void MainWindow::setupColorMapTest(QCustomPlot *customPlot) { customPlot->legend->setVisible(true); presetInteractive(customPlot); QCPColorMap *colorMap = new QCPColorMap(customPlot->xAxis, customPlot->yAxis); customPlot->addPlottable(colorMap); colorMap->setName("Color Map"); customPlot->addLayer("maplayer", customPlot->layer("grid"), QCustomPlot::limBelow); colorMap->setLayer("maplayer"); int nx = 400; int ny = 400; colorMap->data()->setSize(nx, ny); colorMap->data()->setRange(QCPRange(0, 10), QCPRange(0, 10)); colorMap->setInterpolate(true); colorMap->setTightBoundary(false); for (int x=0; x<nx; ++x) { for (int y=0; y<ny; ++y) { colorMap->data()->setCell(x, y, qExp(-qSqrt((x-310)*(x-310)+(y-260)*(y-260))/200.0)+ qExp(-qSqrt((x-200)*(x-200)+(y-290)*(y-290))/80.0)-qExp(-qSqrt((x-180)*(x-180)+(y-140)*(y-140))/200.0)); } } /* manual test of coordinate to cell transformations (and vice versa): connect(customPlot, SIGNAL(mouseMove(QMouseEvent*)), this, SLOT(colorMapMouseMove(QMouseEvent*))); colorMap->data()->setRange(QCPRange(0, 1), QCPRange(0, 1)); colorMap->data()->setSize(2,2); colorMap->data()->setCell(0, 0, 0); colorMap->data()->setCell(0, 1, 0); colorMap->data()->setCell(1, 0, 2); colorMap->data()->setCell(1, 1, 4); */ //customPlot->xAxis->setRangeReversed(true); //customPlot->yAxis->setRangeReversed(true); colorMap->setInterpolate(false); QCPColorScale *colorScale = new QCPColorScale(customPlot); customPlot->plotLayout()->addElement(0, 1, colorScale); colorMap->setColorScale(colorScale); colorScale->setLabel("test"); QCPMarginGroup *group = new QCPMarginGroup(customPlot); colorScale->setMarginGroup(QCP::msTop|QCP::msBottom, group); customPlot->axisRect()->setMarginGroup(QCP::msTop|QCP::msBottom, group); QCPColorGradient gradient = colorMap->gradient(); gradient.loadPreset(QCPColorGradient::gpJet); gradient.setPeriodic(false); colorMap->setGradient(gradient); colorMap->rescaleDataRange(true); connect(customPlot, SIGNAL(beforeReplot()), colorMap, SLOT(updateLegendIcon())); customPlot->rescaleAxes(); customPlot->replot(); }
void YarrGui::detachPlot(){ if(ui->plotTree->currentItem() == nullptr){ std::cerr << "Please select plot to detach...\n"; return; } if(ui->plotTree->currentItem()->childCount() > 0){ std::cerr << "Please select plot to detach...\n"; return; } PlotDialog * myPDiag = new PlotDialog(); QCustomPlot * plotWidget = dynamic_cast<QCustomPlot*>(ui->scanPlots_tabWidget->currentWidget()); if(plotWidget == nullptr){ std::cerr << "Severe cast error. Aborting...\n"; return; } QCustomPlot * transferPlot = dynamic_cast<QCustomPlot*>(myPDiag->childAt(10, 10)); if(transferPlot == nullptr){ std::cerr << "Severe cast error. Aborting...\n"; return; } QCPPlotTitle * widgetPT = dynamic_cast<QCPPlotTitle*>(plotWidget->plotLayout()->element(0, 0)); if(widgetPT == nullptr){ std::cerr << "Severe cast error. Aborting... \n"; return; } if(dynamic_cast<QCPColorMap*>(plotWidget->plottable(0)) != nullptr){ QCPColorMap * widgetCMap = dynamic_cast<QCPColorMap*>(plotWidget->plottable(0)); QCPColorScale * widgetCScale = dynamic_cast<QCPColorScale*>(plotWidget->plotLayout()->element(1, 1)); if(widgetCScale == nullptr) { std::cerr << "Severe cast error. Aborting... \n"; return; } transferPlot->plotLayout()->insertRow(0); transferPlot->plotLayout()->addElement(0, 0, new QCPPlotTitle(transferPlot, widgetPT->text())); QCPColorMap * transferCMap = new QCPColorMap(transferPlot->xAxis, transferPlot->yAxis); transferPlot->addPlottable(transferCMap); transferCMap->data()->setSize(80, 336); transferCMap->setData(widgetCMap->data(), true); QCPColorScale * transferCScale = new QCPColorScale(transferPlot); transferPlot->plotLayout()->addElement(1, 1, transferCScale); transferCScale->setType(QCPAxis::atRight); transferCMap->setColorScale(transferCScale); transferCMap->keyAxis()->setLabel(widgetCMap->keyAxis()->label()); transferCMap->valueAxis()->setLabel(widgetCMap->valueAxis()->label()); transferCScale->axis()->setLabel(widgetCScale->axis()->label()); transferCMap->setGradient(QCPColorGradient::gpPolar); transferCMap->rescaleDataRange(); }else if(dynamic_cast<QCPBars*>(plotWidget->plottable(0)) != nullptr){ QCPBars * widgetBars = dynamic_cast<QCPBars*>(plotWidget->plottable(0)); QCPBars * transferBars = new QCPBars(transferPlot->xAxis, transferPlot->yAxis); transferBars->setData(widgetBars->data(), true); transferBars->rescaleAxes(); transferPlot->plotLayout()->insertRow(0); transferPlot->plotLayout()->addElement(0, 0, new QCPPlotTitle(transferPlot, widgetPT->text())); transferBars->keyAxis()->setLabel(widgetBars->keyAxis()->label()); transferBars->valueAxis()->setLabel(widgetBars->valueAxis()->label()); }else{ std::cerr << "Severe cast error. Aborting... \n"; //DEBUG return; } transferPlot->rescaleAxes(); transferPlot->replot(); myPDiag->setModal(false); myPDiag->show(); removePlot(); return; }
void YarrGui::doScan(QString qn){ std::ofstream *tmpOfCout = new std::ofstream("deleteMeCout.txt"); std::streambuf *coutBuf = std::cout.rdbuf(tmpOfCout->rdbuf()); std::ofstream *tmpOfCerr = new std::ofstream("deleteMeCerr.txt"); std::streambuf *cerrBuf = std::cerr.rdbuf(tmpOfCerr->rdbuf()); int N = ui->feTree->topLevelItemCount(); int M = scanVec.size(); for(int j = 0; j < N; j++){ scanDone = false; processorDone = false; if(!(ui->feTree->topLevelItem(j)->child(4)->checkState(1))){continue;} //Is the Scan checkbox checked? Fei4 * fe = dynamic_cast<Fei4*>(bk->feList.at(j)); ScanBase * s = nullptr; if(qn == "NS") {s = new Fei4NoiseScan(bk);} if(qn == "DS") {s = new Fei4DigitalScan(bk);} if(qn == "AS") {s = new Fei4AnalogScan(bk);} if(qn == "TS") {s = new Fei4ThresholdScan(bk);} if(qn == "ToTS") {s = new Fei4TotScan(bk);} if(qn == "GTT") {s = new Fei4GlobalThresholdTune(bk);} if(qn == "GPT") {s = new Fei4GlobalPreampTune(bk);} if(qn == "PTT") {s = new Fei4PixelThresholdTune(bk);} if(qn == "PPT") {s = new Fei4PixelPreampTune(bk);} if(qn == "CS") {s = &cs;} if(s == nullptr){ std::cerr << "Invalid scan QString parameter passed or scan object construction failed. Returning...\n"; return; } QTreeWidgetItem * plotTreeItem = nullptr; //Plot tree item for current FE for(int k = 0; k < ui->plotTree->topLevelItemCount(); k++){ //Is the current FE already in the tree? ... if(ui->plotTree->topLevelItem(k)->text(0) == ui->feTree->topLevelItem(j)->text(0)){ plotTreeItem = ui->plotTree->topLevelItem(k); break; } } if(plotTreeItem == nullptr){ //... if not: create a branch for it plotTreeItem = new QTreeWidgetItem(ui->plotTree); plotTreeItem->setText(0, ui->feTree->topLevelItem(j)->text(0)); } QTreeWidgetItem * plotTreeItemDS = new QTreeWidgetItem(); //plot tree item for current scan plotTreeItemDS->setText(0, qn); plotTreeItem->addChild(plotTreeItemDS); fe->histogrammer = new Fei4Histogrammer(); fe->histogrammer->connect(fe->clipDataFei4, fe->clipHisto); fe->ana = new Fei4Analysis(bk, fe->getRxChannel()); fe->ana->connect(s, fe->clipHisto, fe->clipResult); if (qn=="CS"){ CustomScan * tmp; tmp = dynamic_cast<CustomScan*>(s); if(tmp->bA.at(OCC_MAP) == true) {fe->histogrammer->addHistogrammer(new OccupancyMap());} if(tmp->bA.at(TOT_MAP) == true) {fe->histogrammer->addHistogrammer(new TotMap());} if(tmp->bA.at(TOT_2_MAP) == true) {fe->histogrammer->addHistogrammer(new Tot2Map());} if(tmp->bA.at(OCC_ANA) == true) {fe->ana->addAlgorithm(new OccupancyAnalysis());} if(tmp->bA.at(NOISE_ANA) == true) {fe->ana->addAlgorithm(new NoiseAnalysis());} if(tmp->bA.at(TOT_ANA) == true) {fe->ana->addAlgorithm(new TotAnalysis());} if(tmp->bA.at(S_CU_FIT) == true) {fe->ana->addAlgorithm(new ScurveFitter());} if(tmp->bA.at(PIX_THR) == true) {fe->ana->addAlgorithm(new OccPixelThresholdTune);} }else{ fe->histogrammer->addHistogrammer(new OccupancyMap()); if (qn == "ToTS" || qn == "GPT" || qn == "PPT"){ fe->histogrammer->addHistogrammer(new TotMap()); fe->histogrammer->addHistogrammer(new Tot2Map()); } if(qn == "NS") {fe->ana->addAlgorithm(new NoiseAnalysis());} if(qn == "DS") {fe->ana->addAlgorithm(new OccupancyAnalysis());} if(qn == "AS") {fe->ana->addAlgorithm(new OccupancyAnalysis());} if(qn == "TS") {fe->ana->addAlgorithm(new ScurveFitter());} if(qn == "ToTS") {fe->ana->addAlgorithm(new TotAnalysis());} if(qn == "GTT") {fe->ana->addAlgorithm(new OccGlobalThresholdTune());} if(qn == "GPT") {fe->ana->addAlgorithm(new TotAnalysis());} if(qn == "PTT") {fe->ana->addAlgorithm(new OccPixelThresholdTune());} if(qn == "PPT") {fe->ana->addAlgorithm(new TotAnalysis());} } s->init(); ui->scanProgressBar->setValue(ui->scanProgressBar->value() + (int)(100.0/(7.0*N*M))); //1 s->preScan(); ui->scanProgressBar->setValue(ui->scanProgressBar->value() + (int)(100.0/(7.0*N*M))); //2 unsigned int numThreads = std::thread::hardware_concurrency(); //std::cout << "-> Starting " << numThreads << " processor Threads:" << std::endl; std::vector<std::thread> procThreads; for (unsigned i=0; i<numThreads; i++){ procThreads.push_back(std::thread(process, bk, &scanDone)); //std::cout << " -> Processor thread #" << i << " started!" << std::endl; } std::vector<std::thread> anaThreads; //std::cout << "-> Starting histogrammer and analysis threads:" << std::endl; if (fe->isActive()){ anaThreads.push_back(std::thread(analysis, fe->histogrammer, fe->ana, &processorDone)); //std::cout << " -> Analysis thread of Fe " << fe->getRxChannel() << std::endl; } s->run(); ui->scanProgressBar->setValue(ui->scanProgressBar->value() + (int)(100.0/(7.0*N*M))); //3 s->postScan(); ui->scanProgressBar->setValue(ui->scanProgressBar->value() + (int)(100.0/(7.0*N*M))); //4 scanDone = true; for (unsigned i=0; i<numThreads; i++){ procThreads[i].join(); } ui->scanProgressBar->setValue(ui->scanProgressBar->value() + (int)(100.0/(7.0*N*M))); //5 processorDone = true; for(unsigned i=0; i<anaThreads.size(); i++){ anaThreads[i].join(); } ui->scanProgressBar->setValue(ui->scanProgressBar->value() + (int)(100.0/(7.0*N*M))); //6 if(qn != "CS") { delete s; } // fe->toFileBinary(); // fe->ana->plot("Scan_GUI"); //DEBUG begin [plotting] //clear raw data while(fe->clipDataFei4->size() != 0){ fe->clipDataFei4->popData(); } //clear raw data while(fe->clipHisto->size() != 0){ fe->clipHisto->popData(); } while(fe->clipResult->size() != 0){ HistogramBase * showMe = fe->clipResult->popData(); //Add tab to plot tab widget QCustomPlot * tabScanPlot = new QCustomPlot(ui->scanPlots_tabWidget); // X QWidget * addToTabWidget = dynamic_cast<QWidget*>(tabScanPlot); QString newTabName = qn + ' ' + ui->feTree->topLevelItem(j)->text(0); ui->scanPlots_tabWidget->addTab(addToTabWidget, newTabName); //Add plot to scan tree QTreeWidgetItem * plotTreeItemP = new QTreeWidgetItem(plotTreeItemDS); // X plotTreeItemP->setText(0, "Plot " + QString::number(plotTreeItemDS->childCount()) + " (" + QString::fromStdString(showMe->getName()) + ")"); plotTreeItemDS->addChild(plotTreeItemP); if(dynamic_cast<Histo2d*>(showMe) != nullptr){ Histo2d * myHist2d = dynamic_cast<Histo2d*>(showMe); //Create plot QCPColorMap * colorMap = new QCPColorMap(tabScanPlot->xAxis, tabScanPlot->yAxis); QCPColorScale * colorScale = new QCPColorScale(tabScanPlot); tabScanPlot->addPlottable(colorMap); tabScanPlot->plotLayout()->insertRow(0); tabScanPlot->plotLayout()->addElement(0, 0, new QCPPlotTitle(tabScanPlot, QString::fromStdString(myHist2d->getName()))); colorMap->setName(QString::fromStdString(myHist2d->getName())); colorMap->data()->setSize(80, 336); colorMap->data()->setRange(QCPRange(0, 80), QCPRange(0, 336)); colorMap->keyAxis()->setLabel(QString::fromStdString(myHist2d->getXaxisTitle())); colorMap->valueAxis()->setLabel(QString::fromStdString(myHist2d->getYaxisTitle())); for(int xCoord = 0; xCoord<80; xCoord++){ for(int yCoord = 0; yCoord<336; yCoord++){ double colVal = myHist2d->getBin(yCoord + 336*xCoord); //TODO make better colorMap->data()->setCell(xCoord, yCoord, colVal); } } tabScanPlot->plotLayout()->addElement(1, 1, colorScale); colorScale->setType(QCPAxis::atRight); colorMap->setColorScale(colorScale); colorScale->axis()->setLabel(QString::fromStdString(myHist2d->getZaxisTitle())); colorMap->setGradient(QCPColorGradient::gpPolar); colorMap->rescaleDataRange(); }else if(dynamic_cast<Histo1d*>(showMe) != nullptr){ Histo1d * myHist1d = dynamic_cast<Histo1d*>(showMe); QCPBars * myBars = new QCPBars(tabScanPlot->xAxis, tabScanPlot->yAxis); tabScanPlot->addPlottable(myBars); myBars->setName(QString::fromStdString(myHist1d->getName())); for(unsigned int i = 0; i < myHist1d->size(); i++) { myBars->addData((double)(i+1), myHist1d->getBin(i)); } myBars->rescaleAxes(); tabScanPlot->plotLayout()->insertRow(0); tabScanPlot->plotLayout()->addElement(0, 0, new QCPPlotTitle(tabScanPlot, QString::fromStdString(myHist1d->getName()))); myBars->keyAxis()->setLabel(QString::fromStdString(myHist1d->getXaxisTitle())); myBars->valueAxis()->setLabel(QString::fromStdString(myHist1d->getYaxisTitle())); }else{ std::cerr << "Correct plot type not found or severe cast error\n"; //DEBUG return; } tabScanPlot->rescaleAxes(); tabScanPlot->replot(); } ui->scanProgressBar->setValue(ui->scanProgressBar->value() + (int)(100.0/(7.0*N*M))); //7 delete fe->histogrammer; fe->histogrammer = nullptr; delete fe->ana; fe->ana = nullptr; } std::cout.rdbuf(coutBuf); std::cerr.rdbuf(cerrBuf); tmpOfCout->close(); tmpOfCerr->close(); std::ifstream tmpInCout("deleteMeCout.txt"); std::ifstream tmpInCerr("deleteMeCerr.txt"); std::cout << tmpInCout.rdbuf(); std::cerr << tmpInCerr.rdbuf(); tmpInCout.close(); tmpInCerr.close(); return; }