
this.NoSpaceAfterTemplateHeadAndMiddle = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.FromTokens([13 /* TemplateHead */, 14 /* TemplateMiddle */]), formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.SpaceAfterTemplateHeadAndMiddle = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.FromTokens([13 /* TemplateHead */, 14 /* TemplateMiddle */]), formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
this.NoSpaceBeforeTemplateMiddleAndTail = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.FromTokens([14 /* TemplateMiddle */, 15 /* TemplateTail */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 8 /* Delete */));
this.SpaceBeforeTemplateMiddleAndTail = new formatting.Rule(formatting.RuleDescriptor.create4(formatting.Shared.TokenRange.Any, formatting.Shared.TokenRange.FromTokens([14 /* TemplateMiddle */, 15 /* TemplateTail */])), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext), 2 /* Space */));
// No space after { and before } in JSX expression
this.NoSpaceAfterOpenBraceInJsxExpression = new formatting.Rule(formatting.RuleDescriptor.create3(16 /* OpenBraceToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsJsxExpressionContext), 8 /* Delete */));
this.SpaceAfterOpenBraceInJsxExpression = new formatting.Rule(formatting.RuleDescriptor.create3(16 /* OpenBraceToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsJsxExpressionContext), 2 /* Space */));
this.NoSpaceBeforeCloseBraceInJsxExpression = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 17 /* CloseBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsJsxExpressionContext), 8 /* Delete */));
this.SpaceBeforeCloseBraceInJsxExpression = new formatting.Rule(formatting.RuleDescriptor.create2(formatting.Shared.TokenRange.Any, 17 /* CloseBraceToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsJsxExpressionContext), 2 /* Space */));
// Insert space after function keyword for anonymous functions
this.SpaceAfterAnonymousFunctionKeyword = new formatting.Rule(formatting.RuleDescriptor.create1(88 /* FunctionKeyword */, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclContext), 2 /* Space */));
this.NoSpaceAfterAnonymousFunctionKeyword = new formatting.Rule(formatting.RuleDescriptor.create1(88 /* FunctionKeyword */, 18 /* OpenParenToken */), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsFunctionDeclContext), 8 /* Delete */));
// No space after type assertion
this.NoSpaceAfterTypeAssertion = new formatting.Rule(formatting.RuleDescriptor.create3(28 /* GreaterThanToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsTypeAssertionContext), 8 /* Delete */));
this.SpaceAfterTypeAssertion = new formatting.Rule(formatting.RuleDescriptor.create3(28 /* GreaterThanToken */, formatting.Shared.TokenRange.Any), formatting.RuleOperation.create2(new formatting.RuleOperationContext(Rules.IsNonJsxSameLineTokenContext, Rules.IsTypeAssertionContext), 2 /* Space */));
}
Rules.prototype.getRuleName = function (rule) {
var o = this;
for (var name_47 in o) {
if (o[name_47] === rule) {
return name_47;
}
}
throw new Error("Unknown rule");
};
///
/// Contexts
///
Rules.IsForContext = function (context) {
return context.contextNode.kind === 211 /* ForStatement */;
};
Rules.IsNotForContext = function (context) {
return !Rules.IsForContext(context);
};
Rules.IsBinaryOpContext = function (context) {
switch (context.contextNode.kind) {
case 192 /* BinaryExpression */:
case 193 /* ConditionalExpression */:
case 200 /* AsExpression */:
case 243 /* ExportSpecifier */:
case 239 /* ImportSpecifier */:
case 156 /* TypePredicate */:
case 164 /* UnionType */:
case 165 /* IntersectionType */:
return true;
// equals in binding elements: function foo([[x, y] = [1, 2]])
case 174 /* BindingElement */:
// equals in type X = ...
case 228 /* TypeAliasDeclaration */:
// equal in import a = module('a');
case 234 /* ImportEqualsDeclaration */:
// equal in let a = 0;
case 223 /* VariableDeclaration */:
// equal in p = 0;
case 144 /* Parameter */:
case 260 /* EnumMember */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
return context.currentTokenSpan.kind === 57 /* EqualsToken */ || context.nextTokenSpan.kind === 57 /* EqualsToken */;
// "in" keyword in for (let x in []) { }
case 212 /* ForInStatement */:
return context.currentTokenSpan.kind === 91 /* InKeyword */ || context.nextTokenSpan.kind === 91 /* InKeyword */;
// Technically, "of" is not a binary operator, but format it the same way as "in"
case 213 /* ForOfStatement */:
return context.currentTokenSpan.kind === 140 /* OfKeyword */ || context.nextTokenSpan.kind === 140 /* OfKeyword */;
}
return false;
};
Rules.IsNotBinaryOpContext = function (context) {
return !Rules.IsBinaryOpContext(context);
};
Rules.IsConditionalOperatorContext = function (context) {
return context.contextNode.kind === 193 /* ConditionalExpression */;
};
Rules.IsSameLineTokenOrBeforeMultilineBlockContext = function (context) {
//// This check is mainly used inside SpaceBeforeOpenBraceInControl and SpaceBeforeOpenBraceInFunction.
////
//// Ex:
//// if (1) { ....
//// * ) and { are on the same line so apply the rule. Here we don't care whether it's same or multi block context
////
//// Ex:
//// if (1)
//// { ... }
//// * ) and { are on different lines. We only need to format if the block is multiline context. So in this case we don't format.
////
//// Ex:
//// if (1)
//// { ...
//// }
//// * ) and { are on different lines. We only need to format if the block is multiline context. So in this case we format.
return context.TokensAreOnSameLine() || Rules.IsBeforeMultilineBlockContext(context);
};
// This check is done before an open brace in a control construct, a function, or a typescript block declaration
Rules.IsBeforeMultilineBlockContext = function (context) {
return Rules.IsBeforeBlockContext(context) && !(context.NextNodeAllOnSameLine() || context.NextNodeBlockIsOnOneLine());
};
Rules.IsMultilineBlockContext = function (context) {
return Rules.IsBlockContext(context) && !(context.ContextNodeAllOnSameLine() || context.ContextNodeBlockIsOnOneLine());
};
Rules.IsSingleLineBlockContext = function (context) {
return Rules.IsBlockContext(context) && (context.ContextNodeAllOnSameLine() || context.ContextNodeBlockIsOnOneLine());
};
Rules.IsBlockContext = function (context) {
return Rules.NodeIsBlockContext(context.contextNode);
};
Rules.IsBeforeBlockContext = function (context) {
return Rules.NodeIsBlockContext(context.nextTokenParent);
};
// IMPORTANT!!! This method must return true ONLY for nodes with open and close braces as immediate children
Rules.NodeIsBlockContext = function (node) {
if (Rules.NodeIsTypeScriptDeclWithBlockContext(node)) {
// This means we are in a context that looks like a block to the user, but in the grammar is actually not a node (it's a class, module, enum, object type literal, etc).
return true;
}
switch (node.kind) {
case 204 /* Block */:
case 232 /* CaseBlock */:
case 176 /* ObjectLiteralExpression */:
case 231 /* ModuleBlock */:
return true;
}
return false;
};
Rules.IsFunctionDeclContext = function (context) {
switch (context.contextNode.kind) {
case 225 /* FunctionDeclaration */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
// case SyntaxKind.MemberFunctionDeclaration:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
// case SyntaxKind.MethodSignature:
case 153 /* CallSignature */:
case 184 /* FunctionExpression */:
case 150 /* Constructor */:
case 185 /* ArrowFunction */:
// case SyntaxKind.ConstructorDeclaration:
// case SyntaxKind.SimpleArrowFunctionExpression:
// case SyntaxKind.ParenthesizedArrowFunctionExpression:
case 227 /* InterfaceDeclaration */:
return true;
}
return false;
};
Rules.IsFunctionDeclarationOrFunctionExpressionContext = function (context) {
return context.contextNode.kind === 225 /* FunctionDeclaration */ || context.contextNode.kind === 184 /* FunctionExpression */;
};
Rules.IsTypeScriptDeclWithBlockContext = function (context) {
return Rules.NodeIsTypeScriptDeclWithBlockContext(context.contextNode);
};
Rules.NodeIsTypeScriptDeclWithBlockContext = function (node) {
switch (node.kind) {
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
case 229 /* EnumDeclaration */:
case 161 /* TypeLiteral */:
case 230 /* ModuleDeclaration */:
case 241 /* ExportDeclaration */:
case 242 /* NamedExports */:
case 235 /* ImportDeclaration */:
case 238 /* NamedImports */:
return true;
}
return false;
};
Rules.IsAfterCodeBlockContext = function (context) {
switch (context.currentTokenParent.kind) {
case 226 /* ClassDeclaration */:
case 230 /* ModuleDeclaration */:
case 229 /* EnumDeclaration */:
case 204 /* Block */:
case 256 /* CatchClause */:
case 231 /* ModuleBlock */:
case 218 /* SwitchStatement */:
return true;
}
return false;
};
Rules.IsControlDeclContext = function (context) {
switch (context.contextNode.kind) {
case 208 /* IfStatement */:
case 218 /* SwitchStatement */:
case 211 /* ForStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 210 /* WhileStatement */:
case 221 /* TryStatement */:
case 209 /* DoStatement */:
case 217 /* WithStatement */:
// TODO
// case SyntaxKind.ElseClause:
case 256 /* CatchClause */:
return true;
default:
return false;
}
};
Rules.IsObjectContext = function (context) {
return context.contextNode.kind === 176 /* ObjectLiteralExpression */;
};
Rules.IsFunctionCallContext = function (context) {
return context.contextNode.kind === 179 /* CallExpression */;
};
Rules.IsNewContext = function (context) {
return context.contextNode.kind === 180 /* NewExpression */;
};
Rules.IsFunctionCallOrNewContext = function (context) {
return Rules.IsFunctionCallContext(context) || Rules.IsNewContext(context);
};
Rules.IsPreviousTokenNotComma = function (context) {
return context.currentTokenSpan.kind !== 25 /* CommaToken */;
};
Rules.IsNextTokenNotCloseBracket = function (context) {
return context.nextTokenSpan.kind !== 21 /* CloseBracketToken */;
};
Rules.IsArrowFunctionContext = function (context) {
return context.contextNode.kind === 185 /* ArrowFunction */;
};
Rules.IsNonJsxSameLineTokenContext = function (context) {
return context.TokensAreOnSameLine() && context.contextNode.kind !== 10 /* JsxText */;
};
Rules.IsNonJsxElementContext = function (context) {
return context.contextNode.kind !== 246 /* JsxElement */;
};
Rules.IsJsxExpressionContext = function (context) {
return context.contextNode.kind === 252 /* JsxExpression */;
};
Rules.IsNextTokenParentJsxAttribute = function (context) {
return context.nextTokenParent.kind === 250 /* JsxAttribute */;
};
Rules.IsJsxAttributeContext = function (context) {
return context.contextNode.kind === 250 /* JsxAttribute */;
};
Rules.IsJsxSelfClosingElementContext = function (context) {
return context.contextNode.kind === 247 /* JsxSelfClosingElement */;
};
Rules.IsNotBeforeBlockInFunctionDeclarationContext = function (context) {
return !Rules.IsFunctionDeclContext(context) && !Rules.IsBeforeBlockContext(context);
};
Rules.IsEndOfDecoratorContextOnSameLine = function (context) {
return context.TokensAreOnSameLine() &&
context.contextNode.decorators &&
Rules.NodeIsInDecoratorContext(context.currentTokenParent) &&
!Rules.NodeIsInDecoratorContext(context.nextTokenParent);
};
Rules.NodeIsInDecoratorContext = function (node) {
while (ts.isPartOfExpression(node)) {
node = node.parent;
}
return node.kind === 145 /* Decorator */;
};
Rules.IsStartOfVariableDeclarationList = function (context) {
return context.currentTokenParent.kind === 224 /* VariableDeclarationList */ &&
context.currentTokenParent.getStart(context.sourceFile) === context.currentTokenSpan.pos;
};
Rules.IsNotFormatOnEnter = function (context) {
return context.formattingRequestKind !== 2 /* FormatOnEnter */;
};
Rules.IsModuleDeclContext = function (context) {
return context.contextNode.kind === 230 /* ModuleDeclaration */;
};
Rules.IsObjectTypeContext = function (context) {
return context.contextNode.kind === 161 /* TypeLiteral */; // && context.contextNode.parent.kind !== SyntaxKind.InterfaceDeclaration;
};
Rules.IsTypeArgumentOrParameterOrAssertion = function (token, parent) {
if (token.kind !== 26 /* LessThanToken */ && token.kind !== 28 /* GreaterThanToken */) {
return false;
}
switch (parent.kind) {
case 157 /* TypeReference */:
case 182 /* TypeAssertionExpression */:
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 199 /* ExpressionWithTypeArguments */:
return true;
default:
return false;
}
};
Rules.IsTypeArgumentOrParameterOrAssertionContext = function (context) {
return Rules.IsTypeArgumentOrParameterOrAssertion(context.currentTokenSpan, context.currentTokenParent) ||
Rules.IsTypeArgumentOrParameterOrAssertion(context.nextTokenSpan, context.nextTokenParent);
};
Rules.IsTypeAssertionContext = function (context) {
return context.contextNode.kind === 182 /* TypeAssertionExpression */;
};
Rules.IsVoidOpContext = function (context) {
return context.currentTokenSpan.kind === 104 /* VoidKeyword */ && context.currentTokenParent.kind === 188 /* VoidExpression */;
};
Rules.IsYieldOrYieldStarWithOperand = function (context) {
return context.contextNode.kind === 195 /* YieldExpression */ && context.contextNode.expression !== undefined;
};
return Rules;
}());
formatting.Rules = Rules;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var RulesMap = (function () {
function RulesMap() {
this.map = [];
this.mapRowLength = 0;
}
RulesMap.create = function (rules) {
var result = new RulesMap();
result.Initialize(rules);
return result;
};
RulesMap.prototype.Initialize = function (rules) {
this.mapRowLength = 140 /* LastToken */ + 1;
this.map = new Array(this.mapRowLength * this.mapRowLength); // new Array<RulesBucket>(this.mapRowLength * this.mapRowLength);
// This array is used only during construction of the rulesbucket in the map
var rulesBucketConstructionStateList = new Array(this.map.length); // new Array<RulesBucketConstructionState>(this.map.length);
this.FillRules(rules, rulesBucketConstructionStateList);
return this.map;
};
RulesMap.prototype.FillRules = function (rules, rulesBucketConstructionStateList) {
var _this = this;
rules.forEach(function (rule) {
_this.FillRule(rule, rulesBucketConstructionStateList);
});
};
RulesMap.prototype.GetRuleBucketIndex = function (row, column) {
ts.Debug.assert(row <= 140 /* LastKeyword */ && column <= 140 /* LastKeyword */, "Must compute formatting context from tokens");
var rulesBucketIndex = (row * this.mapRowLength) + column;
return rulesBucketIndex;
};
RulesMap.prototype.FillRule = function (rule, rulesBucketConstructionStateList) {
var _this = this;
var specificRule = rule.Descriptor.LeftTokenRange !== formatting.Shared.TokenRange.Any &&
rule.Descriptor.RightTokenRange !== formatting.Shared.TokenRange.Any;
rule.Descriptor.LeftTokenRange.GetTokens().forEach(function (left) {
rule.Descriptor.RightTokenRange.GetTokens().forEach(function (right) {
var rulesBucketIndex = _this.GetRuleBucketIndex(left, right);
var rulesBucket = _this.map[rulesBucketIndex];
if (rulesBucket === undefined) {
rulesBucket = _this.map[rulesBucketIndex] = new RulesBucket();
}
rulesBucket.AddRule(rule, specificRule, rulesBucketConstructionStateList, rulesBucketIndex);
});
});
};
RulesMap.prototype.GetRule = function (context) {
var bucketIndex = this.GetRuleBucketIndex(context.currentTokenSpan.kind, context.nextTokenSpan.kind);
var bucket = this.map[bucketIndex];
if (bucket) {
for (var _i = 0, _a = bucket.Rules(); _i < _a.length; _i++) {
var rule = _a[_i];
if (rule.Operation.Context.InContext(context)) {
return rule;
}
}
}
return undefined;
};
return RulesMap;
}());
formatting.RulesMap = RulesMap;
var MaskBitSize = 5;
var Mask = 0x1f;
var RulesPosition;
(function (RulesPosition) {
RulesPosition[RulesPosition["IgnoreRulesSpecific"] = 0] = "IgnoreRulesSpecific";
RulesPosition[RulesPosition["IgnoreRulesAny"] = MaskBitSize * 1] = "IgnoreRulesAny";
RulesPosition[RulesPosition["ContextRulesSpecific"] = MaskBitSize * 2] = "ContextRulesSpecific";
RulesPosition[RulesPosition["ContextRulesAny"] = MaskBitSize * 3] = "ContextRulesAny";
RulesPosition[RulesPosition["NoContextRulesSpecific"] = MaskBitSize * 4] = "NoContextRulesSpecific";
RulesPosition[RulesPosition["NoContextRulesAny"] = MaskBitSize * 5] = "NoContextRulesAny";
})(RulesPosition = formatting.RulesPosition || (formatting.RulesPosition = {}));
var RulesBucketConstructionState = (function () {
function RulesBucketConstructionState() {
//// The Rules list contains all the inserted rules into a rulebucket in the following order:
//// 1- Ignore rules with specific token combination
//// 2- Ignore rules with any token combination
//// 3- Context rules with specific token combination
//// 4- Context rules with any token combination
//// 5- Non-context rules with specific token combination
//// 6- Non-context rules with any token combination
////
//// The member rulesInsertionIndexBitmap is used to describe the number of rules
//// in each sub-bucket (above) hence can be used to know the index of where to insert
//// the next rule. It's a bitmap which contains 6 different sections each is given 5 bits.
////
//// Example:
//// In order to insert a rule to the end of sub-bucket (3), we get the index by adding
//// the values in the bitmap segments 3rd, 2nd, and 1st.
this.rulesInsertionIndexBitmap = 0;
}
RulesBucketConstructionState.prototype.GetInsertionIndex = function (maskPosition) {
var index = 0;
var pos = 0;
var indexBitmap = this.rulesInsertionIndexBitmap;
while (pos <= maskPosition) {
index += (indexBitmap & Mask);
indexBitmap >>= MaskBitSize;
pos += MaskBitSize;
}
return index;
};
RulesBucketConstructionState.prototype.IncreaseInsertionIndex = function (maskPosition) {
var value = (this.rulesInsertionIndexBitmap >> maskPosition) & Mask;
value++;
ts.Debug.assert((value & Mask) === value, "Adding more rules into the sub-bucket than allowed. Maximum allowed is 32 rules.");
var temp = this.rulesInsertionIndexBitmap & ~(Mask << maskPosition);
temp |= value << maskPosition;
this.rulesInsertionIndexBitmap = temp;
};
return RulesBucketConstructionState;
}());
formatting.RulesBucketConstructionState = RulesBucketConstructionState;
var RulesBucket = (function () {
function RulesBucket() {
this.rules = [];
}
RulesBucket.prototype.Rules = function () {
return this.rules;
};
RulesBucket.prototype.AddRule = function (rule, specificTokens, constructionState, rulesBucketIndex) {
var position;
if (rule.Operation.Action === 1 /* Ignore */) {
position = specificTokens ?
RulesPosition.IgnoreRulesSpecific :
RulesPosition.IgnoreRulesAny;
}
else if (!rule.Operation.Context.IsAny()) {
position = specificTokens ?
RulesPosition.ContextRulesSpecific :
RulesPosition.ContextRulesAny;
}
else {
position = specificTokens ?
RulesPosition.NoContextRulesSpecific :
RulesPosition.NoContextRulesAny;
}
var state = constructionState[rulesBucketIndex];
if (state === undefined) {
state = constructionState[rulesBucketIndex] = new RulesBucketConstructionState();
}
var index = state.GetInsertionIndex(position);
this.rules.splice(index, 0, rule);
state.IncreaseInsertionIndex(position);
};
return RulesBucket;
}());
formatting.RulesBucket = RulesBucket;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var Shared;
(function (Shared) {
var TokenRangeAccess = (function () {
function TokenRangeAccess(from, to, except) {
this.tokens = [];
for (var token = from; token <= to; token++) {
if (ts.indexOf(except, token) < 0) {
this.tokens.push(token);
}
}
}
TokenRangeAccess.prototype.GetTokens = function () {
return this.tokens;
};
TokenRangeAccess.prototype.Contains = function (token) {
return this.tokens.indexOf(token) >= 0;
};
return TokenRangeAccess;
}());
Shared.TokenRangeAccess = TokenRangeAccess;
var TokenValuesAccess = (function () {
function TokenValuesAccess(tks) {
this.tokens = tks && tks.length ? tks : [];
}
TokenValuesAccess.prototype.GetTokens = function () {
return this.tokens;
};
TokenValuesAccess.prototype.Contains = function (token) {
return this.tokens.indexOf(token) >= 0;
};
return TokenValuesAccess;
}());
Shared.TokenValuesAccess = TokenValuesAccess;
var TokenSingleValueAccess = (function () {
function TokenSingleValueAccess(token) {
this.token = token;
}
TokenSingleValueAccess.prototype.GetTokens = function () {
return [this.token];
};
TokenSingleValueAccess.prototype.Contains = function (tokenValue) {
return tokenValue === this.token;
};
return TokenSingleValueAccess;
}());
Shared.TokenSingleValueAccess = TokenSingleValueAccess;
var TokenAllAccess = (function () {
function TokenAllAccess() {
}
TokenAllAccess.prototype.GetTokens = function () {
var result = [];
for (var token = 0 /* FirstToken */; token <= 140 /* LastToken */; token++) {
result.push(token);
}
return result;
};
TokenAllAccess.prototype.Contains = function () {
return true;
};
TokenAllAccess.prototype.toString = function () {
return "[allTokens]";
};
return TokenAllAccess;
}());
Shared.TokenAllAccess = TokenAllAccess;
var TokenRange = (function () {
function TokenRange(tokenAccess) {
this.tokenAccess = tokenAccess;
}
TokenRange.FromToken = function (token) {
return new TokenRange(new TokenSingleValueAccess(token));
};
TokenRange.FromTokens = function (tokens) {
return new TokenRange(new TokenValuesAccess(tokens));
};
TokenRange.FromRange = function (f, to, except) {
if (except === void 0) { except = []; }
return new TokenRange(new TokenRangeAccess(f, to, except));
};
TokenRange.AllTokens = function () {
return new TokenRange(new TokenAllAccess());
};
TokenRange.prototype.GetTokens = function () {
return this.tokenAccess.GetTokens();
};
TokenRange.prototype.Contains = function (token) {
return this.tokenAccess.Contains(token);
};
TokenRange.prototype.toString = function () {
return this.tokenAccess.toString();
};
return TokenRange;
}());
TokenRange.Any = TokenRange.AllTokens();
TokenRange.AnyIncludingMultilineComments = TokenRange.FromTokens(TokenRange.Any.GetTokens().concat([3 /* MultiLineCommentTrivia */]));
TokenRange.Keywords = TokenRange.FromRange(71 /* FirstKeyword */, 140 /* LastKeyword */);
TokenRange.BinaryOperators = TokenRange.FromRange(26 /* FirstBinaryOperator */, 69 /* LastBinaryOperator */);
TokenRange.BinaryKeywordOperators = TokenRange.FromTokens([91 /* InKeyword */, 92 /* InstanceOfKeyword */, 140 /* OfKeyword */, 117 /* AsKeyword */, 125 /* IsKeyword */]);
TokenRange.UnaryPrefixOperators = TokenRange.FromTokens([42 /* PlusPlusToken */, 43 /* MinusMinusToken */, 51 /* TildeToken */, 50 /* ExclamationToken */]);
TokenRange.UnaryPrefixExpressions = TokenRange.FromTokens([8 /* NumericLiteral */, 70 /* Identifier */, 18 /* OpenParenToken */, 20 /* OpenBracketToken */, 16 /* OpenBraceToken */, 98 /* ThisKeyword */, 93 /* NewKeyword */]);
TokenRange.UnaryPreincrementExpressions = TokenRange.FromTokens([70 /* Identifier */, 18 /* OpenParenToken */, 98 /* ThisKeyword */, 93 /* NewKeyword */]);
TokenRange.UnaryPostincrementExpressions = TokenRange.FromTokens([70 /* Identifier */, 19 /* CloseParenToken */, 21 /* CloseBracketToken */, 93 /* NewKeyword */]);
TokenRange.UnaryPredecrementExpressions = TokenRange.FromTokens([70 /* Identifier */, 18 /* OpenParenToken */, 98 /* ThisKeyword */, 93 /* NewKeyword */]);
TokenRange.UnaryPostdecrementExpressions = TokenRange.FromTokens([70 /* Identifier */, 19 /* CloseParenToken */, 21 /* CloseBracketToken */, 93 /* NewKeyword */]);
TokenRange.Comments = TokenRange.FromTokens([2 /* SingleLineCommentTrivia */, 3 /* MultiLineCommentTrivia */]);
TokenRange.TypeNames = TokenRange.FromTokens([70 /* Identifier */, 132 /* NumberKeyword */, 134 /* StringKeyword */, 121 /* BooleanKeyword */, 135 /* SymbolKeyword */, 104 /* VoidKeyword */, 118 /* AnyKeyword */]);
Shared.TokenRange = TokenRange;
})(Shared = formatting.Shared || (formatting.Shared = {}));
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='..\services.ts' />
///<reference path='formattingContext.ts' />
///<reference path='formattingRequestKind.ts' />
///<reference path='rule.ts' />
///<reference path='ruleAction.ts' />
///<reference path='ruleDescriptor.ts' />
///<reference path='ruleFlag.ts' />
///<reference path='ruleOperation.ts' />
///<reference path='ruleOperationContext.ts' />
///<reference path='rules.ts' />
///<reference path='rulesMap.ts' />
///<reference path='tokenRange.ts' />
/// <reference path="references.ts"/>
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var RulesProvider = (function () {
function RulesProvider() {
this.globalRules = new formatting.Rules();
}
RulesProvider.prototype.getRuleName = function (rule) {
return this.globalRules.getRuleName(rule);
};
RulesProvider.prototype.getRuleByName = function (name) {
return this.globalRules[name];
};
RulesProvider.prototype.getRulesMap = function () {
return this.rulesMap;
};
RulesProvider.prototype.ensureUpToDate = function (options) {
if (!this.options || !ts.compareDataObjects(this.options, options)) {
var activeRules = this.createActiveRules(options);
var rulesMap = formatting.RulesMap.create(activeRules);
this.activeRules = activeRules;
this.rulesMap = rulesMap;
this.options = ts.clone(options);
}
};
RulesProvider.prototype.createActiveRules = function (options) {
var rules = this.globalRules.HighPriorityCommonRules.slice(0);
if (options.insertSpaceAfterCommaDelimiter) {
rules.push(this.globalRules.SpaceAfterComma);
}
else {
rules.push(this.globalRules.NoSpaceAfterComma);
}
if (options.insertSpaceAfterFunctionKeywordForAnonymousFunctions) {
rules.push(this.globalRules.SpaceAfterAnonymousFunctionKeyword);
}
else {
rules.push(this.globalRules.NoSpaceAfterAnonymousFunctionKeyword);
}
if (options.insertSpaceAfterKeywordsInControlFlowStatements) {
rules.push(this.globalRules.SpaceAfterKeywordInControl);
}
else {
rules.push(this.globalRules.NoSpaceAfterKeywordInControl);
}
if (options.insertSpaceAfterOpeningAndBeforeClosingNonemptyParenthesis) {
rules.push(this.globalRules.SpaceAfterOpenParen);
rules.push(this.globalRules.SpaceBeforeCloseParen);
rules.push(this.globalRules.NoSpaceBetweenParens);
}
else {
rules.push(this.globalRules.NoSpaceAfterOpenParen);
rules.push(this.globalRules.NoSpaceBeforeCloseParen);
rules.push(this.globalRules.NoSpaceBetweenParens);
}
if (options.insertSpaceAfterOpeningAndBeforeClosingNonemptyBrackets) {
rules.push(this.globalRules.SpaceAfterOpenBracket);
rules.push(this.globalRules.SpaceBeforeCloseBracket);
rules.push(this.globalRules.NoSpaceBetweenBrackets);
}
else {
rules.push(this.globalRules.NoSpaceAfterOpenBracket);
rules.push(this.globalRules.NoSpaceBeforeCloseBracket);
rules.push(this.globalRules.NoSpaceBetweenBrackets);
}
// The default value of InsertSpaceAfterOpeningAndBeforeClosingNonemptyBraces is true
// so if the option is undefined, we should treat it as true as well
if (options.insertSpaceAfterOpeningAndBeforeClosingNonemptyBraces !== false) {
rules.push(this.globalRules.SpaceAfterOpenBrace);
rules.push(this.globalRules.SpaceBeforeCloseBrace);
rules.push(this.globalRules.NoSpaceBetweenEmptyBraceBrackets);
}
else {
rules.push(this.globalRules.NoSpaceAfterOpenBrace);
rules.push(this.globalRules.NoSpaceBeforeCloseBrace);
rules.push(this.globalRules.NoSpaceBetweenEmptyBraceBrackets);
}
if (options.insertSpaceAfterOpeningAndBeforeClosingTemplateStringBraces) {
rules.push(this.globalRules.SpaceAfterTemplateHeadAndMiddle);
rules.push(this.globalRules.SpaceBeforeTemplateMiddleAndTail);
}
else {
rules.push(this.globalRules.NoSpaceAfterTemplateHeadAndMiddle);
rules.push(this.globalRules.NoSpaceBeforeTemplateMiddleAndTail);
}
if (options.insertSpaceAfterOpeningAndBeforeClosingJsxExpressionBraces) {
rules.push(this.globalRules.SpaceAfterOpenBraceInJsxExpression);
rules.push(this.globalRules.SpaceBeforeCloseBraceInJsxExpression);
}
else {
rules.push(this.globalRules.NoSpaceAfterOpenBraceInJsxExpression);
rules.push(this.globalRules.NoSpaceBeforeCloseBraceInJsxExpression);
}
if (options.insertSpaceAfterSemicolonInForStatements) {
rules.push(this.globalRules.SpaceAfterSemicolonInFor);
}
else {
rules.push(this.globalRules.NoSpaceAfterSemicolonInFor);
}
if (options.insertSpaceBeforeAndAfterBinaryOperators) {
rules.push(this.globalRules.SpaceBeforeBinaryOperator);
rules.push(this.globalRules.SpaceAfterBinaryOperator);
}
else {
rules.push(this.globalRules.NoSpaceBeforeBinaryOperator);
rules.push(this.globalRules.NoSpaceAfterBinaryOperator);
}
if (options.placeOpenBraceOnNewLineForControlBlocks) {
rules.push(this.globalRules.NewLineBeforeOpenBraceInControl);
}
if (options.placeOpenBraceOnNewLineForFunctions) {
rules.push(this.globalRules.NewLineBeforeOpenBraceInFunction);
rules.push(this.globalRules.NewLineBeforeOpenBraceInTypeScriptDeclWithBlock);
}
if (options.insertSpaceAfterTypeAssertion) {
rules.push(this.globalRules.SpaceAfterTypeAssertion);
}
else {
rules.push(this.globalRules.NoSpaceAfterTypeAssertion);
}
rules = rules.concat(this.globalRules.LowPriorityCommonRules);
return rules;
};
return RulesProvider;
}());
formatting.RulesProvider = RulesProvider;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='..\services.ts' />
///<reference path='formattingScanner.ts' />
///<reference path='rulesProvider.ts' />
///<reference path='references.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var Constants;
(function (Constants) {
Constants[Constants["Unknown"] = -1] = "Unknown";
})(Constants || (Constants = {}));
function formatOnEnter(position, sourceFile, rulesProvider, options) {
var line = sourceFile.getLineAndCharacterOfPosition(position).line;
if (line === 0) {
return [];
}
// After the enter key, the cursor is now at a new line. The new line may or may not contain non-whitespace characters.
// If the new line has only whitespaces, we won't want to format this line, because that would remove the indentation as
// trailing whitespaces. So the end of the formatting span should be the later one between:
// 1. the end of the previous line
// 2. the last non-whitespace character in the current line
var endOfFormatSpan = ts.getEndLinePosition(line, sourceFile);
while (ts.isWhiteSpaceSingleLine(sourceFile.text.charCodeAt(endOfFormatSpan))) {
endOfFormatSpan--;
}
// if the character at the end of the span is a line break, we shouldn't include it, because it indicates we don't want to
// touch the current line at all. Also, on some OSes the line break consists of two characters (\r\n), we should test if the
// previous character before the end of format span is line break character as well.
if (ts.isLineBreak(sourceFile.text.charCodeAt(endOfFormatSpan))) {
endOfFormatSpan--;
}
var span = {
// get start position for the previous line
pos: ts.getStartPositionOfLine(line - 1, sourceFile),
// end value is exclusive so add 1 to the result
end: endOfFormatSpan + 1
};
return formatSpan(span, sourceFile, options, rulesProvider, 2 /* FormatOnEnter */);
}
formatting.formatOnEnter = formatOnEnter;
function formatOnSemicolon(position, sourceFile, rulesProvider, options) {
return formatOutermostParent(position, 24 /* SemicolonToken */, sourceFile, options, rulesProvider, 3 /* FormatOnSemicolon */);
}
formatting.formatOnSemicolon = formatOnSemicolon;
function formatOnClosingCurly(position, sourceFile, rulesProvider, options) {
return formatOutermostParent(position, 17 /* CloseBraceToken */, sourceFile, options, rulesProvider, 4 /* FormatOnClosingCurlyBrace */);
}
formatting.formatOnClosingCurly = formatOnClosingCurly;
function formatDocument(sourceFile, rulesProvider, options) {
var span = {
pos: 0,
end: sourceFile.text.length
};
return formatSpan(span, sourceFile, options, rulesProvider, 0 /* FormatDocument */);
}
formatting.formatDocument = formatDocument;
function formatSelection(start, end, sourceFile, rulesProvider, options) {
// format from the beginning of the line
var span = {
pos: ts.getLineStartPositionForPosition(start, sourceFile),
end: end
};
return formatSpan(span, sourceFile, options, rulesProvider, 1 /* FormatSelection */);
}
formatting.formatSelection = formatSelection;
function formatOutermostParent(position, expectedLastToken, sourceFile, options, rulesProvider, requestKind) {
var parent = findOutermostParent(position, expectedLastToken, sourceFile);
if (!parent) {
return [];
}
var span = {
pos: ts.getLineStartPositionForPosition(parent.getStart(sourceFile), sourceFile),
end: parent.end
};
return formatSpan(span, sourceFile, options, rulesProvider, requestKind);
}
function findOutermostParent(position, expectedTokenKind, sourceFile) {
var precedingToken = ts.findPrecedingToken(position, sourceFile);
// when it is claimed that trigger character was typed at given position
// we verify that there is a token with a matching kind whose end is equal to position (because the character was just typed).
// If this condition is not hold - then trigger character was typed in some other context,
// i.e.in comment and thus should not trigger autoformatting
if (!precedingToken ||
precedingToken.kind !== expectedTokenKind ||
position !== precedingToken.getEnd()) {
return undefined;
}
// walk up and search for the parent node that ends at the same position with precedingToken.
// for cases like this
//
// let x = 1;
// while (true) {
// }
// after typing close curly in while statement we want to reformat just the while statement.
// However if we just walk upwards searching for the parent that has the same end value -
// we'll end up with the whole source file. isListElement allows to stop on the list element level
var current = precedingToken;
while (current &&
current.parent &&
current.parent.end === precedingToken.end &&
!isListElement(current.parent, current)) {
current = current.parent;
}
return current;
}
// Returns true if node is a element in some list in parent
// i.e. parent is class declaration with the list of members and node is one of members.
function isListElement(parent, node) {
switch (parent.kind) {
case 226 /* ClassDeclaration */:
case 227 /* InterfaceDeclaration */:
return ts.rangeContainsRange(parent.members, node);
case 230 /* ModuleDeclaration */:
var body = parent.body;
return body && body.kind === 231 /* ModuleBlock */ && ts.rangeContainsRange(body.statements, node);
case 261 /* SourceFile */:
case 204 /* Block */:
case 231 /* ModuleBlock */:
return ts.rangeContainsRange(parent.statements, node);
case 256 /* CatchClause */:
return ts.rangeContainsRange(parent.block.statements, node);
}
return false;
}
/** find node that fully contains given text range */
function findEnclosingNode(range, sourceFile) {
return find(sourceFile);
function find(n) {
var candidate = ts.forEachChild(n, function (c) { return ts.startEndContainsRange(c.getStart(sourceFile), c.end, range) && c; });
if (candidate) {
var result = find(candidate);
if (result) {
return result;
}
}
return n;
}
}
/** formatting is not applied to ranges that contain parse errors.
* This function will return a predicate that for a given text range will tell
* if there are any parse errors that overlap with the range.
*/
function prepareRangeContainsErrorFunction(errors, originalRange) {
if (!errors.length) {
return rangeHasNoErrors;
}
// pick only errors that fall in range
var sorted = errors
.filter(function (d) { return ts.rangeOverlapsWithStartEnd(originalRange, d.start, d.start + d.length); })
.sort(function (e1, e2) { return e1.start - e2.start; });
if (!sorted.length) {
return rangeHasNoErrors;
}
var index = 0;
return function (r) {
// in current implementation sequence of arguments [r1, r2...] is monotonically increasing.
// 'index' tracks the index of the most recent error that was checked.
while (true) {
if (index >= sorted.length) {
// all errors in the range were already checked -> no error in specified range
return false;
}
var error = sorted[index];
if (r.end <= error.start) {
// specified range ends before the error refered by 'index' - no error in range
return false;
}
if (ts.startEndOverlapsWithStartEnd(r.pos, r.end, error.start, error.start + error.length)) {
// specified range overlaps with error range
return true;
}
index++;
}
};
function rangeHasNoErrors() {
return false;
}
}
/**
* Start of the original range might fall inside the comment - scanner will not yield appropriate results
* This function will look for token that is located before the start of target range
* and return its end as start position for the scanner.
*/
function getScanStartPosition(enclosingNode, originalRange, sourceFile) {
var start = enclosingNode.getStart(sourceFile);
if (start === originalRange.pos && enclosingNode.end === originalRange.end) {
return start;
}
var precedingToken = ts.findPrecedingToken(originalRange.pos, sourceFile);
if (!precedingToken) {
// no preceding token found - start from the beginning of enclosing node
return enclosingNode.pos;
}
// preceding token ends after the start of original range (i.e when originalRange.pos falls in the middle of literal)
// start from the beginning of enclosingNode to handle the entire 'originalRange'
if (precedingToken.end >= originalRange.pos) {
return enclosingNode.pos;
}
return precedingToken.end;
}
/*
* For cases like
* if (a ||
* b ||$
* c) {...}
* If we hit Enter at $ we want line ' b ||' to be indented.
* Formatting will be applied to the last two lines.
* Node that fully encloses these lines is binary expression 'a ||...'.
* Initial indentation for this node will be 0.
* Binary expressions don't introduce new indentation scopes, however it is possible
* that some parent node on the same line does - like if statement in this case.
* Note that we are considering parents only from the same line with initial node -
* if parent is on the different line - its delta was already contributed
* to the initial indentation.
*/
function getOwnOrInheritedDelta(n, options, sourceFile) {
var previousLine = -1 /* Unknown */;
var child;
while (n) {
var line = sourceFile.getLineAndCharacterOfPosition(n.getStart(sourceFile)).line;
if (previousLine !== -1 /* Unknown */ && line !== previousLine) {
break;
}
if (formatting.SmartIndenter.shouldIndentChildNode(n, child)) {
return options.indentSize;
}
previousLine = line;
child = n;
n = n.parent;
}
return 0;
}
function formatSpan(originalRange, sourceFile, options, rulesProvider, requestKind) {
var rangeContainsError = prepareRangeContainsErrorFunction(sourceFile.parseDiagnostics, originalRange);
// formatting context is used by rules provider
var formattingContext = new formatting.FormattingContext(sourceFile, requestKind);
// find the smallest node that fully wraps the range and compute the initial indentation for the node
var enclosingNode = findEnclosingNode(originalRange, sourceFile);
var formattingScanner = formatting.getFormattingScanner(sourceFile, getScanStartPosition(enclosingNode, originalRange, sourceFile), originalRange.end);
var initialIndentation = formatting.SmartIndenter.getIndentationForNode(enclosingNode, originalRange, sourceFile, options);
var previousRangeHasError;
var previousRange;
var previousParent;
var previousRangeStartLine;
var lastIndentedLine;
var indentationOnLastIndentedLine;
var edits = [];
formattingScanner.advance();
if (formattingScanner.isOnToken()) {
var startLine = sourceFile.getLineAndCharacterOfPosition(enclosingNode.getStart(sourceFile)).line;
var undecoratedStartLine = startLine;
if (enclosingNode.decorators) {
undecoratedStartLine = sourceFile.getLineAndCharacterOfPosition(ts.getNonDecoratorTokenPosOfNode(enclosingNode, sourceFile)).line;
}
var delta = getOwnOrInheritedDelta(enclosingNode, options, sourceFile);
processNode(enclosingNode, enclosingNode, startLine, undecoratedStartLine, initialIndentation, delta);
}
if (!formattingScanner.isOnToken()) {
var leadingTrivia = formattingScanner.getCurrentLeadingTrivia();
if (leadingTrivia) {
processTrivia(leadingTrivia, enclosingNode, enclosingNode, undefined);
trimTrailingWhitespacesForRemainingRange();
}
}
formattingScanner.close();
return edits;
// local functions
/** Tries to compute the indentation for a list element.
* If list element is not in range then
* function will pick its actual indentation
* so it can be pushed downstream as inherited indentation.
* If list element is in the range - its indentation will be equal
* to inherited indentation from its predecessors.
*/
function tryComputeIndentationForListItem(startPos, endPos, parentStartLine, range, inheritedIndentation) {
if (ts.rangeOverlapsWithStartEnd(range, startPos, endPos) ||
ts.rangeContainsStartEnd(range, startPos, endPos) /* Not to miss zero-range nodes e.g. JsxText */) {
if (inheritedIndentation !== -1 /* Unknown */) {
return inheritedIndentation;
}
}
else {
var startLine = sourceFile.getLineAndCharacterOfPosition(startPos).line;
var startLinePosition = ts.getLineStartPositionForPosition(startPos, sourceFile);
var column = formatting.SmartIndenter.findFirstNonWhitespaceColumn(startLinePosition, startPos, sourceFile, options);
if (startLine !== parentStartLine || startPos === column) {
// Use the base indent size if it is greater than
// the indentation of the inherited predecessor.
var baseIndentSize = formatting.SmartIndenter.getBaseIndentation(options);
return baseIndentSize > column ? baseIndentSize : column;
}
}
return -1 /* Unknown */;
}
function computeIndentation(node, startLine, inheritedIndentation, parent, parentDynamicIndentation, effectiveParentStartLine) {
var indentation = inheritedIndentation;
var delta = formatting.SmartIndenter.shouldIndentChildNode(node) ? options.indentSize : 0;
if (effectiveParentStartLine === startLine) {
// if node is located on the same line with the parent
// - inherit indentation from the parent
// - push children if either parent of node itself has non-zero delta
indentation = startLine === lastIndentedLine
? indentationOnLastIndentedLine
: parentDynamicIndentation.getIndentation();
delta = Math.min(options.indentSize, parentDynamicIndentation.getDelta(node) + delta);
}
else if (indentation === -1 /* Unknown */) {
if (formatting.SmartIndenter.childStartsOnTheSameLineWithElseInIfStatement(parent, node, startLine, sourceFile)) {
indentation = parentDynamicIndentation.getIndentation();
}
else {
indentation = parentDynamicIndentation.getIndentation() + parentDynamicIndentation.getDelta(node);
}
}
return {
indentation: indentation,
delta: delta
};
}
function getFirstNonDecoratorTokenOfNode(node) {
if (node.modifiers && node.modifiers.length) {
return node.modifiers[0].kind;
}
switch (node.kind) {
case 226 /* ClassDeclaration */: return 74 /* ClassKeyword */;
case 227 /* InterfaceDeclaration */: return 108 /* InterfaceKeyword */;
case 225 /* FunctionDeclaration */: return 88 /* FunctionKeyword */;
case 229 /* EnumDeclaration */: return 229 /* EnumDeclaration */;
case 151 /* GetAccessor */: return 124 /* GetKeyword */;
case 152 /* SetAccessor */: return 133 /* SetKeyword */;
case 149 /* MethodDeclaration */:
if (node.asteriskToken) {
return 38 /* AsteriskToken */;
} /*
fall-through
*/
case 147 /* PropertyDeclaration */:
case 144 /* Parameter */:
return node.name.kind;
}
}
function getDynamicIndentation(node, nodeStartLine, indentation, delta) {
return {
getIndentationForComment: function (kind, tokenIndentation, container) {
switch (kind) {
// preceding comment to the token that closes the indentation scope inherits the indentation from the scope
// .. {
// // comment
// }
case 17 /* CloseBraceToken */:
case 21 /* CloseBracketToken */:
case 19 /* CloseParenToken */:
return indentation + getEffectiveDelta(delta, container);
}
return tokenIndentation !== -1 /* Unknown */ ? tokenIndentation : indentation;
},
getIndentationForToken: function (line, kind, container) {
if (nodeStartLine !== line && node.decorators) {
if (kind === getFirstNonDecoratorTokenOfNode(node)) {
// if this token is the first token following the list of decorators, we do not need to indent
return indentation;
}
}
switch (kind) {
// open and close brace, 'else' and 'while' (in do statement) tokens has indentation of the parent
case 16 /* OpenBraceToken */:
case 17 /* CloseBraceToken */:
case 20 /* OpenBracketToken */:
case 21 /* CloseBracketToken */:
case 18 /* OpenParenToken */:
case 19 /* CloseParenToken */:
case 81 /* ElseKeyword */:
case 105 /* WhileKeyword */:
case 56 /* AtToken */:
return indentation;
default:
// if token line equals to the line of containing node (this is a first token in the node) - use node indentation
return nodeStartLine !== line ? indentation + getEffectiveDelta(delta, container) : indentation;
}
},
getIndentation: function () { return indentation; },
getDelta: function (child) { return getEffectiveDelta(delta, child); },
recomputeIndentation: function (lineAdded) {
if (node.parent && formatting.SmartIndenter.shouldIndentChildNode(node.parent, node)) {
if (lineAdded) {
indentation += options.indentSize;
}
else {
indentation -= options.indentSize;
}
if (formatting.SmartIndenter.shouldIndentChildNode(node)) {
delta = options.indentSize;
}
else {
delta = 0;
}
}
}
};
function getEffectiveDelta(delta, child) {
// Delta value should be zero when the node explicitly prevents indentation of the child node
return formatting.SmartIndenter.nodeWillIndentChild(node, child, true) ? delta : 0;
}
}
function processNode(node, contextNode, nodeStartLine, undecoratedNodeStartLine, indentation, delta) {
if (!ts.rangeOverlapsWithStartEnd(originalRange, node.getStart(sourceFile), node.getEnd())) {
return;
}
var nodeDynamicIndentation = getDynamicIndentation(node, nodeStartLine, indentation, delta);
// a useful observations when tracking context node
// /
// [a]
// / | \
// [b] [c] [d]
// node 'a' is a context node for nodes 'b', 'c', 'd'
// except for the leftmost leaf token in [b] - in this case context node ('e') is located somewhere above 'a'
// this rule can be applied recursively to child nodes of 'a'.
//
// context node is set to parent node value after processing every child node
// context node is set to parent of the token after processing every token
var childContextNode = contextNode;
// if there are any tokens that logically belong to node and interleave child nodes
// such tokens will be consumed in processChildNode for for the child that follows them
ts.forEachChild(node, function (child) {
processChildNode(child, /*inheritedIndentation*/ -1 /* Unknown */, node, nodeDynamicIndentation, nodeStartLine, undecoratedNodeStartLine, /*isListItem*/ false);
}, function (nodes) {
processChildNodes(nodes, node, nodeStartLine, nodeDynamicIndentation);
});
// proceed any tokens in the node that are located after child nodes
while (formattingScanner.isOnToken()) {
var tokenInfo = formattingScanner.readTokenInfo(node);
if (tokenInfo.token.end > node.end) {
break;
}
consumeTokenAndAdvanceScanner(tokenInfo, node, nodeDynamicIndentation);
}
function processChildNode(child, inheritedIndentation, parent, parentDynamicIndentation, parentStartLine, undecoratedParentStartLine, isListItem, isFirstListItem) {
var childStartPos = child.getStart(sourceFile);
var childStartLine = sourceFile.getLineAndCharacterOfPosition(childStartPos).line;
var undecoratedChildStartLine = childStartLine;
if (child.decorators) {
undecoratedChildStartLine = sourceFile.getLineAndCharacterOfPosition(ts.getNonDecoratorTokenPosOfNode(child, sourceFile)).line;
}
// if child is a list item - try to get its indentation
var childIndentationAmount = -1 /* Unknown */;
if (isListItem) {
childIndentationAmount = tryComputeIndentationForListItem(childStartPos, child.end, parentStartLine, originalRange, inheritedIndentation);
if (childIndentationAmount !== -1 /* Unknown */) {
inheritedIndentation = childIndentationAmount;
}
}
// child node is outside the target range - do not dive inside
if (!ts.rangeOverlapsWithStartEnd(originalRange, child.pos, child.end)) {
if (child.end < originalRange.pos) {
formattingScanner.skipToEndOf(child);
}
return inheritedIndentation;
}
if (child.getFullWidth() === 0) {
return inheritedIndentation;
}
while (formattingScanner.isOnToken()) {
// proceed any parent tokens that are located prior to child.getStart()
var tokenInfo = formattingScanner.readTokenInfo(node);
if (tokenInfo.token.end > childStartPos) {
// stop when formatting scanner advances past the beginning of the child
break;
}
consumeTokenAndAdvanceScanner(tokenInfo, node, parentDynamicIndentation);
}
if (!formattingScanner.isOnToken()) {
return inheritedIndentation;
}
// JSX text shouldn't affect indenting
if (ts.isToken(child) && child.kind !== 10 /* JsxText */) {
// if child node is a token, it does not impact indentation, proceed it using parent indentation scope rules
var tokenInfo = formattingScanner.readTokenInfo(child);
ts.Debug.assert(tokenInfo.token.end === child.end, "Token end is child end");
consumeTokenAndAdvanceScanner(tokenInfo, node, parentDynamicIndentation, child);
return inheritedIndentation;
}
var effectiveParentStartLine = child.kind === 145 /* Decorator */ ? childStartLine : undecoratedParentStartLine;
var childIndentation = computeIndentation(child, childStartLine, childIndentationAmount, node, parentDynamicIndentation, effectiveParentStartLine);
processNode(child, childContextNode, childStartLine, undecoratedChildStartLine, childIndentation.indentation, childIndentation.delta);
childContextNode = node;
if (isFirstListItem && parent.kind === 175 /* ArrayLiteralExpression */ && inheritedIndentation === -1 /* Unknown */) {
inheritedIndentation = childIndentation.indentation;
}
return inheritedIndentation;
}
function processChildNodes(nodes, parent, parentStartLine, parentDynamicIndentation) {
var listStartToken = getOpenTokenForList(parent, nodes);
var listEndToken = getCloseTokenForOpenToken(listStartToken);
var listDynamicIndentation = parentDynamicIndentation;
var startLine = parentStartLine;
if (listStartToken !== 0 /* Unknown */) {
// introduce a new indentation scope for lists (including list start and end tokens)
while (formattingScanner.isOnToken()) {
var tokenInfo = formattingScanner.readTokenInfo(parent);
if (tokenInfo.token.end > nodes.pos) {
// stop when formatting scanner moves past the beginning of node list
break;
}
else if (tokenInfo.token.kind === listStartToken) {
// consume list start token
startLine = sourceFile.getLineAndCharacterOfPosition(tokenInfo.token.pos).line;
var indentation_1 = computeIndentation(tokenInfo.token, startLine, -1 /* Unknown */, parent, parentDynamicIndentation, parentStartLine);
listDynamicIndentation = getDynamicIndentation(parent, parentStartLine, indentation_1.indentation, indentation_1.delta);
consumeTokenAndAdvanceScanner(tokenInfo, parent, listDynamicIndentation);
}
else {
// consume any tokens that precede the list as child elements of 'node' using its indentation scope
consumeTokenAndAdvanceScanner(tokenInfo, parent, parentDynamicIndentation);
}
}
}
var inheritedIndentation = -1 /* Unknown */;
for (var i = 0; i < nodes.length; i++) {
var child = nodes[i];
inheritedIndentation = processChildNode(child, inheritedIndentation, node, listDynamicIndentation, startLine, startLine, /*isListItem*/ true, /*isFirstListItem*/ i === 0);
}
if (listEndToken !== 0 /* Unknown */) {
if (formattingScanner.isOnToken()) {
var tokenInfo = formattingScanner.readTokenInfo(parent);
// consume the list end token only if it is still belong to the parent
// there might be the case when current token matches end token but does not considered as one
// function (x: function) <--
// without this check close paren will be interpreted as list end token for function expression which is wrong
if (tokenInfo.token.kind === listEndToken && ts.rangeContainsRange(parent, tokenInfo.token)) {
// consume list end token
consumeTokenAndAdvanceScanner(tokenInfo, parent, listDynamicIndentation);
}
}
}
}
function consumeTokenAndAdvanceScanner(currentTokenInfo, parent, dynamicIndentation, container) {
ts.Debug.assert(ts.rangeContainsRange(parent, currentTokenInfo.token));
var lastTriviaWasNewLine = formattingScanner.lastTrailingTriviaWasNewLine();
var indentToken = false;
if (currentTokenInfo.leadingTrivia) {
processTrivia(currentTokenInfo.leadingTrivia, parent, childContextNode, dynamicIndentation);
}
var lineAdded;
var isTokenInRange = ts.rangeContainsRange(originalRange, currentTokenInfo.token);
var tokenStart = sourceFile.getLineAndCharacterOfPosition(currentTokenInfo.token.pos);
if (isTokenInRange) {
var rangeHasError = rangeContainsError(currentTokenInfo.token);
// save previousRange since processRange will overwrite this value with current one
var savePreviousRange = previousRange;
lineAdded = processRange(currentTokenInfo.token, tokenStart, parent, childContextNode, dynamicIndentation);
if (rangeHasError) {
// do not indent comments\token if token range overlaps with some error
indentToken = false;
}
else {
if (lineAdded !== undefined) {
indentToken = lineAdded;
}
else {
// indent token only if end line of previous range does not match start line of the token
var prevEndLine = savePreviousRange && sourceFile.getLineAndCharacterOfPosition(savePreviousRange.end).line;
indentToken = lastTriviaWasNewLine && tokenStart.line !== prevEndLine;
}
}
}
if (currentTokenInfo.trailingTrivia) {
processTrivia(currentTokenInfo.trailingTrivia, parent, childContextNode, dynamicIndentation);
}
if (indentToken) {
var tokenIndentation = (isTokenInRange && !rangeContainsError(currentTokenInfo.token)) ?
dynamicIndentation.getIndentationForToken(tokenStart.line, currentTokenInfo.token.kind, container) :
-1 /* Unknown */;
var indentNextTokenOrTrivia = true;
if (currentTokenInfo.leadingTrivia) {
var commentIndentation = dynamicIndentation.getIndentationForComment(currentTokenInfo.token.kind, tokenIndentation, container);
for (var _i = 0, _a = currentTokenInfo.leadingTrivia; _i < _a.length; _i++) {
var triviaItem = _a[_i];
var triviaInRange = ts.rangeContainsRange(originalRange, triviaItem);
switch (triviaItem.kind) {
case 3 /* MultiLineCommentTrivia */:
if (triviaInRange) {
indentMultilineComment(triviaItem, commentIndentation, /*firstLineIsIndented*/ !indentNextTokenOrTrivia);
}
indentNextTokenOrTrivia = false;
break;
case 2 /* SingleLineCommentTrivia */:
if (indentNextTokenOrTrivia && triviaInRange) {
insertIndentation(triviaItem.pos, commentIndentation, /*lineAdded*/ false);
}
indentNextTokenOrTrivia = false;
break;
case 4 /* NewLineTrivia */:
indentNextTokenOrTrivia = true;
break;
}
}
}
// indent token only if is it is in target range and does not overlap with any error ranges
if (tokenIndentation !== -1 /* Unknown */ && indentNextTokenOrTrivia) {
insertIndentation(currentTokenInfo.token.pos, tokenIndentation, lineAdded);
lastIndentedLine = tokenStart.line;
indentationOnLastIndentedLine = tokenIndentation;
}
}
formattingScanner.advance();
childContextNode = parent;
}
}
function processTrivia(trivia, parent, contextNode, dynamicIndentation) {
for (var _i = 0, trivia_1 = trivia; _i < trivia_1.length; _i++) {
var triviaItem = trivia_1[_i];
if (ts.isComment(triviaItem.kind) && ts.rangeContainsRange(originalRange, triviaItem)) {
var triviaItemStart = sourceFile.getLineAndCharacterOfPosition(triviaItem.pos);
processRange(triviaItem, triviaItemStart, parent, contextNode, dynamicIndentation);
}
}
}
function processRange(range, rangeStart, parent, contextNode, dynamicIndentation) {
var rangeHasError = rangeContainsError(range);
var lineAdded;
if (!rangeHasError && !previousRangeHasError) {
if (!previousRange) {
// trim whitespaces starting from the beginning of the span up to the current line
var originalStart = sourceFile.getLineAndCharacterOfPosition(originalRange.pos);
trimTrailingWhitespacesForLines(originalStart.line, rangeStart.line);
}
else {
lineAdded =
processPair(range, rangeStart.line, parent, previousRange, previousRangeStartLine, previousParent, contextNode, dynamicIndentation);
}
}
previousRange = range;
previousParent = parent;
previousRangeStartLine = rangeStart.line;
previousRangeHasError = rangeHasError;
return lineAdded;
}
function processPair(currentItem, currentStartLine, currentParent, previousItem, previousStartLine, previousParent, contextNode, dynamicIndentation) {
formattingContext.updateContext(previousItem, previousParent, currentItem, currentParent, contextNode);
var rule = rulesProvider.getRulesMap().GetRule(formattingContext);
var trimTrailingWhitespaces;
var lineAdded;
if (rule) {
applyRuleEdits(rule, previousItem, previousStartLine, currentItem, currentStartLine);
if (rule.Operation.Action & (2 /* Space */ | 8 /* Delete */) && currentStartLine !== previousStartLine) {
lineAdded = false;
// Handle the case where the next line is moved to be the end of this line.
// In this case we don't indent the next line in the next pass.
if (currentParent.getStart(sourceFile) === currentItem.pos) {
dynamicIndentation.recomputeIndentation(/*lineAddedByFormatting*/ false);
}
}
else if (rule.Operation.Action & 4 /* NewLine */ && currentStartLine === previousStartLine) {
lineAdded = true;
// Handle the case where token2 is moved to the new line.
// In this case we indent token2 in the next pass but we set
// sameLineIndent flag to notify the indenter that the indentation is within the line.
if (currentParent.getStart(sourceFile) === currentItem.pos) {
dynamicIndentation.recomputeIndentation(/*lineAddedByFormatting*/ true);
}
}
// We need to trim trailing whitespace between the tokens if they were on different lines, and no rule was applied to put them on the same line
trimTrailingWhitespaces = !(rule.Operation.Action & 8 /* Delete */) && rule.Flag !== 1 /* CanDeleteNewLines */;
}
else {
trimTrailingWhitespaces = true;
}
if (currentStartLine !== previousStartLine && trimTrailingWhitespaces) {
// We need to trim trailing whitespace between the tokens if they were on different lines, and no rule was applied to put them on the same line
trimTrailingWhitespacesForLines(previousStartLine, currentStartLine, previousItem);
}
return lineAdded;
}
function insertIndentation(pos, indentation, lineAdded) {
var indentationString = getIndentationString(indentation, options);
if (lineAdded) {
// new line is added before the token by the formatting rules
// insert indentation string at the very beginning of the token
recordReplace(pos, 0, indentationString);
}
else {
var tokenStart = sourceFile.getLineAndCharacterOfPosition(pos);
var startLinePosition = ts.getStartPositionOfLine(tokenStart.line, sourceFile);
if (indentation !== tokenStart.character || indentationIsDifferent(indentationString, startLinePosition)) {
recordReplace(startLinePosition, tokenStart.character, indentationString);
}
}
}
function indentationIsDifferent(indentationString, startLinePosition) {
return indentationString !== sourceFile.text.substr(startLinePosition, indentationString.length);
}
function indentMultilineComment(commentRange, indentation, firstLineIsIndented) {
// split comment in lines
var startLine = sourceFile.getLineAndCharacterOfPosition(commentRange.pos).line;
var endLine = sourceFile.getLineAndCharacterOfPosition(commentRange.end).line;
var parts;
if (startLine === endLine) {
if (!firstLineIsIndented) {
// treat as single line comment
insertIndentation(commentRange.pos, indentation, /*lineAdded*/ false);
}
return;
}
else {
parts = [];
var startPos = commentRange.pos;
for (var line = startLine; line < endLine; line++) {
var endOfLine = ts.getEndLinePosition(line, sourceFile);
parts.push({ pos: startPos, end: endOfLine });
startPos = ts.getStartPositionOfLine(line + 1, sourceFile);
}
parts.push({ pos: startPos, end: commentRange.end });
}
var startLinePos = ts.getStartPositionOfLine(startLine, sourceFile);
var nonWhitespaceColumnInFirstPart = formatting.SmartIndenter.findFirstNonWhitespaceCharacterAndColumn(startLinePos, parts[0].pos, sourceFile, options);
if (indentation === nonWhitespaceColumnInFirstPart.column) {
return;
}
var startIndex = 0;
if (firstLineIsIndented) {
startIndex = 1;
startLine++;
}
// shift all parts on the delta size
var delta = indentation - nonWhitespaceColumnInFirstPart.column;
for (var i = startIndex, len = parts.length; i < len; i++, startLine++) {
var startLinePos_1 = ts.getStartPositionOfLine(startLine, sourceFile);
var nonWhitespaceCharacterAndColumn = i === 0
? nonWhitespaceColumnInFirstPart
: formatting.SmartIndenter.findFirstNonWhitespaceCharacterAndColumn(parts[i].pos, parts[i].end, sourceFile, options);
var newIndentation = nonWhitespaceCharacterAndColumn.column + delta;
if (newIndentation > 0) {
var indentationString = getIndentationString(newIndentation, options);
recordReplace(startLinePos_1, nonWhitespaceCharacterAndColumn.character, indentationString);
}
else {
recordDelete(startLinePos_1, nonWhitespaceCharacterAndColumn.character);
}
}
}
function trimTrailingWhitespacesForLines(line1, line2, range) {
for (var line = line1; line < line2; line++) {
var lineStartPosition = ts.getStartPositionOfLine(line, sourceFile);
var lineEndPosition = ts.getEndLinePosition(line, sourceFile);
// do not trim whitespaces in comments or template expression
if (range && (ts.isComment(range.kind) || ts.isStringOrRegularExpressionOrTemplateLiteral(range.kind)) && range.pos <= lineEndPosition && range.end > lineEndPosition) {
continue;
}
var whitespaceStart = getTrailingWhitespaceStartPosition(lineStartPosition, lineEndPosition);
if (whitespaceStart !== -1) {
ts.Debug.assert(whitespaceStart === lineStartPosition || !ts.isWhiteSpaceSingleLine(sourceFile.text.charCodeAt(whitespaceStart - 1)));
recordDelete(whitespaceStart, lineEndPosition + 1 - whitespaceStart);
}
}
}
/**
* @param start The position of the first character in range
* @param end The position of the last character in range
*/
function getTrailingWhitespaceStartPosition(start, end) {
var pos = end;
while (pos >= start && ts.isWhiteSpaceSingleLine(sourceFile.text.charCodeAt(pos))) {
pos--;
}
if (pos !== end) {
return pos + 1;
}
return -1;
}
/**
* Trimming will be done for lines after the previous range
*/
function trimTrailingWhitespacesForRemainingRange() {
var startPosition = previousRange ? previousRange.end : originalRange.pos;
var startLine = sourceFile.getLineAndCharacterOfPosition(startPosition).line;
var endLine = sourceFile.getLineAndCharacterOfPosition(originalRange.end).line;
trimTrailingWhitespacesForLines(startLine, endLine + 1, previousRange);
}
function newTextChange(start, len, newText) {
return { span: ts.createTextSpan(start, len), newText: newText };
}
function recordDelete(start, len) {
if (len) {
edits.push(newTextChange(start, len, ""));
}
}
function recordReplace(start, len, newText) {
if (len || newText) {
edits.push(newTextChange(start, len, newText));
}
}
function applyRuleEdits(rule, previousRange, previousStartLine, currentRange, currentStartLine) {
switch (rule.Operation.Action) {
case 1 /* Ignore */:
// no action required
return;
case 8 /* Delete */:
if (previousRange.end !== currentRange.pos) {
// delete characters starting from t1.end up to t2.pos exclusive
recordDelete(previousRange.end, currentRange.pos - previousRange.end);
}
break;
case 4 /* NewLine */:
// exit early if we on different lines and rule cannot change number of newlines
// if line1 and line2 are on subsequent lines then no edits are required - ok to exit
// if line1 and line2 are separated with more than one newline - ok to exit since we cannot delete extra new lines
if (rule.Flag !== 1 /* CanDeleteNewLines */ && previousStartLine !== currentStartLine) {
return;
}
// edit should not be applied only if we have one line feed between elements
var lineDelta = currentStartLine - previousStartLine;
if (lineDelta !== 1) {
recordReplace(previousRange.end, currentRange.pos - previousRange.end, options.newLineCharacter);
}
break;
case 2 /* Space */:
// exit early if we on different lines and rule cannot change number of newlines
if (rule.Flag !== 1 /* CanDeleteNewLines */ && previousStartLine !== currentStartLine) {
return;
}
var posDelta = currentRange.pos - previousRange.end;
if (posDelta !== 1 || sourceFile.text.charCodeAt(previousRange.end) !== 32 /* space */) {
recordReplace(previousRange.end, currentRange.pos - previousRange.end, " ");
}
break;
}
}
}
function getOpenTokenForList(node, list) {
switch (node.kind) {
case 150 /* Constructor */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 185 /* ArrowFunction */:
if (node.typeParameters === list) {
return 26 /* LessThanToken */;
}
else if (node.parameters === list) {
return 18 /* OpenParenToken */;
}
break;
case 179 /* CallExpression */:
case 180 /* NewExpression */:
if (node.typeArguments === list) {
return 26 /* LessThanToken */;
}
else if (node.arguments === list) {
return 18 /* OpenParenToken */;
}
break;
case 157 /* TypeReference */:
if (node.typeArguments === list) {
return 26 /* LessThanToken */;
}
}
return 0 /* Unknown */;
}
function getCloseTokenForOpenToken(kind) {
switch (kind) {
case 18 /* OpenParenToken */:
return 19 /* CloseParenToken */;
case 26 /* LessThanToken */:
return 28 /* GreaterThanToken */;
}
return 0 /* Unknown */;
}
var internedSizes;
var internedTabsIndentation;
var internedSpacesIndentation;
function getIndentationString(indentation, options) {
// reset interned strings if FormatCodeOptions were changed
var resetInternedStrings = !internedSizes || (internedSizes.tabSize !== options.tabSize || internedSizes.indentSize !== options.indentSize);
if (resetInternedStrings) {
internedSizes = { tabSize: options.tabSize, indentSize: options.indentSize };
internedTabsIndentation = internedSpacesIndentation = undefined;
}
if (!options.convertTabsToSpaces) {
var tabs = Math.floor(indentation / options.tabSize);
var spaces = indentation - tabs * options.tabSize;
var tabString = void 0;
if (!internedTabsIndentation) {
internedTabsIndentation = [];
}
if (internedTabsIndentation[tabs] === undefined) {
internedTabsIndentation[tabs] = tabString = repeat("\t", tabs);
}
else {
tabString = internedTabsIndentation[tabs];
}
return spaces ? tabString + repeat(" ", spaces) : tabString;
}
else {
var spacesString = void 0;
var quotient = Math.floor(indentation / options.indentSize);
var remainder = indentation % options.indentSize;
if (!internedSpacesIndentation) {
internedSpacesIndentation = [];
}
if (internedSpacesIndentation[quotient] === undefined) {
spacesString = repeat(" ", options.indentSize * quotient);
internedSpacesIndentation[quotient] = spacesString;
}
else {
spacesString = internedSpacesIndentation[quotient];
}
return remainder ? spacesString + repeat(" ", remainder) : spacesString;
}
function repeat(value, count) {
var s = "";
for (var i = 0; i < count; i++) {
s += value;
}
return s;
}
}
formatting.getIndentationString = getIndentationString;
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
///<reference path='..\services.ts' />
/* @internal */
var ts;
(function (ts) {
var formatting;
(function (formatting) {
var SmartIndenter;
(function (SmartIndenter) {
var Value;
(function (Value) {
Value[Value["Unknown"] = -1] = "Unknown";
})(Value || (Value = {}));
function getIndentation(position, sourceFile, options) {
if (position > sourceFile.text.length) {
return getBaseIndentation(options); // past EOF
}
// no indentation when the indent style is set to none,
// so we can return fast
if (options.indentStyle === ts.IndentStyle.None) {
return 0;
}
var precedingToken = ts.findPrecedingToken(position, sourceFile);
if (!precedingToken) {
return getBaseIndentation(options);
}
// no indentation in string \regex\template literals
var precedingTokenIsLiteral = ts.isStringOrRegularExpressionOrTemplateLiteral(precedingToken.kind);
if (precedingTokenIsLiteral && precedingToken.getStart(sourceFile) <= position && precedingToken.end > position) {
return 0;
}
var lineAtPosition = sourceFile.getLineAndCharacterOfPosition(position).line;
// indentation is first non-whitespace character in a previous line
// for block indentation, we should look for a line which contains something that's not
// whitespace.
if (options.indentStyle === ts.IndentStyle.Block) {
// move backwards until we find a line with a non-whitespace character,
// then find the first non-whitespace character for that line.
var current_1 = position;
while (current_1 > 0) {
var char = sourceFile.text.charCodeAt(current_1);
if (!ts.isWhiteSpace(char)) {
break;
}
current_1--;
}
var lineStart = ts.getLineStartPositionForPosition(current_1, sourceFile);
return SmartIndenter.findFirstNonWhitespaceColumn(lineStart, current_1, sourceFile, options);
}
if (precedingToken.kind === 25 /* CommaToken */ && precedingToken.parent.kind !== 192 /* BinaryExpression */) {
// previous token is comma that separates items in list - find the previous item and try to derive indentation from it
var actualIndentation = getActualIndentationForListItemBeforeComma(precedingToken, sourceFile, options);
if (actualIndentation !== -1 /* Unknown */) {
return actualIndentation;
}
}
// try to find node that can contribute to indentation and includes 'position' starting from 'precedingToken'
// if such node is found - compute initial indentation for 'position' inside this node
var previous;
var current = precedingToken;
var currentStart;
var indentationDelta;
while (current) {
if (ts.positionBelongsToNode(current, position, sourceFile) && shouldIndentChildNode(current, previous)) {
currentStart = getStartLineAndCharacterForNode(current, sourceFile);
if (nextTokenIsCurlyBraceOnSameLineAsCursor(precedingToken, current, lineAtPosition, sourceFile)) {
indentationDelta = 0;
}
else {
indentationDelta = lineAtPosition !== currentStart.line ? options.indentSize : 0;
}
break;
}
// check if current node is a list item - if yes, take indentation from it
var actualIndentation = getActualIndentationForListItem(current, sourceFile, options);
if (actualIndentation !== -1 /* Unknown */) {
return actualIndentation;
}
actualIndentation = getLineIndentationWhenExpressionIsInMultiLine(current, sourceFile, options);
if (actualIndentation !== -1 /* Unknown */) {
return actualIndentation + options.indentSize;
}
previous = current;
current = current.parent;
}
if (!current) {
// no parent was found - return the base indentation of the SourceFile
return getBaseIndentation(options);
}
return getIndentationForNodeWorker(current, currentStart, /*ignoreActualIndentationRange*/ undefined, indentationDelta, sourceFile, options);
}
SmartIndenter.getIndentation = getIndentation;
function getIndentationForNode(n, ignoreActualIndentationRange, sourceFile, options) {
var start = sourceFile.getLineAndCharacterOfPosition(n.getStart(sourceFile));
return getIndentationForNodeWorker(n, start, ignoreActualIndentationRange, /*indentationDelta*/ 0, sourceFile, options);
}
SmartIndenter.getIndentationForNode = getIndentationForNode;
function getBaseIndentation(options) {
return options.baseIndentSize || 0;
}
SmartIndenter.getBaseIndentation = getBaseIndentation;
function getIndentationForNodeWorker(current, currentStart, ignoreActualIndentationRange, indentationDelta, sourceFile, options) {
var parent = current.parent;
var parentStart;
// walk upwards and collect indentations for pairs of parent-child nodes
// indentation is not added if parent and child nodes start on the same line or if parent is IfStatement and child starts on the same line with 'else clause'
while (parent) {
var useActualIndentation = true;
if (ignoreActualIndentationRange) {
var start = current.getStart(sourceFile);
useActualIndentation = start < ignoreActualIndentationRange.pos || start > ignoreActualIndentationRange.end;
}
if (useActualIndentation) {
// check if current node is a list item - if yes, take indentation from it
var actualIndentation = getActualIndentationForListItem(current, sourceFile, options);
if (actualIndentation !== -1 /* Unknown */) {
return actualIndentation + indentationDelta;
}
}
parentStart = getParentStart(parent, current, sourceFile);
var parentAndChildShareLine = parentStart.line === currentStart.line ||
childStartsOnTheSameLineWithElseInIfStatement(parent, current, currentStart.line, sourceFile);
if (useActualIndentation) {
// try to fetch actual indentation for current node from source text
var actualIndentation = getActualIndentationForNode(current, parent, currentStart, parentAndChildShareLine, sourceFile, options);
if (actualIndentation !== -1 /* Unknown */) {
return actualIndentation + indentationDelta;
}
actualIndentation = getLineIndentationWhenExpressionIsInMultiLine(current, sourceFile, options);
if (actualIndentation !== -1 /* Unknown */) {
return actualIndentation + indentationDelta;
}
}
// increase indentation if parent node wants its content to be indented and parent and child nodes don't start on the same line
if (shouldIndentChildNode(parent, current) && !parentAndChildShareLine) {
indentationDelta += options.indentSize;
}
current = parent;
currentStart = parentStart;
parent = current.parent;
}
return indentationDelta + getBaseIndentation(options);
}
function getParentStart(parent, child, sourceFile) {
var containingList = getContainingList(child, sourceFile);
if (containingList) {
return sourceFile.getLineAndCharacterOfPosition(containingList.pos);
}
return sourceFile.getLineAndCharacterOfPosition(parent.getStart(sourceFile));
}
/*
* Function returns Value.Unknown if indentation cannot be determined
*/
function getActualIndentationForListItemBeforeComma(commaToken, sourceFile, options) {
// previous token is comma that separates items in list - find the previous item and try to derive indentation from it
var commaItemInfo = ts.findListItemInfo(commaToken);
if (commaItemInfo && commaItemInfo.listItemIndex > 0) {
return deriveActualIndentationFromList(commaItemInfo.list.getChildren(), commaItemInfo.listItemIndex - 1, sourceFile, options);
}
else {
// handle broken code gracefully
return -1 /* Unknown */;
}
}
/*
* Function returns Value.Unknown if actual indentation for node should not be used (i.e because node is nested expression)
*/
function getActualIndentationForNode(current, parent, currentLineAndChar, parentAndChildShareLine, sourceFile, options) {
// actual indentation is used for statements\declarations if one of cases below is true:
// - parent is SourceFile - by default immediate children of SourceFile are not indented except when user indents them manually
// - parent and child are not on the same line
var useActualIndentation = (ts.isDeclaration(current) || ts.isStatementButNotDeclaration(current)) &&
(parent.kind === 261 /* SourceFile */ || !parentAndChildShareLine);
if (!useActualIndentation) {
return -1 /* Unknown */;
}
return findColumnForFirstNonWhitespaceCharacterInLine(currentLineAndChar, sourceFile, options);
}
function nextTokenIsCurlyBraceOnSameLineAsCursor(precedingToken, current, lineAtPosition, sourceFile) {
var nextToken = ts.findNextToken(precedingToken, current);
if (!nextToken) {
return false;
}
if (nextToken.kind === 16 /* OpenBraceToken */) {
// open braces are always indented at the parent level
return true;
}
else if (nextToken.kind === 17 /* CloseBraceToken */) {
// close braces are indented at the parent level if they are located on the same line with cursor
// this means that if new line will be added at $ position, this case will be indented
// class A {
// $
// }
/// and this one - not
// class A {
// $}
var nextTokenStartLine = getStartLineAndCharacterForNode(nextToken, sourceFile).line;
return lineAtPosition === nextTokenStartLine;
}
return false;
}
function getStartLineAndCharacterForNode(n, sourceFile) {
return sourceFile.getLineAndCharacterOfPosition(n.getStart(sourceFile));
}
function childStartsOnTheSameLineWithElseInIfStatement(parent, child, childStartLine, sourceFile) {
if (parent.kind === 208 /* IfStatement */ && parent.elseStatement === child) {
var elseKeyword = ts.findChildOfKind(parent, 81 /* ElseKeyword */, sourceFile);
ts.Debug.assert(elseKeyword !== undefined);
var elseKeywordStartLine = getStartLineAndCharacterForNode(elseKeyword, sourceFile).line;
return elseKeywordStartLine === childStartLine;
}
return false;
}
SmartIndenter.childStartsOnTheSameLineWithElseInIfStatement = childStartsOnTheSameLineWithElseInIfStatement;
function getContainingList(node, sourceFile) {
if (node.parent) {
switch (node.parent.kind) {
case 157 /* TypeReference */:
if (node.parent.typeArguments &&
ts.rangeContainsStartEnd(node.parent.typeArguments, node.getStart(sourceFile), node.getEnd())) {
return node.parent.typeArguments;
}
break;
case 176 /* ObjectLiteralExpression */:
return node.parent.properties;
case 175 /* ArrayLiteralExpression */:
return node.parent.elements;
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */: {
var start = node.getStart(sourceFile);
if (node.parent.typeParameters &&
ts.rangeContainsStartEnd(node.parent.typeParameters, start, node.getEnd())) {
return node.parent.typeParameters;
}
if (ts.rangeContainsStartEnd(node.parent.parameters, start, node.getEnd())) {
return node.parent.parameters;
}
break;
}
case 180 /* NewExpression */:
case 179 /* CallExpression */: {
var start = node.getStart(sourceFile);
if (node.parent.typeArguments &&
ts.rangeContainsStartEnd(node.parent.typeArguments, start, node.getEnd())) {
return node.parent.typeArguments;
}
if (node.parent.arguments &&
ts.rangeContainsStartEnd(node.parent.arguments, start, node.getEnd())) {
return node.parent.arguments;
}
break;
}
}
}
return undefined;
}
function getActualIndentationForListItem(node, sourceFile, options) {
var containingList = getContainingList(node, sourceFile);
return containingList ? getActualIndentationFromList(containingList) : -1 /* Unknown */;
function getActualIndentationFromList(list) {
var index = ts.indexOf(list, node);
return index !== -1 ? deriveActualIndentationFromList(list, index, sourceFile, options) : -1 /* Unknown */;
}
}
function getLineIndentationWhenExpressionIsInMultiLine(node, sourceFile, options) {
// actual indentation should not be used when:
// - node is close parenthesis - this is the end of the expression
if (node.kind === 19 /* CloseParenToken */) {
return -1 /* Unknown */;
}
if (node.parent && (node.parent.kind === 179 /* CallExpression */ ||
node.parent.kind === 180 /* NewExpression */) &&
node.parent.expression !== node) {
var fullCallOrNewExpression = node.parent.expression;
var startingExpression = getStartingExpression(fullCallOrNewExpression);
if (fullCallOrNewExpression === startingExpression) {
return -1 /* Unknown */;
}
var fullCallOrNewExpressionEnd = sourceFile.getLineAndCharacterOfPosition(fullCallOrNewExpression.end);
var startingExpressionEnd = sourceFile.getLineAndCharacterOfPosition(startingExpression.end);
if (fullCallOrNewExpressionEnd.line === startingExpressionEnd.line) {
return -1 /* Unknown */;
}
return findColumnForFirstNonWhitespaceCharacterInLine(fullCallOrNewExpressionEnd, sourceFile, options);
}
return -1 /* Unknown */;
function getStartingExpression(node) {
while (true) {
switch (node.kind) {
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 177 /* PropertyAccessExpression */:
case 178 /* ElementAccessExpression */:
node = node.expression;
break;
default:
return node;
}
}
}
}
function deriveActualIndentationFromList(list, index, sourceFile, options) {
ts.Debug.assert(index >= 0 && index < list.length);
var node = list[index];
// walk toward the start of the list starting from current node and check if the line is the same for all items.
// if end line for item [i - 1] differs from the start line for item [i] - find column of the first non-whitespace character on the line of item [i]
var lineAndCharacter = getStartLineAndCharacterForNode(node, sourceFile);
for (var i = index - 1; i >= 0; i--) {
if (list[i].kind === 25 /* CommaToken */) {
continue;
}
// skip list items that ends on the same line with the current list element
var prevEndLine = sourceFile.getLineAndCharacterOfPosition(list[i].end).line;
if (prevEndLine !== lineAndCharacter.line) {
return findColumnForFirstNonWhitespaceCharacterInLine(lineAndCharacter, sourceFile, options);
}
lineAndCharacter = getStartLineAndCharacterForNode(list[i], sourceFile);
}
return -1 /* Unknown */;
}
function findColumnForFirstNonWhitespaceCharacterInLine(lineAndCharacter, sourceFile, options) {
var lineStart = sourceFile.getPositionOfLineAndCharacter(lineAndCharacter.line, 0);
return findFirstNonWhitespaceColumn(lineStart, lineStart + lineAndCharacter.character, sourceFile, options);
}
/*
Character is the actual index of the character since the beginning of the line.
Column - position of the character after expanding tabs to spaces
"0\t2$"
value of 'character' for '$' is 3
value of 'column' for '$' is 6 (assuming that tab size is 4)
*/
function findFirstNonWhitespaceCharacterAndColumn(startPos, endPos, sourceFile, options) {
var character = 0;
var column = 0;
for (var pos = startPos; pos < endPos; pos++) {
var ch = sourceFile.text.charCodeAt(pos);
if (!ts.isWhiteSpaceSingleLine(ch)) {
break;
}
if (ch === 9 /* tab */) {
column += options.tabSize + (column % options.tabSize);
}
else {
column++;
}
character++;
}
return { column: column, character: character };
}
SmartIndenter.findFirstNonWhitespaceCharacterAndColumn = findFirstNonWhitespaceCharacterAndColumn;
function findFirstNonWhitespaceColumn(startPos, endPos, sourceFile, options) {
return findFirstNonWhitespaceCharacterAndColumn(startPos, endPos, sourceFile, options).column;
}
SmartIndenter.findFirstNonWhitespaceColumn = findFirstNonWhitespaceColumn;
function nodeContentIsAlwaysIndented(kind) {
switch (kind) {
case 207 /* ExpressionStatement */:
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
case 229 /* EnumDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 175 /* ArrayLiteralExpression */:
case 204 /* Block */:
case 231 /* ModuleBlock */:
case 176 /* ObjectLiteralExpression */:
case 161 /* TypeLiteral */:
case 163 /* TupleType */:
case 232 /* CaseBlock */:
case 254 /* DefaultClause */:
case 253 /* CaseClause */:
case 183 /* ParenthesizedExpression */:
case 177 /* PropertyAccessExpression */:
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 205 /* VariableStatement */:
case 223 /* VariableDeclaration */:
case 240 /* ExportAssignment */:
case 216 /* ReturnStatement */:
case 193 /* ConditionalExpression */:
case 173 /* ArrayBindingPattern */:
case 172 /* ObjectBindingPattern */:
case 248 /* JsxOpeningElement */:
case 247 /* JsxSelfClosingElement */:
case 252 /* JsxExpression */:
case 148 /* MethodSignature */:
case 153 /* CallSignature */:
case 154 /* ConstructSignature */:
case 144 /* Parameter */:
case 158 /* FunctionType */:
case 159 /* ConstructorType */:
case 166 /* ParenthesizedType */:
case 181 /* TaggedTemplateExpression */:
case 189 /* AwaitExpression */:
case 242 /* NamedExports */:
case 238 /* NamedImports */:
case 243 /* ExportSpecifier */:
case 239 /* ImportSpecifier */:
return true;
}
return false;
}
/* @internal */
function nodeWillIndentChild(parent, child, indentByDefault) {
var childKind = child ? child.kind : 0 /* Unknown */;
switch (parent.kind) {
case 209 /* DoStatement */:
case 210 /* WhileStatement */:
case 212 /* ForInStatement */:
case 213 /* ForOfStatement */:
case 211 /* ForStatement */:
case 208 /* IfStatement */:
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 149 /* MethodDeclaration */:
case 185 /* ArrowFunction */:
case 150 /* Constructor */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
return childKind !== 204 /* Block */;
case 241 /* ExportDeclaration */:
return childKind !== 242 /* NamedExports */;
case 235 /* ImportDeclaration */:
return childKind !== 236 /* ImportClause */ ||
(child.namedBindings && child.namedBindings.kind !== 238 /* NamedImports */);
case 246 /* JsxElement */:
return childKind !== 249 /* JsxClosingElement */;
}
// No explicit rule for given nodes so the result will follow the default value argument
return indentByDefault;
}
SmartIndenter.nodeWillIndentChild = nodeWillIndentChild;
/*
Function returns true when the parent node should indent the given child by an explicit rule
*/
function shouldIndentChildNode(parent, child) {
return nodeContentIsAlwaysIndented(parent.kind) || nodeWillIndentChild(parent, child, /*indentByDefault*/ false);
}
SmartIndenter.shouldIndentChildNode = shouldIndentChildNode;
})(SmartIndenter = formatting.SmartIndenter || (formatting.SmartIndenter = {}));
})(formatting = ts.formatting || (ts.formatting = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var codefix;
(function (codefix) {
var codeFixes = ts.createMap();
function registerCodeFix(action) {
ts.forEach(action.errorCodes, function (error) {
var fixes = codeFixes[error];
if (!fixes) {
fixes = [];
codeFixes[error] = fixes;
}
fixes.push(action);
});
}
codefix.registerCodeFix = registerCodeFix;
function getSupportedErrorCodes() {
return Object.keys(codeFixes);
}
codefix.getSupportedErrorCodes = getSupportedErrorCodes;
function getFixes(context) {
var fixes = codeFixes[context.errorCode];
var allActions = [];
ts.forEach(fixes, function (f) {
var actions = f.getCodeActions(context);
if (actions && actions.length > 0) {
allActions = allActions.concat(actions);
}
});
return allActions;
}
codefix.getFixes = getFixes;
})(codefix = ts.codefix || (ts.codefix = {}));
})(ts || (ts = {}));
/* @internal */
var ts;
(function (ts) {
var codefix;
(function (codefix) {
function getOpenBraceEnd(constructor, sourceFile) {
// First token is the open curly, this is where we want to put the 'super' call.
return constructor.body.getFirstToken(sourceFile).getEnd();
}
codefix.registerCodeFix({
errorCodes: [ts.Diagnostics.Constructors_for_derived_classes_must_contain_a_super_call.code],
getCodeActions: function (context) {
var sourceFile = context.sourceFile;
var token = ts.getTokenAtPosition(sourceFile, context.span.start);
if (token.kind !== 122 /* ConstructorKeyword */) {
return undefined;
}
var newPosition = getOpenBraceEnd(token.parent, sourceFile);
return [{
description: ts.getLocaleSpecificMessage(ts.Diagnostics.Add_missing_super_call),
changes: [{ fileName: sourceFile.fileName, textChanges: [{ newText: "super();", span: { start: newPosition, length: 0 } }] }]
}];
}
});
codefix.registerCodeFix({
errorCodes: [ts.Diagnostics.super_must_be_called_before_accessing_this_in_the_constructor_of_a_derived_class.code],
getCodeActions: function (context) {
var sourceFile = context.sourceFile;
var token = ts.getTokenAtPosition(sourceFile, context.span.start);
if (token.kind !== 98 /* ThisKeyword */) {
return undefined;
}
var constructor = ts.getContainingFunction(token);
var superCall = findSuperCall(constructor.body);
if (!superCall) {
return undefined;
}
// figure out if the this access is actuall inside the supercall
// i.e. super(this.a), since in that case we won't suggest a fix
if (superCall.expression && superCall.expression.kind == 179 /* CallExpression */) {
var arguments_1 = superCall.expression.arguments;
for (var i = 0; i < arguments_1.length; i++) {
if (arguments_1[i].expression === token) {
return undefined;
}
}
}
var newPosition = getOpenBraceEnd(constructor, sourceFile);
var changes = [{
fileName: sourceFile.fileName, textChanges: [{
newText: superCall.getText(sourceFile),
span: { start: newPosition, length: 0 }
},
{
newText: "",
span: { start: superCall.getStart(sourceFile), length: superCall.getWidth(sourceFile) }
}]
}];
return [{
description: ts.getLocaleSpecificMessage(ts.Diagnostics.Make_super_call_the_first_statement_in_the_constructor),
changes: changes
}];
function findSuperCall(n) {
if (n.kind === 207 /* ExpressionStatement */ && ts.isSuperCall(n.expression)) {
return n;
}
if (ts.isFunctionLike(n)) {
return undefined;
}
return ts.forEachChild(n, findSuperCall);
}
}
});
})(codefix = ts.codefix || (ts.codefix = {}));
})(ts || (ts = {}));
///<reference path='superFixes.ts' />
/// <reference path="..\compiler\program.ts"/>
/// <reference path="..\compiler\commandLineParser.ts"/>
/// <reference path='types.ts' />
/// <reference path='utilities.ts' />
/// <reference path='breakpoints.ts' />
/// <reference path='classifier.ts' />
/// <reference path='completions.ts' />
/// <reference path='documentHighlights.ts' />
/// <reference path='documentRegistry.ts' />
/// <reference path='findAllReferences.ts' />
/// <reference path='goToDefinition.ts' />
/// <reference path='goToImplementation.ts' />
/// <reference path='jsDoc.ts' />
/// <reference path='jsTyping.ts' />
/// <reference path='navigateTo.ts' />
/// <reference path='navigationBar.ts' />
/// <reference path='outliningElementsCollector.ts' />
/// <reference path='patternMatcher.ts' />
/// <reference path='preProcess.ts' />
/// <reference path='rename.ts' />
/// <reference path='signatureHelp.ts' />
/// <reference path='symbolDisplay.ts' />
/// <reference path='transpile.ts' />
/// <reference path='formatting\formatting.ts' />
/// <reference path='formatting\smartIndenter.ts' />
/// <reference path='codefixes\codeFixProvider.ts' />
/// <reference path='codefixes\fixes.ts' />
var ts;
(function (ts) {
/** The version of the language service API */
ts.servicesVersion = "0.5";
function createNode(kind, pos, end, parent) {
var node = kind >= 141 /* FirstNode */ ? new NodeObject(kind, pos, end) :
kind === 70 /* Identifier */ ? new IdentifierObject(70 /* Identifier */, pos, end) :
new TokenObject(kind, pos, end);
node.parent = parent;
return node;
}
var NodeObject = (function () {
function NodeObject(kind, pos, end) {
this.pos = pos;
this.end = end;
this.flags = 0 /* None */;
this.transformFlags = undefined;
this.parent = undefined;
this.kind = kind;
}
NodeObject.prototype.getSourceFile = function () {
return ts.getSourceFileOfNode(this);
};
NodeObject.prototype.getStart = function (sourceFile, includeJsDocComment) {
return ts.getTokenPosOfNode(this, sourceFile, includeJsDocComment);
};
NodeObject.prototype.getFullStart = function () {
return this.pos;
};
NodeObject.prototype.getEnd = function () {
return this.end;
};
NodeObject.prototype.getWidth = function (sourceFile) {
return this.getEnd() - this.getStart(sourceFile);
};
NodeObject.prototype.getFullWidth = function () {
return this.end - this.pos;
};
NodeObject.prototype.getLeadingTriviaWidth = function (sourceFile) {
return this.getStart(sourceFile) - this.pos;
};
NodeObject.prototype.getFullText = function (sourceFile) {
return (sourceFile || this.getSourceFile()).text.substring(this.pos, this.end);
};
NodeObject.prototype.getText = function (sourceFile) {
if (!sourceFile) {
sourceFile = this.getSourceFile();
}
return sourceFile.text.substring(this.getStart(sourceFile), this.getEnd());
};
NodeObject.prototype.addSyntheticNodes = function (nodes, pos, end, useJSDocScanner) {
ts.scanner.setTextPos(pos);
while (pos < end) {
var token = useJSDocScanner ? ts.scanner.scanJSDocToken() : ts.scanner.scan();
var textPos = ts.scanner.getTextPos();
if (textPos <= end) {
nodes.push(createNode(token, pos, textPos, this));
}
pos = textPos;
}
return pos;
};
NodeObject.prototype.createSyntaxList = function (nodes) {
var list = createNode(291 /* SyntaxList */, nodes.pos, nodes.end, this);
list._children = [];
var pos = nodes.pos;
for (var _i = 0, nodes_5 = nodes; _i < nodes_5.length; _i++) {
var node = nodes_5[_i];
if (pos < node.pos) {
pos = this.addSyntheticNodes(list._children, pos, node.pos);
}
list._children.push(node);
pos = node.end;
}
if (pos < nodes.end) {
this.addSyntheticNodes(list._children, pos, nodes.end);
}
return list;
};
NodeObject.prototype.createChildren = function (sourceFile) {
var _this = this;
var children;
if (this.kind >= 141 /* FirstNode */) {
ts.scanner.setText((sourceFile || this.getSourceFile()).text);
children = [];
var pos_3 = this.pos;
var useJSDocScanner_1 = this.kind >= 278 /* FirstJSDocTagNode */ && this.kind <= 290 /* LastJSDocTagNode */;
var processNode = function (node) {
var isJSDocTagNode = ts.isJSDocTag(node);
if (!isJSDocTagNode && pos_3 < node.pos) {
pos_3 = _this.addSyntheticNodes(children, pos_3, node.pos, useJSDocScanner_1);
}
children.push(node);
if (!isJSDocTagNode) {
pos_3 = node.end;
}
};
var processNodes = function (nodes) {
if (pos_3 < nodes.pos) {
pos_3 = _this.addSyntheticNodes(children, pos_3, nodes.pos, useJSDocScanner_1);
}
children.push(_this.createSyntaxList(nodes));
pos_3 = nodes.end;
};
// jsDocComments need to be the first children
if (this.jsDocComments) {
for (var _i = 0, _a = this.jsDocComments; _i < _a.length; _i++) {
var jsDocComment = _a[_i];
processNode(jsDocComment);
}
}
// For syntactic classifications, all trivia are classcified together, including jsdoc comments.
// For that to work, the jsdoc comments should still be the leading trivia of the first child.
// Restoring the scanner position ensures that.
pos_3 = this.pos;
ts.forEachChild(this, processNode, processNodes);
if (pos_3 < this.end) {
this.addSyntheticNodes(children, pos_3, this.end);
}
ts.scanner.setText(undefined);
}
this._children = children || ts.emptyArray;
};
NodeObject.prototype.getChildCount = function (sourceFile) {
if (!this._children)
this.createChildren(sourceFile);
return this._children.length;
};
NodeObject.prototype.getChildAt = function (index, sourceFile) {
if (!this._children)
this.createChildren(sourceFile);
return this._children[index];
};
NodeObject.prototype.getChildren = function (sourceFile) {
if (!this._children)
this.createChildren(sourceFile);
return this._children;
};
NodeObject.prototype.getFirstToken = function (sourceFile) {
var children = this.getChildren(sourceFile);
if (!children.length) {
return undefined;
}
var child = children[0];
return child.kind < 141 /* FirstNode */ ? child : child.getFirstToken(sourceFile);
};
NodeObject.prototype.getLastToken = function (sourceFile) {
var children = this.getChildren(sourceFile);
var child = ts.lastOrUndefined(children);
if (!child) {
return undefined;
}
return child.kind < 141 /* FirstNode */ ? child : child.getLastToken(sourceFile);
};
return NodeObject;
}());
var TokenOrIdentifierObject = (function () {
function TokenOrIdentifierObject(pos, end) {
// Set properties in same order as NodeObject
this.pos = pos;
this.end = end;
this.flags = 0 /* None */;
this.parent = undefined;
}
TokenOrIdentifierObject.prototype.getSourceFile = function () {
return ts.getSourceFileOfNode(this);
};
TokenOrIdentifierObject.prototype.getStart = function (sourceFile, includeJsDocComment) {
return ts.getTokenPosOfNode(this, sourceFile, includeJsDocComment);
};
TokenOrIdentifierObject.prototype.getFullStart = function () {
return this.pos;
};
TokenOrIdentifierObject.prototype.getEnd = function () {
return this.end;
};
TokenOrIdentifierObject.prototype.getWidth = function (sourceFile) {
return this.getEnd() - this.getStart(sourceFile);
};
TokenOrIdentifierObject.prototype.getFullWidth = function () {
return this.end - this.pos;
};
TokenOrIdentifierObject.prototype.getLeadingTriviaWidth = function (sourceFile) {
return this.getStart(sourceFile) - this.pos;
};
TokenOrIdentifierObject.prototype.getFullText = function (sourceFile) {
return (sourceFile || this.getSourceFile()).text.substring(this.pos, this.end);
};
TokenOrIdentifierObject.prototype.getText = function (sourceFile) {
return (sourceFile || this.getSourceFile()).text.substring(this.getStart(), this.getEnd());
};
TokenOrIdentifierObject.prototype.getChildCount = function () {
return 0;
};
TokenOrIdentifierObject.prototype.getChildAt = function () {
return undefined;
};
TokenOrIdentifierObject.prototype.getChildren = function () {
return ts.emptyArray;
};
TokenOrIdentifierObject.prototype.getFirstToken = function () {
return undefined;
};
TokenOrIdentifierObject.prototype.getLastToken = function () {
return undefined;
};
return TokenOrIdentifierObject;
}());
var SymbolObject = (function () {
function SymbolObject(flags, name) {
this.flags = flags;
this.name = name;
}
SymbolObject.prototype.getFlags = function () {
return this.flags;
};
SymbolObject.prototype.getName = function () {
return this.name;
};
SymbolObject.prototype.getDeclarations = function () {
return this.declarations;
};
SymbolObject.prototype.getDocumentationComment = function () {
if (this.documentationComment === undefined) {
this.documentationComment = ts.JsDoc.getJsDocCommentsFromDeclarations(this.declarations);
}
return this.documentationComment;
};
return SymbolObject;
}());
var TokenObject = (function (_super) {
__extends(TokenObject, _super);
function TokenObject(kind, pos, end) {
var _this = _super.call(this, pos, end) || this;
_this.kind = kind;
return _this;
}
return TokenObject;
}(TokenOrIdentifierObject));
var IdentifierObject = (function (_super) {
__extends(IdentifierObject, _super);
function IdentifierObject(_kind, pos, end) {
return _super.call(this, pos, end) || this;
}
return IdentifierObject;
}(TokenOrIdentifierObject));
IdentifierObject.prototype.kind = 70 /* Identifier */;
var TypeObject = (function () {
function TypeObject(checker, flags) {
this.checker = checker;
this.flags = flags;
}
TypeObject.prototype.getFlags = function () {
return this.flags;
};
TypeObject.prototype.getSymbol = function () {
return this.symbol;
};
TypeObject.prototype.getProperties = function () {
return this.checker.getPropertiesOfType(this);
};
TypeObject.prototype.getProperty = function (propertyName) {
return this.checker.getPropertyOfType(this, propertyName);
};
TypeObject.prototype.getApparentProperties = function () {
return this.checker.getAugmentedPropertiesOfType(this);
};
TypeObject.prototype.getCallSignatures = function () {
return this.checker.getSignaturesOfType(this, 0 /* Call */);
};
TypeObject.prototype.getConstructSignatures = function () {
return this.checker.getSignaturesOfType(this, 1 /* Construct */);
};
TypeObject.prototype.getStringIndexType = function () {
return this.checker.getIndexTypeOfType(this, 0 /* String */);
};
TypeObject.prototype.getNumberIndexType = function () {
return this.checker.getIndexTypeOfType(this, 1 /* Number */);
};
TypeObject.prototype.getBaseTypes = function () {
return this.flags & 32768 /* Object */ && this.objectFlags & (1 /* Class */ | 2 /* Interface */)
? this.checker.getBaseTypes(this)
: undefined;
};
TypeObject.prototype.getNonNullableType = function () {
return this.checker.getNonNullableType(this);
};
return TypeObject;
}());
var SignatureObject = (function () {
function SignatureObject(checker) {
this.checker = checker;
}
SignatureObject.prototype.getDeclaration = function () {
return this.declaration;
};
SignatureObject.prototype.getTypeParameters = function () {
return this.typeParameters;
};
SignatureObject.prototype.getParameters = function () {
return this.parameters;
};
SignatureObject.prototype.getReturnType = function () {
return this.checker.getReturnTypeOfSignature(this);
};
SignatureObject.prototype.getDocumentationComment = function () {
if (this.documentationComment === undefined) {
this.documentationComment = this.declaration ? ts.JsDoc.getJsDocCommentsFromDeclarations([this.declaration]) : [];
}
return this.documentationComment;
};
return SignatureObject;
}());
var SourceFileObject = (function (_super) {
__extends(SourceFileObject, _super);
function SourceFileObject(kind, pos, end) {
return _super.call(this, kind, pos, end) || this;
}
SourceFileObject.prototype.update = function (newText, textChangeRange) {
return ts.updateSourceFile(this, newText, textChangeRange);
};
SourceFileObject.prototype.getLineAndCharacterOfPosition = function (position) {
return ts.getLineAndCharacterOfPosition(this, position);
};
SourceFileObject.prototype.getLineStarts = function () {
return ts.getLineStarts(this);
};
SourceFileObject.prototype.getPositionOfLineAndCharacter = function (line, character) {
return ts.getPositionOfLineAndCharacter(this, line, character);
};
SourceFileObject.prototype.getNamedDeclarations = function () {
if (!this.namedDeclarations) {
this.namedDeclarations = this.computeNamedDeclarations();
}
return this.namedDeclarations;
};
SourceFileObject.prototype.computeNamedDeclarations = function () {
var result = ts.createMap();
ts.forEachChild(this, visit);
return result;
function addDeclaration(declaration) {
var name = getDeclarationName(declaration);
if (name) {
ts.multiMapAdd(result, name, declaration);
}
}
function getDeclarations(name) {
return result[name] || (result[name] = []);
}
function getDeclarationName(declaration) {
if (declaration.name) {
var result_6 = getTextOfIdentifierOrLiteral(declaration.name);
if (result_6 !== undefined) {
return result_6;
}
if (declaration.name.kind === 142 /* ComputedPropertyName */) {
var expr = declaration.name.expression;
if (expr.kind === 177 /* PropertyAccessExpression */) {
return expr.name.text;
}
return getTextOfIdentifierOrLiteral(expr);
}
}
return undefined;
}
function getTextOfIdentifierOrLiteral(node) {
if (node) {
if (node.kind === 70 /* Identifier */ ||
node.kind === 9 /* StringLiteral */ ||
node.kind === 8 /* NumericLiteral */) {
return node.text;
}
}
return undefined;
}
function visit(node) {
switch (node.kind) {
case 225 /* FunctionDeclaration */:
case 184 /* FunctionExpression */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
var functionDeclaration = node;
var declarationName = getDeclarationName(functionDeclaration);
if (declarationName) {
var declarations = getDeclarations(declarationName);
var lastDeclaration = ts.lastOrUndefined(declarations);
// Check whether this declaration belongs to an "overload group".
if (lastDeclaration && functionDeclaration.parent === lastDeclaration.parent && functionDeclaration.symbol === lastDeclaration.symbol) {
// Overwrite the last declaration if it was an overload
// and this one is an implementation.
if (functionDeclaration.body && !lastDeclaration.body) {
declarations[declarations.length - 1] = functionDeclaration;
}
}
else {
declarations.push(functionDeclaration);
}
ts.forEachChild(node, visit);
}
break;
case 226 /* ClassDeclaration */:
case 197 /* ClassExpression */:
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
case 229 /* EnumDeclaration */:
case 230 /* ModuleDeclaration */:
case 234 /* ImportEqualsDeclaration */:
case 243 /* ExportSpecifier */:
case 239 /* ImportSpecifier */:
case 234 /* ImportEqualsDeclaration */:
case 236 /* ImportClause */:
case 237 /* NamespaceImport */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 161 /* TypeLiteral */:
addDeclaration(node);
ts.forEachChild(node, visit);
break;
case 144 /* Parameter */:
// Only consider parameter properties
if (!ts.hasModifier(node, 92 /* ParameterPropertyModifier */)) {
break;
}
// fall through
case 223 /* VariableDeclaration */:
case 174 /* BindingElement */: {
var decl = node;
if (ts.isBindingPattern(decl.name)) {
ts.forEachChild(decl.name, visit);
break;
}
if (decl.initializer)
visit(decl.initializer);
}
case 260 /* EnumMember */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
addDeclaration(node);
break;
case 241 /* ExportDeclaration */:
// Handle named exports case e.g.:
// export {a, b as B} from "mod";
if (node.exportClause) {
ts.forEach(node.exportClause.elements, visit);
}
break;
case 235 /* ImportDeclaration */:
var importClause = node.importClause;
if (importClause) {
// Handle default import case e.g.:
// import d from "mod";
if (importClause.name) {
addDeclaration(importClause);
}
// Handle named bindings in imports e.g.:
// import * as NS from "mod";
// import {a, b as B} from "mod";
if (importClause.namedBindings) {
if (importClause.namedBindings.kind === 237 /* NamespaceImport */) {
addDeclaration(importClause.namedBindings);
}
else {
ts.forEach(importClause.namedBindings.elements, visit);
}
}
}
break;
default:
ts.forEachChild(node, visit);
}
}
};
return SourceFileObject;
}(NodeObject));
function getServicesObjectAllocator() {
return {
getNodeConstructor: function () { return NodeObject; },
getTokenConstructor: function () { return TokenObject; },
getIdentifierConstructor: function () { return IdentifierObject; },
getSourceFileConstructor: function () { return SourceFileObject; },
getSymbolConstructor: function () { return SymbolObject; },
getTypeConstructor: function () { return TypeObject; },
getSignatureConstructor: function () { return SignatureObject; },
};
}
function toEditorSettings(optionsAsMap) {
var allPropertiesAreCamelCased = true;
for (var key in optionsAsMap) {
if (ts.hasProperty(optionsAsMap, key) && !isCamelCase(key)) {
allPropertiesAreCamelCased = false;
break;
}
}
if (allPropertiesAreCamelCased) {
return optionsAsMap;
}
var settings = {};
for (var key in optionsAsMap) {
if (ts.hasProperty(optionsAsMap, key)) {
var newKey = isCamelCase(key) ? key : key.charAt(0).toLowerCase() + key.substr(1);
settings[newKey] = optionsAsMap[key];
}
}
return settings;
}
ts.toEditorSettings = toEditorSettings;
function isCamelCase(s) {
return !s.length || s.charAt(0) === s.charAt(0).toLowerCase();
}
function displayPartsToString(displayParts) {
if (displayParts) {
return ts.map(displayParts, function (displayPart) { return displayPart.text; }).join("");
}
return "";
}
ts.displayPartsToString = displayPartsToString;
function getDefaultCompilerOptions() {
// Always default to "ScriptTarget.ES5" for the language service
return {
target: 1 /* ES5 */,
jsx: 1 /* Preserve */
};
}
ts.getDefaultCompilerOptions = getDefaultCompilerOptions;
function getSupportedCodeFixes() {
return ts.codefix.getSupportedErrorCodes();
}
ts.getSupportedCodeFixes = getSupportedCodeFixes;
// Cache host information about script Should be refreshed
// at each language service public entry point, since we don't know when
// the set of scripts handled by the host changes.
var HostCache = (function () {
function HostCache(host, getCanonicalFileName) {
this.host = host;
this.getCanonicalFileName = getCanonicalFileName;
// script id => script index
this.currentDirectory = host.getCurrentDirectory();
this.fileNameToEntry = ts.createFileMap();
// Initialize the list with the root file names
var rootFileNames = host.getScriptFileNames();
for (var _i = 0, rootFileNames_1 = rootFileNames; _i < rootFileNames_1.length; _i++) {
var fileName = rootFileNames_1[_i];
this.createEntry(fileName, ts.toPath(fileName, this.currentDirectory, getCanonicalFileName));
}
// store the compilation settings
this._compilationSettings = host.getCompilationSettings() || getDefaultCompilerOptions();
}
HostCache.prototype.compilationSettings = function () {
return this._compilationSettings;
};
HostCache.prototype.createEntry = function (fileName, path) {
var entry;
var scriptSnapshot = this.host.getScriptSnapshot(fileName);
if (scriptSnapshot) {
entry = {
hostFileName: fileName,
version: this.host.getScriptVersion(fileName),
scriptSnapshot: scriptSnapshot,
scriptKind: ts.getScriptKind(fileName, this.host)
};
}
this.fileNameToEntry.set(path, entry);
return entry;
};
HostCache.prototype.getEntry = function (path) {
return this.fileNameToEntry.get(path);
};
HostCache.prototype.contains = function (path) {
return this.fileNameToEntry.contains(path);
};
HostCache.prototype.getOrCreateEntry = function (fileName) {
var path = ts.toPath(fileName, this.currentDirectory, this.getCanonicalFileName);
return this.getOrCreateEntryByPath(fileName, path);
};
HostCache.prototype.getOrCreateEntryByPath = function (fileName, path) {
return this.contains(path)
? this.getEntry(path)
: this.createEntry(fileName, path);
};
HostCache.prototype.getRootFileNames = function () {
var fileNames = [];
this.fileNameToEntry.forEachValue(function (_path, value) {
if (value) {
fileNames.push(value.hostFileName);
}
});
return fileNames;
};
HostCache.prototype.getVersion = function (path) {
var file = this.getEntry(path);
return file && file.version;
};
HostCache.prototype.getScriptSnapshot = function (path) {
var file = this.getEntry(path);
return file && file.scriptSnapshot;
};
return HostCache;
}());
var SyntaxTreeCache = (function () {
function SyntaxTreeCache(host) {
this.host = host;
}
SyntaxTreeCache.prototype.getCurrentSourceFile = function (fileName) {
var scriptSnapshot = this.host.getScriptSnapshot(fileName);
if (!scriptSnapshot) {
// The host does not know about this file.
throw new Error("Could not find file: '" + fileName + "'.");
}
var scriptKind = ts.getScriptKind(fileName, this.host);
var version = this.host.getScriptVersion(fileName);
var sourceFile;
if (this.currentFileName !== fileName) {
// This is a new file, just parse it
sourceFile = createLanguageServiceSourceFile(fileName, scriptSnapshot, 5 /* Latest */, version, /*setNodeParents*/ true, scriptKind);
}
else if (this.currentFileVersion !== version) {
// This is the same file, just a newer version. Incrementally parse the file.
var editRange = scriptSnapshot.getChangeRange(this.currentFileScriptSnapshot);
sourceFile = updateLanguageServiceSourceFile(this.currentSourceFile, scriptSnapshot, version, editRange);
}
if (sourceFile) {
// All done, ensure state is up to date
this.currentFileVersion = version;
this.currentFileName = fileName;
this.currentFileScriptSnapshot = scriptSnapshot;
this.currentSourceFile = sourceFile;
}
return this.currentSourceFile;
};
return SyntaxTreeCache;
}());
function setSourceFileFields(sourceFile, scriptSnapshot, version) {
sourceFile.version = version;
sourceFile.scriptSnapshot = scriptSnapshot;
}
function createLanguageServiceSourceFile(fileName, scriptSnapshot, scriptTarget, version, setNodeParents, scriptKind) {
var text = scriptSnapshot.getText(0, scriptSnapshot.getLength());
var sourceFile = ts.createSourceFile(fileName, text, scriptTarget, setNodeParents, scriptKind);
setSourceFileFields(sourceFile, scriptSnapshot, version);
return sourceFile;
}
ts.createLanguageServiceSourceFile = createLanguageServiceSourceFile;
ts.disableIncrementalParsing = false;
function updateLanguageServiceSourceFile(sourceFile, scriptSnapshot, version, textChangeRange, aggressiveChecks) {
// If we were given a text change range, and our version or open-ness changed, then
// incrementally parse this file.
if (textChangeRange) {
if (version !== sourceFile.version) {
// Once incremental parsing is ready, then just call into this function.
if (!ts.disableIncrementalParsing) {
var newText = void 0;
// grab the fragment from the beginning of the original text to the beginning of the span
var prefix = textChangeRange.span.start !== 0
? sourceFile.text.substr(0, textChangeRange.span.start)
: "";
// grab the fragment from the end of the span till the end of the original text
var suffix = ts.textSpanEnd(textChangeRange.span) !== sourceFile.text.length
? sourceFile.text.substr(ts.textSpanEnd(textChangeRange.span))
: "";
if (textChangeRange.newLength === 0) {
// edit was a deletion - just combine prefix and suffix
newText = prefix && suffix ? prefix + suffix : prefix || suffix;
}
else {
// it was actual edit, fetch the fragment of new text that correspond to new span
var changedText = scriptSnapshot.getText(textChangeRange.span.start, textChangeRange.span.start + textChangeRange.newLength);
// combine prefix, changed text and suffix
newText = prefix && suffix
? prefix + changedText + suffix
: prefix
? (prefix + changedText)
: (changedText + suffix);
}
var newSourceFile = ts.updateSourceFile(sourceFile, newText, textChangeRange, aggressiveChecks);
setSourceFileFields(newSourceFile, scriptSnapshot, version);
// after incremental parsing nameTable might not be up-to-date
// drop it so it can be lazily recreated later
newSourceFile.nameTable = undefined;
// dispose all resources held by old script snapshot
if (sourceFile !== newSourceFile && sourceFile.scriptSnapshot) {
if (sourceFile.scriptSnapshot.dispose) {
sourceFile.scriptSnapshot.dispose();
}
sourceFile.scriptSnapshot = undefined;
}
return newSourceFile;
}
}
}
// Otherwise, just create a new source file.
return createLanguageServiceSourceFile(sourceFile.fileName, scriptSnapshot, sourceFile.languageVersion, version, /*setNodeParents*/ true, sourceFile.scriptKind);
}
ts.updateLanguageServiceSourceFile = updateLanguageServiceSourceFile;
var CancellationTokenObject = (function () {
function CancellationTokenObject(cancellationToken) {
this.cancellationToken = cancellationToken;
}
CancellationTokenObject.prototype.isCancellationRequested = function () {
return this.cancellationToken && this.cancellationToken.isCancellationRequested();
};
CancellationTokenObject.prototype.throwIfCancellationRequested = function () {
if (this.isCancellationRequested()) {
throw new ts.OperationCanceledException();
}
};
return CancellationTokenObject;
}());
function createLanguageService(host, documentRegistry) {
if (documentRegistry === void 0) { documentRegistry = ts.createDocumentRegistry(host.useCaseSensitiveFileNames && host.useCaseSensitiveFileNames(), host.getCurrentDirectory()); }
var syntaxTreeCache = new SyntaxTreeCache(host);
var ruleProvider;
var program;
var lastProjectVersion;
var lastTypesRootVersion = 0;
var useCaseSensitivefileNames = host.useCaseSensitiveFileNames && host.useCaseSensitiveFileNames();
var cancellationToken = new CancellationTokenObject(host.getCancellationToken && host.getCancellationToken());
var currentDirectory = host.getCurrentDirectory();
// Check if the localized messages json is set, otherwise query the host for it
if (!ts.localizedDiagnosticMessages && host.getLocalizedDiagnosticMessages) {
ts.localizedDiagnosticMessages = host.getLocalizedDiagnosticMessages();
}
function log(message) {
if (host.log) {
host.log(message);
}
}
var getCanonicalFileName = ts.createGetCanonicalFileName(useCaseSensitivefileNames);
function getValidSourceFile(fileName) {
var sourceFile = program.getSourceFile(fileName);
if (!sourceFile) {
throw new Error("Could not find file: '" + fileName + "'.");
}
return sourceFile;
}
function getRuleProvider(options) {
// Ensure rules are initialized and up to date wrt to formatting options
if (!ruleProvider) {
ruleProvider = new ts.formatting.RulesProvider();
}
ruleProvider.ensureUpToDate(options);
return ruleProvider;
}
function synchronizeHostData() {
// perform fast check if host supports it
if (host.getProjectVersion) {
var hostProjectVersion = host.getProjectVersion();
if (hostProjectVersion) {
if (lastProjectVersion === hostProjectVersion) {
return;
}
lastProjectVersion = hostProjectVersion;
}
}
var typeRootsVersion = host.getTypeRootsVersion ? host.getTypeRootsVersion() : 0;
if (lastTypesRootVersion !== typeRootsVersion) {
log("TypeRoots version has changed; provide new program");
program = undefined;
lastTypesRootVersion = typeRootsVersion;
}
// Get a fresh cache of the host information
var hostCache = new HostCache(host, getCanonicalFileName);
// If the program is already up-to-date, we can reuse it
if (programUpToDate()) {
return;
}
// IMPORTANT - It is critical from this moment onward that we do not check
// cancellation tokens. We are about to mutate source files from a previous program
// instance. If we cancel midway through, we may end up in an inconsistent state where
// the program points to old source files that have been invalidated because of
// incremental parsing.
var oldSettings = program && program.getCompilerOptions();
var newSettings = hostCache.compilationSettings();
var shouldCreateNewSourceFiles = oldSettings &&
(oldSettings.target !== newSettings.target ||
oldSettings.module !== newSettings.module ||
oldSettings.moduleResolution !== newSettings.moduleResolution ||
oldSettings.noResolve !== newSettings.noResolve ||
oldSettings.jsx !== newSettings.jsx ||
oldSettings.allowJs !== newSettings.allowJs ||
oldSettings.disableSizeLimit !== oldSettings.disableSizeLimit ||
oldSettings.baseUrl !== newSettings.baseUrl ||
!ts.equalOwnProperties(oldSettings.paths, newSettings.paths));
// Now create a new compiler
var compilerHost = {
getSourceFile: getOrCreateSourceFile,
getSourceFileByPath: getOrCreateSourceFileByPath,
getCancellationToken: function () { return cancellationToken; },
getCanonicalFileName: getCanonicalFileName,
useCaseSensitiveFileNames: function () { return useCaseSensitivefileNames; },
getNewLine: function () { return ts.getNewLineOrDefaultFromHost(host); },
getDefaultLibFileName: function (options) { return host.getDefaultLibFileName(options); },
writeFile: ts.noop,
getCurrentDirectory: function () { return currentDirectory; },
fileExists: function (fileName) {
// stub missing host functionality
return hostCache.getOrCreateEntry(fileName) !== undefined;
},
readFile: function (fileName) {
// stub missing host functionality
var entry = hostCache.getOrCreateEntry(fileName);
return entry && entry.scriptSnapshot.getText(0, entry.scriptSnapshot.getLength());
},
directoryExists: function (directoryName) {
return ts.directoryProbablyExists(directoryName, host);
},
getDirectories: function (path) {
return host.getDirectories ? host.getDirectories(path) : [];
}
};
if (host.trace) {
compilerHost.trace = function (message) { return host.trace(message); };
}
if (host.resolveModuleNames) {
compilerHost.resolveModuleNames = function (moduleNames, containingFile) { return host.resolveModuleNames(moduleNames, containingFile); };
}
if (host.resolveTypeReferenceDirectives) {
compilerHost.resolveTypeReferenceDirectives = function (typeReferenceDirectiveNames, containingFile) {
return host.resolveTypeReferenceDirectives(typeReferenceDirectiveNames, containingFile);
};
}
var documentRegistryBucketKey = documentRegistry.getKeyForCompilationSettings(newSettings);
var newProgram = ts.createProgram(hostCache.getRootFileNames(), newSettings, compilerHost, program);
// Release any files we have acquired in the old program but are
// not part of the new program.
if (program) {
var oldSourceFiles = program.getSourceFiles();
var oldSettingsKey = documentRegistry.getKeyForCompilationSettings(oldSettings);
for (var _i = 0, oldSourceFiles_1 = oldSourceFiles; _i < oldSourceFiles_1.length; _i++) {
var oldSourceFile = oldSourceFiles_1[_i];
if (!newProgram.getSourceFile(oldSourceFile.fileName) || shouldCreateNewSourceFiles) {
documentRegistry.releaseDocumentWithKey(oldSourceFile.path, oldSettingsKey);
}
}
}
// hostCache is captured in the closure for 'getOrCreateSourceFile' but it should not be used past this point.
// It needs to be cleared to allow all collected snapshots to be released
hostCache = undefined;
program = newProgram;
// Make sure all the nodes in the program are both bound, and have their parent
// pointers set property.
program.getTypeChecker();
return;
function getOrCreateSourceFile(fileName) {
return getOrCreateSourceFileByPath(fileName, ts.toPath(fileName, currentDirectory, getCanonicalFileName));
}
function getOrCreateSourceFileByPath(fileName, path) {
ts.Debug.assert(hostCache !== undefined);
// The program is asking for this file, check first if the host can locate it.
// If the host can not locate the file, then it does not exist. return undefined
// to the program to allow reporting of errors for missing files.
var hostFileInformation = hostCache.getOrCreateEntryByPath(fileName, path);
if (!hostFileInformation) {
return undefined;
}
// Check if the language version has changed since we last created a program; if they are the same,
// it is safe to reuse the sourceFiles; if not, then the shape of the AST can change, and the oldSourceFile
// can not be reused. we have to dump all syntax trees and create new ones.
if (!shouldCreateNewSourceFiles) {
// Check if the old program had this file already
var oldSourceFile = program && program.getSourceFileByPath(path);
if (oldSourceFile) {
// We already had a source file for this file name. Go to the registry to
// ensure that we get the right up to date version of it. We need this to
// address the following race-condition. Specifically, say we have the following:
//
// LS1
// \
// DocumentRegistry
// /
// LS2
//
// Each LS has a reference to file 'foo.ts' at version 1. LS2 then updates
// it's version of 'foo.ts' to version 2. This will cause LS2 and the
// DocumentRegistry to have version 2 of the document. HOwever, LS1 will
// have version 1. And *importantly* this source file will be *corrupt*.
// The act of creating version 2 of the file irrevocably damages the version
// 1 file.
//
// So, later when we call into LS1, we need to make sure that it doesn't use
// it's source file any more, and instead defers to DocumentRegistry to get
// either version 1, version 2 (or some other version) depending on what the
// host says should be used.
// We do not support the scenario where a host can modify a registered
// file's script kind, i.e. in one project some file is treated as ".ts"
// and in another as ".js"
ts.Debug.assert(hostFileInformation.scriptKind === oldSourceFile.scriptKind, "Registered script kind (" + oldSourceFile.scriptKind + ") should match new script kind (" + hostFileInformation.scriptKind + ") for file: " + path);
return documentRegistry.updateDocumentWithKey(fileName, path, newSettings, documentRegistryBucketKey, hostFileInformation.scriptSnapshot, hostFileInformation.version, hostFileInformation.scriptKind);
}
}
// Could not find this file in the old program, create a new SourceFile for it.
return documentRegistry.acquireDocumentWithKey(fileName, path, newSettings, documentRegistryBucketKey, hostFileInformation.scriptSnapshot, hostFileInformation.version, hostFileInformation.scriptKind);
}
function sourceFileUpToDate(sourceFile) {
if (!sourceFile) {
return false;
}
var path = sourceFile.path || ts.toPath(sourceFile.fileName, currentDirectory, getCanonicalFileName);
return sourceFile.version === hostCache.getVersion(path);
}
function programUpToDate() {
// If we haven't create a program yet, then it is not up-to-date
if (!program) {
return false;
}
// If number of files in the program do not match, it is not up-to-date
var rootFileNames = hostCache.getRootFileNames();
if (program.getSourceFiles().length !== rootFileNames.length) {
return false;
}
// If any file is not up-to-date, then the whole program is not up-to-date
for (var _i = 0, rootFileNames_2 = rootFileNames; _i < rootFileNames_2.length; _i++) {
var fileName = rootFileNames_2[_i];
if (!sourceFileUpToDate(program.getSourceFile(fileName))) {
return false;
}
}
// If the compilation settings do no match, then the program is not up-to-date
return ts.compareDataObjects(program.getCompilerOptions(), hostCache.compilationSettings());
}
}
function getProgram() {
synchronizeHostData();
return program;
}
function cleanupSemanticCache() {
// TODO: Should we jettison the program (or it's type checker) here?
}
function dispose() {
if (program) {
ts.forEach(program.getSourceFiles(), function (f) {
return documentRegistry.releaseDocument(f.fileName, program.getCompilerOptions());
});
}
}
/// Diagnostics
function getSyntacticDiagnostics(fileName) {
synchronizeHostData();
return program.getSyntacticDiagnostics(getValidSourceFile(fileName), cancellationToken);
}
/**
* getSemanticDiagnostics return array of Diagnostics. If '-d' is not enabled, only report semantic errors
* If '-d' enabled, report both semantic and emitter errors
*/
function getSemanticDiagnostics(fileName) {
synchronizeHostData();
var targetSourceFile = getValidSourceFile(fileName);
// Only perform the action per file regardless of '-out' flag as LanguageServiceHost is expected to call this function per file.
// Therefore only get diagnostics for given file.
var semanticDiagnostics = program.getSemanticDiagnostics(targetSourceFile, cancellationToken);
if (!program.getCompilerOptions().declaration) {
return semanticDiagnostics;
}
// If '-d' is enabled, check for emitter error. One example of emitter error is export class implements non-export interface
var declarationDiagnostics = program.getDeclarationDiagnostics(targetSourceFile, cancellationToken);
return ts.concatenate(semanticDiagnostics, declarationDiagnostics);
}
function getCompilerOptionsDiagnostics() {
synchronizeHostData();
return program.getOptionsDiagnostics(cancellationToken).concat(program.getGlobalDiagnostics(cancellationToken));
}
function getCompletionsAtPosition(fileName, position) {
synchronizeHostData();
return ts.Completions.getCompletionsAtPosition(host, program.getTypeChecker(), log, program.getCompilerOptions(), getValidSourceFile(fileName), position);
}
function getCompletionEntryDetails(fileName, position, entryName) {
synchronizeHostData();
return ts.Completions.getCompletionEntryDetails(program.getTypeChecker(), log, program.getCompilerOptions(), getValidSourceFile(fileName), position, entryName);
}
function getCompletionEntrySymbol(fileName, position, entryName) {
synchronizeHostData();
return ts.Completions.getCompletionEntrySymbol(program.getTypeChecker(), log, program.getCompilerOptions(), getValidSourceFile(fileName), position, entryName);
}
function getQuickInfoAtPosition(fileName, position) {
synchronizeHostData();
var sourceFile = getValidSourceFile(fileName);
var node = ts.getTouchingPropertyName(sourceFile, position);
if (node === sourceFile) {
return undefined;
}
if (ts.isLabelName(node)) {
return undefined;
}
var typeChecker = program.getTypeChecker();
var symbol = typeChecker.getSymbolAtLocation(node);
if (!symbol || typeChecker.isUnknownSymbol(symbol)) {
// Try getting just type at this position and show
switch (node.kind) {
case 70 /* Identifier */:
case 177 /* PropertyAccessExpression */:
case 141 /* QualifiedName */:
case 98 /* ThisKeyword */:
case 167 /* ThisType */:
case 96 /* SuperKeyword */:
// For the identifiers/this/super etc get the type at position
var type = typeChecker.getTypeAtLocation(node);
if (type) {
return {
kind: ts.ScriptElementKind.unknown,
kindModifiers: ts.ScriptElementKindModifier.none,
textSpan: ts.createTextSpan(node.getStart(), node.getWidth()),
displayParts: ts.typeToDisplayParts(typeChecker, type, ts.getContainerNode(node)),
documentation: type.symbol ? type.symbol.getDocumentationComment() : undefined
};
}
}
return undefined;
}
var displayPartsDocumentationsAndKind = ts.SymbolDisplay.getSymbolDisplayPartsDocumentationAndSymbolKind(typeChecker, symbol, sourceFile, ts.getContainerNode(node), node);
return {
kind: displayPartsDocumentationsAndKind.symbolKind,
kindModifiers: ts.SymbolDisplay.getSymbolModifiers(symbol),
textSpan: ts.createTextSpan(node.getStart(), node.getWidth()),
displayParts: displayPartsDocumentationsAndKind.displayParts,
documentation: displayPartsDocumentationsAndKind.documentation
};
}
/// Goto definition
function getDefinitionAtPosition(fileName, position) {
synchronizeHostData();
return ts.GoToDefinition.getDefinitionAtPosition(program, getValidSourceFile(fileName), position);
}
/// Goto implementation
function getImplementationAtPosition(fileName, position) {
synchronizeHostData();
return ts.GoToImplementation.getImplementationAtPosition(program.getTypeChecker(), cancellationToken, program.getSourceFiles(), ts.getTouchingPropertyName(getValidSourceFile(fileName), position));
}
function getTypeDefinitionAtPosition(fileName, position) {
synchronizeHostData();
return ts.GoToDefinition.getTypeDefinitionAtPosition(program.getTypeChecker(), getValidSourceFile(fileName), position);
}
function getOccurrencesAtPosition(fileName, position) {
var results = getOccurrencesAtPositionCore(fileName, position);
if (results) {
var sourceFile_2 = getCanonicalFileName(ts.normalizeSlashes(fileName));
// Get occurrences only supports reporting occurrences for the file queried. So
// filter down to that list.
results = ts.filter(results, function (r) { return getCanonicalFileName(ts.normalizeSlashes(r.fileName)) === sourceFile_2; });
}
return results;
}
function getDocumentHighlights(fileName, position, filesToSearch) {
synchronizeHostData();
var sourceFilesToSearch = ts.map(filesToSearch, function (f) { return program.getSourceFile(f); });
var sourceFile = getValidSourceFile(fileName);
return ts.DocumentHighlights.getDocumentHighlights(program.getTypeChecker(), cancellationToken, sourceFile, position, sourceFilesToSearch);
}
/// References and Occurrences
function getOccurrencesAtPositionCore(fileName, position) {
synchronizeHostData();
return convertDocumentHighlights(getDocumentHighlights(fileName, position, [fileName]));
function convertDocumentHighlights(documentHighlights) {
if (!documentHighlights) {
return undefined;
}
var result = [];
for (var _i = 0, documentHighlights_1 = documentHighlights; _i < documentHighlights_1.length; _i++) {
var entry = documentHighlights_1[_i];
for (var _a = 0, _b = entry.highlightSpans; _a < _b.length; _a++) {
var highlightSpan = _b[_a];
result.push({
fileName: entry.fileName,
textSpan: highlightSpan.textSpan,
isWriteAccess: highlightSpan.kind === ts.HighlightSpanKind.writtenReference,
isDefinition: false
});
}
}
return result;
}
}
function findRenameLocations(fileName, position, findInStrings, findInComments) {
var referencedSymbols = findReferencedSymbols(fileName, position, findInStrings, findInComments);
return ts.FindAllReferences.convertReferences(referencedSymbols);
}
function getReferencesAtPosition(fileName, position) {
var referencedSymbols = findReferencedSymbols(fileName, position, /*findInStrings*/ false, /*findInComments*/ false);
return ts.FindAllReferences.convertReferences(referencedSymbols);
}
function findReferences(fileName, position) {
var referencedSymbols = findReferencedSymbols(fileName, position, /*findInStrings*/ false, /*findInComments*/ false);
// Only include referenced symbols that have a valid definition.
return ts.filter(referencedSymbols, function (rs) { return !!rs.definition; });
}
function findReferencedSymbols(fileName, position, findInStrings, findInComments) {
synchronizeHostData();
return ts.FindAllReferences.findReferencedSymbols(program.getTypeChecker(), cancellationToken, program.getSourceFiles(), getValidSourceFile(fileName), position, findInStrings, findInComments);
}
/// NavigateTo
function getNavigateToItems(searchValue, maxResultCount, fileName, excludeDtsFiles) {
synchronizeHostData();
var sourceFiles = fileName ? [getValidSourceFile(fileName)] : program.getSourceFiles();
return ts.NavigateTo.getNavigateToItems(sourceFiles, program.getTypeChecker(), cancellationToken, searchValue, maxResultCount, excludeDtsFiles);
}
function getEmitOutput(fileName, emitOnlyDtsFiles) {
synchronizeHostData();
var sourceFile = getValidSourceFile(fileName);
var outputFiles = [];
function writeFile(fileName, data, writeByteOrderMark) {
outputFiles.push({
name: fileName,
writeByteOrderMark: writeByteOrderMark,
text: data
});
}
var emitOutput = program.emit(sourceFile, writeFile, cancellationToken, emitOnlyDtsFiles);
return {
outputFiles: outputFiles,
emitSkipped: emitOutput.emitSkipped
};
}
// Signature help
/**
* This is a semantic operation.
*/
function getSignatureHelpItems(fileName, position) {
synchronizeHostData();
var sourceFile = getValidSourceFile(fileName);
return ts.SignatureHelp.getSignatureHelpItems(program, sourceFile, position, cancellationToken);
}
/// Syntactic features
function getNonBoundSourceFile(fileName) {
return syntaxTreeCache.getCurrentSourceFile(fileName);
}
function getSourceFile(fileName) {
return getNonBoundSourceFile(fileName);
}
function getNameOrDottedNameSpan(fileName, startPos, _endPos) {
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
// Get node at the location
var node = ts.getTouchingPropertyName(sourceFile, startPos);
if (node === sourceFile) {
return;
}
switch (node.kind) {
case 177 /* PropertyAccessExpression */:
case 141 /* QualifiedName */:
case 9 /* StringLiteral */:
case 85 /* FalseKeyword */:
case 100 /* TrueKeyword */:
case 94 /* NullKeyword */:
case 96 /* SuperKeyword */:
case 98 /* ThisKeyword */:
case 167 /* ThisType */:
case 70 /* Identifier */:
break;
// Cant create the text span
default:
return;
}
var nodeForStartPos = node;
while (true) {
if (ts.isRightSideOfPropertyAccess(nodeForStartPos) || ts.isRightSideOfQualifiedName(nodeForStartPos)) {
// If on the span is in right side of the the property or qualified name, return the span from the qualified name pos to end of this node
nodeForStartPos = nodeForStartPos.parent;
}
else if (ts.isNameOfModuleDeclaration(nodeForStartPos)) {
// If this is name of a module declarations, check if this is right side of dotted module name
// If parent of the module declaration which is parent of this node is module declaration and its body is the module declaration that this node is name of
// Then this name is name from dotted module
if (nodeForStartPos.parent.parent.kind === 230 /* ModuleDeclaration */ &&
nodeForStartPos.parent.parent.body === nodeForStartPos.parent) {
// Use parent module declarations name for start pos
nodeForStartPos = nodeForStartPos.parent.parent.name;
}
else {
// We have to use this name for start pos
break;
}
}
else {
// Is not a member expression so we have found the node for start pos
break;
}
}
return ts.createTextSpanFromBounds(nodeForStartPos.getStart(), node.getEnd());
}
function getBreakpointStatementAtPosition(fileName, position) {
// doesn't use compiler - no need to synchronize with host
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
return ts.BreakpointResolver.spanInSourceFileAtLocation(sourceFile, position);
}
function getNavigationBarItems(fileName) {
return ts.NavigationBar.getNavigationBarItems(syntaxTreeCache.getCurrentSourceFile(fileName));
}
function getNavigationTree(fileName) {
return ts.NavigationBar.getNavigationTree(syntaxTreeCache.getCurrentSourceFile(fileName));
}
function isTsOrTsxFile(fileName) {
var kind = ts.getScriptKind(fileName, host);
return kind === 3 /* TS */ || kind === 4 /* TSX */;
}
function getSemanticClassifications(fileName, span) {
if (!isTsOrTsxFile(fileName)) {
// do not run semantic classification on non-ts-or-tsx files
return [];
}
synchronizeHostData();
return ts.getSemanticClassifications(program.getTypeChecker(), cancellationToken, getValidSourceFile(fileName), program.getClassifiableNames(), span);
}
function getEncodedSemanticClassifications(fileName, span) {
if (!isTsOrTsxFile(fileName)) {
// do not run semantic classification on non-ts-or-tsx files
return { spans: [], endOfLineState: 0 /* None */ };
}
synchronizeHostData();
return ts.getEncodedSemanticClassifications(program.getTypeChecker(), cancellationToken, getValidSourceFile(fileName), program.getClassifiableNames(), span);
}
function getSyntacticClassifications(fileName, span) {
// doesn't use compiler - no need to synchronize with host
return ts.getSyntacticClassifications(cancellationToken, syntaxTreeCache.getCurrentSourceFile(fileName), span);
}
function getEncodedSyntacticClassifications(fileName, span) {
// doesn't use compiler - no need to synchronize with host
return ts.getEncodedSyntacticClassifications(cancellationToken, syntaxTreeCache.getCurrentSourceFile(fileName), span);
}
function getOutliningSpans(fileName) {
// doesn't use compiler - no need to synchronize with host
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
return ts.OutliningElementsCollector.collectElements(sourceFile);
}
function getBraceMatchingAtPosition(fileName, position) {
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
var result = [];
var token = ts.getTouchingToken(sourceFile, position);
if (token.getStart(sourceFile) === position) {
var matchKind = getMatchingTokenKind(token);
// Ensure that there is a corresponding token to match ours.
if (matchKind) {
var parentElement = token.parent;
var childNodes = parentElement.getChildren(sourceFile);
for (var _i = 0, childNodes_1 = childNodes; _i < childNodes_1.length; _i++) {
var current = childNodes_1[_i];
if (current.kind === matchKind) {
var range1 = ts.createTextSpan(token.getStart(sourceFile), token.getWidth(sourceFile));
var range2 = ts.createTextSpan(current.getStart(sourceFile), current.getWidth(sourceFile));
// We want to order the braces when we return the result.
if (range1.start < range2.start) {
result.push(range1, range2);
}
else {
result.push(range2, range1);
}
break;
}
}
}
}
return result;
function getMatchingTokenKind(token) {
switch (token.kind) {
case 16 /* OpenBraceToken */: return 17 /* CloseBraceToken */;
case 18 /* OpenParenToken */: return 19 /* CloseParenToken */;
case 20 /* OpenBracketToken */: return 21 /* CloseBracketToken */;
case 26 /* LessThanToken */: return 28 /* GreaterThanToken */;
case 17 /* CloseBraceToken */: return 16 /* OpenBraceToken */;
case 19 /* CloseParenToken */: return 18 /* OpenParenToken */;
case 21 /* CloseBracketToken */: return 20 /* OpenBracketToken */;
case 28 /* GreaterThanToken */: return 26 /* LessThanToken */;
}
return undefined;
}
}
function getIndentationAtPosition(fileName, position, editorOptions) {
var start = ts.timestamp();
var settings = toEditorSettings(editorOptions);
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
log("getIndentationAtPosition: getCurrentSourceFile: " + (ts.timestamp() - start));
start = ts.timestamp();
var result = ts.formatting.SmartIndenter.getIndentation(position, sourceFile, settings);
log("getIndentationAtPosition: computeIndentation : " + (ts.timestamp() - start));
return result;
}
function getFormattingEditsForRange(fileName, start, end, options) {
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
var settings = toEditorSettings(options);
return ts.formatting.formatSelection(start, end, sourceFile, getRuleProvider(settings), settings);
}
function getFormattingEditsForDocument(fileName, options) {
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
var settings = toEditorSettings(options);
return ts.formatting.formatDocument(sourceFile, getRuleProvider(settings), settings);
}
function getFormattingEditsAfterKeystroke(fileName, position, key, options) {
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
var settings = toEditorSettings(options);
if (key === "}") {
return ts.formatting.formatOnClosingCurly(position, sourceFile, getRuleProvider(settings), settings);
}
else if (key === ";") {
return ts.formatting.formatOnSemicolon(position, sourceFile, getRuleProvider(settings), settings);
}
else if (key === "\n") {
return ts.formatting.formatOnEnter(position, sourceFile, getRuleProvider(settings), settings);
}
return [];
}
function getCodeFixesAtPosition(fileName, start, end, errorCodes) {
synchronizeHostData();
var sourceFile = getValidSourceFile(fileName);
var span = { start: start, length: end - start };
var newLineChar = ts.getNewLineOrDefaultFromHost(host);
var allFixes = [];
ts.forEach(errorCodes, function (error) {
cancellationToken.throwIfCancellationRequested();
var context = {
errorCode: error,
sourceFile: sourceFile,
span: span,
program: program,
newLineCharacter: newLineChar
};
var fixes = ts.codefix.getFixes(context);
if (fixes) {
allFixes = allFixes.concat(fixes);
}
});
return allFixes;
}
function getDocCommentTemplateAtPosition(fileName, position) {
return ts.JsDoc.getDocCommentTemplateAtPosition(ts.getNewLineOrDefaultFromHost(host), syntaxTreeCache.getCurrentSourceFile(fileName), position);
}
function isValidBraceCompletionAtPosition(fileName, position, openingBrace) {
// '<' is currently not supported, figuring out if we're in a Generic Type vs. a comparison is too
// expensive to do during typing scenarios
// i.e. whether we're dealing with:
// var x = new foo<| ( with class foo<T>{} )
// or
// var y = 3 <|
if (openingBrace === 60 /* lessThan */) {
return false;
}
var sourceFile = syntaxTreeCache.getCurrentSourceFile(fileName);
// Check if in a context where we don't want to perform any insertion
if (ts.isInString(sourceFile, position) || ts.isInComment(sourceFile, position)) {
return false;
}
if (ts.isInsideJsxElementOrAttribute(sourceFile, position)) {
return openingBrace === 123 /* openBrace */;
}
if (ts.isInTemplateString(sourceFile, position)) {
return false;
}
return true;
}
function getTodoComments(fileName, descriptors) {
// Note: while getting todo comments seems like a syntactic operation, we actually
// treat it as a semantic operation here. This is because we expect our host to call
// this on every single file. If we treat this syntactically, then that will cause
// us to populate and throw away the tree in our syntax tree cache for each file. By
// treating this as a semantic operation, we can access any tree without throwing
// anything away.
synchronizeHostData();
var sourceFile = getValidSourceFile(fileName);
cancellationToken.throwIfCancellationRequested();
var fileContents = sourceFile.text;
var result = [];
if (descriptors.length > 0) {
var regExp = getTodoCommentsRegExp();
var matchArray = void 0;
while (matchArray = regExp.exec(fileContents)) {
cancellationToken.throwIfCancellationRequested();
// If we got a match, here is what the match array will look like. Say the source text is:
//
// " // hack 1"
//
// The result array with the regexp: will be:
//
// ["// hack 1", "// ", "hack 1", undefined, "hack"]
//
// Here are the relevant capture groups:
// 0) The full match for the entire regexp.
// 1) The preamble to the message portion.
// 2) The message portion.
// 3...N) The descriptor that was matched - by index. 'undefined' for each
// descriptor that didn't match. an actual value if it did match.
//
// i.e. 'undefined' in position 3 above means TODO(jason) didn't match.
// "hack" in position 4 means HACK did match.
var firstDescriptorCaptureIndex = 3;
ts.Debug.assert(matchArray.length === descriptors.length + firstDescriptorCaptureIndex);
var preamble = matchArray[1];
var matchPosition = matchArray.index + preamble.length;
// OK, we have found a match in the file. This is only an acceptable match if
// it is contained within a comment.
var token = ts.getTokenAtPosition(sourceFile, matchPosition);
if (!ts.isInsideComment(sourceFile, token, matchPosition)) {
continue;
}
var descriptor = undefined;
for (var i = 0, n = descriptors.length; i < n; i++) {
if (matchArray[i + firstDescriptorCaptureIndex]) {
descriptor = descriptors[i];
}
}
ts.Debug.assert(descriptor !== undefined);
// We don't want to match something like 'TODOBY', so we make sure a non
// letter/digit follows the match.
if (isLetterOrDigit(fileContents.charCodeAt(matchPosition + descriptor.text.length))) {
continue;
}
var message = matchArray[2];
result.push({
descriptor: descriptor,
message: message,
position: matchPosition
});
}
}
return result;
function escapeRegExp(str) {
return str.replace(/[\-\[\]\/\{\}\(\)\*\+\?\.\\\^\$\|]/g, "\\$&");
}
function getTodoCommentsRegExp() {
// NOTE: ?: means 'non-capture group'. It allows us to have groups without having to
// filter them out later in the final result array.
// TODO comments can appear in one of the following forms:
//
// 1) // TODO or /////////// TODO
//
// 2) /* TODO or /********** TODO
//
// 3) /*
// * TODO
// */
//
// The following three regexps are used to match the start of the text up to the TODO
// comment portion.
var singleLineCommentStart = /(?:\/\/+\s*)/.source;
var multiLineCommentStart = /(?:\/\*+\s*)/.source;
var anyNumberOfSpacesAndAsterisksAtStartOfLine = /(?:^(?:\s|\*)*)/.source;
// Match any of the above three TODO comment start regexps.
// Note that the outermost group *is* a capture group. We want to capture the preamble
// so that we can determine the starting position of the TODO comment match.
var preamble = "(" + anyNumberOfSpacesAndAsterisksAtStartOfLine + "|" + singleLineCommentStart + "|" + multiLineCommentStart + ")";
// Takes the descriptors and forms a regexp that matches them as if they were literals.
// For example, if the descriptors are "TODO(jason)" and "HACK", then this will be:
//
// (?:(TODO\(jason\))|(HACK))
//
// Note that the outermost group is *not* a capture group, but the innermost groups
// *are* capture groups. By capturing the inner literals we can determine after
// matching which descriptor we are dealing with.
var literals = "(?:" + ts.map(descriptors, function (d) { return "(" + escapeRegExp(d.text) + ")"; }).join("|") + ")";
// After matching a descriptor literal, the following regexp matches the rest of the
// text up to the end of the line (or */).
var endOfLineOrEndOfComment = /(?:$|\*\/)/.source;
var messageRemainder = /(?:.*?)/.source;
// This is the portion of the match we'll return as part of the TODO comment result. We
// match the literal portion up to the end of the line or end of comment.
var messagePortion = "(" + literals + messageRemainder + ")";
var regExpString = preamble + messagePortion + endOfLineOrEndOfComment;
// The final regexp will look like this:
// /((?:\/\/+\s*)|(?:\/\*+\s*)|(?:^(?:\s|\*)*))((?:(TODO\(jason\))|(HACK))(?:.*?))(?:$|\*\/)/gim
// The flags of the regexp are important here.
// 'g' is so that we are doing a global search and can find matches several times
// in the input.
//
// 'i' is for case insensitivity (We do this to match C# TODO comment code).
//
// 'm' is so we can find matches in a multi-line input.
return new RegExp(regExpString, "gim");
}
function isLetterOrDigit(char) {
return (char >= 97 /* a */ && char <= 122 /* z */) ||
(char >= 65 /* A */ && char <= 90 /* Z */) ||
(char >= 48 /* _0 */ && char <= 57 /* _9 */);
}
}
function getRenameInfo(fileName, position) {
synchronizeHostData();
var defaultLibFileName = host.getDefaultLibFileName(host.getCompilationSettings());
return ts.Rename.getRenameInfo(program.getTypeChecker(), defaultLibFileName, getCanonicalFileName, getValidSourceFile(fileName), position);
}
return {
dispose: dispose,
cleanupSemanticCache: cleanupSemanticCache,
getSyntacticDiagnostics: getSyntacticDiagnostics,
getSemanticDiagnostics: getSemanticDiagnostics,
getCompilerOptionsDiagnostics: getCompilerOptionsDiagnostics,
getSyntacticClassifications: getSyntacticClassifications,
getSemanticClassifications: getSemanticClassifications,
getEncodedSyntacticClassifications: getEncodedSyntacticClassifications,
getEncodedSemanticClassifications: getEncodedSemanticClassifications,
getCompletionsAtPosition: getCompletionsAtPosition,
getCompletionEntryDetails: getCompletionEntryDetails,
getCompletionEntrySymbol: getCompletionEntrySymbol,
getSignatureHelpItems: getSignatureHelpItems,
getQuickInfoAtPosition: getQuickInfoAtPosition,
getDefinitionAtPosition: getDefinitionAtPosition,
getImplementationAtPosition: getImplementationAtPosition,
getTypeDefinitionAtPosition: getTypeDefinitionAtPosition,
getReferencesAtPosition: getReferencesAtPosition,
findReferences: findReferences,
getOccurrencesAtPosition: getOccurrencesAtPosition,
getDocumentHighlights: getDocumentHighlights,
getNameOrDottedNameSpan: getNameOrDottedNameSpan,
getBreakpointStatementAtPosition: getBreakpointStatementAtPosition,
getNavigateToItems: getNavigateToItems,
getRenameInfo: getRenameInfo,
findRenameLocations: findRenameLocations,
getNavigationBarItems: getNavigationBarItems,
getNavigationTree: getNavigationTree,
getOutliningSpans: getOutliningSpans,
getTodoComments: getTodoComments,
getBraceMatchingAtPosition: getBraceMatchingAtPosition,
getIndentationAtPosition: getIndentationAtPosition,
getFormattingEditsForRange: getFormattingEditsForRange,
getFormattingEditsForDocument: getFormattingEditsForDocument,
getFormattingEditsAfterKeystroke: getFormattingEditsAfterKeystroke,
getDocCommentTemplateAtPosition: getDocCommentTemplateAtPosition,
isValidBraceCompletionAtPosition: isValidBraceCompletionAtPosition,
getCodeFixesAtPosition: getCodeFixesAtPosition,
getEmitOutput: getEmitOutput,
getNonBoundSourceFile: getNonBoundSourceFile,
getSourceFile: getSourceFile,
getProgram: getProgram
};
}
ts.createLanguageService = createLanguageService;
/* @internal */
function getNameTable(sourceFile) {
if (!sourceFile.nameTable) {
initializeNameTable(sourceFile);
}
return sourceFile.nameTable;
}
ts.getNameTable = getNameTable;
function initializeNameTable(sourceFile) {
var nameTable = ts.createMap();
walk(sourceFile);
sourceFile.nameTable = nameTable;
function walk(node) {
switch (node.kind) {
case 70 /* Identifier */:
nameTable[node.text] = nameTable[node.text] === undefined ? node.pos : -1;
break;
case 9 /* StringLiteral */:
case 8 /* NumericLiteral */:
// We want to store any numbers/strings if they were a name that could be
// related to a declaration. So, if we have 'import x = require("something")'
// then we want 'something' to be in the name table. Similarly, if we have
// "a['propname']" then we want to store "propname" in the name table.
if (ts.isDeclarationName(node) ||
node.parent.kind === 245 /* ExternalModuleReference */ ||
isArgumentOfElementAccessExpression(node) ||
ts.isLiteralComputedPropertyDeclarationName(node)) {
nameTable[node.text] = nameTable[node.text] === undefined ? node.pos : -1;
}
break;
default:
ts.forEachChild(node, walk);
if (node.jsDocComments) {
for (var _i = 0, _a = node.jsDocComments; _i < _a.length; _i++) {
var jsDocComment = _a[_i];
ts.forEachChild(jsDocComment, walk);
}
}
}
}
}
function isArgumentOfElementAccessExpression(node) {
return node &&
node.parent &&
node.parent.kind === 178 /* ElementAccessExpression */ &&
node.parent.argumentExpression === node;
}
/**
* Get the path of the default library files (lib.d.ts) as distributed with the typescript
* node package.
* The functionality is not supported if the ts module is consumed outside of a node module.
*/
function getDefaultLibFilePath(options) {
// Check __dirname is defined and that we are on a node.js system.
if (typeof __dirname !== "undefined") {
return __dirname + ts.directorySeparator + ts.getDefaultLibFileName(options);
}
throw new Error("getDefaultLibFilePath is only supported when consumed as a node module. ");
}
ts.getDefaultLibFilePath = getDefaultLibFilePath;
function initializeServices() {
ts.objectAllocator = getServicesObjectAllocator();
}
initializeServices();
})(ts || (ts = {}));
// Copyright (c) Microsoft. All rights reserved. Licensed under the Apache License, Version 2.0.
// See LICENSE.txt in the project root for complete license information.
/// <reference path='services.ts' />
/* @internal */
var ts;
(function (ts) {
var BreakpointResolver;
(function (BreakpointResolver) {
/**
* Get the breakpoint span in given sourceFile
*/
function spanInSourceFileAtLocation(sourceFile, position) {
// Cannot set breakpoint in dts file
if (sourceFile.isDeclarationFile) {
return undefined;
}
var tokenAtLocation = ts.getTokenAtPosition(sourceFile, position);
var lineOfPosition = sourceFile.getLineAndCharacterOfPosition(position).line;
if (sourceFile.getLineAndCharacterOfPosition(tokenAtLocation.getStart(sourceFile)).line > lineOfPosition) {
// Get previous token if the token is returned starts on new line
// eg: let x =10; |--- cursor is here
// let y = 10;
// token at position will return let keyword on second line as the token but we would like to use
// token on same line if trailing trivia (comments or white spaces on same line) part of the last token on that line
tokenAtLocation = ts.findPrecedingToken(tokenAtLocation.pos, sourceFile);
// It's a blank line
if (!tokenAtLocation || sourceFile.getLineAndCharacterOfPosition(tokenAtLocation.getEnd()).line !== lineOfPosition) {
return undefined;
}
}
// Cannot set breakpoint in ambient declarations
if (ts.isInAmbientContext(tokenAtLocation)) {
return undefined;
}
// Get the span in the node based on its syntax
return spanInNode(tokenAtLocation);
function textSpan(startNode, endNode) {
var start = startNode.decorators ?
ts.skipTrivia(sourceFile.text, startNode.decorators.end) :
startNode.getStart(sourceFile);
return ts.createTextSpanFromBounds(start, (endNode || startNode).getEnd());
}
function textSpanEndingAtNextToken(startNode, previousTokenToFindNextEndToken) {
return textSpan(startNode, ts.findNextToken(previousTokenToFindNextEndToken, previousTokenToFindNextEndToken.parent));
}
function spanInNodeIfStartsOnSameLine(node, otherwiseOnNode) {
if (node && lineOfPosition === sourceFile.getLineAndCharacterOfPosition(node.getStart(sourceFile)).line) {
return spanInNode(node);
}
return spanInNode(otherwiseOnNode);
}
function spanInNodeArray(nodeArray) {
return ts.createTextSpanFromBounds(ts.skipTrivia(sourceFile.text, nodeArray.pos), nodeArray.end);
}
function spanInPreviousNode(node) {
return spanInNode(ts.findPrecedingToken(node.pos, sourceFile));
}
function spanInNextNode(node) {
return spanInNode(ts.findNextToken(node, node.parent));
}
function spanInNode(node) {
if (node) {
switch (node.kind) {
case 205 /* VariableStatement */:
// Span on first variable declaration
return spanInVariableDeclaration(node.declarationList.declarations[0]);
case 223 /* VariableDeclaration */:
case 147 /* PropertyDeclaration */:
case 146 /* PropertySignature */:
return spanInVariableDeclaration(node);
case 144 /* Parameter */:
return spanInParameterDeclaration(node);
case 225 /* FunctionDeclaration */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 150 /* Constructor */:
case 184 /* FunctionExpression */:
case 185 /* ArrowFunction */:
return spanInFunctionDeclaration(node);
case 204 /* Block */:
if (ts.isFunctionBlock(node)) {
return spanInFunctionBlock(node);
}
// Fall through
case 231 /* ModuleBlock */:
return spanInBlock(node);
case 256 /* CatchClause */:
return spanInBlock(node.block);
case 207 /* ExpressionStatement */:
// span on the expression
return textSpan(node.expression);
case 216 /* ReturnStatement */:
// span on return keyword and expression if present
return textSpan(node.getChildAt(0), node.expression);
case 210 /* WhileStatement */:
// Span on while(...)
return textSpanEndingAtNextToken(node, node.expression);
case 209 /* DoStatement */:
// span in statement of the do statement
return spanInNode(node.statement);
case 222 /* DebuggerStatement */:
// span on debugger keyword
return textSpan(node.getChildAt(0));
case 208 /* IfStatement */:
// set on if(..) span
return textSpanEndingAtNextToken(node, node.expression);
case 219 /* LabeledStatement */:
// span in statement
return spanInNode(node.statement);
case 215 /* BreakStatement */:
case 214 /* ContinueStatement */:
// On break or continue keyword and label if present
return textSpan(node.getChildAt(0), node.label);
case 211 /* ForStatement */:
return spanInForStatement(node);
case 212 /* ForInStatement */:
// span of for (a in ...)
return textSpanEndingAtNextToken(node, node.expression);
case 213 /* ForOfStatement */:
// span in initializer
return spanInInitializerOfForLike(node);
case 218 /* SwitchStatement */:
// span on switch(...)
return textSpanEndingAtNextToken(node, node.expression);
case 253 /* CaseClause */:
case 254 /* DefaultClause */:
// span in first statement of the clause
return spanInNode(node.statements[0]);
case 221 /* TryStatement */:
// span in try block
return spanInBlock(node.tryBlock);
case 220 /* ThrowStatement */:
// span in throw ...
return textSpan(node, node.expression);
case 240 /* ExportAssignment */:
// span on export = id
return textSpan(node, node.expression);
case 234 /* ImportEqualsDeclaration */:
// import statement without including semicolon
return textSpan(node, node.moduleReference);
case 235 /* ImportDeclaration */:
// import statement without including semicolon
return textSpan(node, node.moduleSpecifier);
case 241 /* ExportDeclaration */:
// import statement without including semicolon
return textSpan(node, node.moduleSpecifier);
case 230 /* ModuleDeclaration */:
// span on complete module if it is instantiated
if (ts.getModuleInstanceState(node) !== 1 /* Instantiated */) {
return undefined;
}
case 226 /* ClassDeclaration */:
case 229 /* EnumDeclaration */:
case 260 /* EnumMember */:
case 174 /* BindingElement */:
// span on complete node
return textSpan(node);
case 217 /* WithStatement */:
// span in statement
return spanInNode(node.statement);
case 145 /* Decorator */:
return spanInNodeArray(node.parent.decorators);
case 172 /* ObjectBindingPattern */:
case 173 /* ArrayBindingPattern */:
return spanInBindingPattern(node);
// No breakpoint in interface, type alias
case 227 /* InterfaceDeclaration */:
case 228 /* TypeAliasDeclaration */:
return undefined;
// Tokens:
case 24 /* SemicolonToken */:
case 1 /* EndOfFileToken */:
return spanInNodeIfStartsOnSameLine(ts.findPrecedingToken(node.pos, sourceFile));
case 25 /* CommaToken */:
return spanInPreviousNode(node);
case 16 /* OpenBraceToken */:
return spanInOpenBraceToken(node);
case 17 /* CloseBraceToken */:
return spanInCloseBraceToken(node);
case 21 /* CloseBracketToken */:
return spanInCloseBracketToken(node);
case 18 /* OpenParenToken */:
return spanInOpenParenToken(node);
case 19 /* CloseParenToken */:
return spanInCloseParenToken(node);
case 55 /* ColonToken */:
return spanInColonToken(node);
case 28 /* GreaterThanToken */:
case 26 /* LessThanToken */:
return spanInGreaterThanOrLessThanToken(node);
// Keywords:
case 105 /* WhileKeyword */:
return spanInWhileKeyword(node);
case 81 /* ElseKeyword */:
case 73 /* CatchKeyword */:
case 86 /* FinallyKeyword */:
return spanInNextNode(node);
case 140 /* OfKeyword */:
return spanInOfKeyword(node);
default:
// Destructuring pattern in destructuring assignment
// [a, b, c] of
// [a, b, c] = expression
if (ts.isArrayLiteralOrObjectLiteralDestructuringPattern(node)) {
return spanInArrayLiteralOrObjectLiteralDestructuringPattern(node);
}
// Set breakpoint on identifier element of destructuring pattern
// a or ...c or d: x from
// [a, b, ...c] or { a, b } or { d: x } from destructuring pattern
if ((node.kind === 70 /* Identifier */ ||
node.kind == 196 /* SpreadElement */ ||
node.kind === 257 /* PropertyAssignment */ ||
node.kind === 258 /* ShorthandPropertyAssignment */) &&
ts.isArrayLiteralOrObjectLiteralDestructuringPattern(node.parent)) {
return textSpan(node);
}
if (node.kind === 192 /* BinaryExpression */) {
var binaryExpression = node;
// Set breakpoint in destructuring pattern if its destructuring assignment
// [a, b, c] or {a, b, c} of
// [a, b, c] = expression or
// {a, b, c} = expression
if (ts.isArrayLiteralOrObjectLiteralDestructuringPattern(binaryExpression.left)) {
return spanInArrayLiteralOrObjectLiteralDestructuringPattern(binaryExpression.left);
}
if (binaryExpression.operatorToken.kind === 57 /* EqualsToken */ &&
ts.isArrayLiteralOrObjectLiteralDestructuringPattern(binaryExpression.parent)) {
// Set breakpoint on assignment expression element of destructuring pattern
// a = expression of
// [a = expression, b, c] = someExpression or
// { a = expression, b, c } = someExpression
return textSpan(node);
}
if (binaryExpression.operatorToken.kind === 25 /* CommaToken */) {
return spanInNode(binaryExpression.left);
}
}
if (ts.isPartOfExpression(node)) {
switch (node.parent.kind) {
case 209 /* DoStatement */:
// Set span as if on while keyword
return spanInPreviousNode(node);
case 145 /* Decorator */:
// Set breakpoint on the decorator emit
return spanInNode(node.parent);
case 211 /* ForStatement */:
case 213 /* ForOfStatement */:
return textSpan(node);
case 192 /* BinaryExpression */:
if (node.parent.operatorToken.kind === 25 /* CommaToken */) {
// If this is a comma expression, the breakpoint is possible in this expression
return textSpan(node);
}
break;
case 185 /* ArrowFunction */:
if (node.parent.body === node) {
// If this is body of arrow function, it is allowed to have the breakpoint
return textSpan(node);
}
break;
}
}
// If this is name of property assignment, set breakpoint in the initializer
if (node.parent.kind === 257 /* PropertyAssignment */ &&
node.parent.name === node &&
!ts.isArrayLiteralOrObjectLiteralDestructuringPattern(node.parent.parent)) {
return spanInNode(node.parent.initializer);
}
// Breakpoint in type assertion goes to its operand
if (node.parent.kind === 182 /* TypeAssertionExpression */ && node.parent.type === node) {
return spanInNextNode(node.parent.type);
}
// return type of function go to previous token
if (ts.isFunctionLike(node.parent) && node.parent.type === node) {
return spanInPreviousNode(node);
}
// initializer of variable/parameter declaration go to previous node
if ((node.parent.kind === 223 /* VariableDeclaration */ ||
node.parent.kind === 144 /* Parameter */)) {
var paramOrVarDecl = node.parent;
if (paramOrVarDecl.initializer === node ||
paramOrVarDecl.type === node ||
ts.isAssignmentOperator(node.kind)) {
return spanInPreviousNode(node);
}
}
if (node.parent.kind === 192 /* BinaryExpression */) {
var binaryExpression = node.parent;
if (ts.isArrayLiteralOrObjectLiteralDestructuringPattern(binaryExpression.left) &&
(binaryExpression.right === node ||
binaryExpression.operatorToken === node)) {
// If initializer of destructuring assignment move to previous token
return spanInPreviousNode(node);
}
}
// Default go to parent to set the breakpoint
return spanInNode(node.parent);
}
}
function textSpanFromVariableDeclaration(variableDeclaration) {
var declarations = variableDeclaration.parent.declarations;
if (declarations && declarations[0] === variableDeclaration) {
// First declaration - include let keyword
return textSpan(ts.findPrecedingToken(variableDeclaration.pos, sourceFile, variableDeclaration.parent), variableDeclaration);
}
else {
// Span only on this declaration
return textSpan(variableDeclaration);
}
}
function spanInVariableDeclaration(variableDeclaration) {
// If declaration of for in statement, just set the span in parent
if (variableDeclaration.parent.parent.kind === 212 /* ForInStatement */) {
return spanInNode(variableDeclaration.parent.parent);
}
// If this is a destructuring pattern, set breakpoint in binding pattern
if (ts.isBindingPattern(variableDeclaration.name)) {
return spanInBindingPattern(variableDeclaration.name);
}
// Breakpoint is possible in variableDeclaration only if there is initialization
// or its declaration from 'for of'
if (variableDeclaration.initializer ||
ts.hasModifier(variableDeclaration, 1 /* Export */) ||
variableDeclaration.parent.parent.kind === 213 /* ForOfStatement */) {
return textSpanFromVariableDeclaration(variableDeclaration);
}
var declarations = variableDeclaration.parent.declarations;
if (declarations && declarations[0] !== variableDeclaration) {
// If we cannot set breakpoint on this declaration, set it on previous one
// Because the variable declaration may be binding pattern and
// we would like to set breakpoint in last binding element if that's the case,
// use preceding token instead
return spanInNode(ts.findPrecedingToken(variableDeclaration.pos, sourceFile, variableDeclaration.parent));
}
}
function canHaveSpanInParameterDeclaration(parameter) {
// Breakpoint is possible on parameter only if it has initializer, is a rest parameter, or has public or private modifier
return !!parameter.initializer || parameter.dotDotDotToken !== undefined ||
ts.hasModifier(parameter, 4 /* Public */ | 8 /* Private */);
}
function spanInParameterDeclaration(parameter) {
if (ts.isBindingPattern(parameter.name)) {
// Set breakpoint in binding pattern
return spanInBindingPattern(parameter.name);
}
else if (canHaveSpanInParameterDeclaration(parameter)) {
return textSpan(parameter);
}
else {
var functionDeclaration = parameter.parent;
var indexOfParameter = ts.indexOf(functionDeclaration.parameters, parameter);
if (indexOfParameter) {
// Not a first parameter, go to previous parameter
return spanInParameterDeclaration(functionDeclaration.parameters[indexOfParameter - 1]);
}
else {
// Set breakpoint in the function declaration body
return spanInNode(functionDeclaration.body);
}
}
}
function canFunctionHaveSpanInWholeDeclaration(functionDeclaration) {
return ts.hasModifier(functionDeclaration, 1 /* Export */) ||
(functionDeclaration.parent.kind === 226 /* ClassDeclaration */ && functionDeclaration.kind !== 150 /* Constructor */);
}
function spanInFunctionDeclaration(functionDeclaration) {
// No breakpoints in the function signature
if (!functionDeclaration.body) {
return undefined;
}
if (canFunctionHaveSpanInWholeDeclaration(functionDeclaration)) {
// Set the span on whole function declaration
return textSpan(functionDeclaration);
}
// Set span in function body
return spanInNode(functionDeclaration.body);
}
function spanInFunctionBlock(block) {
var nodeForSpanInBlock = block.statements.length ? block.statements[0] : block.getLastToken();
if (canFunctionHaveSpanInWholeDeclaration(block.parent)) {
return spanInNodeIfStartsOnSameLine(block.parent, nodeForSpanInBlock);
}
return spanInNode(nodeForSpanInBlock);
}
function spanInBlock(block) {
switch (block.parent.kind) {
case 230 /* ModuleDeclaration */:
if (ts.getModuleInstanceState(block.parent) !== 1 /* Instantiated */) {
return undefined;
}
// Set on parent if on same line otherwise on first statement
case 210 /* WhileStatement */:
case 208 /* IfStatement */:
case 212 /* ForInStatement */:
return spanInNodeIfStartsOnSameLine(block.parent, block.statements[0]);
// Set span on previous token if it starts on same line otherwise on the first statement of the block
case 211 /* ForStatement */:
case 213 /* ForOfStatement */:
return spanInNodeIfStartsOnSameLine(ts.findPrecedingToken(block.pos, sourceFile, block.parent), block.statements[0]);
}
// Default action is to set on first statement
return spanInNode(block.statements[0]);
}
function spanInInitializerOfForLike(forLikeStatement) {
if (forLikeStatement.initializer.kind === 224 /* VariableDeclarationList */) {
// Declaration list - set breakpoint in first declaration
var variableDeclarationList = forLikeStatement.initializer;
if (variableDeclarationList.declarations.length > 0) {
return spanInNode(variableDeclarationList.declarations[0]);
}
}
else {
// Expression - set breakpoint in it
return spanInNode(forLikeStatement.initializer);
}
}
function spanInForStatement(forStatement) {
if (forStatement.initializer) {
return spanInInitializerOfForLike(forStatement);
}
if (forStatement.condition) {
return textSpan(forStatement.condition);
}
if (forStatement.incrementor) {
return textSpan(forStatement.incrementor);
}
}
function spanInBindingPattern(bindingPattern) {
// Set breakpoint in first binding element
var firstBindingElement = ts.forEach(bindingPattern.elements, function (element) { return element.kind !== 198 /* OmittedExpression */ ? element : undefined; });
if (firstBindingElement) {
return spanInNode(firstBindingElement);
}
// Empty binding pattern of binding element, set breakpoint on binding element
if (bindingPattern.parent.kind === 174 /* BindingElement */) {
return textSpan(bindingPattern.parent);
}
// Variable declaration is used as the span
return textSpanFromVariableDeclaration(bindingPattern.parent);
}
function spanInArrayLiteralOrObjectLiteralDestructuringPattern(node) {
ts.Debug.assert(node.kind !== 173 /* ArrayBindingPattern */ && node.kind !== 172 /* ObjectBindingPattern */);
var elements = node.kind === 175 /* ArrayLiteralExpression */ ?
node.elements :
node.properties;
var firstBindingElement = ts.forEach(elements, function (element) { return element.kind !== 198 /* OmittedExpression */ ? element : undefined; });
if (firstBindingElement) {
return spanInNode(firstBindingElement);
}
// Could be ArrayLiteral from destructuring assignment or
// just nested element in another destructuring assignment
// set breakpoint on assignment when parent is destructuring assignment
// Otherwise set breakpoint for this element
return textSpan(node.parent.kind === 192 /* BinaryExpression */ ? node.parent : node);
}
// Tokens:
function spanInOpenBraceToken(node) {
switch (node.parent.kind) {
case 229 /* EnumDeclaration */:
var enumDeclaration = node.parent;
return spanInNodeIfStartsOnSameLine(ts.findPrecedingToken(node.pos, sourceFile, node.parent), enumDeclaration.members.length ? enumDeclaration.members[0] : enumDeclaration.getLastToken(sourceFile));
case 226 /* ClassDeclaration */:
var classDeclaration = node.parent;
return spanInNodeIfStartsOnSameLine(ts.findPrecedingToken(node.pos, sourceFile, node.parent), classDeclaration.members.length ? classDeclaration.members[0] : classDeclaration.getLastToken(sourceFile));
case 232 /* CaseBlock */:
return spanInNodeIfStartsOnSameLine(node.parent.parent, node.parent.clauses[0]);
}
// Default to parent node
return spanInNode(node.parent);
}
function spanInCloseBraceToken(node) {
switch (node.parent.kind) {
case 231 /* ModuleBlock */:
// If this is not an instantiated module block, no bp span
if (ts.getModuleInstanceState(node.parent.parent) !== 1 /* Instantiated */) {
return undefined;
}
case 229 /* EnumDeclaration */:
case 226 /* ClassDeclaration */:
// Span on close brace token
return textSpan(node);
case 204 /* Block */:
if (ts.isFunctionBlock(node.parent)) {
// Span on close brace token
return textSpan(node);
}
// fall through
case 256 /* CatchClause */:
return spanInNode(ts.lastOrUndefined(node.parent.statements));
case 232 /* CaseBlock */:
// breakpoint in last statement of the last clause
var caseBlock = node.parent;
var lastClause = ts.lastOrUndefined(caseBlock.clauses);
if (lastClause) {
return spanInNode(ts.lastOrUndefined(lastClause.statements));
}
return undefined;
case 172 /* ObjectBindingPattern */:
// Breakpoint in last binding element or binding pattern if it contains no elements
var bindingPattern = node.parent;
return spanInNode(ts.lastOrUndefined(bindingPattern.elements) || bindingPattern);
// Default to parent node
default:
if (ts.isArrayLiteralOrObjectLiteralDestructuringPattern(node.parent)) {
// Breakpoint in last binding element or binding pattern if it contains no elements
var objectLiteral = node.parent;
return textSpan(ts.lastOrUndefined(objectLiteral.properties) || objectLiteral);
}
return spanInNode(node.parent);
}
}
function spanInCloseBracketToken(node) {
switch (node.parent.kind) {
case 173 /* ArrayBindingPattern */:
// Breakpoint in last binding element or binding pattern if it contains no elements
var bindingPattern = node.parent;
return textSpan(ts.lastOrUndefined(bindingPattern.elements) || bindingPattern);
default:
if (ts.isArrayLiteralOrObjectLiteralDestructuringPattern(node.parent)) {
// Breakpoint in last binding element or binding pattern if it contains no elements
var arrayLiteral = node.parent;
return textSpan(ts.lastOrUndefined(arrayLiteral.elements) || arrayLiteral);
}
// Default to parent node
return spanInNode(node.parent);
}
}
function spanInOpenParenToken(node) {
if (node.parent.kind === 209 /* DoStatement */ ||
node.parent.kind === 179 /* CallExpression */ ||
node.parent.kind === 180 /* NewExpression */) {
return spanInPreviousNode(node);
}
if (node.parent.kind === 183 /* ParenthesizedExpression */) {
return spanInNextNode(node);
}
// Default to parent node
return spanInNode(node.parent);
}
function spanInCloseParenToken(node) {
// Is this close paren token of parameter list, set span in previous token
switch (node.parent.kind) {
case 184 /* FunctionExpression */:
case 225 /* FunctionDeclaration */:
case 185 /* ArrowFunction */:
case 149 /* MethodDeclaration */:
case 148 /* MethodSignature */:
case 151 /* GetAccessor */:
case 152 /* SetAccessor */:
case 150 /* Constructor */:
case 210 /* WhileStatement */:
case 209 /* DoStatement */:
case 211 /* ForStatement */:
case 213 /* ForOfStatement */:
case 179 /* CallExpression */:
case 180 /* NewExpression */:
case 183 /* ParenthesizedExpression */:
return spanInPreviousNode(node);
// Default to parent node
default:
return spanInNode(node.parent);
}
}
function spanInColonToken(node) {
// Is this : specifying return annotation of the function declaration
if (ts.isFunctionLike(node.parent) ||
node.parent.kind === 257 /* PropertyAssignment */ ||
node.parent.kind === 144 /* Parameter */) {
return spanInPreviousNode(node);
}
return spanInNode(node.parent);
}
function spanInGreaterThanOrLessThanToken(node) {
if (node.parent.kind === 182 /* TypeAssertionExpression */) {
return spanInNextNode(node);
}
return spanInNode(node.parent);
}
function spanInWhileKeyword(node) {
if (node.parent.kind === 209 /* DoStatement */) {
// Set span on while expression
return textSpanEndingAtNextToken(node, node.parent.expression);
}
// Default to parent node
return spanInNode(node.parent);
}
function spanInOfKeyword(node) {
if (node.parent.kind === 213 /* ForOfStatement */) {
// Set using next token
return spanInNextNode(node);
}
// Default to parent node
return spanInNode(node.parent);
}
}
}
BreakpointResolver.spanInSourceFileAtLocation = spanInSourceFileAtLocation;
})(BreakpointResolver = ts.BreakpointResolver || (ts.BreakpointResolver = {}));
})(ts || (ts = {}));
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//
/// <reference path='services.ts' />
/* @internal */
var debugObjectHost = (function () { return this; })();
// We need to use 'null' to interface with the managed side.
/* tslint:disable:no-null-keyword */
/* tslint:disable:no-in-operator */
/* @internal */
var ts;
(function (ts) {
function logInternalError(logger, err) {
if (logger) {
logger.log("*INTERNAL ERROR* - Exception in typescript services: " + err.message);
}
}
var ScriptSnapshotShimAdapter = (function () {
function ScriptSnapshotShimAdapter(scriptSnapshotShim) {
this.scriptSnapshotShim = scriptSnapshotShim;
}
ScriptSnapshotShimAdapter.prototype.getText = function (start, end) {
return this.scriptSnapshotShim.getText(start, end);
};
ScriptSnapshotShimAdapter.prototype.getLength = function () {
return this.scriptSnapshotShim.getLength();
};
ScriptSnapshotShimAdapter.prototype.getChangeRange = function (oldSnapshot) {
var oldSnapshotShim = oldSnapshot;
var encoded = this.scriptSnapshotShim.getChangeRange(oldSnapshotShim.scriptSnapshotShim);
// TODO: should this be '==='?
if (encoded == null) {
return null;
}
var decoded = JSON.parse(encoded);
return ts.createTextChangeRange(ts.createTextSpan(decoded.span.start, decoded.span.length), decoded.newLength);
};
ScriptSnapshotShimAdapter.prototype.dispose = function () {
// if scriptSnapshotShim is a COM object then property check becomes method call with no arguments
// 'in' does not have this effect
if ("dispose" in this.scriptSnapshotShim) {
this.scriptSnapshotShim.dispose();
}
};
return ScriptSnapshotShimAdapter;
}());
var LanguageServiceShimHostAdapter = (function () {
function LanguageServiceShimHostAdapter(shimHost) {
var _this = this;
this.shimHost = shimHost;
this.loggingEnabled = false;
this.tracingEnabled = false;
// if shimHost is a COM object then property check will become method call with no arguments.
// 'in' does not have this effect.
if ("getModuleResolutionsForFile" in this.shimHost) {
this.resolveModuleNames = function (moduleNames, containingFile) {
var resolutionsInFile = JSON.parse(_this.shimHost.getModuleResolutionsForFile(containingFile));
return ts.map(moduleNames, function (name) {
var result = ts.getProperty(resolutionsInFile, name);
return result ? { resolvedFileName: result, extension: ts.extensionFromPath(result), isExternalLibraryImport: false } : undefined;
});
};
}
if ("directoryExists" in this.shimHost) {
this.directoryExists = function (directoryName) { return _this.shimHost.directoryExists(directoryName); };
}
if ("getTypeReferenceDirectiveResolutionsForFile" in this.shimHost) {
this.resolveTypeReferenceDirectives = function (typeDirectiveNames, containingFile) {
var typeDirectivesForFile = JSON.parse(_this.shimHost.getTypeReferenceDirectiveResolutionsForFile(containingFile));
return ts.map(typeDirectiveNames, function (name) { return ts.getProperty(typeDirectivesForFile, name); });
};
}
}
LanguageServiceShimHostAdapter.prototype.log = function (s) {
if (this.loggingEnabled) {
this.shimHost.log(s);
}
};
LanguageServiceShimHostAdapter.prototype.trace = function (s) {
if (this.tracingEnabled) {
this.shimHost.trace(s);
}
};
LanguageServiceShimHostAdapter.prototype.error = function (s) {
this.shimHost.error(s);
};
LanguageServiceShimHostAdapter.prototype.getProjectVersion = function () {
if (!this.shimHost.getProjectVersion) {
// shimmed host does not support getProjectVersion
return undefined;
}
return this.shimHost.getProjectVersion();
};
LanguageServiceShimHostAdapter.prototype.getTypeRootsVersion = function () {
if (!this.shimHost.getTypeRootsVersion) {
return 0;
}
return this.shimHost.getTypeRootsVersion();
};
LanguageServiceShimHostAdapter.prototype.useCaseSensitiveFileNames = function () {
return this.shimHost.useCaseSensitiveFileNames ? this.shimHost.useCaseSensitiveFileNames() : false;
};
LanguageServiceShimHostAdapter.prototype.getCompilationSettings = function () {
var settingsJson = this.shimHost.getCompilationSettings();
// TODO: should this be '==='?
if (settingsJson == null || settingsJson == "") {
throw Error("LanguageServiceShimHostAdapter.getCompilationSettings: empty compilationSettings");
}
return JSON.parse(settingsJson);
};
LanguageServiceShimHostAdapter.prototype.getScriptFileNames = function () {
var encoded = this.shimHost.getScriptFileNames();
return this.files = JSON.parse(encoded);
};
LanguageServiceShimHostAdapter.prototype.getScriptSnapshot = function (fileName) {
var scriptSnapshot = this.shimHost.getScriptSnapshot(fileName);
return scriptSnapshot && new ScriptSnapshotShimAdapter(scriptSnapshot);
};
LanguageServiceShimHostAdapter.prototype.getScriptKind = function (fileName) {
if ("getScriptKind" in this.shimHost) {
return this.shimHost.getScriptKind(fileName);
}
else {
return 0 /* Unknown */;
}
};
LanguageServiceShimHostAdapter.prototype.getScriptVersion = function (fileName) {
return this.shimHost.getScriptVersion(fileName);
};
LanguageServiceShimHostAdapter.prototype.getLocalizedDiagnosticMessages = function () {
var diagnosticMessagesJson = this.shimHost.getLocalizedDiagnosticMessages();
if (diagnosticMessagesJson == null || diagnosticMessagesJson == "") {
return null;
}
try {
return JSON.parse(diagnosticMessagesJson);
}
catch (e) {
this.log(e.description || "diagnosticMessages.generated.json has invalid JSON format");
return null;
}
};
LanguageServiceShimHostAdapter.prototype.getCancellationToken = function () {
var hostCancellationToken = this.shimHost.getCancellationToken();
return new ThrottledCancellationToken(hostCancellationToken);
};
LanguageServiceShimHostAdapter.prototype.getCurrentDirectory = function () {
return this.shimHost.getCurrentDirectory();
};
LanguageServiceShimHostAdapter.prototype.getDirectories = function (path) {
return JSON.parse(this.shimHost.getDirectories(path));
};
LanguageServiceShimHostAdapter.prototype.getDefaultLibFileName = function (options) {
return this.shimHost.getDefaultLibFileName(JSON.stringify(options));
};
LanguageServiceShimHostAdapter.prototype.readDirectory = function (path, extensions, exclude, include, depth) {
var pattern = ts.getFileMatcherPatterns(path, exclude, include, this.shimHost.useCaseSensitiveFileNames(), this.shimHost.getCurrentDirectory());
return JSON.parse(this.shimHost.readDirectory(path, JSON.stringify(extensions), JSON.stringify(pattern.basePaths), pattern.excludePattern, pattern.includeFilePattern, pattern.includeDirectoryPattern, depth));
};
LanguageServiceShimHostAdapter.prototype.readFile = function (path, encoding) {
return this.shimHost.readFile(path, encoding);
};
LanguageServiceShimHostAdapter.prototype.fileExists = function (path) {
return this.shimHost.fileExists(path);
};
return LanguageServiceShimHostAdapter;
}());
ts.LanguageServiceShimHostAdapter = LanguageServiceShimHostAdapter;
/** A cancellation that throttles calls to the host */
var ThrottledCancellationToken = (function () {
function ThrottledCancellationToken(hostCancellationToken) {
this.hostCancellationToken = hostCancellationToken;
// Store when we last tried to cancel. Checking cancellation can be expensive (as we have
// to marshall over to the host layer). So we only bother actually checking once enough
// time has passed.
this.lastCancellationCheckTime = 0;
}
ThrottledCancellationToken.prototype.isCancellationRequested = function () {
var time = ts.timestamp();
var duration = Math.abs(time - this.lastCancellationCheckTime);
if (duration > 10) {
// Check no more than once every 10 ms.
this.lastCancellationCheckTime = time;
return this.hostCancellationToken.isCancellationRequested();
}
return false;
};
return ThrottledCancellationToken;
}());
var CoreServicesShimHostAdapter = (function () {
function CoreServicesShimHostAdapter(shimHost) {
var _this = this;
this.shimHost = shimHost;
this.useCaseSensitiveFileNames = this.shimHost.useCaseSensitiveFileNames ? this.shimHost.useCaseSensitiveFileNames() : false;
if ("directoryExists" in this.shimHost) {
this.directoryExists = function (directoryName) { return _this.shimHost.directoryExists(directoryName); };
}
if ("realpath" in this.shimHost) {
this.realpath = function (path) { return _this.shimHost.realpath(path); };
}
}
CoreServicesShimHostAdapter.prototype.readDirectory = function (rootDir, extensions, exclude, include, depth) {
// Wrap the API changes for 2.0 release. This try/catch
// should be removed once TypeScript 2.0 has shipped.
try {
var pattern = ts.getFileMatcherPatterns(rootDir, exclude, include, this.shimHost.useCaseSensitiveFileNames(), this.shimHost.getCurrentDirectory());
return JSON.parse(this.shimHost.readDirectory(rootDir, JSON.stringify(extensions), JSON.stringify(pattern.basePaths), pattern.excludePattern, pattern.includeFilePattern, pattern.includeDirectoryPattern, depth));
}
catch (e) {
var results = [];
for (var _i = 0, extensions_2 = extensions; _i < extensions_2.length; _i++) {
var extension = extensions_2[_i];
for (var _a = 0, _b = this.readDirectoryFallback(rootDir, extension, exclude); _a < _b.length; _a++) {
var file = _b[_a];
if (!ts.contains(results, file)) {
results.push(file);
}
}
}
return results;
}
};
CoreServicesShimHostAdapter.prototype.fileExists = function (fileName) {
return this.shimHost.fileExists(fileName);
};
CoreServicesShimHostAdapter.prototype.readFile = function (fileName) {
return this.shimHost.readFile(fileName);
};
CoreServicesShimHostAdapter.prototype.readDirectoryFallback = function (rootDir, extension, exclude) {
return JSON.parse(this.shimHost.readDirectory(rootDir, extension, JSON.stringify(exclude)));
};
CoreServicesShimHostAdapter.prototype.getDirectories = function (path) {
return JSON.parse(this.shimHost.getDirectories(path));
};
return CoreServicesShimHostAdapter;
}());
ts.CoreServicesShimHostAdapter = CoreServicesShimHostAdapter;
function simpleForwardCall(logger, actionDescription, action, logPerformance) {
var start;
if (logPerformance) {
logger.log(actionDescription);
start = ts.timestamp();
}
var result = action();
if (logPerformance) {
var end = ts.timestamp();
logger.log(actionDescription + " completed in " + (end - start) + " msec");
if (typeof result === "string") {
var str = result;
if (str.length > 128) {
str = str.substring(0, 128) + "...";
}
logger.log(" result.length=" + str.length + ", result='" + JSON.stringify(str) + "'");
}
}
return result;
}
function forwardJSONCall(logger, actionDescription, action, logPerformance) {
return forwardCall(logger, actionDescription, /*returnJson*/ true, action, logPerformance);
}
function forwardCall(logger, actionDescription, returnJson, action, logPerformance) {
try {
var result = simpleForwardCall(logger, actionDescription, action, logPerformance);
return returnJson ? JSON.stringify({ result: result }) : result;
}
catch (err) {
if (err instanceof ts.OperationCanceledException) {
return JSON.stringify({ canceled: true });
}
logInternalError(logger, err);
err.description = actionDescription;
return JSON.stringify({ error: err });
}
}
var ShimBase = (function () {
function ShimBase(factory) {
this.factory = factory;
factory.registerShim(this);
}
ShimBase.prototype.dispose = function (_dummy) {
this.factory.unregisterShim(this);
};
return ShimBase;
}());
function realizeDiagnostics(diagnostics, newLine) {
return diagnostics.map(function (d) { return realizeDiagnostic(d, newLine); });
}
ts.realizeDiagnostics = realizeDiagnostics;
function realizeDiagnostic(diagnostic, newLine) {
return {
message: ts.flattenDiagnosticMessageText(diagnostic.messageText, newLine),
start: diagnostic.start,
length: diagnostic.length,
/// TODO: no need for the tolowerCase call
category: ts.DiagnosticCategory[diagnostic.category].toLowerCase(),
code: diagnostic.code
};
}
var LanguageServiceShimObject = (function (_super) {
__extends(LanguageServiceShimObject, _super);
function LanguageServiceShimObject(factory, host, languageService) {
var _this = _super.call(this, factory) || this;
_this.host = host;
_this.languageService = languageService;
_this.logPerformance = false;
_this.logger = _this.host;
return _this;
}
LanguageServiceShimObject.prototype.forwardJSONCall = function (actionDescription, action) {
return forwardJSONCall(this.logger, actionDescription, action, this.logPerformance);
};
/// DISPOSE
/**
* Ensure (almost) deterministic release of internal Javascript resources when
* some external native objects holds onto us (e.g. Com/Interop).
*/
LanguageServiceShimObject.prototype.dispose = function (dummy) {
this.logger.log("dispose()");
this.languageService.dispose();
this.languageService = null;
// force a GC
if (debugObjectHost && debugObjectHost.CollectGarbage) {
debugObjectHost.CollectGarbage();
this.logger.log("CollectGarbage()");
}
this.logger = null;
_super.prototype.dispose.call(this, dummy);
};
/// REFRESH
/**
* Update the list of scripts known to the compiler
*/
LanguageServiceShimObject.prototype.refresh = function (throwOnError) {
this.forwardJSONCall("refresh(" + throwOnError + ")", function () { return null; });
};
LanguageServiceShimObject.prototype.cleanupSemanticCache = function () {
var _this = this;
this.forwardJSONCall("cleanupSemanticCache()", function () {
_this.languageService.cleanupSemanticCache();
return null;
});
};
LanguageServiceShimObject.prototype.realizeDiagnostics = function (diagnostics) {
var newLine = ts.getNewLineOrDefaultFromHost(this.host);
return ts.realizeDiagnostics(diagnostics, newLine);
};
LanguageServiceShimObject.prototype.getSyntacticClassifications = function (fileName, start, length) {
var _this = this;
return this.forwardJSONCall("getSyntacticClassifications('" + fileName + "', " + start + ", " + length + ")", function () { return _this.languageService.getSyntacticClassifications(fileName, ts.createTextSpan(start, length)); });
};
LanguageServiceShimObject.prototype.getSemanticClassifications = function (fileName, start, length) {
var _this = this;
return this.forwardJSONCall("getSemanticClassifications('" + fileName + "', " + start + ", " + length + ")", function () { return _this.languageService.getSemanticClassifications(fileName, ts.createTextSpan(start, length)); });
};
LanguageServiceShimObject.prototype.getEncodedSyntacticClassifications = function (fileName, start, length) {
var _this = this;
return this.forwardJSONCall("getEncodedSyntacticClassifications('" + fileName + "', " + start + ", " + length + ")",
// directly serialize the spans out to a string. This is much faster to decode
// on the managed side versus a full JSON array.
function () { return convertClassifications(_this.languageService.getEncodedSyntacticClassifications(fileName, ts.createTextSpan(start, length))); });
};
LanguageServiceShimObject.prototype.getEncodedSemanticClassifications = function (fileName, start, length) {
var _this = this;
return this.forwardJSONCall("getEncodedSemanticClassifications('" + fileName + "', " + start + ", " + length + ")",
// directly serialize the spans out to a string. This is much faster to decode
// on the managed side versus a full JSON array.
function () { return convertClassifications(_this.languageService.getEncodedSemanticClassifications(fileName, ts.createTextSpan(start, length))); });
};
LanguageServiceShimObject.prototype.getSyntacticDiagnostics = function (fileName) {
var _this = this;
return this.forwardJSONCall("getSyntacticDiagnostics('" + fileName + "')", function () {
var diagnostics = _this.languageService.getSyntacticDiagnostics(fileName);
return _this.realizeDiagnostics(diagnostics);
});
};
LanguageServiceShimObject.prototype.getSemanticDiagnostics = function (fileName) {
var _this = this;
return this.forwardJSONCall("getSemanticDiagnostics('" + fileName + "')", function () {
var diagnostics = _this.languageService.getSemanticDiagnostics(fileName);
return _this.realizeDiagnostics(diagnostics);
});
};
LanguageServiceShimObject.prototype.getCompilerOptionsDiagnostics = function () {
var _this = this;
return this.forwardJSONCall("getCompilerOptionsDiagnostics()", function () {
var diagnostics = _this.languageService.getCompilerOptionsDiagnostics();
return _this.realizeDiagnostics(diagnostics);
});
};
/// QUICKINFO
/**
* Computes a string representation of the type at the requested position
* in the active file.
*/
LanguageServiceShimObject.prototype.getQuickInfoAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getQuickInfoAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getQuickInfoAtPosition(fileName, position); });
};
/// NAMEORDOTTEDNAMESPAN
/**
* Computes span information of the name or dotted name at the requested position
* in the active file.
*/
LanguageServiceShimObject.prototype.getNameOrDottedNameSpan = function (fileName, startPos, endPos) {
var _this = this;
return this.forwardJSONCall("getNameOrDottedNameSpan('" + fileName + "', " + startPos + ", " + endPos + ")", function () { return _this.languageService.getNameOrDottedNameSpan(fileName, startPos, endPos); });
};
/**
* STATEMENTSPAN
* Computes span information of statement at the requested position in the active file.
*/
LanguageServiceShimObject.prototype.getBreakpointStatementAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getBreakpointStatementAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getBreakpointStatementAtPosition(fileName, position); });
};
/// SIGNATUREHELP
LanguageServiceShimObject.prototype.getSignatureHelpItems = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getSignatureHelpItems('" + fileName + "', " + position + ")", function () { return _this.languageService.getSignatureHelpItems(fileName, position); });
};
/// GOTO DEFINITION
/**
* Computes the definition location and file for the symbol
* at the requested position.
*/
LanguageServiceShimObject.prototype.getDefinitionAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getDefinitionAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getDefinitionAtPosition(fileName, position); });
};
/// GOTO Type
/**
* Computes the definition location of the type of the symbol
* at the requested position.
*/
LanguageServiceShimObject.prototype.getTypeDefinitionAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getTypeDefinitionAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getTypeDefinitionAtPosition(fileName, position); });
};
/// GOTO Implementation
/**
* Computes the implementation location of the symbol
* at the requested position.
*/
LanguageServiceShimObject.prototype.getImplementationAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getImplementationAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getImplementationAtPosition(fileName, position); });
};
LanguageServiceShimObject.prototype.getRenameInfo = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getRenameInfo('" + fileName + "', " + position + ")", function () { return _this.languageService.getRenameInfo(fileName, position); });
};
LanguageServiceShimObject.prototype.findRenameLocations = function (fileName, position, findInStrings, findInComments) {
var _this = this;
return this.forwardJSONCall("findRenameLocations('" + fileName + "', " + position + ", " + findInStrings + ", " + findInComments + ")", function () { return _this.languageService.findRenameLocations(fileName, position, findInStrings, findInComments); });
};
/// GET BRACE MATCHING
LanguageServiceShimObject.prototype.getBraceMatchingAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getBraceMatchingAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getBraceMatchingAtPosition(fileName, position); });
};
LanguageServiceShimObject.prototype.isValidBraceCompletionAtPosition = function (fileName, position, openingBrace) {
var _this = this;
return this.forwardJSONCall("isValidBraceCompletionAtPosition('" + fileName + "', " + position + ", " + openingBrace + ")", function () { return _this.languageService.isValidBraceCompletionAtPosition(fileName, position, openingBrace); });
};
/// GET SMART INDENT
LanguageServiceShimObject.prototype.getIndentationAtPosition = function (fileName, position, options /*Services.EditorOptions*/) {
var _this = this;
return this.forwardJSONCall("getIndentationAtPosition('" + fileName + "', " + position + ")", function () {
var localOptions = JSON.parse(options);
return _this.languageService.getIndentationAtPosition(fileName, position, localOptions);
});
};
/// GET REFERENCES
LanguageServiceShimObject.prototype.getReferencesAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getReferencesAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getReferencesAtPosition(fileName, position); });
};
LanguageServiceShimObject.prototype.findReferences = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("findReferences('" + fileName + "', " + position + ")", function () { return _this.languageService.findReferences(fileName, position); });
};
LanguageServiceShimObject.prototype.getOccurrencesAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getOccurrencesAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getOccurrencesAtPosition(fileName, position); });
};
LanguageServiceShimObject.prototype.getDocumentHighlights = function (fileName, position, filesToSearch) {
var _this = this;
return this.forwardJSONCall("getDocumentHighlights('" + fileName + "', " + position + ")", function () {
var results = _this.languageService.getDocumentHighlights(fileName, position, JSON.parse(filesToSearch));
// workaround for VS document highlighting issue - keep only items from the initial file
var normalizedName = ts.normalizeSlashes(fileName).toLowerCase();
return ts.filter(results, function (r) { return ts.normalizeSlashes(r.fileName).toLowerCase() === normalizedName; });
});
};
/// COMPLETION LISTS
/**
* Get a string based representation of the completions
* to provide at the given source position and providing a member completion
* list if requested.
*/
LanguageServiceShimObject.prototype.getCompletionsAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getCompletionsAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getCompletionsAtPosition(fileName, position); });
};
/** Get a string based representation of a completion list entry details */
LanguageServiceShimObject.prototype.getCompletionEntryDetails = function (fileName, position, entryName) {
var _this = this;
return this.forwardJSONCall("getCompletionEntryDetails('" + fileName + "', " + position + ", '" + entryName + "')", function () { return _this.languageService.getCompletionEntryDetails(fileName, position, entryName); });
};
LanguageServiceShimObject.prototype.getFormattingEditsForRange = function (fileName, start, end, options /*Services.FormatCodeOptions*/) {
var _this = this;
return this.forwardJSONCall("getFormattingEditsForRange('" + fileName + "', " + start + ", " + end + ")", function () {
var localOptions = JSON.parse(options);
return _this.languageService.getFormattingEditsForRange(fileName, start, end, localOptions);
});
};
LanguageServiceShimObject.prototype.getFormattingEditsForDocument = function (fileName, options /*Services.FormatCodeOptions*/) {
var _this = this;
return this.forwardJSONCall("getFormattingEditsForDocument('" + fileName + "')", function () {
var localOptions = JSON.parse(options);
return _this.languageService.getFormattingEditsForDocument(fileName, localOptions);
});
};
LanguageServiceShimObject.prototype.getFormattingEditsAfterKeystroke = function (fileName, position, key, options /*Services.FormatCodeOptions*/) {
var _this = this;
return this.forwardJSONCall("getFormattingEditsAfterKeystroke('" + fileName + "', " + position + ", '" + key + "')", function () {
var localOptions = JSON.parse(options);
return _this.languageService.getFormattingEditsAfterKeystroke(fileName, position, key, localOptions);
});
};
LanguageServiceShimObject.prototype.getDocCommentTemplateAtPosition = function (fileName, position) {
var _this = this;
return this.forwardJSONCall("getDocCommentTemplateAtPosition('" + fileName + "', " + position + ")", function () { return _this.languageService.getDocCommentTemplateAtPosition(fileName, position); });
};
/// NAVIGATE TO
/** Return a list of symbols that are interesting to navigate to */
LanguageServiceShimObject.prototype.getNavigateToItems = function (searchValue, maxResultCount, fileName) {
var _this = this;
return this.forwardJSONCall("getNavigateToItems('" + searchValue + "', " + maxResultCount + ", " + fileName + ")", function () { return _this.languageService.getNavigateToItems(searchValue, maxResultCount, fileName); });
};
LanguageServiceShimObject.prototype.getNavigationBarItems = function (fileName) {
var _this = this;
return this.forwardJSONCall("getNavigationBarItems('" + fileName + "')", function () { return _this.languageService.getNavigationBarItems(fileName); });
};
LanguageServiceShimObject.prototype.getNavigationTree = function (fileName) {
var _this = this;
return this.forwardJSONCall("getNavigationTree('" + fileName + "')", function () { return _this.languageService.getNavigationTree(fileName); });
};
LanguageServiceShimObject.prototype.getOutliningSpans = function (fileName) {
var _this = this;
return this.forwardJSONCall("getOutliningSpans('" + fileName + "')", function () { return _this.languageService.getOutliningSpans(fileName); });
};
LanguageServiceShimObject.prototype.getTodoComments = function (fileName, descriptors) {
var _this = this;
return this.forwardJSONCall("getTodoComments('" + fileName + "')", function () { return _this.languageService.getTodoComments(fileName, JSON.parse(descriptors)); });
};
/// Emit
LanguageServiceShimObject.prototype.getEmitOutput = function (fileName) {
var _this = this;
return this.forwardJSONCall("getEmitOutput('" + fileName + "')", function () { return _this.languageService.getEmitOutput(fileName); });
};
LanguageServiceShimObject.prototype.getEmitOutputObject = function (fileName) {
var _this = this;
return forwardCall(this.logger, "getEmitOutput('" + fileName + "')",
/*returnJson*/ false, function () { return _this.languageService.getEmitOutput(fileName); }, this.logPerformance);
};
return LanguageServiceShimObject;
}(ShimBase));
function convertClassifications(classifications) {
return { spans: classifications.spans.join(","), endOfLineState: classifications.endOfLineState };
}
var ClassifierShimObject = (function (_super) {
__extends(ClassifierShimObject, _super);
function ClassifierShimObject(factory, logger) {
var _this = _super.call(this, factory) || this;
_this.logger = logger;
_this.logPerformance = false;
_this.classifier = ts.createClassifier();
return _this;
}
ClassifierShimObject.prototype.getEncodedLexicalClassifications = function (text, lexState, syntacticClassifierAbsent) {
var _this = this;
return forwardJSONCall(this.logger, "getEncodedLexicalClassifications", function () { return convertClassifications(_this.classifier.getEncodedLexicalClassifications(text, lexState, syntacticClassifierAbsent)); }, this.logPerformance);
};
/// COLORIZATION
ClassifierShimObject.prototype.getClassificationsForLine = function (text, lexState, classifyKeywordsInGenerics) {
var classification = this.classifier.getClassificationsForLine(text, lexState, classifyKeywordsInGenerics);
var result = "";
for (var _i = 0, _a = classification.entries; _i < _a.length; _i++) {
var item = _a[_i];
result += item.length + "\n";
result += item.classification + "\n";
}
result += classification.finalLexState;
return result;
};
return ClassifierShimObject;
}(ShimBase));
var CoreServicesShimObject = (function (_super) {
__extends(CoreServicesShimObject, _super);
function CoreServicesShimObject(factory, logger, host) {
var _this = _super.call(this, factory) || this;
_this.logger = logger;
_this.host = host;
_this.logPerformance = false;
return _this;
}
CoreServicesShimObject.prototype.forwardJSONCall = function (actionDescription, action) {
return forwardJSONCall(this.logger, actionDescription, action, this.logPerformance);
};
CoreServicesShimObject.prototype.resolveModuleName = function (fileName, moduleName, compilerOptionsJson) {
var _this = this;
return this.forwardJSONCall("resolveModuleName('" + fileName + "')", function () {
var compilerOptions = JSON.parse(compilerOptionsJson);
var result = ts.resolveModuleName(moduleName, ts.normalizeSlashes(fileName), compilerOptions, _this.host);
var resolvedFileName = result.resolvedModule ? result.resolvedModule.resolvedFileName : undefined;
if (resolvedFileName && !compilerOptions.allowJs && ts.fileExtensionIs(resolvedFileName, ".js")) {
return {
resolvedFileName: undefined,
failedLookupLocations: []
};
}
return {
resolvedFileName: resolvedFileName,
failedLookupLocations: result.failedLookupLocations
};
});
};
CoreServicesShimObject.prototype.resolveTypeReferenceDirective = function (fileName, typeReferenceDirective, compilerOptionsJson) {
var _this = this;
return this.forwardJSONCall("resolveTypeReferenceDirective(" + fileName + ")", function () {
var compilerOptions = JSON.parse(compilerOptionsJson);
var result = ts.resolveTypeReferenceDirective(typeReferenceDirective, ts.normalizeSlashes(fileName), compilerOptions, _this.host);
return {
resolvedFileName: result.resolvedTypeReferenceDirective ? result.resolvedTypeReferenceDirective.resolvedFileName : undefined,
primary: result.resolvedTypeReferenceDirective ? result.resolvedTypeReferenceDirective.primary : true,
failedLookupLocations: result.failedLookupLocations
};
});
};
CoreServicesShimObject.prototype.getPreProcessedFileInfo = function (fileName, sourceTextSnapshot) {
var _this = this;
return this.forwardJSONCall("getPreProcessedFileInfo('" + fileName + "')", function () {
// for now treat files as JavaScript
var result = ts.preProcessFile(sourceTextSnapshot.getText(0, sourceTextSnapshot.getLength()), /* readImportFiles */ true, /* detectJavaScriptImports */ true);
return {
referencedFiles: _this.convertFileReferences(result.referencedFiles),
importedFiles: _this.convertFileReferences(result.importedFiles),
ambientExternalModules: result.ambientExternalModules,
isLibFile: result.isLibFile,
typeReferenceDirectives: _this.convertFileReferences(result.typeReferenceDirectives)
};
});
};
CoreServicesShimObject.prototype.getAutomaticTypeDirectiveNames = function (compilerOptionsJson) {
var _this = this;
return this.forwardJSONCall("getAutomaticTypeDirectiveNames('" + compilerOptionsJson + "')", function () {
var compilerOptions = JSON.parse(compilerOptionsJson);
return ts.getAutomaticTypeDirectiveNames(compilerOptions, _this.host);
});
};
CoreServicesShimObject.prototype.convertFileReferences = function (refs) {
if (!refs) {
return undefined;
}
var result = [];
for (var _i = 0, refs_2 = refs; _i < refs_2.length; _i++) {
var ref = refs_2[_i];
result.push({
path: ts.normalizeSlashes(ref.fileName),
position: ref.pos,
length: ref.end - ref.pos
});
}
return result;
};
CoreServicesShimObject.prototype.getTSConfigFileInfo = function (fileName, sourceTextSnapshot) {
var _this = this;
return this.forwardJSONCall("getTSConfigFileInfo('" + fileName + "')", function () {
var text = sourceTextSnapshot.getText(0, sourceTextSnapshot.getLength());
var result = ts.parseConfigFileTextToJson(fileName, text);
if (result.error) {
return {
options: {},
typingOptions: {},
files: [],
raw: {},
errors: [realizeDiagnostic(result.error, "\r\n")]
};
}
var normalizedFileName = ts.normalizeSlashes(fileName);
var configFile = ts.parseJsonConfigFileContent(result.config, _this.host, ts.getDirectoryPath(normalizedFileName), /*existingOptions*/ {}, normalizedFileName);
return {
options: configFile.options,
typingOptions: configFile.typingOptions,
files: configFile.fileNames,
raw: configFile.raw,
errors: realizeDiagnostics(configFile.errors, "\r\n")
};
});
};
CoreServicesShimObject.prototype.getDefaultCompilationSettings = function () {
return this.forwardJSONCall("getDefaultCompilationSettings()", function () { return ts.getDefaultCompilerOptions(); });
};
CoreServicesShimObject.prototype.discoverTypings = function (discoverTypingsJson) {
var _this = this;
var getCanonicalFileName = ts.createGetCanonicalFileName(/*useCaseSensitivefileNames:*/ false);
return this.forwardJSONCall("discoverTypings()", function () {
var info = JSON.parse(discoverTypingsJson);
return ts.JsTyping.discoverTypings(_this.host, info.fileNames, ts.toPath(info.projectRootPath, info.projectRootPath, getCanonicalFileName), ts.toPath(info.safeListPath, info.safeListPath, getCanonicalFileName), info.packageNameToTypingLocation, info.typingOptions, info.unresolvedImports);
});
};
return CoreServicesShimObject;
}(ShimBase));
var TypeScriptServicesFactory = (function () {
function TypeScriptServicesFactory() {
this._shims = [];
}
/*
* Returns script API version.
*/
TypeScriptServicesFactory.prototype.getServicesVersion = function () {
return ts.servicesVersion;
};
TypeScriptServicesFactory.prototype.createLanguageServiceShim = function (host) {
try {
if (this.documentRegistry === undefined) {
this.documentRegistry = ts.createDocumentRegistry(host.useCaseSensitiveFileNames && host.useCaseSensitiveFileNames(), host.getCurrentDirectory());
}
var hostAdapter = new LanguageServiceShimHostAdapter(host);
var languageService = ts.createLanguageService(hostAdapter, this.documentRegistry);
return new LanguageServiceShimObject(this, host, languageService);
}
catch (err) {
logInternalError(host, err);
throw err;
}
};
TypeScriptServicesFactory.prototype.createClassifierShim = function (logger) {
try {
return new ClassifierShimObject(this, logger);
}
catch (err) {
logInternalError(logger, err);
throw err;
}
};
TypeScriptServicesFactory.prototype.createCoreServicesShim = function (host) {
try {
var adapter = new CoreServicesShimHostAdapter(host);
return new CoreServicesShimObject(this, host, adapter);
}
catch (err) {
logInternalError(host, err);
throw err;
}
};
TypeScriptServicesFactory.prototype.close = function () {
// Forget all the registered shims
this._shims = [];
this.documentRegistry = undefined;
};
TypeScriptServicesFactory.prototype.registerShim = function (shim) {
this._shims.push(shim);
};
TypeScriptServicesFactory.prototype.unregisterShim = function (shim) {
for (var i = 0, n = this._shims.length; i < n; i++) {
if (this._shims[i] === shim) {
delete this._shims[i];
return;
}
}
throw new Error("Invalid operation");
};
return TypeScriptServicesFactory;
}());
ts.TypeScriptServicesFactory = TypeScriptServicesFactory;
if (typeof module !== "undefined" && module.exports) {
module.exports = ts;
}
})(ts || (ts = {}));
/* tslint:enable:no-in-operator */
/* tslint:enable:no-null */
/// TODO: this is used by VS, clean this up on both sides of the interface
/* @internal */
var TypeScript;
(function (TypeScript) {
var Services;
(function (Services) {
Services.TypeScriptServicesFactory = ts.TypeScriptServicesFactory;
})(Services = TypeScript.Services || (TypeScript.Services = {}));
})(TypeScript || (TypeScript = {}));
// 'toolsVersion' gets consumed by the managed side, so it's not unused.
// TODO: it should be moved into a namespace though.
/* @internal */
var toolsVersion = "2.2";
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