tools/relocation_packer/src/packer.cc - platform/bionic - 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 "packer.h"

 #include <vector>

 #include "debug.h"
 #include "delta_encoder.h"
 #include "elf_traits.h"
 #include "leb128.h"
 #include "run_length_encoder.h"
 #include "sleb128.h"

 namespace relocation_packer {

 // Pack relative relocations into a run-length encoded packed
 // representation.
 void RelocationPacker::PackRelativeRelocations(
     const std::vector<ELF::Rel>& relocations,
     std::vector<uint8_t>* packed) {
   // Run-length encode.
   std::vector<ELF::Xword> packed_words;
   RelocationRunLengthCodec codec;
   codec.Encode(relocations, &packed_words);

   // If insufficient data to run-length encode, do nothing.
   if (packed_words.empty())
     return;

   // LEB128 encode, with "APR1" prefix.
   Leb128Encoder encoder;
   encoder.Enqueue('A');
   encoder.Enqueue('P');
   encoder.Enqueue('R');
   encoder.Enqueue('1');
   encoder.EnqueueAll(packed_words);

   encoder.GetEncoding(packed);

   // Pad packed to a whole number of words.  This padding will decode as
   // LEB128 zeroes.  Run-length decoding ignores it because encoding
   // embeds the pairs count in the stream itself.
   while (packed->size() % sizeof(ELF::Word))
     packed->push_back(0);
 }

 // Unpack relative relocations from a run-length encoded packed
 // representation.
 void RelocationPacker::UnpackRelativeRelocations(
     const std::vector<uint8_t>& packed,
     std::vector<ELF::Rel>* relocations) {
   // LEB128 decode, after checking and stripping "APR1" prefix.
   std::vector<ELF::Xword> packed_words;
   Leb128Decoder decoder(packed);
   CHECK(decoder.Dequeue() == 'A' &&
         decoder.Dequeue() == 'P' &&
         decoder.Dequeue() == 'R' &&
         decoder.Dequeue() == '1');
   decoder.DequeueAll(&packed_words);

   // Run-length decode.
   RelocationRunLengthCodec codec;
   codec.Decode(packed_words, relocations);
 }

 // Pack relative relocations with addends into a delta encoded packed
 // representation.
 void RelocationPacker::PackRelativeRelocations(
     const std::vector<ELF::Rela>& relocations,
     std::vector<uint8_t>* packed) {
   // Delta encode.
   std::vector<ELF::Sxword> packed_words;
   RelocationDeltaCodec codec;
   codec.Encode(relocations, &packed_words);

   // If insufficient data to delta encode, do nothing.
   if (packed_words.empty())
     return;

   // Signed LEB128 encode, with "APA1" prefix.  ASCII does not encode as
   // itself under signed LEB128, so we have to treat it specially.
   Sleb128Encoder encoder;
   encoder.EnqueueAll(packed_words);
   std::vector<uint8_t> encoded;
   encoder.GetEncoding(&encoded);

   packed->push_back('A');
   packed->push_back('P');
   packed->push_back('A');
   packed->push_back('1');
   packed->insert(packed->end(), encoded.begin(), encoded.end());

   // Pad packed to a whole number of words.  This padding will decode as
   // signed LEB128 zeroes.  Delta decoding ignores it because encoding
   // embeds the pairs count in the stream itself.
   while (packed->size() % sizeof(ELF::Word))
     packed->push_back(0);
 }

 // Unpack relative relocations with addends from a delta encoded
 // packed representation.
 void RelocationPacker::UnpackRelativeRelocations(
     const std::vector<uint8_t>& packed,
     std::vector<ELF::Rela>* relocations) {
   // Check "APA1" prefix.
   CHECK(packed.at(0) == 'A' &&
         packed.at(1) == 'P' &&
         packed.at(2) == 'A' &&
         packed.at(3) == '1');

   // Signed LEB128 decode, after stripping "APA1" prefix.
   std::vector<ELF::Sxword> packed_words;
   std::vector<uint8_t> stripped(packed.begin() + 4, packed.end());
   Sleb128Decoder decoder(stripped);
   decoder.DequeueAll(&packed_words);

   // Delta decode.
   RelocationDeltaCodec codec;
   codec.Decode(packed_words, relocations);
 }

 }  // 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 "packer.h"

	#include <vector>

	#include "debug.h"
	#include "delta_encoder.h"
	#include "elf_traits.h"
	#include "leb128.h"
	#include "run_length_encoder.h"
	#include "sleb128.h"

	namespace relocation_packer {

	// Pack relative relocations into a run-length encoded packed
	// representation.
	void RelocationPacker::PackRelativeRelocations(
	const std::vector<ELF::Rel>& relocations,
	std::vector<uint8_t>* packed) {
	// Run-length encode.
	std::vector<ELF::Xword> packed_words;
	RelocationRunLengthCodec codec;
	codec.Encode(relocations, &packed_words);

	// If insufficient data to run-length encode, do nothing.
	if (packed_words.empty())
	return;

	// LEB128 encode, with "APR1" prefix.
	Leb128Encoder encoder;
	encoder.Enqueue('A');
	encoder.Enqueue('P');
	encoder.Enqueue('R');
	encoder.Enqueue('1');
	encoder.EnqueueAll(packed_words);

	encoder.GetEncoding(packed);

	// Pad packed to a whole number of words. This padding will decode as
	// LEB128 zeroes. Run-length decoding ignores it because encoding
	// embeds the pairs count in the stream itself.
	while (packed->size() % sizeof(ELF::Word))
	packed->push_back(0);
	}

	// Unpack relative relocations from a run-length encoded packed
	// representation.
	void RelocationPacker::UnpackRelativeRelocations(
	const std::vector<uint8_t>& packed,
	std::vector<ELF::Rel>* relocations) {
	// LEB128 decode, after checking and stripping "APR1" prefix.
	std::vector<ELF::Xword> packed_words;
	Leb128Decoder decoder(packed);
	CHECK(decoder.Dequeue() == 'A' &&
	decoder.Dequeue() == 'P' &&
	decoder.Dequeue() == 'R' &&
	decoder.Dequeue() == '1');
	decoder.DequeueAll(&packed_words);

	// Run-length decode.
	RelocationRunLengthCodec codec;
	codec.Decode(packed_words, relocations);
	}

	// Pack relative relocations with addends into a delta encoded packed
	// representation.
	void RelocationPacker::PackRelativeRelocations(
	const std::vector<ELF::Rela>& relocations,
	std::vector<uint8_t>* packed) {
	// Delta encode.
	std::vector<ELF::Sxword> packed_words;
	RelocationDeltaCodec codec;
	codec.Encode(relocations, &packed_words);

	// If insufficient data to delta encode, do nothing.
	if (packed_words.empty())
	return;

	// Signed LEB128 encode, with "APA1" prefix. ASCII does not encode as
	// itself under signed LEB128, so we have to treat it specially.
	Sleb128Encoder encoder;
	encoder.EnqueueAll(packed_words);
	std::vector<uint8_t> encoded;
	encoder.GetEncoding(&encoded);

	packed->push_back('A');
	packed->push_back('P');
	packed->push_back('A');
	packed->push_back('1');
	packed->insert(packed->end(), encoded.begin(), encoded.end());

	// Pad packed to a whole number of words. This padding will decode as
	// signed LEB128 zeroes. Delta decoding ignores it because encoding
	// embeds the pairs count in the stream itself.
	while (packed->size() % sizeof(ELF::Word))
	packed->push_back(0);
	}

	// Unpack relative relocations with addends from a delta encoded
	// packed representation.
	void RelocationPacker::UnpackRelativeRelocations(
	const std::vector<uint8_t>& packed,
	std::vector<ELF::Rela>* relocations) {
	// Check "APA1" prefix.
	CHECK(packed.at(0) == 'A' &&
	packed.at(1) == 'P' &&
	packed.at(2) == 'A' &&
	packed.at(3) == '1');

	// Signed LEB128 decode, after stripping "APA1" prefix.
	std::vector<ELF::Sxword> packed_words;
	std::vector<uint8_t> stripped(packed.begin() + 4, packed.end());
	Sleb128Decoder decoder(stripped);
	decoder.DequeueAll(&packed_words);

	// Delta decode.
	RelocationDeltaCodec codec;
	codec.Decode(packed_words, relocations);
	}

	} // namespace relocation_packer