0
0
Fork 0
mirror of https://github.com/go-gitea/gitea synced 2024-11-09 03:21:45 +01:00
gitea/vendor/github.com/gobwas/glob/compiler/compiler.go
WGH 6ddd3b0b47 Implement webhook branch filter (#7791)
* Fix validate() function to handle errors in embedded anon structs

* Implement webhook branch filter

See #2025, #3998.
2019-09-09 08:48:21 +03:00

525 lines
11 KiB
Go
Vendored
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

package compiler
// TODO use constructor with all matchers, and to their structs private
// TODO glue multiple Text nodes (like after QuoteMeta)
import (
"fmt"
"reflect"
"github.com/gobwas/glob/match"
"github.com/gobwas/glob/syntax/ast"
"github.com/gobwas/glob/util/runes"
)
func optimizeMatcher(matcher match.Matcher) match.Matcher {
switch m := matcher.(type) {
case match.Any:
if len(m.Separators) == 0 {
return match.NewSuper()
}
case match.AnyOf:
if len(m.Matchers) == 1 {
return m.Matchers[0]
}
return m
case match.List:
if m.Not == false && len(m.List) == 1 {
return match.NewText(string(m.List))
}
return m
case match.BTree:
m.Left = optimizeMatcher(m.Left)
m.Right = optimizeMatcher(m.Right)
r, ok := m.Value.(match.Text)
if !ok {
return m
}
var (
leftNil = m.Left == nil
rightNil = m.Right == nil
)
if leftNil && rightNil {
return match.NewText(r.Str)
}
_, leftSuper := m.Left.(match.Super)
lp, leftPrefix := m.Left.(match.Prefix)
la, leftAny := m.Left.(match.Any)
_, rightSuper := m.Right.(match.Super)
rs, rightSuffix := m.Right.(match.Suffix)
ra, rightAny := m.Right.(match.Any)
switch {
case leftSuper && rightSuper:
return match.NewContains(r.Str, false)
case leftSuper && rightNil:
return match.NewSuffix(r.Str)
case rightSuper && leftNil:
return match.NewPrefix(r.Str)
case leftNil && rightSuffix:
return match.NewPrefixSuffix(r.Str, rs.Suffix)
case rightNil && leftPrefix:
return match.NewPrefixSuffix(lp.Prefix, r.Str)
case rightNil && leftAny:
return match.NewSuffixAny(r.Str, la.Separators)
case leftNil && rightAny:
return match.NewPrefixAny(r.Str, ra.Separators)
}
return m
}
return matcher
}
func compileMatchers(matchers []match.Matcher) (match.Matcher, error) {
if len(matchers) == 0 {
return nil, fmt.Errorf("compile error: need at least one matcher")
}
if len(matchers) == 1 {
return matchers[0], nil
}
if m := glueMatchers(matchers); m != nil {
return m, nil
}
idx := -1
maxLen := -1
var val match.Matcher
for i, matcher := range matchers {
if l := matcher.Len(); l != -1 && l >= maxLen {
maxLen = l
idx = i
val = matcher
}
}
if val == nil { // not found matcher with static length
r, err := compileMatchers(matchers[1:])
if err != nil {
return nil, err
}
return match.NewBTree(matchers[0], nil, r), nil
}
left := matchers[:idx]
var right []match.Matcher
if len(matchers) > idx+1 {
right = matchers[idx+1:]
}
var l, r match.Matcher
var err error
if len(left) > 0 {
l, err = compileMatchers(left)
if err != nil {
return nil, err
}
}
if len(right) > 0 {
r, err = compileMatchers(right)
if err != nil {
return nil, err
}
}
return match.NewBTree(val, l, r), nil
}
func glueMatchers(matchers []match.Matcher) match.Matcher {
if m := glueMatchersAsEvery(matchers); m != nil {
return m
}
if m := glueMatchersAsRow(matchers); m != nil {
return m
}
return nil
}
func glueMatchersAsRow(matchers []match.Matcher) match.Matcher {
if len(matchers) <= 1 {
return nil
}
var (
c []match.Matcher
l int
)
for _, matcher := range matchers {
if ml := matcher.Len(); ml == -1 {
return nil
} else {
c = append(c, matcher)
l += ml
}
}
return match.NewRow(l, c...)
}
func glueMatchersAsEvery(matchers []match.Matcher) match.Matcher {
if len(matchers) <= 1 {
return nil
}
var (
hasAny bool
hasSuper bool
hasSingle bool
min int
separator []rune
)
for i, matcher := range matchers {
var sep []rune
switch m := matcher.(type) {
case match.Super:
sep = []rune{}
hasSuper = true
case match.Any:
sep = m.Separators
hasAny = true
case match.Single:
sep = m.Separators
hasSingle = true
min++
case match.List:
if !m.Not {
return nil
}
sep = m.List
hasSingle = true
min++
default:
return nil
}
// initialize
if i == 0 {
separator = sep
}
if runes.Equal(sep, separator) {
continue
}
return nil
}
if hasSuper && !hasAny && !hasSingle {
return match.NewSuper()
}
if hasAny && !hasSuper && !hasSingle {
return match.NewAny(separator)
}
if (hasAny || hasSuper) && min > 0 && len(separator) == 0 {
return match.NewMin(min)
}
every := match.NewEveryOf()
if min > 0 {
every.Add(match.NewMin(min))
if !hasAny && !hasSuper {
every.Add(match.NewMax(min))
}
}
if len(separator) > 0 {
every.Add(match.NewContains(string(separator), true))
}
return every
}
func minimizeMatchers(matchers []match.Matcher) []match.Matcher {
var done match.Matcher
var left, right, count int
for l := 0; l < len(matchers); l++ {
for r := len(matchers); r > l; r-- {
if glued := glueMatchers(matchers[l:r]); glued != nil {
var swap bool
if done == nil {
swap = true
} else {
cl, gl := done.Len(), glued.Len()
swap = cl > -1 && gl > -1 && gl > cl
swap = swap || count < r-l
}
if swap {
done = glued
left = l
right = r
count = r - l
}
}
}
}
if done == nil {
return matchers
}
next := append(append([]match.Matcher{}, matchers[:left]...), done)
if right < len(matchers) {
next = append(next, matchers[right:]...)
}
if len(next) == len(matchers) {
return next
}
return minimizeMatchers(next)
}
// minimizeAnyOf tries to apply some heuristics to minimize number of nodes in given tree
func minimizeTree(tree *ast.Node) *ast.Node {
switch tree.Kind {
case ast.KindAnyOf:
return minimizeTreeAnyOf(tree)
default:
return nil
}
}
// minimizeAnyOf tries to find common children of given node of AnyOf pattern
// it searches for common children from left and from right
// if any common children are found then it returns new optimized ast tree
// else it returns nil
func minimizeTreeAnyOf(tree *ast.Node) *ast.Node {
if !areOfSameKind(tree.Children, ast.KindPattern) {
return nil
}
commonLeft, commonRight := commonChildren(tree.Children)
commonLeftCount, commonRightCount := len(commonLeft), len(commonRight)
if commonLeftCount == 0 && commonRightCount == 0 { // there are no common parts
return nil
}
var result []*ast.Node
if commonLeftCount > 0 {
result = append(result, ast.NewNode(ast.KindPattern, nil, commonLeft...))
}
var anyOf []*ast.Node
for _, child := range tree.Children {
reuse := child.Children[commonLeftCount : len(child.Children)-commonRightCount]
var node *ast.Node
if len(reuse) == 0 {
// this pattern is completely reduced by commonLeft and commonRight patterns
// so it become nothing
node = ast.NewNode(ast.KindNothing, nil)
} else {
node = ast.NewNode(ast.KindPattern, nil, reuse...)
}
anyOf = appendIfUnique(anyOf, node)
}
switch {
case len(anyOf) == 1 && anyOf[0].Kind != ast.KindNothing:
result = append(result, anyOf[0])
case len(anyOf) > 1:
result = append(result, ast.NewNode(ast.KindAnyOf, nil, anyOf...))
}
if commonRightCount > 0 {
result = append(result, ast.NewNode(ast.KindPattern, nil, commonRight...))
}
return ast.NewNode(ast.KindPattern, nil, result...)
}
func commonChildren(nodes []*ast.Node) (commonLeft, commonRight []*ast.Node) {
if len(nodes) <= 1 {
return
}
// find node that has least number of children
idx := leastChildren(nodes)
if idx == -1 {
return
}
tree := nodes[idx]
treeLength := len(tree.Children)
// allocate max able size for rightCommon slice
// to get ability insert elements in reverse order (from end to start)
// without sorting
commonRight = make([]*ast.Node, treeLength)
lastRight := treeLength // will use this to get results as commonRight[lastRight:]
var (
breakLeft bool
breakRight bool
commonTotal int
)
for i, j := 0, treeLength-1; commonTotal < treeLength && j >= 0 && !(breakLeft && breakRight); i, j = i+1, j-1 {
treeLeft := tree.Children[i]
treeRight := tree.Children[j]
for k := 0; k < len(nodes) && !(breakLeft && breakRight); k++ {
// skip least children node
if k == idx {
continue
}
restLeft := nodes[k].Children[i]
restRight := nodes[k].Children[j+len(nodes[k].Children)-treeLength]
breakLeft = breakLeft || !treeLeft.Equal(restLeft)
// disable searching for right common parts, if left part is already overlapping
breakRight = breakRight || (!breakLeft && j <= i)
breakRight = breakRight || !treeRight.Equal(restRight)
}
if !breakLeft {
commonTotal++
commonLeft = append(commonLeft, treeLeft)
}
if !breakRight {
commonTotal++
lastRight = j
commonRight[j] = treeRight
}
}
commonRight = commonRight[lastRight:]
return
}
func appendIfUnique(target []*ast.Node, val *ast.Node) []*ast.Node {
for _, n := range target {
if reflect.DeepEqual(n, val) {
return target
}
}
return append(target, val)
}
func areOfSameKind(nodes []*ast.Node, kind ast.Kind) bool {
for _, n := range nodes {
if n.Kind != kind {
return false
}
}
return true
}
func leastChildren(nodes []*ast.Node) int {
min := -1
idx := -1
for i, n := range nodes {
if idx == -1 || (len(n.Children) < min) {
min = len(n.Children)
idx = i
}
}
return idx
}
func compileTreeChildren(tree *ast.Node, sep []rune) ([]match.Matcher, error) {
var matchers []match.Matcher
for _, desc := range tree.Children {
m, err := compile(desc, sep)
if err != nil {
return nil, err
}
matchers = append(matchers, optimizeMatcher(m))
}
return matchers, nil
}
func compile(tree *ast.Node, sep []rune) (m match.Matcher, err error) {
switch tree.Kind {
case ast.KindAnyOf:
// todo this could be faster on pattern_alternatives_combine_lite (see glob_test.go)
if n := minimizeTree(tree); n != nil {
return compile(n, sep)
}
matchers, err := compileTreeChildren(tree, sep)
if err != nil {
return nil, err
}
return match.NewAnyOf(matchers...), nil
case ast.KindPattern:
if len(tree.Children) == 0 {
return match.NewNothing(), nil
}
matchers, err := compileTreeChildren(tree, sep)
if err != nil {
return nil, err
}
m, err = compileMatchers(minimizeMatchers(matchers))
if err != nil {
return nil, err
}
case ast.KindAny:
m = match.NewAny(sep)
case ast.KindSuper:
m = match.NewSuper()
case ast.KindSingle:
m = match.NewSingle(sep)
case ast.KindNothing:
m = match.NewNothing()
case ast.KindList:
l := tree.Value.(ast.List)
m = match.NewList([]rune(l.Chars), l.Not)
case ast.KindRange:
r := tree.Value.(ast.Range)
m = match.NewRange(r.Lo, r.Hi, r.Not)
case ast.KindText:
t := tree.Value.(ast.Text)
m = match.NewText(t.Text)
default:
return nil, fmt.Errorf("could not compile tree: unknown node type")
}
return optimizeMatcher(m), nil
}
func Compile(tree *ast.Node, sep []rune) (match.Matcher, error) {
m, err := compile(tree, sep)
if err != nil {
return nil, err
}
return m, nil
}