示例#1
0
bool AMExporterGeneralAscii::writeSeparateFiles(const QString& destinationFolderPath)
{
	for(int s=0; s<separateFileDataSources_.count(); s++) {

		setCurrentDataSource(separateFileDataSources_.at(s));	// sets currentDataSourceIndex_
		AMDataSource* ds = currentScan_->dataSourceAt(currentDataSourceIndex_);

		QFile file;
		QString separateFileName = parseKeywordString( destinationFolderPath % "/" % option_->separateSectionFileName() );

		if(!openFile(&file, separateFileName)) {
			AMErrorMon::report(AMErrorReport(this, AMErrorReport::Alert, -4, "Export failed (partially): You selected to create separate files for certain data sets. Could not open the file '" % separateFileName % "' for writing.  Check that you have permission to save files there, and that a file with that name doesn't already exists."));
			return false;
		}

		QTextStream ts(&file);

		// section header?
		if(option_->sectionHeaderIncluded()) {
			ts << parseKeywordString(option_->sectionHeader());
			ts << option_->newlineDelimiter();
		}

		// column header?
		if(option_->columnHeaderIncluded()) {
			// 1D data sources:
			if(ds->rank() == 0) {
				ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();
			}
			else if(ds->rank() == 1) {
				if(separateFileIncludeX_.at(s))
					ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
				ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();
			}
			else if(ds->rank() == 2) {	// 2D
				if(separateFileIncludeX_.at(s))
					ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
				// need a loop over the second axis columns
				for(int cc=0; cc<ds->size(1); cc++) {
					setCurrentColumnIndex(cc);
					ts << parseKeywordString(option_->columnHeader()) << "[" << ds->axisValue(1, cc).toString() << ds->axisInfoAt(1).units << "]" << option_->columnDelimiter();
				}
			}
			ts << option_->newlineDelimiter() << option_->columnHeaderDelimiter() << option_->newlineDelimiter();
		}

		// table
		switch(ds->rank()) {
		case 0:
			ts << ds->value(AMnDIndex()).toString() << option_->columnDelimiter() << option_->newlineDelimiter();
			break;
		case 1: {
			int maxTableRows = ds->size(0);
			for(int r=0; r<maxTableRows; r++) {
				if(separateFileIncludeX_.at(s)) {
					ts << ds->axisValue(0,r).toString() << option_->columnDelimiter();
				}
				ts << ds->value(r).toString() << option_->columnDelimiter() << option_->newlineDelimiter();
			}
		}
		break;
		case 2: {
			int maxTableRows = ds->size(0);
			for(int r=0; r<maxTableRows; r++) {
				if(separateFileIncludeX_.at(s))
					ts << ds->axisValue(0,r).toString() << option_->columnDelimiter();
				// need a loop over the second axis columns
				for(int cc=0; cc<ds->size(1); cc++) {
					ts << ds->value(AMnDIndex(r,cc)).toString() << option_->columnDelimiter();
				}
				ts << option_->newlineDelimiter();
			}
		}
		break;
		default:
			/// \todo Implement 3D
			break;
		}
	}

	return true;
}
示例#2
0
void AMExporterGeneralAscii::writeSeparateSections()
{
	QTextStream ts(file_);

	for(int s=0; s<separateSectionDataSources_.count(); s++) {

		ts << option_->newlineDelimiter();

		setCurrentDataSource(separateSectionDataSources_.at(s));	// sets currentDataSourceIndex_
		AMDataSource* ds = currentScan_->dataSourceAt(currentDataSourceIndex_);

		// section header?
		if(option_->sectionHeaderIncluded()) {
			ts << parseKeywordString(option_->sectionHeader());
			ts << option_->newlineDelimiter();
		}

		// column header?
		if(option_->columnHeaderIncluded()) {
			// 1D data sources:
			if(ds->rank() == 0) {
				ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();
			}
			else if(ds->rank() == 1) {
				if(separateSectionIncludeX_.at(s))
					ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
				ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();
			}
			else if(ds->rank() == 2) {	// 2D
				if(separateSectionIncludeX_.at(s))
					ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
				// need a loop over the second axis columns
				for(int cc=0; cc<ds->size(1); cc++) {
					setCurrentColumnIndex(cc);
					ts << parseKeywordString(option_->columnHeader()) << "[" << ds->axisValue(1, cc).toString() << ds->axisInfoAt(1).units << "]" << option_->columnDelimiter();
				}
			}
			ts << option_->newlineDelimiter() << option_->columnHeaderDelimiter() << option_->newlineDelimiter();
		}

		// table
		switch(ds->rank()) {
		case 0:
			ts << ds->value(AMnDIndex()).toString() << option_->columnDelimiter() << option_->newlineDelimiter();
			break;
		case 1: {
			int maxTableRows = ds->size(0);
			for(int r=0; r<maxTableRows; r++) {
				if(separateSectionIncludeX_.at(s)) {
					ts << ds->axisValue(0,r).toString() << option_->columnDelimiter();
				}
				ts << ds->value(r).toString() << option_->columnDelimiter() << option_->newlineDelimiter();
			}
		}
		break;
		case 2: {
			int maxTableRows = ds->size(0);
			for(int r=0; r<maxTableRows; r++) {
				if(separateSectionIncludeX_.at(s))
					ts << ds->axisValue(0,r).toString() << option_->columnDelimiter();
				// need a loop over the second axis columns
				for(int cc=0; cc<ds->size(1); cc++) {
					ts << ds->value(AMnDIndex(r,cc)).toString() << option_->columnDelimiter();
				}
				ts << option_->newlineDelimiter();
			}
		}
		break;
		default:
			/// \todo Implement 3D
			break;
		}
	}
}
void AMExporterGeneralAscii::writeSeparateSections()
{
	QTextStream ts(file_);

	if (option_->higherDimensionsInRows()){

		for(int s=0; s<separateSectionDataSources_.count(); s++) {

			ts << option_->newlineDelimiter();

			setCurrentDataSource(separateSectionDataSources_.at(s));	// sets currentDataSourceIndex_
			AMDataSource* ds = currentScan_->dataSourceAt(currentDataSourceIndex_);
			int precision = option_->exportPrecision(ds->name());

			// section header?
			if(option_->sectionHeaderIncluded()) {
				ts << parseKeywordString(option_->sectionHeader());
				ts << option_->newlineDelimiter();
			}

			// column header?
			if(option_->columnHeaderIncluded()) {
				// 1D data sources:
				if(ds->rank() == 0) {
					ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();
				}
				else if(ds->rank() == 1) {
					if(separateSectionIncludeX_.at(s))
						ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
					ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();
				}
				else if(ds->rank() == 2) {	// 2D
					if(separateSectionIncludeX_.at(s))
						ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
					// need a loop over the second axis columns
					for(int cc=0; cc<ds->size(1); cc++) {
						setCurrentColumnIndex(cc);
						ts << parseKeywordString(option_->columnHeader()) << "[" << ds->axisValue(1, cc).toString(precision) << ds->axisInfoAt(1).units << "]" << option_->columnDelimiter();
					}
				}
				ts << option_->newlineDelimiter() << option_->columnHeaderDelimiter() << option_->newlineDelimiter();
			}

			// table
			switch(ds->rank()) {
			case 0:
				ts << ds->value(AMnDIndex()).toString(precision) << option_->columnDelimiter() << option_->newlineDelimiter();
				break;
			case 1: {
				int maxTableRows = ds->size(0);
				for(int r=0; r<maxTableRows; r++) {
					if(separateSectionIncludeX_.at(s)) {
						ts << ds->axisValue(0,r).toString(precision) << option_->columnDelimiter();
					}
					ts << ds->value(r).toString(precision) << option_->columnDelimiter() << option_->newlineDelimiter();
				}
			}
				break;
			case 2: {
				int maxTableRows = ds->size(0);
				for(int r=0; r<maxTableRows; r++) {
					if(separateSectionIncludeX_.at(s))
						ts << ds->axisValue(0,r).toString(precision) << option_->columnDelimiter();
					// need a loop over the second axis columns
					for(int cc=0; cc<ds->size(1); cc++) {
						ts << ds->value(AMnDIndex(r,cc)).toString(precision) << option_->columnDelimiter();
					}
					ts << option_->newlineDelimiter();
				}
			}
				break;
			default:
				/// \todo Implement 3D
				break;
			}
		}
	}

	// For writing out in columns.  Essentially transposing the file.
	else{

		for(int s=0; s<separateSectionDataSources_.count(); s++) {

			setCurrentDataSource(separateSectionDataSources_.at(s));	// sets currentDataSourceIndex_
			AMDataSource* ds = currentScan_->dataSourceAt(currentDataSourceIndex_);
			int precision = option_->exportPrecision(ds->name());

			// section header?
			if(option_->sectionHeaderIncluded()) {
				ts << parseKeywordString(option_->sectionHeader());
				ts << option_->newlineDelimiter();
			}

			// If including the X values.
			if (separateSectionIncludeX_.at(s)){

				switch(ds->rank()){

				case 0:
					break;

				case 1:
				case 2:{

					ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();

					int maxTableColumns = ds->size(0);

					for(int column = 0; column < maxTableColumns; column++)
						ts << ds->axisValue(0,column).toString(precision) << option_->columnDelimiter();

					ts << option_->newlineDelimiter();

					break;
				}

				default:
					/// \todo 3D.
					break;
				}
			}

			// Main table with column headers prefacing rows.
			switch (ds->rank()){

			case 0:{

				if(option_->columnHeaderIncluded())
					ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();

				ts << ds->value(AMnDIndex()).toString(precision) << option_->columnDelimiter() << option_->newlineDelimiter();

				break;
			}

			case 1:{

				if (option_->columnHeaderIncluded())
					ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();

				int maxTableColumns = ds->size(0);

				for(int column = 0; column < maxTableColumns; column++)
					ts << ds->value(column).toString(precision) << option_->columnDelimiter();

				ts << option_->newlineDelimiter();

				break;
			}

			case 2:{

				for (int cc = 0; cc < ds->size(1); cc++){

					if (option_->columnHeaderIncluded())
						ts << parseKeywordString(option_->columnHeader()) << "[" << ds->axisValue(1, cc).toString(precision) << ds->axisInfoAt(1).units << "]" << option_->columnDelimiter();

					int maxTableColumns = ds->size(0);

					for (int column = 0; column < maxTableColumns; column++)
						ts << ds->value(AMnDIndex(column, cc)).toString(precision) << option_->columnDelimiter();

					ts << option_->newlineDelimiter();
				}

				break;
			}

			default:
				/// \todo 3D
				break;
			}
		}
	}
}
示例#4
0
void AMExporterGeneralAscii::writeMainTable()
{
	QTextStream ts(file_);

	// 1. Column header.
	int maxTableRows = 0;
	if(option_->columnHeaderIncluded()) {
		for(int c=0; c<mainTableDataSources_.count(); c++) {
			setCurrentDataSource(mainTableDataSources_.at(c));
			AMDataSource* ds = currentScan_->dataSourceAt(currentDataSourceIndex_);

			if(ds->size(0) > maxTableRows)
				maxTableRows = ds->size(0); // convenient... lets figure this out while we're looping through anyway

			// 1D data sources:
			if(ds->rank() == 1) {
				if(mainTableIncludeX_.at(c))
					ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
				ts << parseKeywordString(option_->columnHeader()) << option_->columnDelimiter();
			}
			else {	// 2D
				if(mainTableIncludeX_.at(c))
					ts << parseKeywordString(option_->columnHeader()) << ".X" << option_->columnDelimiter();
				// need a loop over the second axis columns
				for(int cc=0; cc<ds->size(1); cc++) {
					setCurrentColumnIndex(cc);
					ts << parseKeywordString(option_->columnHeader()) << "[" << ds->axisValue(1, cc).toString() << ds->axisInfoAt(1).units << "]" << option_->columnDelimiter();
				}
			}
		}
		ts << option_->newlineDelimiter() << option_->columnHeaderDelimiter() << option_->newlineDelimiter();
	}


	// 2. rows
	for(int r=0; r<maxTableRows; r++) {

		// over rows within columns
		for(int c=0; c<mainTableDataSources_.count(); c++) {
			setCurrentDataSource(mainTableDataSources_.at(c));
			AMDataSource* ds = currentScan_->dataSourceAt(currentDataSourceIndex_);

			bool doPrint = (ds->size(0) > r);

			// print x column?
			if(mainTableIncludeX_.at(c)) {
				if(doPrint)
					ts << ds->axisValue(0,r).toString();
				ts << option_->columnDelimiter();
			}

			// 1D data sources:
			if(ds->rank() == 1) {
				if(doPrint)
					ts << ds->value(r).toString();
				ts << option_->columnDelimiter();
			}
			else if(ds->rank() == 2) {
				// need a loop over the second axis columns
				for(int cc=0; cc<ds->size(1); cc++) {
					if(doPrint)
						ts << ds->value(AMnDIndex(r,cc)).toString();
					ts << option_->columnDelimiter();
				}
			}
		}
		ts << option_->newlineDelimiter();
	}
}
示例#5
0
void AM3dDataSourceView::updatePlotFromDataSource()
{
	// Know from previously that the rank of this data source is 2.

	// Or the scan is 0, which means we have no data to show.
	if(scan_ == 0) {
		surfacePlot_->loadFromData(0,0,0);
		return;
	}


	AMDataSource* ds = scan_->dataSourceAt(dataSourceIndex_);

	double minZ = 0, maxZ = 1;
	int sizeX = ds->size(0);
	int sizeY = ds->size(1);

	bool uniformAxisScales = ds->axisInfoAt(0).isUniform && ds->axisInfoAt(1).isUniform;

	if(uniformAxisScales) {
		qDebug() << "Uniform axis scales. Using simplest (uniform) grid filling";
		double** zValues = new2dArray<double>(sizeX, sizeY);

		if(logScaleEnabled_) {
			if(sizeX > 0 && sizeY > 0)
				minZ = maxZ = log(qMax(logMin_,(double)ds->value(AMnDIndex(0,0))));

			for(int i=0; i<sizeX; i++)
				for(int j=0; j<sizeY; j++) {
					double zValue = log(qMax(logMin_,(double)ds->value(AMnDIndex(i,j))));
					minZ = qMin(minZ, zValue);
					maxZ = qMax(maxZ, zValue);
					zValues[i][j] = zValue;
				}
		}
		else {
			if(sizeX > 0 && sizeY > 0)
				minZ = maxZ = ds->value(AMnDIndex(0,0));

			for(int i=0; i<sizeX; i++)
				for(int j=0; j<sizeY; j++) {
					double zValue = ds->value(AMnDIndex(i,j));
					minZ = qMin(minZ, zValue);
					maxZ = qMax(maxZ, zValue);
					zValues[i][j] = zValue;
				}
		}

		surfacePlot_->loadFromData(zValues,
								   sizeX,
								   sizeY,
								   ds->axisValue(0,0),
								   ds->axisValue(0,sizeX-1),
								   ds->axisValue(1,0),
								   ds->axisValue(1,sizeY-1));

		// called from loadFromData(): surfacePlot_->updateData();
		// not necessary?: surfacePlot_->updateGL();

		delete2dArray(zValues);
	}
	else {	// non-uniform axis scale grid
		qDebug() << "Non-uniform axis scale. Using irregular grid";

		Qwt3D::Triple** gridValues = new2dArray<Qwt3D::Triple>(sizeX, sizeY);

		if(logScaleEnabled_) {
			if(sizeX >0 && sizeY > 0)
				minZ = maxZ = log(qMax(logMin_,(double)ds->value(AMnDIndex(0,0))));

			for(int i=0; i<sizeX; i++) {
				double xAxisValue = ds->axisValue(0,i);
				for(int j=0; j<sizeY; j++) {
					double zValue = log(qMax(logMin_,(double)ds->value(AMnDIndex(i,j))));
					minZ = qMin(minZ, zValue);
					maxZ = qMax(maxZ, zValue);
					gridValues[i][j] = Qwt3D::Triple(xAxisValue, ds->axisValue(1,j), zValue);
				}
			}
		}
		else {
			if(sizeX >0 && sizeY > 0)
				minZ = maxZ = ds->value(AMnDIndex(0,0));

			for(int i=0; i<sizeX; i++) {
				double xAxisValue = ds->axisValue(0,i);
				for(int j=0; j<sizeY; j++) {
					double zValue = ds->value(AMnDIndex(i,j));
					minZ = qMin(minZ, zValue);
					maxZ = qMax(maxZ, zValue);
					gridValues[i][j] = Qwt3D::Triple(xAxisValue, ds->axisValue(1,j), zValue);
				}
			}
		}

		surfacePlot_->loadFromData(gridValues, sizeX, sizeY);
		delete2dArray(gridValues);
	}

	// doesnt realy do anyting: surfacePlot_->coordinates()->setAutoScale(true);

	double zRange = maxZ - minZ;
	double xRange = (double)ds->axisValue(0, sizeX-1) - (double)ds->axisValue(0,0);
	double yRange = (double)ds->axisValue(1, sizeY-1) - (double)ds->axisValue(1,0);

	surfacePlot_->setScale(100*zRange/xRange, 100*zRange/yRange, 100);

	double drad = (surfacePlot_->hull().maxVertex-surfacePlot_->hull().minVertex).length();
	drad *= 30/20.;
	surfacePlot_->setLightShift(drad,drad,drad);
	surfacePlot_->setLightRotation(90,0,0);

	AMAxisInfo xInfo = ds->axisInfoAt(0);
	AMAxisInfo yInfo = ds->axisInfoAt(1);

	QString xLabel = xInfo.description % " (" % xInfo.units % ")";
	QString yLabel = yInfo.description % " (" % yInfo.units % ")";
	QString zLabel = ds->description();

	surfacePlot_->coordinates()->axes[Qwt3D::X1].setLabelString(xLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::X2].setLabelString(xLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::X3].setLabelString(xLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::X4].setLabelString(xLabel);

	surfacePlot_->coordinates()->axes[Qwt3D::Y1].setLabelString(yLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::Y2].setLabelString(yLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::Y3].setLabelString(yLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::Y4].setLabelString(yLabel);

	surfacePlot_->coordinates()->axes[Qwt3D::Z1].setLabelString(zLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::Z2].setLabelString(zLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::Z3].setLabelString(zLabel);
	surfacePlot_->coordinates()->axes[Qwt3D::Z4].setLabelString(zLabel);
}