When doing a ray trace with `rayTraceP`

, I can find the point where a ray intersects with a diagram.

```
> rayTraceP (p2 (0, 0)) (r2 (1, 0)) ((p2 (1,-1) ~~ p2 (1,1))
Just (p2 (1.0, 0.0))
```

I want to use this to find not only the "collision point", but also the collision time and the normal vector to the surface at that point.

```
-- A Collision has a time, a contact point, and a normal vector.
-- The normal vector is perpendicular to the surface at the contact
-- point.
data Collision v n = Collision n (Point v n) (v n)
deriving (Show)
```

Given a start point for the ray and a velocity vector along the ray, I can find the contact point `end`

using `rayTraceP`

:

```
end <- rayTraceP start vel dia
```

And I can find the collision time using the distance between `start`

and `end`

:

```
time = distance start end / norm vel
```

But I'm stuck on finding the normal vector. I'm working within this function:

```
rayTraceC :: (Metric v, OrderedField n)
=> Point v n -> v n -> QDiagram B v n Any -> Maybe (Collision v n)
-- Takes a starting position for the ray, a velocity vector for the
-- ray, and a diagram to trace the ray to. If the ray intersects with
-- the diagram, it returns a Collision containing:
-- * The amount of time it takes for a point along the ray going at
-- the given velocity to intersect with the diagram.
-- * The point at which it intersects with the diagram.
-- * The normal vector to the surface at that point (which will be
-- perpendicular to the surface there).
-- If the ray does not intersect with the diagram, it returns Nothing.
rayTraceC start vel dia =
do
end <- rayTraceP start vel dia
let time = distance start end / norm vel
-- This is where I'm getting stuck.
-- How do I find the normal vector?
let normalV = ???
return (Collision time end normalV)
```

Some examples of what I want it to do:

```
> -- colliding straight on:
> rayTraceC (p2 (0, 0)) (r2 (1, 0)) (p2 (1,-1) ~~ p2 (1,1))
Just (Collision 1 (p2 (1, 0)) (r2 (-1, 0)))
> -- colliding from a diagonal:
> rayTraceC (p2 (0, 0)) (r2 (1, 1)) (p2 (1,0) ~~ p2 (1,2))
Just (Collision 1 (p2 (1, 1)) (r2 (-1, 0))
> -- colliding onto a diagonal:
> rayTraceC (p2 (0, 0)) (r2 (1, 0)) (p2 (0,-1) ~~ p2 (2,1))
Just (Collision 1 (p2 (1, 0)) (r2 (-√2/2, √2/2)))
> -- no collision
> rayTraceC (p2 (0, 0)) (r2 (1, 0)) (p2 (1,1) ~~ p2 (1,2))
Nothing
```

It is correct on everything in these examples except for the normal vector.

I have looked in the documentation for both Diagrams.Trace and Diagrams.Core.Trace, but maybe I'm looking in the wrong places.