/* Copyright (c) 2008-2019 Jan W. Krieger & Sebastian Isbaner (contour plot) This software is free software: you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License (LGPL) as published by the Free Software Foundation, either version 2.1 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License (LGPL) for more details. You should have received a copy of the GNU Lesser General Public License (LGPL) along with this program. If not, see . */ #include "jkqtplotter/jkqtpgraphscontour.h" #include "jkqtplotter/jkqtpbaseplotter.h" #include "jkqtplottertools/jkqtpimagetools.h" #include "jkqtcommon/jkqtptools.h" #include "jkqtplottertools/jkqtpenhancedpainter.h" #include "jkqtplotter/jkqtplotter.h" #include "jkqtpgraphscontour.h" #include #include #include #include #include #include # include JKQTPContourPlot::JKQTPContourPlot(JKQTBasePlotter *parent) : JKQTPMathImage(parent) { ignoreOnPlane=false; contourColoringMode=ColorContoursFromPaletteByValue; relativeLevels=false; initLineStyle(parent, parentPlotStyle); } JKQTPContourPlot::JKQTPContourPlot(JKQTPlotter *parent) : JKQTPContourPlot(parent->getPlotter()) { } void JKQTPContourPlot::draw(JKQTPEnhancedPainter &painter) { //qDebug()<<"JKQTPContourPlot::draw"; ensureImageData(); int numberOfLevels=contourLevels.size(); if (numberOfLevels<=0) return; int64_t colChecksum=-1; if (data && Nx*Ny>0) { colChecksum=static_cast(qChecksum(reinterpret_cast(data), Nx*Ny* getSampleSize())); } /*if (parent && parent->getDatastore() && imageColumn>=0) { colChecksum=static_cast(parent->getDatastore()->getColumnChecksum(imageColumn)); }*/ if(contourLinesCache.isEmpty() || (contourLinesCachedForChecksum!=colChecksum) || (contourLinesCachedForChecksum<0)) { // contour lines are only calculated once QList > lines; lines.reserve(contourLevels.size()); for(int i =0; i (0)); } this->calcContourLines(lines); contourLinesCache.clear(); contourLinesCachedForChecksum=colChecksum; for (const QVector& l: lines) { contourLinesCache.push_back(JKQTPUnifyLinesToPolygons(l, qMin(getWidth()/static_cast(getNx()),getHeight()/static_cast(getNy()))/4.0)); } } // draw lines painter.save(); auto __finalpaint=JKQTPFinally([&painter]() {painter.restore();}); QPen p=getLinePen(painter, parent); painter.setPen(p); // calculate an image with one pixel per contour level and fill it with the appropriate colors QImage colorLevels = getPaletteImage(palette,numberOfLevels); // (contourColoringMode==ContourColoringMode::ColorContoursFromPalette) if (contourColoringMode==ContourColoringMode::SingleColorContours) { for (int i=0; i(0, (internalDataMax-contourLevels.value(i, 0))*static_cast(colorDataLevels.width())/(internalDataMax-internalDataMin), colorDataLevels.width()-1),0)); } } // set override colors for (int i=0; i contourLinesTransformedSingleLevel; p.setColor(QColor(colorLevels.pixel(i,0))); painter.setPen(p); // transform into plot coordinates for(auto polygon =contourLinesCache.at(i).begin(); polygon!=contourLinesCache.at(i).end();++polygon ) { contourLinesTransformedSingleLevel.push_back(QPolygonF()); for (auto& p: *polygon) { contourLinesTransformedSingleLevel.last().append(transform(x+p.x()/double(Nx-1)*width, y+p.y()/double(Ny-1)*height)); } //qDebug()<(nLevels+1); for(int i=1; i<=nLevels; ++i) { contourLevels.append(min + i*delta); } relativeLevels=false; clearCachedContours(); } void JKQTPContourPlot::createContourLevelsLog(int nLevels, int m) { ensureImageData(); clearContourLevel(); if (!data) return; if (nLevels<1) return; double min,max; getDataMinMax(min,max); if(min<=0) min=1; // FIXME get smallest number greater zero int S=floor((log10(max)-log10(min))/log10(m)); if(S<2) S=1; int P = floor(static_cast(nLevels)/static_cast(S)); if(P<1) P=1; double delta=min; contourLevels.append(2*delta); for (long s=0; signoreOnPlane = __value; clearCachedContours(); } bool JKQTPContourPlot::getIgnoreOnPlane() const { return this->ignoreOnPlane; } int JKQTPContourPlot::getNumberOfLevels() const { return this->contourLevels.size(); } void JKQTPContourPlot::setContourColoringMode(ContourColoringMode __value) { this->contourColoringMode = __value; } JKQTPContourPlot::ContourColoringMode JKQTPContourPlot::getContourColoringMode() const { return this->contourColoringMode; } QVector JKQTPContourPlot::getContourLevels() const { return this->contourLevels; } void JKQTPContourPlot::setRelativeLevels(bool __value) { this->relativeLevels = __value; } bool JKQTPContourPlot::getRelativeLevels() const { return this->relativeLevels; } void JKQTPContourPlot::addContourLevel(double level) { contourLevels.append(level); qSort(contourLevels); clearCachedContours(); } void JKQTPContourPlot::addContourLevel(double level, QColor overrideColor) { addContourLevel(level); setOverrideColor(level, overrideColor); } void JKQTPContourPlot::setOverrideColor(double level, QColor overrideColor) { contourOverrideColor[level]=overrideColor; } QColor JKQTPContourPlot::getOverrideColor(int level) const { if (level>=0 && level=0 && level=0 && level > &ContourLines) { #ifdef JKQTBP_AUTOTIMER JKQTPAutoOutputTimer jkaat(QString("JKQTPContourPlot::calcContourLines()")); #else qDebug()<<"JKQTPContourPlot::calcContourLines()"; #endif double scale=1; ///< scale of the contour levels; if(relativeLevels) { double min; double max; getDataMinMax(min,max); scale=1/(max-min); } enum Position { // the positions of points of one box // vertex 1 +-------------------+ vertex 2 // | \ / | // | \ m=3 / | // | \ / | // | \ / | // | m=2 X m=2 | the center is vertex 0 // | / \ | // | / \ | // | / m=1 \ | // | / \ | // vertex 4 +-------------------+ vertex 3 Center=0, TopLeft=1, TopRight=2, BottomRight=3, BottomLeft=4, NumPositions=5 }; for ( int yp = 0; yp < (int64_t)getNy() - 1; ++yp ) { // go through image (pixel coordinates) in row major order QVector vertices(NumPositions); for ( int xp = 0; xp < (int64_t)getNx() - 1; ++xp ) { if ( xp == 0 ) { vertices[TopRight].setX(xp); // will be used for TopLeft later vertices[TopRight].setY(yp); vertices[TopRight].setZ( getPixelValue( vertices[TopRight].x(), vertices[TopRight].y())*scale ); vertices[BottomRight].setX(xp); vertices[BottomRight].setY(yp+1); vertices[BottomRight].setZ( getPixelValue(vertices[BottomRight].x(), vertices[BottomRight].y())*scale ); } vertices[TopLeft] = vertices[TopRight]; // use right vertices of the last box as new left vertices vertices[BottomLeft] = vertices[BottomRight]; vertices[TopRight].setX(xp + 1); vertices[TopRight].setY(yp); // <---- vertices[TopRight].setZ( getPixelValue(vertices[TopRight].x(), vertices[TopRight].y())*scale ); vertices[BottomRight].setX(xp + 1); vertices[BottomRight].setY(yp + 1); vertices[BottomRight].setZ( getPixelValue(vertices[BottomRight].x(), vertices[BottomRight].y())*scale ); double zMin = vertices[TopLeft].z(); double zMax = zMin; double zSum = zMin; for ( int i = TopRight; i <= BottomLeft; ++i ) { const double z = vertices[i].z(); zSum += z; if ( z < zMin ) zMin = z; if ( z > zMax ) zMax = z; } if ( zMax >= contourLevels.first() && zMin <= contourLevels.last() ) { vertices[Center].setX(xp + 0.5); // pseudo pixel coordinates vertices[Center].setY(yp + 0.5); vertices[Center].setZ(0.25 * zSum); for (int levelIdx=0; levelIdx= zMin && contourLevels.at(levelIdx) <= zMax ) { QLineF line; QVector triangle(3); /* triangle[1] X / \ / \ / m \ / \ triangle[2] +-------------------+ triangle[0] */ for (int m = TopLeft; m < NumPositions; m++) { // construct triangles triangle[0] = vertices[m]; triangle[1] = vertices[Center]; triangle[2] = vertices[(m!=BottomLeft)?(m + 1):TopLeft]; const bool intersects =intersect(line, triangle.at(0),triangle.at(1),triangle.at(2), contourLevels.at(levelIdx)); if ( intersects ) { ContourLines[levelIdx]<imageColumn=imageColumn; this->datatype=JKQTPMathImageBase::DoubleArray; } JKQTPColumnContourPlot::JKQTPColumnContourPlot(JKQTPlotter *parent): JKQTPColumnContourPlot(parent->getPlotter()) { } void JKQTPColumnContourPlot::setImageColumn(int __value) { this->imageColumn = __value; if (parent && __value>=0 && parent->getDatastore()) { setNx(parent->getDatastore()->getColumnImageWidth(__value)); setNy(parent->getDatastore()->getColumnImageHeight(__value)); } } int JKQTPColumnContourPlot::getImageColumn() const { return this->imageColumn; } bool JKQTPColumnContourPlot::usesColumn(int c) const { return (c==imageColumn); } void JKQTPColumnContourPlot::ensureImageData() { if (this->Nx==0 || imageColumn<0 || !parent->getDatastore()->getColumnPointer(imageColumn,0)) { this->Ny=0; this->data=nullptr; this->datatype=JKQTPMathImageBase::DoubleArray; } else { this->datatype=JKQTPMathImageBase::DoubleArray; this->data=parent->getDatastore()->getColumnPointer(imageColumn,0); this->Ny=parent->getDatastore()->getRows(imageColumn)/this->Nx; } }