Say that the viewer is at position `(x1,y1)`

and the target at `(x2,y2)`

. Now, I am assuming that there is a set of `n`

contiguous tiles along along `x`

and `m`

along `y`

. The lower, left corner of the first of these tiles is at position `(x0,y0)`

. The size of tiles are `d`

along `x`

and `t`

along `y`

. Now the math:

The line connecting viewer and target is

`y = y1 + (y2 - y1) * (x - x1) / (x2 - x1)`

The tiles corners are at points `p1 = (x0,y0)`

; `p2 = (x0 + n * d, y0)`

; `p3 = (x0 + n * d, y0 + m * t)`

; `p4 = (x0, y0 + m * t)`

. Now the job is to find if that line crosses any of the 4 segments connecting two consecutive corners. Let's take the segment between p1 and p2 (a horizontal line) defined by `y = y0`

. If you set this into the line equation you can find the possible interception `x`

which I named `xi`

:

`y0 = (y2 - y1) * (xi - x1) / (x2 - x1) + y1`

You can invert this equation and find the possibx:

`xi = x1 + (y0 - y1) * (x2 - x1) / (y2 - y1)`

Now if `xi > x0`

and `xi < x0 + n * d`

you have an interception for this segment. Otherwise you have a free line of sight.

Do the same for the other three segments whose straight lines are defined by `p2 -> p3: x = x0 + n * d`

; `p3 -> p4: y = y0 + m * d`

; and `p4 -> p1: x = x0`

.

Note that when the segment is horizontal (`y = const`

) you have to put this `y`

in the line of sight straight line, calculate `x`

and compare this `x`

with the intercept. If the segment is vertical (`x = const`

) then you have to put `x`

in the straight line equation, calculate `y`

and check if it falls in the interval or not.

A final remark is that you have to take particular care of cases where `x1 = x2`

or `y1 = y2`

. This are vertical and horizontal line of sights and may lead to division by zero in the above equations. The solution: deal with these cases separately.