hardware_samsung/exynos4/exynos4210/libsensors/AkmSensor.cpp

/*
 * Copyright (C) 2008 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 <fcntl.h>
#include <errno.h>
#include <math.h>
#include <poll.h>
#include <unistd.h>
#include <dirent.h>
#include <sys/select.h>
#include <dlfcn.h>

#include "ak8973b.h"

#include <cutils/log.h>
#include "AkmSensor.h"

//#define LOG_NDEBUG 0

/*****************************************************************************/

int (*akm_is_sensor_enabled)(uint32_t sensor_type);
int (*akm_enable_sensor)(uint32_t sensor_type);
int (*akm_disable_sensor)(uint32_t sensor_type);
int (*akm_set_delay)(uint32_t sensor_type, uint64_t delay);

int stub_is_sensor_enabled(uint32_t sensor_type) {
    return 0;
}

int stub_enable_disable_sensor(uint32_t sensor_type) {
    return -ENODEV;
}

int stub_set_delay(uint32_t sensor_type, uint64_t delay) {
    return -ENODEV;
}

AkmSensor::AkmSensor()
: SensorBase(NULL, NULL),
      mEnabled(0),
      mPendingMask(0),
      mInputReader(32)
{
    /* Open the library before opening the input device.  The library
     * creates a uinput device.
     */
    if (loadAKMLibrary() == 0) {
        data_name = "compass_sensor";
        data_fd = openInput("compass_sensor");
    }

    memset(mPendingEvents, 0, sizeof(mPendingEvents));

    mPendingEvents[Accelerometer].version = sizeof(sensors_event_t);
    mPendingEvents[Accelerometer].sensor = ID_A;
    mPendingEvents[Accelerometer].type = SENSOR_TYPE_ACCELEROMETER;
    mPendingEvents[Accelerometer].acceleration.status = SENSOR_STATUS_ACCURACY_HIGH;

    mPendingEvents[MagneticField].version = sizeof(sensors_event_t);
    mPendingEvents[MagneticField].sensor = ID_M;
    mPendingEvents[MagneticField].type = SENSOR_TYPE_MAGNETIC_FIELD;
    mPendingEvents[MagneticField].magnetic.status = SENSOR_STATUS_ACCURACY_HIGH;

    mPendingEvents[Orientation  ].version = sizeof(sensors_event_t);
    mPendingEvents[Orientation  ].sensor = ID_O;
    mPendingEvents[Orientation  ].type = SENSOR_TYPE_ORIENTATION;
    mPendingEvents[Orientation  ].orientation.status = SENSOR_STATUS_ACCURACY_HIGH;

    // read the actual value of all sensors if they're enabled already
    struct input_absinfo absinfo;
    short flags = 0;

    if (akm_is_sensor_enabled(SENSOR_TYPE_ACCELEROMETER))  {
        mEnabled |= 1<<Accelerometer;
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ACCEL_X), &absinfo)) {
            mPendingEvents[Accelerometer].acceleration.x = absinfo.value * CONVERT_A_X;
        }
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ACCEL_Y), &absinfo)) {
            mPendingEvents[Accelerometer].acceleration.y = absinfo.value * CONVERT_A_Y;
        }
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ACCEL_Z), &absinfo)) {
            mPendingEvents[Accelerometer].acceleration.z = absinfo.value * CONVERT_A_Z;
        }
    }
    if (akm_is_sensor_enabled(SENSOR_TYPE_MAGNETIC_FIELD))  {
        mEnabled |= 1<<MagneticField;
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_MAGV_X), &absinfo)) {
            mPendingEvents[MagneticField].magnetic.x = absinfo.value * CONVERT_M_X;
        }
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_MAGV_Y), &absinfo)) {
            mPendingEvents[MagneticField].magnetic.y = absinfo.value * CONVERT_M_Y;
        }
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_MAGV_Z), &absinfo)) {
            mPendingEvents[MagneticField].magnetic.z = absinfo.value * CONVERT_M_Z;
        }
    }
    if (akm_is_sensor_enabled(SENSOR_TYPE_ORIENTATION))  {
        mEnabled |= 1<<Orientation;
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_YAW), &absinfo)) {
            mPendingEvents[Orientation].orientation.azimuth = absinfo.value;
        }
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_PITCH), &absinfo)) {
            mPendingEvents[Orientation].orientation.pitch = absinfo.value;
        }
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ROLL), &absinfo)) {
            mPendingEvents[Orientation].orientation.roll = -absinfo.value;
        }
        if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ORIENT_STATUS), &absinfo)) {
            mPendingEvents[Orientation].orientation.status = uint8_t(absinfo.value & SENSOR_STATE_MASK);
        }
    }

    // disable temperature sensor, since it is not supported
    akm_disable_sensor(SENSOR_TYPE_TEMPERATURE);
}

AkmSensor::~AkmSensor()
{
    if (mLibAKM) {
        unsigned ref = ::dlclose(mLibAKM);
    }
}

int AkmSensor::enable(int32_t handle, int en)
{
    int what = -1;

    switch (handle) {
        case ID_A: what = Accelerometer; break;
        case ID_M: what = MagneticField; break;
        case ID_O: what = Orientation;   break;
    }

    if (uint32_t(what) >= numSensors)
        return -EINVAL;

    int newState  = en ? 1 : 0;
    int err = 0;

    if ((uint32_t(newState)<<what) != (mEnabled & (1<<what))) {
        uint32_t sensor_type;
        switch (what) {
            case Accelerometer: sensor_type = SENSOR_TYPE_ACCELEROMETER;  break;
            case MagneticField: sensor_type = SENSOR_TYPE_MAGNETIC_FIELD; break;
            case Orientation:   sensor_type = SENSOR_TYPE_ORIENTATION;  break;
        }
        short flags = newState;
        if (en)
            err = akm_enable_sensor(sensor_type);
        else
            err = akm_disable_sensor(sensor_type);

        LOGE_IF(err, "Could not change sensor state (%s)", strerror(-err));
        if (!err) {
            mEnabled &= ~(1<<what);
            mEnabled |= (uint32_t(flags)<<what);
        }
    }
    return err;
}

int AkmSensor::setDelay(int32_t handle, int64_t ns)
{
    int what = -1;
    uint32_t sensor_type = 0;

    if (ns < 0)
        return -EINVAL;

    switch (handle) {
        case ID_A: sensor_type = SENSOR_TYPE_ACCELEROMETER; break;
        case ID_M: sensor_type = SENSOR_TYPE_MAGNETIC_FIELD; break;
        case ID_O: sensor_type = SENSOR_TYPE_ORIENTATION; break;
    }

    if (sensor_type == 0)
        return -EINVAL;

    mDelays[what] = ns;
    return update_delay();
}

int AkmSensor::update_delay()
{
    if (mEnabled) {
        uint64_t wanted = -1LLU;
        for (int i=0 ; i<numSensors ; i++) {
            if (mEnabled & (1<<i)) {
                uint64_t ns = mDelays[i];
                wanted = wanted < ns ? wanted : ns;
            }
        }
        short delay = int64_t(wanted) / 1000000;
        if (ioctl(dev_fd, ECS_IOCTL_APP_SET_DELAY, &delay)) {
            return -errno;
        }
    }
    return 0;
}


int AkmSensor::loadAKMLibrary()
{
    mLibAKM = dlopen("libakm.so", RTLD_NOW);

    if (!mLibAKM) {
        akm_is_sensor_enabled = stub_is_sensor_enabled;
        akm_enable_sensor = stub_enable_disable_sensor;
        akm_disable_sensor = stub_enable_disable_sensor;
        akm_set_delay = stub_set_delay;
        LOGE("AkmSensor: unable to load AKM Library, %s", dlerror());
        return -ENOENT;
    }

    *(void **)&akm_is_sensor_enabled = dlsym(mLibAKM, "akm_is_sensor_enabled");
    *(void **)&akm_enable_sensor = dlsym(mLibAKM, "akm_enable_sensor");
    *(void **)&akm_disable_sensor = dlsym(mLibAKM, "akm_disable_sensor");
    *(void **)&akm_set_delay = dlsym(mLibAKM, "akm_set_delay");

    return 0;
}

int AkmSensor::readEvents(sensors_event_t* data, int count)
{
    if (count < 1)
        return -EINVAL;

    ssize_t n = mInputReader.fill(data_fd);
    if (n < 0)
        return n;

    int numEventReceived = 0;
    input_event const* event;

    while (count && mInputReader.readEvent(&event)) {
        int type = event->type;
        if (type == EV_REL) {
            processEvent(event->code, event->value);
            mInputReader.next();
        } else if (type == EV_SYN) {
            int64_t time = timevalToNano(event->time);
            for (int j=0 ; count && mPendingMask && j<numSensors ; j++) {
                if (mPendingMask & (1<<j)) {
                    mPendingMask &= ~(1<<j);
                    mPendingEvents[j].timestamp = time;
                    if (mEnabled & (1<<j)) {
                        *data++ = mPendingEvents[j];
                        count--;
                        numEventReceived++;
                    }
                }
            }
            if (!mPendingMask) {
                mInputReader.next();
            }
        } else {
            LOGE("AkmSensor: unknown event (type=%d, code=%d)",
                    type, event->code);
            mInputReader.next();
        }
    }
    return numEventReceived;
}

void AkmSensor::processEvent(int code, int value)
{
    switch (code) {
        case EVENT_TYPE_ACCEL_X:
            mPendingMask |= 1<<Accelerometer;
            mPendingEvents[Accelerometer].acceleration.x = value * CONVERT_A_X;
            break;
        case EVENT_TYPE_ACCEL_Y:
            mPendingMask |= 1<<Accelerometer;
            mPendingEvents[Accelerometer].acceleration.y = value * CONVERT_A_Y;
            break;
        case EVENT_TYPE_ACCEL_Z:
            mPendingMask |= 1<<Accelerometer;
            mPendingEvents[Accelerometer].acceleration.z = value * CONVERT_A_Z;
            break;

        case EVENT_TYPE_MAGV_X:
            LOGV("AkmSensor: EVENT_TYPE_MAGV_X value =%d", value);
            mPendingMask |= 1<<MagneticField;
            mPendingEvents[MagneticField].magnetic.x = value * CONVERT_M_X;
            break;
        case EVENT_TYPE_MAGV_Y:
            LOGV("AkmSensor: EVENT_TYPE_MAGV_Y value =%d", value);
            mPendingMask |= 1<<MagneticField;
            mPendingEvents[MagneticField].magnetic.y = value * CONVERT_M_Y;
            break;
        case EVENT_TYPE_MAGV_Z:
            LOGV("AkmSensor: EVENT_TYPE_MAGV_Z value =%d", value);
            mPendingMask |= 1<<MagneticField;
            mPendingEvents[MagneticField].magnetic.z = value * CONVERT_M_Z;
            break;

        case EVENT_TYPE_YAW:
            mPendingMask |= 1<<Orientation;
            mPendingEvents[Orientation].orientation.azimuth = value * CONVERT_O_A;
            break;
        case EVENT_TYPE_PITCH:
            mPendingMask |= 1<<Orientation;
            mPendingEvents[Orientation].orientation.pitch = value * CONVERT_O_P;
            break;
        case EVENT_TYPE_ROLL:
            mPendingMask |= 1<<Orientation;
            mPendingEvents[Orientation].orientation.roll = value * CONVERT_O_R;
            break;
        case EVENT_TYPE_ORIENT_STATUS:
            uint8_t status = uint8_t(value & SENSOR_STATE_MASK);
            if (status == 4)
                status = 0;
            mPendingMask |= 1<<Orientation;
            mPendingEvents[Orientation].orientation.status = status;
            break;
    }
}
initial commit, taken and modified from linaro/insignal 13 years ago			`/*`
			`* Copyright (C) 2008 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 <fcntl.h>`
			`#include <errno.h>`
			`#include <math.h>`
			`#include <poll.h>`
			`#include <unistd.h>`
			`#include <dirent.h>`
			`#include <sys/select.h>`
			`#include <dlfcn.h>`

			`#include "ak8973b.h"`

			`#include <cutils/log.h>`
			`#include "AkmSensor.h"`

			`//#define LOG_NDEBUG 0`

			`/*****************************************************************************/`

			`int (*akm_is_sensor_enabled)(uint32_t sensor_type);`
			`int (*akm_enable_sensor)(uint32_t sensor_type);`
			`int (*akm_disable_sensor)(uint32_t sensor_type);`
			`int (*akm_set_delay)(uint32_t sensor_type, uint64_t delay);`

			`int stub_is_sensor_enabled(uint32_t sensor_type) {`
			`return 0;`
			`}`

			`int stub_enable_disable_sensor(uint32_t sensor_type) {`
			`return -ENODEV;`
			`}`

			`int stub_set_delay(uint32_t sensor_type, uint64_t delay) {`
			`return -ENODEV;`
			`}`

			`AkmSensor::AkmSensor()`
			`: SensorBase(NULL, NULL),`
			`mEnabled(0),`
			`mPendingMask(0),`
			`mInputReader(32)`
			`{`
			`/* Open the library before opening the input device. The library`
			`* creates a uinput device.`
			`*/`
			`if (loadAKMLibrary() == 0) {`
			`data_name = "compass_sensor";`
			`data_fd = openInput("compass_sensor");`
			`}`

			`memset(mPendingEvents, 0, sizeof(mPendingEvents));`

			`mPendingEvents[Accelerometer].version = sizeof(sensors_event_t);`
			`mPendingEvents[Accelerometer].sensor = ID_A;`
			`mPendingEvents[Accelerometer].type = SENSOR_TYPE_ACCELEROMETER;`
			`mPendingEvents[Accelerometer].acceleration.status = SENSOR_STATUS_ACCURACY_HIGH;`

			`mPendingEvents[MagneticField].version = sizeof(sensors_event_t);`
			`mPendingEvents[MagneticField].sensor = ID_M;`
			`mPendingEvents[MagneticField].type = SENSOR_TYPE_MAGNETIC_FIELD;`
			`mPendingEvents[MagneticField].magnetic.status = SENSOR_STATUS_ACCURACY_HIGH;`

			`mPendingEvents[Orientation ].version = sizeof(sensors_event_t);`
			`mPendingEvents[Orientation ].sensor = ID_O;`
			`mPendingEvents[Orientation ].type = SENSOR_TYPE_ORIENTATION;`
			`mPendingEvents[Orientation ].orientation.status = SENSOR_STATUS_ACCURACY_HIGH;`

			`// read the actual value of all sensors if they're enabled already`
			`struct input_absinfo absinfo;`
			`short flags = 0;`

			`if (akm_is_sensor_enabled(SENSOR_TYPE_ACCELEROMETER)) {`
			`mEnabled \|= 1<<Accelerometer;`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ACCEL_X), &absinfo)) {`
			`mPendingEvents[Accelerometer].acceleration.x = absinfo.value * CONVERT_A_X;`
			`}`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ACCEL_Y), &absinfo)) {`
			`mPendingEvents[Accelerometer].acceleration.y = absinfo.value * CONVERT_A_Y;`
			`}`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ACCEL_Z), &absinfo)) {`
			`mPendingEvents[Accelerometer].acceleration.z = absinfo.value * CONVERT_A_Z;`
			`}`
			`}`
			`if (akm_is_sensor_enabled(SENSOR_TYPE_MAGNETIC_FIELD)) {`
			`mEnabled \|= 1<<MagneticField;`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_MAGV_X), &absinfo)) {`
			`mPendingEvents[MagneticField].magnetic.x = absinfo.value * CONVERT_M_X;`
			`}`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_MAGV_Y), &absinfo)) {`
			`mPendingEvents[MagneticField].magnetic.y = absinfo.value * CONVERT_M_Y;`
			`}`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_MAGV_Z), &absinfo)) {`
			`mPendingEvents[MagneticField].magnetic.z = absinfo.value * CONVERT_M_Z;`
			`}`
			`}`
			`if (akm_is_sensor_enabled(SENSOR_TYPE_ORIENTATION)) {`
			`mEnabled \|= 1<<Orientation;`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_YAW), &absinfo)) {`
			`mPendingEvents[Orientation].orientation.azimuth = absinfo.value;`
			`}`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_PITCH), &absinfo)) {`
			`mPendingEvents[Orientation].orientation.pitch = absinfo.value;`
			`}`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ROLL), &absinfo)) {`
			`mPendingEvents[Orientation].orientation.roll = -absinfo.value;`
			`}`
			`if (!ioctl(data_fd, EVIOCGABS(EVENT_TYPE_ORIENT_STATUS), &absinfo)) {`
			`mPendingEvents[Orientation].orientation.status = uint8_t(absinfo.value & SENSOR_STATE_MASK);`
			`}`
			`}`

			`// disable temperature sensor, since it is not supported`
			`akm_disable_sensor(SENSOR_TYPE_TEMPERATURE);`
			`}`

			`AkmSensor::~AkmSensor()`
			`{`
			`if (mLibAKM) {`
			`unsigned ref = ::dlclose(mLibAKM);`
			`}`
			`}`

			`int AkmSensor::enable(int32_t handle, int en)`
			`{`
			`int what = -1;`

			`switch (handle) {`
			`case ID_A: what = Accelerometer; break;`
			`case ID_M: what = MagneticField; break;`
			`case ID_O: what = Orientation; break;`
			`}`

			`if (uint32_t(what) >= numSensors)`
			`return -EINVAL;`

			`int newState = en ? 1 : 0;`
			`int err = 0;`

			`if ((uint32_t(newState)<<what) != (mEnabled & (1<<what))) {`
			`uint32_t sensor_type;`
			`switch (what) {`
			`case Accelerometer: sensor_type = SENSOR_TYPE_ACCELEROMETER; break;`
			`case MagneticField: sensor_type = SENSOR_TYPE_MAGNETIC_FIELD; break;`
			`case Orientation: sensor_type = SENSOR_TYPE_ORIENTATION; break;`
			`}`
			`short flags = newState;`
			`if (en)`
			`err = akm_enable_sensor(sensor_type);`
			`else`
			`err = akm_disable_sensor(sensor_type);`

			`LOGE_IF(err, "Could not change sensor state (%s)", strerror(-err));`
			`if (!err) {`
			`mEnabled &= ~(1<<what);`
			`mEnabled \|= (uint32_t(flags)<<what);`
			`}`
			`}`
			`return err;`
			`}`

			`int AkmSensor::setDelay(int32_t handle, int64_t ns)`
			`{`
Update AkmSensor to manually set poll interval Change-Id: I84fc5c3fc1cb552874129512ea6dfc19b1f9a60a 13 years ago			`int what = -1;`
initial commit, taken and modified from linaro/insignal 13 years ago			`uint32_t sensor_type = 0;`

			`if (ns < 0)`
			`return -EINVAL;`

			`switch (handle) {`
			`case ID_A: sensor_type = SENSOR_TYPE_ACCELEROMETER; break;`
			`case ID_M: sensor_type = SENSOR_TYPE_MAGNETIC_FIELD; break;`
			`case ID_O: sensor_type = SENSOR_TYPE_ORIENTATION; break;`
			`}`

			`if (sensor_type == 0)`
			`return -EINVAL;`

Update AkmSensor to manually set poll interval Change-Id: I84fc5c3fc1cb552874129512ea6dfc19b1f9a60a 13 years ago			`mDelays[what] = ns;`
			`return update_delay();`
initial commit, taken and modified from linaro/insignal 13 years ago			`}`

Update AkmSensor to manually set poll interval Change-Id: I84fc5c3fc1cb552874129512ea6dfc19b1f9a60a 13 years ago			`int AkmSensor::update_delay()`
			`{`
			`if (mEnabled) {`
			`uint64_t wanted = -1LLU;`
			`for (int i=0 ; i<numSensors ; i++) {`
			`if (mEnabled & (1<<i)) {`
			`uint64_t ns = mDelays[i];`
			`wanted = wanted < ns ? wanted : ns;`
			`}`
			`}`
			`short delay = int64_t(wanted) / 1000000;`
			`if (ioctl(dev_fd, ECS_IOCTL_APP_SET_DELAY, &delay)) {`
			`return -errno;`
			`}`
			`}`
			`return 0;`
			`}`


initial commit, taken and modified from linaro/insignal 13 years ago			`int AkmSensor::loadAKMLibrary()`
			`{`
			`mLibAKM = dlopen("libakm.so", RTLD_NOW);`

			`if (!mLibAKM) {`
			`akm_is_sensor_enabled = stub_is_sensor_enabled;`
			`akm_enable_sensor = stub_enable_disable_sensor;`
			`akm_disable_sensor = stub_enable_disable_sensor;`
			`akm_set_delay = stub_set_delay;`
			`LOGE("AkmSensor: unable to load AKM Library, %s", dlerror());`
			`return -ENOENT;`
			`}`

			`(void *)&akm_is_sensor_enabled = dlsym(mLibAKM, "akm_is_sensor_enabled");`
			`(void *)&akm_enable_sensor = dlsym(mLibAKM, "akm_enable_sensor");`
			`(void *)&akm_disable_sensor = dlsym(mLibAKM, "akm_disable_sensor");`
			`(void *)&akm_set_delay = dlsym(mLibAKM, "akm_set_delay");`

			`return 0;`
			`}`

			`int AkmSensor::readEvents(sensors_event_t* data, int count)`
			`{`
			`if (count < 1)`
			`return -EINVAL;`

			`ssize_t n = mInputReader.fill(data_fd);`
			`if (n < 0)`
			`return n;`

			`int numEventReceived = 0;`
			`input_event const* event;`

			`while (count && mInputReader.readEvent(&event)) {`
			`int type = event->type;`
			`if (type == EV_REL) {`
			`processEvent(event->code, event->value);`
			`mInputReader.next();`
			`} else if (type == EV_SYN) {`
			`int64_t time = timevalToNano(event->time);`
			`for (int j=0 ; count && mPendingMask && j<numSensors ; j++) {`
			`if (mPendingMask & (1<<j)) {`
			`mPendingMask &= ~(1<<j);`
			`mPendingEvents[j].timestamp = time;`
			`if (mEnabled & (1<<j)) {`
			`*data++ = mPendingEvents[j];`
			`count--;`
			`numEventReceived++;`
			`}`
			`}`
			`}`
			`if (!mPendingMask) {`
			`mInputReader.next();`
			`}`
			`} else {`
			`LOGE("AkmSensor: unknown event (type=%d, code=%d)",`
			`type, event->code);`
			`mInputReader.next();`
			`}`
			`}`
			`return numEventReceived;`
			`}`

			`void AkmSensor::processEvent(int code, int value)`
			`{`
			`switch (code) {`
			`case EVENT_TYPE_ACCEL_X:`
			`mPendingMask \|= 1<<Accelerometer;`
			`mPendingEvents[Accelerometer].acceleration.x = value * CONVERT_A_X;`
			`break;`
			`case EVENT_TYPE_ACCEL_Y:`
			`mPendingMask \|= 1<<Accelerometer;`
			`mPendingEvents[Accelerometer].acceleration.y = value * CONVERT_A_Y;`
			`break;`
			`case EVENT_TYPE_ACCEL_Z:`
			`mPendingMask \|= 1<<Accelerometer;`
			`mPendingEvents[Accelerometer].acceleration.z = value * CONVERT_A_Z;`
			`break;`

			`case EVENT_TYPE_MAGV_X:`
			`LOGV("AkmSensor: EVENT_TYPE_MAGV_X value =%d", value);`
			`mPendingMask \|= 1<<MagneticField;`
			`mPendingEvents[MagneticField].magnetic.x = value * CONVERT_M_X;`
			`break;`
			`case EVENT_TYPE_MAGV_Y:`
			`LOGV("AkmSensor: EVENT_TYPE_MAGV_Y value =%d", value);`
			`mPendingMask \|= 1<<MagneticField;`
			`mPendingEvents[MagneticField].magnetic.y = value * CONVERT_M_Y;`
			`break;`
			`case EVENT_TYPE_MAGV_Z:`
			`LOGV("AkmSensor: EVENT_TYPE_MAGV_Z value =%d", value);`
			`mPendingMask \|= 1<<MagneticField;`
			`mPendingEvents[MagneticField].magnetic.z = value * CONVERT_M_Z;`
			`break;`

			`case EVENT_TYPE_YAW:`
			`mPendingMask \|= 1<<Orientation;`
			`mPendingEvents[Orientation].orientation.azimuth = value * CONVERT_O_A;`
			`break;`
			`case EVENT_TYPE_PITCH:`
			`mPendingMask \|= 1<<Orientation;`
			`mPendingEvents[Orientation].orientation.pitch = value * CONVERT_O_P;`
			`break;`
			`case EVENT_TYPE_ROLL:`
			`mPendingMask \|= 1<<Orientation;`
			`mPendingEvents[Orientation].orientation.roll = value * CONVERT_O_R;`
			`break;`
			`case EVENT_TYPE_ORIENT_STATUS:`
			`uint8_t status = uint8_t(value & SENSOR_STATE_MASK);`
			`if (status == 4)`
			`status = 0;`
			`mPendingMask \|= 1<<Orientation;`
			`mPendingEvents[Orientation].orientation.status = status;`
			`break;`
			`}`
			`}`