# Pythagoras tree with g2d

I'm trying to build my first fractal (Pythagoras Tree):

in Java using Graphics2D. Here's what I have now :

``````import java.awt.*;
import java.awt.geom.*;
import javax.swing.*;
import java.util.Scanner;

public class Main {

public static void main(String[] args) {

int i=0;
Scanner scanner = new Scanner(System.in);

System.out.println("Give amount of steps: ");
i = scanner.nextInt();

new Pitagoras(i);
}
}

class Pitagoras extends JFrame {

private int powt, counter;

public Pitagoras(int i) {
super("Pythagoras Tree.");
setSize(1000, 1000);
setDefaultCloseOperation(JFrame.EXIT_ON_CLOSE);
setVisible(true);
powt = i;
}

private void paintIt(Graphics2D g) {

double p1=450, p2=800, size=200;

for (int i = 0; i < powt; i++) {
if (i == 0) {
g.drawRect((int)p1, (int)p2, (int)size, (int)size);
counter++;
}
else{
if( i%2 == 0){
//here I must draw two squares
}
else{
//here I must draw right triangle
}
}
}
}

@Override
public void paint(Graphics graph) {

Graphics2D g = (Graphics2D)graph;
paintIt(g);

}
``````

So basically I set number of steps, and then draw first square (p1, p2 and size). Then if step is odd I need to build right triangle on the top of square. If step is even I need to build two squares on free sides of the triangle. What method should I choose now for drawing both triangle and squares ? I was thinking about drawing triangle with simple lines transforming them with AffineTransform but I'm not sure if it's doable and it doesn't solve drawing squares.

-

You do not have to draw triangles, only squares (the edges of the squares are the triangle) in this tree.

You can make things a lot easier looking into recursion (these types of fractals are standard examples for recursion):

In Pseudo-Code

``````drawSquare(coordinates) {
// Check break condition (e.g. if square is very small)
// Calculate coordinates{1|2} of squares on top of this square -> Pythagoras
drawSquare(coordinates1)
drawSquare(coordinates2)
}
``````

And since I often programmed fractals, a hint: Draw the fractal itself in a BufferedImage and only paint the image in the paint-method. The paint-Method gets called possibly several times per second, so it must be faaaaast.

Also do not directly draw in a JFrame but use a Canvas (if you want to use awt) or a JPanel (if you use swing).

-
the problem with recursion is that at some depth in the fractal you're going to run out of stack space. So while elegant, it's probably impractical here. –  Stefan Monov May 22 '10 at 17:19
Well, in this case you would run out of space no matter which data structure you use. –  Searles May 26 '10 at 20:49
good point, I'm stupid. –  Stefan Monov Jul 6 '10 at 18:59

My final solution :

``````import java.awt.*;
import java.util.Scanner;
import javax.swing.*;

public class Main extends JFrame {;

public Main(int n) {
setSize(900, 900);
setTitle("Pythagoras tree");
setDefaultCloseOperation(JFrame.EXIT_ON_CLOSE);
setVisible(true);
}

public static void main(String[] args) {
Scanner sc = new Scanner(System.in);
System.out.print("Give amount of steps: ");
new Main(sc.nextInt());
}
}

class Draw extends JComponent {
private int height = 800;
private int width = 800;
private int steps;

public Draw(int n) {
steps = n;

Dimension d = new Dimension(width, height);
setMinimumSize(d);
setPreferredSize(d);
setMaximumSize(d);
}

@Override
public void paintComponent(Graphics g) {
super.paintComponent(g);
g.setColor(Color.white);
g.fillRect(0, 0, width, height);
g.setColor(Color.black);

int x1, x2, x3, y1, y2, y3;
int base = width/7;

x1 = (width/2)-(base/2);
x2 = (width/2)+(base/2);
x3 = width/2;
y1 = (height-(height/15))-base;
y2 = height-(height/15);
y3 = (height-(height/15))-(base+(base/2));

g.drawPolygon(new int[]{x1, x1, x2, x2, x1}, new int[]{y1, y2, y2, y1, y1}, 5);

int n1 = steps;
if(--n1 > 0){
g.drawPolygon(new int[] {x1, x3, x2}, new int[] {y1, y3, y1}, 3);
paintMore(n1, g, x1, x3, x2, y1, y3, y1);
paintMore(n1, g, x2, x3, x1, y1, y3, y1);
}
}

public void paintMore(int n1, Graphics g, double x1_1, double x2_1, double x3_1, double y1_1, double y2_1, double y3_1){
int x1, x2, x3, y1, y2, y3;

x1 = (int)(x1_1 + (x2_1-x3_1));
x2 = (int)(x2_1 + (x2_1-x3_1));
x3 = (int)(((x2_1 + (x2_1-x3_1)) + ((x2_1-x3_1)/2)) + ((x1_1-x2_1)/2));
y1 = (int)(y1_1 + (y2_1-y3_1));
y2 = (int)(y2_1 + (y2_1-y3_1));
y3 = (int)(((y1_1 + (y2_1-y3_1)) + ((y2_1-y1_1)/2)) + ((y2_1-y3_1)/2));

g.setColor(Color.green);
g.drawPolygon(new int[] {x1, x2, (int)x2_1, x1}, new int[] {y1, y2, (int)y2_1, y1}, 4);
g.drawLine((int)x1, (int)y1, (int)x1_1, (int)y1_1);
g.drawLine((int)x2_1, (int)y2_1, (int)x2, (int)y2);
g.drawLine((int)x1, (int)y1, (int)x2, (int)y2);

if(--n1 > 0){
g.drawLine((int)x1, (int)y1, (int)x3, (int)y3);
g.drawLine((int)x2, (int)y2, (int)x3, (int)y3);
paintMore(n1, g, x1, x3, x2, y1, y3, y2);
paintMore(n1, g, x2, x3, x1, y2, y3, y1);
}
}
}
``````
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