示例#1
0
bool AMInMemoryDataStore::setValue(const AMnDIndex &scanIndex, int measurementId, const AMnDIndex &measurementIndex, const AMNumber &newValue) {

	if(scanIndex.rank() != axes_.count())
		return false; // scan axis index doesn't provide enough / too many dimensions

	if((unsigned)measurementId >= (unsigned)measurements_.count())
		return false;	// invalid measurement specified;

	if(measurementIndex.rank() != measurements_.at(measurementId).rank())
		return false;

	int flatMeasurementIndex = flatIndexForMeasurement(measurementId, measurementIndex);

	if(axes_.count() == 0) {
#ifdef AM_ENABLE_BOUNDS_CHECKING
		if(flatMeasurementIndex >= scalarScanPoint_.at(measurementId).size())
			return false;
#endif
		scalarScanPoint_[measurementId][flatMeasurementIndex] = newValue;
	}
	else { // higher dimensions:
		int flatScanIndex = scanIndex.flatIndexInArrayOfSize(scanSize_);
#ifdef AM_ENABLE_BOUNDS_CHECKING
		if(flatScanIndex >= scanPoints_.count())
			return false;
		if(flatMeasurementIndex >= scanPoints_.at(flatScanIndex).at(measurementId).size())
			return false;
#endif
		scanPoints_[flatScanIndex][measurementId][flatMeasurementIndex] = newValue;
	}

	emitDataChanged(scanIndex, scanIndex, measurementId);
	return true;
}
示例#2
0
AMNumber AMInMemoryDataStore::value(const AMnDIndex &scanIndex, int measurementId, const AMnDIndex &measurementIndex) const {

	// scan axis index doesn't provide enough / too many dimensions
	if(scanIndex.rank() != axes_.count())
		return AMNumber(AMNumber::DimensionError);

	if((unsigned)measurementId >= (unsigned)measurements_.count())
		return AMNumber(AMNumber::InvalidError);	// invalid measurement specified;

	if(measurementIndex.rank() != measurements_.at(measurementId).rank())
		return AMNumber(AMNumber::DimensionError);

	int flatMeasurementIndex = flatIndexForMeasurement(measurementId, measurementIndex);

	if(axes_.count() == 0) {
#ifdef AM_ENABLE_BOUNDS_CHECKING
		if(flatMeasurementIndex >= scalarScanPoint_.at(measurementId).size())
			return AMNumber(AMNumber::OutOfBoundsError);
#endif
		return scalarScanPoint_.at(measurementId).at(flatMeasurementIndex);
	}
	else { // higher dimensions:
		int flatScanIndex = scanIndex.flatIndexInArrayOfSize(scanSize_);
#ifdef AM_ENABLE_BOUNDS_CHECKING
		if(flatScanIndex >= scanPoints_.count())
			return AMNumber(AMNumber::OutOfBoundsError);
		if(flatMeasurementIndex >= scanPoints_.at(flatScanIndex).at(measurementId).size())
			return AMNumber(AMNumber::OutOfBoundsError);
#endif
		return scanPoints_.at(flatScanIndex).at(measurementId).at(flatMeasurementIndex);
	}
}
示例#3
0
// Connected to be called when the values of the input data source change
void AM2DDeadTimeAB::onInputSourceValuesChanged(const AMnDIndex& start, const AMnDIndex& end)
{
	if (start.rank() == axes_.size() && end.rank() == axes_.size())
		emitValuesChanged(start, end);

	else
		emitValuesChanged();
}
示例#4
0
QPair<double, double> AM2DScanView::getCurrentExclusiveDataSourceRange(const AMnDIndex &start, const AMnDIndex &end) const
{
	if (start == end && start.rank() == 2 && end.rank() == 2){

		QPair<double, double> range = exclusive2DScanBar_->range();
		double val = double(currentExclusiveDataSource_->value(start));

		if ((val != -1 && range.first > val) || range.first == -1)
			range.first = val;

		if (range.second < val)
			range.second = val;

		return range;
	}

	else {

		int totalSize = 0;
		AMnDIndex startIndex = start;
		AMnDIndex endIndex = end;

		if (startIndex.rank() == 0 || endIndex.rank() == 0){

			startIndex = AMnDIndex(0, 0);
			endIndex = AMnDIndex(currentExclusiveDataSource_->size(0)-1, currentExclusiveDataSource_->size(1)-1);
			totalSize = startIndex.totalPointsTo(endIndex);
		}

		else
			totalSize = start.totalPointsTo(end);

		if (totalSize > 0){

			QVector<double> data(totalSize);
			currentExclusiveDataSource_->values(startIndex, endIndex, data.data());

			double min = data.at(0);
			double max = data.at(0);

			foreach (double value, data){

				if ((value != -1 && min > value) || min == -1)
					min = value;

				if (max < value)
					max = value;
			}

			return qMakePair(min, max);
		}

		else
			return qMakePair(-1.0, -1.0);
示例#5
0
// Connected to be called when the values of the input data source change
void AM3DAdditionAB::onInputSourceValuesChanged(const AMnDIndex& start, const AMnDIndex& end)
{
	cacheUpdateRequired_ = true;

	AMnDIndex scanStart = start;
	AMnDIndex scanEnd = end;
	scanStart.setRank(start.rank()-1);
	scanEnd.setRank(end.rank()-1);

	if (scanStart == scanEnd)
		dirtyIndices_ << start;

	emitValuesChanged(start, end);
}
示例#6
0
bool AM3DDeadTimeAB::values(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, double *outputValues) const
{
	if(indexStart.rank() != 3 || indexEnd.rank() != 3)
		return false;

	if(!isValid())
		return false;

#ifdef AM_ENABLE_BOUNDS_CHECKING
	if((unsigned)indexEnd.i() >= (unsigned)axes_.at(0).size || (unsigned)indexStart.i() > (unsigned)indexEnd.i()
			|| (unsigned)indexEnd.j() >= (unsigned)axes_.at(1).size || (unsigned)indexStart.j() > (unsigned)indexEnd.j()
			|| (unsigned)indexEnd.k() >= (unsigned)axes_.at(2).size || (unsigned)indexStart.k() > (unsigned)indexEnd.k())
		return false;
#endif

	int totalSize = indexStart.totalPointsTo(indexEnd);
	AMnDIndex start2D = AMnDIndex(indexStart.i(), indexStart.j());
	AMnDIndex end2D = AMnDIndex(indexEnd.i(), indexEnd.j());
	int icrOcrTotalSize = start2D.totalPointsTo(end2D);

	QVector<double> data = QVector<double>(totalSize);
	QVector<double> icr = QVector<double>(icrOcrTotalSize);
	QVector<double> ocr = QVector<double>(icrOcrTotalSize);
	spectra_->values(indexStart, indexEnd, data.data());
	icr_->values(start2D, end2D, icr.data());
	ocr_->values(start2D, end2D, ocr.data());

	for (int i = 0, iSize = indexEnd.i()-indexStart.i()+1; i < iSize; i++){

		for (int j = 0, jSize = indexEnd.j()-indexStart.j()+1; j < jSize; j++){

			// If ocr is equal to 0 then that will cause division by zero.  Since these are both count rates, they should both be greater than zero.
			if (icr.at(i*jSize+j) <= 0 || ocr.at(i*jSize+j) <= 0){

				for (int k = 0, kSize = indexEnd.k()-indexStart.k()+1; k < kSize; k++)
					outputValues[i*jSize*kSize+j*kSize+k] = 0;
			}

			else {

				double factor = icr.at(i*jSize+j)/ocr.at(i*jSize+j);

				for (int k = 0, kSize = indexEnd.k()-indexStart.k()+1; k < kSize; k++)
					outputValues[i*jSize*kSize+j*kSize+k] = data.at(i*jSize*kSize+j*kSize+k)*factor;
			}
		}
	}

	return true;
}
示例#7
0
void AMNormalizationAB::reviewState()
{
	// Are there data sources?
	if(sources_.isEmpty()){

		setState(AMDataSource::InvalidFlag);
		return;
	}

	// Are all the data sources the same size?
	AMnDIndex firstSize = sources_.first()->size();

	for (int i = 0, size = firstSize.rank(); i < size; i++)
		foreach (AMDataSource *dataSource, sources_)
			if(firstSize.at(i) != dataSource->size(i)){

				setState(AMDataSource::InvalidFlag);
				return;
			}

	// Validity check on all data sources.
	bool valid = true;

	for (int i = 0; i < sources_.size(); i++)
		valid = valid && sources_.at(i)->isValid();

	if (valid)
		setState(0);
	else
		setState(AMDataSource::InvalidFlag);
}
示例#8
0
AMNumber CLSQE65000Detector::reading(const AMnDIndex &indexes) const{
	if( (!isConnected()) || (indexes.rank() != 1) || (indexes.i() > 1024) )
		return AMNumber(AMNumber::DimensionError);

	AMReadOnlyPVControl *tmpControl = qobject_cast<AMReadOnlyPVControl*>(spectrumControl_);
	return tmpControl->readPV()->lastIntegerValues().at(indexes.i());
}
示例#9
0
bool AMInMemoryDataStore::setValue(const AMnDIndex &scanIndex, int measurementId, const double *inputData) {
	// scan axis index doesn't provide enough / too many dimensions
	if(scanIndex.rank() != axes_.count())
		return false;

	if((unsigned)measurementId >= (unsigned)measurements_.count())
		return false;	// invalid measurement specified;

	// scalar scan space:
	if(axes_.count() == 0) {
		AMIMDSMeasurement& measurement = scalarScanPoint_[measurementId];
		for(int i=0,cc=measurement.size(); i<cc; ++i)
			measurement[i] = inputData[i];
	}
	// higher dimension scan space:
	else {
		int flatScanIndex = scanIndex.flatIndexInArrayOfSize(scanSize_);
#ifdef AM_ENABLE_BOUNDS_CHECKING
		if(flatScanIndex >= scanPoints_.count())
			return false;
#endif
		AMIMDSMeasurement& measurement = scanPoints_[flatScanIndex][measurementId];
		for(int i=0,cc=measurement.size(); i<cc; ++i)
			measurement[i] = inputData[i];
	}

	emitDataChanged(scanIndex, scanIndex, measurementId);
	return true;
}
示例#10
0
bool AM1DInterpolationAB::values(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, double *outputValues) const
{
	if(indexStart.rank() != 1 || indexEnd.rank() != 1)
		return false;

	if(!isValid())
		return false;

#ifdef AM_ENABLE_BOUNDS_CHECKING
	if((unsigned)indexEnd.i() >= (unsigned)axes_.at(0).size || (unsigned)indexStart.i() > (unsigned)indexEnd.i())
		return false;
#endif

	inputSource_->values(indexStart, indexEnd, outputValues);
	return true;
}
示例#11
0
AMNumber AMNormalizationAB::value(const AMnDIndex &indexes) const
{
	if(indexes.rank() != rank())
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

	for (int i = 0, size = indexes.rank(); i < size; i++)
		if((unsigned)indexes.at(i) >= (unsigned)axes_.at(i).size)
			return AMNumber(AMNumber::OutOfBoundsError);

	if (cacheUpdateRequired_)
		computeCachedValues();

	return cachedData_.at(indexes.flatIndexInArrayOfSize(size()));
}
示例#12
0
AMnDIndex AMDetector::size() const
{
    AMnDIndex index = AMnDIndex(axes_.size(), AMnDIndex::DoNotInit);

    for (int i = 0, size = index.rank(); i < size; i++)
        index[i] = axes_.at(i).size;

    return index;
}
示例#13
0
bool AMBasicXRFDetectorInfo::setSize(const AMnDIndex &size)
{
	if (size.rank() != 1)
		return false;

	channels_ = size.i();
	setModified(true);
	return true;
}
示例#14
0
void AMInMemoryDataStore::measurementValuesImplementationRecursive(const AMIMDSMeasurement &measurement, const AMnDIndex &indexStart, const AMnDIndex &indexEnd, const AMnDIndex &fullSize, double **outputValues, int dimension, int cOffset) const {

	if(dimension == indexStart.rank()-1) { // base case: final dimension
		for(int i=indexStart.at(dimension); i<=indexEnd.at(dimension); ++i) {
			*((*outputValues)++) = double(measurement.at(cOffset+i));
		}
	}
	else {
		for(int i=indexStart.at(dimension); i<=indexEnd.at(dimension); ++i) {
			// get product of all higher dimensions:
			int multiplier = 1;
			for(int mu=dimension+1; mu<indexStart.rank(); ++mu)
				multiplier *= fullSize.at(mu);

			// recurse:
			measurementValuesImplementationRecursive(measurement, indexStart, indexEnd, fullSize, outputValues, dimension+1, cOffset + i*multiplier);
		}
	}
}
bool AM3DDeadTimeCorrectionAB::values(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, double *outputValues) const
{
	if(indexStart.rank() != 3 || indexEnd.rank() != 3)
		return false;

	if(!isValid())
		return false;

	if((unsigned)indexEnd.i() >= (unsigned)axes_.at(0).size || (unsigned)indexStart.i() > (unsigned)indexEnd.i()
			|| (unsigned)indexEnd.j() >= (unsigned)axes_.at(1).size || (unsigned)indexStart.j() > (unsigned)indexEnd.j()
			|| (unsigned)indexEnd.k() >= (unsigned)axes_.at(2).size || (unsigned)indexStart.k() > (unsigned)indexEnd.k())
		return false;

	int totalSize = indexStart.totalPointsTo(indexEnd);

	QVector<double> data = QVector<double>(totalSize);
	QVector<double> icr = QVector<double>(totalSize);
	QVector<double> ocr = QVector<double>(totalSize);
	spectra_->values(indexStart, indexEnd, data.data());
	icr_->values(indexStart, indexEnd, icr.data());
	ocr_->values(indexStart, indexEnd, ocr.data());

	for (int i = 0, iSize = indexEnd.i()-indexStart.i()+1; i < iSize; i++){

		for (int j = 0, jSize = indexEnd.j()-indexStart.j()+1; j < jSize; j++){

			for (int k = 0, kSize = indexEnd.k()-indexStart.k()+1; k < kSize; k++){

				int index = i + j*iSize + k*iSize*jSize;

				// If ocr is equal to 0 then that will cause division by zero.  Since these are both count rates, they should both be greater than zero.
				if (icr.at(index) <= 0 || ocr.at(index) <= 0)
					outputValues[index] = 0;

				else
					outputValues[index] = data.at(index)*icr.at(index)/ocr.at(index);
			}
		}
	}

	return true;
}
示例#16
0
bool AMNormalizationAB::values(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, double *outputValues) const
{
	if(indexStart.rank() != rank() || indexEnd.rank() != rank())
		return false;

	if(!isValid())
		return false;

	for (int i = 0, size = indexStart.rank(); i < size; i++)
		if((unsigned)indexStart.at(i) >= (unsigned)axes_.at(i).size || (unsigned)indexStart.at(i) > (unsigned)indexEnd.at(i))
			return false;

	if (cacheUpdateRequired_)
		computeCachedValues();

	int totalSize = indexStart.totalPointsTo(indexEnd);
	memcpy(outputValues, cachedData_.constData()+indexStart.flatIndexInArrayOfSize(size()), totalSize*sizeof(double));

	return true;
}
示例#17
0
bool AMDetector::readingND(const AMnDIndex &startIndex, const AMnDIndex &endIndex, double *outputValues) const {
    switch(startIndex.rank()) {
    case 0:
        return reading0D(startIndex, endIndex, outputValues);
    case 1:
        return reading1D(startIndex, endIndex, outputValues);
    case 2:
        return reading2D(startIndex, endIndex, outputValues);
    default:
        return false;
    }
}
bool REIXSXESImageInterpolationAB::values(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, double *outputValues) const
{
	if(indexStart.rank() != 1 || indexEnd.rank() != 1)
		return false;	// dimension error

	if(!isValid())
		return false; // invalid error

	// Max x pixel value:
	int maxI = inputSource_->size(0);

	if(indexEnd.i() < indexStart.i())
		return false;
	if(indexEnd.i() >= maxI)
		return false;

	if(cacheUpdateRequired_)
		computeCachedValues();

	memcpy(outputValues, (cachedData_.constData()+indexStart.i()), (indexEnd.i()-indexStart.i()+1)*sizeof(double));

	return true;
}
示例#19
0
// Returns the dependent value at a (complete) set of axis indexes. Returns an invalid AMNumber if the indexes are insuffient or any are out of range, or if the data is not ready.
AMNumber AM1DExpressionAB::value(const AMnDIndex& indexes) const {
	if(!isValid())	// will catch most invalid situations: non matching sizes, invalid inputs, invalid expressions.
		return AMNumber(AMNumber::InvalidError);

	if(indexes.rank() != 1)
		return AMNumber(AMNumber::DimensionError);

#ifdef AM_ENABLE_BOUNDS_CHECKING
		if(indexes.i() < 0 || indexes.i() >= size_)
			return AMNumber(AMNumber::OutOfBoundsError);
#endif


	// can we get it directly? Single-value expressions don't require the parser.
	if(direct_) {
		// info on which variable to use is contained in directVar_.
		if(directVar_.useAxisValue)
			return sources_.at(directVar_.sourceIndex)->axisValue(0, indexes.i());
		else
			return sources_.at(directVar_.sourceIndex)->value(indexes);
	}

	// otherwise we need the parser
	else {
		// copy the new input data values into parser storage
		for(int i=0; i<usedVariables_.count(); i++) {
			AMParserVariable* usedVar = usedVariables_.at(i);
			if(usedVar->useAxisValue)
				usedVar->value = sources_.at(usedVar->sourceIndex)->axisValue(0, indexes.i());
			else
				usedVar->value = sources_.at(usedVar->sourceIndex)->value(indexes);
		}

		// evaluate using the parser:
		double rv;
		try {
			rv = parser_.Eval();
		}
		catch(mu::Parser::exception_type& e) {
			QString explanation = QString("AM1DExpressionAB Analysis Block: error evaluating value: %1: '%2'.  We found '%3' at position %4.").arg(QString::fromStdString(e.GetMsg()), QString::fromStdString(e.GetExpr()), QString::fromStdString(e.GetToken())).arg(e.GetPos());
			AMErrorMon::report(AMErrorReport(this, AMErrorReport::Debug, e.GetCode(), explanation));
			return AMNumber(AMNumber::InvalidError);
		}

		if (rv == std::numeric_limits<qreal>::infinity() || rv == -std::numeric_limits<qreal>::infinity() || rv == std::numeric_limits<qreal>::quiet_NaN())
			return 0;

		return rv;
	}
}
示例#20
0
bool AM1DSummingAB::values(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, double *outputValues) const
{
	if(indexStart.rank() != 1 || indexEnd.rank() != 1)
		return false;

	if(!isValid())
		return false;

#ifdef AM_ENABLE_BOUNDS_CHECKING
	for (int i = 0; i < sources_.size(); i++)
		if ((unsigned)indexEnd.i() >= (unsigned)axes_.at(0).size)
			return false;

	if ((unsigned)indexStart.i() > (unsigned)indexEnd.i())
		return false;
#endif

	int totalSize = indexStart.totalPointsTo(indexEnd);

	QVector<double> data = QVector<double>(totalSize);
	sources_.at(0)->values(indexStart, indexEnd, data.data());

	// Do the first data source separately to initialize the values.
	for (int i = 0; i < totalSize; i++)
		outputValues[i] = data.at(i);

	// Iterate through the rest of the sources.
	for (int i = 1, count = sources_.size(); i < count; i++){

		sources_.at(i)->values(indexStart, indexEnd, data.data());

		for (int j = 0; j < totalSize; j++)
			outputValues[j] += data.at(j);
	}

	return true;
}
示例#21
0
bool AMDeadTimeAB::values(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, double *outputValues) const
{
	if(indexStart.rank() != 1 || indexEnd.rank() != 1)
		return false;

	if(!isValid())
		return false;

	if((unsigned)indexEnd.i() >= (unsigned)axes_.at(0).size || (unsigned)indexStart.i() > (unsigned)indexEnd.i())
		return false;

	int totalSize = indexStart.totalPointsTo(indexEnd);

	QVector<double> data = QVector<double>(totalSize);
	spectra_->values(indexStart, indexEnd, data.data());

	double icr = double(icr_->value(AMnDIndex()));
	double ocr = double(ocr_->value(AMnDIndex()));

	// If ocr is equal to 0 then that will cause division by zero.  Since these are both count rates, they should both be greater than zero.
	if (icr <= 0 || ocr <= 0){

		for (int i = 0; i < totalSize; i++)
			outputValues[i] = 0;
	}

	else {

		double factor = icr/ocr;

		for (int i = 0; i < totalSize; i++)
			outputValues[i] = data.at(i)*factor;
	}

	return true;
}
示例#22
0
// Helper function to implement the base-class version of values() when rank > 4.
void AMDataSource::valuesImplementationRecursive(const AMnDIndex &indexStart, const AMnDIndex &indexEnd, AMnDIndex current, int dimension, double **outputValues) const
{
    if(dimension == current.rank()-1) {	// base case: final dimension
        for(int i=indexStart.at(dimension); i<=indexEnd.at(dimension); ++i) {
            current[dimension] = i;
            *((*outputValues)++) = double(value(current));
        }
    }
    else {
        for(int i=indexStart.at(dimension); i<indexEnd.at(dimension); ++i) {
            current[dimension] = i;
            valuesImplementationRecursive(indexStart, indexEnd, current, dimension+1, outputValues);
        }
    }
}
AMNumber REIXSXESImageInterpolationAB::value(const AMnDIndex &indexes) const
{
	if((indexes.rank() != 1))
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

	if(((unsigned long)indexes.i() >= (unsigned long)axes_.at(0).size))
		return AMNumber(AMNumber::OutOfBoundsError);

	if(cacheUpdateRequired_)
		computeCachedValues();

	return AMNumber(cachedData_.at(indexes.i()));
}
示例#24
0
AMNumber AM1DInterpolationAB::value(const AMnDIndex& indexes) const{
	if(indexes.rank() != 1)
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

#ifdef AM_ENABLE_BOUNDS_CHECKING
		if((unsigned)indexes.i() >= (unsigned)axes_.at(0).size)
			return AMNumber(AMNumber::OutOfBoundsError);
#endif

	int index = indexes.i();

	return inputSource_->value(index);
}
示例#25
0
AMNumber AMDeadTimeAB::value(const AMnDIndex &indexes) const
{
	if(indexes.rank() != 1)
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

	if (indexes.i() >= spectra_->size(0))
		return AMNumber(AMNumber::OutOfBoundsError);

	if ((int)spectra_->value(indexes.i()) == 0)
		return 0;
	else
		return double(icr_->value(AMnDIndex()))/double(ocr_->value(AMnDIndex()))*(int)spectra_->value(indexes.i());
}
AMNumber AM2DDeadTimeCorrectionAB::value(const AMnDIndex &indexes) const
{
	if(indexes.rank() != 2)
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

	if (indexes.i() >= spectra_->size(0)
			|| indexes.j() >= spectra_->size(1))
		return AMNumber(AMNumber::OutOfBoundsError);

	if ((int)spectra_->value(indexes) == 0 || double(ocr_->value(indexes)) == 0)
		return 0;
	else
		return double(icr_->value(indexes))/double(ocr_->value(indexes))*(int)spectra_->value(indexes);
}
示例#27
0
AMNumber AM3DAdditionAB::value(const AMnDIndex &indexes) const
{
	if(indexes.rank() != 3)
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

	for (int i = 0; i < sources_.size(); i++)
		if (indexes.i() >= sources_.at(i)->size(0) || indexes.j() >= sources_.at(i)->size(1) || indexes.k() >= sources_.at(i)->size(2))
			return AMNumber(AMNumber::OutOfBoundsError);

    if (cacheUpdateRequired_)
        computeCachedValues();

    return cachedData_.at(indexes.i()*size(1)*size(2)+indexes.j()*size(2)+indexes.k());
}
示例#28
0
AMNumber AM2DDeadTimeAB::value(const AMnDIndex &indexes) const
{
	if(indexes.rank() != 2)
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

#ifdef AM_ENABLE_BOUNDS_CHECKING
	if (indexes.i() >= spectra_->size(0)
			|| indexes.j() >= spectra_->size(1))
		return AMNumber(AMNumber::OutOfBoundsError);
#endif

	if ((int)spectra_->value(indexes) == 0 || double(ocr_->value(indexes.i())) == 0)
		return 0;
	else
		return double(icr_->value(indexes.i()))/double(ocr_->value(indexes.i()))*(int)spectra_->value(indexes);
}
void AMExternalScanDataSourceAB::copyAxisValues(int dataSourceIndex)
{
	AMDataSource* ds = scan_->dataSourceAt(dataSourceIndex);
	const AMnDIndex size = ds->size();

	axisValues_.clear();

	for(int mu=0; mu<size.rank(); mu++) {	// for each axis
		QVector<AMNumber> av;

		if(!axes_.at(mu).isUniform) {
			int axisLength = size.at(mu);
			for(int i=0; i<axisLength; i++)	// copy all the axis values
				av << axisValue(mu, i);
		}

		axisValues_ << av;
	}
}
示例#30
0
AMNumber AMnDDeadTimeAB::value(const AMnDIndex &indexes) const
{
	if(indexes.rank() != rank())
		return AMNumber(AMNumber::DimensionError);

	if(!isValid())
		return AMNumber(AMNumber::InvalidError);

#ifdef AM_ENABLE_BOUNDS_CHECKING
	for (int i = 0, size = axes_.size(); i < size; i++)
		if (indexes.at(i) >= axes_.at(i).size)
			return AMNumber(AMNumber::OutOfBoundsError);
#endif

	if ((int)spectrum_->value(indexes) == 0 || double(outputCounts_->value(indexes.i())) == 0)
		return 0;
	else
		return double(inputCounts_->value(indexes.i()))/double(outputCounts_->value(indexes.i()))*(int)spectrum_->value(indexes);
}