Simple Plotting Library for C++
This is a simple plotting library that I wrote mostly for myself in C++. The Purpose of it is to be a light header-only library to allow easy plotting in C++.
The Code has been tested on Linux Ubuntu 16.04 with C++11. You should be able to replicate the results yourself just by pulling the repository and compiling the plot.cpp file.
Note: The images are all saved as .ppm files.
Example plots:
Example Code:
int main(){
setHeight(1024);
setWidth(1024);
vector< vector<int> > testLine = {{0,0},{1,2},{2,4},{4,8},{8,16}}; // y = x*2
vector< vector<int> > testLineWeird = {{0,0},{1,2},{2,4},{4,3},{8,16}};
vector< vector<int> > testPoints = {{0,0}, {5,5}, {1,6}, {3,2}, {1,2}, {3,4}, {2,3}, {2,2}, {3,3}, {5,2}, {7,8}};
vector< vector<int> > parabola;
for(int i = 0; i <= 100; i++)parabola.push_back({i, i*i});
// In order to make a plot we need to put each one of our parameters in a vector. So that we can plot multiple
// point groups with different colors as well as get a bit more flexibility
// Here are some quick examples
plotPoints("selectionDotWithGrid.ppm", vector< vector< vector<int> > >{testPoints}, 0, 1, 7, vector<Color>{Color(60,10,255)}, vector<string>{"*"});
plotPoints("selectionCrossWithGrid.ppm", vector< vector< vector<int> > >{testPoints}, 0, 1, 7, vector<Color>{Color(60,10,255)}, vector<string>{"+"});
plotLine("testLinePlotParabola.ppm", vector< vector< vector<int> > >{parabola}, 0, 1, 1, vector<Color>{Color(60,10,255)});
plotPoints("groupPointPlot.ppm", vector< vector< vector<int> > >{testPoints, testLineWeird}, 0, 1, 6, vector<Color>{Color(60,10,255), Color(255,10,60)}, vector<string>{"*","*"});
}Plotting the Iris Dataset:
#include <bits/stdc++.h>
#include "plot.h"
using namespace std;
/*
1. sepal length in cm
2. sepal width in cm
3. petal length in cm
4. petal width in cm
5. class:
Iris-setosa --> 0
Iris-versicolor --> 1
Iris-virginica --> 2
*/
int main(){
// Create containers to store each class
//50 samples for each class. Each one with 4 Features + class Label
vector< vector<double> > Iris_setosa(50, vector<double>(5));
vector< vector<double> > Iris_versicolor(50, vector<double>(5));
vector< vector<double> > Iris_virginica(50, vector<double>(5));
// Choose colors to represent each class
Color setosaColor(60,20,180);
Color versicolorColor(180,20,60);
Color virginicaColor(20,180,60);
// Read data to stdin
freopen("iris.data", "r", stdin); // Read data to stdin
// Fill each container
// 150 train samples
for(int sample = 0; sample < 150; sample++){
// 4 Features + Class Label
for(int feature = 0; feature < 5; feature++){
if(sample<50)cin >> Iris_setosa[sample][feature];
else if(sample<100)cin >> Iris_versicolor[sample%50][feature];
else if(sample<150)cin >> Iris_virginica[sample%100][feature];
}
}
// Set Width and height of plot
setHeight(512);
setWidth(512+256);
// In this tutorial we will be plotting the "petal length" against the "sepal length" for each sample
// First since we are creating a GroupPlot let's add our colors, symbols and data into containers
vector< vector< vector<double> > > plotData = {Iris_setosa, Iris_versicolor, Iris_virginica};
vector<Color> colors = {setosaColor, versicolorColor, virginicaColor};
vector<string> symbols = {"*","*","*"};
// Now let's plot the graph
// Filename, DataVector, xAxis, yAxis, dotSize, colorVector, Symbols
plotPoints("Iris.PetalLength.SepalLength.ppm", plotData, 0, 2, 4, colors, symbols);
}Panagiotis Petridis, High School Student
Greece
If you have an opening in your team be sure to shoot me an email!