public BSDF(DifferentialGeometry dgs, Normal ngeom, double eta)
{
dgShading = new DifferentialGeometry (dgs);
Eta = eta;
ng = new Normal (ngeom);
nn = new Normal (dgShading.n);
sn = dgShading.dpdu.Normalized;
tn = nn % sn;
nBxDFs = 0;
}
public override Spectrum SampleL(Point p, double pEpsilon, LightSample ls, double time, ref Vector wi, ref double pdf, ref VisibilityTester visibility)
{
Normal ns = new Normal ();
Point ps = ShapeSet.Sample (p, ls, ref ns);
wi = (ps - p).Normalized;
pdf = ShapeSet.Pdf (p, wi);
visibility.SetSegment (p, pEpsilon, ps, 0.001, time);
Spectrum Ls = L (ps, ns, -wi);
return Ls;
}
public override Spectrum SampleL(Scene scene, LightSample ls, double u1, double u2, double time, ref Ray ray, ref Normal Ns, ref double pdf)
{
Point org = ShapeSet.Sample (ls, ref Ns);
Vector dir = MonteCarlo.UniformSampleSphere (u1, u2);
if ((dir ^ Ns) < 0.0)
dir *= -1.0;
ray = new Ray (org, dir, 0.001, double.PositiveInfinity, time);
pdf = ShapeSet.Pdf (org) * Util.InvTwoPi;
Spectrum Ls = L (org, Ns, dir);
return Ls;
}
public DifferentialGeometry()
{
p = new Point ();
n = new Normal ();
dpdu = new Vector ();
dpdv = new Vector ();
dndu = new Normal ();
dndv = new Normal ();
dpdx = new Vector ();
dpdy = new Vector ();
u = v = 0.0;
dudx = dudy = dvdx = dvdy = 0.0;
Shape = null;
}
public DifferentialGeometry(Point p, Vector dpdu, Vector dpdv, Normal dndu, Normal dndv, double u, double v, IShape shape)
{
this.p = new Point (p);
this.dpdu = new Vector (dpdu);
this.dpdv = new Vector (dpdv);
this.dndu = new Normal (dndu);
this.dndv = new Normal (dndv);
this.n = new Normal ((dpdu % dpdv).Normalized);
this.u = u;
this.v = v;
dudx = dvdx = dudy = dvdy = 0.0;
this.Shape = shape;
if (shape != null && (shape.ReverseOrientation ^ shape.TransformSwapsHandedness))
n *= -1.0;
}
public DifferentialGeometry(DifferentialGeometry dg)
{
this.p = new Point (dg.p);
this.dpdu = new Vector (dg.dpdu);
this.dpdv = new Vector (dg.dpdv);
this.dndu = new Normal (dg.dndu);
this.dndv = new Normal (dg.dndv);
this.n = new Normal (dg.n);
this.u = dg.u;
this.v = dg.v;
this.dudx = dg.dudx;
this.dvdx = dg.dvdx;
this.dudy = dg.dudy;
this.dvdy = dg.dvdy;
this.Shape = dg.Shape;
}
public Point Sample(Point p, LightSample lightSample, ref Normal Ns)
{
double temp = 0.0;
int sn = AreaDistribution.SampleDiscrete (lightSample.uComponent, ref temp);
Point pt = Shapes[sn].Sample (p, lightSample.uPos[0], lightSample.uPos[1], ref Ns);
// Find closest intersection of ray with shapes in _ShapeSet_
Ray r = new Ray (p, pt - p, 0.001, double.PositiveInfinity);
double rayEps = 0.0, thit = 1.0;
bool anyHit = false;
DifferentialGeometry dg = new DifferentialGeometry ();
foreach (IShape shape in Shapes)
anyHit |= shape.Intersect (r, ref thit, ref rayEps, ref dg);
if (anyHit)
Ns = new Normal (dg.n);
return r.Apply (thit);
}
public override Spectrum SampleL(Scene scene, LightSample ls, double u1, double u2, double time, ref Ray ray, ref Normal Ns, ref double pdf)
{
// Choose point on disk oriented toward infinite light direction
Point worldCenter;
double worldRadius;
scene.WorldBound.BoundingSphere (out worldCenter, out worldRadius);
Vector v1, v2;
Util.CoordinateSystem (LightDir, out v1, out v2);
double d1 = 0.0, d2 = 0.0;
MonteCarlo.ConcentricSampleDisk (ls.uPos[0], ls.uPos[1], ref d1, ref d2);
Point Pdisk = worldCenter + worldRadius * (d1 * v1 + d2 * v2);
// Set ray origin and direction for infinite light ray
ray = new Ray (Pdisk + worldRadius * LightDir, -LightDir, 0.0, double.PositiveInfinity, time);
Ns = new Normal (ray.Direction);
pdf = 1.0 / (Util.Pi * worldRadius * worldRadius);
return L;
}
public TriangleMesh(Transform objectToWorld, Transform worldToObject, bool ro, int ntris, int nverts, int[] vptr, Point[] p, Normal[] n, Vector[] s, double[] uv,
ITexture<double> atex)
: base(objectToWorld, worldToObject, ro)
{
NumberOfTriangles = ntris;
NumberOfVertices = nverts;
AlphaTexture = atex;
/*VertexIndices = new int[3 * NumberOfTriangles];
vptr.CopyTo (VertexIndices, 0);*/
VertexIndices = vptr;
/*if (uv != null)
{
Uvs = new double[2 * NumberOfVertices];
uv.CopyTo (Uvs, 0);
}
else
Uvs = null;*/
Points = new Point[NumberOfVertices];
Normals = n;
Vectors = s;
Uvs = uv;
/*if (n != null)
{
Normals = new Normal[NumberOfVertices];
n.CopyTo (Normals, 0);
}
else
Normals = null;
if (s != null)
{
Vectors = new Vector[NumberOfVertices];
s.CopyTo (Vectors, 0);
}
else
Vectors = null;*/
for (int i = 0; i < NumberOfVertices; ++i)
Points[i] = objectToWorld.Apply (p[i]);
}
public Point Sample(LightSample lightSample, ref Normal Ns)
{
double temp = 0.0;
int sn = AreaDistribution.SampleDiscrete (lightSample.uComponent, ref temp);
return Shapes[sn].Sample (lightSample.uPos[0], lightSample.uPos[1], ref Ns);
}
public abstract Spectrum L(Point p, Normal n, Vector w);
public BSDF(DifferentialGeometry dgs, Normal ngeom)
: this(dgs, ngeom, 1.0)
{
}
public virtual Point Sample(double u1, double u2, ref Normal Ns)
{
return new Point ();
}
public override Point Sample(Point p, double u1, double u2, ref Normal Ns)
{
// Compute coordinate system for sphere sampling
Point Pcenter = ObjectToWorld.Apply (new Point ());
Vector wc = (Pcenter - p).Normalized;
Vector wcX, wcY;
Util.CoordinateSystem (wc, out wcX, out wcY);
// Sample uniformly on sphere if $\pt{}$ is inside it
if (Util.DistanceSquared (p, Pcenter) - Radius * Radius < 0.0001)
return Sample (u1, u2, ref Ns);
// Sample sphere uniformly inside subtended cone
double sinThetaMax2 = Radius * Radius / Util.DistanceSquared (p, Pcenter);
double cosThetaMax = Math.Sqrt (Math.Max (0.0, 1.0 - sinThetaMax2));
DifferentialGeometry dgSphere = new DifferentialGeometry ();
double thit = 0.0, rayEpsilon = 0.0;
Point ps;
Ray r = new Ray (p, MonteCarlo.UniformSampleCone (u1, u2, cosThetaMax, wcX, wcY, wc), 0.001);
if (!Intersect (r, ref thit, ref rayEpsilon, ref dgSphere))
thit = ((Pcenter - p) ^ r.Direction.Normalized);
ps = r.Apply (thit);
Ns = new Normal ((ps - Pcenter).Normalized);
if (ReverseOrientation)
Ns *= -1.0;
return ps;
}
public Normal(Normal vec)
: this(vec.x, vec.y, vec.z)
{
}
public override bool Intersect(Ray r, ref double tHit, ref double rayEpsilon, ref DifferentialGeometry dg)
{
// Transform _Ray_ to object space
Ray ray = new Ray ();
WorldToObject.Apply (r, ref ray);
// Compute plane intersection for disk
if (Math.Abs (ray.Direction.z) < 1E-07)
return false;
double thit = (Height - ray.Origin.z) / ray.Direction.z;
if (thit < ray.MinT || thit > ray.MaxT)
return false;
// See if hit point is inside disk radii and $\phimax$
Point phit = ray.Apply (thit);
double dist2 = phit.x * phit.x + phit.y * phit.y;
if (dist2 > Radius * Radius || dist2 < InnerRadius * InnerRadius)
return false;
// Test disk $\phi$ value against $\phimax$
double phi = Math.Atan2 (phit.y, phit.x);
if (phi < 0)
phi += 2.0 * Util.Pi;
if (phi > PhiMax)
return false;
// Find parametric representation of disk hit
double u = phi / PhiMax;
double v = 1.0 - ((Math.Sqrt (dist2) - InnerRadius) / (Radius - InnerRadius));
Vector dpdu = new Vector (-PhiMax * phit.y, PhiMax * phit.x, 0.0);
Vector dpdv = new Vector (-phit.x / (1 - v), -phit.y / (1 - v), 0.0);
dpdu *= PhiMax * Util.InvTwoPi;
dpdv *= (Radius - InnerRadius) / Radius;
Normal dndu = new Normal (0, 0, 0), dndv = new Normal (0, 0, 0);
// Initialize _DifferentialGeometry_ from parametric information
dg = new DifferentialGeometry (ObjectToWorld.Apply (phit), ObjectToWorld.Apply (dpdu), ObjectToWorld.Apply (dpdv), ObjectToWorld.Apply (dndu), ObjectToWorld.Apply (dndv), u, v, this);
// Update _tHit_ for quadric intersection
tHit = thit;
// Compute _rayEpsilon_ for quadric intersection
rayEpsilon = 0.0005 * tHit;
return true;
}
public override void GetShadingGeometry(Transform objectToWorld, DifferentialGeometry dg, ref DifferentialGeometry dgShading)
{
if (Mesh.Normals == null && Mesh.Vectors == null)
{
dgShading = new DifferentialGeometry (dg);
return;
}
// Initialize _Triangle_ shading geometry with _n_ and _s_
// Compute barycentric coordinates for point
double[] b = new double[3];
// Initialize _A_ and _C_ matrices for barycentrics
double[] uv = new double[6];
GetUVs (uv);
double[][] A = new double[][] { new double[] { uv[2] - uv[0], uv[4] - uv[0] }, new double[] { uv[3] - uv[1], uv[5] - uv[1] } };
double[] C = new double[] { dg.u - uv[0], dg.v - uv[1] };
if (!Util.SolveLinearSystem2x2 (A, C[0], C[1], out b[1], out b[2]))
{
// Handle degenerate parametric mapping
b[0] = b[1] = b[2] = 1.0 / 3.0;
} else
b[0] = 1.0 - b[1] - b[2];
// Use _n_ and _s_ to compute shading tangents for triangle, _ss_ and _ts_
Normal ns;
Vector ss, ts;
if (Mesh.Normals != null)
ns = objectToWorld.Apply (b[0] * Mesh.Normals[Vertices[0]] +
b[1] * Mesh.Normals[Vertices[1]] +
b[2] * Mesh.Normals[Vertices[2]]).Normalized;
else
ns = new Normal (dg.n);
if (Mesh.Vectors != null)
ss = objectToWorld.Apply (b[0] * Mesh.Vectors[Vertices[0]] +
b[1] * Mesh.Vectors[Vertices[1]] +
b[2] * Mesh.Vectors[Vertices[2]]).Normalized;
else
ss = dg.dpdu.Normalized;
ts = ss % ns;
if (ts.SquaredLength > 0.0)
{
ts = ts.Normalized;
ss = ts % ns;
} else
Util.CoordinateSystem (new Vector (ns), out ss, out ts);
Normal dndu, dndv;
// Compute $\dndu$ and $\dndv$ for triangle shading geometry
if (Mesh.Normals != null)
{
double[] uvs = new double[6];
GetUVs (uvs);
// Compute deltas for triangle partial derivatives of normal
double du1 = uvs[0] - uvs[4];
double du2 = uvs[2] - uvs[4];
double dv1 = uvs[1] - uvs[5];
double dv2 = uvs[3] - uvs[5];
Normal dn1 = Mesh.Normals[Vertices[0]] - Mesh.Normals[Vertices[2]];
Normal dn2 = Mesh.Normals[Vertices[1]] - Mesh.Normals[Vertices[2]];
double determinant = du1 * dv2 - dv1 * du2;
if (determinant == 0.0)
{
dndu = new Normal (0, 0, 0);
dndv = new Normal (0, 0, 0);
} else
{
double invdet = 1.0 / determinant;
dndu = (dv2 * dn1 - dv1 * dn2) * invdet;
dndv = (-du2 * dn1 + du1 * dn2) * invdet;
}
} else
{
dndu = new Normal (0, 0, 0);
dndv = new Normal (0, 0, 0);
}
dgShading = new DifferentialGeometry (dg.p, ss, ts, ObjectToWorld.Apply (dndu), ObjectToWorld.Apply (dndv), dg.u, dg.v, dg.Shape);
dgShading.dudx = dg.dudx;
dgShading.dvdx = dg.dvdx;
dgShading.dudy = dg.dudy;
dgShading.dvdy = dg.dvdy;
dgShading.dpdx = new Vector (dg.dpdx);
dgShading.dpdy = new Vector (dg.dpdy);
}
public abstract Spectrum SampleL(Scene scene, LightSample ls, double u1, double u2, double time, ref Ray ray, ref Normal Ns, ref double pdf);
public static double AbsDot(Vector a, Normal b)
{
return Math.Abs (a ^ b);
}
public static double AbsDot(Normal a, Vector b)
{
return Math.Abs (a ^ b);
}
public static Normal FaceForward(Normal a, Normal b)
{
return ((a ^ b) < 0.0) ? -a : a;
}
public override bool Intersect(Ray r, ref double tHit, ref double rayEpsilon, ref DifferentialGeometry dg)
{
double phi;
Point phit;
// Transform _Ray_ to object space
Ray ray = new Ray ();
WorldToObject.Apply (r, ref ray);
// Compute quadratic sphere coefficients
double A = ray.Direction.x * ray.Direction.x + ray.Direction.y * ray.Direction.y + ray.Direction.z * ray.Direction.z;
double B = 2 * (ray.Direction.x * ray.Origin.x + ray.Direction.y * ray.Origin.y + ray.Direction.z * ray.Origin.z);
double C = ray.Origin.x * ray.Origin.x + ray.Origin.y * ray.Origin.y + ray.Origin.z * ray.Origin.z - Radius * Radius;
// Solve quadratic equation for _t_ values
double t0 = 0.0, t1 = 0.0;
if (!Util.Quadratic (A, B, C, ref t0, ref t1))
return false;
// Compute intersection distance along ray
if (t0 > ray.MaxT || t1 < ray.MinT)
return false;
double thit = t0;
if (t0 < ray.MinT)
{
thit = t1;
if (thit > ray.MaxT)
return false;
}
// Compute sphere hit position and $\phi$
phit = ray.Apply (thit);
if (phit.x == 0.0 && phit.y == 0.0)
phit.x = 1E-5 * Radius;
phi = Math.Atan2 (phit.y, phit.x);
if (phi < 0.0)
phi += 2.0 * Util.Pi;
// Test sphere intersection against clipping parameters
if ((zMin > -Radius && phit.z < zMin) || (zMax < Radius && phit.z > zMax) || phi > PhiMax)
{
if (thit == t1)
return false;
if (t1 > ray.MaxT)
return false;
thit = t1;
// Compute sphere hit position and $\phi$
phit = ray.Apply (thit);
if (phit.x == 0.0 && phit.y == 0.0)
phit.x = 1E-5f * Radius;
phi = Math.Atan2 (phit.y, phit.x);
if (phi < 0.0)
phi += 2.0 * Util.Pi;
if ((zMin > -Radius && phit.z < zMin) || (zMax < Radius && phit.z > zMax) || phi > PhiMax)
return false;
}
// Find parametric representation of sphere hit
double u = phi / PhiMax;
double theta = Math.Acos (Util.Clamp (phit.z / Radius, -1.0, 1.0));
double v = (theta - ThetaMin) / (ThetaMax - ThetaMin);
// Compute sphere $\dpdu$ and $\dpdv$
double zRadius = Math.Sqrt (phit.x * phit.x + phit.y * phit.y);
double invzRadius = 1.0 / zRadius;
double cosphi = phit.x * invzRadius;
double sinphi = phit.y * invzRadius;
Vector dpdu = new Vector (-PhiMax * phit.y, PhiMax * phit.x, 0);
Vector dpdv = (ThetaMax - ThetaMin) * new Vector (phit.z * cosphi, phit.z * sinphi, -Radius * Math.Sin (theta));
// Compute sphere $\dndu$ and $\dndv$
Vector d2Pduu = -PhiMax * PhiMax * new Vector (phit.x, phit.y, 0);
Vector d2Pduv = (ThetaMax - ThetaMin) * phit.z * PhiMax * new Vector (-sinphi, cosphi, 0.0);
Vector d2Pdvv = -(ThetaMax - ThetaMin) * (ThetaMax - ThetaMin) * new Vector (phit.x, phit.y, phit.z);
// Compute coefficients for fundamental forms
double E = (dpdu ^ dpdu);
double F = (dpdu ^ dpdv);
double G = (dpdv ^ dpdv);
Vector N = (dpdu % dpdv).Normalized;
double e = (N ^ d2Pduu);
double f = (N ^ d2Pduv);
double g = (N ^ d2Pdvv);
// Compute $\dndu$ and $\dndv$ from fundamental form coefficients
double invEGF2 = 1.0 / (E * G - F * F);
Normal dndu = new Normal ((f * F - e * G) * invEGF2 * dpdu + (e * F - f * E) * invEGF2 * dpdv);
Normal dndv = new Normal ((g * F - f * G) * invEGF2 * dpdu + (f * F - g * E) * invEGF2 * dpdv);
// Initialize _DifferentialGeometry_ from parametric information
dg = new DifferentialGeometry (ObjectToWorld.Apply (phit), ObjectToWorld.Apply (dpdu), ObjectToWorld.Apply (dpdv), ObjectToWorld.Apply (dndu), ObjectToWorld.Apply (dndv), u, v, this);
// Update _tHit_ for quadric intersection
tHit = thit;
// Compute _rayEpsilon_ for quadric intersection
rayEpsilon = 0.0005 * tHit;
return true;
}
public override Spectrum L(Point p, Normal n, Vector w)
{
return (n ^ w) > 0.0 ? Lemit : new Spectrum ();
}
public virtual Point Sample(Point p, double u1, double u2, ref Normal Ns)
{
return Sample (u1, u2, ref Ns);
}
public override Point Sample(double u1, double u2, ref Normal Ns)
{
Point p1 = Mesh.Points[Vertices[0]];
Point p2 = Mesh.Points[Vertices[1]];
Point p3 = Mesh.Points[Vertices[2]];
double b1, b2;
MonteCarlo.UniformSampleTriangle (u1, u2, out b1, out b2);
Point p = b1 * p1 + b2 * p2 + (1.0 - b1 - b2) * p3;
Normal n = new Normal ((p2 - p1) % (p3 - p1));
Ns = n.Normalized;
if (ReverseOrientation)
Ns *= -1.0;
return p;
}
public override Point Sample(double u1, double u2, ref Normal Ns)
{
Point p = new Point () + Radius * MonteCarlo.UniformSampleSphere (u1, u2);
Ns = ObjectToWorld.Apply (new Normal (p.x, p.y, p.z)).Normalized;
if (ReverseOrientation)
Ns *= -1.0;
return ObjectToWorld.Apply (p);
}
public Vector(Normal vec)
: this(vec.x, vec.y, vec.z)
{
}
public override Point Sample(double u1, double u2, ref Normal Ns)
{
Point p = new Point ();
MonteCarlo.ConcentricSampleDisk (u1, u2, ref p.x, ref p.y);
p.x *= Radius;
p.y *= Radius;
p.z = Height;
Ns = ObjectToWorld.Apply (new Normal (0, 0, 1)).Normalized;
if (ReverseOrientation)
Ns *= -1.0;
return ObjectToWorld.Apply (p);
}