power/stats/aidl/vts/VtsHalPowerStatsTargetTest.cpp - LeafOS-Project/android_hardware_interfaces - Gitiles

 /*
  * Copyright (C) 2020 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 <aidl/Gtest.h>
 #include <aidl/Vintf.h>

 #include <aidl/android/hardware/power/stats/IPowerStats.h>
 #include <android-base/properties.h>
 #include <android/binder_manager.h>
 #include <android/binder_process.h>

 #include <algorithm>
 #include <iterator>
 #include <random>
 #include <unordered_map>

 using aidl::android::hardware::power::stats::Channel;
 using aidl::android::hardware::power::stats::EnergyConsumer;
 using aidl::android::hardware::power::stats::EnergyConsumerAttribution;
 using aidl::android::hardware::power::stats::EnergyConsumerResult;
 using aidl::android::hardware::power::stats::EnergyConsumerType;
 using aidl::android::hardware::power::stats::EnergyMeasurement;
 using aidl::android::hardware::power::stats::IPowerStats;
 using aidl::android::hardware::power::stats::PowerEntity;
 using aidl::android::hardware::power::stats::State;
 using aidl::android::hardware::power::stats::StateResidency;
 using aidl::android::hardware::power::stats::StateResidencyResult;

 using ndk::SpAIBinder;

 #define ASSERT_OK(a)                                     \
     do {                                                 \
         auto ret = a;                                    \
         ASSERT_TRUE(ret.isOk()) << ret.getDescription(); \
     } while (0)

 class PowerStatsAidl : public testing::TestWithParam<std::string> {
   public:
     virtual void SetUp() override {
         powerstats = IPowerStats::fromBinder(
                 SpAIBinder(AServiceManager_waitForService(GetParam().c_str())));
         ASSERT_NE(nullptr, powerstats.get());
     }

     template <typename T>
     std::vector<T> getRandomSubset(std::vector<T> const& collection);

     void testNameValid(const std::string& name);

     template <typename T, typename S>
     void testUnique(std::vector<T> const& collection, S T::*field);

     template <typename T, typename S, typename R>
     void testMatching(std::vector<T> const& c1, R T::*f1, std::vector<S> const& c2, R S::*f2);

     bool isEntitySkipped(const std::string& str);

     void excludeSkippedEntities(std::vector<PowerEntity>* entities,
                                 std::vector<StateResidencyResult>* results);

     std::shared_ptr<IPowerStats> powerstats;
 };

 // Returns a random subset from a collection
 template <typename T>
 std::vector<T> PowerStatsAidl::getRandomSubset(std::vector<T> const& collection) {
     if (collection.empty()) {
         return {};
     }

     std::vector<T> selected;
     std::sample(collection.begin(), collection.end(), std::back_inserter(selected),
                 rand() % collection.size() + 1, std::mt19937{std::random_device{}()});

     return selected;
 }

 // Tests whether a name is valid
 void PowerStatsAidl::testNameValid(const std::string& name) {
     EXPECT_NE(name, "");
 }

 // Tests whether the fields in a given collection are unique
 template <typename T, typename S>
 void PowerStatsAidl::testUnique(std::vector<T> const& collection, S T::*field) {
     std::set<S> cSet;
     for (auto const& elem : collection) {
         EXPECT_TRUE(cSet.insert(elem.*field).second);
     }
 }

 template <typename T, typename S, typename R>
 void PowerStatsAidl::testMatching(std::vector<T> const& c1, R T::*f1, std::vector<S> const& c2,
                                   R S::*f2) {
     std::set<R> c1fields, c2fields;
     for (auto elem : c1) {
         c1fields.insert(elem.*f1);
     }

     for (auto elem : c2) {
         c2fields.insert(elem.*f2);
     }

     EXPECT_EQ(c1fields, c2fields);
 }

 bool PowerStatsAidl::isEntitySkipped(const std::string& str) {
     bool skip = false;
     // TODO(b/229698505): Extend PowerEntityInfo to identify timed power entity
     skip |= str.find("AoC") != std::string::npos;
     // Lassen GNSS power stats will be present after running GPS session once.
     // Otherwise, VTS will fail due to missing GPS power stats.
     skip |= str.find("GPS") != std::string::npos;
     return skip;
 }

 void PowerStatsAidl::excludeSkippedEntities(std::vector<PowerEntity>* entities,
                                             std::vector<StateResidencyResult>* results) {
     for (auto it = entities->begin(); it != entities->end(); it++) {
         if (isEntitySkipped((*it).name)) {
             auto entityId = (*it).id;
             entities->erase(it--);

             // Erase result element matching the entity ID
             for (auto resultsIt = results->begin(); resultsIt != results->end(); resultsIt++) {
                 if ((*resultsIt).id == entityId) {
                     results->erase(resultsIt--);
                     break;
                 }
             }
         }
     }
 }

 // Each PowerEntity must have a valid name
 TEST_P(PowerStatsAidl, ValidatePowerEntityNames) {
     std::vector<PowerEntity> infos;
     ASSERT_OK(powerstats->getPowerEntityInfo(&infos));

     for (auto info : infos) {
         testNameValid(info.name);
     }
 }

 // Each power entity must have a unique name
 TEST_P(PowerStatsAidl, ValidatePowerEntityUniqueNames) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     testUnique(entities, &PowerEntity::name);
 }

 // Each PowerEntity must have a unique ID
 TEST_P(PowerStatsAidl, ValidatePowerEntityIds) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     testUnique(entities, &PowerEntity::id);
 }

 // Each power entity must have at least one state
 TEST_P(PowerStatsAidl, ValidateStateSize) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     for (auto entity : entities) {
         EXPECT_GT(entity.states.size(), 0);
     }
 }

 // Each state must have a valid name
 TEST_P(PowerStatsAidl, ValidateStateNames) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     for (auto entity : entities) {
         for (auto state : entity.states) {
             testNameValid(state.name);
         }
     }
 }

 // Each state must have a name that is unique to the given PowerEntity
 TEST_P(PowerStatsAidl, ValidateStateUniqueNames) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     for (auto entity : entities) {
         testUnique(entity.states, &State::name);
     }
 }

 // Each state must have an ID that is unique to the given PowerEntity
 TEST_P(PowerStatsAidl, ValidateStateUniqueIds) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     for (auto entity : entities) {
         testUnique(entity.states, &State::id);
     }
 }

 // State residency must return a valid status
 TEST_P(PowerStatsAidl, TestGetStateResidency) {
     std::vector<StateResidencyResult> results;
     ASSERT_OK(powerstats->getStateResidency({}, &results));
 }

 // State residency must return all results except timed power entities
 TEST_P(PowerStatsAidl, TestGetStateResidencyAllResultsExceptSkippedEntities) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     std::vector<StateResidencyResult> results;
     ASSERT_OK(powerstats->getStateResidency({}, &results));
     excludeSkippedEntities(&entities, &results);

     testMatching(entities, &PowerEntity::id, results, &StateResidencyResult::id);
 }

 // Each result must contain all state residencies except timed power entities
 TEST_P(PowerStatsAidl, TestGetStateResidencyAllStateResidenciesExceptSkippedEntities) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

     std::vector<StateResidencyResult> results;
     ASSERT_OK(powerstats->getStateResidency({}, &results));

     for (auto entity : entities) {
         if (!isEntitySkipped(entity.name)) {
             auto it = std::find_if(results.begin(), results.end(),
                                    [&entity](const auto& x) { return x.id == entity.id; });
             ASSERT_NE(it, results.end());

             testMatching(entity.states, &State::id, it->stateResidencyData, &StateResidency::id);
         }
     }
 }

 // State residency must return results for each requested power entity except timed power entities
 TEST_P(PowerStatsAidl, TestGetStateResidencySelectedResultsExceptTimedEntities) {
     std::vector<PowerEntity> entities;
     ASSERT_OK(powerstats->getPowerEntityInfo(&entities));
     if (entities.empty()) {
         return;
     }

     std::vector<PowerEntity> selectedEntities = getRandomSubset(entities);
     std::vector<int32_t> selectedIds;
     for (auto it = selectedEntities.begin(); it != selectedEntities.end(); it++) {
         if (!isEntitySkipped((*it).name)) {
             selectedIds.push_back((*it).id);
         } else {
             selectedEntities.erase(it--);
         }
     }

     std::vector<StateResidencyResult> selectedResults;
     ASSERT_OK(powerstats->getStateResidency(selectedIds, &selectedResults));

     testMatching(selectedEntities, &PowerEntity::id, selectedResults, &StateResidencyResult::id);
 }

 // Energy meter info must return a valid status
 TEST_P(PowerStatsAidl, TestGetEnergyMeterInfo) {
     std::vector<Channel> info;
     ASSERT_OK(powerstats->getEnergyMeterInfo(&info));
 }

 // Each channel must have a valid name
 TEST_P(PowerStatsAidl, ValidateChannelNames) {
     std::vector<Channel> channels;
     ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

     for (auto channel : channels) {
         testNameValid(channel.name);
     }
 }

 // Each channel must have a valid subsystem
 TEST_P(PowerStatsAidl, ValidateSubsystemNames) {
     std::vector<Channel> channels;
     ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

     for (auto channel : channels) {
         testNameValid(channel.subsystem);
     }
 }

 // Each channel must have a unique name
 TEST_P(PowerStatsAidl, ValidateChannelUniqueNames) {
     std::vector<Channel> channels;
     ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

     testUnique(channels, &Channel::name);
 }

 // Each channel must have a unique ID
 TEST_P(PowerStatsAidl, ValidateChannelUniqueIds) {
     std::vector<Channel> channels;
     ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

     testUnique(channels, &Channel::id);
 }

 // Reading energy meter must return a valid status
 TEST_P(PowerStatsAidl, TestReadEnergyMeter) {
     std::vector<EnergyMeasurement> data;
     ASSERT_OK(powerstats->readEnergyMeter({}, &data));
 }

 // Reading energy meter must return results for all available channels
 TEST_P(PowerStatsAidl, TestGetAllEnergyMeasurements) {
     std::vector<Channel> channels;
     ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

     std::vector<EnergyMeasurement> measurements;
     ASSERT_OK(powerstats->readEnergyMeter({}, &measurements));

     testMatching(channels, &Channel::id, measurements, &EnergyMeasurement::id);
 }

 // Reading energy must must return results for each selected channel
 TEST_P(PowerStatsAidl, TestGetSelectedEnergyMeasurements) {
     std::vector<Channel> channels;
     ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));
     if (channels.empty()) {
         return;
     }

     std::vector<Channel> selectedChannels = getRandomSubset(channels);
     std::vector<int32_t> selectedIds;
     for (auto const& channel : selectedChannels) {
         selectedIds.push_back(channel.id);
     }

     std::vector<EnergyMeasurement> selectedMeasurements;
     ASSERT_OK(powerstats->readEnergyMeter(selectedIds, &selectedMeasurements));

     testMatching(selectedChannels, &Channel::id, selectedMeasurements, &EnergyMeasurement::id);
 }

 // Energy consumer info must return a valid status
 TEST_P(PowerStatsAidl, TestGetEnergyConsumerInfo) {
     std::vector<EnergyConsumer> consumers;
     ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));
 }

 // Each energy consumer must have a unique id
 TEST_P(PowerStatsAidl, TestGetEnergyConsumerUniqueId) {
     std::vector<EnergyConsumer> consumers;
     ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

     testUnique(consumers, &EnergyConsumer::id);
 }

 // Each energy consumer must have a valid name
 TEST_P(PowerStatsAidl, ValidateEnergyConsumerNames) {
     std::vector<EnergyConsumer> consumers;
     ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

     for (auto consumer : consumers) {
         testNameValid(consumer.name);
     }
 }

 // Each energy consumer must have a unique name
 TEST_P(PowerStatsAidl, ValidateEnergyConsumerUniqueNames) {
     std::vector<EnergyConsumer> consumers;
     ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

     testUnique(consumers, &EnergyConsumer::name);
 }

 // Energy consumers of the same type must have ordinals that are 0,1,2,..., N - 1
 TEST_P(PowerStatsAidl, ValidateEnergyConsumerOrdinals) {
     std::vector<EnergyConsumer> consumers;
     ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

     std::unordered_map<EnergyConsumerType, std::set<int32_t>> ordinalMap;

     // Ordinals must be unique for each type
     for (auto consumer : consumers) {
         EXPECT_TRUE(ordinalMap[consumer.type].insert(consumer.ordinal).second);
     }

     // Min ordinal must be 0, max ordinal must be N - 1
     for (const auto& [unused, ordinals] : ordinalMap) {
         EXPECT_EQ(0, *std::min_element(ordinals.begin(), ordinals.end()));
         EXPECT_EQ(ordinals.size() - 1, *std::max_element(ordinals.begin(), ordinals.end()));
     }
 }

 // Energy consumed must return a valid status
 TEST_P(PowerStatsAidl, TestGetEnergyConsumed) {
     std::vector<EnergyConsumerResult> results;
     ASSERT_OK(powerstats->getEnergyConsumed({}, &results));
 }

 // Energy consumed must return data for all energy consumers
 TEST_P(PowerStatsAidl, TestGetAllEnergyConsumed) {
     std::vector<EnergyConsumer> consumers;
     ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

     std::vector<EnergyConsumerResult> results;
     ASSERT_OK(powerstats->getEnergyConsumed({}, &results));

     testMatching(consumers, &EnergyConsumer::id, results, &EnergyConsumerResult::id);
 }

 // Energy consumed must return data for each selected energy consumer
 TEST_P(PowerStatsAidl, TestGetSelectedEnergyConsumed) {
     std::vector<EnergyConsumer> consumers;
     ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));
     if (consumers.empty()) {
         return;
     }

     std::vector<EnergyConsumer> selectedConsumers = getRandomSubset(consumers);
     std::vector<int32_t> selectedIds;
     for (auto const& consumer : selectedConsumers) {
         selectedIds.push_back(consumer.id);
     }

     std::vector<EnergyConsumerResult> selectedResults;
     ASSERT_OK(powerstats->getEnergyConsumed(selectedIds, &selectedResults));

     testMatching(selectedConsumers, &EnergyConsumer::id, selectedResults,
                  &EnergyConsumerResult::id);
 }

 // Energy consumed attribution uids must be unique for a given energy consumer
 TEST_P(PowerStatsAidl, ValidateEnergyConsumerAttributionUniqueUids) {
     std::vector<EnergyConsumerResult> results;
     ASSERT_OK(powerstats->getEnergyConsumed({}, &results));

     for (auto result : results) {
         testUnique(result.attribution, &EnergyConsumerAttribution::uid);
     }
 }

 // Energy consumed total energy >= sum total of uid-attributed energy
 TEST_P(PowerStatsAidl, TestGetEnergyConsumedAttributedEnergy) {
     std::vector<EnergyConsumerResult> results;
     ASSERT_OK(powerstats->getEnergyConsumed({}, &results));

     for (auto result : results) {
         int64_t totalAttributedEnergyUWs = 0;
         for (auto attribution : result.attribution) {
             totalAttributedEnergyUWs += attribution.energyUWs;
         }
         EXPECT_TRUE(result.energyUWs >= totalAttributedEnergyUWs);
     }
 }

 GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(PowerStatsAidl);
 INSTANTIATE_TEST_SUITE_P(
         PowerStats, PowerStatsAidl,
         testing::ValuesIn(android::getAidlHalInstanceNames(IPowerStats::descriptor)),
         android::PrintInstanceNameToString);

 int main(int argc, char** argv) {
     ::testing::InitGoogleTest(&argc, argv);
     ABinderProcess_setThreadPoolMaxThreadCount(1);
     ABinderProcess_startThreadPool();
     return RUN_ALL_TESTS();
 }
	/*
	* Copyright (C) 2020 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 <aidl/Gtest.h>
	#include <aidl/Vintf.h>

	#include <aidl/android/hardware/power/stats/IPowerStats.h>
	#include <android-base/properties.h>
	#include <android/binder_manager.h>
	#include <android/binder_process.h>

	#include <algorithm>
	#include <iterator>
	#include <random>
	#include <unordered_map>

	using aidl::android::hardware::power::stats::Channel;
	using aidl::android::hardware::power::stats::EnergyConsumer;
	using aidl::android::hardware::power::stats::EnergyConsumerAttribution;
	using aidl::android::hardware::power::stats::EnergyConsumerResult;
	using aidl::android::hardware::power::stats::EnergyConsumerType;
	using aidl::android::hardware::power::stats::EnergyMeasurement;
	using aidl::android::hardware::power::stats::IPowerStats;
	using aidl::android::hardware::power::stats::PowerEntity;
	using aidl::android::hardware::power::stats::State;
	using aidl::android::hardware::power::stats::StateResidency;
	using aidl::android::hardware::power::stats::StateResidencyResult;

	using ndk::SpAIBinder;

	#define ASSERT_OK(a) \
	do { \
	auto ret = a; \
	ASSERT_TRUE(ret.isOk()) << ret.getDescription(); \
	} while (0)

	class PowerStatsAidl : public testing::TestWithParam<std::string> {
	public:
	virtual void SetUp() override {
	powerstats = IPowerStats::fromBinder(
	SpAIBinder(AServiceManager_waitForService(GetParam().c_str())));
	ASSERT_NE(nullptr, powerstats.get());
	}

	template <typename T>
	std::vector<T> getRandomSubset(std::vector<T> const& collection);

	void testNameValid(const std::string& name);

	template <typename T, typename S>
	void testUnique(std::vector<T> const& collection, S T::*field);

	template <typename T, typename S, typename R>
	void testMatching(std::vector<T> const& c1, R T::f1, std::vector<S> const& c2, R S::f2);

	bool isEntitySkipped(const std::string& str);

	void excludeSkippedEntities(std::vector<PowerEntity>* entities,
	std::vector<StateResidencyResult>* results);

	std::shared_ptr<IPowerStats> powerstats;
	};

	// Returns a random subset from a collection
	template <typename T>
	std::vector<T> PowerStatsAidl::getRandomSubset(std::vector<T> const& collection) {
	if (collection.empty()) {
	return {};
	}

	std::vector<T> selected;
	std::sample(collection.begin(), collection.end(), std::back_inserter(selected),
	rand() % collection.size() + 1, std::mt19937{std::random_device{}()});

	return selected;
	}

	// Tests whether a name is valid
	void PowerStatsAidl::testNameValid(const std::string& name) {
	EXPECT_NE(name, "");
	}

	// Tests whether the fields in a given collection are unique
	template <typename T, typename S>
	void PowerStatsAidl::testUnique(std::vector<T> const& collection, S T::*field) {
	std::set<S> cSet;
	for (auto const& elem : collection) {
	EXPECT_TRUE(cSet.insert(elem.*field).second);
	}
	}

	template <typename T, typename S, typename R>
	void PowerStatsAidl::testMatching(std::vector<T> const& c1, R T::*f1, std::vector<S> const& c2,
	R S::*f2) {
	std::set<R> c1fields, c2fields;
	for (auto elem : c1) {
	c1fields.insert(elem.*f1);
	}

	for (auto elem : c2) {
	c2fields.insert(elem.*f2);
	}

	EXPECT_EQ(c1fields, c2fields);
	}

	bool PowerStatsAidl::isEntitySkipped(const std::string& str) {
	bool skip = false;
	// TODO(b/229698505): Extend PowerEntityInfo to identify timed power entity
	skip \|= str.find("AoC") != std::string::npos;
	// Lassen GNSS power stats will be present after running GPS session once.
	// Otherwise, VTS will fail due to missing GPS power stats.
	skip \|= str.find("GPS") != std::string::npos;
	return skip;
	}

	void PowerStatsAidl::excludeSkippedEntities(std::vector<PowerEntity>* entities,
	std::vector<StateResidencyResult>* results) {
	for (auto it = entities->begin(); it != entities->end(); it++) {
	if (isEntitySkipped((*it).name)) {
	auto entityId = (*it).id;
	entities->erase(it--);

	// Erase result element matching the entity ID
	for (auto resultsIt = results->begin(); resultsIt != results->end(); resultsIt++) {
	if ((*resultsIt).id == entityId) {
	results->erase(resultsIt--);
	break;
	}
	}
	}
	}
	}

	// Each PowerEntity must have a valid name
	TEST_P(PowerStatsAidl, ValidatePowerEntityNames) {
	std::vector<PowerEntity> infos;
	ASSERT_OK(powerstats->getPowerEntityInfo(&infos));

	for (auto info : infos) {
	testNameValid(info.name);
	}
	}

	// Each power entity must have a unique name
	TEST_P(PowerStatsAidl, ValidatePowerEntityUniqueNames) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	testUnique(entities, &PowerEntity::name);
	}

	// Each PowerEntity must have a unique ID
	TEST_P(PowerStatsAidl, ValidatePowerEntityIds) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	testUnique(entities, &PowerEntity::id);
	}

	// Each power entity must have at least one state
	TEST_P(PowerStatsAidl, ValidateStateSize) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	for (auto entity : entities) {
	EXPECT_GT(entity.states.size(), 0);
	}
	}

	// Each state must have a valid name
	TEST_P(PowerStatsAidl, ValidateStateNames) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	for (auto entity : entities) {
	for (auto state : entity.states) {
	testNameValid(state.name);
	}
	}
	}

	// Each state must have a name that is unique to the given PowerEntity
	TEST_P(PowerStatsAidl, ValidateStateUniqueNames) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	for (auto entity : entities) {
	testUnique(entity.states, &State::name);
	}
	}

	// Each state must have an ID that is unique to the given PowerEntity
	TEST_P(PowerStatsAidl, ValidateStateUniqueIds) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	for (auto entity : entities) {
	testUnique(entity.states, &State::id);
	}
	}

	// State residency must return a valid status
	TEST_P(PowerStatsAidl, TestGetStateResidency) {
	std::vector<StateResidencyResult> results;
	ASSERT_OK(powerstats->getStateResidency({}, &results));
	}

	// State residency must return all results except timed power entities
	TEST_P(PowerStatsAidl, TestGetStateResidencyAllResultsExceptSkippedEntities) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	std::vector<StateResidencyResult> results;
	ASSERT_OK(powerstats->getStateResidency({}, &results));
	excludeSkippedEntities(&entities, &results);

	testMatching(entities, &PowerEntity::id, results, &StateResidencyResult::id);
	}

	// Each result must contain all state residencies except timed power entities
	TEST_P(PowerStatsAidl, TestGetStateResidencyAllStateResidenciesExceptSkippedEntities) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));

	std::vector<StateResidencyResult> results;
	ASSERT_OK(powerstats->getStateResidency({}, &results));

	for (auto entity : entities) {
	if (!isEntitySkipped(entity.name)) {
	auto it = std::find_if(results.begin(), results.end(),
	[&entity](const auto& x) { return x.id == entity.id; });
	ASSERT_NE(it, results.end());

	testMatching(entity.states, &State::id, it->stateResidencyData, &StateResidency::id);
	}
	}
	}

	// State residency must return results for each requested power entity except timed power entities
	TEST_P(PowerStatsAidl, TestGetStateResidencySelectedResultsExceptTimedEntities) {
	std::vector<PowerEntity> entities;
	ASSERT_OK(powerstats->getPowerEntityInfo(&entities));
	if (entities.empty()) {
	return;
	}

	std::vector<PowerEntity> selectedEntities = getRandomSubset(entities);
	std::vector<int32_t> selectedIds;
	for (auto it = selectedEntities.begin(); it != selectedEntities.end(); it++) {
	if (!isEntitySkipped((*it).name)) {
	selectedIds.push_back((*it).id);
	} else {
	selectedEntities.erase(it--);
	}
	}

	std::vector<StateResidencyResult> selectedResults;
	ASSERT_OK(powerstats->getStateResidency(selectedIds, &selectedResults));

	testMatching(selectedEntities, &PowerEntity::id, selectedResults, &StateResidencyResult::id);
	}

	// Energy meter info must return a valid status
	TEST_P(PowerStatsAidl, TestGetEnergyMeterInfo) {
	std::vector<Channel> info;
	ASSERT_OK(powerstats->getEnergyMeterInfo(&info));
	}

	// Each channel must have a valid name
	TEST_P(PowerStatsAidl, ValidateChannelNames) {
	std::vector<Channel> channels;
	ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

	for (auto channel : channels) {
	testNameValid(channel.name);
	}
	}

	// Each channel must have a valid subsystem
	TEST_P(PowerStatsAidl, ValidateSubsystemNames) {
	std::vector<Channel> channels;
	ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

	for (auto channel : channels) {
	testNameValid(channel.subsystem);
	}
	}

	// Each channel must have a unique name
	TEST_P(PowerStatsAidl, ValidateChannelUniqueNames) {
	std::vector<Channel> channels;
	ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

	testUnique(channels, &Channel::name);
	}

	// Each channel must have a unique ID
	TEST_P(PowerStatsAidl, ValidateChannelUniqueIds) {
	std::vector<Channel> channels;
	ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

	testUnique(channels, &Channel::id);
	}

	// Reading energy meter must return a valid status
	TEST_P(PowerStatsAidl, TestReadEnergyMeter) {
	std::vector<EnergyMeasurement> data;
	ASSERT_OK(powerstats->readEnergyMeter({}, &data));
	}

	// Reading energy meter must return results for all available channels
	TEST_P(PowerStatsAidl, TestGetAllEnergyMeasurements) {
	std::vector<Channel> channels;
	ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));

	std::vector<EnergyMeasurement> measurements;
	ASSERT_OK(powerstats->readEnergyMeter({}, &measurements));

	testMatching(channels, &Channel::id, measurements, &EnergyMeasurement::id);
	}

	// Reading energy must must return results for each selected channel
	TEST_P(PowerStatsAidl, TestGetSelectedEnergyMeasurements) {
	std::vector<Channel> channels;
	ASSERT_OK(powerstats->getEnergyMeterInfo(&channels));
	if (channels.empty()) {
	return;
	}

	std::vector<Channel> selectedChannels = getRandomSubset(channels);
	std::vector<int32_t> selectedIds;
	for (auto const& channel : selectedChannels) {
	selectedIds.push_back(channel.id);
	}

	std::vector<EnergyMeasurement> selectedMeasurements;
	ASSERT_OK(powerstats->readEnergyMeter(selectedIds, &selectedMeasurements));

	testMatching(selectedChannels, &Channel::id, selectedMeasurements, &EnergyMeasurement::id);
	}

	// Energy consumer info must return a valid status
	TEST_P(PowerStatsAidl, TestGetEnergyConsumerInfo) {
	std::vector<EnergyConsumer> consumers;
	ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));
	}

	// Each energy consumer must have a unique id
	TEST_P(PowerStatsAidl, TestGetEnergyConsumerUniqueId) {
	std::vector<EnergyConsumer> consumers;
	ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

	testUnique(consumers, &EnergyConsumer::id);
	}

	// Each energy consumer must have a valid name
	TEST_P(PowerStatsAidl, ValidateEnergyConsumerNames) {
	std::vector<EnergyConsumer> consumers;
	ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

	for (auto consumer : consumers) {
	testNameValid(consumer.name);
	}
	}

	// Each energy consumer must have a unique name
	TEST_P(PowerStatsAidl, ValidateEnergyConsumerUniqueNames) {
	std::vector<EnergyConsumer> consumers;
	ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

	testUnique(consumers, &EnergyConsumer::name);
	}

	// Energy consumers of the same type must have ordinals that are 0,1,2,..., N - 1
	TEST_P(PowerStatsAidl, ValidateEnergyConsumerOrdinals) {
	std::vector<EnergyConsumer> consumers;
	ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

	std::unordered_map<EnergyConsumerType, std::set<int32_t>> ordinalMap;

	// Ordinals must be unique for each type
	for (auto consumer : consumers) {
	EXPECT_TRUE(ordinalMap[consumer.type].insert(consumer.ordinal).second);
	}

	// Min ordinal must be 0, max ordinal must be N - 1
	for (const auto& [unused, ordinals] : ordinalMap) {
	EXPECT_EQ(0, *std::min_element(ordinals.begin(), ordinals.end()));
	EXPECT_EQ(ordinals.size() - 1, *std::max_element(ordinals.begin(), ordinals.end()));
	}
	}

	// Energy consumed must return a valid status
	TEST_P(PowerStatsAidl, TestGetEnergyConsumed) {
	std::vector<EnergyConsumerResult> results;
	ASSERT_OK(powerstats->getEnergyConsumed({}, &results));
	}

	// Energy consumed must return data for all energy consumers
	TEST_P(PowerStatsAidl, TestGetAllEnergyConsumed) {
	std::vector<EnergyConsumer> consumers;
	ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));

	std::vector<EnergyConsumerResult> results;
	ASSERT_OK(powerstats->getEnergyConsumed({}, &results));

	testMatching(consumers, &EnergyConsumer::id, results, &EnergyConsumerResult::id);
	}

	// Energy consumed must return data for each selected energy consumer
	TEST_P(PowerStatsAidl, TestGetSelectedEnergyConsumed) {
	std::vector<EnergyConsumer> consumers;
	ASSERT_OK(powerstats->getEnergyConsumerInfo(&consumers));
	if (consumers.empty()) {
	return;
	}

	std::vector<EnergyConsumer> selectedConsumers = getRandomSubset(consumers);
	std::vector<int32_t> selectedIds;
	for (auto const& consumer : selectedConsumers) {
	selectedIds.push_back(consumer.id);
	}

	std::vector<EnergyConsumerResult> selectedResults;
	ASSERT_OK(powerstats->getEnergyConsumed(selectedIds, &selectedResults));

	testMatching(selectedConsumers, &EnergyConsumer::id, selectedResults,
	&EnergyConsumerResult::id);
	}

	// Energy consumed attribution uids must be unique for a given energy consumer
	TEST_P(PowerStatsAidl, ValidateEnergyConsumerAttributionUniqueUids) {
	std::vector<EnergyConsumerResult> results;
	ASSERT_OK(powerstats->getEnergyConsumed({}, &results));

	for (auto result : results) {
	testUnique(result.attribution, &EnergyConsumerAttribution::uid);
	}
	}

	// Energy consumed total energy >= sum total of uid-attributed energy
	TEST_P(PowerStatsAidl, TestGetEnergyConsumedAttributedEnergy) {
	std::vector<EnergyConsumerResult> results;
	ASSERT_OK(powerstats->getEnergyConsumed({}, &results));

	for (auto result : results) {
	int64_t totalAttributedEnergyUWs = 0;
	for (auto attribution : result.attribution) {
	totalAttributedEnergyUWs += attribution.energyUWs;
	}
	EXPECT_TRUE(result.energyUWs >= totalAttributedEnergyUWs);
	}
	}

	GTEST_ALLOW_UNINSTANTIATED_PARAMETERIZED_TEST(PowerStatsAidl);
	INSTANTIATE_TEST_SUITE_P(
	PowerStats, PowerStatsAidl,
	testing::ValuesIn(android::getAidlHalInstanceNames(IPowerStats::descriptor)),
	android::PrintInstanceNameToString);

	int main(int argc, char** argv) {
	::testing::InitGoogleTest(&argc, argv);
	ABinderProcess_setThreadPoolMaxThreadCount(1);
	ABinderProcess_startThreadPool();
	return RUN_ALL_TESTS();
	}