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I have a line, defined by the parameters m, h, where

y = m*x + h

This line goes across a grid (i.e. pixels). For each square (a, b) of the grid (ie the square [a, a+1] x [b, b+1]), I want to determine if the given line crosses this square or not, and if so, what is the length of the segment in the square.

Eventually, I would like to be able to do this with multiple lines at once (ie m and h are vectors, matlab-style), but we can focus on the "simple" case for now.

I figured how to determine if the line crosses the square:

  1. Compute the intersection of the line with the vertical lines x = a and x = a + 1, and the horizontal lines y = b and y = b + 1
  2. Check if 2 of these 4 points are on the square boundaries (ie a <= x < a + 1 and b <= y < b + 1)

If two on these points are on the square, the line crosses it. Then, to compute the length, you simply subtract the two points, and use Pythagorean theorem.

My problem is more on the implementation side: how can I implement that nicely (especially when selecting which 2 points to subtract) ?

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Another way to check if the line crosses the square is to check if atleast one pair of diagonal points lie on opposite sides of the line. If both pairs are on the same side (ie...all 4 square corner points either satisfy y <=mx+h OR y >= mx+h) the line doesnt intersect the square. This may be computationally more efficient compared to steps 1 and 2 you describe. –  Tryer Dec 7 '10 at 17:52
    
Thank you Tryer, this is effectively a much better solution ! –  Wookai Dec 7 '10 at 19:35

2 Answers 2

up vote 1 down vote accepted

Let square be defined by corner points (a,b), (a+1,b), (a,b+1), (a+1,b+1).

Step 1: Check if the line intersects the square...

(a)Substitute each of the coordinates of the 4 corner points, in turn into y - mx - h. If the sign of this evaluation includes both positive and negative terms, go to step b. Otherwise, the line does not intersect the square.

(b)Now there are two sub-cases:

(b1)Case 1: In step (a) you had three points for which y - mx - h evaluated to one sign and the fourth point evaluated to the other sign. Let this 4th point be some (x*,y*). Then the points of intersection are (x*,mx*+h) and ((y*-h)/m,y*).

(b2)Case 2: In step (a) you had two points for which y - mx - h evaluate to one sign and the other two points evaluated to the other sign. Pick any two points that evaluated to the same sign, say (x*,y*) and (x*+1, y*). Then the intersection points are (x*, mx* + h) and (x*+1,m(x*+1) + h).

You would have to consider some degenerate cases where the line touches exactly one of the four corner points and the case where the line lies exactly on one side of the square.

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Thank you ! Your answer is the most complete, and uses a better solution to check for intersection ! –  Wookai Dec 7 '10 at 19:37
    
There are still "lots" of if, else, etc. Do you have a suggestion on how I could implement this for multiple points at once, in matlab ? I got point 1), but I'm stuck with the cases a) and b) in 2). –  Wookai Dec 8 '10 at 9:27
    
I guess ANY algorithm for this problem will have many "if"s and "else"s. Case (1) should be relatively straightforward. Because there is just one corner point with the opposing sign. The thing to note about Case (2) is that there will always be a pair of points of form (x*,y*) and [(x*+1,y*) or (x*,y*+1)]. So, in your case if you find yourself in Case (2) simply choose (a,b) as one of the point pairs. You then only need to check if (a+1,b) or (a,b+1) has the same sign as (a,b). If you check the first of the latter and it is of opposing sign, you know it is the other point. –  Tryer Dec 8 '10 at 10:22

Your proposed method may meet with problems in step (1) when m is 0 (when trying to compute the intersection with y = k).

if m is 0, then it's easy (the line segment length is either 1 or 0, depending on whether b <= h <= b+1).

Otherwise, you can find the intersections with x = a and a+1, say, y_a, y_{a+1} via a substitution. Then, clip y_a and y_{a+1} to between b and b+1 (say, y1 and y2, i.e. y1 = min(b+1, max(b, y_a)) and similarly for y2), and use the proportion abs((y1-y2)/m) * sqrt(m^2+1).

This makes use of the fact that the line segment between x=k and x=k+1 is sqrt(m^2+1), and the difference in y is m, and similarity.

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