/* * Copyright (C) 2007 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 "install/install.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "install/snapshot_utils.h" #include "install/spl_check.h" #include "install/wipe_data.h" #include "install/wipe_device.h" #include "otautil/error_code.h" #include "otautil/package.h" #include "otautil/paths.h" #include "otautil/sysutil.h" #include "otautil/verifier.h" #include "private/setup_commands.h" #include "recovery_ui/ui.h" #include "recovery_utils/roots.h" #include "recovery_utils/thermalutil.h" using namespace std::chrono_literals; static constexpr int kRecoveryApiVersion = 3; // We define RECOVERY_API_VERSION in Android.mk, which will be picked up by build system and packed // into target_files.zip. Assert the version defined in code and in Android.mk are consistent. static_assert(kRecoveryApiVersion == RECOVERY_API_VERSION, "Mismatching recovery API versions."); // Default allocation of progress bar segments to operations static constexpr int VERIFICATION_PROGRESS_TIME = 60; static constexpr float VERIFICATION_PROGRESS_FRACTION = 0.25; // The charater used to separate dynamic fingerprints. e.x. sargo|aosp-sargo static const char* FINGERPRING_SEPARATOR = "|"; static constexpr auto&& RELEASE_KEYS_TAG = "release-keys"; // If brick packages are smaller than |MEMORY_PACKAGE_LIMIT|, read the entire package into memory static constexpr size_t MEMORY_PACKAGE_LIMIT = 1024 * 1024; static std::condition_variable finish_log_temperature; static bool isInStringList(const std::string& target_token, const std::string& str_list, const std::string& deliminator); bool ReadMetadataFromPackage(ZipArchiveHandle zip, std::map* metadata) { CHECK(metadata != nullptr); static constexpr const char* METADATA_PATH = "META-INF/com/android/metadata"; ZipEntry64 entry; if (FindEntry(zip, METADATA_PATH, &entry) != 0) { return false; } uint32_t length = entry.uncompressed_length; std::string metadata_string(length, '\0'); int32_t err = ExtractToMemory(zip, &entry, reinterpret_cast(&metadata_string[0]), length); if (err != 0) { LOG(ERROR) << "Failed to extract " << METADATA_PATH << ": " << ErrorCodeString(err); return false; } for (const std::string& line : android::base::Split(metadata_string, "\n")) { size_t eq = line.find('='); if (eq != std::string::npos) { metadata->emplace(android::base::Trim(line.substr(0, eq)), android::base::Trim(line.substr(eq + 1))); } } return true; } // Gets the value for the given key in |metadata|. Returns an emtpy string if the key isn't // present. static std::string get_value(const std::map& metadata, const std::string& key) { const auto& it = metadata.find(key); return (it == metadata.end()) ? "" : it->second; } static std::string OtaTypeToString(OtaType type) { switch (type) { case OtaType::AB: return "AB"; case OtaType::BLOCK: return "BLOCK"; case OtaType::BRICK: return "BRICK"; } } // Read the build.version.incremental of src/tgt from the metadata and log it to last_install. static void ReadSourceTargetBuild(const std::map& metadata, std::vector* log_buffer) { // Examples of the pre-build and post-build strings in metadata: // pre-build-incremental=2943039 // post-build-incremental=2951741 auto source_build = get_value(metadata, "pre-build-incremental"); if (!source_build.empty()) { log_buffer->push_back("source_build: " + source_build); } auto target_build = get_value(metadata, "post-build-incremental"); if (!target_build.empty()) { log_buffer->push_back("target_build: " + target_build); } } // Checks the build version, fingerprint and timestamp in the metadata of the A/B package. // Downgrading is not allowed unless explicitly enabled in the package and only for // incremental packages. static bool CheckAbSpecificMetadata(const std::map& metadata) { // Incremental updates should match the current build. auto device_pre_build = android::base::GetProperty("ro.build.version.incremental", ""); auto pkg_pre_build = get_value(metadata, "pre-build-incremental"); if (!pkg_pre_build.empty() && pkg_pre_build != device_pre_build) { LOG(ERROR) << "Package is for source build " << pkg_pre_build << " but expected " << device_pre_build; return false; } auto device_fingerprint = android::base::GetProperty("ro.build.fingerprint", ""); auto pkg_pre_build_fingerprint = get_value(metadata, "pre-build"); if (!pkg_pre_build_fingerprint.empty() && !isInStringList(device_fingerprint, pkg_pre_build_fingerprint, FINGERPRING_SEPARATOR)) { LOG(ERROR) << "Package is for source build " << pkg_pre_build_fingerprint << " but expected " << device_fingerprint; return false; } // Check for downgrade version. /*int64_t build_timestamp = android::base::GetIntProperty("ro.build.date.utc", std::numeric_limits::max()); int64_t pkg_post_timestamp = 0; // We allow to full update to the same version we are running, in case there // is a problem with the current copy of that version. auto pkg_post_timestamp_string = get_value(metadata, "post-timestamp"); if (pkg_post_timestamp_string.empty() || !android::base::ParseInt(pkg_post_timestamp_string, &pkg_post_timestamp) || pkg_post_timestamp < build_timestamp) { if (get_value(metadata, "ota-downgrade") != "yes") { LOG(ERROR) << "Update package is older than the current build, expected a build " "newer than timestamp " << build_timestamp << " but package has timestamp " << pkg_post_timestamp << " and downgrade not allowed."; return false; } if (pkg_pre_build_fingerprint.empty()) { LOG(ERROR) << "Downgrade package must have a pre-build version set, not allowed."; return false; } } const auto post_build = get_value(metadata, "post-build"); const auto build_fingerprint = android::base::Tokenize(post_build, "/"); if (!build_fingerprint.empty()) { const auto& post_build_tag = build_fingerprint.back(); const auto build_tag = android::base::GetProperty("ro.build.tags", ""); if (build_tag != post_build_tag) { LOG(ERROR) << "Post build-tag " << post_build_tag << " does not match device build tag " << build_tag; return false; } } return true; }*/ bool CheckPackageMetadata(const std::map& metadata, OtaType ota_type) { auto package_ota_type = get_value(metadata, "ota-type"); auto expected_ota_type = OtaTypeToString(ota_type); if (ota_type != OtaType::AB && ota_type != OtaType::BRICK) { LOG(INFO) << "Skip package metadata check for ota type " << expected_ota_type; return true; } if (package_ota_type != expected_ota_type) { LOG(ERROR) << "Unexpected ota package type, expects " << expected_ota_type << ", actual " << package_ota_type; return false; } auto device = android::base::GetProperty("ro.product.device", ""); auto pkg_device = get_value(metadata, "pre-device"); // device name can be a | separated list, so need to check if (pkg_device.empty() || !isInStringList(device, pkg_device, FINGERPRING_SEPARATOR)) { LOG(ERROR) << "Package is for product " << pkg_device << " but expected " << device; return false; } // We allow the package to not have any serialno; and we also allow it to carry multiple serial // numbers split by "|"; e.g. serialno=serialno1|serialno2|serialno3 ... We will fail the // verification if the device's serialno doesn't match any of these carried numbers. auto pkg_serial_no = get_value(metadata, "serialno"); if (!pkg_serial_no.empty()) { auto device_serial_no = android::base::GetProperty("ro.serialno", ""); bool serial_number_match = false; for (const auto& number : android::base::Split(pkg_serial_no, "|")) { if (device_serial_no == android::base::Trim(number)) { serial_number_match = true; } } if (!serial_number_match) { LOG(ERROR) << "Package is for serial " << pkg_serial_no; return false; } } else if (ota_type == OtaType::BRICK) { const auto device_build_tag = android::base::GetProperty("ro.build.tags", ""); if (device_build_tag.empty()) { LOG(ERROR) << "Unable to determine device build tags, serial number is missing from package. " "Rejecting the brick OTA package."; return false; } if (device_build_tag == RELEASE_KEYS_TAG) { LOG(ERROR) << "Device is release key build, serial number is missing from package. " "Rejecting the brick OTA package."; return false; } LOG(INFO) << "Serial number is missing from brick OTA package, permitting anyway because device is " << device_build_tag; } if (ota_type == OtaType::AB) { return CheckAbSpecificMetadata(metadata); } return true; } static std::string ExtractPayloadProperties(ZipArchiveHandle zip) { // For A/B updates we extract the payload properties to a buffer and obtain the RAW payload offset // in the zip file. static constexpr const char* AB_OTA_PAYLOAD_PROPERTIES = "payload_properties.txt"; ZipEntry64 properties_entry; if (FindEntry(zip, AB_OTA_PAYLOAD_PROPERTIES, &properties_entry) != 0) { return {}; } auto properties_entry_length = properties_entry.uncompressed_length; if (properties_entry_length > std::numeric_limits::max()) { LOG(ERROR) << "Failed to extract " << AB_OTA_PAYLOAD_PROPERTIES << " because's uncompressed size exceeds size of address space. " << properties_entry_length; return {}; } std::string payload_properties(properties_entry_length, '\0'); int32_t err = ExtractToMemory(zip, &properties_entry, reinterpret_cast(payload_properties.data()), properties_entry_length); if (err != 0) { LOG(ERROR) << "Failed to extract " << AB_OTA_PAYLOAD_PROPERTIES << ": " << ErrorCodeString(err); return {}; } return payload_properties; } bool SetUpAbUpdateCommands(const std::string& package, ZipArchiveHandle zip, int status_fd, std::vector* cmd) { CHECK(cmd != nullptr); // For A/B updates we extract the payload properties to a buffer and obtain the RAW payload offset // in the zip file. const auto payload_properties = ExtractPayloadProperties(zip); if (payload_properties.empty()) { return false; } static constexpr const char* AB_OTA_PAYLOAD = "payload.bin"; ZipEntry64 payload_entry; if (FindEntry(zip, AB_OTA_PAYLOAD, &payload_entry) != 0) { LOG(ERROR) << "Failed to find " << AB_OTA_PAYLOAD; return false; } long payload_offset = payload_entry.offset; *cmd = { "/system/bin/update_engine_sideload", "--payload=file://" + package, android::base::StringPrintf("--offset=%ld", payload_offset), "--headers=" + std::string(payload_properties.begin(), payload_properties.end()), android::base::StringPrintf("--status_fd=%d", status_fd), }; return true; } bool SetUpNonAbUpdateCommands(const std::string& package, ZipArchiveHandle zip, int retry_count, int status_fd, std::vector* cmd) { CHECK(cmd != nullptr); // In non-A/B updates we extract the update binary from the package. static constexpr const char* UPDATE_BINARY_NAME = "META-INF/com/google/android/update-binary"; ZipEntry64 binary_entry; if (FindEntry(zip, UPDATE_BINARY_NAME, &binary_entry) != 0) { LOG(ERROR) << "Failed to find update binary " << UPDATE_BINARY_NAME; return false; } const std::string binary_path = Paths::Get().temporary_update_binary(); unlink(binary_path.c_str()); android::base::unique_fd fd( open(binary_path.c_str(), O_CREAT | O_WRONLY | O_TRUNC | O_CLOEXEC, 0755)); if (fd == -1) { PLOG(ERROR) << "Failed to create " << binary_path; return false; } if (auto error = ExtractEntryToFile(zip, &binary_entry, fd); error != 0) { LOG(ERROR) << "Failed to extract " << UPDATE_BINARY_NAME << ": " << ErrorCodeString(error); return false; } // When executing the update binary contained in the package, the arguments passed are: // - the version number for this interface // - an FD to which the program can write in order to update the progress bar. // - the name of the package zip file. // - an optional argument "retry" if this update is a retry of a failed update attempt. *cmd = { binary_path, std::to_string(kRecoveryApiVersion), std::to_string(status_fd), package, }; if (retry_count > 0) { cmd->push_back("retry"); } return true; } static void log_max_temperature(int* max_temperature, const std::atomic& logger_finished) { CHECK(max_temperature != nullptr); std::mutex mtx; std::unique_lock lck(mtx); while (!logger_finished.load() && finish_log_temperature.wait_for(lck, 20s) == std::cv_status::timeout) { *max_temperature = std::max(*max_temperature, GetMaxValueFromThermalZone()); } } static bool PerformPowerwashIfRequired(ZipArchiveHandle zip, Device *device) { const auto payload_properties = ExtractPayloadProperties(zip); if (payload_properties.find("POWERWASH=1") != std::string::npos) { LOG(INFO) << "Payload properties has POWERWASH=1, wiping userdata..."; return WipeData(device); } return true; } // If the package contains an update binary, extract it and run it. static InstallResult TryUpdateBinary(Package* package, bool* wipe_cache, std::vector* log_buffer, int retry_count, int* max_temperature, Device* device) { auto ui = device->GetUI(); std::map metadata; auto zip = package->GetZipArchiveHandle(); bool has_metadata = ReadMetadataFromPackage(zip, &metadata); bool package_is_ab = has_metadata && get_value(metadata, "ota-type") == OtaTypeToString(OtaType::AB); const bool package_is_brick = get_value(metadata, "ota-type") == OtaTypeToString(OtaType::BRICK); if (package_is_brick) { LOG(INFO) << "Installing a brick package"; if (package->GetType() == PackageType::kFile && package->GetPackageSize() < MEMORY_PACKAGE_LIMIT) { std::vector content(package->GetPackageSize()); if (package->ReadFullyAtOffset(content.data(), content.size(), 0)) { auto memory_package = Package::CreateMemoryPackage(std::move(content), {}); return WipeAbDevice(device, memory_package.get()) ? INSTALL_SUCCESS : INSTALL_ERROR; } } return WipeAbDevice(device, package) ? INSTALL_SUCCESS : INSTALL_ERROR; } bool device_supports_ab = android::base::GetBoolProperty("ro.build.ab_update", false); bool ab_device_supports_nonab = true; bool device_only_supports_ab = device_supports_ab && !ab_device_supports_nonab; bool device_supports_virtual_ab = android::base::GetBoolProperty("ro.virtual_ab.enabled", false); /*const auto current_spl = android::base::GetProperty("ro.build.version.security_patch", ""); if (ViolatesSPLDowngrade(zip, current_spl)) { LOG(ERROR) << "Denying OTA because it's SPL downgrade"; return INSTALL_ERROR; }*/ if (package_is_ab) { CHECK(package->GetType() == PackageType::kFile); } // Verify against the metadata in the package first. Expects A/B metadata if: // Package declares itself as an A/B package // Package does not declare itself as an A/B package, but device only supports A/B; // still calls CheckPackageMetadata to get a meaningful error message. if (package_is_ab || device_only_supports_ab) { if (!CheckPackageMetadata(metadata, OtaType::AB)) { log_buffer->push_back(android::base::StringPrintf("error: %d", kUpdateBinaryCommandFailure)); return INSTALL_ERROR; } } if (!package_is_ab && !logical_partitions_mapped()) { CreateSnapshotPartitions(); map_logical_partitions(); } else if (package_is_ab && device_supports_virtual_ab && logical_partitions_mapped()) { LOG(ERROR) << "Logical partitions are mapped. " << "Please reboot recovery before installing an OTA update."; return INSTALL_ERROR; } ReadSourceTargetBuild(metadata, log_buffer); // The updater in child process writes to the pipe to communicate with recovery. android::base::unique_fd pipe_read, pipe_write; // Explicitly disable O_CLOEXEC using 0 as the flags (last) parameter to Pipe // so that the child updater process will recieve a non-closed fd. if (!android::base::Pipe(&pipe_read, &pipe_write, 0)) { PLOG(ERROR) << "Failed to create pipe for updater-recovery communication"; return INSTALL_CORRUPT; } // The updater-recovery communication protocol. // // progress // fill up the next part of of the progress bar over seconds. If is // zero, use `set_progress` commands to manually control the progress of this segment of the // bar. // // set_progress // should be between 0.0 and 1.0; sets the progress bar within the segment defined by // the most recent progress command. // // ui_print // display on the screen. // // wipe_cache // a wipe of cache will be performed following a successful installation. // // clear_display // turn off the text display. // // enable_reboot // packages can explicitly request that they want the user to be able to reboot during // installation (useful for debugging packages that don't exit). // // retry_update // updater encounters some issue during the update. It requests a reboot to retry the same // package automatically. // // log // updater requests logging the string (e.g. cause of the failure). // std::string package_path = package->GetPath(); std::vector args; if (auto setup_result = package_is_ab ? SetUpAbUpdateCommands(package_path, zip, pipe_write.get(), &args) : SetUpNonAbUpdateCommands(package_path, zip, retry_count, pipe_write.get(), &args); !setup_result) { log_buffer->push_back(android::base::StringPrintf("error: %d", kUpdateBinaryCommandFailure)); return INSTALL_CORRUPT; } pid_t pid = fork(); if (pid == -1) { PLOG(ERROR) << "Failed to fork update binary"; log_buffer->push_back(android::base::StringPrintf("error: %d", kForkUpdateBinaryFailure)); return INSTALL_ERROR; } if (pid == 0) { umask(022); pipe_read.reset(); // Convert the std::string vector to a NULL-terminated char* vector suitable for execv. auto chr_args = StringVectorToNullTerminatedArray(args); execv(chr_args[0], chr_args.data()); // We shouldn't use LOG/PLOG in the forked process, since they may cause the child process to // hang. This deadlock results from an improperly copied mutex in the ui functions. // (Bug: 34769056) fprintf(stdout, "E:Can't run %s (%s)\n", chr_args[0], strerror(errno)); _exit(EXIT_FAILURE); } pipe_write.reset(); std::atomic logger_finished(false); std::thread temperature_logger(log_max_temperature, max_temperature, std::ref(logger_finished)); *wipe_cache = false; bool retry_update = false; char buffer[1024]; FILE* from_child = android::base::Fdopen(std::move(pipe_read), "r"); while (fgets(buffer, sizeof(buffer), from_child) != nullptr) { std::string line(buffer); size_t space = line.find_first_of(" \n"); std::string command(line.substr(0, space)); if (command.empty()) continue; // Get rid of the leading and trailing space and/or newline. std::string args = space == std::string::npos ? "" : android::base::Trim(line.substr(space)); if (command == "progress") { std::vector tokens = android::base::Split(args, " "); double fraction; int seconds; if (tokens.size() == 2 && android::base::ParseDouble(tokens[0].c_str(), &fraction) && android::base::ParseInt(tokens[1], &seconds)) { ui->ShowProgress(fraction * (1 - VERIFICATION_PROGRESS_FRACTION), seconds); } else { LOG(ERROR) << "invalid \"progress\" parameters: " << line; } } else if (command == "set_progress") { std::vector tokens = android::base::Split(args, " "); double fraction; if (tokens.size() == 1 && android::base::ParseDouble(tokens[0].c_str(), &fraction)) { ui->SetProgress(fraction); } else { LOG(ERROR) << "invalid \"set_progress\" parameters: " << line; } } else if (command == "ui_print") { ui->PrintOnScreenOnly("%s\n", args.c_str()); fflush(stdout); } else if (command == "wipe_cache") { *wipe_cache = true; } else if (command == "clear_display") { ui->SetBackground(RecoveryUI::NONE); } else if (command == "enable_reboot") { // packages can explicitly request that they want the user // to be able to reboot during installation (useful for // debugging packages that don't exit). ui->SetEnableReboot(true); } else if (command == "retry_update") { retry_update = true; } else if (command == "log") { if (!args.empty()) { // Save the logging request from updater and write to last_install later. log_buffer->push_back(args); } else { LOG(ERROR) << "invalid \"log\" parameters: " << line; } } else { LOG(ERROR) << "unknown command [" << command << "]"; } } fclose(from_child); int status; waitpid(pid, &status, 0); logger_finished.store(true); finish_log_temperature.notify_one(); temperature_logger.join(); if (retry_update) { return INSTALL_RETRY; } if (WIFEXITED(status)) { if (WEXITSTATUS(status) != EXIT_SUCCESS) { LOG(ERROR) << "Error in " << package_path << " (status " << WEXITSTATUS(status) << ")"; return INSTALL_ERROR; } } else if (WIFSIGNALED(status)) { LOG(ERROR) << "Error in " << package_path << " (killed by signal " << WTERMSIG(status) << ")"; return INSTALL_ERROR; } else { LOG(FATAL) << "Invalid status code " << status; } if (package_is_ab) { PerformPowerwashIfRequired(zip, device); } return INSTALL_SUCCESS; } static InstallResult VerifyAndInstallPackage(Package* package, bool* wipe_cache, std::vector* log_buffer, int retry_count, int* max_temperature, Device* device) { auto ui = device->GetUI(); ui->SetBackground(RecoveryUI::INSTALLING_UPDATE); // Give verification half the progress bar... ui->SetProgressType(RecoveryUI::DETERMINATE); ui->ShowProgress(VERIFICATION_PROGRESS_FRACTION, VERIFICATION_PROGRESS_TIME); // Verify package. /*if (!verify_package(package, ui)) { log_buffer->push_back(android::base::StringPrintf("error: %d", kZipVerificationFailure)); return INSTALL_CORRUPT; }*/ // Verify and install the contents of the package. ui->Print("Installing update...\n"); if (retry_count > 0) { ui->Print("Retry attempt: %d\n", retry_count); } ui->SetEnableReboot(false); auto result = TryUpdateBinary(package, wipe_cache, log_buffer, retry_count, max_temperature, device); ui->SetEnableReboot(true); ui->Print("\n"); return result; } InstallResult InstallPackage(Package* package, const std::string_view package_id, bool should_wipe_cache, int retry_count, Device* device) { auto ui = device->GetUI(); auto start = std::chrono::system_clock::now(); int start_temperature = GetMaxValueFromThermalZone(); int max_temperature = start_temperature; InstallResult result; std::vector log_buffer; ui->Print("Supported API: %d\n", kRecoveryApiVersion); ui->Print("Finding update package...\n"); LOG(INFO) << "Update package id: " << package_id; if (!package) { log_buffer.push_back(android::base::StringPrintf("error: %d", kMapFileFailure)); result = INSTALL_CORRUPT; } else if (setup_install_mounts() != 0) { LOG(ERROR) << "failed to set up expected mounts for install; aborting"; result = INSTALL_ERROR; } else { bool updater_wipe_cache = false; result = VerifyAndInstallPackage(package, &updater_wipe_cache, &log_buffer, retry_count, &max_temperature, device); should_wipe_cache = should_wipe_cache || updater_wipe_cache; } // Measure the time spent to apply OTA update in seconds. std::chrono::duration duration = std::chrono::system_clock::now() - start; int time_total = static_cast(duration.count()); bool has_cache = volume_for_mount_point("/cache") != nullptr; // Skip logging the uncrypt_status on devices without /cache. if (has_cache) { static constexpr const char* UNCRYPT_STATUS = "/cache/recovery/uncrypt_status"; if (ensure_path_mounted(UNCRYPT_STATUS) != 0) { LOG(WARNING) << "Can't mount " << UNCRYPT_STATUS; } else { std::string uncrypt_status; if (!android::base::ReadFileToString(UNCRYPT_STATUS, &uncrypt_status)) { PLOG(WARNING) << "failed to read uncrypt status"; } else if (!android::base::StartsWith(uncrypt_status, "uncrypt_")) { LOG(WARNING) << "corrupted uncrypt_status: " << uncrypt_status; } else { log_buffer.push_back(android::base::Trim(uncrypt_status)); } } } // The first two lines need to be the package name and install result. std::vector log_header = { std::string(package_id), result == INSTALL_SUCCESS ? "1" : "0", "time_total: " + std::to_string(time_total), "retry: " + std::to_string(retry_count), }; int end_temperature = GetMaxValueFromThermalZone(); max_temperature = std::max(end_temperature, max_temperature); if (start_temperature > 0) { log_buffer.push_back("temperature_start: " + std::to_string(start_temperature)); } if (end_temperature > 0) { log_buffer.push_back("temperature_end: " + std::to_string(end_temperature)); } if (max_temperature > 0) { log_buffer.push_back("temperature_max: " + std::to_string(max_temperature)); } std::string log_content = android::base::Join(log_header, "\n") + "\n" + android::base::Join(log_buffer, "\n") + "\n"; const std::string& install_file = Paths::Get().temporary_install_file(); if (!android::base::WriteStringToFile(log_content, install_file)) { PLOG(ERROR) << "failed to write " << install_file; } // Write a copy into last_log. LOG(INFO) << log_content; if (result == INSTALL_SUCCESS && should_wipe_cache) { if (!WipeCache(ui, nullptr)) { result = INSTALL_ERROR; } } return result; } bool verify_package(Package* package, RecoveryUI* ui) { static constexpr const char* CERTIFICATE_ZIP_FILE = "/system/etc/security/otacerts.zip"; std::vector loaded_keys = LoadKeysFromZipfile(CERTIFICATE_ZIP_FILE); if (loaded_keys.empty()) { LOG(ERROR) << "Failed to load keys"; return false; } LOG(INFO) << loaded_keys.size() << " key(s) loaded from " << CERTIFICATE_ZIP_FILE; // Verify package. ui->Print("Verifying update package...\n"); auto t0 = std::chrono::system_clock::now(); int err = verify_file(package, loaded_keys); std::chrono::duration duration = std::chrono::system_clock::now() - t0; ui->Print("Update package verification took %.1f s (result %d).\n", duration.count(), err); if (err != VERIFY_SUCCESS) { LOG(ERROR) << "Signature verification failed"; LOG(ERROR) << "error: " << kZipVerificationFailure; return false; } return true; } bool SetupPackageMount(const std::string& package_path, bool* should_use_fuse) { CHECK(should_use_fuse != nullptr); if (package_path.empty()) { return false; } *should_use_fuse = true; if (package_path[0] == '@') { auto block_map_path = package_path.substr(1); if (ensure_path_mounted(block_map_path) != 0) { LOG(ERROR) << "Failed to mount " << block_map_path; return false; } // uncrypt only produces block map only if the package stays on /data. *should_use_fuse = false; return true; } // Package is not a block map file. if (ensure_path_mounted(package_path) != 0) { LOG(ERROR) << "Failed to mount " << package_path; return false; } // Reject the package if the input path doesn't equal the canonicalized path. // e.g. /cache/../sdcard/update_package. std::error_code ec; auto canonical_path = std::filesystem::canonical(package_path, ec); if (ec) { LOG(ERROR) << "Failed to get canonical of " << package_path << ", " << ec.message(); return false; } if (canonical_path.string() != package_path) { LOG(ERROR) << "Installation aborts. The canonical path " << canonical_path.string() << " doesn't equal the original path " << package_path; return false; } constexpr const char* CACHE_ROOT = "/cache"; if (android::base::StartsWith(package_path, CACHE_ROOT)) { *should_use_fuse = false; } return true; } // Check if `target_token` is in string `str_list`, where `str_list` is expected to be a // list delimited by `deliminator` // E.X. isInStringList("a", "a|b|c|d", "|") => true // E.X. isInStringList("abc", "abc", "|") => true static bool isInStringList(const std::string& target_token, const std::string& str_list, const std::string& deliminator) { if (target_token.length() > str_list.length()) { return false; } else if (target_token.length() == str_list.length() || deliminator.length() == 0) { return target_token == str_list; } auto&& list = android::base::Split(str_list, deliminator); return std::find(list.begin(), list.end(), target_token) != list.end(); }