/* * 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 "android.hardware.thermal@1.0-impl" #include #include #include #include #include #include #include "Thermal.h" namespace android { namespace hardware { namespace thermal { namespace V1_0 { namespace implementation { namespace { float finalizeTemperature(float temperature) { return temperature == UNKNOWN_TEMPERATURE ? NAN : temperature; } } Thermal::Thermal(thermal_module_t* module) : mModule(module) {} // Methods from ::android::hardware::thermal::V1_0::IThermal follow. Return Thermal::getTemperatures(getTemperatures_cb _hidl_cb) { ThermalStatus status; status.code = ThermalStatusCode::SUCCESS; hidl_vec temperatures; if (!mModule || !mModule->getTemperatures) { ALOGI("getTemperatures is not implemented in Thermal HAL."); _hidl_cb(status, temperatures); return Void(); } ssize_t size = mModule->getTemperatures(mModule, nullptr, 0); if (size >= 0) { std::vector list; list.resize(size); size = mModule->getTemperatures(mModule, list.data(), list.size()); if (size >= 0) { temperatures.resize(list.size()); for (size_t i = 0; i < list.size(); ++i) { switch (list[i].type) { case DEVICE_TEMPERATURE_UNKNOWN: temperatures[i].type = TemperatureType::UNKNOWN; break; case DEVICE_TEMPERATURE_CPU: temperatures[i].type = TemperatureType::CPU; break; case DEVICE_TEMPERATURE_GPU: temperatures[i].type = TemperatureType::GPU; break; case DEVICE_TEMPERATURE_BATTERY: temperatures[i].type = TemperatureType::BATTERY; break; case DEVICE_TEMPERATURE_SKIN: temperatures[i].type = TemperatureType::SKIN; break; default: ALOGE("Unknown temperature %s type", list[i].name); ; } temperatures[i].name = list[i].name; temperatures[i].currentValue = finalizeTemperature(list[i].current_value); temperatures[i].throttlingThreshold = finalizeTemperature(list[i].throttling_threshold); temperatures[i].shutdownThreshold = finalizeTemperature(list[i].shutdown_threshold); temperatures[i].vrThrottlingThreshold = finalizeTemperature(list[i].vr_throttling_threshold); } } } if (size < 0) { status.code = ThermalStatusCode::FAILURE; status.debugMessage = strerror(-size); } _hidl_cb(status, temperatures); return Void(); } Return Thermal::getCpuUsages(getCpuUsages_cb _hidl_cb) { ThermalStatus status; hidl_vec cpuUsages; status.code = ThermalStatusCode::SUCCESS; if (!mModule || !mModule->getCpuUsages) { ALOGI("getCpuUsages is not implemented in Thermal HAL"); _hidl_cb(status, cpuUsages); return Void(); } ssize_t size = mModule->getCpuUsages(mModule, nullptr); if (size >= 0) { std::vector list; list.resize(size); size = mModule->getCpuUsages(mModule, list.data()); if (size >= 0) { list.resize(size); cpuUsages.resize(size); for (size_t i = 0; i < list.size(); ++i) { cpuUsages[i].name = list[i].name; cpuUsages[i].active = list[i].active; cpuUsages[i].total = list[i].total; cpuUsages[i].isOnline = list[i].is_online; } } else { status.code = ThermalStatusCode::FAILURE; status.debugMessage = strerror(-size); } } if (size < 0) { status.code = ThermalStatusCode::FAILURE; status.debugMessage = strerror(-size); } _hidl_cb(status, cpuUsages); return Void(); } Return Thermal::getCoolingDevices(getCoolingDevices_cb _hidl_cb) { ThermalStatus status; status.code = ThermalStatusCode::SUCCESS; hidl_vec coolingDevices; if (!mModule || !mModule->getCoolingDevices) { ALOGI("getCoolingDevices is not implemented in Thermal HAL."); _hidl_cb(status, coolingDevices); return Void(); } ssize_t size = mModule->getCoolingDevices(mModule, nullptr, 0); if (size >= 0) { std::vector list; list.resize(size); size = mModule->getCoolingDevices(mModule, list.data(), list.size()); if (size >= 0) { list.resize(size); coolingDevices.resize(list.size()); for (size_t i = 0; i < list.size(); ++i) { switch (list[i].type) { case FAN_RPM: coolingDevices[i].type = CoolingType::FAN_RPM; break; default: ALOGE("Unknown cooling device %s type", list[i].name); } coolingDevices[i].name = list[i].name; coolingDevices[i].currentValue = list[i].current_value; } } } if (size < 0) { status.code = ThermalStatusCode::FAILURE; status.debugMessage = strerror(-size); } _hidl_cb(status, coolingDevices); return Void(); } IThermal* HIDL_FETCH_IThermal(const char* /* name */) { thermal_module_t* module; status_t err = hw_get_module(THERMAL_HARDWARE_MODULE_ID, const_cast( reinterpret_cast(&module))); if (err || !module) { ALOGE("Couldn't load %s module (%s)", THERMAL_HARDWARE_MODULE_ID, strerror(-err)); } if (err == 0 && module->common.methods->open) { struct hw_device_t* device; err = module->common.methods->open(&module->common, THERMAL_HARDWARE_MODULE_ID, &device); if (err) { ALOGE("Couldn't open %s module (%s)", THERMAL_HARDWARE_MODULE_ID, strerror(-err)); } else { return new Thermal(reinterpret_cast(device)); } } return new Thermal(module); } } // namespace implementation } // namespace V1_0 } // namespace thermal } // namespace hardware } // namespace android