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# Fast way to get the bounding rectangle of a flood fill

I need to perform a flood fill on a region of an image. However I do not actually need the resulting image, I only need to know the smallest rectangle containing all pixels that would be changed by the flood fill.

Is there a variant of a flood fill algorithm that can compute this rectangle more cheaply than doing a full flood fill?

Example input and output (only the red rectangle is required):

Edit: Example #2 with islands:

Example #3:

Edit

Sorry, images were lost in a hard disk failure. When I first posted this, SO did not host images so I kept them on my own server.

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I find problems like this extremely interesting. We can determine instantly what the bounding rectangle is by looking at it, but it's very hard for us to nail down an algorithm. – Brian R. Bondy Feb 14 '10 at 15:53

Basically you need to determine biggestX, biggestY, smallestX, and smallestY.

Find the bottom right corner of the real edge:

You can do this by going as far right+down as possible inside your color.

When you can't go right+down anymore, then you need to check to make sure you aren't stuck in a corner of an island. To check for this you need to follow around the entire edge looking for a chance to go more right+down. You can keep track of (biggestX, biggestY, smallestX, smallestY) every time this happens in case you actually have your real edge.

If you actually do have an island, you will eventually find a place following the edge that you can go more right+down.

If you don't have a chance to go more right+down, and you reach your starting point, then you have your actual edge. And you have calculated your (biggestX, biggestY, smallestX, and smallestY).

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Sorry, but this fails for the example image; It will return the whole input image, because one of the corners will touch one or more neighbouring shapes on each pass. That's why I chose that image as an example. – finnw Feb 14 '10 at 14:25
I think you misunderstood my answer. You will visit EVERY pixel. "Continue to call this function until you have 0 neighbors of your color", although you for example stop calling the function on the right pixel, you will call it on the right pixel on all of the neighboring pixels. My method is not very efficient though since you will visit every pixel. – Brian R. Bondy Feb 14 '10 at 14:55
I updated my answer to a more efficient method. – Brian R. Bondy Feb 14 '10 at 15:13
How can you detect whether the edge you hit belongs to an island? – finnw Feb 14 '10 at 15:15
You detect whether it is an island or not by seeing if any point on the edge of what you hit has a more bottom+right spot (which is not bounding the edge) than what you currently have when you started the edge tracing. – Brian R. Bondy Feb 14 '10 at 15:21

One possible method would be to go as far (left,up,down.right) as you can from your starting point, then follow the edge clock-wise or counter-clockwise until you return to your first edge-point. Keep track of min(X,y) and max(X,Y) as you traverse the edge.

That ought to let you look at fewer pixels, unless you have rather odd shapes to fill.

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Interesting, but I think it will need modifying to work with my 2nd example, otherwise it will return a box containing one or more islands but not the whole region. – finnw Feb 14 '10 at 14:51
There may be thinkable shapes where it happens, but in the specific case of the second example, it should hit an "island", then turn and go to the border and then follow the border. – Vatine Feb 15 '10 at 14:44