//===- Endian.h - Utilities for IO with endian specific data ----*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file declares generic functions to read and write endian specific data. // //===----------------------------------------------------------------------===// #ifndef LLVM_SUPPORT_ENDIAN_H #define LLVM_SUPPORT_ENDIAN_H #include "llvm/Support/AlignOf.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Host.h" #include "llvm/Support/SwapByteOrder.h" #include <cassert> #include <cstddef> #include <cstdint> #include <cstring> #include <type_traits> namespace llvm { namespace support { enum endianness {big, little, native}; // These are named values for common alignments. enum {aligned = 0, unaligned = 1}; namespace detail { /// ::value is either alignment, or alignof(T) if alignment is 0. template<class T, int alignment> struct PickAlignment { enum { value = alignment == 0 ? alignof(T) : alignment }; }; } // end namespace detail namespace endian { constexpr endianness system_endianness() { return sys::IsBigEndianHost ? big : little; } template <typename value_type> inline value_type byte_swap(value_type value, endianness endian) { if ((endian != native) && (endian != system_endianness())) sys::swapByteOrder(value); return value; } /// Swap the bytes of value to match the given endianness. template<typename value_type, endianness endian> inline value_type byte_swap(value_type value) { return byte_swap(value, endian); } /// Read a value of a particular endianness from memory. template <typename value_type, std::size_t alignment> inline value_type read(const void *memory, endianness endian) { value_type ret; memcpy(&ret, LLVM_ASSUME_ALIGNED( memory, (detail::PickAlignment<value_type, alignment>::value)), sizeof(value_type)); return byte_swap<value_type>(ret, endian); } template<typename value_type, endianness endian, std::size_t alignment> inline value_type read(const void *memory) { return read<value_type, alignment>(memory, endian); } /// Read a value of a particular endianness from a buffer, and increment the /// buffer past that value. template <typename value_type, std::size_t alignment, typename CharT> inline value_type readNext(const CharT *&memory, endianness endian) { value_type ret = read<value_type, alignment>(memory, endian); memory += sizeof(value_type); return ret; } template<typename value_type, endianness endian, std::size_t alignment, typename CharT> inline value_type readNext(const CharT *&memory) { return readNext<value_type, alignment, CharT>(memory, endian); } /// Write a value to memory with a particular endianness. template <typename value_type, std::size_t alignment> inline void write(void *memory, value_type value, endianness endian) { value = byte_swap<value_type>(value, endian); memcpy(LLVM_ASSUME_ALIGNED( memory, (detail::PickAlignment<value_type, alignment>::value)), &value, sizeof(value_type)); } template<typename value_type, endianness endian, std::size_t alignment> inline void write(void *memory, value_type value) { write<value_type, alignment>(memory, value, endian); } template <typename value_type> using make_unsigned_t = typename std::make_unsigned<value_type>::type; /// Read a value of a particular endianness from memory, for a location /// that starts at the given bit offset within the first byte. template <typename value_type, endianness endian, std::size_t alignment> inline value_type readAtBitAlignment(const void *memory, uint64_t startBit) { assert(startBit < 8); if (startBit == 0) return read<value_type, endian, alignment>(memory); else { // Read two values and compose the result from them. value_type val[2]; memcpy(&val[0], LLVM_ASSUME_ALIGNED( memory, (detail::PickAlignment<value_type, alignment>::value)), sizeof(value_type) * 2); val[0] = byte_swap<value_type, endian>(val[0]); val[1] = byte_swap<value_type, endian>(val[1]); // Shift bits from the lower value into place. make_unsigned_t<value_type> lowerVal = val[0] >> startBit; // Mask off upper bits after right shift in case of signed type. make_unsigned_t<value_type> numBitsFirstVal = (sizeof(value_type) * 8) - startBit; lowerVal &= ((make_unsigned_t<value_type>)1 << numBitsFirstVal) - 1; // Get the bits from the upper value. make_unsigned_t<value_type> upperVal = val[1] & (((make_unsigned_t<value_type>)1 << startBit) - 1); // Shift them in to place. upperVal <<= numBitsFirstVal; return lowerVal | upperVal; } } /// Write a value to memory with a particular endianness, for a location /// that starts at the given bit offset within the first byte. template <typename value_type, endianness endian, std::size_t alignment> inline void writeAtBitAlignment(void *memory, value_type value, uint64_t startBit) { assert(startBit < 8); if (startBit == 0) write<value_type, endian, alignment>(memory, value); else { // Read two values and shift the result into them. value_type val[2]; memcpy(&val[0], LLVM_ASSUME_ALIGNED( memory, (detail::PickAlignment<value_type, alignment>::value)), sizeof(value_type) * 2); val[0] = byte_swap<value_type, endian>(val[0]); val[1] = byte_swap<value_type, endian>(val[1]); // Mask off any existing bits in the upper part of the lower value that // we want to replace. val[0] &= ((make_unsigned_t<value_type>)1 << startBit) - 1; make_unsigned_t<value_type> numBitsFirstVal = (sizeof(value_type) * 8) - startBit; make_unsigned_t<value_type> lowerVal = value; if (startBit > 0) { // Mask off the upper bits in the new value that are not going to go into // the lower value. This avoids a left shift of a negative value, which // is undefined behavior. lowerVal &= (((make_unsigned_t<value_type>)1 << numBitsFirstVal) - 1); // Now shift the new bits into place lowerVal <<= startBit; } val[0] |= lowerVal; // Mask off any existing bits in the lower part of the upper value that // we want to replace. val[1] &= ~(((make_unsigned_t<value_type>)1 << startBit) - 1); // Next shift the bits that go into the upper value into position. make_unsigned_t<value_type> upperVal = value >> numBitsFirstVal; // Mask off upper bits after right shift in case of signed type. upperVal &= ((make_unsigned_t<value_type>)1 << startBit) - 1; val[1] |= upperVal; // Finally, rewrite values. val[0] = byte_swap<value_type, endian>(val[0]); val[1] = byte_swap<value_type, endian>(val[1]); memcpy(LLVM_ASSUME_ALIGNED( memory, (detail::PickAlignment<value_type, alignment>::value)), &val[0], sizeof(value_type) * 2); } } } // end namespace endian namespace detail { template<typename value_type, endianness endian, std::size_t alignment> struct packed_endian_specific_integral { packed_endian_specific_integral() = default; explicit packed_endian_specific_integral(value_type val) { *this = val; } operator value_type() const { return endian::read<value_type, endian, alignment>( (const void*)Value.buffer); } void operator=(value_type newValue) { endian::write<value_type, endian, alignment>( (void*)Value.buffer, newValue); } packed_endian_specific_integral &operator+=(value_type newValue) { *this = *this + newValue; return *this; } packed_endian_specific_integral &operator-=(value_type newValue) { *this = *this - newValue; return *this; } packed_endian_specific_integral &operator|=(value_type newValue) { *this = *this | newValue; return *this; } packed_endian_specific_integral &operator&=(value_type newValue) { *this = *this & newValue; return *this; } private: AlignedCharArray<PickAlignment<value_type, alignment>::value, sizeof(value_type)> Value; public: struct ref { explicit ref(void *Ptr) : Ptr(Ptr) {} operator value_type() const { return endian::read<value_type, endian, alignment>(Ptr); } void operator=(value_type NewValue) { endian::write<value_type, endian, alignment>(Ptr, NewValue); } private: void *Ptr; }; }; } // end namespace detail using ulittle16_t = detail::packed_endian_specific_integral<uint16_t, little, unaligned>; using ulittle32_t = detail::packed_endian_specific_integral<uint32_t, little, unaligned>; using ulittle64_t = detail::packed_endian_specific_integral<uint64_t, little, unaligned>; using little16_t = detail::packed_endian_specific_integral<int16_t, little, unaligned>; using little32_t = detail::packed_endian_specific_integral<int32_t, little, unaligned>; using little64_t = detail::packed_endian_specific_integral<int64_t, little, unaligned>; using aligned_ulittle16_t = detail::packed_endian_specific_integral<uint16_t, little, aligned>; using aligned_ulittle32_t = detail::packed_endian_specific_integral<uint32_t, little, aligned>; using aligned_ulittle64_t = detail::packed_endian_specific_integral<uint64_t, little, aligned>; using aligned_little16_t = detail::packed_endian_specific_integral<int16_t, little, aligned>; using aligned_little32_t = detail::packed_endian_specific_integral<int32_t, little, aligned>; using aligned_little64_t = detail::packed_endian_specific_integral<int64_t, little, aligned>; using ubig16_t = detail::packed_endian_specific_integral<uint16_t, big, unaligned>; using ubig32_t = detail::packed_endian_specific_integral<uint32_t, big, unaligned>; using ubig64_t = detail::packed_endian_specific_integral<uint64_t, big, unaligned>; using big16_t = detail::packed_endian_specific_integral<int16_t, big, unaligned>; using big32_t = detail::packed_endian_specific_integral<int32_t, big, unaligned>; using big64_t = detail::packed_endian_specific_integral<int64_t, big, unaligned>; using aligned_ubig16_t = detail::packed_endian_specific_integral<uint16_t, big, aligned>; using aligned_ubig32_t = detail::packed_endian_specific_integral<uint32_t, big, aligned>; using aligned_ubig64_t = detail::packed_endian_specific_integral<uint64_t, big, aligned>; using aligned_big16_t = detail::packed_endian_specific_integral<int16_t, big, aligned>; using aligned_big32_t = detail::packed_endian_specific_integral<int32_t, big, aligned>; using aligned_big64_t = detail::packed_endian_specific_integral<int64_t, big, aligned>; using unaligned_uint16_t = detail::packed_endian_specific_integral<uint16_t, native, unaligned>; using unaligned_uint32_t = detail::packed_endian_specific_integral<uint32_t, native, unaligned>; using unaligned_uint64_t = detail::packed_endian_specific_integral<uint64_t, native, unaligned>; using unaligned_int16_t = detail::packed_endian_specific_integral<int16_t, native, unaligned>; using unaligned_int32_t = detail::packed_endian_specific_integral<int32_t, native, unaligned>; using unaligned_int64_t = detail::packed_endian_specific_integral<int64_t, native, unaligned>; namespace endian { template <typename T> inline T read(const void *P, endianness E) { return read<T, unaligned>(P, E); } template <typename T, endianness E> inline T read(const void *P) { return *(const detail::packed_endian_specific_integral<T, E, unaligned> *)P; } inline uint16_t read16(const void *P, endianness E) { return read<uint16_t>(P, E); } inline uint32_t read32(const void *P, endianness E) { return read<uint32_t>(P, E); } inline uint64_t read64(const void *P, endianness E) { return read<uint64_t>(P, E); } template <endianness E> inline uint16_t read16(const void *P) { return read<uint16_t, E>(P); } template <endianness E> inline uint32_t read32(const void *P) { return read<uint32_t, E>(P); } template <endianness E> inline uint64_t read64(const void *P) { return read<uint64_t, E>(P); } inline uint16_t read16le(const void *P) { return read16<little>(P); } inline uint32_t read32le(const void *P) { return read32<little>(P); } inline uint64_t read64le(const void *P) { return read64<little>(P); } inline uint16_t read16be(const void *P) { return read16<big>(P); } inline uint32_t read32be(const void *P) { return read32<big>(P); } inline uint64_t read64be(const void *P) { return read64<big>(P); } template <typename T> inline void write(void *P, T V, endianness E) { write<T, unaligned>(P, V, E); } template <typename T, endianness E> inline void write(void *P, T V) { *(detail::packed_endian_specific_integral<T, E, unaligned> *)P = V; } inline void write16(void *P, uint16_t V, endianness E) { write<uint16_t>(P, V, E); } inline void write32(void *P, uint32_t V, endianness E) { write<uint32_t>(P, V, E); } inline void write64(void *P, uint64_t V, endianness E) { write<uint64_t>(P, V, E); } template <endianness E> inline void write16(void *P, uint16_t V) { write<uint16_t, E>(P, V); } template <endianness E> inline void write32(void *P, uint32_t V) { write<uint32_t, E>(P, V); } template <endianness E> inline void write64(void *P, uint64_t V) { write<uint64_t, E>(P, V); } inline void write16le(void *P, uint16_t V) { write16<little>(P, V); } inline void write32le(void *P, uint32_t V) { write32<little>(P, V); } inline void write64le(void *P, uint64_t V) { write64<little>(P, V); } inline void write16be(void *P, uint16_t V) { write16<big>(P, V); } inline void write32be(void *P, uint32_t V) { write32<big>(P, V); } inline void write64be(void *P, uint64_t V) { write64<big>(P, V); } } // end namespace endian } // end namespace support } // end namespace llvm #endif // LLVM_SUPPORT_ENDIAN_H