components/zucchini/patch_reader.cc - chromium/src - Git at Google

 // Copyright 2017 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 "components/zucchini/patch_reader.h"

 #include <type_traits>
 #include <utility>

 #include "base/numerics/safe_conversions.h"
 #include "components/zucchini/algorithm.h"
 #include "components/zucchini/crc32.h"

 namespace zucchini {

 namespace patch {

 bool ParseElementMatch(BufferSource* source, ElementMatch* element_match) {
   PatchElementHeader unsafe_element_header;
   if (!source->GetValue(&unsafe_element_header)) {
     LOG(ERROR) << "Impossible to read ElementMatch from source.";
     return false;
   }
   ExecutableType exe_type =
       CastToExecutableType(unsafe_element_header.exe_type);
   if (exe_type == kExeTypeUnknown) {
     LOG(ERROR) << "Invalid ExecutableType found.";
     return false;
   }
   if (!unsafe_element_header.old_length || !unsafe_element_header.new_length) {
     LOG(ERROR) << "Empty patch element found.";
     return false;
   }
   // |unsafe_element_header| is now considered to be safe as it has a valid
   // |exe_type| and the length fields are of sufficient size.
   const auto& element_header = unsafe_element_header;

   // Caveat: Element offsets and lengths can still be invalid (e.g., exceeding
   // archive bounds), but this will be checked later.
   element_match->old_element.offset = element_header.old_offset;
   element_match->old_element.size = element_header.old_length;
   element_match->new_element.offset = element_header.new_offset;
   element_match->new_element.size = element_header.new_length;
   element_match->old_element.exe_type = exe_type;
   element_match->new_element.exe_type = exe_type;
   return true;
 }

 bool ParseBuffer(BufferSource* source, BufferSource* buffer) {
   uint32_t unsafe_size = 0;  // Bytes.
   static_assert(sizeof(size_t) >= sizeof(unsafe_size),
                 "size_t is expected to be larger than uint32_t.");
   if (!source->GetValue(&unsafe_size)) {
     LOG(ERROR) << "Impossible to read buffer size from source.";
     return false;
   }
   if (!source->GetRegion(static_cast<size_t>(unsafe_size), buffer)) {
     LOG(ERROR) << "Impossible to read buffer content from source.";
     return false;
   }
   // Caveat: |buffer| is considered to be safe as it was possible to extract it
   // from the patch. However, this does not mean its contents are safe and when
   // parsed must be validated if possible.
   return true;
 }

 }  // namespace patch

 /******** EquivalenceSource ********/

 EquivalenceSource::EquivalenceSource() = default;
 EquivalenceSource::EquivalenceSource(const EquivalenceSource&) = default;
 EquivalenceSource::~EquivalenceSource() = default;

 bool EquivalenceSource::Initialize(BufferSource* source) {
   return patch::ParseBuffer(source, &src_skip_) &&
          patch::ParseBuffer(source, &dst_skip_) &&
          patch::ParseBuffer(source, &copy_count_);
 }

 base::Optional<Equivalence> EquivalenceSource::GetNext() {
   if (src_skip_.empty() || dst_skip_.empty() || copy_count_.empty())
     return base::nullopt;

   Equivalence equivalence = {};

   uint32_t length = 0;
   if (!patch::ParseVarUInt<uint32_t>(&copy_count_, &length))
     return base::nullopt;
   equivalence.length = base::strict_cast<offset_t>(length);

   int32_t src_offset_diff = 0;  // Intentionally signed.
   if (!patch::ParseVarInt<int32_t>(&src_skip_, &src_offset_diff))
     return base::nullopt;
   base::CheckedNumeric<offset_t> src_offset =
       previous_src_offset_ + src_offset_diff;
   if (!src_offset.IsValid())
     return base::nullopt;

   equivalence.src_offset = src_offset.ValueOrDie();
   previous_src_offset_ = src_offset + equivalence.length;
   if (!previous_src_offset_.IsValid())
     return base::nullopt;

   uint32_t dst_offset_diff = 0;  // Intentionally unsigned.
   if (!patch::ParseVarUInt<uint32_t>(&dst_skip_, &dst_offset_diff))
     return base::nullopt;
   base::CheckedNumeric<offset_t> dst_offset =
       previous_dst_offset_ + dst_offset_diff;
   if (!dst_offset.IsValid())
     return base::nullopt;

   equivalence.dst_offset = dst_offset.ValueOrDie();
   previous_dst_offset_ = equivalence.dst_offset + equivalence.length;
   if (!previous_dst_offset_.IsValid())
     return base::nullopt;

   // Caveat: |equivalence| is assumed to be safe only once the
   // ValidateEquivalencesAndExtraData() method has returned true. Prior to this
   // any equivalence returned is assumed to be unsafe.
   return equivalence;
 }

 /******** ExtraDataSource ********/

 ExtraDataSource::ExtraDataSource() = default;
 ExtraDataSource::ExtraDataSource(const ExtraDataSource&) = default;
 ExtraDataSource::~ExtraDataSource() = default;

 bool ExtraDataSource::Initialize(BufferSource* source) {
   return patch::ParseBuffer(source, &extra_data_);
 }

 base::Optional<ConstBufferView> ExtraDataSource::GetNext(offset_t size) {
   ConstBufferView buffer;
   if (!extra_data_.GetRegion(size, &buffer))
     return base::nullopt;
   // |buffer| is assumed to always be safe/valid.
   return buffer;
 }

 /******** RawDeltaSource ********/

 RawDeltaSource::RawDeltaSource() = default;
 RawDeltaSource::RawDeltaSource(const RawDeltaSource&) = default;
 RawDeltaSource::~RawDeltaSource() = default;

 bool RawDeltaSource::Initialize(BufferSource* source) {
   return patch::ParseBuffer(source, &raw_delta_skip_) &&
          patch::ParseBuffer(source, &raw_delta_diff_);
 }

 base::Optional<RawDeltaUnit> RawDeltaSource::GetNext() {
   if (raw_delta_skip_.empty() || raw_delta_diff_.empty())
     return base::nullopt;

   RawDeltaUnit raw_delta = {};
   uint32_t copy_offset_diff = 0;
   if (!patch::ParseVarUInt<uint32_t>(&raw_delta_skip_, &copy_offset_diff))
     return base::nullopt;
   base::CheckedNumeric<offset_t> copy_offset =
       copy_offset_diff + copy_offset_compensation_;
   if (!copy_offset.IsValid())
     return base::nullopt;
   raw_delta.copy_offset = copy_offset.ValueOrDie();

   if (!raw_delta_diff_.GetValue<int8_t>(&raw_delta.diff))
     return base::nullopt;

   // A 0 value for a delta.diff is considered invalid since it has no meaning.
   if (!raw_delta.diff)
     return base::nullopt;

   // We keep track of the compensation needed for next offset, taking into
   // account delta encoding and bias of -1.
   copy_offset_compensation_ = copy_offset + 1;
   if (!copy_offset_compensation_.IsValid())
     return base::nullopt;
   // |raw_delta| is assumed to always be safe/valid.
   return raw_delta;
 }

 /******** ReferenceDeltaSource ********/

 ReferenceDeltaSource::ReferenceDeltaSource() = default;
 ReferenceDeltaSource::ReferenceDeltaSource(const ReferenceDeltaSource&) =
     default;
 ReferenceDeltaSource::~ReferenceDeltaSource() = default;

 bool ReferenceDeltaSource::Initialize(BufferSource* source) {
   return patch::ParseBuffer(source, &source_);
 }

 base::Optional<int32_t> ReferenceDeltaSource::GetNext() {
   if (source_.empty())
     return base::nullopt;
   int32_t ref_delta = 0;
   if (!patch::ParseVarInt<int32_t>(&source_, &ref_delta))
     return base::nullopt;
   // |ref_delta| is assumed to always be safe/valid.
   return ref_delta;
 }

 /******** TargetSource ********/

 TargetSource::TargetSource() = default;
 TargetSource::TargetSource(const TargetSource&) = default;
 TargetSource::~TargetSource() = default;

 bool TargetSource::Initialize(BufferSource* source) {
   return patch::ParseBuffer(source, &extra_targets_);
 }

 base::Optional<offset_t> TargetSource::GetNext() {
   if (extra_targets_.empty())
     return base::nullopt;

   uint32_t target_diff = 0;
   if (!patch::ParseVarUInt<uint32_t>(&extra_targets_, &target_diff))
     return base::nullopt;
   base::CheckedNumeric<offset_t> target = target_diff + target_compensation_;
   if (!target.IsValid())
     return base::nullopt;

   // We keep track of the compensation needed for next target, taking into
   // account delta encoding and bias of -1.
   target_compensation_ = target + 1;
   if (!target_compensation_.IsValid())
     return base::nullopt;
   // Caveat: |target| will be a valid offset_t, but it's up to the caller to
   // check whether it's a valid offset for an image.
   return offset_t(target.ValueOrDie());
 }

 /******** PatchElementReader ********/

 PatchElementReader::PatchElementReader() = default;
 PatchElementReader::PatchElementReader(PatchElementReader&&) = default;
 PatchElementReader::~PatchElementReader() = default;

 bool PatchElementReader::Initialize(BufferSource* source) {
   bool ok =
       patch::ParseElementMatch(source, &element_match_) &&
       equivalences_.Initialize(source) && extra_data_.Initialize(source) &&
       ValidateEquivalencesAndExtraData() && raw_delta_.Initialize(source) &&
       reference_delta_.Initialize(source);
   if (!ok)
     return false;
   uint32_t pool_count = 0;
   if (!source->GetValue(&pool_count)) {
     LOG(ERROR) << "Impossible to read pool_count from source.";
     return false;
   }
   for (uint32_t i = 0; i < pool_count; ++i) {
     uint8_t pool_tag_value = 0;
     if (!source->GetValue(&pool_tag_value)) {
       LOG(ERROR) << "Impossible to read pool_tag from source.";
       return false;
     }
     PoolTag pool_tag(pool_tag_value);
     if (pool_tag == kNoPoolTag) {
       LOG(ERROR) << "Invalid pool_tag encountered in ExtraTargetList.";
       return false;
     }
     auto insert_result = extra_targets_.insert({pool_tag, {}});
     if (!insert_result.second) {  // Element already present.
       LOG(ERROR) << "Multiple ExtraTargetList found for the same pool_tag.";
       return false;
     }
     if (!insert_result.first->second.Initialize(source))
       return false;
   }
   return true;
 }

 bool PatchElementReader::ValidateEquivalencesAndExtraData() {
   EquivalenceSource equivalences_copy = equivalences_;

   const size_t old_region_size = element_match_.old_element.size;
   const size_t new_region_size = element_match_.new_element.size;

   base::CheckedNumeric<uint32_t> total_length = 0;
   // Validate that each |equivalence| falls within the bounds of the
   // |element_match_| and are in order.
   offset_t prev_dst_end = 0;
   for (auto equivalence = equivalences_copy.GetNext(); equivalence.has_value();
        equivalence = equivalences_copy.GetNext()) {
     if (!RangeIsBounded(equivalence->src_offset, equivalence->length,
                         old_region_size) ||
         !RangeIsBounded(equivalence->dst_offset, equivalence->length,
                         new_region_size)) {
       LOG(ERROR) << "Out of bounds equivalence detected.";
       return false;
     }
     if (prev_dst_end > equivalence->dst_end()) {
       LOG(ERROR) << "Out of order equivalence detected.";
       return false;
     }
     prev_dst_end = equivalence->dst_end();
     total_length += equivalence->length;
   }
   if (!total_length.IsValid() ||
       element_match_.new_element.region().size < total_length.ValueOrDie() ||
       extra_data_.extra_data().size() !=
           element_match_.new_element.region().size -
               static_cast<size_t>(total_length.ValueOrDie())) {
     LOG(ERROR) << "Incorrect amount of extra_data.";
     return false;
   }
   return true;
 }

 /******** EnsemblePatchReader ********/

 base::Optional<EnsemblePatchReader> EnsemblePatchReader::Create(
     ConstBufferView buffer) {
   BufferSource source(buffer);
   EnsemblePatchReader patch;
   if (!patch.Initialize(&source))
     return base::nullopt;
   return patch;
 }

 EnsemblePatchReader::EnsemblePatchReader() = default;
 EnsemblePatchReader::EnsemblePatchReader(EnsemblePatchReader&&) = default;
 EnsemblePatchReader::~EnsemblePatchReader() = default;

 bool EnsemblePatchReader::Initialize(BufferSource* source) {
   if (!source->GetValue(&header_)) {
     LOG(ERROR) << "Impossible to read header from source.";
     return false;
   }
   if (header_.magic != PatchHeader::kMagic) {
     LOG(ERROR) << "Patch contains invalid magic.";
     return false;
   }
   // |header_| is assumed to be safe from this point forward.

   uint32_t element_count = 0;
   if (!source->GetValue(&element_count)) {
     LOG(ERROR) << "Impossible to read element_count from source.";
     return false;
   }

   offset_t current_dst_offset = 0;
   for (uint32_t i = 0; i < element_count; ++i) {
     PatchElementReader element_patch;
     if (!element_patch.Initialize(source))
       return false;

     if (!element_patch.old_element().FitsIn(header_.old_size) ||
         !element_patch.new_element().FitsIn(header_.new_size)) {
       LOG(ERROR) << "Invalid element encountered.";
       return false;
     }

     if (element_patch.new_element().offset != current_dst_offset) {
       LOG(ERROR) << "Invalid element encountered.";
       return false;
     }
     current_dst_offset = element_patch.new_element().EndOffset();

     elements_.push_back(std::move(element_patch));
   }
   if (current_dst_offset != header_.new_size) {
     LOG(ERROR) << "Patch elements don't fully cover new image file.";
     return false;
   }

   if (!source->empty()) {
     LOG(ERROR) << "Patch was not fully consumed.";
     return false;
   }

   return true;
 }

 bool EnsemblePatchReader::CheckOldFile(ConstBufferView old_image) const {
   return old_image.size() == header_.old_size &&
          CalculateCrc32(old_image.begin(), old_image.end()) == header_.old_crc;
 }

 bool EnsemblePatchReader::CheckNewFile(ConstBufferView new_image) const {
   return new_image.size() == header_.new_size &&
          CalculateCrc32(new_image.begin(), new_image.end()) == header_.new_crc;
 }

 }  // namespace zucchini
	// Copyright 2017 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 "components/zucchini/patch_reader.h"

	#include <type_traits>
	#include <utility>

	#include "base/numerics/safe_conversions.h"
	#include "components/zucchini/algorithm.h"
	#include "components/zucchini/crc32.h"

	namespace zucchini {

	namespace patch {

	bool ParseElementMatch(BufferSource* source, ElementMatch* element_match) {
	PatchElementHeader unsafe_element_header;
	if (!source->GetValue(&unsafe_element_header)) {
	LOG(ERROR) << "Impossible to read ElementMatch from source.";
	return false;
	}
	ExecutableType exe_type =
	CastToExecutableType(unsafe_element_header.exe_type);
	if (exe_type == kExeTypeUnknown) {
	LOG(ERROR) << "Invalid ExecutableType found.";
	return false;
	}
	if (!unsafe_element_header.old_length \|\| !unsafe_element_header.new_length) {
	LOG(ERROR) << "Empty patch element found.";
	return false;
	}
	// \|unsafe_element_header\| is now considered to be safe as it has a valid
	// \|exe_type\| and the length fields are of sufficient size.
	const auto& element_header = unsafe_element_header;

	// Caveat: Element offsets and lengths can still be invalid (e.g., exceeding
	// archive bounds), but this will be checked later.
	element_match->old_element.offset = element_header.old_offset;
	element_match->old_element.size = element_header.old_length;
	element_match->new_element.offset = element_header.new_offset;
	element_match->new_element.size = element_header.new_length;
	element_match->old_element.exe_type = exe_type;
	element_match->new_element.exe_type = exe_type;
	return true;
	}

	bool ParseBuffer(BufferSource* source, BufferSource* buffer) {
	uint32_t unsafe_size = 0; // Bytes.
	static_assert(sizeof(size_t) >= sizeof(unsafe_size),
	"size_t is expected to be larger than uint32_t.");
	if (!source->GetValue(&unsafe_size)) {
	LOG(ERROR) << "Impossible to read buffer size from source.";
	return false;
	}
	if (!source->GetRegion(static_cast<size_t>(unsafe_size), buffer)) {
	LOG(ERROR) << "Impossible to read buffer content from source.";
	return false;
	}
	// Caveat: \|buffer\| is considered to be safe as it was possible to extract it
	// from the patch. However, this does not mean its contents are safe and when
	// parsed must be validated if possible.
	return true;
	}

	} // namespace patch

	/****** EquivalenceSource ******/

	EquivalenceSource::EquivalenceSource() = default;
	EquivalenceSource::EquivalenceSource(const EquivalenceSource&) = default;
	EquivalenceSource::~EquivalenceSource() = default;

	bool EquivalenceSource::Initialize(BufferSource* source) {
	return patch::ParseBuffer(source, &src_skip_) &&
	patch::ParseBuffer(source, &dst_skip_) &&
	patch::ParseBuffer(source, &copy_count_);
	}

	base::Optional<Equivalence> EquivalenceSource::GetNext() {
	if (src_skip_.empty() \|\| dst_skip_.empty() \|\| copy_count_.empty())
	return base::nullopt;

	Equivalence equivalence = {};

	uint32_t length = 0;
	if (!patch::ParseVarUInt<uint32_t>(&copy_count_, &length))
	return base::nullopt;
	equivalence.length = base::strict_cast<offset_t>(length);

	int32_t src_offset_diff = 0; // Intentionally signed.
	if (!patch::ParseVarInt<int32_t>(&src_skip_, &src_offset_diff))
	return base::nullopt;
	base::CheckedNumeric<offset_t> src_offset =
	previous_src_offset_ + src_offset_diff;
	if (!src_offset.IsValid())
	return base::nullopt;

	equivalence.src_offset = src_offset.ValueOrDie();
	previous_src_offset_ = src_offset + equivalence.length;
	if (!previous_src_offset_.IsValid())
	return base::nullopt;

	uint32_t dst_offset_diff = 0; // Intentionally unsigned.
	if (!patch::ParseVarUInt<uint32_t>(&dst_skip_, &dst_offset_diff))
	return base::nullopt;
	base::CheckedNumeric<offset_t> dst_offset =
	previous_dst_offset_ + dst_offset_diff;
	if (!dst_offset.IsValid())
	return base::nullopt;

	equivalence.dst_offset = dst_offset.ValueOrDie();
	previous_dst_offset_ = equivalence.dst_offset + equivalence.length;
	if (!previous_dst_offset_.IsValid())
	return base::nullopt;

	// Caveat: \|equivalence\| is assumed to be safe only once the
	// ValidateEquivalencesAndExtraData() method has returned true. Prior to this
	// any equivalence returned is assumed to be unsafe.
	return equivalence;
	}

	/****** ExtraDataSource ******/

	ExtraDataSource::ExtraDataSource() = default;
	ExtraDataSource::ExtraDataSource(const ExtraDataSource&) = default;
	ExtraDataSource::~ExtraDataSource() = default;

	bool ExtraDataSource::Initialize(BufferSource* source) {
	return patch::ParseBuffer(source, &extra_data_);
	}

	base::Optional<ConstBufferView> ExtraDataSource::GetNext(offset_t size) {
	ConstBufferView buffer;
	if (!extra_data_.GetRegion(size, &buffer))
	return base::nullopt;
	// \|buffer\| is assumed to always be safe/valid.
	return buffer;
	}

	/****** RawDeltaSource ******/

	RawDeltaSource::RawDeltaSource() = default;
	RawDeltaSource::RawDeltaSource(const RawDeltaSource&) = default;
	RawDeltaSource::~RawDeltaSource() = default;

	bool RawDeltaSource::Initialize(BufferSource* source) {
	return patch::ParseBuffer(source, &raw_delta_skip_) &&
	patch::ParseBuffer(source, &raw_delta_diff_);
	}

	base::Optional<RawDeltaUnit> RawDeltaSource::GetNext() {
	if (raw_delta_skip_.empty() \|\| raw_delta_diff_.empty())
	return base::nullopt;

	RawDeltaUnit raw_delta = {};
	uint32_t copy_offset_diff = 0;
	if (!patch::ParseVarUInt<uint32_t>(&raw_delta_skip_, &copy_offset_diff))
	return base::nullopt;
	base::CheckedNumeric<offset_t> copy_offset =
	copy_offset_diff + copy_offset_compensation_;
	if (!copy_offset.IsValid())
	return base::nullopt;
	raw_delta.copy_offset = copy_offset.ValueOrDie();

	if (!raw_delta_diff_.GetValue<int8_t>(&raw_delta.diff))
	return base::nullopt;

	// A 0 value for a delta.diff is considered invalid since it has no meaning.
	if (!raw_delta.diff)
	return base::nullopt;

	// We keep track of the compensation needed for next offset, taking into
	// account delta encoding and bias of -1.
	copy_offset_compensation_ = copy_offset + 1;
	if (!copy_offset_compensation_.IsValid())
	return base::nullopt;
	// \|raw_delta\| is assumed to always be safe/valid.
	return raw_delta;
	}

	/****** ReferenceDeltaSource ******/

	ReferenceDeltaSource::ReferenceDeltaSource() = default;
	ReferenceDeltaSource::ReferenceDeltaSource(const ReferenceDeltaSource&) =
	default;
	ReferenceDeltaSource::~ReferenceDeltaSource() = default;

	bool ReferenceDeltaSource::Initialize(BufferSource* source) {
	return patch::ParseBuffer(source, &source_);
	}

	base::Optional<int32_t> ReferenceDeltaSource::GetNext() {
	if (source_.empty())
	return base::nullopt;
	int32_t ref_delta = 0;
	if (!patch::ParseVarInt<int32_t>(&source_, &ref_delta))
	return base::nullopt;
	// \|ref_delta\| is assumed to always be safe/valid.
	return ref_delta;
	}

	/****** TargetSource ******/

	TargetSource::TargetSource() = default;
	TargetSource::TargetSource(const TargetSource&) = default;
	TargetSource::~TargetSource() = default;

	bool TargetSource::Initialize(BufferSource* source) {
	return patch::ParseBuffer(source, &extra_targets_);
	}

	base::Optional<offset_t> TargetSource::GetNext() {
	if (extra_targets_.empty())
	return base::nullopt;

	uint32_t target_diff = 0;
	if (!patch::ParseVarUInt<uint32_t>(&extra_targets_, &target_diff))
	return base::nullopt;
	base::CheckedNumeric<offset_t> target = target_diff + target_compensation_;
	if (!target.IsValid())
	return base::nullopt;

	// We keep track of the compensation needed for next target, taking into
	// account delta encoding and bias of -1.
	target_compensation_ = target + 1;
	if (!target_compensation_.IsValid())
	return base::nullopt;
	// Caveat: \|target\| will be a valid offset_t, but it's up to the caller to
	// check whether it's a valid offset for an image.
	return offset_t(target.ValueOrDie());
	}

	/****** PatchElementReader ******/

	PatchElementReader::PatchElementReader() = default;
	PatchElementReader::PatchElementReader(PatchElementReader&&) = default;
	PatchElementReader::~PatchElementReader() = default;

	bool PatchElementReader::Initialize(BufferSource* source) {
	bool ok =
	patch::ParseElementMatch(source, &element_match_) &&
	equivalences_.Initialize(source) && extra_data_.Initialize(source) &&
	ValidateEquivalencesAndExtraData() && raw_delta_.Initialize(source) &&
	reference_delta_.Initialize(source);
	if (!ok)
	return false;
	uint32_t pool_count = 0;
	if (!source->GetValue(&pool_count)) {
	LOG(ERROR) << "Impossible to read pool_count from source.";
	return false;
	}
	for (uint32_t i = 0; i < pool_count; ++i) {
	uint8_t pool_tag_value = 0;
	if (!source->GetValue(&pool_tag_value)) {
	LOG(ERROR) << "Impossible to read pool_tag from source.";
	return false;
	}
	PoolTag pool_tag(pool_tag_value);
	if (pool_tag == kNoPoolTag) {
	LOG(ERROR) << "Invalid pool_tag encountered in ExtraTargetList.";
	return false;
	}
	auto insert_result = extra_targets_.insert({pool_tag, {}});
	if (!insert_result.second) { // Element already present.
	LOG(ERROR) << "Multiple ExtraTargetList found for the same pool_tag.";
	return false;
	}
	if (!insert_result.first->second.Initialize(source))
	return false;
	}
	return true;
	}

	bool PatchElementReader::ValidateEquivalencesAndExtraData() {
	EquivalenceSource equivalences_copy = equivalences_;

	const size_t old_region_size = element_match_.old_element.size;
	const size_t new_region_size = element_match_.new_element.size;

	base::CheckedNumeric<uint32_t> total_length = 0;
	// Validate that each \|equivalence\| falls within the bounds of the
	// \|element_match_\| and are in order.
	offset_t prev_dst_end = 0;
	for (auto equivalence = equivalences_copy.GetNext(); equivalence.has_value();
	equivalence = equivalences_copy.GetNext()) {
	if (!RangeIsBounded(equivalence->src_offset, equivalence->length,
	old_region_size) \|\|
	!RangeIsBounded(equivalence->dst_offset, equivalence->length,
	new_region_size)) {
	LOG(ERROR) << "Out of bounds equivalence detected.";
	return false;
	}
	if (prev_dst_end > equivalence->dst_end()) {
	LOG(ERROR) << "Out of order equivalence detected.";
	return false;
	}
	prev_dst_end = equivalence->dst_end();
	total_length += equivalence->length;
	}
	if (!total_length.IsValid() \|\|
	element_match_.new_element.region().size < total_length.ValueOrDie() \|\|
	extra_data_.extra_data().size() !=
	element_match_.new_element.region().size -
	static_cast<size_t>(total_length.ValueOrDie())) {
	LOG(ERROR) << "Incorrect amount of extra_data.";
	return false;
	}
	return true;
	}

	/****** EnsemblePatchReader ******/

	base::Optional<EnsemblePatchReader> EnsemblePatchReader::Create(
	ConstBufferView buffer) {
	BufferSource source(buffer);
	EnsemblePatchReader patch;
	if (!patch.Initialize(&source))
	return base::nullopt;
	return patch;
	}

	EnsemblePatchReader::EnsemblePatchReader() = default;
	EnsemblePatchReader::EnsemblePatchReader(EnsemblePatchReader&&) = default;
	EnsemblePatchReader::~EnsemblePatchReader() = default;

	bool EnsemblePatchReader::Initialize(BufferSource* source) {
	if (!source->GetValue(&header_)) {
	LOG(ERROR) << "Impossible to read header from source.";
	return false;
	}
	if (header_.magic != PatchHeader::kMagic) {
	LOG(ERROR) << "Patch contains invalid magic.";
	return false;
	}
	// \|header_\| is assumed to be safe from this point forward.

	uint32_t element_count = 0;
	if (!source->GetValue(&element_count)) {
	LOG(ERROR) << "Impossible to read element_count from source.";
	return false;
	}

	offset_t current_dst_offset = 0;
	for (uint32_t i = 0; i < element_count; ++i) {
	PatchElementReader element_patch;
	if (!element_patch.Initialize(source))
	return false;

	if (!element_patch.old_element().FitsIn(header_.old_size) \|\|
	!element_patch.new_element().FitsIn(header_.new_size)) {
	LOG(ERROR) << "Invalid element encountered.";
	return false;
	}

	if (element_patch.new_element().offset != current_dst_offset) {
	LOG(ERROR) << "Invalid element encountered.";
	return false;
	}
	current_dst_offset = element_patch.new_element().EndOffset();

	elements_.push_back(std::move(element_patch));
	}
	if (current_dst_offset != header_.new_size) {
	LOG(ERROR) << "Patch elements don't fully cover new image file.";
	return false;
	}

	if (!source->empty()) {
	LOG(ERROR) << "Patch was not fully consumed.";
	return false;
	}

	return true;
	}

	bool EnsemblePatchReader::CheckOldFile(ConstBufferView old_image) const {
	return old_image.size() == header_.old_size &&
	CalculateCrc32(old_image.begin(), old_image.end()) == header_.old_crc;
	}

	bool EnsemblePatchReader::CheckNewFile(ConstBufferView new_image) const {
	return new_image.size() == header_.new_size &&
	CalculateCrc32(new_image.begin(), new_image.end()) == header_.new_crc;
	}

	} // namespace zucchini