tools/relocation_packer/src/sleb128.cc - mirrors/engine - Git at Google

 // 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.

 #include "sleb128.h"

 #include <limits.h>
 #include <stdint.h>
 #include <vector>

 #include "elf_traits.h"

 namespace relocation_packer {

 // Empty constructor and destructor to silence chromium-style.
 Sleb128Encoder::Sleb128Encoder() { }
 Sleb128Encoder::~Sleb128Encoder() { }

 // Add a single value to the encoding.  Values are encoded with variable
 // length.  The least significant 7 bits of each byte hold 7 bits of data,
 // and the most significant bit is set on each byte except the last.  The
 // value is sign extended up to a multiple of 7 bits (ensuring that the
 // most significant bit is zero for a positive number and one for a
 // negative number).
 void Sleb128Encoder::Enqueue(ELF::Sxword value) {
   static const size_t size = CHAR_BIT * sizeof(value);

   bool more = true;
   const bool negative = value < 0;

   while (more) {
     uint8_t byte = value & 127;
     value >>= 7;

     // Sign extend if encoding a -ve value.
     if (negative)
       value |= -(static_cast<ELF::Sxword>(1) << (size - 7));

     // The sign bit of byte is second high order bit.
     const bool sign_bit = byte & 64;
     if ((value == 0 && !sign_bit) || (value == -1 && sign_bit))
       more = false;
     else
       byte |= 128;
     encoding_.push_back(byte);
   }
 }

 // Add a vector of values to the encoding.
 void Sleb128Encoder::EnqueueAll(const std::vector<ELF::Sxword>& values) {
   for (size_t i = 0; i < values.size(); ++i)
     Enqueue(values[i]);
 }

 // Create a new decoder for the given encoded stream.
 Sleb128Decoder::Sleb128Decoder(const std::vector<uint8_t>& encoding) {
   encoding_ = encoding;
   cursor_ = 0;
 }

 // Empty destructor to silence chromium-style.
 Sleb128Decoder::~Sleb128Decoder() { }

 // Decode and retrieve a single value from the encoding.  Consume bytes
 // until one without its most significant bit is found, and re-form the
 // value from the 7 bit fields of the bytes consumed.
 ELF::Sxword Sleb128Decoder::Dequeue() {
   ELF::Sxword value = 0;
   static const size_t size = CHAR_BIT * sizeof(value);

   size_t shift = 0;
   uint8_t byte;

   // Loop until we reach a byte with its high order bit clear.
   do {
     byte = encoding_[cursor_++];
     value |= (static_cast<ELF::Sxword>(byte & 127) << shift);
     shift += 7;
   } while (byte & 128);

   // The sign bit is second high order bit of the final byte decoded.
   // Sign extend if value is -ve and we did not shift all of it.
   if (shift < size && (byte & 64))
     value |= -(static_cast<ELF::Sxword>(1) << shift);

   return value;
 }

 // Decode and retrieve all remaining values from the encoding.
 void Sleb128Decoder::DequeueAll(std::vector<ELF::Sxword>* values) {
   while (cursor_ < encoding_.size())
     values->push_back(Dequeue());
 }

 }  // namespace relocation_packer
	// 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.

	#include "sleb128.h"

	#include <limits.h>
	#include <stdint.h>
	#include <vector>

	#include "elf_traits.h"

	namespace relocation_packer {

	// Empty constructor and destructor to silence chromium-style.
	Sleb128Encoder::Sleb128Encoder() { }
	Sleb128Encoder::~Sleb128Encoder() { }

	// Add a single value to the encoding. Values are encoded with variable
	// length. The least significant 7 bits of each byte hold 7 bits of data,
	// and the most significant bit is set on each byte except the last. The
	// value is sign extended up to a multiple of 7 bits (ensuring that the
	// most significant bit is zero for a positive number and one for a
	// negative number).
	void Sleb128Encoder::Enqueue(ELF::Sxword value) {
	static const size_t size = CHAR_BIT * sizeof(value);

	bool more = true;
	const bool negative = value < 0;

	while (more) {
	uint8_t byte = value & 127;
	value >>= 7;

	// Sign extend if encoding a -ve value.
	if (negative)
	value \|= -(static_cast<ELF::Sxword>(1) << (size - 7));

	// The sign bit of byte is second high order bit.
	const bool sign_bit = byte & 64;
	if ((value == 0 && !sign_bit) \|\| (value == -1 && sign_bit))
	more = false;
	else
	byte \|= 128;
	encoding_.push_back(byte);
	}
	}

	// Add a vector of values to the encoding.
	void Sleb128Encoder::EnqueueAll(const std::vector<ELF::Sxword>& values) {
	for (size_t i = 0; i < values.size(); ++i)
	Enqueue(values[i]);
	}

	// Create a new decoder for the given encoded stream.
	Sleb128Decoder::Sleb128Decoder(const std::vector<uint8_t>& encoding) {
	encoding_ = encoding;
	cursor_ = 0;
	}

	// Empty destructor to silence chromium-style.
	Sleb128Decoder::~Sleb128Decoder() { }

	// Decode and retrieve a single value from the encoding. Consume bytes
	// until one without its most significant bit is found, and re-form the
	// value from the 7 bit fields of the bytes consumed.
	ELF::Sxword Sleb128Decoder::Dequeue() {
	ELF::Sxword value = 0;
	static const size_t size = CHAR_BIT * sizeof(value);

	size_t shift = 0;
	uint8_t byte;

	// Loop until we reach a byte with its high order bit clear.
	do {
	byte = encoding_[cursor_++];
	value \|= (static_cast<ELF::Sxword>(byte & 127) << shift);
	shift += 7;
	} while (byte & 128);

	// The sign bit is second high order bit of the final byte decoded.
	// Sign extend if value is -ve and we did not shift all of it.
	if (shift < size && (byte & 64))
	value \|= -(static_cast<ELF::Sxword>(1) << shift);

	return value;
	}

	// Decode and retrieve all remaining values from the encoding.
	void Sleb128Decoder::DequeueAll(std::vector<ELF::Sxword>* values) {
	while (cursor_ < encoding_.size())
	values->push_back(Dequeue());
	}

	} // namespace relocation_packer