/* * Copyright (C) 2022 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 ATRACE_TAG (ATRACE_TAG_THERMAL | ATRACE_TAG_HAL) #include "Thermal.h" #include #include #include namespace aidl { namespace android { namespace hardware { namespace thermal { namespace implementation { namespace { ndk::ScopedAStatus initErrorStatus() { return ndk::ScopedAStatus::fromExceptionCodeWithMessage(EX_ILLEGAL_STATE, "ThermalHAL not initialized properly."); } ndk::ScopedAStatus readErrorStatus() { return ndk::ScopedAStatus::fromExceptionCodeWithMessage( EX_ILLEGAL_STATE, "ThermalHal cannot read any sensor data"); } bool interfacesEqual(const std::shared_ptr<::ndk::ICInterface> left, const std::shared_ptr<::ndk::ICInterface> right) { if (left == nullptr || right == nullptr || !left->isRemote() || !right->isRemote()) { return left == right; } return left->asBinder() == right->asBinder(); } } // namespace Thermal::Thermal() : thermal_helper_( std::bind(&Thermal::sendThermalChangedCallback, this, std::placeholders::_1)) {} ndk::ScopedAStatus Thermal::getTemperatures(std::vector *_aidl_return) { return getFilteredTemperatures(false, TemperatureType::UNKNOWN, _aidl_return); } ndk::ScopedAStatus Thermal::getTemperaturesWithType(TemperatureType type, std::vector *_aidl_return) { return getFilteredTemperatures(true, type, _aidl_return); } ndk::ScopedAStatus Thermal::getFilteredTemperatures(bool filterType, TemperatureType type, std::vector *_aidl_return) { *_aidl_return = {}; if (!thermal_helper_.isInitializedOk()) { return initErrorStatus(); } if (!thermal_helper_.fillCurrentTemperatures(filterType, false, type, _aidl_return)) { return readErrorStatus(); } return ndk::ScopedAStatus::ok(); } ndk::ScopedAStatus Thermal::getCoolingDevices(std::vector *_aidl_return) { return getFilteredCoolingDevices(false, CoolingType::BATTERY, _aidl_return); } ndk::ScopedAStatus Thermal::getCoolingDevicesWithType(CoolingType type, std::vector *_aidl_return) { return getFilteredCoolingDevices(true, type, _aidl_return); } ndk::ScopedAStatus Thermal::getFilteredCoolingDevices(bool filterType, CoolingType type, std::vector *_aidl_return) { *_aidl_return = {}; if (!thermal_helper_.isInitializedOk()) { return initErrorStatus(); } if (!thermal_helper_.fillCurrentCoolingDevices(filterType, type, _aidl_return)) { return readErrorStatus(); } return ndk::ScopedAStatus::ok(); } ndk::ScopedAStatus Thermal::getTemperatureThresholds( std::vector *_aidl_return) { *_aidl_return = {}; return getFilteredTemperatureThresholds(false, TemperatureType::UNKNOWN, _aidl_return); } ndk::ScopedAStatus Thermal::getTemperatureThresholdsWithType( TemperatureType type, std::vector *_aidl_return) { return getFilteredTemperatureThresholds(true, type, _aidl_return); } ndk::ScopedAStatus Thermal::getFilteredTemperatureThresholds( bool filterType, TemperatureType type, std::vector *_aidl_return) { *_aidl_return = {}; if (!thermal_helper_.isInitializedOk()) { return initErrorStatus(); } if (!thermal_helper_.fillTemperatureThresholds(filterType, type, _aidl_return)) { return readErrorStatus(); } return ndk::ScopedAStatus::ok(); } ndk::ScopedAStatus Thermal::registerThermalChangedCallback( const std::shared_ptr &callback) { ATRACE_CALL(); return registerThermalChangedCallback(callback, false, TemperatureType::UNKNOWN); } ndk::ScopedAStatus Thermal::registerThermalChangedCallbackWithType( const std::shared_ptr &callback, TemperatureType type) { ATRACE_CALL(); return registerThermalChangedCallback(callback, true, type); } ndk::ScopedAStatus Thermal::unregisterThermalChangedCallback( const std::shared_ptr &callback) { if (callback == nullptr) { return ndk::ScopedAStatus::fromExceptionCodeWithMessage(EX_ILLEGAL_ARGUMENT, "Invalid nullptr callback"); } bool removed = false; std::lock_guard _lock(thermal_callback_mutex_); callbacks_.erase( std::remove_if( callbacks_.begin(), callbacks_.end(), [&](const CallbackSetting &c) { if (interfacesEqual(c.callback, callback)) { LOG(INFO) << "a callback has been unregistered to ThermalHAL, isFilter: " << c.is_filter_type << " Type: " << toString(c.type); removed = true; return true; } return false; }), callbacks_.end()); if (!removed) { return ndk::ScopedAStatus::fromExceptionCodeWithMessage(EX_ILLEGAL_ARGUMENT, "Callback wasn't registered"); } return ndk::ScopedAStatus::ok(); } ndk::ScopedAStatus Thermal::registerThermalChangedCallback( const std::shared_ptr &callback, bool filterType, TemperatureType type) { ATRACE_CALL(); if (callback == nullptr) { return ndk::ScopedAStatus::fromExceptionCodeWithMessage(EX_ILLEGAL_ARGUMENT, "Invalid nullptr callback"); } if (!thermal_helper_.isInitializedOk()) { return initErrorStatus(); } std::lock_guard _lock(thermal_callback_mutex_); if (std::any_of(callbacks_.begin(), callbacks_.end(), [&](const CallbackSetting &c) { return interfacesEqual(c.callback, callback); })) { return ndk::ScopedAStatus::fromExceptionCodeWithMessage(EX_ILLEGAL_ARGUMENT, "Callback already registered"); } auto c = callbacks_.emplace_back(callback, filterType, type); LOG(INFO) << "a callback has been registered to ThermalHAL, isFilter: " << c.is_filter_type << " Type: " << toString(c.type); // Send notification right away after successful thermal callback registration std::function handler = [this, c, filterType, type]() { std::vector temperatures; if (thermal_helper_.fillCurrentTemperatures(filterType, true, type, &temperatures)) { for (const auto &t : temperatures) { if (!filterType || t.type == type) { LOG(INFO) << "Sending notification: " << " Type: " << toString(t.type) << " Name: " << t.name << " CurrentValue: " << t.value << " ThrottlingStatus: " << toString(t.throttlingStatus); c.callback->notifyThrottling(t); } } } }; looper_.addEvent(Looper::Event{handler}); return ndk::ScopedAStatus::ok(); } void Thermal::sendThermalChangedCallback(const Temperature &t) { ATRACE_CALL(); std::lock_guard _lock(thermal_callback_mutex_); LOG(VERBOSE) << "Sending notification: " << " Type: " << toString(t.type) << " Name: " << t.name << " CurrentValue: " << t.value << " ThrottlingStatus: " << toString(t.throttlingStatus); callbacks_.erase(std::remove_if(callbacks_.begin(), callbacks_.end(), [&](const CallbackSetting &c) { if (!c.is_filter_type || t.type == c.type) { ::ndk::ScopedAStatus ret = c.callback->notifyThrottling(t); if (!ret.isOk()) { LOG(ERROR) << "a Thermal callback is dead, removed " "from callback list."; return true; } return false; } return false; }), callbacks_.end()); } void Thermal::dumpVirtualSensorInfo(std::ostringstream *dump_buf) { *dump_buf << "getVirtualSensorInfo:" << std::endl; const auto &map = thermal_helper_.GetSensorInfoMap(); for (const auto &sensor_info_pair : map) { if (sensor_info_pair.second.virtual_sensor_info != nullptr) { *dump_buf << " Name: " << sensor_info_pair.first << std::endl; *dump_buf << " LinkedSensorName: ["; for (size_t i = 0; i < sensor_info_pair.second.virtual_sensor_info->linked_sensors.size(); i++) { *dump_buf << sensor_info_pair.second.virtual_sensor_info->linked_sensors[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " LinkedSensorCoefficient: ["; for (size_t i = 0; i < sensor_info_pair.second.virtual_sensor_info->coefficients.size(); i++) { *dump_buf << sensor_info_pair.second.virtual_sensor_info->coefficients[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " Offset: " << sensor_info_pair.second.virtual_sensor_info->offset << std::endl; *dump_buf << " Trigger Sensor: "; if (sensor_info_pair.second.virtual_sensor_info->trigger_sensors.empty()) { *dump_buf << "N/A" << std::endl; } else { for (size_t i = 0; i < sensor_info_pair.second.virtual_sensor_info->trigger_sensors.size(); i++) { *dump_buf << sensor_info_pair.second.virtual_sensor_info->trigger_sensors[i] << " "; } *dump_buf << std::endl; } *dump_buf << " Formula: "; switch (sensor_info_pair.second.virtual_sensor_info->formula) { case FormulaOption::COUNT_THRESHOLD: *dump_buf << "COUNT_THRESHOLD"; break; case FormulaOption::WEIGHTED_AVG: *dump_buf << "WEIGHTED_AVG"; break; case FormulaOption::MAXIMUM: *dump_buf << "MAXIMUM"; break; case FormulaOption::MINIMUM: *dump_buf << "MINIMUM"; break; default: *dump_buf << "NONE"; break; } *dump_buf << std::endl; } } } void Thermal::dumpThrottlingInfo(std::ostringstream *dump_buf) { *dump_buf << "getThrottlingInfo:" << std::endl; const auto &map = thermal_helper_.GetSensorInfoMap(); const auto &thermal_throttling_status_map = thermal_helper_.GetThermalThrottlingStatusMap(); for (const auto &name_info_pair : map) { if (name_info_pair.second.throttling_info == nullptr) { continue; } if (name_info_pair.second.throttling_info->binded_cdev_info_map.size()) { if (thermal_throttling_status_map.find(name_info_pair.first) == thermal_throttling_status_map.end()) { continue; } *dump_buf << " Name: " << name_info_pair.first << std::endl; if (thermal_throttling_status_map.at(name_info_pair.first) .pid_power_budget_map.size()) { *dump_buf << " PID Info:" << std::endl; *dump_buf << " K_po: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->k_po[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " K_pu: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->k_pu[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " K_i: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->k_i[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " K_d: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->k_d[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " i_max: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->i_max[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " max_alloc_power: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->max_alloc_power[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " min_alloc_power: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->min_alloc_power[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " s_power: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->s_power[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " i_cutoff: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << name_info_pair.second.throttling_info->i_cutoff[i] << " "; } *dump_buf << "]" << std::endl; } *dump_buf << " Binded CDEV Info:" << std::endl; for (const auto &binded_cdev_info_pair : name_info_pair.second.throttling_info->binded_cdev_info_map) { *dump_buf << " Cooling device name: " << binded_cdev_info_pair.first << std::endl; if (thermal_throttling_status_map.at(name_info_pair.first) .pid_power_budget_map.size()) { *dump_buf << " WeightForPID: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << binded_cdev_info_pair.second.cdev_weight_for_pid[i] << " "; } *dump_buf << "]" << std::endl; } *dump_buf << " Ceiling: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << binded_cdev_info_pair.second.cdev_ceiling[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " Hard limit: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << binded_cdev_info_pair.second.limit_info[i] << " "; } *dump_buf << "]" << std::endl; if (!binded_cdev_info_pair.second.power_rail.empty()) { *dump_buf << " Binded power rail: " << binded_cdev_info_pair.second.power_rail << std::endl; *dump_buf << " Power threshold: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << binded_cdev_info_pair.second.power_thresholds[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " Floor with PowerLink: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { *dump_buf << binded_cdev_info_pair.second.cdev_floor_with_power_link[i] << " "; } *dump_buf << "]" << std::endl; *dump_buf << " Release logic: "; switch (binded_cdev_info_pair.second.release_logic) { case ReleaseLogic::INCREASE: *dump_buf << "INCREASE"; break; case ReleaseLogic::DECREASE: *dump_buf << "DECREASE"; break; case ReleaseLogic::STEPWISE: *dump_buf << "STEPWISE"; break; case ReleaseLogic::RELEASE_TO_FLOOR: *dump_buf << "RELEASE_TO_FLOOR"; break; default: *dump_buf << "NONE"; break; } *dump_buf << std::endl; *dump_buf << " high_power_check: " << std::boolalpha << binded_cdev_info_pair.second.high_power_check << std::endl; *dump_buf << " throttling_with_power_link: " << std::boolalpha << binded_cdev_info_pair.second.throttling_with_power_link << std::endl; } } } } } void Thermal::dumpThrottlingRequestStatus(std::ostringstream *dump_buf) { const auto &thermal_throttling_status_map = thermal_helper_.GetThermalThrottlingStatusMap(); if (!thermal_throttling_status_map.size()) { return; } *dump_buf << "getThrottlingRequestStatus:" << std::endl; for (const auto &thermal_throttling_status_pair : thermal_throttling_status_map) { *dump_buf << " Name: " << thermal_throttling_status_pair.first << std::endl; if (thermal_throttling_status_pair.second.pid_power_budget_map.size()) { *dump_buf << " power budget request state" << std::endl; for (const auto &request_pair : thermal_throttling_status_pair.second.pid_power_budget_map) { *dump_buf << " " << request_pair.first << ": " << request_pair.second << std::endl; } } if (thermal_throttling_status_pair.second.pid_cdev_request_map.size()) { *dump_buf << " pid cdev request state" << std::endl; for (const auto &request_pair : thermal_throttling_status_pair.second.pid_cdev_request_map) { *dump_buf << " " << request_pair.first << ": " << request_pair.second << std::endl; } } if (thermal_throttling_status_pair.second.hardlimit_cdev_request_map.size()) { *dump_buf << " hard limit cdev request state" << std::endl; for (const auto &request_pair : thermal_throttling_status_pair.second.hardlimit_cdev_request_map) { *dump_buf << " " << request_pair.first << ": " << request_pair.second << std::endl; } } if (thermal_throttling_status_pair.second.throttling_release_map.size()) { *dump_buf << " cdev release state" << std::endl; for (const auto &request_pair : thermal_throttling_status_pair.second.throttling_release_map) { *dump_buf << " " << request_pair.first << ": " << request_pair.second << std::endl; } } if (thermal_throttling_status_pair.second.cdev_status_map.size()) { *dump_buf << " cdev request state" << std::endl; for (const auto &request_pair : thermal_throttling_status_pair.second.cdev_status_map) { *dump_buf << " " << request_pair.first << ": " << request_pair.second << std::endl; } } } } void Thermal::dumpPowerRailInfo(std::ostringstream *dump_buf) { const auto &power_rail_info_map = thermal_helper_.GetPowerRailInfoMap(); const auto &power_status_map = thermal_helper_.GetPowerStatusMap(); *dump_buf << "getPowerRailInfo:" << std::endl; for (const auto &power_rail_pair : power_rail_info_map) { *dump_buf << " Power Rail: " << power_rail_pair.first << std::endl; *dump_buf << " Power Sample Count: " << power_rail_pair.second.power_sample_count << std::endl; *dump_buf << " Power Sample Delay: " << power_rail_pair.second.power_sample_delay.count() << std::endl; if (power_status_map.count(power_rail_pair.first)) { auto power_history = power_status_map.at(power_rail_pair.first).power_history; *dump_buf << " Last Updated AVG Power: " << power_status_map.at(power_rail_pair.first).last_updated_avg_power << " mW" << std::endl; if (power_rail_pair.second.virtual_power_rail_info != nullptr) { *dump_buf << " Formula="; switch (power_rail_pair.second.virtual_power_rail_info->formula) { case FormulaOption::COUNT_THRESHOLD: *dump_buf << "COUNT_THRESHOLD"; break; case FormulaOption::WEIGHTED_AVG: *dump_buf << "WEIGHTED_AVG"; break; case FormulaOption::MAXIMUM: *dump_buf << "MAXIMUM"; break; case FormulaOption::MINIMUM: *dump_buf << "MINIMUM"; break; default: *dump_buf << "NONE"; break; } *dump_buf << std::endl; } for (size_t i = 0; i < power_history.size(); ++i) { if (power_rail_pair.second.virtual_power_rail_info != nullptr) { *dump_buf << " Linked power rail " << power_rail_pair.second.virtual_power_rail_info->linked_power_rails[i] << std::endl; *dump_buf << " Coefficient=" << power_rail_pair.second.virtual_power_rail_info->coefficients[i] << std::endl; *dump_buf << " Power Samples: "; } else { *dump_buf << " Power Samples: "; } while (power_history[i].size() > 0) { const auto power_sample = power_history[i].front(); power_history[i].pop(); *dump_buf << "(T=" << power_sample.duration << ", uWs=" << power_sample.energy_counter << ") "; } *dump_buf << std::endl; } } } } void Thermal::dumpStatsRecord(std::ostringstream *dump_buf, const StatsRecord &stats_record, std::string_view line_prefix) { const auto now = boot_clock::now(); *dump_buf << line_prefix << "Time Since Last Stats Report: " << std::chrono::duration_cast( now - stats_record.last_stats_report_time) .count() << " mins" << std::endl; *dump_buf << line_prefix << "Time in State ms: ["; for (const auto &time_in_state : stats_record.time_in_state_ms) { *dump_buf << time_in_state.count() << " "; } *dump_buf << "]" << std::endl; } void Thermal::dumpThermalStats(std::ostringstream *dump_buf) { *dump_buf << "getThermalStatsInfo:" << std::endl; *dump_buf << " Sensor Temp Stats Info:" << std::endl; const auto &sensor_temp_stats_map_ = thermal_helper_.GetSensorTempStatsSnapshot(); const std::string sensor_temp_stats_line_prefix(" "); for (const auto &sensor_temp_stats_pair : sensor_temp_stats_map_) { *dump_buf << " Sensor Name: " << sensor_temp_stats_pair.first << std::endl; const auto &sensor_temp_stats = sensor_temp_stats_pair.second; *dump_buf << " Max Temp: " << sensor_temp_stats.max_temp << ", TimeStamp: " << system_clock::to_time_t(sensor_temp_stats.max_temp_timestamp) << std::endl; *dump_buf << " Min Temp: " << sensor_temp_stats.min_temp << ", TimeStamp: " << system_clock::to_time_t(sensor_temp_stats.min_temp_timestamp) << std::endl; for (const auto &stats_by_threshold : sensor_temp_stats.stats_by_custom_threshold) { *dump_buf << " Record by Threshold: ["; for (const auto &threshold : stats_by_threshold.thresholds) { *dump_buf << threshold << " "; } *dump_buf << "]" << std::endl; if (stats_by_threshold.logging_name.has_value()) { *dump_buf << " Logging Name: " << stats_by_threshold.logging_name.value() << std::endl; } dumpStatsRecord(dump_buf, stats_by_threshold.stats_record, sensor_temp_stats_line_prefix); } if (sensor_temp_stats.stats_by_default_threshold.has_value()) { *dump_buf << " Record by Severity:" << std::endl; dumpStatsRecord(dump_buf, sensor_temp_stats.stats_by_default_threshold.value(), sensor_temp_stats_line_prefix); } } *dump_buf << " Sensor Cdev Request Stats Info:" << std::endl; const auto &sensor_cdev_request_stats_map_ = thermal_helper_.GetSensorCoolingDeviceRequestStatsSnapshot(); const std::string sensor_cdev_request_stats_line_prefix(" "); for (const auto &sensor_cdev_request_stats_pair : sensor_cdev_request_stats_map_) { *dump_buf << " Sensor Name: " << sensor_cdev_request_stats_pair.first << std::endl; for (const auto &cdev_request_stats_pair : sensor_cdev_request_stats_pair.second) { *dump_buf << " Cooling Device Name: " << cdev_request_stats_pair.first << std::endl; const auto &request_stats = cdev_request_stats_pair.second; for (const auto &stats_by_threshold : request_stats.stats_by_custom_threshold) { *dump_buf << " Record by Threshold: ["; for (const auto &threshold : stats_by_threshold.thresholds) { *dump_buf << threshold << " "; } *dump_buf << "]" << std::endl; if (stats_by_threshold.logging_name.has_value()) { *dump_buf << " Logging Name: " << stats_by_threshold.logging_name.value() << std::endl; } dumpStatsRecord(dump_buf, stats_by_threshold.stats_record, sensor_cdev_request_stats_line_prefix); } if (request_stats.stats_by_default_threshold.has_value()) { *dump_buf << " Record by All State" << std::endl; dumpStatsRecord(dump_buf, request_stats.stats_by_default_threshold.value(), sensor_cdev_request_stats_line_prefix); } } } } void Thermal::dumpThermalData(int fd) { std::ostringstream dump_buf; if (!thermal_helper_.isInitializedOk()) { dump_buf << "ThermalHAL not initialized properly." << std::endl; } else { const auto &sensor_status_map = thermal_helper_.GetSensorStatusMap(); { dump_buf << "getCachedTemperatures:" << std::endl; boot_clock::time_point now = boot_clock::now(); for (const auto &sensor_status_pair : sensor_status_map) { if ((sensor_status_pair.second.thermal_cached.timestamp) == boot_clock::time_point::min()) { continue; } dump_buf << " Name: " << sensor_status_pair.first << " CachedValue: " << sensor_status_pair.second.thermal_cached.temp << " TimeToCache: " << std::chrono::duration_cast( now - sensor_status_pair.second.thermal_cached.timestamp) .count() << "ms" << std::endl; } } { dump_buf << "getEmulTemperatures:" << std::endl; for (const auto &sensor_status_pair : sensor_status_map) { if (sensor_status_pair.second.emul_setting == nullptr) { continue; } dump_buf << " Name: " << sensor_status_pair.first << " EmulTemp: " << sensor_status_pair.second.emul_setting->emul_temp << " EmulSeverity: " << sensor_status_pair.second.emul_setting->emul_severity << std::endl; } } { const auto &map = thermal_helper_.GetSensorInfoMap(); dump_buf << "getCurrentTemperatures:" << std::endl; Temperature temp_2_0; for (const auto &name_info_pair : map) { thermal_helper_.readTemperature(name_info_pair.first, &temp_2_0, nullptr, true); dump_buf << " Type: " << toString(temp_2_0.type) << " Name: " << name_info_pair.first << " CurrentValue: " << temp_2_0.value << " ThrottlingStatus: " << toString(temp_2_0.throttlingStatus) << std::endl; } dump_buf << "getTemperatureThresholds:" << std::endl; for (const auto &name_info_pair : map) { if (!name_info_pair.second.is_watch) { continue; } dump_buf << " Type: " << toString(name_info_pair.second.type) << " Name: " << name_info_pair.first; dump_buf << " hotThrottlingThreshold: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { dump_buf << name_info_pair.second.hot_thresholds[i] << " "; } dump_buf << "] coldThrottlingThreshold: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { dump_buf << name_info_pair.second.cold_thresholds[i] << " "; } dump_buf << "] vrThrottlingThreshold: " << name_info_pair.second.vr_threshold; dump_buf << std::endl; } dump_buf << "getHysteresis:" << std::endl; for (const auto &name_info_pair : map) { if (!name_info_pair.second.is_watch) { continue; } dump_buf << " Name: " << name_info_pair.first; dump_buf << " hotHysteresis: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { dump_buf << name_info_pair.second.hot_hysteresis[i] << " "; } dump_buf << "] coldHysteresis: ["; for (size_t i = 0; i < kThrottlingSeverityCount; ++i) { dump_buf << name_info_pair.second.cold_hysteresis[i] << " "; } dump_buf << "]" << std::endl; } } { dump_buf << "getCurrentCoolingDevices:" << std::endl; std::vector cooling_devices; if (!thermal_helper_.fillCurrentCoolingDevices(false, CoolingType::CPU, &cooling_devices)) { dump_buf << " Failed to getCurrentCoolingDevices." << std::endl; } for (const auto &c : cooling_devices) { dump_buf << " Type: " << toString(c.type) << " Name: " << c.name << " CurrentValue: " << c.value << std::endl; } } { dump_buf << "getCallbacks:" << std::endl; dump_buf << " Total: " << callbacks_.size() << std::endl; for (const auto &c : callbacks_) { dump_buf << " IsFilter: " << c.is_filter_type << " Type: " << toString(c.type) << std::endl; } } { dump_buf << "sendCallback:" << std::endl; dump_buf << " Enabled List: "; const auto &map = thermal_helper_.GetSensorInfoMap(); for (const auto &name_info_pair : map) { if (name_info_pair.second.send_cb) { dump_buf << name_info_pair.first << " "; } } dump_buf << std::endl; } { dump_buf << "sendPowerHint:" << std::endl; dump_buf << " Enabled List: "; const auto &map = thermal_helper_.GetSensorInfoMap(); for (const auto &name_info_pair : map) { if (name_info_pair.second.send_powerhint) { dump_buf << name_info_pair.first << " "; } } dump_buf << std::endl; } dumpVirtualSensorInfo(&dump_buf); dumpThrottlingInfo(&dump_buf); dumpThrottlingRequestStatus(&dump_buf); dumpPowerRailInfo(&dump_buf); dumpThermalStats(&dump_buf); { dump_buf << "getAIDLPowerHalInfo:" << std::endl; dump_buf << " Exist: " << std::boolalpha << thermal_helper_.isAidlPowerHalExist() << std::endl; dump_buf << " Connected: " << std::boolalpha << thermal_helper_.isPowerHalConnected() << std::endl; dump_buf << " Ext connected: " << std::boolalpha << thermal_helper_.isPowerHalExtConnected() << std::endl; } } std::string buf = dump_buf.str(); if (!::android::base::WriteStringToFd(buf, fd)) { PLOG(ERROR) << "Failed to dump state to fd"; } fsync(fd); } binder_status_t Thermal::dump(int fd, const char **args, uint32_t numArgs) { if (numArgs == 0 || std::string(args[0]) == "-a") { dumpThermalData(fd); return STATUS_OK; } if (std::string(args[0]) == "emul_temp") { return (numArgs != 3 || !thermal_helper_.emulTemp(std::string(args[1]), std::atof(args[2]))) ? STATUS_BAD_VALUE : STATUS_OK; } else if (std::string(args[0]) == "emul_severity") { return (numArgs != 3 || !thermal_helper_.emulSeverity(std::string(args[1]), std::atoi(args[2]))) ? STATUS_BAD_VALUE : STATUS_OK; } else if (std::string(args[0]) == "emul_clear") { return (numArgs != 2 || !thermal_helper_.emulClear(std::string(args[1]))) ? STATUS_BAD_VALUE : STATUS_OK; } return STATUS_BAD_VALUE; } void Thermal::Looper::addEvent(const Thermal::Looper::Event &e) { std::unique_lock lock(mutex_); events_.push(e); cv_.notify_all(); } void Thermal::Looper::loop() { while (true) { std::unique_lock lock(mutex_); cv_.wait(lock, [&] { return !events_.empty(); }); Event event = events_.front(); events_.pop(); lock.unlock(); event.handler(); } } } // namespace implementation } // namespace thermal } // namespace hardware } // namespace android } // namespace aidl