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// Internal Headers
#include "accelerometersym.h"
#include <sensrvgeneralproperties.h>

#define GRAVITATION_CONSTANT 9.812865328        //According to wikipedia link http://en.wikipedia.org/wiki/Standard_gravity

/**
 * set the id of the accelerometer sensor
 */
char const * const CAccelerometerSensorSym::id("sym.accelerometer");

/**
 * Factory function, this is used to create the accelerometer object
 * @return CAccelerometerSensorSym if successful, leaves on failure
 */
CAccelerometerSensorSym* CAccelerometerSensorSym::NewL(QSensor *sensor)
    {
    CAccelerometerSensorSym* self = new (ELeave) CAccelerometerSensorSym(sensor);
    CleanupStack::PushL(self);
    self->ConstructL();
    CleanupStack::Pop();
    return self;
    }

/**
 * Destructor
 * Closes the backend resources
 */
CAccelerometerSensorSym::~CAccelerometerSensorSym()
    {
    // Release the backend resources
    Close();
    }

/**
 * Default constructor
 */
CAccelerometerSensorSym::CAccelerometerSensorSym(QSensor *sensor):CSensorBackendSym(sensor),
        iScaleRange(0),
        iUnit(0)
        {
        setReading<QAccelerometerReading>(&iReading);
        iBackendData.iSensorType = KSensrvChannelTypeIdAccelerometerXYZAxisData;
        //Disable property listening
        SetListening(ETrue, EFalse);
        }

void CAccelerometerSensorSym::start()
{
    TSensrvProperty dataFormatProperty;
    TInt err;
    CSensorBackendSym::start();
    TRAP(err, iBackendData.iSensorChannel->GetPropertyL(KSensrvPropIdChannelDataFormat, ESensrvSingleProperty, dataFormatProperty));
    if(err == KErrNone)
        {
        TSensrvProperty scaleRangeProperty;
        TRAP(err, iBackendData.iSensorChannel->GetPropertyL(KSensrvPropIdScaledRange, KSensrvItemIndexNone, scaleRangeProperty));
        if(err == KErrNone)
            {
            if(scaleRangeProperty.GetArrayIndex() == ESensrvSingleProperty)
                {
                if(scaleRangeProperty.PropertyType() == ESensrvIntProperty)
                    {
                    scaleRangeProperty.GetMaxValue(iScaleRange);
                    }
                else if(scaleRangeProperty.PropertyType() == ESensrvRealProperty)
                    {
                    TReal realScale;
                    scaleRangeProperty.GetMaxValue(realScale);
                    iScaleRange = realScale;
                    }
                }
            else if(scaleRangeProperty.GetArrayIndex() == ESensrvArrayPropertyInfo)
                {
                TInt index;
                if(scaleRangeProperty.PropertyType() == ESensrvIntProperty)
                    {
                    scaleRangeProperty.GetValue(index);
                    }
                else if(scaleRangeProperty.PropertyType() == ESensrvRealProperty)
                    {
                    TReal realIndex;
                    scaleRangeProperty.GetValue(realIndex);
                    index = realIndex;
                    }
                TRAP(err, iBackendData.iSensorChannel->GetPropertyL(KSensrvPropIdScaledRange, KSensrvItemIndexNone, index, scaleRangeProperty));
                if(err == KErrNone)
                    {
                    if(scaleRangeProperty.PropertyType() == ESensrvIntProperty)
                        {
                        scaleRangeProperty.GetMaxValue(iScaleRange);
                        }
                    else if(scaleRangeProperty.PropertyType() == ESensrvRealProperty)
                        {
                        TReal realScaleRange;
                        scaleRangeProperty.GetMaxValue(realScaleRange);
                        iScaleRange = realScaleRange;
                        }
                    }
                }
            }
        }
}

/*
 * DataReceived is used to retrieve the sensor reading from sensor server
 * It is implemented here to handle accelerometer sensor specific
 * reading data and provides conversion and utility code
 */
void CAccelerometerSensorSym::DataReceived(CSensrvChannel &aChannel, TInt aCount, TInt /*aDataLost*/)
    {
    ProcessData(aChannel, aCount, iData);
    }

void CAccelerometerSensorSym::ProcessReading()
    {
    TReal x = iData.iAxisX;
    TReal y = iData.iAxisY;
    TReal z = iData.iAxisZ;
    //Converting unit to m/s^2
    if(iScaleRange && iUnit == ESensevChannelUnitAcceleration)
        {
        qoutputrangelist rangeList = sensor()->outputRanges();
        int outputRange = sensor()->outputRange();
        if (outputRange == -1)
            outputRange = 0;
        TReal maxValue = rangeList[outputRange].maximum;
        x = (x/iScaleRange) * maxValue;
        y = (y/iScaleRange) * maxValue;
        z = (z/iScaleRange) * maxValue;
        }
    else if(iUnit == ESensrvChannelUnitGravityConstant)
        {
        //conversion is yet to done
        }
    // Get a lock on the reading data
    iBackendData.iReadingLock.Wait();
    // Set qt mobility accelerometer reading with data from sensor server
    iReading.setX(x);
    iReading.setY(y);
    iReading.setZ(z);
    // Set the timestamp
    iReading.setTimestamp(iData.iTimeStamp.Int64());
    // Release the lock
    iBackendData.iReadingLock.Signal();
    // Notify that a reading is available
    newReadingAvailable();
    }

/**
 * Second phase constructor
 * Initialize the backend resources
 */
void CAccelerometerSensorSym::ConstructL()
    {
    //Initialize the backend resources
    InitializeL();

    TInt err;
    TSensrvProperty unitProperty;
    TRAP(err, iBackendData.iSensorChannel->GetPropertyL(KSensrvPropIdChannelUnit, ESensrvSingleProperty, unitProperty));
    if(err == KErrNone)
        {
        unitProperty.GetValue(iUnit);
        }
    }