0
0
Fork 0
mirror of https://github.com/matrix-construct/construct synced 2024-11-18 07:50:57 +01:00
construct/include/ircd/cbor/cbor.h
2018-08-11 00:42:08 -07:00

309 lines
6.3 KiB
C++

// Matrix Construct
//
// Copyright (C) Matrix Construct Developers, Authors & Contributors
// Copyright (C) 2016-2018 Jason Volk <jason@zemos.net>
//
// Permission to use, copy, modify, and/or distribute this software for any
// purpose with or without fee is hereby granted, provided that the above
// copyright notice and this permission notice is present in all copies. The
// full license for this software is available in the LICENSE file.
#pragma once
#define HAVE_IRCD_CBOR_H
/// Concise Binary Object Representation (RFC7049)
///
namespace ircd::cbor
{
IRCD_EXCEPTION(ircd::error, error);
IRCD_EXCEPTION(error, type_error);
IRCD_EXCEPTION(error, parse_error);
IRCD_EXCEPTION(parse_error, buffer_underrun);
struct positive;
struct negative;
struct binary;
struct string;
struct array;
struct object;
struct tag;
struct primitive;
enum major :uint8_t;
enum minor :uint8_t;
struct head;
struct item;
string_view reflect(const enum major &);
enum major major(const const_buffer &);
}
/// Item head.
///
/// This object represents the head byte and any following-integer bytes under
/// its const_buffer. If the major type has a payload, it starts immediately
/// following the end of this object's buffer. The first byte of this object's
/// buffer is the leading head byte. This object's buffer will never be empty()
/// unless it's default-initialized (i.e not pointing at anything).
///
/// This is used to query information about the item from the head data.
///
struct ircd::cbor::head
:const_buffer
{
static uint8_t major(const uint8_t &); // Major type
static uint8_t minor(const uint8_t &); // Minor type
static size_t length(const uint8_t &); // (1 + size(following()))
// Member ops when buffer has >= 1 byte
const uint8_t &leading() const; // Reference the leading byte
enum major major() const; // major(leading())
enum minor minor() const; // minor(leading())
size_t length() const; // length(leading())
// Get bytes following leading byte based on major/minor
const_buffer following() const;
template<class T> const T &following() const;
// Construct from at least first byte of item or more
head(const const_buffer &);
head() = default;
head(head &&) = default;
head(const head &) = default;
};
/// Abstract item
///
struct ircd::cbor::item
:const_buffer
{
operator head() const;
const_buffer value() const;
item(const const_buffer &buf);
item() = default;
};
/// Positive integer item.
///
/// Represents a positive integer item. This is a buffer spanning the item,
/// which is same span as the cbor::head buffer because positive integer items
/// only have a payload of an integer item within or following the leading head
/// byte.
///
/// The integer value is returned through the cast operator.
///
struct ircd::cbor::positive
:item
{
uint64_t value() const;
operator uint64_t() const;
positive(const head &);
positive() = default;
};
/// Negative integer item.
///
/// This is similar to cbor::positive except that the integer returned is signed
/// and computed from 1 - cbor::positive(buf).
///
struct ircd::cbor::negative
:positive
{
int64_t value() const;
operator int64_t() const;
negative(const head &);
negative() = default;
};
/// Binary buffer item
///
///
struct ircd::cbor::binary
:positive
{
const_buffer value() const;
binary(const const_buffer &);
};
struct ircd::cbor::string
:binary
{
string_view value() const;
explicit operator string_view() const;
string(const const_buffer &);
};
struct ircd::cbor::array
:item
{
struct const_iterator;
size_t count() const;
const_buffer value() const;
const_iterator begin() const;
const_iterator end() const;
item operator[](size_t i) const;
array(const const_buffer &);
};
struct ircd::cbor::array::const_iterator
{
cbor::array array;
const_buffer state;
public:
bool operator!() const
{
return ircd::empty(state);
}
explicit operator bool() const
{
return !operator!();
}
const const_buffer &operator*() const
{
return state;
}
const const_buffer *operator->() const
{
return &state;
}
const_iterator &operator++();
const_iterator(const cbor::array &);
};
struct ircd::cbor::object
:item
{
struct member;
struct const_iterator;
size_t count() const;
const_buffer value() const;
member operator[](const string_view &name) const;
object(const const_buffer &);
};
struct ircd::cbor::object::member
:std::pair<item, item>
{
using std::pair<item, item>::pair;
};
struct ircd::cbor::object::const_iterator
{
cbor::object object;
member state;
public:
bool operator!() const
{
return ircd::empty(state.first);
}
explicit operator bool() const
{
return !operator!();
}
const member &operator*() const
{
return state;
}
const member *operator->() const
{
return &state;
}
const_iterator &operator++();
const_iterator(const cbor::object &);
};
/*
union ircd::cbor::primitive
{
bool ud;
bool nul;
bool boolean;
float fsingle;
double fdouble;
};
struct ircd::cbor::item
:const_buffer
{
item(const const_buffer &);
item() = default;
friend enum major major(const item &);
};
struct ircd::cbor::binary
:const_buffer
{
binary(const item &);
};
struct ircd::cbor::object
:const_buffer
{
using member = std::pair<item, item>;
using const_buffer::const_buffer;
object(const item &);
};
struct ircd::cbor::tag
:const_buffer
{
using const_buffer::const_buffer;
tag(const item &);
};
*/
enum ircd::cbor::major
:uint8_t
{
POSITIVE = 0, ///< Z*
NEGATIVE = 1, ///< Z-
BINARY = 2, ///< Raw byte sequence
STRING = 3, ///< UTF-8 character sequence
ARRAY = 4, ///< Array of items
OBJECT = 5, ///< Dictionary of items
TAG = 6, ///< CBOR extensions (IANA registered)
PRIMITIVE = 7, ///< Literals / floats
};
enum ircd::cbor::minor
:uint8_t
{
FALSE = 20, ///< False
TRUE = 21, ///< True
NUL = 22, ///< Null
UD = 23, ///< Undefined value
U8 = 24, ///< 8 bits follow
U16 = 25, ///< 16 bits follow
F16 = 25, ///< IEEE754 half-precision (16 bits follow)
U32 = 26, ///< 32 bits follow
F32 = 26, ///< IEEE754 single-precision (32 bits follow)
U64 = 27, ///< 64 bits follow
F64 = 27, ///< IEEE754 double-precision (64 bits follow)
STREAM = 31, ///< Variable length (terminated by BREAK)
BREAK = 31, ///< Terminator code
};