I would solve this mathematically:

Let `N`

be the normal vector.
Let `V`

be the light vector.
Let `O`

be the reflected vector.

`O`

is in the same plane as `N`

,`V`

- The cosine of the angle between
`V`

and `N`

is the same as the cosine of the angle between `V`

and `O`

(With a minus sign).
`O`

has the same same length as `V`

This yields 3 equations:

- dot(O, cross(N,V)) = 0
- dot(N,V)/ norm(N) / norm(V) = - dot(N,O) / norm(N) / norm(O)
- norm(O) = norm(V)

After manipulating these equations, you will reach a 3x3 equations system. All that is left is to solve it.

**Edit** My colleague has just told me of an easier way:

`V`

can be separated into 2 parts, `V = Vp + Vn`

`Vp`

- parallel to `N`

`Vn`

- has straight angle with `N`

`O`

has the same parallel part `Vp`

, but exactly the opposite `Vn`

Thus, `O = Vp - Vn`

, but `V = Vp + Vn`

and then `O = V - 2 * Vn`

Where `Vn = dot(V,N) * N`

(Assuming that `N`

has norm of 1)

So the final answer is:

```
function O = FindReflected(V,N)
N = N / norm(N);
O = V - 2 * dot(V,N) * N;
end
```

**Edit 2**
I've just found a much better explanation on `Math.stackexchange`

:
http://math.stackexchange.com/questions/13261/how-to-get-a-reflection-vector

`a(end:-1:1)`

? – petrichor Jun 13 '12 at 11:48