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construct/ircd/cbor.cc

217 lines
5.3 KiB
C++

// Matrix Construct
//
// Copyright (C) Matrix Construct Developers, Authors & Contributors
// Copyright (C) 2016-2019 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.
/// Given a buffer of CBOR this function parses the head data and maintains
/// a const_buffer span of the head. The span includes the leading head byte
/// and one or more integer bytes following the leading byte. If the major
/// type found in this head has a data payload which is not a following-integer
/// then that data starts directly after this head buffer ends.
///
/// The argument buffer must be at least one byte and must at least cover the
/// following-integer bytes (and can also be as large as possible).
///
ircd::cbor::head::head(const const_buffer &buf)
:const_buffer{[&buf]
{
if(unlikely(size(buf) < sizeof(uint8_t)))
throw buffer_underrun
{
"Item buffer is too small to contain a header"
};
const uint8_t &leading
{
*reinterpret_cast<const uint8_t *>(data(buf))
};
return const_buffer
{
data(buf), length(leading)
};
}()}
{
if(unlikely(size(*this) > size(buf)))
throw buffer_underrun
{
"Item buffer is too small to contain full header"
};
}
/// Pun a reference to the integer contained by the bytes following the head.
/// If there are no bytes following the head because the integer is contained
/// as bits packed into the leading head byte, this function will throw.
///
template<class T>
const T &
ircd::cbor::head::following()
const
{
if(unlikely(size(following()) < sizeof(T)))
throw buffer_underrun
{
"Buffer following header is too small (%zu) for type requiring %zu",
size(following()),
sizeof(T)
};
return *reinterpret_cast<const T *>(data(following()));
}
/// Return buffer spanning the integer bytes following this head. This may be
/// an empty buffer if the integer byte is packed into bits of the leading
/// byte (denoted by minor()).
ircd::const_buffer
ircd::cbor::head::following()
const
{
return { data(*this) + 1, length() - 1 };
}
/// Extract the length of the head from the buffer (requires 1 byte of buffer)
size_t
ircd::cbor::head::length()
const
{
return length(leading());
}
/// Extract the minor type from the reference to the leading byte in the head.
enum ircd::cbor::minor
ircd::cbor::head::minor()
const
{
return static_cast<enum minor>(minor(leading()));
}
/// Extract the major type from the reference to the leading byte in the head.
enum ircd::cbor::major
ircd::cbor::head::major()
const
{
return static_cast<enum major>(major(leading()));
}
/// Reference the leading byte of the head.
const uint8_t &
ircd::cbor::head::leading()
const
{
assert(size(*this) >= sizeof(uint8_t));
return *reinterpret_cast<const uint8_t *>(data(*this));
}
/// Extract length of head from leading head byte (arg); this is the length of
/// the integer following the leading head byte plus the one leading head
/// byte. This length covers all bytes which come before item payload bytes
/// (when such a payload exists). If this length is 1 then no integer bytes
/// are following the leading head byte. The length/returned value is never 0.
size_t
ircd::cbor::head::length(const uint8_t &a)
{
switch(major(a))
{
case POSITIVE:
case NEGATIVE:
case BINARY:
case STRING:
case ARRAY:
case OBJECT:
case TAG:
{
if(minor(a) > 23) switch(minor(a))
{
case minor::U8: return 2;
case minor::U16: return 3;
case minor::U32: return 5;
case minor::U64: return 9;
default: throw type_error
{
"Unknown minor type (%u); length of header unknown", minor(a)
};
}
else return 1;
}
case PRIMITIVE:
{
if(minor(a) > 23) switch(minor(a))
{
case FALSE:
case TRUE:
case NUL:
case UD: return 1;
case minor::F16: return 3;
case minor::F32: return 5;
case minor::F64: return 9;
default: throw type_error
{
"Unknown primitive minor type (%u); length of header unknown", minor(a)
};
}
else return 1;
}
default: throw type_error
{
"Unknown major type; length of header unknown"
};
}
}
/// Extract major type from leading head byte (arg)
uint8_t
ircd::cbor::head::major(const uint8_t &a)
{
// shift for higher 3 bits only
static const int &shift(5);
return a >> shift;
}
/// Extract minor type from leading head byte (arg)
uint8_t
ircd::cbor::head::minor(const uint8_t &a)
{
// mask of lower 5 bits only
static const uint8_t &mask
{
uint8_t(0xFF) >> 3
};
return a & mask;
}
//
// cbor.h
//
enum ircd::cbor::major
ircd::cbor::major(const const_buffer &buf)
{
const head head(buf);
return head.major();
}
ircd::string_view
ircd::cbor::reflect(const enum major &major)
{
switch(major)
{
case major::POSITIVE: return "POSITIVE";
case major::NEGATIVE: return "NEGATIVE";
case major::BINARY: return "BINARY";
case major::STRING: return "STRING";
case major::ARRAY: return "ARRAY";
case major::OBJECT: return "OBJECT";
case major::TAG: return "TAG";
case major::PRIMITIVE: return "PRIMITIVE";
}
return "??????";
}