// // Copyright (C) 2012 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/filesystem_verifier_action.h" #include #include #include #include #include #include #include #include #include #include #include "update_engine/common/boot_control_interface.h" #include "update_engine/common/utils.h" #include "update_engine/payload_consumer/delta_performer.h" #include "update_engine/payload_consumer/payload_constants.h" using std::string; namespace chromeos_update_engine { namespace { const off_t kReadFileBufferSize = 128 * 1024; string StringForHashBytes(const brillo::Blob& hash) { return brillo::data_encoding::Base64Encode(hash.data(), hash.size()); } } // namespace void FilesystemVerifierAction::PerformAction() { // Will tell the ActionProcessor we've failed if we return. ScopedActionCompleter abort_action_completer(processor_, this); if (!HasInputObject()) { LOG(ERROR) << "FilesystemVerifierAction missing input object."; return; } install_plan_ = GetInputObject(); if (install_plan_.partitions.empty()) { LOG(INFO) << "No partitions to verify."; if (HasOutputPipe()) SetOutputObject(install_plan_); abort_action_completer.set_code(ErrorCode::kSuccess); return; } StartPartitionHashing(); abort_action_completer.set_should_complete(false); } void FilesystemVerifierAction::TerminateProcessing() { cancelled_ = true; Cleanup(ErrorCode::kSuccess); // error code is ignored if canceled_ is true. } bool FilesystemVerifierAction::IsCleanupPending() const { return src_stream_ != nullptr; } void FilesystemVerifierAction::Cleanup(ErrorCode code) { src_stream_.reset(); // This memory is not used anymore. buffer_.clear(); if (cancelled_) return; if (code == ErrorCode::kSuccess && HasOutputPipe()) SetOutputObject(install_plan_); processor_->ActionComplete(this, code); } void FilesystemVerifierAction::StartPartitionHashing() { if (partition_index_ == install_plan_.partitions.size()) { Cleanup(ErrorCode::kSuccess); return; } InstallPlan::Partition& partition = install_plan_.partitions[partition_index_]; string part_path; switch (verifier_step_) { case VerifierStep::kVerifySourceHash: part_path = partition.source_path; remaining_size_ = partition.source_size; break; case VerifierStep::kVerifyTargetHash: part_path = partition.target_path; remaining_size_ = partition.target_size; break; } LOG(INFO) << "Hashing partition " << partition_index_ << " (" << partition.name << ") on device " << part_path; if (part_path.empty()) return Cleanup(ErrorCode::kFilesystemVerifierError); brillo::ErrorPtr error; src_stream_ = brillo::FileStream::Open( base::FilePath(part_path), brillo::Stream::AccessMode::READ, brillo::FileStream::Disposition::OPEN_EXISTING, &error); if (!src_stream_) { LOG(ERROR) << "Unable to open " << part_path << " for reading"; return Cleanup(ErrorCode::kFilesystemVerifierError); } buffer_.resize(kReadFileBufferSize); read_done_ = false; hasher_.reset(new HashCalculator()); // Start the first read. ScheduleRead(); } void FilesystemVerifierAction::ScheduleRead() { size_t bytes_to_read = std::min(static_cast(buffer_.size()), remaining_size_); if (!bytes_to_read) { OnReadDoneCallback(0); return; } bool read_async_ok = src_stream_->ReadAsync( buffer_.data(), bytes_to_read, base::Bind(&FilesystemVerifierAction::OnReadDoneCallback, base::Unretained(this)), base::Bind(&FilesystemVerifierAction::OnReadErrorCallback, base::Unretained(this)), nullptr); if (!read_async_ok) { LOG(ERROR) << "Unable to schedule an asynchronous read from the stream."; Cleanup(ErrorCode::kError); } } void FilesystemVerifierAction::OnReadDoneCallback(size_t bytes_read) { if (bytes_read == 0) { read_done_ = true; } else { remaining_size_ -= bytes_read; CHECK(!read_done_); if (!hasher_->Update(buffer_.data(), bytes_read)) { LOG(ERROR) << "Unable to update the hash."; Cleanup(ErrorCode::kError); return; } } // We either terminate the current partition or have more data to read. if (cancelled_) return Cleanup(ErrorCode::kError); if (read_done_ || remaining_size_ == 0) { if (remaining_size_ != 0) { LOG(ERROR) << "Failed to read the remaining " << remaining_size_ << " bytes from partition " << install_plan_.partitions[partition_index_].name; return Cleanup(ErrorCode::kFilesystemVerifierError); } return FinishPartitionHashing(); } ScheduleRead(); } void FilesystemVerifierAction::OnReadErrorCallback( const brillo::Error* error) { // TODO(deymo): Transform the read-error into an specific ErrorCode. LOG(ERROR) << "Asynchronous read failed."; Cleanup(ErrorCode::kError); } void FilesystemVerifierAction::FinishPartitionHashing() { if (!hasher_->Finalize()) { LOG(ERROR) << "Unable to finalize the hash."; return Cleanup(ErrorCode::kError); } InstallPlan::Partition& partition = install_plan_.partitions[partition_index_]; LOG(INFO) << "Hash of " << partition.name << ": " << hasher_->hash(); switch (verifier_step_) { case VerifierStep::kVerifyTargetHash: if (partition.target_hash != hasher_->raw_hash()) { LOG(ERROR) << "New '" << partition.name << "' partition verification failed."; if (install_plan_.payload_type == InstallPayloadType::kFull) return Cleanup(ErrorCode::kNewRootfsVerificationError); // If we have not verified source partition yet, now that the target // partition does not match, and it's not a full payload, we need to // switch to kVerifySourceHash step to check if it's because the source // partition does not match either. verifier_step_ = VerifierStep::kVerifySourceHash; } else { partition_index_++; } break; case VerifierStep::kVerifySourceHash: if (partition.source_hash != hasher_->raw_hash()) { LOG(ERROR) << "Old '" << partition.name << "' partition verification failed."; LOG(ERROR) << "This is a server-side error due to mismatched delta" << " update image!"; LOG(ERROR) << "The delta I've been given contains a " << partition.name << " delta update that must be applied over a " << partition.name << " with a specific checksum, but the " << partition.name << " we're starting with doesn't have that checksum! This" " means that the delta I've been given doesn't match my" " existing system. The " << partition.name << " partition I have has hash: " << StringForHashBytes(hasher_->raw_hash()) << " but the update expected me to have " << StringForHashBytes(partition.source_hash) << " ."; LOG(INFO) << "To get the checksum of the " << partition.name << " partition run this command: dd if=" << partition.source_path << " bs=1M count=" << partition.source_size << " iflag=count_bytes 2>/dev/null | openssl dgst -sha256 " "-binary | openssl base64"; LOG(INFO) << "To get the checksum of partitions in a bin file, " << "run: .../src/scripts/sha256_partitions.sh .../file.bin"; return Cleanup(ErrorCode::kDownloadStateInitializationError); } // The action will skip kVerifySourceHash step if target partition hash // matches, if we are in this step, it means target hash does not match, // and now that the source partition hash matches, we should set the error // code to reflect the error in target partition. // We only need to verify the source partition which the target hash does // not match, the rest of the partitions don't matter. return Cleanup(ErrorCode::kNewRootfsVerificationError); } // Start hashing the next partition, if any. hasher_.reset(); buffer_.clear(); src_stream_->CloseBlocking(nullptr); StartPartitionHashing(); } } // namespace chromeos_update_engine