# Example (JKQTPlotter): Scatter Graph with Parametrized Symbols/Colors {#JKQTPlotterParamScatter} This project (see `./examples/simpletest_paramscatterplot/`) demonstrates the capabilities of `JKQTPXYParametrizedScatterGraph`. This graph class plots symbol&line-graphs, juts like [`JKQTPXYLineGraph`](https://github.com/jkriege2/JKQtPlotter/tree/master/examples/simpletest_symbols_and_styles/) and in addition modifies several properties of each plot point by data from an additional column. These properties can be modified: - symbol size - symbol type - symbol/line color - line width The source code of the main application can be found in [`jkqtplotter_simpletest_paramscatterplot.cpp`](https://github.com/jkriege2/JKQtPlotter/tree/master/examples/simpletest_paramscatterplot/jkqtplotter_simpletest_paramscatterplot.cpp). First, several datasets are generated and added to the internal datastore. the resulting datatable looks like this: ![jkqtplotter_simpletest_paramscatterplot](https://raw.githubusercontent.com/jkriege2/JKQtPlotter/master/screenshots/jkqtplotter_simpletest_paramscatterplot_datatable.png) Then several plots are added that modify different properties. The simplest case is to modify the symbol type. Simply set the property `symbolColumn` with `graph1->setSymbolColumn(columnP)` to a data column. The values in the data column will be cast to an integer and then will be translated to `JKQTPGraphSymbols`. If the numbers are larger than the available symbol types in `JKQTPGraphSymbols`, the graph will cycle through the available symbols (via a modulo-operation with the max. symbol count!). ```.cpp JKQTPXYParametrizedScatterGraph* graph1=new JKQTPXYParametrizedScatterGraph(&plot); graph1->setXColumn(columnX); graph1->setYColumn(columnY1); graph1->setSymbolColumn(columnP); graph1->setDrawLine(true); graph1->setColor(QColor("blueviolet")); graph1->setTitle("1: symbol type"); plot.addGraph(graph1); ``` The next two code snippets show how to modify the size of the symbols and the line width of the lines, connecting the symbols (ensure to set `graph6->setDrawLine(true)`, because otherwise no line will be drawn). The principle is the same as above, but here you need to set the properties `sizeColumn` for the symbol size and `linewidthColumn` for the line width. All values in the line width or symbol size columns are interpreted as sizes in dtp points (pt)! ```.cpp // symbol size JKQTPXYParametrizedScatterGraph* graph3=new JKQTPXYParametrizedScatterGraph(&plot); graph3->setXColumn(columnX); graph3->setYColumn(columnY3); graph3->setSizeColumn(columnS); graph3->setSymbolType(JKQTPFilledCircle); graph3->setDrawLine(true); graph3->setTitle("3: symbol size"); plot.addGraph(graph3); // line width JKQTPXYParametrizedScatterGraph* graph6=new JKQTPXYParametrizedScatterGraph(&plot); graph6->setXColumn(columnX); graph6->setYColumn(columnY6); graph6->setLinewidthColumn(columnLW); graph6->setDrawLine(true); graph6->setSymbolType(JKQTPNoSymbol); graph6->setTitle("6: line width"); plot.addGraph(graph6); ``` Finally you can set the color of each symbol, based on data in the column `colorColumn`. Here two possibilities exist: First you can store the RGB(A) value for each datapoint explicitly. For this, you first need to create the data in the column, using the Qt-function [`qRgb()`](http://doc.qt.io/qt-5/qcolor.html#qRgb) or [`qRgba()`}(http://doc.qt.io/qt-5/qcolor.html#qRgba): ```.cpp QVector RGB; const int Ndata=10; // number of plot points in each curve for (int i=0; iaddCopiedColumn(RGB, "rgb"); ```.cpp Basically the data points in a RGB(A)-column will be interpreted by castig them to [`QRgb`](http://doc.qt.io/qt-5/qcolor.html#QRgb-typedef). Now you can add the graph. In order to interpret the color column as RGB(A)-values, ensure to set `graph4->setColorColumnContainsRGB(true)`: ```.cpp JKQTPXYParametrizedScatterGraph* graph4=new JKQTPXYParametrizedScatterGraph(&plot); graph4->setXColumn(columnX); graph4->setYColumn(columnY4); graph4->setColorColumn(columnRGB); graph4->setColorColumnContainsRGB(true); graph4->setDrawLine(true); graph4->setSymbolType(JKQTPFilledDownTriangle); graph4->setTitle("4: RGB-color"); plot.addGraph(graph4); ``` The second variant for setting the color of each datapoint is by mapping the values in the column to a color palette (`JKQTPMathImageRYGB` in this example). For this you simply need to define the color coumn and the palette to use. By default, the color palette spans the full range of values in `colorColumn`: ```.cpp JKQTPXYParametrizedScatterGraph* graph2=new JKQTPXYParametrizedScatterGraph(&plot); graph2->setXColumn(columnX); graph2->setYColumn(columnY2); graph2->setColorColumn(columnC); graph2->setPalette(JKQTPMathImageRYGB); graph2->setSymbolType(JKQTPFilledRect); graph2->setDrawLine(true); graph2->setTitle("2: color"); graph2->getColorBarRightAxis()->setAxisLabel("color scale for graph2"); plot.addGraph(graph2); ``` Note: If you want to set the range manually, use `ste_imageMin()` and `setImageMax()` after setting `setAutoImageRange(false)`. Note also that it is possible to combine any of parametrizations above in a single graph, by setting two or more columns: ```.cpp JKQTPXYParametrizedScatterGraph* graph5=new JKQTPXYParametrizedScatterGraph(&plot); graph5->setXColumn(columnX); graph5->setYColumn(columnY5); graph5->setColorColumn(columnC); graph5->setSizeColumn(columnS); graph5->setPalette(JKQTPMathImageBLUEYELLOW); graph5->setDrawLine(true); graph5->setTitle("5: color+size"); graph5->getColorBarRightAxis()->setAxisLabel("color scale for graph5"); plot.addGraph(graph5); ``` The full test appication combines all these variants and the result looks like this: ![jkqtplotter_simpletest_paramscatterplot](https://raw.githubusercontent.com/jkriege2/JKQtPlotter/master/screenshots/jkqtplotter_simpletest_paramscatterplot.png) In `` you can also set special functors that transform the values from the data columns (symbol type+size, datapoint), before using them for the plot, which gives you even more control. As an example you can set a special functor to `graph6`: ```.cpp graph6->setLinewidthColumnFunctor([](double x, double y, double w) { return fabs(sin(w/3.0)*25.0); }); ``` This will result in modulated linewidths as shown below: ![JKQTPXYParametrizedScatterGraph_LinewidthFunctor.png](https://raw.githubusercontent.com/jkriege2/JKQtPlotter/master/doc/images/JKQTPXYParametrizedScatterGraph_LinewidthFunctor.png) The same can be done for symbol type, e.g. with code like this: ```.cpp graph1->setSymbolColumnFunctor([](double x, double y, double sym) -> JKQTPGraphSymbols { if (symNdata/2) { return JKQTPGraphSymbols::JKQTPFilledCircle; } else { return JKQTPGraphSymbols::JKQTPPlus; } }); ``` This will result in symbols as shown below: ![JKQTPXYParametrizedScatterGraph_SymbolFunctor.png](https://raw.githubusercontent.com/jkriege2/JKQtPlotter/master/doc/images/JKQTPXYParametrizedScatterGraph_SymbolFunctor.png) As an alternaitve for symbols, you can define the functor also in terms of a QMap: ```.cpp graph1->setSymbolColumnFunctor([](double x, double y, double sym) -> JKQTPGraphSymbols { if (symNdata/2) { return JKQTPGraphSymbols::JKQTPFilledCircle; } else { return JKQTPGraphSymbols::JKQTPPlus; } }); ``` This will result in symbols as shown below: ![JKQTPXYParametrizedScatterGraph_MappedSymbolFunctor.png](https://raw.githubusercontent.com/jkriege2/JKQtPlotter/master/doc/images/JKQTPXYParametrizedScatterGraph_MappedSymbolFunctor.png)