TracedRay trace_ray(Surface surface, TraceIntensityMode m,
RayTraceResults result, TracedRay incident,
Vector3Pair local,
Vector3Pair pt)
{
incident.set_len((pt.origin().minus(local.origin())).len());
incident.set_intercept(surface, pt.origin());
if (m == TraceIntensityMode.Simpletrace)
{
incident.set_intercept_intensity(1.0);
return(trace_ray_simple(surface, result, incident, local, pt));
}
else
{
// apply absorbtion from current material
double i_intensity
= incident.get_intensity()
* incident.get_material().get_internal_transmittance(
incident.get_wavelen(), incident.get_len());
incident.set_intercept_intensity(i_intensity);
// FIXME
// if (i_intensity < _discard_intensity)
// return;
if (m == TraceIntensityMode.Intensitytrace)
{
return(trace_ray_intensity(surface, result, incident, local, pt));
}
else if (m == TraceIntensityMode.Polarizedtrace)
{
return(trace_ray_polarized(surface, result, incident, local, pt));
}
else
{
throw new InvalidOperationException();
}
}
}
TracedRay trace_ray_simple(Stop surface, RayTraceResults result, TracedRay incident, Vector3Pair local,
Vector3Pair intersect)
{
Vector2 v = intersect.origin().project_xy();
bool ir = true; // FIXME _intercept_reemit || result.get_params ().is_sequential ();
if (ir && surface.get_shape().inside(v))
{
// re-emit incident ray
TracedRay r = result.newRay(intersect.origin(), incident.get_ray().direction());
r.set_wavelen(incident.get_wavelen());
r.set_intensity(incident.get_intensity());
r.set_material(incident.get_material());
r.set_creator(surface);
incident.add_generated(r);
return(r);
}
return(null);
}
private TracedRay trace_ray_simple(OpticalSurface surface, RayTraceResults result, TracedRay incident,
Vector3Pair local, Vector3Pair intersect)
{
bool right_to_left = intersect.normal().z() > 0;
Medium prev_mat = surface.get_material(right_to_left ? 1 : 0);
Medium next_mat = surface.get_material(!right_to_left ? 1 : 0);
// check ray didn't "escaped" from its material
// std::cout << prev_mat->name << " " << next_mat->name <<
// " " << incident.get_material()->name << std::endl;
if (prev_mat != incident.get_material())
{
return(null);
}
double wl = incident.get_wavelen();
double index = prev_mat.get_refractive_index(wl)
/ next_mat.get_refractive_index(wl);
// refracted ray direction
Vector3 direction = refract(surface, local, intersect.normal(), index);
if (direction == null)
{
// total internal reflection
Vector3 o = intersect.origin();
Vector3 dir = reflect(surface, local, intersect.normal());
TracedRay r = result.newRay(o, dir);
r.set_wavelen(wl);
r.set_intensity(incident.get_intensity());
r.set_material(prev_mat);
r.set_creator(surface);
incident.add_generated(r);
return(r);
}
// transmit
if (!next_mat.is_opaque())
{
Vector3 o = intersect.origin();
TracedRay r = result.newRay(o, direction);
r.set_wavelen(wl);
r.set_intensity(incident.get_intensity());
r.set_material(next_mat);
r.set_creator(surface);
incident.add_generated(r);
return(r);
}
// reflect
if (next_mat.is_reflecting())
{
Vector3 o = intersect.origin();
Vector3 dir = reflect(surface, local, intersect.normal());
TracedRay r = result.newRay(o, dir);
r.set_wavelen(wl);
r.set_intensity(incident.get_intensity());
r.set_material(prev_mat);
r.set_creator(surface);
incident.add_generated(r);
return(r);
}
return(null);
}
