Ok, I have a clearer picture of the problem now, and inspired by @walkytalky suggestion, here is a more ellaborate answer.

You mentioned that `p1`

and `p2`

travel along straight line segments. I don't know if these segments are aligned in a way such that both `p1`

and `p2`

always start new segments at the same time. However, you can always cut a line segment into two line segments (with the same slope) so that both `p1`

and `p2`

always start new line segments at the same time.

Assume `p1`

travels along line `A-B`

, and `p2`

travels (at the same time) along `C-D`

as a parameter `t`

goes from 0 to 1. (That is, at time `t=0.5`

, `p1`

is in the middle of `A-B`

and `p2`

in the middle of `C-D`

.)

By letting `Ax`

and `Ay`

denote the x and y coordinate of point `A`

(and similarly for `B`

, `C`

and `D`

) we can express `p1`

and `p2`

as functions of `t`

in the following way:

```
p1(t) = (Ax + t*(Bx - Ax), Ay + t(By - Ay))
p2(t) = (Cx + t*(Dx - Cx), Cy + t(Dy - Cy))
```

(For instance, when `t=0`

, `Ax + t*(Bx - Ax)`

evaluates to `Ax`

, and when `t=1`

it evaluates to `Bx`

.)

To find each "a-vertex-is-passing-by-between-p1-and-p2"-time we do the following:

For each obstacle vertex `v=(Vx, Vy)`

we need to find a `t`

so that `p1(t)`

, `p2(t)`

and `v`

are in line with each other.

This can be done by solving the following equations (two equations, and two unknown, `t`

and `k`

):

```
Vx=p1(t).x + k*(p2(t).x - p1(t).x)
Vy=p1(t).y + k*(p2(t).y - p1(t).y)`
```

If `k`

lies between 0 and 1, the polygon vertex `v`

is actually *between* the (extended) `A-B`

line and the (extended) `C-D`

line. If `t`

is also between 0 and 1, the vertex `v`

is actually passed by the `p1-p2`

line during the time the points travel along these segments (since when `t`

is, say, 1.3, the points will already be on new segments).

Once all "a-vertex-is-passing-by-between-p1-and-p2"-times has been computed, it's a simple task to figure out the rest. (That is, figuring out if it is a "becoming-in-sight", "becoming-out-of-sight" or "neither" type of passing):

For all pairs `t0`

and `t1`

of consecutive vertex-passing times, you check if the line `p1((t1-t0)/2)-p2((t1-t0)/2)`

is free of intersections with a polygon edge. If it is free of intersections, the points will be in line of sight the entire period (`t0-t1`

), otherwise they will be out of sight the entire period (since no other vertices are passed during this time period).