在这个系列的文章我们只是为了讲清楚Sensor框架的设计和工作原理基于4.0,4.0以下的代码有所区别,尤其是2.2以下根本就没有Binder架构,不讲驱动,也不讲具体的某一个应用该怎么处理Sensor的数据。 从这个图来看Sensor的架构还是非常的清淅, 黄色部分表示硬件,它要挂在I2C总线上 红色部分表示驱动,把驱动注册到Kernel的Input Subsystem上,然后通过Event Device把Sensor数据传到HAL层,准确说是HAL从Event读 绿色部分表示动态库,它封装了整个Sensor的IPC机制,如SensorManager是客户端,SensorService是服务端,而HAL部分是封装了服务端对Kernel的直接访问 蓝色部分就是我们的Framework和Application了,JNI负责访问Sensor的客户端,而Application就是具体的应用程序,用来接收Sensor返回的数据,并处理实现对应的UI效果,如屏幕旋转,打电话时灭屏,自动调接背光(这三个功能的具体实现会在以后分析) 相关代码: 从HAL到Framework: Framework部分: frameworks/base/core/Java/Android/hardware/SensorManager.Java
frameworks/base/core/jni/android_hardware_sensorManager.cpp
下面的代码会生成到:libgui.so
frameworks/base/libs/gui/SensorManager.cpp
frameworks/base/libs/gui/SensorEventQueue.cpp
frameworks/base/libs/gui/SensorChannel.cpp
frameworks/base/libs/gui/Sensor.cpp 下面的代码会生成:libsensorservice.so
frameworks/base/services/sensorservice/SensorService.cpp
frameworks/base/services/sensorservice/SensorDevice.cpp
HAL部分:这部分代码最终会生成 sensor.default.so 到/system/lib/hw/ hardware/libhardware/include/hardware/Sensors.h device/qcom/msm7627a/libsensors/Sensors.cpp device/qcom/msm7627a/libsensors/SensorBase.h
device/qcom/msm7627a/libsensors/AccSensor.cpp
device/qcom/msm7627a/libsensors/ProximitySensor.cpp
device/qcom/msm7627a/libsensors/LightSensor.cpp
device/qcom/msm7627a/libsensors/TmdSensor.cpp
device/qcom/msm7627a/libsensors/MagnetoSensor.cpp
device/qcom/msm7627a/libsensors/GyroSensor.cpp device/qcom/msm7627a/libsensors/InputEventRead.h device/qcom/msm7627a/libsensors/InputEventRead.cpp
Drivers: P-Sensor: device/qcom/msm7627a/libsensors/Tmd2771.h kernel/drivers/misc/Tmd2771.c (从这个代码路径大家可以看出我用来分析的代码是高通7627a平台的, 和Google原生代码没什么差别,而MTK的代码差别就大了,从HAL层开始完全不一样。) AccelerometerSensor MagneticSensor
OrientationSensor ProximitySensor
LightSensor Gyro 这是我们最常见手机上有的Sensor,不过一般低端手机是没有Gyro的,而A Sensor用的并不是三轴的而是两轴。
二、应用举例: [java] view plain copy
- SensorManager sensorManager = (SensorManager)getSystemService(Context.SENSOR_SERVICE);
- Sensor accSensor = sensorManager.getDefaultSensor(Sensor.TYPE_ACCELEROMETER);
- sensorManager.registerListener(this, accSensor, SensorManager.SENSOR_DELAY_NORMAL);
- sensorManager.unregisterListener(this, accSensor);
- //然后在当前Activity中实现以下的两个函数
- public void onSensorChanged(SensorEvent event)
- public void onAccuracyChanged(Sensor sensor, int accuracy)
三、SensorService 服务程序启动,它是由SystemManager启动起来的: frameworks/base/cmds/system_server/library/system_init.cpp [cpp] view plain copy
- property_get("system_init.startsensorservice", propBuf, "1");
- if (strcmp(propBuf, "1") == 0) {
- // Start the sensor service
- SensorService::instantiate();
- }
整个C/S通信的架构图:![]()
需要特别说明的是,BpSensorServer并没有在系统中被用到,如果你从ISensorServer.cpp中把它删除也不会对Sensor的工作有任何影响。它的工作被SensorManager.cpp所取代,ServiceManager直接获取上面System_init文件中添加的SensorService对像。 四、创建SensorManager 1. new SensorManager 它有两个地方去创建这个Sensor client Object,一个就是ContextImpl,另一个就是PowerManagerService中,contextImpl大家都明白是为了应用程序很方便的获取Service,PowerManager中为什么要创建这个对象我们后面再分析。 2.natvieClassInit 它在SensorManager(JAVA)的构造函数中被调用,作用就是创建一个Sensor.java类的实例对象。 3.sensors_module_init() 它也是在SensorManager(JAVA)的构造函数中被调用的,它的作用就是初始华SensorManager(cpp)。 [cpp] view plain copy
- static jint
- sensors_module_init(JNIEnv *env, jclass clazz)
- {
- SensorManager::getInstance();
- return 0;
- }
通过getInstance()就可以知道它是一个单件类,实例的创建由其父类Singleton<SensorManager>,SensorManager只需要在实现文件调用以下的代码: ANDROID_SINGLETON_STATIC_INSTANCE(SensorManager)
接着是SensorManager(cpp)的构造函数也没有做什么就是通过ServiceManager获取了SensorService的实例对象。 4. onFirstRef的实例 其实SensorService在添加实例到ServiceManager的时候就已经实例化过后了,因为在Binder.c中就会保存对它的引用,而RefBase的意思就是用来管理对像的引用,所以它会在对象第一次被引用的时候就调用onFirstRef。 接下来我们看看SensorService: nFirstRef里面做了哪些工作。 5. 创建SensorDevice SensorDevice的构造函数: [cpp] view plain copy
- status_t err = hw_get_module(SENSORS_HARDWARE_MODULE_ID,
- (hw_module_t const**)&mSensorModule);
这句话的意思是JNI加载HAL的库文件,并创建SensorModle的对象,Sensor的库文件通常是sensor.default.so上图接下来是sensors_open,这个函数并没有在SensorDevice中实现,而是调用的HAL层的函数,相关代码路径已在上面列出。 [cpp] view plain copy
- static int open_sensors(const struct hw_module_t* module, const char* id,
- struct hw_device_t** device)
- {
- int status = -EINVAL;
- LOGE("%s %d => %s", __FILE__, __LINE__, __func__);
- sensors_poll_context_t *dev = new sensors_poll_context_t();
-
- memset(&dev->device, 0, sizeof(sensors_poll_device_t));
-
- dev->device.common.tag = HARDWARE_DEVICE_TAG;
- dev->device.common.version = 0;
- dev->device.common.module = const_cast<hw_module_t*>(module);
- dev->device.common.close = poll__close;
- dev->device.activate = poll__activate;
- dev->device.setDelay = poll__setDelay;
- dev->device.poll = poll__poll;
-
- *device = &dev->device.common;
- status = 0;
-
- return status;
- }
我们看new sensors_poll_device_t();[cpp] view plain copy
- sensors_poll_context_t::sensors_poll_context_t()
- {
- #ifdef TMD27713_SENSOR
- mSensors[tmd] = new TmdSensor();
- mPollFds[tmd].fd = mSensors[tmd]->getFd();
- mPollFds[tmd].events = POLLIN;
- mPollFds[tmd].revents = 0;
- #else
- mSensors[light] = new LightSensor();
- mPollFds[light].fd = mSensors[light]->getFd();
- mPollFds[light].events = POLLIN;
- #endif
- mSensors[acc] = new AccSensor();
- mPollFds[acc].fd = mSensors[acc]->getFd();
- mPollFds[acc].events = POLLIN;
- mPollFds[acc].revents = 0;
-
- mSensors[mag] = new MagnetoSensor((AccSensor*)mSensors[acc]);
- mPollFds[mag].fd = mSensors[mag]->getFd();
- mPollFds[mag].events = POLLIN;
- mPollFds[mag].revents = 0;
-
- int wakeFds[2];
- int result = pipe(wakeFds);
- fcntl(wakeFds[0], F_SETFL, O_NONBLOCK);
- fcntl(wakeFds[1], F_SETFL, O_NONBLOCK);
- mWritePipeFd = wakeFds[1];
-
- mPollFds[wake].fd = wakeFds[0];
- mPollFds[wake].events = POLLIN;
- mPollFds[wake].revents = 0;
- }
这部分代码就创建HAL和Kernel Event通信的类,还有Sensor数据读写管道的创建。
返回open_sensors再看剩下的代码,就是创建sensors_poll_device_t对象并把sensor控制的相关函数指针赋值给它。6. SensorDevice 调用get_sensors_list 这个方法还是调用到了HAL中,而HAL中的这个函数也就是返回以下数组: [cpp] view plain copy
- /* The SENSORS Module */
- static const struct sensor_t sSensorList[] = {
- { "ST 3-axis Accelerometer",
- "STMicroelectronics",
- 1, SENSORS_ACCELERATION_HANDLE,
- SENSOR_TYPE_ACCELEROMETER, RANGE_A, CONVERT_A, 0.23f, 20000, { } },
- { "ST 3-axis Magnetic field sensor",
- "STMicroelectronics",
- 1, SENSORS_MAGNETIC_FIELD_HANDLE,
- SENSOR_TYPE_MAGNETIC_FIELD, 2000.0f, CONVERT_M, 6.8f, 16667, { } },
- { "iNemo Orientation sensor",
- "STMicroelectronics",
- 1, SENSORS_ORIENTATION_HANDLE,
- SENSOR_TYPE_ORIENTATION, 360.0f, CONVERT_O, 7.8f, 16667, { } },
- };
我们需要特别关组的是第4,5个参数,第4参数Handle是对kernel而言的,如激活,读写event,代码中的说明: /* handle that identifies this sensors. This handle is used to activate
* and deactivate this sensor. The value of the handle must be 8 bits
* in this version of the API.
*/
而第五个参数是相对于上层代码而言。
7. mSensorDevice->activate 在获取到Sensor列表以后,我们就去激活每一个Sensor: mSensorDevice->activate(mSensorDevice, list.handle, 0);
[cpp] view plain copy
- int sensors_poll_context_t::activate(int handle, int enabled) {
- int index = handleToDriver(handle);
- if (index < 0) return index;
- LOGE("sensor.cpp:index = %d\t handle= %d\t en=%d",index,handle,enabled);//by zhangfeng
- int err = mSensors[index]->enable(handle, enabled);
- if (enabled && !err) {
- const char wakeMessage(WAKE_MESSAGE);
- int result = write(mWritePipeFd, &wakeMessage, 1);
- LOGE_IF(result<0, "error sending wake message (%s)", strerror(errno));
- }
- return err;
- }
这儿要介绍一下handleToDriver[cpp] view plain copy
- int handleToDriver(int handle) const {
- switch (handle) {
- case ID_A:
- return acc;
- case ID_M:
- case ID_O:
- return mag;
- #ifdef TMD27713_SENSOR
- case ID_P:
- case ID_L:
- return tmd;
- #else
- case ID_P:
- return proximity;
- case ID_L:
- return light;
- #endif
- case ID_GY:
- return gyro;
- }
- return -EINVAL;
- }
传进来的就是我们上面说的第4个参数Handle,返回的是对应的和kernel交互的类的数组下标(Sensors[acc])下标。从上面的sensors_poll_context_t()中sensors[]的定义我们可以找到Sensors[acc]对应的值为AccSensor。 mSensors[index]->enable(handle,enabled)目的就是打开这个Sensor,里面如何打开的?Linux上面不是一切兼为文件吗?就是打开对应的驱动文件嘛,所以里面的东西我们就不看了,HAL我们只分析到Sensors.cpp。 8. 扩展Sensor list 好SensorDevice里面的初始化代码走完了,回到SensorService。 [cpp] view plain copy
- void SensorService:nFirstRef()
- {
- LOGD("nuSensorService starting...");
-
- SensorDevice& dev(SensorDevice::getInstance());
- ....
- if (hasGyro) {
- // Always instantiate Android's virtual sensors. Since they are
- // instantiated behind sensors from the HAL, they won't
- // interfere with applications, unless they looks specifically
- // for them (by name).
-
- registerVirtualSensor( new RotationVectorSensor() );
- registerVirtualSensor( new GravitySensor(list, count) );
- registerVirtualSensor( new LinearAccelerationSensor(list, count) );
-
- // these are optional
- registerVirtualSensor( new OrientationSensor() );
- registerVirtualSensor( new CorrectedGyroSensor(list, count) );
-
- // virtual debugging sensors...
- char value[PROPERTY_VALUE_MAX];
- property_get("debug.sensors", value, "0");
- if (atoi(value)) {
- registerVirtualSensor( new GyroDriftSensor() );
- }
- }
省去了很多的代码,从上面的代码可以看出如果有Gyro在Sensor List中,那么它就会注册RotationVector,Gravity,LinearAcceleration,Orientation,CorrectedGyro这些虚拟Sensor。这些Sensor又是如何与Kernel通信的呢,我们在第七节会来分析。 最后这个run方法不得不介绍,其实SensorService是继承了Thread,而线程函数就是threadLoop,这个threadLoop在干什么呢?我们也放到第七节来讲吧! 好SensorService的初始化工作也看完了。 9、返回到SensorManager(Java) 首先它也会获取Sensor列表。 然后创建SensorEventPool和SensorThread,但这儿还没有用到,在第六节会用到。 五、获取Sensor [cpp] view plain copy
- public Sensor getDefaultSensor(int type) {
- // TODO: need to be smarter, for now, just return the 1st sensor
- List<Sensor> l = getSensorList(type);
- return l.isEmpty() ? null : l.get(0);
- }
这个很简单就不用解释了。六、注册SensorLisenter 1. new ListenerDelegate(SensorEventListener listener, Sensor sensor, Handler handler) 这儿要特别说明一下,在这个构造函数中会创建一个Handler,它会在获取到Sensor数据的时候被调用。 [cpp] view plain copy
- mHandler = new Handler(looper) {
- @Override
- public void handleMessage(Message msg) {
- final SensorEvent t = (SensorEvent)msg.obj;
- final int handle = t.sensor.getHandle();
-
- switch (t.sensor.getType()) {
- // Only report accuracy for sensors that support it.
- case Sensor.TYPE_MAGNETIC_FIELD:
- case Sensor.TYPE_ORIENTATION:
- // call onAccuracyChanged() only if the value changes
- final int accuracy = mSensorAccuracies.get(handle);
- if ((t.accuracy >= 0) && (accuracy != t.accuracy)) {
- mSensorAccuracies.put(handle, t.accuracy);
- mSensorEventListener.onAccuracyChanged(t.sensor, t.accuracy);
- }
- break;
- default:
- // For other sensors, just report the accuracy once
- if (mFirstEvent.get(handle) == false) {
- mFirstEvent.put(handle, true);
- mSensorEventListener.onAccuracyChanged(
- t.sensor, SENSOR_STATUS_ACCURACY_HIGH);
- }
- break;
- }
-
- mSensorEventListener.onSensorChanged(t);
- sPool.returnToPool(t);
- }
- };
2. sensors_create_queue要注意一下SensorEventConnection的构造 [cpp] view plain copy
- SensorService::SensorEventConnection::SensorEventConnection(
- const sp<SensorService>& service)
- : mService(service), mChannel(new SensorChannel())
- {
- }
SensorChannel构造://这部分还没有搞懂,这个管道的具体功能,接着往下分析希望能搞明白[cpp] view plain copy
- SensorChannel::SensorChannel()
- : mSendFd(-1), mReceiveFd(-1)
- {
- int fds[2];
- if (pipe(fds) == 0) {
- mReceiveFd = fds[0];
- mSendFd = fds[1];
- fcntl(mReceiveFd, F_SETFL, O_NONBLOCK);
- fcntl(mSendFd, F_SETFL, O_NONBLOCK);
- }
- }
3. sensors_data_poll
七、Sensor的数据处理流程
八、校准 初始化校准 它都是把校准数据写在一些文件里的,qcom 7627a的路径是: /persist/GsensorCalibrationData /persist/MsensorCalibrationData
/persist/PSensorCalibrateData 然后在Hal中对应的Sensor的构造函数中去读数据,如P-sensor对应的TmdSensor [cpp] view plain copy
- ioctl(dev_fd, TAOS_IOCTL_ALS_CALIBRATE, 0);
- if((fp = fopen(PSENSOR_CALIBRATED_DATA_FILE, "r+"))!= NULL)
- {
- fscanf(fp,"%d %d\n",&TaosProxCalibateData[0],&TaosProxCalibateData[1]);
- fclose( fp );
- if((TaosProxCalibateData[0] > 0) && (TaosProxCalibateData[1] < 1023) && (TaosProxCalibateData[0] < TaosProxCalibateData[1]))
- ioctl(dev_fd,TAOS_IOCTL_SET_PROX_CALIBRATE_DATA,&TaosProxCalibateData);
- else
- ioctl(dev_fd, TAOS_IOCTL_PROX_CALIBRATE, 0);
- }
- else
- {
- ioctl(dev_fd, TAOS_IOCTL_PROX_CALIBRATE, 0);
- }
发ioctl到Tmd驱动程序中去,其实这个功能比较的简单,从TaosProxcalibateData的定义可以看出就是传一个大值和一个小值。
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