lib/ReaderWriter/MachO/MachONormalizedFileBinaryUtils.h - llvm-project/lld - Git at Google

 //===- lib/ReaderWriter/MachO/MachONormalizedFileBinaryUtils.h ------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLD_READER_WRITER_MACHO_NORMALIZED_FILE_BINARY_UTILS_H
 #define LLD_READER_WRITER_MACHO_NORMALIZED_FILE_BINARY_UTILS_H

 #include "MachONormalizedFile.h"
 #include "lld/Common/LLVM.h"
 #include "lld/Core/Error.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/BinaryFormat/MachO.h"
 #include "llvm/Support/Casting.h"
 #include "llvm/Support/Endian.h"
 #include "llvm/Support/ErrorHandling.h"
 #include "llvm/Support/Host.h"
 #include "llvm/Support/LEB128.h"
 #include <system_error>

 namespace lld {
 namespace mach_o {
 namespace normalized {

 class ByteBuffer {
 public:
   ByteBuffer() : _ostream(_bytes) { }

   void append_byte(uint8_t b) {
     _ostream << b;
   }
   void append_uleb128(uint64_t value) {
     llvm::encodeULEB128(value, _ostream);
   }
   void append_uleb128Fixed(uint64_t value, unsigned byteCount) {
     unsigned min = llvm::getULEB128Size(value);
     assert(min <= byteCount);
     unsigned pad = byteCount - min;
     llvm::encodeULEB128(value, _ostream, pad);
   }
   void append_sleb128(int64_t value) {
     llvm::encodeSLEB128(value, _ostream);
   }
   void append_string(StringRef str) {
     _ostream << str;
     append_byte(0);
   }
   void align(unsigned alignment) {
     while ( (_ostream.tell() % alignment) != 0 )
       append_byte(0);
   }
   size_t size() {
     return _ostream.tell();
   }
   const uint8_t *bytes() {
     return reinterpret_cast<const uint8_t*>(_ostream.str().data());
   }

 private:
   SmallVector<char, 128>        _bytes;
   // Stream ivar must be after SmallVector ivar to construct properly.
   llvm::raw_svector_ostream     _ostream;
 };

 using namespace llvm::support::endian;
 using llvm::sys::getSwappedBytes;

 template<typename T>
 static inline uint16_t read16(const T *loc, bool isBig) {
   assert((uint64_t)loc % alignof(T) == 0 && "invalid pointer alignment");
   return isBig ? read16be(loc) : read16le(loc);
 }

 template<typename T>
 static inline uint32_t read32(const T *loc, bool isBig) {
   assert((uint64_t)loc % alignof(T) == 0 && "invalid pointer alignment");
   return isBig ? read32be(loc) : read32le(loc);
 }

 template<typename T>
 static inline uint64_t read64(const T *loc, bool isBig) {
   assert((uint64_t)loc % alignof(T) == 0 && "invalid pointer alignment");
   return isBig ? read64be(loc) : read64le(loc);
 }

 inline void write16(uint8_t *loc, uint16_t value, bool isBig) {
   if (isBig)
     write16be(loc, value);
   else
     write16le(loc, value);
 }

 inline void write32(uint8_t *loc, uint32_t value, bool isBig) {
   if (isBig)
     write32be(loc, value);
   else
     write32le(loc, value);
 }

 inline void write64(uint8_t *loc, uint64_t value, bool isBig) {
   if (isBig)
     write64be(loc, value);
   else
     write64le(loc, value);
 }

 inline uint32_t
 bitFieldExtract(uint32_t value, bool isBigEndianBigField, uint8_t firstBit,
                                                           uint8_t bitCount) {
   const uint32_t mask = ((1<<bitCount)-1);
   const uint8_t shift = isBigEndianBigField ? (32-firstBit-bitCount) : firstBit;
   return (value >> shift) & mask;
 }

 inline void
 bitFieldSet(uint32_t &bits, bool isBigEndianBigField, uint32_t newBits,
                             uint8_t firstBit, uint8_t bitCount) {
   const uint32_t mask = ((1<<bitCount)-1);
   assert((newBits & mask) == newBits);
   const uint8_t shift = isBigEndianBigField ? (32-firstBit-bitCount) : firstBit;
   bits &= ~(mask << shift);
   bits |= (newBits << shift);
 }

 inline Relocation unpackRelocation(const llvm::MachO::any_relocation_info &r,
                                    bool isBigEndian) {
   uint32_t r0 = read32(&r.r_word0, isBigEndian);
   uint32_t r1 = read32(&r.r_word1, isBigEndian);

   Relocation result;
   if (r0 & llvm::MachO::R_SCATTERED) {
     // scattered relocation record always laid out like big endian bit field
     result.offset     = bitFieldExtract(r0, true, 8, 24);
     result.scattered  = true;
     result.type       = (RelocationInfoType)
                         bitFieldExtract(r0, true, 4, 4);
     result.length     = bitFieldExtract(r0, true, 2, 2);
     result.pcRel      = bitFieldExtract(r0, true, 1, 1);
     result.isExtern   = false;
     result.value      = r1;
     result.symbol     = 0;
   } else {
     result.offset     = r0;
     result.scattered  = false;
     result.type       = (RelocationInfoType)
                         bitFieldExtract(r1, isBigEndian, 28, 4);
     result.length     = bitFieldExtract(r1, isBigEndian, 25, 2);
     result.pcRel      = bitFieldExtract(r1, isBigEndian, 24, 1);
     result.isExtern   = bitFieldExtract(r1, isBigEndian, 27, 1);
     result.value      = 0;
     result.symbol     = bitFieldExtract(r1, isBigEndian, 0, 24);
   }
   return result;
 }


 inline llvm::MachO::any_relocation_info
 packRelocation(const Relocation &r, bool swap, bool isBigEndian) {
   uint32_t r0 = 0;
   uint32_t r1 = 0;

   if (r.scattered) {
     r1 = r.value;
     bitFieldSet(r0, true, r.offset,    8, 24);
     bitFieldSet(r0, true, r.type,      4, 4);
     bitFieldSet(r0, true, r.length,    2, 2);
     bitFieldSet(r0, true, r.pcRel,     1, 1);
     bitFieldSet(r0, true, r.scattered, 0, 1); // R_SCATTERED
   } else {
     r0 = r.offset;
     bitFieldSet(r1, isBigEndian, r.type,     28, 4);
     bitFieldSet(r1, isBigEndian, r.isExtern, 27, 1);
     bitFieldSet(r1, isBigEndian, r.length,   25, 2);
     bitFieldSet(r1, isBigEndian, r.pcRel,    24, 1);
     bitFieldSet(r1, isBigEndian, r.symbol,   0,  24);
   }

   llvm::MachO::any_relocation_info result;
   result.r_word0 = swap ? getSwappedBytes(r0) : r0;
   result.r_word1 = swap ? getSwappedBytes(r1) : r1;
   return result;
 }

 inline StringRef getString16(const char s[16]) {
   // The StringRef(const char *) constructor passes the const char * to
   // strlen(), so we can't use this constructor here, because if there is no
   // null terminator in s, then strlen() will read past the end of the array.
   return StringRef(s, strnlen(s, 16));
 }

 inline void setString16(StringRef str, char s[16]) {
   memset(s, 0, 16);
   memcpy(s, str.begin(), (str.size() > 16) ? 16: str.size());
 }

 // Implemented in normalizedToAtoms() and used by normalizedFromAtoms() so
 // that the same table can be used to map mach-o sections to and from
 // DefinedAtom::ContentType.
 void relocatableSectionInfoForContentType(DefinedAtom::ContentType atomType,
                                           StringRef &segmentName,
                                           StringRef &sectionName,
                                           SectionType &sectionType,
                                           SectionAttr &sectionAttrs,
                                           bool &relocsToDefinedCanBeImplicit);

 } // namespace normalized
 } // namespace mach_o
 } // namespace lld

 #endif // LLD_READER_WRITER_MACHO_NORMALIZED_FILE_BINARY_UTILS_H
	//===- lib/ReaderWriter/MachO/MachONormalizedFileBinaryUtils.h ------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLD_READER_WRITER_MACHO_NORMALIZED_FILE_BINARY_UTILS_H
	#define LLD_READER_WRITER_MACHO_NORMALIZED_FILE_BINARY_UTILS_H

	#include "MachONormalizedFile.h"
	#include "lld/Common/LLVM.h"
	#include "lld/Core/Error.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/BinaryFormat/MachO.h"
	#include "llvm/Support/Casting.h"
	#include "llvm/Support/Endian.h"
	#include "llvm/Support/ErrorHandling.h"
	#include "llvm/Support/Host.h"
	#include "llvm/Support/LEB128.h"
	#include <system_error>

	namespace lld {
	namespace mach_o {
	namespace normalized {

	class ByteBuffer {
	public:
	ByteBuffer() : _ostream(_bytes) { }

	void append_byte(uint8_t b) {
	_ostream << b;
	}
	void append_uleb128(uint64_t value) {
	llvm::encodeULEB128(value, _ostream);
	}
	void append_uleb128Fixed(uint64_t value, unsigned byteCount) {
	unsigned min = llvm::getULEB128Size(value);
	assert(min <= byteCount);
	unsigned pad = byteCount - min;
	llvm::encodeULEB128(value, _ostream, pad);
	}
	void append_sleb128(int64_t value) {
	llvm::encodeSLEB128(value, _ostream);
	}
	void append_string(StringRef str) {
	_ostream << str;
	append_byte(0);
	}
	void align(unsigned alignment) {
	while ( (_ostream.tell() % alignment) != 0 )
	append_byte(0);
	}
	size_t size() {
	return _ostream.tell();
	}
	const uint8_t *bytes() {
	return reinterpret_cast<const uint8_t*>(_ostream.str().data());
	}

	private:
	SmallVector<char, 128> _bytes;
	// Stream ivar must be after SmallVector ivar to construct properly.
	llvm::raw_svector_ostream _ostream;
	};

	using namespace llvm::support::endian;
	using llvm::sys::getSwappedBytes;

	template<typename T>
	static inline uint16_t read16(const T *loc, bool isBig) {
	assert((uint64_t)loc % alignof(T) == 0 && "invalid pointer alignment");
	return isBig ? read16be(loc) : read16le(loc);
	}

	template<typename T>
	static inline uint32_t read32(const T *loc, bool isBig) {
	assert((uint64_t)loc % alignof(T) == 0 && "invalid pointer alignment");
	return isBig ? read32be(loc) : read32le(loc);
	}

	template<typename T>
	static inline uint64_t read64(const T *loc, bool isBig) {
	assert((uint64_t)loc % alignof(T) == 0 && "invalid pointer alignment");
	return isBig ? read64be(loc) : read64le(loc);
	}

	inline void write16(uint8_t *loc, uint16_t value, bool isBig) {
	if (isBig)
	write16be(loc, value);
	else
	write16le(loc, value);
	}

	inline void write32(uint8_t *loc, uint32_t value, bool isBig) {
	if (isBig)
	write32be(loc, value);
	else
	write32le(loc, value);
	}

	inline void write64(uint8_t *loc, uint64_t value, bool isBig) {
	if (isBig)
	write64be(loc, value);
	else
	write64le(loc, value);
	}

	inline uint32_t
	bitFieldExtract(uint32_t value, bool isBigEndianBigField, uint8_t firstBit,
	uint8_t bitCount) {
	const uint32_t mask = ((1<<bitCount)-1);
	const uint8_t shift = isBigEndianBigField ? (32-firstBit-bitCount) : firstBit;
	return (value >> shift) & mask;
	}

	inline void
	bitFieldSet(uint32_t &bits, bool isBigEndianBigField, uint32_t newBits,
	uint8_t firstBit, uint8_t bitCount) {
	const uint32_t mask = ((1<<bitCount)-1);
	assert((newBits & mask) == newBits);
	const uint8_t shift = isBigEndianBigField ? (32-firstBit-bitCount) : firstBit;
	bits &= ~(mask << shift);
	bits \|= (newBits << shift);
	}

	inline Relocation unpackRelocation(const llvm::MachO::any_relocation_info &r,
	bool isBigEndian) {
	uint32_t r0 = read32(&r.r_word0, isBigEndian);
	uint32_t r1 = read32(&r.r_word1, isBigEndian);

	Relocation result;
	if (r0 & llvm::MachO::R_SCATTERED) {
	// scattered relocation record always laid out like big endian bit field
	result.offset = bitFieldExtract(r0, true, 8, 24);
	result.scattered = true;
	result.type = (RelocationInfoType)
	bitFieldExtract(r0, true, 4, 4);
	result.length = bitFieldExtract(r0, true, 2, 2);
	result.pcRel = bitFieldExtract(r0, true, 1, 1);
	result.isExtern = false;
	result.value = r1;
	result.symbol = 0;
	} else {
	result.offset = r0;
	result.scattered = false;
	result.type = (RelocationInfoType)
	bitFieldExtract(r1, isBigEndian, 28, 4);
	result.length = bitFieldExtract(r1, isBigEndian, 25, 2);
	result.pcRel = bitFieldExtract(r1, isBigEndian, 24, 1);
	result.isExtern = bitFieldExtract(r1, isBigEndian, 27, 1);
	result.value = 0;
	result.symbol = bitFieldExtract(r1, isBigEndian, 0, 24);
	}
	return result;
	}


	inline llvm::MachO::any_relocation_info
	packRelocation(const Relocation &r, bool swap, bool isBigEndian) {
	uint32_t r0 = 0;
	uint32_t r1 = 0;

	if (r.scattered) {
	r1 = r.value;
	bitFieldSet(r0, true, r.offset, 8, 24);
	bitFieldSet(r0, true, r.type, 4, 4);
	bitFieldSet(r0, true, r.length, 2, 2);
	bitFieldSet(r0, true, r.pcRel, 1, 1);
	bitFieldSet(r0, true, r.scattered, 0, 1); // R_SCATTERED
	} else {
	r0 = r.offset;
	bitFieldSet(r1, isBigEndian, r.type, 28, 4);
	bitFieldSet(r1, isBigEndian, r.isExtern, 27, 1);
	bitFieldSet(r1, isBigEndian, r.length, 25, 2);
	bitFieldSet(r1, isBigEndian, r.pcRel, 24, 1);
	bitFieldSet(r1, isBigEndian, r.symbol, 0, 24);
	}

	llvm::MachO::any_relocation_info result;
	result.r_word0 = swap ? getSwappedBytes(r0) : r0;
	result.r_word1 = swap ? getSwappedBytes(r1) : r1;
	return result;
	}

	inline StringRef getString16(const char s[16]) {
	// The StringRef(const char ) constructor passes the const char to
	// strlen(), so we can't use this constructor here, because if there is no
	// null terminator in s, then strlen() will read past the end of the array.
	return StringRef(s, strnlen(s, 16));
	}

	inline void setString16(StringRef str, char s[16]) {
	memset(s, 0, 16);
	memcpy(s, str.begin(), (str.size() > 16) ? 16: str.size());
	}

	// Implemented in normalizedToAtoms() and used by normalizedFromAtoms() so
	// that the same table can be used to map mach-o sections to and from
	// DefinedAtom::ContentType.
	void relocatableSectionInfoForContentType(DefinedAtom::ContentType atomType,
	StringRef &segmentName,
	StringRef &sectionName,
	SectionType &sectionType,
	SectionAttr &sectionAttrs,
	bool &relocsToDefinedCanBeImplicit);

	} // namespace normalized
	} // namespace mach_o
	} // namespace lld

	#endif // LLD_READER_WRITER_MACHO_NORMALIZED_FILE_BINARY_UTILS_H