This is a half programming, half math question.

I've got some boxes, which are represented as four corner points. They are true rectangles, the intersections of two sets of parallel lines, with every line in each set at a right angle to both lines in the other set (just so we're clear.)

For any set of n boxes, how can I efficiently calculate where to move them (the least distance) so that they do not overlap each other?

I'm working in javascript here. Here's the data:

//an array of indefinite length of boxes
//boxes represented as arrays of four points
//points represented as arrays of two things, an x and a y, measured in
//pixels from the upper left corner

var boxes = [[[504.36100124308336,110.58685958804978],[916.3610012430834,110.58685958804978],[916.3610012430834,149.58685958804978],[504.36100124308336,149.58685958804978]],[[504.4114378910622,312.3334473005064],[554.4114378910622,312.3334473005064],[554.4114378910622,396.3334473005064],[504.4114378910622,396.3334473005064]],[[479.4272869132357,343.82042608058134],[516.4272869132358,343.82042608058134],[516.4272869132358,427.82042608058134],[479.4272869132357,427.82042608058134]],[[345.0558946408693,400.12499171846],[632.0558946408694,400.12499171846],[632.0558946408694,439.12499171846],[345.0558946408693,439.12499171846]],[[164.54073131913765,374.02074227992966],[264.54073131913765,374.02074227992966],[264.54073131913765,428.02074227992966],[164.54073131913765,428.02074227992966]],[[89.76601656567325,257.7956256799442],[176.76601656567325,257.7956256799442],[176.76601656567325,311.7956256799442],[89.76601656567325,311.7956256799442]],[[60.711850703535845,103.10558195262593],[185.71185070353584,103.10558195262593],[185.71185070353584,157.10558195262593],[60.711850703535845,157.10558195262593]],[[169.5240557746245,23.743626531766495],[231.5240557746245,23.743626531766495],[231.5240557746245,92.7436265317665],[169.5240557746245,92.7436265317665]],[[241.6776988694169,24.30106373152889],[278.6776988694169,24.30106373152889],[278.6776988694169,63.30106373152889],[241.6776988694169,63.30106373152889]],[[272.7734457459479,15.53275710947554],[305.7734457459479,15.53275710947554],[305.7734457459479,54.53275710947554],[272.7734457459479,54.53275710947554]],[[304.2905062327675,-3.9599943474960035],[341.2905062327675,-3.9599943474960035],[341.2905062327675,50.04000565250399],[304.2905062327675,50.04000565250399]],[[334.86335590542114,12.526345270766143],[367.86335590542114,12.526345270766143],[367.86335590542114,51.52634527076614],[334.86335590542114,51.52634527076614]],[[504.36100124308336,110.58685958804978],[916.3610012430834,110.58685958804978],[916.3610012430834,149.58685958804978],[504.36100124308336,149.58685958804978]],[[504.4114378910622,312.3334473005064],[554.4114378910622,312.3334473005064],[554.4114378910622,396.3334473005064],[504.4114378910622,396.3334473005064]],[[479.4272869132357,343.82042608058134],[516.4272869132358,343.82042608058134],[516.4272869132358,427.82042608058134],[479.4272869132357,427.82042608058134]],[[345.0558946408693,400.12499171846],[632.0558946408694,400.12499171846],[632.0558946408694,439.12499171846],[345.0558946408693,439.12499171846]],[[164.54073131913765,374.02074227992966],[264.54073131913765,374.02074227992966],[264.54073131913765,428.02074227992966],[164.54073131913765,428.02074227992966]],[[89.76601656567325,257.7956256799442],[176.76601656567325,257.7956256799442],[176.76601656567325,311.7956256799442],[89.76601656567325,311.7956256799442]],[[60.711850703535845,103.10558195262593],[185.71185070353584,103.10558195262593],[185.71185070353584,157.10558195262593],[60.711850703535845,157.10558195262593]],[[169.5240557746245,23.743626531766495],[231.5240557746245,23.743626531766495],[231.5240557746245,92.7436265317665],[169.5240557746245,92.7436265317665]],[[241.6776988694169,24.30106373152889],[278.6776988694169,24.30106373152889],[278.6776988694169,63.30106373152889],[241.6776988694169,63.30106373152889]],[[272.7734457459479,15.53275710947554],[305.7734457459479,15.53275710947554],[305.7734457459479,54.53275710947554],[272.7734457459479,54.53275710947554]],[[304.2905062327675,-3.9599943474960035],[341.2905062327675,-3.9599943474960035],[341.2905062327675,50.04000565250399],[304.2905062327675,50.04000565250399]],[[334.86335590542114,12.526345270766143],[367.86335590542114,12.526345270766143],[367.86335590542114,51.52634527076614],[334.86335590542114,51.52634527076614]]]

This fiddle shows the boxes drawn on a canvas semi-transparently for clarity.

  • are the two boxes axis-aligned? Commented Jul 19, 2011 at 16:11
  • 1
    For simplicity, say the boxes are all aligned parallel to the x and y axes (with origin in the upper left). The fiddle is sample data, entirely usable, for testing solutions. No, it's not homework. It's curiosity.
    – Mario
    Commented Jul 19, 2011 at 16:13
  • 1
    Use it. It's a set of data. I could have provided no data, would you have preferred that? The comment above the variable explains the exact content of the variable.
    – Mario
    Commented Jul 19, 2011 at 16:18
  • 1
    @Mario - The thing that's useless about the fiddle is that you could have just included that data in your question.
    – Wayne
    Commented Jul 19, 2011 at 16:21
  • 2
    I suspect that an exact solution to this problem is NP-hard Commented Jul 19, 2011 at 17:01

3 Answers 3


You could use a greedy algorithm. It will be far from optimal, but may be "good enough". Here is a sketch:

 1 Sort the rectangles by the x-axis, topmost first. (n log n)
 2 for each rectangle r1, top to bottom
       //check for intersections with the rectangles below it.
       // you only have to check the first few b/c they are sorted 
 3     for every other rectangle r2 that might intersect with it 
 4         if r1 and r2 intersect //this part is easy, see @Jose's answer
 5             left = the amount needed to resolve the collision by moving r2 left
 6             right = the amount needed to resolve the collision by moving r2 right
 7             down = the amount needed to resolve the collision by moving r2 down

 8             move r2 according to the minimum value of (left, right down)
               // (this may create new collisions, they will be resolved in later steps)
 9         end if

10     end
11 end

Note step 8 could create a new collision with a prior rectangle, which wouldn't be resolved properly. Hm. You may need to carry around some metadata about previous rectangles to avoid this. Thinking...

  • Yes that is what I was talking about. I used to avoid that problem by updating the positions only virtually, this way you can share the movement needed to touch between each intersecting rectangle (depending on their speed) when you checked them all, so that they are always moving, otherwise you may find only one moving.
    – Jose Faeti
    Commented Jul 19, 2011 at 18:25
  • are you also involved in game programming? :) personally, I never liked to resolve the collision problems later, I prefer to do a better collision checking from the start (code speed permitting).
    – Jose Faeti
    Commented Jul 19, 2011 at 18:27
  • @Jose no, I don't do game programming Commented Jul 19, 2011 at 21:29

Keep in mind the box model, given any two rectangles you have to calculate the two boxes width and height, adding their respective margins, paddings, and borders (add the left/right of them to detect collision on the x axis, and top/bottom to detect collision on the y axis), then you can calculate the distance between element 1 and 2 adding the result to their respective coordinate position, for example ((positionX2+totalWidth2) - (positionX1+totalWidth1)) to calculate collision along the X axis. If it is negative, they are overlapping. Once you know this, if they won't overlap by moving them, you can move them normally, otherwise you have to subtract the amount of space they are overlapping from the value you want to move them.

Since the environment is a 2D plane, this should be pretty straightforward. With a library such as jQuery would be a joke, but even in plain js is just basic addiction and subtraction.

  • 1
    Calculating intersections is easy, but optimally deciding how to move the rectangles is not. Commented Jul 19, 2011 at 17:02
  • What do you mean by optimally? The user asked for how to calculate the least distance to move them, I always did it like this. Once you have elements coordinates and their size, by knowing the distance between them (both along the X and Y axis) you automatically know by how much you can move them.
    – Jose Faeti
    Commented Jul 19, 2011 at 17:13
  • 1
    For 2 boxes, sure. But there are n boxes. How do you know that in fixing one collision you are not creating another? Commented Jul 19, 2011 at 17:22
  • Because the user asked "For any two boxes, how can I efficiently calculate where to move them (the least distance) so that they do not overlap each other?". Anyway, in video games programming for example the basic way to do it is to take into consideration every single box at once, and for every one of them you check the collision with the others. Then there are more efficient and complex way, expecially for 3D environments, but I doubt this is what the user is looking for.
    – Jose Faeti
    Commented Jul 19, 2011 at 17:26
  • fixed. Set of n, I meant to say. I was thinking of doing it by iterating through each box and resolving collisions with all previous boxes before moving on.
    – Mario
    Commented Jul 19, 2011 at 17:28

Assuming the boxes are aligned to the x and y axis as in your comment, first I'd change the representation of each rectangle to 4 points: top, right, bottom, left and store them as points on the rectangle. Second, let's simplify the problem to "Given n rectangles, where is the nearest point where rectangle r can move to so that it doesn't overlap any other rectangles"? That simplifies the problem a great deal, but also should provide a decent solution. Thus, we have our function:

function deOverlapTheHonkOuttaTheRectangle(rectangle, otherRectangles){

Now, each other rectangle will disallow a certain range of motion for the original rectangle. Thus, you calculate all of these disallowed moves. From these, you can calculate the disallow shape that overlaps the origin and each other. For example, lets say rect1 disallows a shift of -3px to 5px right and 4px to 10px up, and rect2 disallows -4px to 1px right and -2px to 5px up. rect1 was not considered until rect2 came along, since that one overlaps the origin and rect1. Starting with rect2, you'd have [[-4, -2],[1,-2],[1,5],[-4,5]]. Figuring in rect1 gives [[-4, -2],[1,-2],[1,4],[5,4],[5,10],[-3,10],[-3,5],[-4,5]] (see image below for clarification). You keep building these up for each overlapping disallowed rectangle. Once you have considered all the rectangles, then you can use a distance formula from the origin to get the smallest distance you can move your rectangle and move it.

Disallowed Moves

Finally, you repeat this process for all remaining rectangles.

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