You probably want to compute the segment (if any) of the ray `AB`

that intersects the rectangle. If your rectangle is axis-aligned, this will be easier to compute in a numerical sense, but the logic should be similar.

You can represent a directed line `L`

as `[a, b, c]`

such that, if point `P`

is `(X, Y)`

:

```
let L(P) = a*X + b*Y + c
then, if L(P) == 0, point P is on L
if L(P) > 0, point P is to the left of L
if L(P) < 0, point P is to the right of L
```

Note that this is redundant in the sense that, given any `k > 0`

, [k*a, k*b, k*c] represents the *same line* (this property makes it a homogeneous coordinate system). We can also represent points with homogeneous coordinates by augmenting them with a third coordinate:

```
2D point P = (X, Y)
-> homogeneous coordinates [x, y, w] for P are [X, Y, 1]
L(P) = L.a*P.x + L.b*P.y + L.c*P.w == a*X + b*Y + c*1
```

In any case, given two corners of your rectangle (say, `P`

and `Q`

), you can compute the homogeneous coordinates of the line through `P`

and `Q`

using a 3-D cross-product of their homogeneous coordinates:

```
homogeneous coordinates for line PQ are: [P.X, P.Y, 1] cross [Q.X, Q.Y, 1]
-> PQ.a = P.Y - Q.Y
PQ.b = Q.X - P.X
PQ.c = P.X*Q.Y - Q.X*P.Y
```

You can verify mathematically that points P and Q are both on the above-described line PQ.

To represent the segment of line `AB`

that intersects the rectangle, first compute vector `V = B - A`

, as in @btilly's answer. For homogeneous coordinates, this works as follows:

```
A = [A.X, A.Y, 1]
B = [B.X, B.Y, 1]
-> V = B - A = [B.X-A.X, B.Y-A.Y, 0]
for any point C on AB: homogeneous coordinates for C = u*A + v*V
(where u and v are not both zero)
```

Point `C`

will be on the ray part of the line only if `u`

and `v`

are both non-negative. (This representation may seem obscure, compared to the usual formulation of `C = A + lambda * V`

, but doing it this way avoids unnecessary divide-by-zero cases...)

Now, we can compute the ray intersection: we represent a segment of the line `AB`

by the parametric `[u,v]`

coordinates of each endpoint: `{ start = [start.u, start.v]; end = [end.u, end.v] }`

.

We compute the edges of the rectangle in the counterclockwise direction, so that points inside the rectangle are on the left/positive side (`L(P)>0`

) of every edge.

```
Starting segment is entire ray:
start.u = 1; start.v = 0
end.u = 0; end.v = 1
for each counterclockwise-directed edge L of the rectangle:
compute:
L(A) = L.a*A.X + L.b*A.Y + L.c
L(V) = L.a*V.X + L.b*V.Y
L(start) = start.u * L(A) + start.v * L(V)
L(end) = end.u * L(A) + end.v * L(V)
if L(start) and L(end) are both less than zero:
exit early: return "no intersection found"
if L(start) and L(end) are both greater or equal to zero:
do not update the segment; continue with the next line
else, if L(start) < 0:
update start coordinates:
start.u := L(V)
start.v := -L(A)
else, if L(end) < 0:
update end coordinates:
end.u := -L(V)
end.v := L(A)
on normal loop exit, the ray does intersect the rectangle;
the part of the ray inside the rectangle is the segment between points:
homog_start = start.u * A + start.v * V
homog_end = end.u * A + end.v * V
return "intersection found":
intersection_start.X = homog_start.x/homog_start.w
intersection_start.Y = homog_start.y/homog_start.w
intersection_end.X = homog_end.x/homog_end.w
intersection_end.Y = homog_end.y/homog_end.w
```

Note that this will work for arbitrary convex polygons, not just rectangles; the above is actually a general ray/convex polygon intersection algorithm. For a rectangle, you can unroll the for-loop; and, if the rectangle is axis-aligned, you can drastically simplify the arithmetic. However, the 4-case decision in the inner loop should remain the same for each edge.