services/sensorservice/SensorDeviceUtils.cpp - android_frameworks_native - Gitiles

 /*
  * Copyright (C) 2017 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 "SensorDeviceUtils.h"

 #include <android/hardware/sensors/1.0/ISensors.h>
 #include <android/hardware/sensors/2.1/ISensors.h>
 #include <utils/Log.h>

 #include <chrono>
 #include <thread>

 using ::android::hardware::Void;
 using SensorTypeV2_1 = android::hardware::sensors::V2_1::SensorType;
 using namespace android::hardware::sensors::V1_0;

 namespace android {
 namespace SensorDeviceUtils {

 void quantizeSensorEventValues(sensors_event_t *event, float resolution) {
     if (resolution == 0) {
         return;
     }

     size_t axes = 0;
     switch ((SensorTypeV2_1)event->type) {
         case SensorTypeV2_1::ACCELEROMETER:
         case SensorTypeV2_1::MAGNETIC_FIELD:
         case SensorTypeV2_1::GYROSCOPE:
         case SensorTypeV2_1::MAGNETIC_FIELD_UNCALIBRATED:
         case SensorTypeV2_1::GYROSCOPE_UNCALIBRATED:
         case SensorTypeV2_1::ACCELEROMETER_UNCALIBRATED:
             axes = 3;
             break;
         case SensorTypeV2_1::DEVICE_ORIENTATION:
         case SensorTypeV2_1::LIGHT:
         case SensorTypeV2_1::PRESSURE:
         case SensorTypeV2_1::TEMPERATURE:
         case SensorTypeV2_1::PROXIMITY:
         case SensorTypeV2_1::RELATIVE_HUMIDITY:
         case SensorTypeV2_1::AMBIENT_TEMPERATURE:
         case SensorTypeV2_1::SIGNIFICANT_MOTION:
         case SensorTypeV2_1::STEP_DETECTOR:
         case SensorTypeV2_1::TILT_DETECTOR:
         case SensorTypeV2_1::WAKE_GESTURE:
         case SensorTypeV2_1::GLANCE_GESTURE:
         case SensorTypeV2_1::PICK_UP_GESTURE:
         case SensorTypeV2_1::WRIST_TILT_GESTURE:
         case SensorTypeV2_1::STATIONARY_DETECT:
         case SensorTypeV2_1::MOTION_DETECT:
         case SensorTypeV2_1::HEART_BEAT:
         case SensorTypeV2_1::LOW_LATENCY_OFFBODY_DETECT:
         case SensorTypeV2_1::HINGE_ANGLE:
             axes = 1;
             break;
         default:
             // No other sensors have data that needs to be quantized.
             break;
     }

     // sensor_event_t is a union so we're able to perform the same quanitization action for most
     // sensors by only knowing the number of axes their output data has.
     for (size_t i = 0; i < axes; i++) {
         quantizeValue(&event->data[i], resolution);
     }
 }

 float resolutionForSensor(const sensor_t &sensor) {
     switch ((SensorTypeV2_1)sensor.type) {
         case SensorTypeV2_1::ACCELEROMETER:
         case SensorTypeV2_1::MAGNETIC_FIELD:
         case SensorTypeV2_1::GYROSCOPE:
         case SensorTypeV2_1::MAGNETIC_FIELD_UNCALIBRATED:
         case SensorTypeV2_1::GYROSCOPE_UNCALIBRATED:
         case SensorTypeV2_1::ACCELEROMETER_UNCALIBRATED: {
             if (sensor.maxRange == 0) {
                 ALOGE("No max range for sensor type %d, can't determine appropriate resolution",
                         sensor.type);
                 return sensor.resolution;
             }
             // Accel, gyro, and mag shouldn't have more than 24 bits of resolution on the most
             // advanced devices.
             double lowerBound = 2.0 * sensor.maxRange / std::pow(2, 24);

             // No need to check the upper bound as that's already enforced through CTS.
             return std::max(sensor.resolution, static_cast<float>(lowerBound));
         }
         case SensorTypeV2_1::SIGNIFICANT_MOTION:
         case SensorTypeV2_1::STEP_DETECTOR:
         case SensorTypeV2_1::STEP_COUNTER:
         case SensorTypeV2_1::TILT_DETECTOR:
         case SensorTypeV2_1::WAKE_GESTURE:
         case SensorTypeV2_1::GLANCE_GESTURE:
         case SensorTypeV2_1::PICK_UP_GESTURE:
         case SensorTypeV2_1::WRIST_TILT_GESTURE:
         case SensorTypeV2_1::STATIONARY_DETECT:
         case SensorTypeV2_1::MOTION_DETECT:
             // Ignore input resolution as all of these sensors are required to have a resolution of
             // 1.
             return 1.0f;
         default:
             // fall through and return the current resolution for all other types
             break;
     }
     return sensor.resolution;
 }

 HidlServiceRegistrationWaiter::HidlServiceRegistrationWaiter() {
 }

 void HidlServiceRegistrationWaiter::onFirstRef() {
     // Creating sp<...>(this) in the constructor should be avoided, hence
     // registerForNotifications is called in onFirstRef callback.
     mRegistered = ISensors::registerForNotifications("default", this);
 }

 Return<void> HidlServiceRegistrationWaiter::onRegistration(
         const hidl_string &fqName, const hidl_string &name, bool preexisting) {
     ALOGV("onRegistration fqName %s, name %s, preexisting %d",
           fqName.c_str(), name.c_str(), preexisting);

     {
         std::lock_guard<std::mutex> lk(mLock);
         mRestartObserved = true;
     }
     mCondition.notify_all();
     return Void();
 }

 void HidlServiceRegistrationWaiter::reset() {
     std::lock_guard<std::mutex> lk(mLock);
     mRestartObserved = false;
 }

 bool HidlServiceRegistrationWaiter::wait() {
     constexpr int DEFAULT_WAIT_MS = 100;
     constexpr int TIMEOUT_MS = 1000;

     if (!mRegistered) {
         ALOGW("Cannot register service notification, use default wait(%d ms)", DEFAULT_WAIT_MS);
         std::this_thread::sleep_for(std::chrono::milliseconds(DEFAULT_WAIT_MS));
         // not sure if service is actually restarted
         return false;
     }

     std::unique_lock<std::mutex> lk(mLock);
     return mCondition.wait_for(lk, std::chrono::milliseconds(TIMEOUT_MS),
             [this]{return mRestartObserved;});
 }

 } // namespace SensorDeviceUtils
 } // namespace android
	/*
	* Copyright (C) 2017 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 "SensorDeviceUtils.h"

	#include <android/hardware/sensors/1.0/ISensors.h>
	#include <android/hardware/sensors/2.1/ISensors.h>
	#include <utils/Log.h>

	#include <chrono>
	#include <thread>

	using ::android::hardware::Void;
	using SensorTypeV2_1 = android::hardware::sensors::V2_1::SensorType;
	using namespace android::hardware::sensors::V1_0;

	namespace android {
	namespace SensorDeviceUtils {

	void quantizeSensorEventValues(sensors_event_t *event, float resolution) {
	if (resolution == 0) {
	return;
	}

	size_t axes = 0;
	switch ((SensorTypeV2_1)event->type) {
	case SensorTypeV2_1::ACCELEROMETER:
	case SensorTypeV2_1::MAGNETIC_FIELD:
	case SensorTypeV2_1::GYROSCOPE:
	case SensorTypeV2_1::MAGNETIC_FIELD_UNCALIBRATED:
	case SensorTypeV2_1::GYROSCOPE_UNCALIBRATED:
	case SensorTypeV2_1::ACCELEROMETER_UNCALIBRATED:
	axes = 3;
	break;
	case SensorTypeV2_1::DEVICE_ORIENTATION:
	case SensorTypeV2_1::LIGHT:
	case SensorTypeV2_1::PRESSURE:
	case SensorTypeV2_1::TEMPERATURE:
	case SensorTypeV2_1::PROXIMITY:
	case SensorTypeV2_1::RELATIVE_HUMIDITY:
	case SensorTypeV2_1::AMBIENT_TEMPERATURE:
	case SensorTypeV2_1::SIGNIFICANT_MOTION:
	case SensorTypeV2_1::STEP_DETECTOR:
	case SensorTypeV2_1::TILT_DETECTOR:
	case SensorTypeV2_1::WAKE_GESTURE:
	case SensorTypeV2_1::GLANCE_GESTURE:
	case SensorTypeV2_1::PICK_UP_GESTURE:
	case SensorTypeV2_1::WRIST_TILT_GESTURE:
	case SensorTypeV2_1::STATIONARY_DETECT:
	case SensorTypeV2_1::MOTION_DETECT:
	case SensorTypeV2_1::HEART_BEAT:
	case SensorTypeV2_1::LOW_LATENCY_OFFBODY_DETECT:
	case SensorTypeV2_1::HINGE_ANGLE:
	axes = 1;
	break;
	default:
	// No other sensors have data that needs to be quantized.
	break;
	}

	// sensor_event_t is a union so we're able to perform the same quanitization action for most
	// sensors by only knowing the number of axes their output data has.
	for (size_t i = 0; i < axes; i++) {
	quantizeValue(&event->data[i], resolution);
	}
	}

	float resolutionForSensor(const sensor_t &sensor) {
	switch ((SensorTypeV2_1)sensor.type) {
	case SensorTypeV2_1::ACCELEROMETER:
	case SensorTypeV2_1::MAGNETIC_FIELD:
	case SensorTypeV2_1::GYROSCOPE:
	case SensorTypeV2_1::MAGNETIC_FIELD_UNCALIBRATED:
	case SensorTypeV2_1::GYROSCOPE_UNCALIBRATED:
	case SensorTypeV2_1::ACCELEROMETER_UNCALIBRATED: {
	if (sensor.maxRange == 0) {
	ALOGE("No max range for sensor type %d, can't determine appropriate resolution",
	sensor.type);
	return sensor.resolution;
	}
	// Accel, gyro, and mag shouldn't have more than 24 bits of resolution on the most
	// advanced devices.
	double lowerBound = 2.0 * sensor.maxRange / std::pow(2, 24);

	// No need to check the upper bound as that's already enforced through CTS.
	return std::max(sensor.resolution, static_cast<float>(lowerBound));
	}
	case SensorTypeV2_1::SIGNIFICANT_MOTION:
	case SensorTypeV2_1::STEP_DETECTOR:
	case SensorTypeV2_1::STEP_COUNTER:
	case SensorTypeV2_1::TILT_DETECTOR:
	case SensorTypeV2_1::WAKE_GESTURE:
	case SensorTypeV2_1::GLANCE_GESTURE:
	case SensorTypeV2_1::PICK_UP_GESTURE:
	case SensorTypeV2_1::WRIST_TILT_GESTURE:
	case SensorTypeV2_1::STATIONARY_DETECT:
	case SensorTypeV2_1::MOTION_DETECT:
	// Ignore input resolution as all of these sensors are required to have a resolution of
	// 1.
	return 1.0f;
	default:
	// fall through and return the current resolution for all other types
	break;
	}
	return sensor.resolution;
	}

	HidlServiceRegistrationWaiter::HidlServiceRegistrationWaiter() {
	}

	void HidlServiceRegistrationWaiter::onFirstRef() {
	// Creating sp<...>(this) in the constructor should be avoided, hence
	// registerForNotifications is called in onFirstRef callback.
	mRegistered = ISensors::registerForNotifications("default", this);
	}

	Return<void> HidlServiceRegistrationWaiter::onRegistration(
	const hidl_string &fqName, const hidl_string &name, bool preexisting) {
	ALOGV("onRegistration fqName %s, name %s, preexisting %d",
	fqName.c_str(), name.c_str(), preexisting);

	{
	std::lock_guard<std::mutex> lk(mLock);
	mRestartObserved = true;
	}
	mCondition.notify_all();
	return Void();
	}

	void HidlServiceRegistrationWaiter::reset() {
	std::lock_guard<std::mutex> lk(mLock);
	mRestartObserved = false;
	}

	bool HidlServiceRegistrationWaiter::wait() {
	constexpr int DEFAULT_WAIT_MS = 100;
	constexpr int TIMEOUT_MS = 1000;

	if (!mRegistered) {
	ALOGW("Cannot register service notification, use default wait(%d ms)", DEFAULT_WAIT_MS);
	std::this_thread::sleep_for(std::chrono::milliseconds(DEFAULT_WAIT_MS));
	// not sure if service is actually restarted
	return false;
	}

	std::unique_lock<std::mutex> lk(mLock);
	return mCondition.wait_for(lk, std::chrono::milliseconds(TIMEOUT_MS),
	[this]{return mRestartObserved;});
	}

	} // namespace SensorDeviceUtils
	} // namespace android