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// Copyright (c) 2011 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.
// The main idea in Courgette is to do patching *under a tranformation*. The
// input is transformed into a new representation, patching occurs in the new
// repesentation, and then the tranform is reversed to get the patched data.
//
// The idea is applied to pieces (or 'elements') of the whole (or 'ensemble').
// Each of the elements has to go through the same set of steps in lock-step.
// This file contains the code to create the patch.
#include "courgette/ensemble.h"
#include <vector>
#include <limits>
#include "base/basictypes.h"
#include "base/logging.h"
#include "base/time.h"
#include "courgette/third_party/bsdiff.h"
#include "courgette/crc.h"
#include "courgette/difference_estimator.h"
#include "courgette/image_info.h"
#include "courgette/streams.h"
#include "courgette/region.h"
#include "courgette/simple_delta.h"
#include "courgette/win32_x86_patcher.h"
#include "courgette/win32_x86_generator.h"
namespace courgette {
TransformationPatchGenerator::TransformationPatchGenerator(
Element* old_element,
Element* new_element,
TransformationPatcher* patcher)
: old_element_(old_element),
new_element_(new_element),
patcher_(patcher) {
}
TransformationPatchGenerator::~TransformationPatchGenerator() {
delete patcher_;
}
// The default implementation of PredictTransformParameters delegates to the
// patcher.
Status TransformationPatchGenerator::PredictTransformParameters(
SinkStreamSet* prediction) {
return patcher_->PredictTransformParameters(prediction);
}
// The default implementation of Reform delegates to the patcher.
Status TransformationPatchGenerator::Reform(
SourceStreamSet* transformed_element,
SinkStream* reformed_element) {
return patcher_->Reform(transformed_element, reformed_element);
}
// Makes a TransformationPatchGenerator of the appropriate variety for the
// Element kind.
TransformationPatchGenerator* MakeGenerator(Element* old_element,
Element* new_element) {
switch (new_element->kind()) {
case UNKNOWN:
break;
case WIN32_X86: {
TransformationPatchGenerator* generator =
new CourgetteWin32X86PatchGenerator(
old_element,
new_element,
new CourgetteWin32X86Patcher(old_element->region()));
return generator;
}
}
LOG(WARNING) << "Unexpected Element::Kind " << old_element->kind();
return NULL;
}
// Checks to see if the proposed comparison is 'unsafe'. Sometimes one element
// from 'old' is matched as the closest element to multiple elements from 'new'.
// Each time this happens, the old element is transformed and serialized. This
// is a problem when the old element is huge compared with the new element
// because the mutliple serialized copies can be much bigger than the size of
// either ensemble.
//
// The right way to avoid this is to ensure any one element from 'old' is
// serialized once, which requires matching code in the patch application.
//
// This is a quick hack to avoid the problem by prohibiting a big difference in
// size between matching elements.
bool UnsafeDifference(Element* old_element, Element* new_element) {
double kMaxBloat = 2.0;
size_t kMinWorrysomeDifference = 2 << 20; // 2MB
size_t old_size = old_element->region().length();
size_t new_size = new_element->region().length();
size_t low_size = std::min(old_size, new_size);
size_t high_size = std::max(old_size, new_size);
if (high_size - low_size < kMinWorrysomeDifference) return false;
if (high_size < low_size * kMaxBloat) return false;
return true;
}
// FindGenerators finds TransformationPatchGenerators for the elements of
// |new_ensemble|. For each element of |new_ensemble| we find the closest
// matching element from |old_ensemble| and use that as the basis for
// differential compression. The elements have to be the same kind so as to
// support transformation into the same kind of 'new representation'.
//
Status FindGenerators(Ensemble* old_ensemble, Ensemble* new_ensemble,
std::vector<TransformationPatchGenerator*>* generators) {
base::Time start_find_time = base::Time::Now();
old_ensemble->FindEmbeddedElements();
new_ensemble->FindEmbeddedElements();
VLOG(1) << "done FindEmbeddedElements "
<< (base::Time::Now() - start_find_time).InSecondsF();
std::vector<Element*> old_elements(old_ensemble->elements());
std::vector<Element*> new_elements(new_ensemble->elements());
VLOG(1) << "old has " << old_elements.size() << " elements";
VLOG(1) << "new has " << new_elements.size() << " elements";
DifferenceEstimator difference_estimator;
std::vector<DifferenceEstimator::Base*> bases;
base::Time start_bases_time = base::Time::Now();
for (size_t i = 0; i < old_elements.size(); ++i) {
bases.push_back(
difference_estimator.MakeBase(old_elements[i]->region()));
}
VLOG(1) << "done make bases "
<< (base::Time::Now() - start_bases_time).InSecondsF() << "s";
for (size_t new_index = 0; new_index < new_elements.size(); ++new_index) {
Element* new_element = new_elements[new_index];
DifferenceEstimator::Subject* new_subject =
difference_estimator.MakeSubject(new_element->region());
// Search through old elements to find the best match.
//
// TODO(sra): This is O(N x M), i.e. O(N^2) since old_ensemble and
// new_ensemble probably have a very similar structure. We can make the
// search faster by making the comparison provided by DifferenceEstimator
// more nuanced, returning early if the measured difference is greater than
// the current best. This will be most effective if we can arrange that the
// first elements we try to match are likely the 'right' ones. We could
// prioritize elements that are of a similar size or similar position in the
// sequence of elements.
//
Element* best_old_element = NULL;
size_t best_difference = std::numeric_limits<size_t>::max();
for (size_t old_index = 0; old_index < old_elements.size(); ++old_index) {
Element* old_element = old_elements[old_index];
// Elements of different kinds are incompatible.
if (old_element->kind() != new_element->kind())
continue;
if (UnsafeDifference(old_element, new_element))
continue;
base::Time start_compare = base::Time::Now();
DifferenceEstimator::Base* old_base = bases[old_index];
size_t difference = difference_estimator.Measure(old_base, new_subject);
VLOG(1) << "Compare " << old_element->Name()
<< " to " << new_element->Name()
<< " --> " << difference
<< " in " << (base::Time::Now() - start_compare).InSecondsF()
<< "s";
if (difference == 0) {
VLOG(1) << "Skip " << new_element->Name()
<< " - identical to " << old_element->Name();
best_difference = 0;
best_old_element = NULL;
break;
}
if (difference < best_difference) {
best_difference = difference;
best_old_element = old_element;
}
}
if (best_old_element) {
VLOG(1) << "Matched " << best_old_element->Name()
<< " to " << new_element->Name()
<< " --> " << best_difference;
TransformationPatchGenerator* generator =
MakeGenerator(best_old_element, new_element);
if (generator)
generators->push_back(generator);
}
}
VLOG(1) << "done FindGenerators found " << generators->size()
<< " in " << (base::Time::Now() - start_find_time).InSecondsF()
<< "s";
return C_OK;
}
void FreeGenerators(std::vector<TransformationPatchGenerator*>* generators) {
for (size_t i = 0; i < generators->size(); ++i) {
delete (*generators)[i];
}
generators->clear();
}
////////////////////////////////////////////////////////////////////////////////
Status GenerateEnsemblePatch(SourceStream* base,
SourceStream* update,
SinkStream* final_patch) {
VLOG(1) << "start GenerateEnsemblePatch";
base::Time start_time = base::Time::Now();
Region old_region(base->Buffer(), base->Remaining());
Region new_region(update->Buffer(), update->Remaining());
Ensemble old_ensemble(old_region, "old");
Ensemble new_ensemble(new_region, "new");
std::vector<TransformationPatchGenerator*> generators;
Status generators_status = FindGenerators(&old_ensemble, &new_ensemble,
&generators);
if (generators_status != C_OK)
return generators_status;
SinkStreamSet patch_streams;
SinkStream* tranformation_descriptions = patch_streams.stream(0);
SinkStream* parameter_correction = patch_streams.stream(1);
SinkStream* transformed_elements_correction = patch_streams.stream(2);
SinkStream* ensemble_correction = patch_streams.stream(3);
size_t number_of_transformations = generators.size();
if (!tranformation_descriptions->WriteSizeVarint32(number_of_transformations))
return C_STREAM_ERROR;
for (size_t i = 0; i < number_of_transformations; ++i) {
CourgettePatchFile::TransformationMethodId kind = generators[i]->Kind();
if (!tranformation_descriptions->WriteVarint32(kind))
return C_STREAM_ERROR;
}
for (size_t i = 0; i < number_of_transformations; ++i) {
Status status =
generators[i]->WriteInitialParameters(tranformation_descriptions);
if (status != C_OK)
return status;
}
//
// Generate sub-patch for parameters.
//
SinkStreamSet predicted_parameters_sink;
SinkStreamSet corrected_parameters_sink;
for (size_t i = 0; i < number_of_transformations; ++i) {
SinkStreamSet single_predicted_parameters;
Status status;
status = generators[i]->PredictTransformParameters(
&single_predicted_parameters);
if (status != C_OK)
return status;
if (!predicted_parameters_sink.WriteSet(&single_predicted_parameters))
return C_STREAM_ERROR;
SinkStreamSet single_corrected_parameters;
status = generators[i]->CorrectedTransformParameters(
&single_corrected_parameters);
if (status != C_OK)
return status;
if (!corrected_parameters_sink.WriteSet(&single_corrected_parameters))
return C_STREAM_ERROR;
}
SinkStream linearized_predicted_parameters;
SinkStream linearized_corrected_parameters;
if (!predicted_parameters_sink.CopyTo(&linearized_predicted_parameters))
return C_STREAM_ERROR;
if (!corrected_parameters_sink.CopyTo(&linearized_corrected_parameters))
return C_STREAM_ERROR;
SourceStream predicted_parameters_source;
SourceStream corrected_parameters_source;
predicted_parameters_source.Init(linearized_predicted_parameters);
corrected_parameters_source.Init(linearized_corrected_parameters);
Status delta1_status = GenerateSimpleDelta(&predicted_parameters_source,
&corrected_parameters_source,
parameter_correction);
if (delta1_status != C_OK)
return delta1_status;
//
// Generate sub-patch for elements.
//
corrected_parameters_source.Init(linearized_corrected_parameters);
SourceStreamSet corrected_parameters_source_set;
if (!corrected_parameters_source_set.Init(&corrected_parameters_source))
return C_STREAM_ERROR;
SinkStreamSet predicted_transformed_elements;
SinkStreamSet corrected_transformed_elements;
for (size_t i = 0; i < number_of_transformations; ++i) {
SourceStreamSet single_parameters;
if (!corrected_parameters_source_set.ReadSet(&single_parameters))
return C_STREAM_ERROR;
SinkStreamSet single_predicted_transformed_element;
SinkStreamSet single_corrected_transformed_element;
Status status = generators[i]->Transform(
&single_parameters,
&single_predicted_transformed_element,
&single_corrected_transformed_element);
if (status != C_OK)
return status;
if (!single_parameters.Empty())
return C_STREAM_NOT_CONSUMED;
if (!predicted_transformed_elements.WriteSet(
&single_predicted_transformed_element))
return C_STREAM_ERROR;
if (!corrected_transformed_elements.WriteSet(
&single_corrected_transformed_element))
return C_STREAM_ERROR;
}
if (!corrected_parameters_source_set.Empty())
return C_STREAM_NOT_CONSUMED;
SinkStream linearized_predicted_transformed_elements;
SinkStream linearized_corrected_transformed_elements;
if (!predicted_transformed_elements.CopyTo(
&linearized_predicted_transformed_elements))
return C_STREAM_ERROR;
if (!corrected_transformed_elements.CopyTo(
&linearized_corrected_transformed_elements))
return C_STREAM_ERROR;
SourceStream predicted_transformed_elements_source;
SourceStream corrected_transformed_elements_source;
predicted_transformed_elements_source
.Init(linearized_predicted_transformed_elements);
corrected_transformed_elements_source
.Init(linearized_corrected_transformed_elements);
Status delta2_status =
GenerateSimpleDelta(&predicted_transformed_elements_source,
&corrected_transformed_elements_source,
transformed_elements_correction);
if (delta2_status != C_OK)
return delta2_status;
// Last use, free storage.
linearized_predicted_transformed_elements.Retire();
//
// Generate sub-patch for whole enchilada.
//
SinkStream predicted_ensemble;
if (!predicted_ensemble.Write(base->Buffer(), base->Remaining()))
return C_STREAM_ERROR;
SourceStreamSet corrected_transformed_elements_source_set;
corrected_transformed_elements_source
.Init(linearized_corrected_transformed_elements);
if (!corrected_transformed_elements_source_set
.Init(&corrected_transformed_elements_source))
return C_STREAM_ERROR;
for (size_t i = 0; i < number_of_transformations; ++i) {
SourceStreamSet single_corrected_transformed_element;
if (!corrected_transformed_elements_source_set.ReadSet(
&single_corrected_transformed_element))
return C_STREAM_ERROR;
Status status = generators[i]->Reform(&single_corrected_transformed_element,
&predicted_ensemble);
if (status != C_OK)
return status;
if (!single_corrected_transformed_element.Empty())
return C_STREAM_NOT_CONSUMED;
}
if (!corrected_transformed_elements_source_set.Empty())
return C_STREAM_NOT_CONSUMED;
// No more references to this stream's buffer.
linearized_corrected_transformed_elements.Retire();
FreeGenerators(&generators);
size_t final_patch_input_size = predicted_ensemble.Length();
SourceStream predicted_ensemble_source;
predicted_ensemble_source.Init(predicted_ensemble);
Status delta3_status = GenerateSimpleDelta(&predicted_ensemble_source,
update,
ensemble_correction);
if (delta3_status != C_OK)
return delta3_status;
//
// Final output stream has a header followed by a StreamSet.
//
if (!final_patch->WriteVarint32(CourgettePatchFile::kMagic) ||
!final_patch->WriteVarint32(CourgettePatchFile::kVersion) ||
!final_patch->WriteVarint32(CalculateCrc(old_region.start(),
old_region.length())) ||
!final_patch->WriteVarint32(CalculateCrc(new_region.start(),
new_region.length())) ||
!final_patch->WriteSizeVarint32(final_patch_input_size) ||
!patch_streams.CopyTo(final_patch)) {
return C_STREAM_ERROR;
}
VLOG(1) << "done GenerateEnsemblePatch "
<< (base::Time::Now() - start_time).InSecondsF() << "s";
return C_OK;
}
} // namespace
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