/// <summary>
/// Metoda postavlja sve paramtere potrebne za crtanje slike pomocu raytracinga
/// </summary>
public void read()
{
CultureInfo c = CultureInfo.InvariantCulture;
float x = float.Parse(getNextParameter().ToString(), c);
float y = float.Parse(getNextParameter().ToString(), c);
float z = float.Parse(getNextParameter().ToString(), c);
eyePosition = new Point(x, y, z);
screenSize = float.Parse(getNextParameter().ToString(), c);
screenResolution = float.Parse(getNextParameter().ToString(), c);
x = float.Parse(getNextParameter().ToString(), c);
y = float.Parse(getNextParameter().ToString(), c);
z = float.Parse(getNextParameter().ToString(), c);
lightPosition = new Point(x, y, z);
numberOfObjects = float.Parse(getNextParameter().ToString(), c);
sphereParameters = new SphereParameters[Convert.ToInt32(numberOfObjects)];
for (int j = 0; j < Convert.ToInt32(numberOfObjects); j++)
{
x = float.Parse(getNextParameter().ToString(), c);
y = float.Parse(getNextParameter().ToString(), c);
z = float.Parse(getNextParameter().ToString(), c);
Point centerPosition = new Point(x, y, z);
float radius = float.Parse(getNextParameter().ToString(), c);
float[] raysContributions = { 0, 0 };
float contribution = float.Parse(getNextParameter().ToString(), c);
raysContributions[0] = contribution;
contribution = float.Parse(getNextParameter().ToString(), c);
raysContributions[1] = contribution;
PropertyVector[] materialParameters = new PropertyVector[3];
float k1 = float.Parse(getNextParameter().ToString(), c);
float k2 = float.Parse(getNextParameter().ToString(), c);
float k3 = float.Parse(getNextParameter().ToString(), c);
materialParameters[0] = new PropertyVector(k1, k2, k3);
k1 = float.Parse(getNextParameter().ToString(), c);
k2 = float.Parse(getNextParameter().ToString(), c);
k3 = float.Parse(getNextParameter().ToString(), c);
materialParameters[1] = new PropertyVector(k1, k2, k3);
k1 = float.Parse(getNextParameter().ToString(), c);
k2 = float.Parse(getNextParameter().ToString(), c);
k3 = float.Parse(getNextParameter().ToString(), c);
materialParameters[2] = new PropertyVector(k1, k2, k3);
k1 = float.Parse(getNextParameter().ToString(), c);
n = k1;
k1 = float.Parse(getNextParameter().ToString(), c);
ni = k1;
sphereParameters[j] = new SphereParameters(centerPosition, radius, raysContributions, materialParameters, n, ni);
}
}
/// <summary>
/// Inicijalni konstruktor koji postavlja poziciju objekta, doprinose zraka i
/// paramtere materijala.
/// </summary>
/// <param name="centerPosition">pozicija centra objekta</param>
/// <param name="raysContributions">doprinosi lomljene i refraktirane zrake</param>
/// <param name="materialParameters">parametri materijala</param>
/// <param name="n">faktor jacine spekularne komponente</param>
/// <param name="ni">indeks loma</param>
public Object(Point centerPosition, float[] raysContributions, PropertyVector[] materialParameters, float n, float ni)
{
this.centerPosition = centerPosition;
this.reflection = raysContributions[0];
this.refraction = raysContributions[1];
this.ka = materialParameters[0];
this.kd = materialParameters[1];
this.ks = materialParameters[2];
this.n = n;
this.ni = ni;
}
/// <summary>
/// Metoda koja pomocu pracenja zrake racuna boju u tocki presjeka. Racuna se
/// osvjetljenje u tocki presjeka te se zbraja s doprinosima osvjetljenja koje
/// donosi reflektirana i refraktirana zraka.
/// </summary>
/// <param name="ray">pracena zraka</param>
/// <param name="depth">dubina rekurzije</param>
/// <returns>vektor boje u tocki presjeka</returns>
public ColorVector traceRay(Ray ray, int depth)
{
ColorVector Clocal = backgroundColors;
ColorVector C = new ColorVector(0, 0, 0);
int tocka_najblizeg_presjeka = -1;
bool presjek = false;
if (depth > MAXDEPTH)
{
C = new ColorVector(0, 0, 0);
return(C);
}
else
{
for (int i = 0; i < this.numberOfObjects; i++)
{
if (sphere[i].intersection(ray))
{
presjek = true;
if (tocka_najblizeg_presjeka == -1)
{
tocka_najblizeg_presjeka = i;
}
if (ray.getStartingPoint().getDistanceFrom(sphere[tocka_najblizeg_presjeka].getIntersectionPoint()) > ray.getStartingPoint().getDistanceFrom(sphere[i].getIntersectionPoint()))
{
tocka_najblizeg_presjeka = i;
}
}
}
if (presjek)
{
PropertyVector ambijetalniKoef = sphere[tocka_najblizeg_presjeka].getKa();
double r, g, b, pom;
r = ambientLight.getRed() * ambijetalniKoef.getRedParameter();
g = ambientLight.getGreen() * ambijetalniKoef.getGreenParameter();
b = ambientLight.getBlue() * ambijetalniKoef.getBlueParameter();
Clocal = new ColorVector((float)r, (float)g, (float)b);
Point najblizatocka = sphere[tocka_najblizeg_presjeka].getIntersectionPoint();
PropertyVector difuzniKoef = sphere[tocka_najblizeg_presjeka].getKd();
Vector L = new Vector(najblizatocka, lightPosition);
Vector N = sphere[tocka_najblizeg_presjeka].getNormal(najblizatocka);
Vector V = new Vector(najblizatocka, ray.getStartingPoint());
Vector R = L.getReflectedVector(N);
V.normalize();
R.normalize();
L.normalize();
double ni = sphere[tocka_najblizeg_presjeka].getNi();
double vn = V.dotProduct(N);
if (vn < 0)
{
N = N.multiple(-1);
ni = 1.0 / ni;
}
bool sjena = shadow(najblizatocka);
if ((pom = L.dotProduct(N)) > 0 && !sjena)
{
r = light.getRed() * difuzniKoef.getRedParameter() * pom;
g = light.getGreen() * difuzniKoef.getGreenParameter() * pom;
b = light.getBlue() * difuzniKoef.getBlueParameter() * pom;
ColorVector Cdifuzno = new ColorVector((float)r, (float)g, (float)b);
Clocal = Clocal.add(Cdifuzno);
}
PropertyVector spekularniKoef = sphere[tocka_najblizeg_presjeka].getKs();
if ((pom = R.dotProduct(V)) > 0 && !sjena)
{
r = light.getRed() * spekularniKoef.getRedParameter() * Math.Pow(pom, sphere[tocka_najblizeg_presjeka].getN());
g = light.getGreen() * spekularniKoef.getGreenParameter() * Math.Pow(pom, sphere[tocka_najblizeg_presjeka].getN());
b = light.getBlue() * spekularniKoef.getBlueParameter() * Math.Pow(pom, sphere[tocka_najblizeg_presjeka].getN());
ColorVector Cspekularno = new ColorVector((float)r, (float)g, (float)b);
Clocal = Clocal.add(Cspekularno);
}
Vector ReflektiraniV = V.getReflectedVector(N);
ReflektiraniV.normalize();
Ray Rrefl = new Ray(najblizatocka, ReflektiraniV);
ColorVector Crefl = traceRay(Rrefl, depth + 1);
Vector U = V.getRefractedVector(N, ni);
U.normalize();
Ray Rrefr = new Ray(najblizatocka, U);
ColorVector Crefr = traceRay(Rrefr, depth + 1);
C = C.add(Clocal);
C = C.add(Crefl.multiple(sphere[tocka_najblizeg_presjeka].getReflectionFactor()));
C = C.add(Crefr.multiple(sphere[tocka_najblizeg_presjeka].getRefractionFactor()));
C.correct();
return(C);
}
else
{
return(C = new ColorVector(backgroundColors.getRed(), backgroundColors.getBlue(), backgroundColors.getGreen()));
}
}
}
/// <summary>
/// Sluzi za mnozenje vektora boje s vektorom koeficijenata. Koristi se kod
/// odredivanja boje lokalnog osvjetljenja.
/// </summary>
/// <param name="c">vektor koeficijenata s kojim se mnozi</param>
/// <returns>vektor boje koji je rezultat mnozenja vektora boje s vektorom koeficijenata</returns>
public ColorVector multiple(PropertyVector c)
{
return(new ColorVector(c.getRedParameter() * red, c.getGreenParameter() * green,
c.getBlueParameter() * blue));
}
