# Convex Decomposition of a Complex Polygon?

With both my 2D physics system (box2D) and OpenGL, conplex polygons need to be decomposed into convex polygons. Ensuring models conform to this is easy. However, I would also like to edit the polygons as the simulation progresses, so I need a dynamic way of fracturing existing polygons into more polygons that are still convex.

I hope this drawing helps describe what I'm after:

My Question is, Is there an existing library that can accomplish this? And if not, what would be the least error prone way of doing it myself?

(I was looking through Boost, which has both a Geometry and a Polygon module, but the documentation is proving a little too esoteric for me to know if either can do what I want.)

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Definitely not understanding your equations--B - A should be that chunk of B which doesn't overlap A, and I don't know what A*B could possibly mean, certainly not how it could equal C3 –  Matt Phillips Oct 10 '11 at 3:23
@Matt - Sorry, my equations are backwards. A * B should find the intersection, and B - A should find the non-overlapping section of A. The operators themselves, I just threw in for the sake of needing operators, I'm not sure what the actual operator for this sort of thing would be. –  Clairvoire Oct 10 '11 at 3:42
Intersection is traditionally represented with an upside-down u shape, ^ is probably the best you can do with ascii. The non-overlapping section of A is A - B, which is precisely not B_A! Pretty confusing. Also, is a method for finding the vertices formed by the intersecting edges of A and B what you want? –  Matt Phillips Oct 10 '11 at 3:51
@Clairvoire I think you're looking for the intersection operator ∩. To do a difference you need a complement: B-A is B∩!A in set notation, and the intersection is just B∩A –  Ozzah Oct 10 '11 at 3:54
@Matt - I imagine it would be a part of it, but the main thing giving me trouble is finding the right existing vertices to connect them to, to form convex polygons –  Clairvoire Oct 10 '11 at 3:54

I think this is what you're looking for.

As for finding the intersection, that's just a little algebra; for any two line segments it's easy to derive the corresponding lines ('rise over run', etc.),

y = a1*x + b1

y = a2*x + b2

then the point of intersection (x', y') is

x' = (b2 - b1) / (a1 - a2)

y' = a1*x' + b1

Now of course that's the point of intersection of the lines, to determine that the line segments actually intersect you'll need to do simple range checking with the x, y coordinates.

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That is it! Thank you –  Clairvoire Oct 10 '11 at 4:13