// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef BASE_BIG_ENDIAN_H_ #define BASE_BIG_ENDIAN_H_ #include #include #include #include "base/base_export.h" #include "base/strings/string_piece.h" namespace base { // Read an integer (signed or unsigned) from |buf| in Big Endian order. // Note: this loop is unrolled with -O1 and above. // NOTE(szym): glibc dns-canon.c use ntohs(*(uint16_t*)ptr) which is // potentially unaligned. // This would cause SIGBUS on ARMv5 or earlier and ARMv6-M. template inline void ReadBigEndian(const char buf[], T* out) { static_assert(std::is_integral::value, "T has to be an integral type."); // Make an unsigned version of the output type to make shift possible // without UB. typename std::make_unsigned::type unsigned_result = uint8_t{buf[0]}; for (size_t i = 1; i < sizeof(T); ++i) { unsigned_result <<= 8; // Must cast to uint8_t to avoid clobbering by sign extension. unsigned_result |= static_cast(buf[i]); } *out = unsigned_result; } // Write an integer (signed or unsigned) |val| to |buf| in Big Endian order. // Note: this loop is unrolled with -O1 and above. template inline void WriteBigEndian(char buf[], T val) { static_assert(std::is_integral::value, "T has to be an integral type."); auto unsigned_val = static_cast::type>(val); for (size_t i = 0; i < sizeof(T); ++i) { buf[sizeof(T) - i - 1] = static_cast(unsigned_val & 0xFF); unsigned_val >>= 8; } } // Specializations to make clang happy about the (dead code) shifts above. template <> inline void ReadBigEndian(const char buf[], uint8_t* out) { *out = buf[0]; } template <> inline void WriteBigEndian(char buf[], uint8_t val) { buf[0] = static_cast(val); } template <> inline void ReadBigEndian(const char buf[], int8_t* out) { *out = buf[0]; } template <> inline void WriteBigEndian(char buf[], int8_t val) { buf[0] = static_cast(val); } // Allows reading integers in network order (big endian) while iterating over // an underlying buffer. All the reading functions advance the internal pointer. class BASE_EXPORT BigEndianReader { public: BigEndianReader(const char* buf, size_t len); const char* ptr() const { return ptr_; } size_t remaining() const { return end_ - ptr_; } bool Skip(size_t len); bool ReadBytes(void* out, size_t len); // Creates a StringPiece in |out| that points to the underlying buffer. bool ReadPiece(base::StringPiece* out, size_t len); bool ReadU8(uint8_t* value); bool ReadU16(uint16_t* value); bool ReadU32(uint32_t* value); bool ReadU64(uint64_t* value); // Reads a length-prefixed region: // 1. reads a big-endian length L from the buffer; // 2. sets |*out| to a StringPiece over the next L many bytes // of the buffer (beyond the end of the bytes encoding the length); and // 3. skips the main reader past this L-byte substring. // // Fails if reading a U8 or U16 fails, or if the parsed length is greater // than the number of bytes remaining in the stream. // // On failure, leaves the stream at the same position // as before the call. bool ReadU8LengthPrefixed(base::StringPiece* out); bool ReadU16LengthPrefixed(base::StringPiece* out); private: // Hidden to promote type safety. template bool Read(T* v); template bool ReadLengthPrefixed(base::StringPiece* out); const char* ptr_; const char* end_; }; // Allows writing integers in network order (big endian) while iterating over // an underlying buffer. All the writing functions advance the internal pointer. class BASE_EXPORT BigEndianWriter { public: BigEndianWriter(char* buf, size_t len); char* ptr() const { return ptr_; } size_t remaining() const { return end_ - ptr_; } bool Skip(size_t len); bool WriteBytes(const void* buf, size_t len); bool WriteU8(uint8_t value); bool WriteU16(uint16_t value); bool WriteU32(uint32_t value); bool WriteU64(uint64_t value); private: // Hidden to promote type safety. template bool Write(T v); char* ptr_; char* end_; }; } // namespace base #endif // BASE_BIG_ENDIAN_H_