# Calculating area of intersection of rectangles in java [duplicate]

I have a problem with one algorithm. I suppose to calculate the area of intersection of 2 rectangles(both are paraller to the OX and OY). The rectangle(let's call it A) is described by (x1,y1,x2,y2) upper left corner(x1,y1) and lower right corner (x2,y2), the secodn will be B (x3,y3,x4,y4). I thought about one algorithm but it seems lame.

``````if(all of the points of rectangle A are inside of rectangle B)
calculate(A);
else if(all of points the points of rectangle B are in A)
calculate(B);
else if(x1 y1 is inside rectangle B)
if(x1 is on the left from x3){
if(y1 is under the y3)
else
}
``````

etc. it will be so long and silly.

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## marked as duplicate by Denys Séguret, trashgod, Daniel Fischer, Anony-Mousse, Robert Harvey♦Oct 23 '12 at 19:27

Consider `java.awt.geom.Area`. – trashgod Oct 23 '12 at 18:14

Yes, it seems a bit inefficient, because as I think of, the problem is separable and can be extended to 3 or more dimensions.

It's sufficient to calculate the overlapping width in dimension x, and the overlapping height in dimension y and multiply those.

(In case the rectangle doesn't overlap in some dimension, then that value is 0)

Overlapping detection happens by comparing the min_x, max_x values of each rectangle:

`````` <------>  <------->   vs.  <-----> <----->
a      b  c       d        c     d a     b
Thus if b<=c OR a>=d, then no overlapping length = 0

<------------->   or   <------------->
a    <---->   b        a       <------------->
c    d                    c     b       d
+ the 2 symmetric cases (swap ab & cd)
``````

From the last rows the endpoint of the common area is minimum of d & b; The start point of the common area is the maximum of a & c.

Then the common area is min(d,b) - max (a,c) -- what if this is negative? Well, you've just checked the conditions at the first row...

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Yes I want to calculete this overlaping width and height but how I can do it? It is not said that they even overlap anywhere. – Yoda Oct 23 '12 at 18:49