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Lets say I've got two squares and I know their positions, a red and blue square:

redTopX;
redTopY;
redBotX;
redBotY;
blueTopX;
blueTopY;
blueBotX;
blueBotY;

Now, I want to check if square blue resides (partly) within (or around) square red. This can happen in a lot of situations, as you can see in this image I created to illustrate my situation better: alt text

Note that there's always only one blue and one red square, I just added multiple so I didn't have to redraw 18 times.

My original logic was simple, I'd check all corners of square blue and see if any of them are inside square red:

if (
((redTopX >= blueTopX) && (redTopY >= blueTopY) && (redTopX <= blueBotX) && (redTopY <= blueBotY)) || //top left
((redBotX >= blueTopX) && (redTopY >= blueTopY) && (redBotX <= blueBotX) && (redTopY <= blueBotY)) || //top right
((redTopX >= blueTopX) && (redBotY >= blueTopY) && (redTopX <= blueBotX) && (redBotY <= blueBotY)) || //bottom left
((redBotX >= blueTopX) && (redBotY >= blueTopY) && (redBotX <= blueBotX) && (redBotY <= blueBotY)) //bottom right
) {
    //blue resides in red
}

Unfortunately, there are a couple of flaws in this logic. For example, what if red surrounds blue (like in situation 1)?

I thought this would be pretty easy but am having trouble coming up with a good way of covering all these situations.. can anyone help me out here?

Regards, Tom

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possible duplicate of Determine if two rectangles overlap each other? –  Lance Roberts May 28 '10 at 16:46
    
@Lance: Yes, looks like it. –  Aryabhatta May 28 '10 at 16:51
    
Sorry, didn't know. –  Tom May 28 '10 at 17:08

6 Answers 6

up vote 6 down vote accepted

A test that checks whether red rectangle resides completely outside the blue rectangle looks as follows

bool outside = 
  redBotX > blueTopX || redTopX < blueBotX || 
  redBotY > blueTopY || redTopY < blueBotY;

Now, the negative of that will tell you whether red rectangle intersects the blue rectangle

bool intersects =
  !(redBotX > blueTopX || redTopX < blueBotX || 
    redBotY > blueTopY || redTopY < blueBotY);

If you wish, you can apply the De Morgan rule and rewrite it as

bool intersects =
  redBotX <= blueTopX && redTopX >= blueBotX && 
  redBotY <= blueTopY && redTopY >= blueBotY;

Of course, the above tests assume that the coordinates are "normalized*, i.e.

assert(redBotX <= redTopX && redBotY <= redTopY);
assert(blueBotX <= blueTopX && blueBotY <= blueTopY);

Also, the comparisons might be strict or non-strict depending on whether you consider touching rectangles as intersecting or not.

EDIT: I see that you use a different convention for rectangle coordinates: Top is the lower coordinate and Bot is the higher one, i.e.

assert(redTopX <= redBotX && redTopY <= redBotY);
assert(blueTopX <= blueBotX && blueTopY <= blueBotY);

To handle this case you just need to swap the Bot and Top coordinates in all conditions. For example, the last one will now look as follows

bool intersects =
  redTopX <= blueBotX && redBotX >= blueTopX && 
  redTopY <= blueBotY && redBotY >= blueTopY;
share|improve this answer
    
This is a great answer! –  Escualo May 28 '10 at 19:39
    
I mistakenly accepted your answer before testing it, it doesn't actually work. redBotX <= blueTopX for example fails on most of the situations shown in the image I created. –  Tom May 29 '10 at 9:16
    
(Since all the examples above need to return true, whether you look if red is inside blue or blue is inside red.) –  Tom May 29 '10 at 9:17
    
if (RectA.X1 < RectB.X2 && RectA.X2 > RectB.X1 && RectA.Y1 < RectB.Y2 && RectA.Y2 > RectB.Y1) does seem to work. –  Tom May 29 '10 at 9:30
    
@Tom: Everything in the answer works perfectly. The only thing is that in the answer I assumed different representation of a rectangle (I clearly stated it at the end - see the assertions). In my assumption Bot stands for minimum coordinate and Top stands for maximum. I.e. each rectangle is represented by its lower-left and upper-right corners. In your case it is lower-right and upper-left. If you insist on your representation, just update the comparisons (swap ...BotX and ...TopX everywhere). Although I'd say that your initial representation is rather... weird (why?). –  AnT May 29 '10 at 16:48

Assuming both squares are aligned, as you've indicated:

The squares intersect if all of the following hold:

  1. The left side of Red is left of the right side of Blue.
  2. The right side of Red is right of the left side of Blue.
  3. The top of Red is above the bottom of Blue.
  4. The bottom of Red is below the top of Blue.

(Convince yourself that this is true!)

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One formula for intersection of two rectangles would be

! ( (redTopX > blueBotX) || (blueTopX > redBotX) || (redTopY < blueBotY) || (blueTopY < redBotY))

You can use DeMorgan's Theorem to simplify.

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if (blueTopY < redBotY) return (0);
if (blueBotY > redTopY) return (0);
if (blueBotX < redTopX) return (0);
if (blueTopX > redBotX) return (0);
return (1); // there must clash
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for each blue corner:
  if corner is between all four red sides:
    return true
return false
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For higher-dimensional ranges or if you want to check a lot of ranges it might be worthwhile to store your ranges (e.g. their centers) in a R tree and search for it for where the corners of your range are.

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