# How can I modify this line of sight algorithm to accept rays which pass through corners?

I am working on a pathfinding algorithm based on Theta*, a variant of A* which provides a good system for pathfinding which is not constrained to a grid, even though the terrain/obstructions are based on a grid pattern. This system requires a line of sight algorithm to determine whether or not a particular path is obstructed.

I found this extremely useful line of sight algorithm, and I've successfully implemented it in my code. Unfortunately, it considers the following to be an invalid path:

However, for my purposes, I want such a path to be considered valid. I've tried to modify the algorithm by detecting whether or not a point is on the line itself using the basic `y = mx + b` formula, but the algorithm's inconsistencies prevent me from relying on such a system.

Is there any efficient way to modify this algorithm to allow such a path? Is there another algorithm that would work better? Keep in mind that the start and end points of the path will not necessarily be confined to a grid, so all points use `double` precision.

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## 1 Answer

the code you reference actually omits to explicitly handle the case where the line goes through a grid point (where four squares touch). You need to check for `error == 0`.

In this case, at most one of the four squares touching the grid point may be blocked to still have a valid path.

Regards, Erich

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Alright, cool, that works. But could you just point me why exactly it does? I sort of understand it, but I don't completely. – Alexis King Jul 2 '12 at 17:31
1. `error == 0`means that your LOS is hitting a grid point – Erich Schreiner Jul 3 '12 at 7:52
Right, I get that, but could you elaborate on what the `error` value does in general? – Alexis King Jul 3 '12 at 8:00
From what I see by just skimming the sources you referenced (the last section using integer math), when passing through a grid point, the LOS is actually divided into two (or more) similar segments. As the author notes, his algorithms will always move vertically from such an intersection. – Erich Schreiner Jul 3 '12 at 9:03