/* * Copyright (C) 2011 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_NDEBUG 0 #define LOG_TAG "Sensors" //#define FUNC_LOG ALOGV("%s", __PRETTY_FUNCTION__) #define FUNC_LOG #include <hardware/sensors.h> #include <fcntl.h> #include <errno.h> #include <dirent.h> #include <math.h> #include <poll.h> #include <pthread.h> #include <stdlib.h> #include <linux/input.h> #include <utils/Atomic.h> #include <utils/Log.h> #include "sensors.h" #include "MPLSensor.h" #include "LightSensor.h" #include "ProximitySensor.h" #include "PressureSensor.h" /*****************************************************************************/ #define DELAY_OUT_TIME 0x7FFFFFFF #define LIGHT_SENSOR_POLLTIME 2000000000 #define SENSORS_ROTATION_VECTOR (1<<ID_RV) #define SENSORS_LINEAR_ACCEL (1<<ID_LA) #define SENSORS_GRAVITY (1<<ID_GR) #define SENSORS_GYROSCOPE (1<<ID_GY) #define SENSORS_ACCELERATION (1<<ID_A) #define SENSORS_MAGNETIC_FIELD (1<<ID_M) #define SENSORS_ORIENTATION (1<<ID_O) #define SENSORS_LIGHT (1<<ID_L) #define SENSORS_PROXIMITY (1<<ID_P) #define SENSORS_PRESSURE (1<<ID_PR) #define SENSORS_ROTATION_VECTOR_HANDLE (ID_RV) #define SENSORS_LINEAR_ACCEL_HANDLE (ID_LA) #define SENSORS_GRAVITY_HANDLE (ID_GR) #define SENSORS_GYROSCOPE_HANDLE (ID_GY) #define SENSORS_ACCELERATION_HANDLE (ID_A) #define SENSORS_MAGNETIC_FIELD_HANDLE (ID_M) #define SENSORS_ORIENTATION_HANDLE (ID_O) #define SENSORS_LIGHT_HANDLE (ID_L) #define SENSORS_PROXIMITY_HANDLE (ID_P) #define SENSORS_PRESSURE_HANDLE (ID_PR) #define AKM_FTRACE 0 #define AKM_DEBUG 0 #define AKM_DATA 0 /*****************************************************************************/ /* The SENSORS Module */ #define LOCAL_SENSORS (3) static struct sensor_t sSensorList[LOCAL_SENSORS + MPLSensor::numSensors] = { { "GP2A Light sensor", "Sharp", 1, SENSORS_LIGHT_HANDLE, SENSOR_TYPE_LIGHT, powf(10, 125.0f/ 24.0f) * 4, 1.0f, 0.75f, 0, { } }, { "GP2A Proximity sensor", "Sharp", 1, SENSORS_PROXIMITY_HANDLE, SENSOR_TYPE_PROXIMITY, 5.0f, 5.0f, 0.75f, 0, { } }, { "BMP180 Pressure sensor", "Bosch", 1, SENSORS_PRESSURE_HANDLE, SENSOR_TYPE_PRESSURE, 1100.0f, 0.01f, 0.67f, 20000, { } }, }; static int numSensors = LOCAL_SENSORS; static int open_sensors(const struct hw_module_t* module, const char* id, struct hw_device_t** device); static int sensors__get_sensors_list(struct sensors_module_t* module, struct sensor_t const** list) { *list = sSensorList; return numSensors; } static struct hw_module_methods_t sensors_module_methods = { open: open_sensors }; struct sensors_module_t HAL_MODULE_INFO_SYM = { common: { tag: HARDWARE_MODULE_TAG, version_major: 1, version_minor: 0, id: SENSORS_HARDWARE_MODULE_ID, name: "Samsung Sensor module", author: "Samsung Electronic Company", methods: &sensors_module_methods, dso: 0, reserved: {}, }, get_sensors_list: sensors__get_sensors_list, }; struct sensors_poll_context_t { struct sensors_poll_device_t device; // must be first sensors_poll_context_t(); ~sensors_poll_context_t(); int activate(int handle, int enabled); int setDelay(int handle, int64_t ns); int pollEvents(sensors_event_t* data, int count); private: enum { mpl = 0, //all mpl entries must be consecutive and in this order mpl_accel, mpl_timer, light, proximity, pressure, numSensorDrivers, // wake pipe goes here mpl_power, //special handle for MPL pm interaction numFds, }; static const size_t wake = numFds - 2; static const char WAKE_MESSAGE = 'W'; struct pollfd mPollFds[numFds]; int mWritePipeFd; SensorBase* mSensors[numSensorDrivers]; int handleToDriver(int handle) const { switch (handle) { case ID_RV: case ID_LA: case ID_GR: case ID_GY: case ID_A: case ID_M: case ID_O: return mpl; case ID_L: return light; case ID_P: return proximity; case ID_PR: return pressure; } return -EINVAL; } }; /*****************************************************************************/ sensors_poll_context_t::sensors_poll_context_t() { FUNC_LOG; MPLSensor* p_mplsen = new MPLSensor(); setCallbackObject(p_mplsen); //setup the callback object for handing mpl callbacks numSensors = LOCAL_SENSORS + p_mplsen->populateSensorList(sSensorList + LOCAL_SENSORS, sizeof(sSensorList[0]) * (ARRAY_SIZE(sSensorList) - LOCAL_SENSORS)); mSensors[mpl] = p_mplsen; mPollFds[mpl].fd = mSensors[mpl]->getFd(); mPollFds[mpl].events = POLLIN; mPollFds[mpl].revents = 0; mSensors[mpl_accel] = mSensors[mpl]; mPollFds[mpl_accel].fd = ((MPLSensor*)mSensors[mpl])->getAccelFd(); mPollFds[mpl_accel].events = POLLIN; mPollFds[mpl_accel].revents = 0; mSensors[mpl_timer] = mSensors[mpl]; mPollFds[mpl_timer].fd = ((MPLSensor*)mSensors[mpl])->getTimerFd(); mPollFds[mpl_timer].events = POLLIN; mPollFds[mpl_timer].revents = 0; mSensors[light] = new LightSensor(); mPollFds[light].fd = mSensors[light]->getFd(); mPollFds[light].events = POLLIN; mPollFds[light].revents = 0; mSensors[proximity] = new ProximitySensor(); mPollFds[proximity].fd = mSensors[proximity]->getFd(); mPollFds[proximity].events = POLLIN; mPollFds[proximity].revents = 0; mSensors[pressure] = new PressureSensor(); mPollFds[pressure].fd = mSensors[pressure]->getFd(); mPollFds[pressure].events = POLLIN; mPollFds[pressure].revents = 0; int wakeFds[2]; int result = pipe(wakeFds); ALOGE_IF(result<0, "error creating wake pipe (%s)", strerror(errno)); 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; //setup MPL pm interaction handle mPollFds[mpl_power].fd = ((MPLSensor*)mSensors[mpl])->getPowerFd(); mPollFds[mpl_power].events = POLLIN; mPollFds[mpl_power].revents = 0; } sensors_poll_context_t::~sensors_poll_context_t() { FUNC_LOG; for (int i=0 ; i<numSensorDrivers ; i++) { delete mSensors[i]; } close(mPollFds[wake].fd); close(mWritePipeFd); } int sensors_poll_context_t::activate(int handle, int enabled) { FUNC_LOG; int index = handleToDriver(handle); if (index < 0) return index; int err = mSensors[index]->enable(handle, enabled); if (!err) { const char wakeMessage(WAKE_MESSAGE); int result = write(mWritePipeFd, &wakeMessage, 1); ALOGE_IF(result<0, "error sending wake message (%s)", strerror(errno)); } return err; } int sensors_poll_context_t::setDelay(int handle, int64_t ns) { FUNC_LOG; int index = handleToDriver(handle); if (index < 0) return index; return mSensors[index]->setDelay(handle, ns); } int sensors_poll_context_t::pollEvents(sensors_event_t* data, int count) { //FUNC_LOG; int nbEvents = 0; int n = 0; int polltime = -1; do { // see if we have some leftover from the last poll() for (int i=0 ; count && i<numSensorDrivers ; i++) { SensorBase* const sensor(mSensors[i]); if ((mPollFds[i].revents & POLLIN) || (sensor->hasPendingEvents())) { int nb = sensor->readEvents(data, count); if (nb < count) { // no more data for this sensor mPollFds[i].revents = 0; } count -= nb; nbEvents += nb; data += nb; //special handling for the mpl, which has multiple handles if(i==mpl) { i+=2; //skip accel and timer mPollFds[mpl_accel].revents = 0; mPollFds[mpl_timer].revents = 0; } if(i==mpl_accel) { i+=1; //skip timer mPollFds[mpl_timer].revents = 0; } } } if (count) { // we still have some room, so try to see if we can get // some events immediately or just wait if we don't have // anything to return int i; do { n = poll(mPollFds, numFds, nbEvents ? 0 : polltime); } while (n < 0 && errno == EINTR); if (n<0) { ALOGE("poll() failed (%s)", strerror(errno)); return -errno; } if (mPollFds[wake].revents & POLLIN) { char msg; int result = read(mPollFds[wake].fd, &msg, 1); ALOGE_IF(result<0, "error reading from wake pipe (%s)", strerror(errno)); ALOGE_IF(msg != WAKE_MESSAGE, "unknown message on wake queue (0x%02x)", int(msg)); mPollFds[wake].revents = 0; } if(mPollFds[mpl_power].revents & POLLIN) { ((MPLSensor*)mSensors[mpl])->handlePowerEvent(); mPollFds[mpl_power].revents = 0; } } // if we have events and space, go read them } while (n && count); return nbEvents; } /*****************************************************************************/ static int poll__close(struct hw_device_t *dev) { FUNC_LOG; sensors_poll_context_t *ctx = (sensors_poll_context_t *)dev; if (ctx) { delete ctx; } return 0; } static int poll__activate(struct sensors_poll_device_t *dev, int handle, int enabled) { FUNC_LOG; sensors_poll_context_t *ctx = (sensors_poll_context_t *)dev; return ctx->activate(handle, enabled); } static int poll__setDelay(struct sensors_poll_device_t *dev, int handle, int64_t ns) { FUNC_LOG; sensors_poll_context_t *ctx = (sensors_poll_context_t *)dev; return ctx->setDelay(handle, ns); } static int poll__poll(struct sensors_poll_device_t *dev, sensors_event_t* data, int count) { FUNC_LOG; sensors_poll_context_t *ctx = (sensors_poll_context_t *)dev; return ctx->pollEvents(data, count); } /*****************************************************************************/ /** Open a new instance of a sensor device using name */ static int open_sensors(const struct hw_module_t* module, const char* id, struct hw_device_t** device) { FUNC_LOG; int status = -EINVAL; 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; }