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// Internal Headers
#include "magnetometersensorsym.h"
#include <sensrvgeneralproperties.h>
/**
* set the id of the magnetometer sensor
*/
char const * const CMagnetometerSensorSym::id("sym.magnetometer");
/**
* Factory function, this is used to create the magnetometer sensor object
* @return CMagnetometerSensorSym if successful, leaves on failure
*/
CMagnetometerSensorSym* CMagnetometerSensorSym::NewL(QSensor *sensor)
{
CMagnetometerSensorSym* self = new (ELeave) CMagnetometerSensorSym(sensor);
CleanupStack::PushL(self);
self->ConstructL();
CleanupStack::Pop();
return self;
}
/**
* Destructor
* Closes the backend resources
*/
CMagnetometerSensorSym::~CMagnetometerSensorSym()
{
//Closes the backend resources
Close();
}
/**
* Default constructor
*/
CMagnetometerSensorSym::CMagnetometerSensorSym(QSensor *sensor):CSensorBackendSym(sensor),
iCalibrationLevel(0.0),
iScaleRange(0)
{
if(sensor)
{
setReading<QMagnetometerReading>(&iReading);
}
iBackendData.iSensorType = KSensrvChannelTypeIdMagnetometerXYZAxisData;
//Enable Property listening, required to get Calibration level
SetListening(ETrue, ETrue);
}
/**
* start is overridden to allow retrieving initial calibration property before
* and to set the required value type flags
*/
void CMagnetometerSensorSym::start()
{
if(sensor())
{
// Initialize the values
iReading.setX(0);
iReading.setY(0);
iReading.setZ(0);
// Set the required type of values
QVariant v = sensor()->property("returnGeoValues");
iReturnGeoValues = (v.isValid() && v.toBool()); // if the property isn't set it's false
}
TInt err;
// get current property value for calibration and set it to reading
TSensrvProperty calibration;
TRAP(err, iBackendData.iSensorChannel->GetPropertyL(KSensrvPropCalibrationLevel, ESensrvSingleProperty, calibration));
// If error in getting the calibration level, continue to start the sensor
// as it is not a fatal error
if ( err == KErrNone )
{
TInt calibrationVal;
calibration.GetValue(calibrationVal);
iCalibrationLevel = calibrationVal * (1.0/3.0);
}
// Call backend start
CSensorBackendSym::start();
TSensrvProperty dataFormatProperty;
TRAP(err, iBackendData.iSensorChannel->GetPropertyL(KSensrvPropIdChannelDataFormat, ESensrvSingleProperty, dataFormatProperty));
if(err == KErrNone)
{
TInt dataFormat;
dataFormatProperty.GetValue(dataFormat);
if(dataFormat == ESensrvChannelDataFormatScaled)
{
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;
}
}
}
}
}
}
}
/*
* RecvData is used to retrieve the sensor reading from sensor server
* It is implemented here to handle magnetometer sensor specific
* reading data and provides conversion and utility code
*/
void CMagnetometerSensorSym::RecvData(CSensrvChannel &aChannel)
{
TPckg<TSensrvMagnetometerAxisData> magnetometerpkg( iData );
TInt ret = aChannel.GetData( magnetometerpkg );
if(KErrNone != ret)
{
// If there is no reading available, return without setting
return;
}
TReal x, y, z;
// If Geo values are requested set it
if(iReturnGeoValues)
{
x = iData.iAxisXCalibrated;
y = iData.iAxisYCalibrated;
z = iData.iAxisZCalibrated;
}
// If Raw values are requested set it
else
{
x = iData.iAxisXRaw;
y = iData.iAxisYRaw;
z = iData.iAxisZRaw;
}
// Scale adjustments
if(iScaleRange)
{
qoutputrangelist rangeList = sensor()->outputRanges();
TReal maxValue = rangeList[sensor()->outputRange()].maximum;
x = (x/iScaleRange) * maxValue;
y = (y/iScaleRange) * maxValue;
z = (z/iScaleRange) * maxValue;
}
// Get a lock on the reading data
iBackendData.iReadingLock.Wait();
iReading.setX(x);
iReading.setY(y);
iReading.setZ(z);
// Set the timestamp
iReading.setTimestamp(iData.iTimeStamp.Int64());
// Set the calibration level
iReading.setCalibrationLevel(iCalibrationLevel);
// Release the lock
iBackendData.iReadingLock.Signal();
}
/**
* HandlePropertyChange is called from backend, to indicate a change in property
*/
void CMagnetometerSensorSym::HandlePropertyChange(CSensrvChannel &/*aChannel*/, const TSensrvProperty &aChangedProperty)
{
if(aChangedProperty.GetPropertyId() != KSensrvPropCalibrationLevel)
{
// Do nothing, if calibration property has not changed
return;
}
TInt calibrationlevel;
aChangedProperty.GetValue(calibrationlevel);
// As Qt requires calibration level in qreal but symbian provides in enum
// It has been agreed with DS Team that the following mechanism will be
// used till discussions with qt mobility are complete
iCalibrationLevel = (1.0/3.0) * calibrationlevel;
}
/*
* Used to retrieve the current calibration level
* iCalibrationLevel is automatically updated whenever there is a change
* in calibration level
*/
qreal CMagnetometerSensorSym::GetCalibrationLevel()
{
return iCalibrationLevel;
}
/**
* Second phase constructor
* Initialize the backend resources
*/
void CMagnetometerSensorSym::ConstructL()
{
InitializeL();
}