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I'm looking for an algorithm that can cut a shape with holes into shapes without holes. Language is preferably C#.

Here's an example image of such a shape. original shape

I'd like to cut that shape into the least amount of smaller shapes without holes getting rid of most of the empty space (white). In this case this might probabyl be a bunch of rectangles. But the original shape might be more complex with rounded holes for example.

For me this sounds like some sort of a bin packing problem and therefore might be solved best with a genetical algorithm.

But in case you know a better approach, it's why I ask.

//edit: alright, I've obviously got some things to explain:

  1. The shape is a Geometry object (WPF) resulting from the subtraction of a bunch of small Geometries from a larger Geometry. So I guess there are vertex points stored somewhere.

  2. The amount of resulting shapes should be minimized, yes, the smallest set.

  3. The resulting shapes should have edges that are as straight as possible with the smallest amount of corners possible.

  4. Unfortunately, I can't provide any code, yet, since I have no clou whatsoever how to practically approach this programmatically. I'm really sorry.

  5. The resulting shapes should be complex but don't have to.

To explain the reason for this: I'm working on a textile crafting (in particular patchworking) program with which one can create patchworks and calculate how much fabric is needed and the cost. Placing the patches on the fabric panel already works somehow using a Tetris like algorithm where patches get placed as close together as possible to reduce waste.

Additionally, everywhere the shape gets cut I need to add a seam allowance to the resulting parts (that's what you can already see in green in the example image).

//edit 2 An acceptable solution might look as follows. Red lines show where shape gets cut in order to get an amount of resulting shapes that don't have holes. The result set contains six large and 25 small rectangles:

red lines show where shape gets cut

However depending on the original shape which might look totally different, even with rounded edges (circular holes), acceptable solutions also might look different. The goal is to get rid of the white areas as far as possible while maintaining some convenience regarding the later actual cutting of the fabric. It'd be somehow counter-productive to have lots of shred that has to be sewed together again (and hence all need seam allowances) only to save a little bit fabric more.

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A lot of this is going to depend on how the "shape" is currently defined. Is it an image? A collection of points? –  user7116 Jul 30 '13 at 15:07
Does the resulting group of shapes need to be a smallest set? Or is any number of shapes acceptable? Additionally, does the algorithm need to be able to handle shapes with curves and non 90 degree angles? –  Luke Willis Jul 30 '13 at 15:11
Please provide some code you've attempted and a set of more rigorous definitions and conditions. I think that would answer the comments' questions so far. –  Jesse Smith Jul 30 '13 at 15:13
Can you please submit a set of acceptable solutions to the problem? You should either clearly define "shape" and/or "hole". If, for instance, a "hole" is defined as whitespace that has no connection to the outside area, then a solution to the example image might be to sever the figure along four horizontal cuts, each slicing through a row of holes. This solution will give you five polylines; all without holes. –  Tormod Jul 30 '13 at 16:11
The result-picture you posted is actually not the smallest way to subdivide it without holes. It consists of 31 parts, and there is a way to do it with 23 parts (I don't know whether that's minimal) –  harold Jul 30 '13 at 17:48

1 Answer 1

I'm not sure how you want the resulting shapes to be but I'm going to assume that you want them in Polygon. As in an object Polygon which is a vector of 2D vertex points (x,y). What you can do now is use this Clipper library for solving geometric spatial problems. It does polygon subtraction, addition, intersection, and a bit more. Its also fast, free, and no license is needed.


Afterwards, you can calculate your seam lengths by just finding the distances along each polygon vertex and adding them up. However, this library does not support curved contours.

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