payload_consumer/partition_writer.cc - platform/system/update_engine - Gitiles

 //
 // Copyright (C) 2020 The Android Open Source Project
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //      http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 //
 #include <update_engine/payload_consumer/partition_writer.h>

 #include <fcntl.h>
 #include <linux/fs.h>

 #include <algorithm>
 #include <initializer_list>
 #include <memory>
 #include <utility>
 #include <vector>

 #include <base/strings/string_number_conversions.h>
 #include <bsdiff/bspatch.h>
 #include <puffin/puffpatch.h>
 #include <bsdiff/file_interface.h>
 #include <puffin/stream.h>

 #include "update_engine/common/terminator.h"
 #include "update_engine/common/utils.h"
 #include "update_engine/payload_consumer/bzip_extent_writer.h"
 #include "update_engine/payload_consumer/cached_file_descriptor.h"
 #include "update_engine/payload_consumer/extent_reader.h"
 #include "update_engine/payload_consumer/extent_writer.h"
 #include "update_engine/payload_consumer/fec_file_descriptor.h"
 #include "update_engine/payload_consumer/file_descriptor_utils.h"
 #include "update_engine/payload_consumer/install_plan.h"
 #include "update_engine/payload_consumer/mount_history.h"
 #include "update_engine/payload_consumer/payload_constants.h"
 #include "update_engine/payload_consumer/xz_extent_writer.h"

 namespace chromeos_update_engine {

 namespace {
 constexpr uint64_t kCacheSize = 1024 * 1024;  // 1MB

 // Discard the tail of the block device referenced by |fd|, from the offset
 // |data_size| until the end of the block device. Returns whether the data was
 // discarded.

 bool DiscardPartitionTail(const FileDescriptorPtr& fd, uint64_t data_size) {
   uint64_t part_size = fd->BlockDevSize();
   if (!part_size || part_size <= data_size)
     return false;

   struct blkioctl_request {
     int number;
     const char* name;
   };
   const std::initializer_list<blkioctl_request> blkioctl_requests = {
       {BLKDISCARD, "BLKDISCARD"},
       {BLKSECDISCARD, "BLKSECDISCARD"},
 #ifdef BLKZEROOUT
       {BLKZEROOUT, "BLKZEROOUT"},
 #endif
   };
   for (const auto& req : blkioctl_requests) {
     int error = 0;
     if (fd->BlkIoctl(req.number, data_size, part_size - data_size, &error) &&
         error == 0) {
       return true;
     }
     LOG(WARNING) << "Error discarding the last "
                  << (part_size - data_size) / 1024 << " KiB using ioctl("
                  << req.name << ")";
   }
   return false;
 }

 }  // namespace

 // Opens path for read/write. On success returns an open FileDescriptor
 // and sets *err to 0. On failure, sets *err to errno and returns nullptr.
 FileDescriptorPtr OpenFile(const char* path,
                            int mode,
                            bool cache_writes,
                            int* err) {
   // Try to mark the block device read-only based on the mode. Ignore any
   // failure since this won't work when passing regular files.
   bool read_only = (mode & O_ACCMODE) == O_RDONLY;
   utils::SetBlockDeviceReadOnly(path, read_only);

   FileDescriptorPtr fd(new EintrSafeFileDescriptor());
   if (cache_writes && !read_only) {
     fd = FileDescriptorPtr(new CachedFileDescriptor(fd, kCacheSize));
     LOG(INFO) << "Caching writes.";
   }
   if (!fd->Open(path, mode, 000)) {
     *err = errno;
     PLOG(ERROR) << "Unable to open file " << path;
     return nullptr;
   }
   *err = 0;
   return fd;
 }

 class BsdiffExtentFile : public bsdiff::FileInterface {
  public:
   BsdiffExtentFile(std::unique_ptr<ExtentReader> reader, size_t size)
       : BsdiffExtentFile(std::move(reader), nullptr, size) {}
   BsdiffExtentFile(std::unique_ptr<ExtentWriter> writer, size_t size)
       : BsdiffExtentFile(nullptr, std::move(writer), size) {}

   ~BsdiffExtentFile() override = default;

   bool Read(void* buf, size_t count, size_t* bytes_read) override {
     TEST_AND_RETURN_FALSE(reader_->Read(buf, count));
     *bytes_read = count;
     offset_ += count;
     return true;
   }

   bool Write(const void* buf, size_t count, size_t* bytes_written) override {
     TEST_AND_RETURN_FALSE(writer_->Write(buf, count));
     *bytes_written = count;
     offset_ += count;
     return true;
   }

   bool Seek(off_t pos) override {
     if (reader_ != nullptr) {
       TEST_AND_RETURN_FALSE(reader_->Seek(pos));
       offset_ = pos;
     } else {
       // For writes technically there should be no change of position, or it
       // should be equivalent of current offset.
       TEST_AND_RETURN_FALSE(offset_ == static_cast<uint64_t>(pos));
     }
     return true;
   }

   bool Close() override { return true; }

   bool GetSize(uint64_t* size) override {
     *size = size_;
     return true;
   }

  private:
   BsdiffExtentFile(std::unique_ptr<ExtentReader> reader,
                    std::unique_ptr<ExtentWriter> writer,
                    size_t size)
       : reader_(std::move(reader)),
         writer_(std::move(writer)),
         size_(size),
         offset_(0) {}

   std::unique_ptr<ExtentReader> reader_;
   std::unique_ptr<ExtentWriter> writer_;
   uint64_t size_;
   uint64_t offset_;

   DISALLOW_COPY_AND_ASSIGN(BsdiffExtentFile);
 };
 // A class to be passed to |puffpatch| for reading from |source_fd_| and writing
 // into |target_fd_|.
 class PuffinExtentStream : public puffin::StreamInterface {
  public:
   // Constructor for creating a stream for reading from an |ExtentReader|.
   PuffinExtentStream(std::unique_ptr<ExtentReader> reader, uint64_t size)
       : PuffinExtentStream(std::move(reader), nullptr, size) {}

   // Constructor for creating a stream for writing to an |ExtentWriter|.
   PuffinExtentStream(std::unique_ptr<ExtentWriter> writer, uint64_t size)
       : PuffinExtentStream(nullptr, std::move(writer), size) {}

   ~PuffinExtentStream() override = default;

   bool GetSize(uint64_t* size) const override {
     *size = size_;
     return true;
   }

   bool GetOffset(uint64_t* offset) const override {
     *offset = offset_;
     return true;
   }

   bool Seek(uint64_t offset) override {
     if (is_read_) {
       TEST_AND_RETURN_FALSE(reader_->Seek(offset));
       offset_ = offset;
     } else {
       // For writes technically there should be no change of position, or it
       // should equivalent of current offset.
       TEST_AND_RETURN_FALSE(offset_ == offset);
     }
     return true;
   }

   bool Read(void* buffer, size_t count) override {
     TEST_AND_RETURN_FALSE(is_read_);
     TEST_AND_RETURN_FALSE(reader_->Read(buffer, count));
     offset_ += count;
     return true;
   }

   bool Write(const void* buffer, size_t count) override {
     TEST_AND_RETURN_FALSE(!is_read_);
     TEST_AND_RETURN_FALSE(writer_->Write(buffer, count));
     offset_ += count;
     return true;
   }

   bool Close() override { return true; }

  private:
   PuffinExtentStream(std::unique_ptr<ExtentReader> reader,
                      std::unique_ptr<ExtentWriter> writer,
                      uint64_t size)
       : reader_(std::move(reader)),
         writer_(std::move(writer)),
         size_(size),
         offset_(0),
         is_read_(reader_ ? true : false) {}

   std::unique_ptr<ExtentReader> reader_;
   std::unique_ptr<ExtentWriter> writer_;
   uint64_t size_;
   uint64_t offset_;
   bool is_read_;

   DISALLOW_COPY_AND_ASSIGN(PuffinExtentStream);
 };

 PartitionWriter::PartitionWriter(
     const PartitionUpdate& partition_update,
     const InstallPlan::Partition& install_part,
     DynamicPartitionControlInterface* dynamic_control,
     size_t block_size,
     bool is_interactive)
     : partition_update_(partition_update),
       install_part_(install_part),
       dynamic_control_(dynamic_control),
       interactive_(is_interactive),
       block_size_(block_size) {}

 PartitionWriter::~PartitionWriter() {
   Close();
 }

 bool PartitionWriter::OpenSourcePartition(uint32_t source_slot,
                                           bool source_may_exist) {
   source_path_.clear();
   if (!source_may_exist) {
     return true;
   }
   if (install_part_.source_size > 0 && !install_part_.source_path.empty()) {
     source_path_ = install_part_.source_path;
     int err;
     source_fd_ = OpenFile(source_path_.c_str(), O_RDONLY, false, &err);
     if (source_fd_ == nullptr) {
       LOG(ERROR) << "Unable to open source partition " << install_part_.name
                  << " on slot " << BootControlInterface::SlotName(source_slot)
                  << ", file " << source_path_;
       return false;
     }
   }
   return true;
 }

 bool PartitionWriter::Init(const InstallPlan* install_plan,
                            bool source_may_exist,
                            size_t next_op_index) {
   const PartitionUpdate& partition = partition_update_;
   uint32_t source_slot = install_plan->source_slot;
   uint32_t target_slot = install_plan->target_slot;
   TEST_AND_RETURN_FALSE(OpenSourcePartition(source_slot, source_may_exist));

   // We shouldn't open the source partition in certain cases, e.g. some dynamic
   // partitions in delta payload, partitions included in the full payload for
   // partial updates. Use the source size as the indicator.

   target_path_ = install_part_.target_path;
   int err;

   int flags = O_RDWR;
   if (!interactive_)
     flags |= O_DSYNC;

   LOG(INFO) << "Opening " << target_path_ << " partition with"
             << (interactive_ ? "out" : "") << " O_DSYNC";

   target_fd_ = OpenFile(target_path_.c_str(), flags, true, &err);
   if (!target_fd_) {
     LOG(ERROR) << "Unable to open target partition "
                << partition.partition_name() << " on slot "
                << BootControlInterface::SlotName(target_slot) << ", file "
                << target_path_;
     return false;
   }

   LOG(INFO) << "Applying " << partition.operations().size()
             << " operations to partition \"" << partition.partition_name()
             << "\"";

   // Discard the end of the partition, but ignore failures.
   DiscardPartitionTail(target_fd_, install_part_.target_size);

   return true;
 }

 bool PartitionWriter::PerformReplaceOperation(const InstallOperation& operation,
                                               const void* data,
                                               size_t count) {
   // Setup the ExtentWriter stack based on the operation type.
   std::unique_ptr<ExtentWriter> writer = CreateBaseExtentWriter();

   if (operation.type() == InstallOperation::REPLACE_BZ) {
     writer.reset(new BzipExtentWriter(std::move(writer)));
   } else if (operation.type() == InstallOperation::REPLACE_XZ) {
     writer.reset(new XzExtentWriter(std::move(writer)));
   }

   TEST_AND_RETURN_FALSE(
       writer->Init(target_fd_, operation.dst_extents(), block_size_));
   TEST_AND_RETURN_FALSE(writer->Write(data, operation.data_length()));

   return true;
 }

 bool PartitionWriter::PerformZeroOrDiscardOperation(
     const InstallOperation& operation) {
 #ifdef BLKZEROOUT
   bool attempt_ioctl = true;
   int request =
       (operation.type() == InstallOperation::ZERO ? BLKZEROOUT : BLKDISCARD);
 #else   // !defined(BLKZEROOUT)
   bool attempt_ioctl = false;
   int request = 0;
 #endif  // !defined(BLKZEROOUT)

   brillo::Blob zeros;
   for (const Extent& extent : operation.dst_extents()) {
     const uint64_t start = extent.start_block() * block_size_;
     const uint64_t length = extent.num_blocks() * block_size_;
     if (attempt_ioctl) {
       int result = 0;
       if (target_fd_->BlkIoctl(request, start, length, &result) && result == 0)
         continue;
       attempt_ioctl = false;
     }
     // In case of failure, we fall back to writing 0 to the selected region.
     zeros.resize(16 * block_size_);
     for (uint64_t offset = 0; offset < length; offset += zeros.size()) {
       uint64_t chunk_length =
           std::min(length - offset, static_cast<uint64_t>(zeros.size()));
       TEST_AND_RETURN_FALSE(utils::WriteAll(
           target_fd_, zeros.data(), chunk_length, start + offset));
     }
   }
   return true;
 }

 bool PartitionWriter::PerformSourceCopyOperation(
     const InstallOperation& operation, ErrorCode* error) {
   TEST_AND_RETURN_FALSE(source_fd_ != nullptr);

   // The device may optimize the SOURCE_COPY operation.
   // Being this a device-specific optimization let DynamicPartitionController
   // decide it the operation should be skipped.
   const PartitionUpdate& partition = partition_update_;
   const auto& partition_control = dynamic_control_;

   InstallOperation buf;
   bool should_optimize = partition_control->OptimizeOperation(
       partition.partition_name(), operation, &buf);
   const InstallOperation& optimized = should_optimize ? buf : operation;

   if (operation.has_src_sha256_hash()) {
     bool read_ok;
     brillo::Blob source_hash;
     brillo::Blob expected_source_hash(operation.src_sha256_hash().begin(),
                                       operation.src_sha256_hash().end());

     // We fall back to use the error corrected device if the hash of the raw
     // device doesn't match or there was an error reading the source partition.
     // Note that this code will also fall back if writing the target partition
     // fails.
     if (should_optimize) {
       // Hash operation.src_extents(), then copy optimized.src_extents to
       // optimized.dst_extents.
       read_ok =
           fd_utils::ReadAndHashExtents(
               source_fd_, operation.src_extents(), block_size_, &source_hash) &&
           fd_utils::CopyAndHashExtents(source_fd_,
                                        optimized.src_extents(),
                                        target_fd_,
                                        optimized.dst_extents(),
                                        block_size_,
                                        nullptr /* skip hashing */);
     } else {
       read_ok = fd_utils::CopyAndHashExtents(source_fd_,
                                              operation.src_extents(),
                                              target_fd_,
                                              operation.dst_extents(),
                                              block_size_,
                                              &source_hash);
     }
     if (read_ok && expected_source_hash == source_hash)
       return true;
     LOG(WARNING) << "Source hash from RAW device mismatched, attempting to "
                     "correct using ECC";
     if (!OpenCurrentECCPartition()) {
       // The following function call will return false since the source hash
       // mismatches, but we still want to call it so it prints the appropriate
       // log message.
       return ValidateSourceHash(source_hash, operation, source_fd_, error);
     }

     LOG(WARNING) << "Source hash from RAW device mismatched: found "
                  << base::HexEncode(source_hash.data(), source_hash.size())
                  << ", expected "
                  << base::HexEncode(expected_source_hash.data(),
                                     expected_source_hash.size());
     if (should_optimize) {
       TEST_AND_RETURN_FALSE(fd_utils::ReadAndHashExtents(
           source_ecc_fd_, operation.src_extents(), block_size_, &source_hash));
       TEST_AND_RETURN_FALSE(
           fd_utils::CopyAndHashExtents(source_ecc_fd_,
                                        optimized.src_extents(),
                                        target_fd_,
                                        optimized.dst_extents(),
                                        block_size_,
                                        nullptr /* skip hashing */));
     } else {
       TEST_AND_RETURN_FALSE(
           fd_utils::CopyAndHashExtents(source_ecc_fd_,
                                        operation.src_extents(),
                                        target_fd_,
                                        operation.dst_extents(),
                                        block_size_,
                                        &source_hash));
     }
     TEST_AND_RETURN_FALSE(
         ValidateSourceHash(source_hash, operation, source_ecc_fd_, error));
     // At this point reading from the error corrected device worked, but
     // reading from the raw device failed, so this is considered a recovered
     // failure.
     source_ecc_recovered_failures_++;
   } else {
     // When the operation doesn't include a source hash, we attempt the error
     // corrected device first since we can't verify the block in the raw device
     // at this point, but we fall back to the raw device since the error
     // corrected device can be shorter or not available.

     if (OpenCurrentECCPartition() &&
         fd_utils::CopyAndHashExtents(source_ecc_fd_,
                                      optimized.src_extents(),
                                      target_fd_,
                                      optimized.dst_extents(),
                                      block_size_,
                                      nullptr)) {
       return true;
     }
     TEST_AND_RETURN_FALSE(fd_utils::CopyAndHashExtents(source_fd_,
                                                        optimized.src_extents(),
                                                        target_fd_,
                                                        optimized.dst_extents(),
                                                        block_size_,
                                                        nullptr));
   }
   return true;
 }

 bool PartitionWriter::PerformSourceBsdiffOperation(
     const InstallOperation& operation,
     ErrorCode* error,
     const void* data,
     size_t count) {
   FileDescriptorPtr source_fd = ChooseSourceFD(operation, error);
   TEST_AND_RETURN_FALSE(source_fd != nullptr);

   auto reader = std::make_unique<DirectExtentReader>();
   TEST_AND_RETURN_FALSE(
       reader->Init(source_fd, operation.src_extents(), block_size_));
   auto src_file = std::make_unique<BsdiffExtentFile>(
       std::move(reader),
       utils::BlocksInExtents(operation.src_extents()) * block_size_);

   auto writer = CreateBaseExtentWriter();
   TEST_AND_RETURN_FALSE(
       writer->Init(target_fd_, operation.dst_extents(), block_size_));
   auto dst_file = std::make_unique<BsdiffExtentFile>(
       std::move(writer),
       utils::BlocksInExtents(operation.dst_extents()) * block_size_);

   TEST_AND_RETURN_FALSE(bsdiff::bspatch(std::move(src_file),
                                         std::move(dst_file),
                                         reinterpret_cast<const uint8_t*>(data),
                                         count) == 0);
   return true;
 }

 bool PartitionWriter::PerformPuffDiffOperation(
     const InstallOperation& operation,
     ErrorCode* error,
     const void* data,
     size_t count) {
   FileDescriptorPtr source_fd = ChooseSourceFD(operation, error);
   TEST_AND_RETURN_FALSE(source_fd != nullptr);

   auto reader = std::make_unique<DirectExtentReader>();
   TEST_AND_RETURN_FALSE(
       reader->Init(source_fd, operation.src_extents(), block_size_));
   puffin::UniqueStreamPtr src_stream(new PuffinExtentStream(
       std::move(reader),
       utils::BlocksInExtents(operation.src_extents()) * block_size_));

   auto writer = CreateBaseExtentWriter();
   TEST_AND_RETURN_FALSE(
       writer->Init(target_fd_, operation.dst_extents(), block_size_));
   puffin::UniqueStreamPtr dst_stream(new PuffinExtentStream(
       std::move(writer),
       utils::BlocksInExtents(operation.dst_extents()) * block_size_));

   constexpr size_t kMaxCacheSize = 5 * 1024 * 1024;  // Total 5MB cache.
   TEST_AND_RETURN_FALSE(
       puffin::PuffPatch(std::move(src_stream),
                         std::move(dst_stream),
                         reinterpret_cast<const uint8_t*>(data),
                         count,
                         kMaxCacheSize));
   return true;
 }

 FileDescriptorPtr PartitionWriter::ChooseSourceFD(
     const InstallOperation& operation, ErrorCode* error) {
   if (source_fd_ == nullptr) {
     LOG(ERROR) << "ChooseSourceFD fail: source_fd_ == nullptr";
     return nullptr;
   }

   if (!operation.has_src_sha256_hash()) {
     // When the operation doesn't include a source hash, we attempt the error
     // corrected device first since we can't verify the block in the raw device
     // at this point, but we first need to make sure all extents are readable
     // since the error corrected device can be shorter or not available.
     if (OpenCurrentECCPartition() &&
         fd_utils::ReadAndHashExtents(
             source_ecc_fd_, operation.src_extents(), block_size_, nullptr)) {
       return source_ecc_fd_;
     }
     return source_fd_;
   }

   brillo::Blob source_hash;
   brillo::Blob expected_source_hash(operation.src_sha256_hash().begin(),
                                     operation.src_sha256_hash().end());
   if (fd_utils::ReadAndHashExtents(
           source_fd_, operation.src_extents(), block_size_, &source_hash) &&
       source_hash == expected_source_hash) {
     return source_fd_;
   }
   // We fall back to use the error corrected device if the hash of the raw
   // device doesn't match or there was an error reading the source partition.
   if (!OpenCurrentECCPartition()) {
     // The following function call will return false since the source hash
     // mismatches, but we still want to call it so it prints the appropriate
     // log message.
     ValidateSourceHash(source_hash, operation, source_fd_, error);
     return nullptr;
   }
   LOG(WARNING) << "Source hash from RAW device mismatched: found "
                << base::HexEncode(source_hash.data(), source_hash.size())
                << ", expected "
                << base::HexEncode(expected_source_hash.data(),
                                   expected_source_hash.size());

   if (fd_utils::ReadAndHashExtents(
           source_ecc_fd_, operation.src_extents(), block_size_, &source_hash) &&
       ValidateSourceHash(source_hash, operation, source_ecc_fd_, error)) {
     // At this point reading from the error corrected device worked, but
     // reading from the raw device failed, so this is considered a recovered
     // failure.
     source_ecc_recovered_failures_++;
     return source_ecc_fd_;
   }
   return nullptr;
 }

 bool PartitionWriter::OpenCurrentECCPartition() {
   // No support for ECC for full payloads.
   // Full payload should not have any opeartion that requires ECC partitions.
   if (source_ecc_fd_)
     return true;

   if (source_ecc_open_failure_)
     return false;

 #if USE_FEC
   const PartitionUpdate& partition = partition_update_;
   const InstallPlan::Partition& install_part = install_part_;
   std::string path = install_part.source_path;
   FileDescriptorPtr fd(new FecFileDescriptor());
   if (!fd->Open(path.c_str(), O_RDONLY, 0)) {
     PLOG(ERROR) << "Unable to open ECC source partition "
                 << partition.partition_name() << ", file " << path;
     source_ecc_open_failure_ = true;
     return false;
   }
   source_ecc_fd_ = fd;
 #else
   // No support for ECC compiled.
   source_ecc_open_failure_ = true;
 #endif  // USE_FEC

   return !source_ecc_open_failure_;
 }

 int PartitionWriter::Close() {
   int err = 0;
   if (source_fd_ && !source_fd_->Close()) {
     err = errno;
     PLOG(ERROR) << "Error closing source partition";
     if (!err)
       err = 1;
   }
   source_fd_.reset();
   source_path_.clear();

   if (target_fd_ && !target_fd_->Close()) {
     err = errno;
     PLOG(ERROR) << "Error closing target partition";
     if (!err)
       err = 1;
   }
   target_fd_.reset();
   target_path_.clear();

   if (source_ecc_fd_ && !source_ecc_fd_->Close()) {
     err = errno;
     PLOG(ERROR) << "Error closing ECC source partition";
     if (!err)
       err = 1;
   }
   source_ecc_fd_.reset();
   source_ecc_open_failure_ = false;
   return -err;
 }

 void PartitionWriter::CheckpointUpdateProgress(size_t next_op_index) {
   target_fd_->Flush();
 }

 std::unique_ptr<ExtentWriter> PartitionWriter::CreateBaseExtentWriter() {
   return std::make_unique<DirectExtentWriter>();
 }

 }  // namespace chromeos_update_engine
	//
	// Copyright (C) 2020 The Android Open Source Project
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	//
	#include <update_engine/payload_consumer/partition_writer.h>

	#include <fcntl.h>
	#include <linux/fs.h>

	#include <algorithm>
	#include <initializer_list>
	#include <memory>
	#include <utility>
	#include <vector>

	#include <base/strings/string_number_conversions.h>
	#include <bsdiff/bspatch.h>
	#include <puffin/puffpatch.h>
	#include <bsdiff/file_interface.h>
	#include <puffin/stream.h>

	#include "update_engine/common/terminator.h"
	#include "update_engine/common/utils.h"
	#include "update_engine/payload_consumer/bzip_extent_writer.h"
	#include "update_engine/payload_consumer/cached_file_descriptor.h"
	#include "update_engine/payload_consumer/extent_reader.h"
	#include "update_engine/payload_consumer/extent_writer.h"
	#include "update_engine/payload_consumer/fec_file_descriptor.h"
	#include "update_engine/payload_consumer/file_descriptor_utils.h"
	#include "update_engine/payload_consumer/install_plan.h"
	#include "update_engine/payload_consumer/mount_history.h"
	#include "update_engine/payload_consumer/payload_constants.h"
	#include "update_engine/payload_consumer/xz_extent_writer.h"

	namespace chromeos_update_engine {

	namespace {
	constexpr uint64_t kCacheSize = 1024 * 1024; // 1MB

	// Discard the tail of the block device referenced by \|fd\|, from the offset
	// \|data_size\| until the end of the block device. Returns whether the data was
	// discarded.

	bool DiscardPartitionTail(const FileDescriptorPtr& fd, uint64_t data_size) {
	uint64_t part_size = fd->BlockDevSize();
	if (!part_size \|\| part_size <= data_size)
	return false;

	struct blkioctl_request {
	int number;
	const char* name;
	};
	const std::initializer_list<blkioctl_request> blkioctl_requests = {
	{BLKDISCARD, "BLKDISCARD"},
	{BLKSECDISCARD, "BLKSECDISCARD"},
	#ifdef BLKZEROOUT
	{BLKZEROOUT, "BLKZEROOUT"},
	#endif
	};
	for (const auto& req : blkioctl_requests) {
	int error = 0;
	if (fd->BlkIoctl(req.number, data_size, part_size - data_size, &error) &&
	error == 0) {
	return true;
	}
	LOG(WARNING) << "Error discarding the last "
	<< (part_size - data_size) / 1024 << " KiB using ioctl("
	<< req.name << ")";
	}
	return false;
	}

	} // namespace

	// Opens path for read/write. On success returns an open FileDescriptor
	// and sets err to 0. On failure, sets err to errno and returns nullptr.
	FileDescriptorPtr OpenFile(const char* path,
	int mode,
	bool cache_writes,
	int* err) {
	// Try to mark the block device read-only based on the mode. Ignore any
	// failure since this won't work when passing regular files.
	bool read_only = (mode & O_ACCMODE) == O_RDONLY;
	utils::SetBlockDeviceReadOnly(path, read_only);

	FileDescriptorPtr fd(new EintrSafeFileDescriptor());
	if (cache_writes && !read_only) {
	fd = FileDescriptorPtr(new CachedFileDescriptor(fd, kCacheSize));
	LOG(INFO) << "Caching writes.";
	}
	if (!fd->Open(path, mode, 000)) {
	*err = errno;
	PLOG(ERROR) << "Unable to open file " << path;
	return nullptr;
	}
	*err = 0;
	return fd;
	}

	class BsdiffExtentFile : public bsdiff::FileInterface {
	public:
	BsdiffExtentFile(std::unique_ptr<ExtentReader> reader, size_t size)
	: BsdiffExtentFile(std::move(reader), nullptr, size) {}
	BsdiffExtentFile(std::unique_ptr<ExtentWriter> writer, size_t size)
	: BsdiffExtentFile(nullptr, std::move(writer), size) {}

	~BsdiffExtentFile() override = default;

	bool Read(void* buf, size_t count, size_t* bytes_read) override {
	TEST_AND_RETURN_FALSE(reader_->Read(buf, count));
	*bytes_read = count;
	offset_ += count;
	return true;
	}

	bool Write(const void* buf, size_t count, size_t* bytes_written) override {
	TEST_AND_RETURN_FALSE(writer_->Write(buf, count));
	*bytes_written = count;
	offset_ += count;
	return true;
	}

	bool Seek(off_t pos) override {
	if (reader_ != nullptr) {
	TEST_AND_RETURN_FALSE(reader_->Seek(pos));
	offset_ = pos;
	} else {
	// For writes technically there should be no change of position, or it
	// should be equivalent of current offset.
	TEST_AND_RETURN_FALSE(offset_ == static_cast<uint64_t>(pos));
	}
	return true;
	}

	bool Close() override { return true; }

	bool GetSize(uint64_t* size) override {
	*size = size_;
	return true;
	}

	private:
	BsdiffExtentFile(std::unique_ptr<ExtentReader> reader,
	std::unique_ptr<ExtentWriter> writer,
	size_t size)
	: reader_(std::move(reader)),
	writer_(std::move(writer)),
	size_(size),
	offset_(0) {}

	std::unique_ptr<ExtentReader> reader_;
	std::unique_ptr<ExtentWriter> writer_;
	uint64_t size_;
	uint64_t offset_;

	DISALLOW_COPY_AND_ASSIGN(BsdiffExtentFile);
	};
	// A class to be passed to \|puffpatch\| for reading from \|source_fd_\| and writing
	// into \|target_fd_\|.
	class PuffinExtentStream : public puffin::StreamInterface {
	public:
	// Constructor for creating a stream for reading from an \|ExtentReader\|.
	PuffinExtentStream(std::unique_ptr<ExtentReader> reader, uint64_t size)
	: PuffinExtentStream(std::move(reader), nullptr, size) {}

	// Constructor for creating a stream for writing to an \|ExtentWriter\|.
	PuffinExtentStream(std::unique_ptr<ExtentWriter> writer, uint64_t size)
	: PuffinExtentStream(nullptr, std::move(writer), size) {}

	~PuffinExtentStream() override = default;

	bool GetSize(uint64_t* size) const override {
	*size = size_;
	return true;
	}

	bool GetOffset(uint64_t* offset) const override {
	*offset = offset_;
	return true;
	}

	bool Seek(uint64_t offset) override {
	if (is_read_) {
	TEST_AND_RETURN_FALSE(reader_->Seek(offset));
	offset_ = offset;
	} else {
	// For writes technically there should be no change of position, or it
	// should equivalent of current offset.
	TEST_AND_RETURN_FALSE(offset_ == offset);
	}
	return true;
	}

	bool Read(void* buffer, size_t count) override {
	TEST_AND_RETURN_FALSE(is_read_);
	TEST_AND_RETURN_FALSE(reader_->Read(buffer, count));
	offset_ += count;
	return true;
	}

	bool Write(const void* buffer, size_t count) override {
	TEST_AND_RETURN_FALSE(!is_read_);
	TEST_AND_RETURN_FALSE(writer_->Write(buffer, count));
	offset_ += count;
	return true;
	}

	bool Close() override { return true; }

	private:
	PuffinExtentStream(std::unique_ptr<ExtentReader> reader,
	std::unique_ptr<ExtentWriter> writer,
	uint64_t size)
	: reader_(std::move(reader)),
	writer_(std::move(writer)),
	size_(size),
	offset_(0),
	is_read_(reader_ ? true : false) {}

	std::unique_ptr<ExtentReader> reader_;
	std::unique_ptr<ExtentWriter> writer_;
	uint64_t size_;
	uint64_t offset_;
	bool is_read_;

	DISALLOW_COPY_AND_ASSIGN(PuffinExtentStream);
	};

	PartitionWriter::PartitionWriter(
	const PartitionUpdate& partition_update,
	const InstallPlan::Partition& install_part,
	DynamicPartitionControlInterface* dynamic_control,
	size_t block_size,
	bool is_interactive)
	: partition_update_(partition_update),
	install_part_(install_part),
	dynamic_control_(dynamic_control),
	interactive_(is_interactive),
	block_size_(block_size) {}

	PartitionWriter::~PartitionWriter() {
	Close();
	}

	bool PartitionWriter::OpenSourcePartition(uint32_t source_slot,
	bool source_may_exist) {
	source_path_.clear();
	if (!source_may_exist) {
	return true;
	}
	if (install_part_.source_size > 0 && !install_part_.source_path.empty()) {
	source_path_ = install_part_.source_path;
	int err;
	source_fd_ = OpenFile(source_path_.c_str(), O_RDONLY, false, &err);
	if (source_fd_ == nullptr) {
	LOG(ERROR) << "Unable to open source partition " << install_part_.name
	<< " on slot " << BootControlInterface::SlotName(source_slot)
	<< ", file " << source_path_;
	return false;
	}
	}
	return true;
	}

	bool PartitionWriter::Init(const InstallPlan* install_plan,
	bool source_may_exist,
	size_t next_op_index) {
	const PartitionUpdate& partition = partition_update_;
	uint32_t source_slot = install_plan->source_slot;
	uint32_t target_slot = install_plan->target_slot;
	TEST_AND_RETURN_FALSE(OpenSourcePartition(source_slot, source_may_exist));

	// We shouldn't open the source partition in certain cases, e.g. some dynamic
	// partitions in delta payload, partitions included in the full payload for
	// partial updates. Use the source size as the indicator.

	target_path_ = install_part_.target_path;
	int err;

	int flags = O_RDWR;
	if (!interactive_)
	flags \|= O_DSYNC;

	LOG(INFO) << "Opening " << target_path_ << " partition with"
	<< (interactive_ ? "out" : "") << " O_DSYNC";

	target_fd_ = OpenFile(target_path_.c_str(), flags, true, &err);
	if (!target_fd_) {
	LOG(ERROR) << "Unable to open target partition "
	<< partition.partition_name() << " on slot "
	<< BootControlInterface::SlotName(target_slot) << ", file "
	<< target_path_;
	return false;
	}

	LOG(INFO) << "Applying " << partition.operations().size()
	<< " operations to partition \"" << partition.partition_name()
	<< "\"";

	// Discard the end of the partition, but ignore failures.
	DiscardPartitionTail(target_fd_, install_part_.target_size);

	return true;
	}

	bool PartitionWriter::PerformReplaceOperation(const InstallOperation& operation,
	const void* data,
	size_t count) {
	// Setup the ExtentWriter stack based on the operation type.
	std::unique_ptr<ExtentWriter> writer = CreateBaseExtentWriter();

	if (operation.type() == InstallOperation::REPLACE_BZ) {
	writer.reset(new BzipExtentWriter(std::move(writer)));
	} else if (operation.type() == InstallOperation::REPLACE_XZ) {
	writer.reset(new XzExtentWriter(std::move(writer)));
	}

	TEST_AND_RETURN_FALSE(
	writer->Init(target_fd_, operation.dst_extents(), block_size_));
	TEST_AND_RETURN_FALSE(writer->Write(data, operation.data_length()));

	return true;
	}

	bool PartitionWriter::PerformZeroOrDiscardOperation(
	const InstallOperation& operation) {
	#ifdef BLKZEROOUT
	bool attempt_ioctl = true;
	int request =
	(operation.type() == InstallOperation::ZERO ? BLKZEROOUT : BLKDISCARD);
	#else // !defined(BLKZEROOUT)
	bool attempt_ioctl = false;
	int request = 0;
	#endif // !defined(BLKZEROOUT)

	brillo::Blob zeros;
	for (const Extent& extent : operation.dst_extents()) {
	const uint64_t start = extent.start_block() * block_size_;
	const uint64_t length = extent.num_blocks() * block_size_;
	if (attempt_ioctl) {
	int result = 0;
	if (target_fd_->BlkIoctl(request, start, length, &result) && result == 0)
	continue;
	attempt_ioctl = false;
	}
	// In case of failure, we fall back to writing 0 to the selected region.
	zeros.resize(16 * block_size_);
	for (uint64_t offset = 0; offset < length; offset += zeros.size()) {
	uint64_t chunk_length =
	std::min(length - offset, static_cast<uint64_t>(zeros.size()));
	TEST_AND_RETURN_FALSE(utils::WriteAll(
	target_fd_, zeros.data(), chunk_length, start + offset));
	}
	}
	return true;
	}

	bool PartitionWriter::PerformSourceCopyOperation(
	const InstallOperation& operation, ErrorCode* error) {
	TEST_AND_RETURN_FALSE(source_fd_ != nullptr);

	// The device may optimize the SOURCE_COPY operation.
	// Being this a device-specific optimization let DynamicPartitionController
	// decide it the operation should be skipped.
	const PartitionUpdate& partition = partition_update_;
	const auto& partition_control = dynamic_control_;

	InstallOperation buf;
	bool should_optimize = partition_control->OptimizeOperation(
	partition.partition_name(), operation, &buf);
	const InstallOperation& optimized = should_optimize ? buf : operation;

	if (operation.has_src_sha256_hash()) {
	bool read_ok;
	brillo::Blob source_hash;
	brillo::Blob expected_source_hash(operation.src_sha256_hash().begin(),
	operation.src_sha256_hash().end());

	// We fall back to use the error corrected device if the hash of the raw
	// device doesn't match or there was an error reading the source partition.
	// Note that this code will also fall back if writing the target partition
	// fails.
	if (should_optimize) {
	// Hash operation.src_extents(), then copy optimized.src_extents to
	// optimized.dst_extents.
	read_ok =
	fd_utils::ReadAndHashExtents(
	source_fd_, operation.src_extents(), block_size_, &source_hash) &&
	fd_utils::CopyAndHashExtents(source_fd_,
	optimized.src_extents(),
	target_fd_,
	optimized.dst_extents(),
	block_size_,
	nullptr /* skip hashing */);
	} else {
	read_ok = fd_utils::CopyAndHashExtents(source_fd_,
	operation.src_extents(),
	target_fd_,
	operation.dst_extents(),
	block_size_,
	&source_hash);
	}
	if (read_ok && expected_source_hash == source_hash)
	return true;
	LOG(WARNING) << "Source hash from RAW device mismatched, attempting to "
	"correct using ECC";
	if (!OpenCurrentECCPartition()) {
	// The following function call will return false since the source hash
	// mismatches, but we still want to call it so it prints the appropriate
	// log message.
	return ValidateSourceHash(source_hash, operation, source_fd_, error);
	}

	LOG(WARNING) << "Source hash from RAW device mismatched: found "
	<< base::HexEncode(source_hash.data(), source_hash.size())
	<< ", expected "
	<< base::HexEncode(expected_source_hash.data(),
	expected_source_hash.size());
	if (should_optimize) {
	TEST_AND_RETURN_FALSE(fd_utils::ReadAndHashExtents(
	source_ecc_fd_, operation.src_extents(), block_size_, &source_hash));
	TEST_AND_RETURN_FALSE(
	fd_utils::CopyAndHashExtents(source_ecc_fd_,
	optimized.src_extents(),
	target_fd_,
	optimized.dst_extents(),
	block_size_,
	nullptr /* skip hashing */));
	} else {
	TEST_AND_RETURN_FALSE(
	fd_utils::CopyAndHashExtents(source_ecc_fd_,
	operation.src_extents(),
	target_fd_,
	operation.dst_extents(),
	block_size_,
	&source_hash));
	}
	TEST_AND_RETURN_FALSE(
	ValidateSourceHash(source_hash, operation, source_ecc_fd_, error));
	// At this point reading from the error corrected device worked, but
	// reading from the raw device failed, so this is considered a recovered
	// failure.
	source_ecc_recovered_failures_++;
	} else {
	// When the operation doesn't include a source hash, we attempt the error
	// corrected device first since we can't verify the block in the raw device
	// at this point, but we fall back to the raw device since the error
	// corrected device can be shorter or not available.

	if (OpenCurrentECCPartition() &&
	fd_utils::CopyAndHashExtents(source_ecc_fd_,
	optimized.src_extents(),
	target_fd_,
	optimized.dst_extents(),
	block_size_,
	nullptr)) {
	return true;
	}
	TEST_AND_RETURN_FALSE(fd_utils::CopyAndHashExtents(source_fd_,
	optimized.src_extents(),
	target_fd_,
	optimized.dst_extents(),
	block_size_,
	nullptr));
	}
	return true;
	}

	bool PartitionWriter::PerformSourceBsdiffOperation(
	const InstallOperation& operation,
	ErrorCode* error,
	const void* data,
	size_t count) {
	FileDescriptorPtr source_fd = ChooseSourceFD(operation, error);
	TEST_AND_RETURN_FALSE(source_fd != nullptr);

	auto reader = std::make_unique<DirectExtentReader>();
	TEST_AND_RETURN_FALSE(
	reader->Init(source_fd, operation.src_extents(), block_size_));
	auto src_file = std::make_unique<BsdiffExtentFile>(
	std::move(reader),
	utils::BlocksInExtents(operation.src_extents()) * block_size_);

	auto writer = CreateBaseExtentWriter();
	TEST_AND_RETURN_FALSE(
	writer->Init(target_fd_, operation.dst_extents(), block_size_));
	auto dst_file = std::make_unique<BsdiffExtentFile>(
	std::move(writer),
	utils::BlocksInExtents(operation.dst_extents()) * block_size_);

	TEST_AND_RETURN_FALSE(bsdiff::bspatch(std::move(src_file),
	std::move(dst_file),
	reinterpret_cast<const uint8_t*>(data),
	count) == 0);
	return true;
	}

	bool PartitionWriter::PerformPuffDiffOperation(
	const InstallOperation& operation,
	ErrorCode* error,
	const void* data,
	size_t count) {
	FileDescriptorPtr source_fd = ChooseSourceFD(operation, error);
	TEST_AND_RETURN_FALSE(source_fd != nullptr);

	auto reader = std::make_unique<DirectExtentReader>();
	TEST_AND_RETURN_FALSE(
	reader->Init(source_fd, operation.src_extents(), block_size_));
	puffin::UniqueStreamPtr src_stream(new PuffinExtentStream(
	std::move(reader),
	utils::BlocksInExtents(operation.src_extents()) * block_size_));

	auto writer = CreateBaseExtentWriter();
	TEST_AND_RETURN_FALSE(
	writer->Init(target_fd_, operation.dst_extents(), block_size_));
	puffin::UniqueStreamPtr dst_stream(new PuffinExtentStream(
	std::move(writer),
	utils::BlocksInExtents(operation.dst_extents()) * block_size_));

	constexpr size_t kMaxCacheSize = 5 * 1024 * 1024; // Total 5MB cache.
	TEST_AND_RETURN_FALSE(
	puffin::PuffPatch(std::move(src_stream),
	std::move(dst_stream),
	reinterpret_cast<const uint8_t*>(data),
	count,
	kMaxCacheSize));
	return true;
	}

	FileDescriptorPtr PartitionWriter::ChooseSourceFD(
	const InstallOperation& operation, ErrorCode* error) {
	if (source_fd_ == nullptr) {
	LOG(ERROR) << "ChooseSourceFD fail: source_fd_ == nullptr";
	return nullptr;
	}

	if (!operation.has_src_sha256_hash()) {
	// When the operation doesn't include a source hash, we attempt the error
	// corrected device first since we can't verify the block in the raw device
	// at this point, but we first need to make sure all extents are readable
	// since the error corrected device can be shorter or not available.
	if (OpenCurrentECCPartition() &&
	fd_utils::ReadAndHashExtents(
	source_ecc_fd_, operation.src_extents(), block_size_, nullptr)) {
	return source_ecc_fd_;
	}
	return source_fd_;
	}

	brillo::Blob source_hash;
	brillo::Blob expected_source_hash(operation.src_sha256_hash().begin(),
	operation.src_sha256_hash().end());
	if (fd_utils::ReadAndHashExtents(
	source_fd_, operation.src_extents(), block_size_, &source_hash) &&
	source_hash == expected_source_hash) {
	return source_fd_;
	}
	// We fall back to use the error corrected device if the hash of the raw
	// device doesn't match or there was an error reading the source partition.
	if (!OpenCurrentECCPartition()) {
	// The following function call will return false since the source hash
	// mismatches, but we still want to call it so it prints the appropriate
	// log message.
	ValidateSourceHash(source_hash, operation, source_fd_, error);
	return nullptr;
	}
	LOG(WARNING) << "Source hash from RAW device mismatched: found "
	<< base::HexEncode(source_hash.data(), source_hash.size())
	<< ", expected "
	<< base::HexEncode(expected_source_hash.data(),
	expected_source_hash.size());

	if (fd_utils::ReadAndHashExtents(
	source_ecc_fd_, operation.src_extents(), block_size_, &source_hash) &&
	ValidateSourceHash(source_hash, operation, source_ecc_fd_, error)) {
	// At this point reading from the error corrected device worked, but
	// reading from the raw device failed, so this is considered a recovered
	// failure.
	source_ecc_recovered_failures_++;
	return source_ecc_fd_;
	}
	return nullptr;
	}

	bool PartitionWriter::OpenCurrentECCPartition() {
	// No support for ECC for full payloads.
	// Full payload should not have any opeartion that requires ECC partitions.
	if (source_ecc_fd_)
	return true;

	if (source_ecc_open_failure_)
	return false;

	#if USE_FEC
	const PartitionUpdate& partition = partition_update_;
	const InstallPlan::Partition& install_part = install_part_;
	std::string path = install_part.source_path;
	FileDescriptorPtr fd(new FecFileDescriptor());
	if (!fd->Open(path.c_str(), O_RDONLY, 0)) {
	PLOG(ERROR) << "Unable to open ECC source partition "
	<< partition.partition_name() << ", file " << path;
	source_ecc_open_failure_ = true;
	return false;
	}
	source_ecc_fd_ = fd;
	#else
	// No support for ECC compiled.
	source_ecc_open_failure_ = true;
	#endif // USE_FEC

	return !source_ecc_open_failure_;
	}

	int PartitionWriter::Close() {
	int err = 0;
	if (source_fd_ && !source_fd_->Close()) {
	err = errno;
	PLOG(ERROR) << "Error closing source partition";
	if (!err)
	err = 1;
	}
	source_fd_.reset();
	source_path_.clear();

	if (target_fd_ && !target_fd_->Close()) {
	err = errno;
	PLOG(ERROR) << "Error closing target partition";
	if (!err)
	err = 1;
	}
	target_fd_.reset();
	target_path_.clear();

	if (source_ecc_fd_ && !source_ecc_fd_->Close()) {
	err = errno;
	PLOG(ERROR) << "Error closing ECC source partition";
	if (!err)
	err = 1;
	}
	source_ecc_fd_.reset();
	source_ecc_open_failure_ = false;
	return -err;
	}

	void PartitionWriter::CheckpointUpdateProgress(size_t next_op_index) {
	target_fd_->Flush();
	}

	std::unique_ptr<ExtentWriter> PartitionWriter::CreateBaseExtentWriter() {
	return std::make_unique<DirectExtentWriter>();
	}

	} // namespace chromeos_update_engine