path: root/payload_consumer/payload_metadata.cc

//
// Copyright (C) 2018 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/payload_metadata.h"

#include <endian.h>

#include <base/strings/stringprintf.h>
#include <brillo/data_encoding.h>

#include "update_engine/common/constants.h"
#include "update_engine/common/hash_calculator.h"
#include "update_engine/common/utils.h"
#include "update_engine/payload_consumer/payload_constants.h"
#include "update_engine/payload_consumer/payload_verifier.h"

using std::string;

namespace chromeos_update_engine {

const uint64_t PayloadMetadata::kDeltaVersionOffset = sizeof(kDeltaMagic);
const uint64_t PayloadMetadata::kDeltaVersionSize = 8;
const uint64_t PayloadMetadata::kDeltaManifestSizeOffset =
    kDeltaVersionOffset + kDeltaVersionSize;
const uint64_t PayloadMetadata::kDeltaManifestSizeSize = 8;
const uint64_t PayloadMetadata::kDeltaMetadataSignatureSizeSize = 4;

uint64_t PayloadMetadata::GetMetadataSignatureSizeOffset() const {
  return kDeltaManifestSizeOffset + kDeltaManifestSizeSize;
}

uint64_t PayloadMetadata::GetManifestOffset() const {
  // Actual manifest begins right after the metadata signature size field.
  return kDeltaManifestSizeOffset + kDeltaManifestSizeSize +
         kDeltaMetadataSignatureSizeSize;
}

MetadataParseResult PayloadMetadata::ParsePayloadHeader(
    const brillo::Blob& payload, ErrorCode* error) {
  return ParsePayloadHeader(payload.data(), payload.size(), error);
}

MetadataParseResult PayloadMetadata::ParsePayloadHeader(
    const unsigned char* payload, size_t size, ErrorCode* error) {
  // Ensure we have data to cover the major payload version.
  if (size < kDeltaManifestSizeOffset)
    return MetadataParseResult::kInsufficientData;

  // Validate the magic string.
  if (memcmp(payload, kDeltaMagic, sizeof(kDeltaMagic)) != 0) {
    LOG(ERROR) << "Bad payload format -- invalid delta magic: "
               << base::StringPrintf("%02x%02x%02x%02x",
                                     payload[0],
                                     payload[1],
                                     payload[2],
                                     payload[3])
               << " Expected: "
               << base::StringPrintf("%02x%02x%02x%02x",
                                     kDeltaMagic[0],
                                     kDeltaMagic[1],
                                     kDeltaMagic[2],
                                     kDeltaMagic[3]);
    *error = ErrorCode::kDownloadInvalidMetadataMagicString;
    return MetadataParseResult::kError;
  }

  uint64_t manifest_offset = GetManifestOffset();
  // Check again with the manifest offset.
  if (size < manifest_offset)
    return MetadataParseResult::kInsufficientData;

  // Extract the payload version from the metadata.
  static_assert(sizeof(major_payload_version_) == kDeltaVersionSize,
                "Major payload version size mismatch");
  memcpy(&major_payload_version_,
         &payload[kDeltaVersionOffset],
         kDeltaVersionSize);
  // Switch big endian to host.
  major_payload_version_ = be64toh(major_payload_version_);

  if (major_payload_version_ < kMinSupportedMajorPayloadVersion ||
      major_payload_version_ > kMaxSupportedMajorPayloadVersion) {
    LOG(ERROR) << "Bad payload format -- unsupported payload version: "
               << major_payload_version_;
    *error = ErrorCode::kUnsupportedMajorPayloadVersion;
    return MetadataParseResult::kError;
  }

  // Next, parse the manifest size.
  static_assert(sizeof(manifest_size_) == kDeltaManifestSizeSize,
                "manifest_size size mismatch");
  memcpy(&manifest_size_,
         &payload[kDeltaManifestSizeOffset],
         kDeltaManifestSizeSize);
  manifest_size_ = be64toh(manifest_size_);  // switch big endian to host

  metadata_size_ = manifest_offset + manifest_size_;
  if (metadata_size_ < manifest_size_) {
    // Overflow detected.
    LOG(ERROR) << "Overflow detected on manifest size.";
    *error = ErrorCode::kDownloadInvalidMetadataSize;
    return MetadataParseResult::kError;
  }

  // Parse the metadata signature size.
  static_assert(
      sizeof(metadata_signature_size_) == kDeltaMetadataSignatureSizeSize,
      "metadata_signature_size size mismatch");
  uint64_t metadata_signature_size_offset = GetMetadataSignatureSizeOffset();
  memcpy(&metadata_signature_size_,
         &payload[metadata_signature_size_offset],
         kDeltaMetadataSignatureSizeSize);
  metadata_signature_size_ = be32toh(metadata_signature_size_);

  if (metadata_size_ + metadata_signature_size_ < metadata_size_) {
    // Overflow detected.
    LOG(ERROR) << "Overflow detected on metadata and signature size.";
    *error = ErrorCode::kDownloadInvalidMetadataSize;
    return MetadataParseResult::kError;
  }
  return MetadataParseResult::kSuccess;
}

bool PayloadMetadata::ParsePayloadHeader(const brillo::Blob& payload) {
  ErrorCode error;
  return ParsePayloadHeader(payload, &error) == MetadataParseResult::kSuccess;
}

bool PayloadMetadata::GetManifest(const brillo::Blob& payload,
                                  DeltaArchiveManifest* out_manifest) const {
  return GetManifest(payload.data(), payload.size(), out_manifest);
}

bool PayloadMetadata::GetManifest(const unsigned char* payload,
                                  size_t size,
                                  DeltaArchiveManifest* out_manifest) const {
  uint64_t manifest_offset = GetManifestOffset();
  CHECK_GE(size, manifest_offset + manifest_size_);
  return out_manifest->ParseFromArray(&payload[manifest_offset],
                                      manifest_size_);
}

ErrorCode PayloadMetadata::ValidateMetadataSignature(
    const brillo::Blob& payload,
    const string& metadata_signature,
    const PayloadVerifier& payload_verifier) const {
  if (payload.size() < metadata_size_ + metadata_signature_size_)
    return ErrorCode::kDownloadMetadataSignatureError;

  // A single signature in raw bytes.
  brillo::Blob metadata_signature_blob;
  // The serialized Signatures protobuf message stored in major version >=2
  // payload, it may contain multiple signatures.
  string metadata_signature_protobuf;
  if (!metadata_signature.empty()) {
    // Convert base64-encoded signature to raw bytes.
    if (!brillo::data_encoding::Base64Decode(metadata_signature,
                                             &metadata_signature_blob)) {
      LOG(ERROR) << "Unable to decode base64 metadata signature: "
                 << metadata_signature;
      return ErrorCode::kDownloadMetadataSignatureError;
    }
  } else {
    metadata_signature_protobuf.assign(
        payload.begin() + metadata_size_,
        payload.begin() + metadata_size_ + metadata_signature_size_);
  }

  if (metadata_signature_blob.empty() && metadata_signature_protobuf.empty()) {
    LOG(ERROR) << "Missing mandatory metadata signature in both Omaha "
               << "response and payload.";
    return ErrorCode::kDownloadMetadataSignatureMissingError;
  }

  brillo::Blob metadata_hash;
  if (!HashCalculator::RawHashOfBytes(
          payload.data(), metadata_size_, &metadata_hash)) {
    LOG(ERROR) << "Unable to compute actual hash of manifest";
    return ErrorCode::kDownloadMetadataSignatureVerificationError;
  }

  if (metadata_hash.size() != kSHA256Size) {
    LOG(ERROR) << "Computed actual hash of metadata has incorrect size: "
               << metadata_hash.size();
    return ErrorCode::kDownloadMetadataSignatureVerificationError;
  }

  if (!metadata_signature_blob.empty()) {
    brillo::Blob decrypted_signature;
    if (!payload_verifier.VerifyRawSignature(
            metadata_signature_blob, metadata_hash, &decrypted_signature)) {
      LOG(ERROR) << "Manifest hash verification failed. Decrypted hash = ";
      utils::HexDumpVector(decrypted_signature);
      LOG(ERROR) << "Calculated hash before padding = ";
      utils::HexDumpVector(metadata_hash);
      return ErrorCode::kDownloadMetadataSignatureMismatch;
    }
  } else {
    if (!payload_verifier.VerifySignature(metadata_signature_protobuf,
                                          metadata_hash)) {
      LOG(ERROR) << "Manifest hash verification failed.";
      return ErrorCode::kDownloadMetadataSignatureMismatch;
    }
  }

  // The autoupdate_CatchBadSignatures test checks for this string in
  // log-files. Keep in sync.
  LOG(INFO) << "Metadata hash signature matches value in Omaha response.";
  return ErrorCode::kSuccess;
}

bool PayloadMetadata::ParsePayloadFile(const string& payload_path,
                                       DeltaArchiveManifest* manifest,
                                       Signatures* metadata_signatures) {
  brillo::Blob payload;
  TEST_AND_RETURN_FALSE(
      utils::ReadFileChunk(payload_path, 0, kMaxPayloadHeaderSize, &payload));
  TEST_AND_RETURN_FALSE(ParsePayloadHeader(payload));

  if (manifest != nullptr) {
    TEST_AND_RETURN_FALSE(
        utils::ReadFileChunk(payload_path,
                             kMaxPayloadHeaderSize,
                             GetMetadataSize() - kMaxPayloadHeaderSize,
                             &payload));
    TEST_AND_RETURN_FALSE(GetManifest(payload, manifest));
  }

  if (metadata_signatures != nullptr) {
    payload.clear();
    TEST_AND_RETURN_FALSE(utils::ReadFileChunk(
        payload_path, GetMetadataSize(), GetMetadataSignatureSize(), &payload));
    TEST_AND_RETURN_FALSE(
        metadata_signatures->ParseFromArray(payload.data(), payload.size()));
  }

  return true;
}

}  // namespace chromeos_update_engine