I'm stuck on this problem as I cannot find any examples of light dispersion.

What I’ve got:

- Function that can calculate point of two lines intersection and angle between them. (Using for mirror reflection)
- Prism with 3 or 33 angles. Counting like a sphere.

And I haven’t got idea how to create this.

Light is falling from top ( | ) to bottom of the screen and then I am counting all intersection lines and using a coordinate filter, which removes bottom points (for example – rectangle prism, light-line intersect with top of it and bottom – I delete bottom point so I can see which point was first).

And now I don’t know what to do next. I tried to take angle between light and prism, divide it by 2 and create a line, rotating a random point (`ClientRectangle.Width * 5, pt.X`

) around this point of intersection. I then search for second intersection point (now – in prism) and just another rotationto give me the "out" rays.

As I saw – it gave me weird artifacts and sometimes it redirects light in wrong direction. Also, there are no examples in C++/C# on the internet, so I can’t watch out how to do such things.

```
// tmp1, tmp2, tmp3, tmp4 - points to get the reflection throught prism
void RecountPrism()
{
PointF out_pt = new PointF();
double angle;
// Collect all intersection points
pil.Clear();
for (int i = 0; i < light.LightsPoints.Count; i++)
{
List<PointF> lp = light.LightsPoints[i];
for (int j = 0; j < lp.Count; j++)
{
PointF p = lp[j];
for (int k = 0; k < prism.PrismPts.Length - 1; k++)
{
// Connect last and first points
if (k + 2 == prism.PrismPts.Length)
{
if (LinesIntersection(prism.PrismPts[0], prism.PrismPts[k + 1], p, new PointF(p.X, ClientRectangle.Height), out out_pt, out angle))
{
pil.Add(new PrismIntersections(out_pt, out_pt.X, angle));
}
}
if (LinesIntersection(prism.PrismPts[k], prism.PrismPts[k + 1], p, new PointF(p.X, ClientRectangle.Height), out out_pt, out angle))
{
pil.Add(new PrismIntersections(out_pt, out_pt.X, angle));
}
}
}
}
/*
* Filter all intersection point
* If they're on top, so they're in prism
* TODO: upgrade filter for advanced light and for reflected by light, by the mirror
*/
bool flag = false;
List<PrismIntersections> tmp = new List<PrismIntersections>();
for (int i = 0; i < pil.Count; i++)
{
flag = false;
PrismIntersections pi_tmp = new PrismIntersections();
for (int j = pil.Count-1; j > i; j--)
{
if (pil[i].destination_Xpoint == pil[j].destination_Xpoint)
{
// Points from one ray, so calculate what point is highter
flag = true;
if (pil[i].intersection_coordinate.Y < pil[j].intersection_coordinate.Y)
pi_tmp = pil[i];
else
pi_tmp = pil[j];
}
}
if(flag)
tmp.Add(pi_tmp);
}
// Create output light
foreach(PrismIntersections pi in tmp)
{
tmp1 = pi.intersection_coordinate;
PointF tmp3 = new PointF((float)ClientRectangle.Width * 5, (float)out_pt.Y);
pi.angle -= Math.PI; // Turn back, because angle calucates for specular reflection
pi.angle /= 2.0; // Calculate angle in prism
tmp2 = new PointF((float)(Math.Cos(pi.angle) * (tmp3.X - tmp1.X) - Math.Sin(pi.angle) * (tmp3.Y - tmp1.Y) + tmp1.X),
(float)(Math.Sin(pi.angle) * (tmp3.X - tmp1.X) + Math.Cos(pi.angle) * (tmp3.Y - tmp1.Y) + tmp1.Y));
for (int k = 0; k < prism.PrismPts.Length - 1; k++)
{
if (LinesIntersection(prism.PrismPts[k], prism.PrismPts[k + 1], tmp1, tmp2, out out_pt, out angle))
{
tmp2 = tmp4 = out_pt;
tmp3 = new PointF((float)ClientRectangle.Width * 5, (float)out_pt.Y);
angle -= Math.PI;
tmp5 = new PointF((float)(Math.Cos(angle) * (tmp3.X - tmp1.X) - Math.Sin(angle) * (tmp3.Y - tmp1.Y) + tmp1.X),
(float)(Math.Sin(angle) * (tmp3.X - tmp1.X) + Math.Cos(angle) * (tmp3.Y - tmp1.Y) + tmp1.Y));
}
// Repeat for the line, that connects first and last points
if (k + 2 == prism.PrismPts.Length)
{
if (LinesIntersection(prism.PrismPts[0], prism.PrismPts[k + 1], tmp1, tmp2, out out_pt, out angle))
{
tmp2 = tmp4 = out_pt;
tmp3 = new PointF((float)ClientRectangle.Width * 5, (float)out_pt.Y);
angle -= Math.PI;
tmp5 = new PointF((float)(Math.Cos(angle) * (tmp3.X - tmp1.X) - Math.Sin(angle) * (tmp3.Y - tmp1.Y) + tmp1.X),
(float)(Math.Sin(angle) * (tmp3.X - tmp1.X) + Math.Cos(angle) * (tmp3.Y - tmp1.Y) + tmp1.Y));
}
}
}
}
}
```