Exemple #1
0
static int print(const Spectrum &s) {
    Float rgb[3];
    s.ToRGB(rgb);
    int np = print(rgb[0]);
    np += print(rgb[1]);
    return np + print(rgb[2]);
}
Exemple #2
0
void SubsurfaceFromDiffuse(const Spectrum &Kd, float meanPathLength,
        float eta, Spectrum *sigma_a, Spectrum *sigma_prime_s) {
    float A = (1.f + Fdr(eta)) / (1.f - Fdr(eta));
    float rgb[3];
    Kd.ToRGB(rgb);
    float sigma_prime_s_rgb[3], sigma_a_rgb[3];
    for (int i = 0; i < 3; ++i) {
       float alphap = RdToAlphap(rgb[i], A);
       float sigma_tr = 1.f / meanPathLength;
       float sigma_prime_t = sigma_tr / sqrtf(3.f * 1.f - alphap);
       sigma_prime_s_rgb[i] = alphap * sigma_prime_t;
       sigma_a_rgb[i] = sigma_prime_t - sigma_prime_s_rgb[i];
    }
    *sigma_a = Spectrum::FromRGB(sigma_a_rgb);
    *sigma_prime_s = Spectrum::FromRGB(sigma_prime_s_rgb);
}
Exemple #3
0
void testMaterial(DifferentialGeometry &dg) {

	float c1[] = {1.f,1.f,1.f};
	Spectrum spec1 = RGBSpectrum::FromRGB(c1, SpectrumType::SPECTRUM_REFLECTANCE);

	MatteMaterial *matte = new MatteMaterial(
		new ConstantTexture<Spectrum>(spec1),
		new ConstantTexture<float>(0.0f), NULL);

	MemoryArena m;

	BSDF* bsdf = matte->GetBSDF(dg, dg, m);

	Vector woW = Point(-10,0,0) - dg.p;
	Vector wiW = Point(-7,2,2) - dg.p;
	// world vectors

	Spectrum spec = bsdf->f(woW, wiW);
	float rgb[3];
	spec.ToRGB(rgb);

	printf("spectrum %g %g %g\n", rgb[0], rgb[1], rgb[2]);

}
Exemple #4
0
// Integrator Utility Functions
Spectrum UniformSampleAllLights(const Scene *scene,
        const Renderer *renderer, MemoryArena &arena, const Point &p,
        const Normal &n, const Vector &wo, float rayEpsilon,
        float time, BSDF *bsdf, const Sample *sample, RNG &rng,
        const LightSampleOffsets *lightSampleOffsets,
        const BSDFSampleOffsets *bsdfSampleOffsets) {
    Spectrum L(0.);
    Spectrum zero(0.);
    Vector wi; // Normal vector to sample PBRT's BRDF
    wi.x = n.x;
    wi.y = n.y;
    wi.z = n.z;
    vector<cutvertex> cut; // Heap (based on error) of vertices in the cut
    cutvertex v;
    Spectrum total; // Store the total illumination for the current cut
    v.l = scene->lighttree; // Initial cut consists only the root
    SetError(v); // Compute it's error
    Factor(v); // Compute it's factor
    Illuminate(v); // Compute it's illumination
    total = v.illumination;
    cut.push_back(v);
    while(cut.size() < MAXCUT) {
        pop_heap(cut.begin(), cut.end()); // Get the vertex in the cut with the maximum error
        v = cut[cut.size() - 1];
        float err[3];
        float intensity[3];
        v.error.ToRGB(err);
        total.ToRGB(intensity);
        // Check if error is below the threshold. If so, we are done
        if(err[0] >= 0 && err[1] >= 0 && err[2] >= 0 && err[0] <= THRESHOLD * intensity[0] && err[1] <= THRESHOLD * intensity[1] && err[2] <= THRESHOLD * intensity[2])
            break;
        // If not, refine the cut by subdividing this vertex
        cut.pop_back(); // Remove the vertex from the cut
        total = total - v.illumination; // Remove the illumination due to this vertex
        cutvertex v1, v2; // We will add the vertex's children to the cut
        v1.l = v.l->leftChild;
        v2.l = v.l->rightChild;
        // Compute their errors and illumination
        SetError(v1);
        SetError(v2);
	if(v1.l != v.l) {
		Factor(v1);
	}
	else {
		v1.factor = v.factor;
	}
	if(v2.l != v.l) {
		Factor(v2);
	}
	else {
		v2.factor = v.factor;
	}
        Illuminate(v1);
        Illuminate(v2);
        // Add them to the cut and update the total illumination
        cut.push_back(v1);
        push_heap(cut.begin(), cut.end());
        total += v1.illumination;
        cut.push_back(v2);
        push_heap(cut.begin(), cut.end());
        total += v2.illumination;
    }
    return total;
}