/* * Copyright (C) 2016 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. */ #define LOG_TAG "storaged" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace android::base; using namespace chrono; using namespace google::protobuf::io; using namespace storaged_proto; namespace { /* * The system user is the initial user that is implicitly created on first boot * and hosts most of the system services. Keep this in sync with * frameworks/base/core/java/android/os/UserManager.java */ constexpr int USER_SYSTEM = 0; constexpr ssize_t benchmark_unit_size = 16 * 1024; // 16KB constexpr ssize_t min_benchmark_size = 128 * 1024; // 128KB } // namespace const uint32_t storaged_t::current_version = 4; using android::hardware::interfacesEqual; using android::hardware::Return; using android::hardware::health::V1_0::BatteryStatus; using android::hardware::health::V1_0::toString; using android::hardware::health::V2_0::get_health_service; using android::hardware::health::V2_0::HealthInfo; using android::hardware::health::V2_0::IHealth; using android::hardware::health::V2_0::Result; using android::hidl::manager::V1_0::IServiceManager; inline charger_stat_t is_charger_on(BatteryStatus prop) { return (prop == BatteryStatus::CHARGING || prop == BatteryStatus::FULL) ? CHARGER_ON : CHARGER_OFF; } Return storaged_t::healthInfoChanged(const HealthInfo& props) { mUidm.set_charger_state(is_charger_on(props.legacy.batteryStatus)); return android::hardware::Void(); } void storaged_t::init() { init_health_service(); mDsm = std::make_unique(health); storage_info.reset(storage_info_t::get_storage_info(health)); } void storaged_t::init_health_service() { if (!mUidm.enabled()) return; health = get_health_service(); if (health == NULL) { LOG(WARNING) << "health: failed to find IHealth service"; return; } BatteryStatus status = BatteryStatus::UNKNOWN; auto ret = health->getChargeStatus([&](Result r, BatteryStatus v) { if (r != Result::SUCCESS) { LOG(WARNING) << "health: cannot get battery status " << toString(r); return; } if (v == BatteryStatus::UNKNOWN) { LOG(WARNING) << "health: invalid battery status"; } status = v; }); if (!ret.isOk()) { LOG(WARNING) << "health: get charge status transaction error " << ret.description(); } mUidm.init(is_charger_on(status)); // register listener after init uid_monitor health->registerCallback(this); health->linkToDeath(this, 0 /* cookie */); } void storaged_t::serviceDied(uint64_t cookie, const wp<::android::hidl::base::V1_0::IBase>& who) { if (health != NULL && interfacesEqual(health, who.promote())) { LOG(ERROR) << "health service died, exiting"; android::hardware::IPCThreadState::self()->stopProcess(); exit(1); } else { LOG(ERROR) << "unknown service died"; } } void storaged_t::report_storage_info() { storage_info->report(); } /* storaged_t */ storaged_t::storaged_t(void) { mConfig.periodic_chores_interval_unit = property_get_int32("ro.storaged.event.interval", DEFAULT_PERIODIC_CHORES_INTERVAL_UNIT); mConfig.event_time_check_usec = property_get_int32("ro.storaged.event.perf_check", 0); mConfig.periodic_chores_interval_disk_stats_publish = property_get_int32("ro.storaged.disk_stats_pub", DEFAULT_PERIODIC_CHORES_INTERVAL_DISK_STATS_PUBLISH); mConfig.periodic_chores_interval_uid_io = property_get_int32("ro.storaged.uid_io.interval", DEFAULT_PERIODIC_CHORES_INTERVAL_UID_IO); mConfig.periodic_chores_interval_flush_proto = property_get_int32("ro.storaged.flush_proto.interval", DEFAULT_PERIODIC_CHORES_INTERVAL_FLUSH_PROTO); mStarttime = time(NULL); mTimer = 0; } void storaged_t::add_user_ce(userid_t user_id) { Mutex::Autolock _l(proto_lock); if (!proto_loaded[user_id]) { load_proto(user_id); proto_loaded[user_id] = true; } } void storaged_t::remove_user_ce(userid_t user_id) { Mutex::Autolock _l(proto_lock); proto_loaded[user_id] = false; mUidm.clear_user_history(user_id); RemoveFileIfExists(proto_path(user_id), nullptr); } void storaged_t::load_proto(userid_t user_id) { string proto_file = proto_path(user_id); ifstream in(proto_file, ofstream::in | ofstream::binary); if (!in.good()) return; stringstream ss; ss << in.rdbuf(); StoragedProto proto; proto.ParseFromString(ss.str()); const UidIOUsage& uid_io_usage = proto.uid_io_usage(); uint32_t computed_crc = crc32(current_version, reinterpret_cast(uid_io_usage.SerializeAsString().c_str()), uid_io_usage.ByteSize()); if (proto.crc() != computed_crc) { LOG(WARNING) << "CRC mismatch in " << proto_file; return; } mUidm.load_uid_io_proto(user_id, proto.uid_io_usage()); if (user_id == USER_SYSTEM) { storage_info->load_perf_history_proto(proto.perf_history()); } } char* storaged_t:: prepare_proto(userid_t user_id, StoragedProto* proto) { proto->set_version(current_version); const UidIOUsage& uid_io_usage = proto->uid_io_usage(); proto->set_crc(crc32(current_version, reinterpret_cast(uid_io_usage.SerializeAsString().c_str()), uid_io_usage.ByteSize())); uint32_t pagesize = sysconf(_SC_PAGESIZE); if (user_id == USER_SYSTEM) { proto->set_padding("", 1); vector padding; ssize_t size = ROUND_UP(MAX(min_benchmark_size, proto->ByteSize()), pagesize); padding = vector(size - proto->ByteSize(), 0xFD); proto->set_padding(padding.data(), padding.size()); while (!IS_ALIGNED(proto->ByteSize(), pagesize)) { padding.push_back(0xFD); proto->set_padding(padding.data(), padding.size()); } } char* data = nullptr; if (posix_memalign(reinterpret_cast(&data), pagesize, proto->ByteSize())) { PLOG(ERROR) << "Faied to alloc aligned buffer (size: " << proto->ByteSize() << ")"; return data; } proto->SerializeToArray(data, proto->ByteSize()); return data; } void storaged_t::flush_proto_data(userid_t user_id, const char* data, ssize_t size) { string proto_file = proto_path(user_id); string tmp_file = proto_file + "_tmp"; unique_fd fd(TEMP_FAILURE_RETRY(open(tmp_file.c_str(), O_SYNC | O_CREAT | O_TRUNC | O_WRONLY | O_CLOEXEC | (user_id == USER_SYSTEM ? O_DIRECT : 0), S_IRUSR | S_IWUSR))); if (fd == -1) { PLOG(ERROR) << "Faied to open tmp file: " << tmp_file; return; } if (user_id == USER_SYSTEM) { time_point start, end; uint32_t benchmark_size = 0; uint64_t benchmark_time_ns = 0; ssize_t ret; bool first_write = true; while (size > 0) { start = steady_clock::now(); ret = write(fd, data, MIN(benchmark_unit_size, size)); if (ret <= 0) { PLOG(ERROR) << "Faied to write tmp file: " << tmp_file; return; } end = steady_clock::now(); /* * compute bandwidth after the first write and if write returns * exactly unit size. */ if (!first_write && ret == benchmark_unit_size) { benchmark_size += benchmark_unit_size; benchmark_time_ns += duration_cast(end - start).count(); } size -= ret; data += ret; first_write = false; } if (benchmark_size) { int perf = benchmark_size * 1000000LLU / benchmark_time_ns; storage_info->update_perf_history(perf, system_clock::now()); } } else { if (!WriteFully(fd, data, size)) { PLOG(ERROR) << "Faied to write tmp file: " << tmp_file; return; } } fd.reset(-1); rename(tmp_file.c_str(), proto_file.c_str()); } void storaged_t::flush_proto(userid_t user_id, StoragedProto* proto) { unique_ptr proto_data(prepare_proto(user_id, proto)); if (proto_data == nullptr) return; flush_proto_data(user_id, proto_data.get(), proto->ByteSize()); } void storaged_t::flush_protos(unordered_map* protos) { Mutex::Autolock _l(proto_lock); for (auto& it : *protos) { /* * Don't flush proto if we haven't attempted to load it from file. */ if (proto_loaded[it.first]) { flush_proto(it.first, &it.second); } } } void storaged_t::event(void) { unordered_map protos; if (mDsm->enabled()) { mDsm->update(); if (!(mTimer % mConfig.periodic_chores_interval_disk_stats_publish)) { mDsm->publish(); } } if (!(mTimer % mConfig.periodic_chores_interval_uid_io)) { mUidm.report(&protos); } if (storage_info) { storage_info->refresh(protos[USER_SYSTEM].mutable_perf_history()); } if (!(mTimer % mConfig.periodic_chores_interval_flush_proto)) { flush_protos(&protos); } mTimer += mConfig.periodic_chores_interval_unit; } void storaged_t::event_checked(void) { struct timespec start_ts, end_ts; bool check_time = true; if (mConfig.event_time_check_usec && clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &start_ts) < 0) { check_time = false; PLOG(ERROR) << "clock_gettime() failed"; } event(); if (mConfig.event_time_check_usec && check_time) { if (clock_gettime(CLOCK_PROCESS_CPUTIME_ID, &end_ts) < 0) { PLOG(ERROR) << "clock_gettime() failed"; return; } int64_t cost = (end_ts.tv_sec - start_ts.tv_sec) * SEC_TO_USEC + (end_ts.tv_nsec - start_ts.tv_nsec) / USEC_TO_NSEC; if (cost > mConfig.event_time_check_usec) { LOG(ERROR) << "event loop spent " << cost << " usec, threshold " << mConfig.event_time_check_usec << " usec"; } } }