My answer is based off of your comment on a linked question: is there also an easy way to determine at which coordinates diagonal rays of light intersect each other for two given points? It looks like you want to determine the points of the intersection for the rays given by the light sources.
From what you have already described, the horizontal/vertical cases are easy. The points between the two sources describe the intersection. The diagonal cases are more tricky, and I think the easiest way to approach it is just calculating line intersections.
You can describe each diagonal/anti-diagonal as a line described by a vector equation
ray = s + u * d where
s is the position of the light source and
d is the direction of the ray (either
[1, 1] ,
[1, 0], or
[0, 1]). You have four of such equations for each source, one for each direction. Now, to find the intersection of the diagonal, just find the intersection of the non-parallel lines for the two sources (one pair will be parallel, and so cannot intersection).
Sorry if this isn't clear, I'll try to update this.
As a simple optimization, rays intersect diagonally if and only if the rectilinear distance (
|x1 - x2| + |y1 - y2|) between the sources is even. I think there's other conditions that help to simplify your case.
Here's a derivation to find the equations you need. We start with two rays:
ray1 = s1 + u1 * d1
ray2 = s2 + u2 * d2
In cartesian coordinates:
ray1x = s1x + u1 * d1x
ray1y = s1y + u1 * d1y
ray2x = s2x + u2 * d2x
ray2y = s2y + u2 * d2y
At the intersection,
ray1x = ray2x and
ray1y = ray2y:
s1x + u1 * d1x = s2x + u2 * d2x
s1y + u1 * d1y = s2y + u2 * d2y
To make things easier, we can isolate and eliminate
u2 = (s1x - s2x + u1 * d1x) / d2x
u2 = (s1y - s2y + u1 * d1y) / d2y
(s1x - s2x + u1 * d1x) / d2x = (s1y - s2y + u1 * d1y) / d2y
(s1x - s2x + u1 * d1x) * d2y = (s1y - s2y + u1 * d1y) * d2x
Then solve for
(s1x - s2x) * d2y + u1 * d1x * d2y = (s1y - s2y) * d2x + u1 * d1y * d2x
u1 * (d1x * d2y - d1y * d2x) = (s1y - s2y) * d2x - (s1x - s2x) * d2y
u1 = ((s1y - s2y) * d2x - (s1x - s2x) * d2y) / (d1x * d2y - d1y * d2x)
u2 you can just evaluate one of equations above or use:
u2 = ((s2y - s1y) * d1x - (s2x - s1x) * d1y) / (d2x * d1y - d2y * d1x)
So there you have it. Two equations to solve for
u2 given the source locations
s2 and ray directions
d2. You just plug in
u2 values into the original
ray equations and you have the intersections for one pair. In your case, an intersection exists if and only if
u2 are integers. There's one case where a division by zero occurs, when the directions are
[1, 0] and
[0, 1], but that case is trivial to solve (the non-zero coordinates of the sources form the coordinates of the intersection).