/* * 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 "variables.h" #include #include #include #include #include #include #include #include #include #include #include #include "fastboot_device.h" #include "flashing.h" #include "utility.h" #ifdef FB_ENABLE_FETCH static constexpr bool kEnableFetch = true; #else static constexpr bool kEnableFetch = false; #endif using ::android::hardware::boot::V1_0::BoolResult; using ::android::hardware::boot::V1_0::Slot; using ::android::hardware::boot::V1_1::MergeStatus; using ::android::hardware::fastboot::V1_0::FileSystemType; using ::android::hardware::fastboot::V1_0::Result; using ::android::hardware::fastboot::V1_0::Status; using IBootControl1_1 = ::android::hardware::boot::V1_1::IBootControl; using namespace android::fs_mgr; constexpr char kFastbootProtocolVersion[] = "0.4"; bool GetVersion(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = kFastbootProtocolVersion; return true; } bool GetBootloaderVersion(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.bootloader", ""); return true; } bool GetBasebandVersion(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.build.expect.baseband", ""); return true; } bool GetOsVersion(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.build.version.release", ""); return true; } bool GetVndkVersion(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.vndk.version", ""); return true; } bool GetProduct(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.product.device", ""); return true; } bool GetSerial(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.serialno", ""); return true; } bool GetSecure(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetBoolProperty("ro.secure", "") ? "yes" : "no"; return true; } bool GetVariant(FastbootDevice* device, const std::vector& /* args */, std::string* message) { auto fastboot_hal = device->fastboot_hal(); if (!fastboot_hal) { *message = "Fastboot HAL not found"; return false; } Result ret; auto ret_val = fastboot_hal->getVariant([&](std::string device_variant, Result result) { *message = device_variant; ret = result; }); if (!ret_val.isOk() || ret.status != Status::SUCCESS) { *message = "Unable to get device variant"; return false; } return true; } bool GetBatteryVoltageHelper(FastbootDevice* device, int32_t* battery_voltage) { using android::hardware::health::V2_0::HealthInfo; using android::hardware::health::V2_0::Result; auto health_hal = device->health_hal(); if (!health_hal) { return false; } Result ret; auto ret_val = health_hal->getHealthInfo([&](Result result, HealthInfo info) { *battery_voltage = info.legacy.batteryVoltage; ret = result; }); if (!ret_val.isOk() || (ret != Result::SUCCESS)) { return false; } return true; } bool GetBatterySoCOk(FastbootDevice* device, const std::vector& /* args */, std::string* message) { int32_t battery_voltage = 0; if (!GetBatteryVoltageHelper(device, &battery_voltage)) { *message = "Unable to read battery voltage"; return false; } auto fastboot_hal = device->fastboot_hal(); if (!fastboot_hal) { *message = "Fastboot HAL not found"; return false; } Result ret; auto ret_val = fastboot_hal->getBatteryVoltageFlashingThreshold( [&](int32_t voltage_threshold, Result result) { *message = battery_voltage >= voltage_threshold ? "yes" : "no"; ret = result; }); if (!ret_val.isOk() || ret.status != Status::SUCCESS) { *message = "Unable to get battery voltage flashing threshold"; return false; } return true; } bool GetOffModeChargeState(FastbootDevice* device, const std::vector& /* args */, std::string* message) { auto fastboot_hal = device->fastboot_hal(); if (!fastboot_hal) { *message = "Fastboot HAL not found"; return false; } Result ret; auto ret_val = fastboot_hal->getOffModeChargeState([&](bool off_mode_charging_state, Result result) { *message = off_mode_charging_state ? "1" : "0"; ret = result; }); if (!ret_val.isOk() || (ret.status != Status::SUCCESS)) { *message = "Unable to get off mode charge state"; return false; } return true; } bool GetBatteryVoltage(FastbootDevice* device, const std::vector& /* args */, std::string* message) { int32_t battery_voltage = 0; if (GetBatteryVoltageHelper(device, &battery_voltage)) { *message = std::to_string(battery_voltage); return true; } *message = "Unable to get battery voltage"; return false; } bool GetCurrentSlot(FastbootDevice* device, const std::vector& /* args */, std::string* message) { std::string suffix = device->GetCurrentSlot(); *message = suffix.size() == 2 ? suffix.substr(1) : suffix; return true; } bool GetSlotCount(FastbootDevice* device, const std::vector& /* args */, std::string* message) { auto boot_control_hal = device->boot_control_hal(); if (!boot_control_hal) { *message = "0"; } else { *message = std::to_string(boot_control_hal->getNumberSlots()); } return true; } bool GetSlotSuccessful(FastbootDevice* device, const std::vector& args, std::string* message) { if (args.empty()) { *message = "Missing argument"; return false; } Slot slot; if (!GetSlotNumber(args[0], &slot)) { *message = "Invalid slot"; return false; } auto boot_control_hal = device->boot_control_hal(); if (!boot_control_hal) { *message = "Device has no slots"; return false; } if (boot_control_hal->isSlotMarkedSuccessful(slot) != BoolResult::TRUE) { *message = "no"; } else { *message = "yes"; } return true; } bool GetSlotUnbootable(FastbootDevice* device, const std::vector& args, std::string* message) { if (args.empty()) { *message = "Missing argument"; return false; } Slot slot; if (!GetSlotNumber(args[0], &slot)) { *message = "Invalid slot"; return false; } auto boot_control_hal = device->boot_control_hal(); if (!boot_control_hal) { *message = "Device has no slots"; return false; } if (boot_control_hal->isSlotBootable(slot) != BoolResult::TRUE) { *message = "yes"; } else { *message = "no"; } return true; } bool GetMaxDownloadSize(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::StringPrintf("0x%X", kMaxDownloadSizeDefault); return true; } bool GetUnlocked(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = GetDeviceLockStatus() ? "no" : "yes"; return true; } bool GetHasSlot(FastbootDevice* device, const std::vector& args, std::string* message) { if (args.empty()) { *message = "Missing argument"; return false; } std::string slot_suffix = device->GetCurrentSlot(); if (slot_suffix.empty()) { *message = "no"; return true; } std::string partition_name = args[0] + slot_suffix; if (FindPhysicalPartition(partition_name) || LogicalPartitionExists(device, partition_name)) { *message = "yes"; } else { *message = "no"; } return true; } bool GetPartitionSize(FastbootDevice* device, const std::vector& args, std::string* message) { if (args.size() < 1) { *message = "Missing argument"; return false; } // Zero-length partitions cannot be created through device-mapper, so we // special case them here. bool is_zero_length; if (LogicalPartitionExists(device, args[0], &is_zero_length) && is_zero_length) { *message = "0x0"; return true; } // Otherwise, open the partition as normal. PartitionHandle handle; if (!OpenPartition(device, args[0], &handle)) { *message = "Could not open partition"; return false; } uint64_t size = get_block_device_size(handle.fd()); *message = android::base::StringPrintf("0x%" PRIX64, size); return true; } bool GetPartitionType(FastbootDevice* device, const std::vector& args, std::string* message) { if (args.size() < 1) { *message = "Missing argument"; return false; } std::string partition_name = args[0]; if (!FindPhysicalPartition(partition_name) && !LogicalPartitionExists(device, partition_name)) { *message = "Invalid partition"; return false; } auto fastboot_hal = device->fastboot_hal(); if (!fastboot_hal) { *message = "Fastboot HAL not found"; return false; } FileSystemType type; Result ret; auto ret_val = fastboot_hal->getPartitionType(args[0], [&](FileSystemType fs_type, Result result) { type = fs_type; ret = result; }); if (!ret_val.isOk() || (ret.status != Status::SUCCESS)) { *message = "Unable to retrieve partition type"; } else { switch (type) { case FileSystemType::RAW: *message = "raw"; return true; case FileSystemType::EXT4: *message = "ext4"; return true; case FileSystemType::F2FS: *message = "f2fs"; return true; default: *message = "Unknown file system type"; } } return false; } bool GetPartitionIsLogical(FastbootDevice* device, const std::vector& args, std::string* message) { if (args.size() < 1) { *message = "Missing argument"; return false; } // Note: if a partition name is in both the GPT and the super partition, we // return "true", to be consistent with prefering to flash logical partitions // over physical ones. std::string partition_name = args[0]; if (LogicalPartitionExists(device, partition_name)) { *message = "yes"; return true; } if (FindPhysicalPartition(partition_name)) { *message = "no"; return true; } *message = "Partition not found"; return false; } bool GetIsUserspace(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = "yes"; return true; } std::vector> GetAllPartitionArgsWithSlot(FastbootDevice* device) { std::vector> args; auto partitions = ListPartitions(device); for (const auto& partition : partitions) { args.emplace_back(std::initializer_list{partition}); } return args; } std::vector> GetAllPartitionArgsNoSlot(FastbootDevice* device) { auto partitions = ListPartitions(device); std::string slot_suffix = device->GetCurrentSlot(); if (!slot_suffix.empty()) { auto names = std::move(partitions); for (const auto& name : names) { std::string slotless_name = name; if (android::base::EndsWith(name, "_a") || android::base::EndsWith(name, "_b")) { slotless_name = name.substr(0, name.rfind("_")); } if (std::find(partitions.begin(), partitions.end(), slotless_name) == partitions.end()) { partitions.emplace_back(slotless_name); } } } std::vector> args; for (const auto& partition : partitions) { args.emplace_back(std::initializer_list{partition}); } return args; } bool GetHardwareRevision(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.revision", ""); return true; } bool GetSuperPartitionName(FastbootDevice* device, const std::vector& /* args */, std::string* message) { uint32_t slot_number = SlotNumberForSlotSuffix(device->GetCurrentSlot()); *message = fs_mgr_get_super_partition_name(slot_number); return true; } bool GetSnapshotUpdateStatus(FastbootDevice* device, const std::vector& /* args */, std::string* message) { // Note that we use the HAL rather than mounting /metadata, since we want // our results to match the bootloader. auto hal = device->boot1_1(); if (!hal) { *message = "not supported"; return false; } MergeStatus status = hal->getSnapshotMergeStatus(); switch (status) { case MergeStatus::SNAPSHOTTED: *message = "snapshotted"; break; case MergeStatus::MERGING: *message = "merging"; break; default: *message = "none"; break; } return true; } bool GetCpuAbi(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.product.cpu.abi", ""); return true; } bool GetSystemFingerprint(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.system.build.fingerprint", ""); if (message->empty()) { *message = android::base::GetProperty("ro.build.fingerprint", ""); } return true; } bool GetVendorFingerprint(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.vendor.build.fingerprint", ""); return true; } bool GetDynamicPartition(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.boot.dynamic_partitions", ""); return true; } bool GetFirstApiLevel(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.product.first_api_level", ""); return true; } bool GetSecurityPatchLevel(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.build.version.security_patch", ""); return true; } bool GetTrebleEnabled(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { *message = android::base::GetProperty("ro.treble.enabled", ""); return true; } bool GetMaxFetchSize(FastbootDevice* /* device */, const std::vector& /* args */, std::string* message) { if (!kEnableFetch) { *message = "fetch not supported on user builds"; return false; } *message = android::base::StringPrintf("0x%X", kMaxFetchSizeDefault); return true; }