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Let's say I have a triangle given by the three integer vertices (x1,y1), (x2,y2) and (x3,y3). What sort of algorithm can I use to return a comprehensive list of ALL (x,y) integer pairs that lie inside the triangle.

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That would be an infinite number of points, unless you impose some kind of constraint, e.g. coordinates are integers ? –  Paul R Jan 21 '12 at 22:00
    
Please specify. If @PaulR is right, solutions are very different to what I suggest in my answer. –  Alexandre C. Jan 21 '12 at 22:05
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You stress that you want ALL pairs but obviously there are uncountably many. Do you mean integer pairs? In that case this is the problem of rasterisation and there is a vast literature on this subject. This is a nice tutorial: joshbeam.com/articles/triangle_rasterization You may have to tweak it depending on what you mean by 'inside' because I don't know if you want to include the boundary. –  sigfpe Jan 21 '12 at 22:09
    
Now that the question has been updated to specify that the resulting x,y coordinates must be integers, it might also be useful to know whether the coordinates of the vertices are also integers ? –  Paul R Jan 22 '12 at 11:47
    
Yes, they are integers. –  CodeGuy Jan 22 '12 at 21:18

4 Answers 4

up vote 1 down vote accepted

The following algorithm should be appropriate:

  1. Sort the triangle vertices by x coordinate in increasing order. Now we have two segments (1-2 and 2-3) on the one side (top or bottom), and one segment from the other one (1-3).

  2. Compute coefficients of equations of lines (which contain the segments):

    A * x + B * y + C = 0
    A = y2 - y1
    B = x1 - x2
    C = x2 * y1 - x1 * y2
    

    There (x1, y1) and (x2, y2) are two points of the line.

  3. For each of ranges [x1, x2), (x2, x3], and x2 (special case) iterate over integer points in ranges and do the following for every x:

    1. Find top bound as y_top = (- A1 * x - C1) div B1.
    2. Find bottom bound as y_bottom = (- A2 * y - C2 - 1) div B2 + 1.
    3. Add all points between (x, y_bottom) and (x, y_top) to the result.

This algorithm is for not strictly internal vertices. For strictly internal vertices items 3.1 and 3.2 slightly differ.

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I suppose you have a list of pairs you want to test (if this is not what your problem is about, please specify your question clearly). You should store the pairs into quad-tree or kd-tree structure first, in order to have a set of candidates which is small enough. If you have few points, this is probably not worth the hassle (but it won't scale well if you don't do it).

You can also narrow down candidates further by testing against a bounding box for your triangle.

Then, for each candidate pair (x, y), solve in a, b, c the system

a + b + c = 1
a x1 + b x2 + c x3 = x
a y2 + b y2 + c y3 = y

(I let you work this out), and the point is inside the triangle if a b and c are all positive.

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The proper name for this problem is triangle rasterization.

It's a well researched problem and there's variety of methods to do it. The two popular methods are:

  1. Scan line by scan line.

    For each scan-line you require some basic geometry to recalculate the start and the end of the line. See Bresenham's Line drawing algorithm.

  2. Test every pixel in the bounding box to see if it is in the triangle.

    This is usually done by using barycentric co-ordinates.

Most people assume method 1) is more efficient as you don't waste time testing pixels that can are outside the triangle, approximately half of all the pixels in the bounding box. However, 2) has a major advantage - it can be run in parallel far more easily and so for hardware is usually the much faster option. 2) is also simpler to code.

The original paper for describing exactly how to use method 2) is written by Juan Pineda in 1988 and is called "A Parallel Algorithm for Polygon Rasterization".

For triangles, it's conceptually very simple (if you learn barycentric co-ordindates). If you convert each pixel into triangle barycentric coordinates, alpha, beta and gamma - then the simple test is that alpha, beta and gamma must be between 0 and 1.

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I like ray casting, nicely described in this Wikipedia article. Used it in my project for the same purpose. That method scales on other polygons too, including concave. Not sure about the performance, but it is easily coded, so you could try it yourself (I had no performance issues in my project)

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