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In my current project I need to calculate the intersection area of triangles and the unit squares in an infinite grid.

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For every triangle (given by three pairs of floating point numbers) I need to know the area (in the interval (0,1]) it has in common with every square it intersects.

Right now I convert both (the triangle and the square) to polygons and use Sutherland-Hodgman polygon clipping to calculate the intersection polygon, which I then use to calculate its area.

This approach now shows to be a performance bottleneck in my application. I guess a more specialized (analytical) algorithm would be much faster. Is there a standard solution for this problem, or do you have any idea? I only need the areas, not the shape of the intersections.

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You'd better to specify usage scenario - for example, is square set constant and so on. –  MBo Mar 28 '14 at 4:49
OK, thanks. I hope it is clearer now after my edit. –  Tobias Hermann Mar 28 '14 at 11:40
Yes, it is clear that problem is completely different from initial formulation ;) Will try to elaborate some clues later –  MBo Mar 28 '14 at 12:47
Can you please explain how you're describing the coordinates of the triangle vertices? Are you using integer numbers (pixels?) or rather floating point variables? –  apendua Apr 1 '14 at 8:13
Thanks for the remark. The coordinates are foating point numbers. I edited my questions accordingly. –  Tobias Hermann Apr 1 '14 at 11:17

4 Answers 4

Your polygon are convex. There are some algorithms for convex polygons faster than general ones. I've used O'Rourke algorithm with success (code from his book here, I believe that good description exists). Note that some values may be precomputed for your squares.

If your polygons not always intersect, then you may at first check the fact of intersection with separating axes method.

Another option to try- Liang-Barski algorithm for clipping every triangle edge by square.

Edit: You can quickly find all intersections of triangle edges with grid using algorthm of Amanatides and Woo (example in grid traversal section here)

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Thanks. I guess intersecting two convex polygons is still kind of an overkill for my very simple shapes. But if nothing better pops up, I will probably follow your suggestion. –  Tobias Hermann Mar 25 '14 at 14:21
Yes, modification for square is simpler, but the general principle of O'Rourke algorithm - ordered alternate walk through edges - is applicable. –  MBo Mar 25 '14 at 15:10
The Amanatides-and-Woo-thing looks quite promising, thx. Can you tell me how you would use it for my goal? –  Tobias Hermann Mar 31 '14 at 12:03
It may be useful to speed up finding of intersections. –  MBo Mar 31 '14 at 13:01
Yes sure, this part would become faster. But for the cells that are intersected, I still need to calculate the overlapping area sizes. –  Tobias Hermann Mar 31 '14 at 13:12

To process this task with hi performance , i suggest some modifications of Vatti line sweep clipping. http://en.wikipedia.org/wiki/Vatti_clipping_algorithm

Stepping from minimal Y vertex of your Triangle make such steps:

  1. sort vertexes by Y coordinate
  2. step Y higher to MIN(nextVertex.Y, nextGridBottom)
  3. Calculate points of intersection of grid with edges.
  4. Collect current trapezoid
  5. repeat from step2 until vertex with highest Y coordinate.
  6. Split trapezoids by X coordinate if required.

here is example of Trapezoidalization in X direction http://www.personal.kent.edu/~rmuhamma/Compgeometry/MyCG/PolyPart/polyPartition.htm

It illustrate main idea of line sweep algorithm. Good luck.

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You are not mentioning what precision you are looking for. In case you are looking for a analytical method, disregard this answer, but if you just want to do antialiasing I suggest a scanline edge-flag algorithm by Kiia Kallio. I have used it a few times and it is quite fast and can be set up for very high precision. I have a java implementation if you are interested.

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Sounds interesting, but initially I was looking for an analytic solution. –  Tobias Hermann Apr 3 '14 at 13:04

You can take advantage of the regular pattern of squares.

I'm assuming the reason this is a bottleneck is because you have to wait while your algorithm finds all squares intersecting any of the triangles and computes all the areas of intersection. So we'll compute all the areas, but in batches for each triangle in order to get the most information from the fewest calculations.

First, as explained by others, for each edge of the triangle, you can find the sequence of squares that edge passes through, as well as the points at which it crosses each vertical or horizontal edge of a square.

Do this for all three sides, keeping a list of all the squares you encounter, but keep only one copy of each square. It may be useful to store the squares in multiple lists, so that all squares on a given row are all kept in the same list.

When you've found all squares the triangle's edges pass through, if two of those squares were on the same row, any squares between those two that are not in the list are completely inside the triangle, so 100% of each of those squares is covered.

For the other squares, the calculation of area can depend on how many vertices of the triangle are in the square (0, 1, 2, or 3) and where the edges of the triangle intersect the sides of the square. You can summarize all the cases in a few pencil-and-paper drawings, and come up with calculations for each one. For example, when an edge of triangle crosses two sides of the square, with one corner of the square on the "outside" side of the edge, that corner is one angle of a small triangle "cut off" by that edge of the larger triangle; use the points of intersection on the square's sides to compute the area of the small triangle and deduct it from the area of the square. If two points instead of one are "outside", you have a trapezoid whose two base lengths are found from the points of intersection, and whose height is the width of the square; deduct its area from the square. If three points are outside, deduct the entire area of the square and then add the area of the small triangle.

One vertex of the large triangle inside the square, three corners of the square outside that angle: draw a line from the remaining corner to the triangle's vertex, so you have two small triangles, deduct the entire square and add those triangles' areas. Two corners of the square outside the angle, draw lines to the vertex to get three small triangles, etc.

I'm phrasing this so that you always assume you start with the entire area of the square and reduce the area by some amount depending on how the edge of the triangle intersects the square. That way, in the case where the edges of the triangle intersect the square more than twice--such as one edge cuts across one corner of the square and another edge cuts across a different corner, you can just deduct the area cut off by the first edge, then deduct the area cut off by the second edge.

This will be a considerable number of special cases, though you can take advantage of symmetry; for example, you don't have to write the complete calculation for "cut off a triangle in one corner" four times.

You'll write a lot more code than if you just took someone's convex-polygon library off the shelf, and you will want to test the living daylights out of it to make sure you didn't forget to code any cases, but once you get it working, it shouldn't take much more effort to make it reasonably fast.

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