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Imagine a plain rectangular bitmap of, say, 1024x768 pixels filled with white. There are a few (non-overlapping) sprites drawn onto the bitmap: circles, squares and triangles.

Is there an algorithm (possibly even a C++ implementation) which, given the bitmap and the color which is the background color (white, in the above example), yields a list containing the smallest bounding rectangles for each of the sprites?

Here's some sample: On the left side you can see a sample bitmap which my code is given (together with the information that the 'background' is white). On the right side you can see the same image together with the bounding rectangles of the four shapes (in red); the algorithm I'm looking for computes the geometry of these rectangles.

Input picture Output picture

Some painting programs have a similiar feature for selecting shapes: they can even compute seemingly arbitrary bounding polygons. Instead of dragging a selection rectangle manually, you can click the 'background' (what's background and what's not is determined by some threshold) and then the tool automatically computes the shape of the object drawn onto the background. I need something like this, except that I'm perfectly fine if I just have the rectangular bounding areas for objects.

I became aware of OpenCV; it appears to be relevant (it seems to be a library which includes every graphics algorithm I can think of - and then some) but in the fast amount of information I couldn't find the way to the algorithm I'm thinking of. I would be surprised if OpenCV couldn't do this, but I fear you've got to have a PhD to use it. :-)

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Are you talking about edge detection? –  FailedDev Dec 14 '11 at 22:43
@FailedDev: Not quite; I don't know the proper terminology, but googling for 'edge detection' suggests that it finds the borders at which e.g. the brightness changes sharply. I basically only need to find the 'outermost' border. –  Frerich Raabe Dec 14 '11 at 22:53
A picture would serve 100 words here - sketch what is the situation and what do you want out of it. I can guess, but with picture, it would be much better... –  Daniel Mošmondor Dec 14 '11 at 22:59
like this: imageshack.us/photo/my-images/209/selectg.png, where it drew a box around the red circle? –  TBohne Dec 14 '11 at 23:17
@DanielMošmondor: I guess you're right. I now added two pictures, showing a sample input bitmap and then the same including the (red) bounding rectangles; the algorithm I'm looking for can compute the geometry of these rectangles. –  Frerich Raabe Dec 14 '11 at 23:23

2 Answers 2

up vote 2 down vote accepted

Here is the great article on the subject:


I think that PhD is not required here :)

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These are my first thoughts, none complicated, except for the edge detection

For each square, 
   if it's not-white
       mark as "found"
       if you havn't found one next to it already
           add it to points list
for each point in the points list
    use basic edge detection to find outline
    keep track of bounds while doing so
    add bounds to shapes list
remove duplicates from shapes list. (this can happen for concave shapes)

I just realized this will consider white "holes" (like in your leftmost circle in your sample) to be it's own shape. If the first "loop" is a flood fill, it doesn't have this problem, but will be much slower/take much more memory.

The basic edge detection I was thinking of was simple:

given eight cardinal directions left, downleft, etc...
given two relative directions cw(direction-1) and ccw(direction+1)
starting with a point "begin"
set bounds to point
find direction d, where the begin+d is not white, and begin+cw(d) is white.
set current to begin+d
    if current is outside of bounds, increase bounds
    set d = cw(d)
    while(cur+d is white or cur+ccw(d) is not white)
        d = ccw(d)
    cur = cur + d;
while(cur != begin


There's a quite a few edge cases not considered here: what if begin is a single point, what if it runs to the edge of the picture, what if start point is only 1 px wide, but has blobs to two sides, probably others... But the basic algorithm isn't that complicated.

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I don't even think you need the edge detection. Just look for all non-white pixels neighboring ones that you've found. Once you don't have any more pixels to test, return the bounding box of that shape that you've just traversed. –  David Brigada Dec 15 '11 at 2:17
Edge detection will be slightly faster, and easier to code than the flood fill to find all non-white. –  TBohne Dec 15 '11 at 5:57
+1 Interesting idea! Do you have some particular edge detection algorithm in mind when you write basic edge detection? –  Frerich Raabe Dec 15 '11 at 9:12
@FrerichRaabe: Updated answer with a nieve edge detection algorithm. –  TBohne Dec 15 '11 at 21:01

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