thermal/2.0/default/Thermal.cpp - LeafOS-Project/android_hardware_interfaces - Gitiles

 /*
  * 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.
  */

 #define LOG_TAG "android.hardware.thermal@2.0-service-mock"

 #include <cmath>
 #include <set>

 #include <android-base/logging.h>
 #include <hidl/HidlTransportSupport.h>

 #include "Thermal.h"

 namespace android {
 namespace hardware {
 namespace thermal {
 namespace V2_0 {
 namespace implementation {

 using ::android::sp;
 using ::android::hardware::interfacesEqual;
 using ::android::hardware::thermal::V1_0::ThermalStatus;
 using ::android::hardware::thermal::V1_0::ThermalStatusCode;

 std::set<sp<IThermalChangedCallback>> gCallbacks;

 static const Temperature_1_0 kTemp_1_0 = {
         .type = static_cast<::android::hardware::thermal::V1_0::TemperatureType>(
                 TemperatureType::SKIN),
         .name = "test temperature sensor",
         .currentValue = 30.8,
         .throttlingThreshold = 48.0,
         .shutdownThreshold = 60.0,
         .vrThrottlingThreshold = 49.0,
 };

 static const Temperature_2_0 kTemp_2_0 = {
         .type = TemperatureType::SKIN,
         .name = "test temperature sensor",
         .value = 30.8,
         .throttlingStatus = ThrottlingSeverity::NONE,
 };

 static const TemperatureThreshold kTempThreshold = {
         .type = TemperatureType::SKIN,
         .name = "test temperature sensor",
         .hotThrottlingThresholds = {{NAN, NAN, NAN, 48.0, NAN, NAN, 60.0}},
         .coldThrottlingThresholds = {{NAN, NAN, NAN, NAN, NAN, NAN, NAN}},
         .vrThrottlingThreshold = 49.0,
 };

 static const CoolingDevice_1_0 kCooling_1_0 = {
         .type = ::android::hardware::thermal::V1_0::CoolingType::FAN_RPM,
         .name = "test cooling device",
         .currentValue = 100.0,
 };

 static const CoolingDevice_2_0 kCooling_2_0 = {
         .type = CoolingType::FAN,
         .name = "test cooling device",
         .value = 100,
 };

 static const CpuUsage kCpuUsage = {
         .name = "cpu_name",
         .active = 0,
         .total = 0,
         .isOnline = true,
 };

 // Methods from ::android::hardware::thermal::V1_0::IThermal follow.
 Return<void> Thermal::getTemperatures(getTemperatures_cb _hidl_cb) {
     ThermalStatus status;
     status.code = ThermalStatusCode::SUCCESS;
     std::vector<Temperature_1_0> temperatures = {kTemp_1_0};
     _hidl_cb(status, temperatures);
     return Void();
 }

 Return<void> Thermal::getCpuUsages(getCpuUsages_cb _hidl_cb) {
     ThermalStatus status;
     status.code = ThermalStatusCode::SUCCESS;
     std::vector<CpuUsage> cpu_usages = {kCpuUsage};
     _hidl_cb(status, cpu_usages);
     return Void();
 }

 Return<void> Thermal::getCoolingDevices(getCoolingDevices_cb _hidl_cb) {
     ThermalStatus status;
     status.code = ThermalStatusCode::SUCCESS;
     std::vector<CoolingDevice_1_0> cooling_devices = {kCooling_1_0};
     _hidl_cb(status, cooling_devices);
     return Void();
 }

 // Methods from ::android::hardware::thermal::V2_0::IThermal follow.
 Return<void> Thermal::getCurrentTemperatures(bool filterType, TemperatureType type,
                                              getCurrentTemperatures_cb _hidl_cb) {
     ThermalStatus status;
     status.code = ThermalStatusCode::SUCCESS;
     std::vector<Temperature_2_0> temperatures;
     if (filterType && type != kTemp_2_0.type) {
         status.code = ThermalStatusCode::FAILURE;
         status.debugMessage = "Failed to read data";
     } else {
         temperatures = {kTemp_2_0};
     }
     _hidl_cb(status, temperatures);
     return Void();
 }

 Return<void> Thermal::getTemperatureThresholds(bool filterType, TemperatureType type,
                                                getTemperatureThresholds_cb _hidl_cb) {
     ThermalStatus status;
     status.code = ThermalStatusCode::SUCCESS;
     std::vector<TemperatureThreshold> temperature_thresholds;
     if (filterType && type != kTempThreshold.type) {
         status.code = ThermalStatusCode::FAILURE;
         status.debugMessage = "Failed to read data";
     } else {
         temperature_thresholds = {kTempThreshold};
     }
     _hidl_cb(status, temperature_thresholds);
     return Void();
 }

 Return<void> Thermal::getCurrentCoolingDevices(bool filterType, CoolingType type,
                                                getCurrentCoolingDevices_cb _hidl_cb) {
     ThermalStatus status;
     status.code = ThermalStatusCode::SUCCESS;
     std::vector<CoolingDevice_2_0> cooling_devices;
     if (filterType && type != kCooling_2_0.type) {
         status.code = ThermalStatusCode::FAILURE;
         status.debugMessage = "Failed to read data";
     } else {
         cooling_devices = {kCooling_2_0};
     }
     _hidl_cb(status, cooling_devices);
     return Void();
 }

 Return<void> Thermal::registerThermalChangedCallback(const sp<IThermalChangedCallback>& callback,
                                                      bool filterType, TemperatureType type,
                                                      registerThermalChangedCallback_cb _hidl_cb) {
     ThermalStatus status;
     if (callback == nullptr) {
         status.code = ThermalStatusCode::FAILURE;
         status.debugMessage = "Invalid nullptr callback";
         LOG(ERROR) << status.debugMessage;
         _hidl_cb(status);
         return Void();
     } else {
         status.code = ThermalStatusCode::SUCCESS;
     }
     std::lock_guard<std::mutex> _lock(thermal_callback_mutex_);
     if (std::any_of(callbacks_.begin(), callbacks_.end(), [&](const CallbackSetting& c) {
             return interfacesEqual(c.callback, callback);
         })) {
         status.code = ThermalStatusCode::FAILURE;
         status.debugMessage = "Same callback interface registered already";
         LOG(ERROR) << status.debugMessage;
     } else {
         callbacks_.emplace_back(callback, filterType, type);
         LOG(INFO) << "A callback has been registered to ThermalHAL, isFilter: " << filterType
                   << " Type: " << android::hardware::thermal::V2_0::toString(type);
     }
     _hidl_cb(status);
     return Void();
 }

 Return<void> Thermal::unregisterThermalChangedCallback(
     const sp<IThermalChangedCallback>& callback, unregisterThermalChangedCallback_cb _hidl_cb) {
     ThermalStatus status;
     if (callback == nullptr) {
         status.code = ThermalStatusCode::FAILURE;
         status.debugMessage = "Invalid nullptr callback";
         LOG(ERROR) << status.debugMessage;
         _hidl_cb(status);
         return Void();
     } else {
         status.code = ThermalStatusCode::SUCCESS;
     }
     bool removed = false;
     std::lock_guard<std::mutex> _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 from ThermalHAL, isFilter: "
                                    << c.is_filter_type << " Type: "
                                    << android::hardware::thermal::V2_0::toString(c.type);
                                removed = true;
                                return true;
                            }
                            return false;
                        }),
         callbacks_.end());
     if (!removed) {
         status.code = ThermalStatusCode::FAILURE;
         status.debugMessage = "The callback was not registered before";
         LOG(ERROR) << status.debugMessage;
     }
     _hidl_cb(status);
     return Void();
 }

 }  // namespace implementation
 }  // namespace V2_0
 }  // namespace thermal
 }  // namespace hardware
 }  // namespace android
	/*
	* 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.
	*/

	#define LOG_TAG "android.hardware.thermal@2.0-service-mock"

	#include <cmath>
	#include <set>

	#include <android-base/logging.h>
	#include <hidl/HidlTransportSupport.h>

	#include "Thermal.h"

	namespace android {
	namespace hardware {
	namespace thermal {
	namespace V2_0 {
	namespace implementation {

	using ::android::sp;
	using ::android::hardware::interfacesEqual;
	using ::android::hardware::thermal::V1_0::ThermalStatus;
	using ::android::hardware::thermal::V1_0::ThermalStatusCode;

	std::set<sp<IThermalChangedCallback>> gCallbacks;

	static const Temperature_1_0 kTemp_1_0 = {
	.type = static_cast<::android::hardware::thermal::V1_0::TemperatureType>(
	TemperatureType::SKIN),
	.name = "test temperature sensor",
	.currentValue = 30.8,
	.throttlingThreshold = 48.0,
	.shutdownThreshold = 60.0,
	.vrThrottlingThreshold = 49.0,
	};

	static const Temperature_2_0 kTemp_2_0 = {
	.type = TemperatureType::SKIN,
	.name = "test temperature sensor",
	.value = 30.8,
	.throttlingStatus = ThrottlingSeverity::NONE,
	};

	static const TemperatureThreshold kTempThreshold = {
	.type = TemperatureType::SKIN,
	.name = "test temperature sensor",
	.hotThrottlingThresholds = {{NAN, NAN, NAN, 48.0, NAN, NAN, 60.0}},
	.coldThrottlingThresholds = {{NAN, NAN, NAN, NAN, NAN, NAN, NAN}},
	.vrThrottlingThreshold = 49.0,
	};

	static const CoolingDevice_1_0 kCooling_1_0 = {
	.type = ::android::hardware::thermal::V1_0::CoolingType::FAN_RPM,
	.name = "test cooling device",
	.currentValue = 100.0,
	};

	static const CoolingDevice_2_0 kCooling_2_0 = {
	.type = CoolingType::FAN,
	.name = "test cooling device",
	.value = 100,
	};

	static const CpuUsage kCpuUsage = {
	.name = "cpu_name",
	.active = 0,
	.total = 0,
	.isOnline = true,
	};

	// Methods from ::android::hardware::thermal::V1_0::IThermal follow.
	Return<void> Thermal::getTemperatures(getTemperatures_cb _hidl_cb) {
	ThermalStatus status;
	status.code = ThermalStatusCode::SUCCESS;
	std::vector<Temperature_1_0> temperatures = {kTemp_1_0};
	_hidl_cb(status, temperatures);
	return Void();
	}

	Return<void> Thermal::getCpuUsages(getCpuUsages_cb _hidl_cb) {
	ThermalStatus status;
	status.code = ThermalStatusCode::SUCCESS;
	std::vector<CpuUsage> cpu_usages = {kCpuUsage};
	_hidl_cb(status, cpu_usages);
	return Void();
	}

	Return<void> Thermal::getCoolingDevices(getCoolingDevices_cb _hidl_cb) {
	ThermalStatus status;
	status.code = ThermalStatusCode::SUCCESS;
	std::vector<CoolingDevice_1_0> cooling_devices = {kCooling_1_0};
	_hidl_cb(status, cooling_devices);
	return Void();
	}

	// Methods from ::android::hardware::thermal::V2_0::IThermal follow.
	Return<void> Thermal::getCurrentTemperatures(bool filterType, TemperatureType type,
	getCurrentTemperatures_cb _hidl_cb) {
	ThermalStatus status;
	status.code = ThermalStatusCode::SUCCESS;
	std::vector<Temperature_2_0> temperatures;
	if (filterType && type != kTemp_2_0.type) {
	status.code = ThermalStatusCode::FAILURE;
	status.debugMessage = "Failed to read data";
	} else {
	temperatures = {kTemp_2_0};
	}
	_hidl_cb(status, temperatures);
	return Void();
	}

	Return<void> Thermal::getTemperatureThresholds(bool filterType, TemperatureType type,
	getTemperatureThresholds_cb _hidl_cb) {
	ThermalStatus status;
	status.code = ThermalStatusCode::SUCCESS;
	std::vector<TemperatureThreshold> temperature_thresholds;
	if (filterType && type != kTempThreshold.type) {
	status.code = ThermalStatusCode::FAILURE;
	status.debugMessage = "Failed to read data";
	} else {
	temperature_thresholds = {kTempThreshold};
	}
	_hidl_cb(status, temperature_thresholds);
	return Void();
	}

	Return<void> Thermal::getCurrentCoolingDevices(bool filterType, CoolingType type,
	getCurrentCoolingDevices_cb _hidl_cb) {
	ThermalStatus status;
	status.code = ThermalStatusCode::SUCCESS;
	std::vector<CoolingDevice_2_0> cooling_devices;
	if (filterType && type != kCooling_2_0.type) {
	status.code = ThermalStatusCode::FAILURE;
	status.debugMessage = "Failed to read data";
	} else {
	cooling_devices = {kCooling_2_0};
	}
	_hidl_cb(status, cooling_devices);
	return Void();
	}

	Return<void> Thermal::registerThermalChangedCallback(const sp<IThermalChangedCallback>& callback,
	bool filterType, TemperatureType type,
	registerThermalChangedCallback_cb _hidl_cb) {
	ThermalStatus status;
	if (callback == nullptr) {
	status.code = ThermalStatusCode::FAILURE;
	status.debugMessage = "Invalid nullptr callback";
	LOG(ERROR) << status.debugMessage;
	_hidl_cb(status);
	return Void();
	} else {
	status.code = ThermalStatusCode::SUCCESS;
	}
	std::lock_guard<std::mutex> _lock(thermal_callback_mutex_);
	if (std::any_of(callbacks_.begin(), callbacks_.end(), [&](const CallbackSetting& c) {
	return interfacesEqual(c.callback, callback);
	})) {
	status.code = ThermalStatusCode::FAILURE;
	status.debugMessage = "Same callback interface registered already";
	LOG(ERROR) << status.debugMessage;
	} else {
	callbacks_.emplace_back(callback, filterType, type);
	LOG(INFO) << "A callback has been registered to ThermalHAL, isFilter: " << filterType
	<< " Type: " << android::hardware::thermal::V2_0::toString(type);
	}
	_hidl_cb(status);
	return Void();
	}

	Return<void> Thermal::unregisterThermalChangedCallback(
	const sp<IThermalChangedCallback>& callback, unregisterThermalChangedCallback_cb _hidl_cb) {
	ThermalStatus status;
	if (callback == nullptr) {
	status.code = ThermalStatusCode::FAILURE;
	status.debugMessage = "Invalid nullptr callback";
	LOG(ERROR) << status.debugMessage;
	_hidl_cb(status);
	return Void();
	} else {
	status.code = ThermalStatusCode::SUCCESS;
	}
	bool removed = false;
	std::lock_guard<std::mutex> _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 from ThermalHAL, isFilter: "
	<< c.is_filter_type << " Type: "
	<< android::hardware::thermal::V2_0::toString(c.type);
	removed = true;
	return true;
	}
	return false;
	}),
	callbacks_.end());
	if (!removed) {
	status.code = ThermalStatusCode::FAILURE;
	status.debugMessage = "The callback was not registered before";
	LOG(ERROR) << status.debugMessage;
	}
	_hidl_cb(status);
	return Void();
	}

	} // namespace implementation
	} // namespace V2_0
	} // namespace thermal
	} // namespace hardware
	} // namespace android