tools/relocation_packer/src/run_length_encoder.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 "run_length_encoder.h"

 #include <vector>

 #include "debug.h"
 #include "elf_traits.h"

 namespace relocation_packer {

 namespace {

 // Generate a vector of deltas between the r_offset fields of adjacent
 // relative relocations.
 void GetDeltas(const std::vector<ELF::Rel>& relocations,
                std::vector<ELF::Addr>* deltas) {
   CHECK(relocations.size() >= 2);

   for (size_t i = 0; i < relocations.size() - 1; ++i) {
     const ELF::Rel* first = &relocations[i];
     CHECK(ELF_R_TYPE(first->r_info) == ELF::kRelativeRelocationCode);

     const ELF::Rel* second = &relocations[i + 1];
     CHECK(ELF_R_TYPE(second->r_info) == ELF::kRelativeRelocationCode);

     // Requires that offsets are 'strictly increasing'.  The packing
     // algorithm fails if this does not hold.
     CHECK(second->r_offset > first->r_offset);
     deltas->push_back(second->r_offset - first->r_offset);
   }
 }

 // Condense a set of r_offset deltas into a run-length encoded packing.
 // Represented as count-delta pairs, where count is the run length and
 // delta the common difference between adjacent r_offsets.
 void Condense(const std::vector<ELF::Addr>& deltas,
               std::vector<ELF::Xword>* packed) {
   CHECK(!deltas.empty());
   size_t count = 0;
   ELF::Addr current = deltas[0];

   // Identify spans of identically valued deltas.
   for (size_t i = 0; i < deltas.size(); ++i) {
     const ELF::Addr delta = deltas[i];
     if (delta == current) {
       count++;
     } else {
       // We reached the end of a span of identically valued deltas.
       packed->push_back(count);
       packed->push_back(current);
       current = delta;
       count = 1;
     }
   }

   // Write the final span.
   packed->push_back(count);
   packed->push_back(current);
 }

 // Uncondense a set of r_offset deltas from a run-length encoded packing.
 // The initial address for uncondensing, the start index for the first
 // condensed slot in packed, and the count of pairs are provided.
 void Uncondense(ELF::Addr addr,
                 const std::vector<ELF::Xword>& packed,
                 size_t start_index,
                 size_t end_index,
                 std::vector<ELF::Rel>* relocations) {
   // The first relocation is just one created from the initial address.
   ELF::Rel initial;
   initial.r_offset = addr;
   initial.r_info = ELF_R_INFO(0, ELF::kRelativeRelocationCode);
   relocations->push_back(initial);

   // Read each count and delta pair, beginning at the start index and
   // finishing at the end index.
   for (size_t i = start_index; i < end_index; i += 2) {
     size_t count = packed[i];
     const ELF::Addr delta = packed[i + 1];
     CHECK(count > 0 && delta > 0);

     // Generate relocations for this count and delta pair.
     while (count) {
       addr += delta;
       ELF::Rel relocation;
       relocation.r_offset = addr;
       relocation.r_info = ELF_R_INFO(0, ELF::kRelativeRelocationCode);
       relocations->push_back(relocation);
       count--;
     }
   }
 }

 }  // namespace

 // Encode relative relocations into a run-length encoded (packed)
 // representation.
 void RelocationRunLengthCodec::Encode(const std::vector<ELF::Rel>& relocations,
                                       std::vector<ELF::Xword>* packed) {
   // If we have zero or one relocation only then there is no packing
   // possible; a run-length encoding needs a run.
   if (relocations.size() < 2)
     return;

   std::vector<ELF::Addr> deltas;
   GetDeltas(relocations, &deltas);

   // Reserve space for the element count.
   packed->push_back(0);

   // Initialize the packed data with the first offset, then follow up with
   // the condensed deltas vector.
   packed->push_back(relocations[0].r_offset);
   Condense(deltas, packed);

   // Fill in the packed pair count.
   packed->at(0) = (packed->size() - 2) >> 1;
 }

 // Decode relative relocations from a run-length encoded (packed)
 // representation.
 void RelocationRunLengthCodec::Decode(const std::vector<ELF::Xword>& packed,
                                       std::vector<ELF::Rel>* relocations) {
   // We need at least one packed pair after the packed pair count and start
   // address to be able to unpack.
   if (packed.size() < 4)
     return;

   // Ensure that the packed data offers enough pairs.  There may be zero
   // padding on it that we ignore.
   CHECK(packed[0] <= (packed.size() - 2) >> 1);

   // The first packed vector element is the pairs count and the second the
   // initial address.  Start uncondensing pairs at the third, and finish
   // at the end of the pairs data.
   const size_t pairs_count = packed[0];
   const ELF::Addr addr = packed[1];
   Uncondense(addr, packed, 2, 2 + (pairs_count << 1), 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 "run_length_encoder.h"

	#include <vector>

	#include "debug.h"
	#include "elf_traits.h"

	namespace relocation_packer {

	namespace {

	// Generate a vector of deltas between the r_offset fields of adjacent
	// relative relocations.
	void GetDeltas(const std::vector<ELF::Rel>& relocations,
	std::vector<ELF::Addr>* deltas) {
	CHECK(relocations.size() >= 2);

	for (size_t i = 0; i < relocations.size() - 1; ++i) {
	const ELF::Rel* first = &relocations[i];
	CHECK(ELF_R_TYPE(first->r_info) == ELF::kRelativeRelocationCode);

	const ELF::Rel* second = &relocations[i + 1];
	CHECK(ELF_R_TYPE(second->r_info) == ELF::kRelativeRelocationCode);

	// Requires that offsets are 'strictly increasing'. The packing
	// algorithm fails if this does not hold.
	CHECK(second->r_offset > first->r_offset);
	deltas->push_back(second->r_offset - first->r_offset);
	}
	}

	// Condense a set of r_offset deltas into a run-length encoded packing.
	// Represented as count-delta pairs, where count is the run length and
	// delta the common difference between adjacent r_offsets.
	void Condense(const std::vector<ELF::Addr>& deltas,
	std::vector<ELF::Xword>* packed) {
	CHECK(!deltas.empty());
	size_t count = 0;
	ELF::Addr current = deltas[0];

	// Identify spans of identically valued deltas.
	for (size_t i = 0; i < deltas.size(); ++i) {
	const ELF::Addr delta = deltas[i];
	if (delta == current) {
	count++;
	} else {
	// We reached the end of a span of identically valued deltas.
	packed->push_back(count);
	packed->push_back(current);
	current = delta;
	count = 1;
	}
	}

	// Write the final span.
	packed->push_back(count);
	packed->push_back(current);
	}

	// Uncondense a set of r_offset deltas from a run-length encoded packing.
	// The initial address for uncondensing, the start index for the first
	// condensed slot in packed, and the count of pairs are provided.
	void Uncondense(ELF::Addr addr,
	const std::vector<ELF::Xword>& packed,
	size_t start_index,
	size_t end_index,
	std::vector<ELF::Rel>* relocations) {
	// The first relocation is just one created from the initial address.
	ELF::Rel initial;
	initial.r_offset = addr;
	initial.r_info = ELF_R_INFO(0, ELF::kRelativeRelocationCode);
	relocations->push_back(initial);

	// Read each count and delta pair, beginning at the start index and
	// finishing at the end index.
	for (size_t i = start_index; i < end_index; i += 2) {
	size_t count = packed[i];
	const ELF::Addr delta = packed[i + 1];
	CHECK(count > 0 && delta > 0);

	// Generate relocations for this count and delta pair.
	while (count) {
	addr += delta;
	ELF::Rel relocation;
	relocation.r_offset = addr;
	relocation.r_info = ELF_R_INFO(0, ELF::kRelativeRelocationCode);
	relocations->push_back(relocation);
	count--;
	}
	}
	}

	} // namespace

	// Encode relative relocations into a run-length encoded (packed)
	// representation.
	void RelocationRunLengthCodec::Encode(const std::vector<ELF::Rel>& relocations,
	std::vector<ELF::Xword>* packed) {
	// If we have zero or one relocation only then there is no packing
	// possible; a run-length encoding needs a run.
	if (relocations.size() < 2)
	return;

	std::vector<ELF::Addr> deltas;
	GetDeltas(relocations, &deltas);

	// Reserve space for the element count.
	packed->push_back(0);

	// Initialize the packed data with the first offset, then follow up with
	// the condensed deltas vector.
	packed->push_back(relocations[0].r_offset);
	Condense(deltas, packed);

	// Fill in the packed pair count.
	packed->at(0) = (packed->size() - 2) >> 1;
	}

	// Decode relative relocations from a run-length encoded (packed)
	// representation.
	void RelocationRunLengthCodec::Decode(const std::vector<ELF::Xword>& packed,
	std::vector<ELF::Rel>* relocations) {
	// We need at least one packed pair after the packed pair count and start
	// address to be able to unpack.
	if (packed.size() < 4)
	return;

	// Ensure that the packed data offers enough pairs. There may be zero
	// padding on it that we ignore.
	CHECK(packed[0] <= (packed.size() - 2) >> 1);

	// The first packed vector element is the pairs count and the second the
	// initial address. Start uncondensing pairs at the third, and finish
	// at the end of the pairs data.
	const size_t pairs_count = packed[0];
	const ELF::Addr addr = packed[1];
	Uncondense(addr, packed, 2, 2 + (pairs_count << 1), relocations);
	}

	} // namespace relocation_packer