# Easy Rotated Rectangle Collision

I'm making a game using LibGDX, but I have run into a problem concerning rectangle collision detection.

``````public class Rectangle{
final float width = 1f;
final float height = 0.5f;
Point topLeft;
Point topRight;
Point bottomRight;
Point bottomLeft;
//The point of rotation is the middle of the rectangle
float angle;
}

public class Point{
float x;
float y;
}
``````

Using this information (all these variables would be pre-calculated), I want to calculate if two rectangles are overlapping at all?

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"but I am not sure on how to continue with detecting the collision of them, and what I have searched so far has been very complicated." And ..what is your question? Be warned if it is "How to do Easy Rotated Rectangle Collision?" the answer is "hire someone". – Andrew Thompson Apr 14 '13 at 4:01
The 'easy' way is probably to check `Rectangle2D.contains(x,y)` for each of 4 x,y pairs representing the corners of the other rectangle. – Andrew Thompson Apr 14 '13 at 4:02
I don't believe that the Rectangle class has a way to angle the rectangle sadly. – cheifing Apr 14 '13 at 4:07
For better help sooner, post an SSCCE. – Andrew Thompson Apr 14 '13 at 4:20
Edited my post, hope it clears some stuff up. – cheifing Apr 14 '13 at 4:35

If two rectangles intersect, there will be a point inside one rectangle that is also inside the other rectangle.

You can consider each rectangle as four lines. To be inside the rectangle, a point has to be right of the left line, left of the right line, above the bottom line, and below the top line. So a rectangle can be represented as a system of four linear inequalities which has solutions.

If you combine the four linear inequalities of one rectangle with the four linear inequalities of the other rectangle into an eight-inequality system, the new system will have solutions only if the rectangles intersect.

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This was what I was originally thinking, but I would have thought it would be to long, I'll post the code in a sec. – cheifing Apr 15 '13 at 0:22

Here's what I ended up using, note that I didn't feel like optimizing the code at all, yet.

``````private boolean isColliding(Point p){
float countCol = 0f;
// BottomLeft - BottomRight
float slope = ((player.getBottomLeft().getY() - player.getBottomRight().getY()) / (player.getBottomLeft().getX() - player.getBottomRight().getX()));
float intercept = (player.getBottomLeft().getY() - (player.getBottomLeft().getX() * slope));

// BottomLeft - TopLeft
float slope2 = ((player.getBottomLeft().getY() - player.getTopLeft().getY()) / (player.getBottomLeft().getX() - player.getTopLeft().getX()));
float intercept2 = (player.getTopLeft().getY() - (player.getTopLeft().getX() * slope2));

// TopLeft - TopRight
float slope3 = ((player.getTopLeft().getY() - player.getTopRight().getY()) / (player.getTopLeft().getX() - player.getTopRight().getX()));
float intercept3 = (player.getTopRight().getY() - (player.getTopRight().getX() * slope3));

// TopRight - BottomRight
float slope4 = ((player.getTopRight().getY() - player.getBottomRight().getY()) / (player.getTopRight().getX() - player.getBottomRight().getX()));
float intercept4 = (player.getBottomRight().getY() - (player.getBottomRight().getX() * slope4));

// Between top and bottom
if(player.getAngle() > -90 && player.getAngle() < 90){
// BottomLeft - BottomRight
if(p.getX() * slope + intercept < p.getY()){
countCol += 1;
}

// TopLeft - TopRight
if(p.getX() * slope3 + intercept3 > p.getY()){
countCol += 1;
}
}
else{
// BottomLeft - BottomRight
if(p.getX() * slope + intercept > p.getY()){
countCol += 1;
}

// TopLeft - TopRight
if(p.getX() * slope3 + intercept3 < p.getY()){
countCol += 1;
}
}

// BottomLeft - TopLeft
if(player.getAngle() < 0){
if(p.getX() * slope2 + intercept2 > p.getY()){
countCol += 1;
}
if(p.getX() * slope4 + intercept4 < p.getY()){
countCol += 1;
}
}
else{
if(p.getX() * slope2 + intercept2 < p.getY()){
countCol += 1;
}
if(p.getX() * slope4 + intercept4 > p.getY()){
countCol += 1;
}
}

if(countCol >= 4){
return true;
}
return false;
}
``````
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