Spectrum DiffusePRTIntegrator::Li(const Scene *scene, const Renderer *, const RayDifferential &ray, const Intersection &isect, const Sample *sample, MemoryArena &arena) const { Spectrum L = 0.f; Vector wo = -ray.d; // Compute emitted light if ray hit an area light source L += isect.Le(wo); // Evaluate BSDF at hit point BSDF *bsdf = isect.GetBSDF(ray, arena); const Point &p = bsdf->dgShading.p; const Normal &n = bsdf->dgShading.nn; // Compute reflected radiance using diffuse PRT // Project diffuse transfer function at point to SH Spectrum *c_transfer = arena.Alloc<Spectrum>(SHTerms(lmax)); SHComputeDiffuseTransfer(p, Faceforward(n, wo), isect.rayEpsilon, scene, *sample->rng, nSamples, lmax, c_transfer); // Compute integral of product of incident radiance and transfer function Spectrum LT = 0.f; for (int i = 0; i < SHTerms(lmax); ++i) LT += c_in[i] * c_transfer[i]; // Compute reflectance at point for diffuse transfer const int sqrtRhoSamples = 6; float rhoRSamples[2*sqrtRhoSamples*sqrtRhoSamples]; StratifiedSample2D(rhoRSamples, sqrtRhoSamples, sqrtRhoSamples, *sample->rng); Spectrum Kd = bsdf->rho(wo, sqrtRhoSamples*sqrtRhoSamples, rhoRSamples, BSDF_ALL_REFLECTION) * INV_PI; return L + Kd * LT.Clamp(); }
Spectrum UseRadianceProbes::Li(const Scene *scene, const Renderer *renderer, const RayDifferential &ray, const Intersection &isect, const Sample *sample, RNG &rng, MemoryArena &arena, int wavelength) const { Spectrum L(0.); Vector wo = -ray.d; // Compute emitted light if ray hit an area light source L += isect.Le(wo); // Evaluate BSDF at hit point BSDF *bsdf = isect.GetBSDF(ray, arena, wavelength); const Point &p = bsdf->dgShading.p; const Normal &n = bsdf->dgShading.nn; // Compute reflection for radiance probes integrator if (!includeDirectInProbes) L += UniformSampleAllLights(scene, renderer, arena, p, n, wo, isect.rayEpsilon, ray.time, bsdf, sample, rng, lightSampleOffsets, bsdfSampleOffsets); // Compute reflected lighting using radiance probes // Compute probe coordinates and offsets for lookup point Vector offset = bbox.Offset(p); float voxx = (offset.x * nProbes[0]) - 0.5f; float voxy = (offset.y * nProbes[1]) - 0.5f; float voxz = (offset.z * nProbes[2]) - 0.5f; int vx = Floor2Int(voxx), vy = Floor2Int(voxy), vz = Floor2Int(voxz); float dx = voxx - vx, dy = voxy - vy, dz = voxz - vz; // Get radiance probe coefficients around lookup point const Spectrum *b000 = c_inXYZ(lmax, vx, vy, vz); const Spectrum *b100 = c_inXYZ(lmax, vx+1, vy, vz); const Spectrum *b010 = c_inXYZ(lmax, vx, vy+1, vz); const Spectrum *b110 = c_inXYZ(lmax, vx+1, vy+1, vz); const Spectrum *b001 = c_inXYZ(lmax, vx, vy, vz+1); const Spectrum *b101 = c_inXYZ(lmax, vx+1, vy, vz+1); const Spectrum *b011 = c_inXYZ(lmax, vx, vy+1, vz+1); const Spectrum *b111 = c_inXYZ(lmax, vx+1, vy+1, vz+1); // Compute incident radiance from radiance probe coefficients Spectrum *c_inp = arena.Alloc<Spectrum>(SHTerms(lmax)); for (int i = 0; i < SHTerms(lmax); ++i) { // Do trilinear interpolation to compute SH coefficients at point Spectrum c00 = Lerp(dx, b000[i], b100[i]); Spectrum c10 = Lerp(dx, b010[i], b110[i]); Spectrum c01 = Lerp(dx, b001[i], b101[i]); Spectrum c11 = Lerp(dx, b011[i], b111[i]); Spectrum c0 = Lerp(dy, c00, c10); Spectrum c1 = Lerp(dy, c01, c11); c_inp[i] = Lerp(dz, c0, c1); } // Convolve incident radiance to compute irradiance function Spectrum *c_E = arena.Alloc<Spectrum>(SHTerms(lmax)); SHConvolveCosTheta(lmax, c_inp, c_E); // Evaluate irradiance function and accumulate reflection Spectrum rho = bsdf->rho(wo, rng, BSDF_ALL_REFLECTION); float *Ylm = ALLOCA(float, SHTerms(lmax)); SHEvaluate(Vector(Faceforward(n, wo)), lmax, Ylm); Spectrum E = 0.f; for (int i = 0; i < SHTerms(lmax); ++i) E += c_E[i] * Ylm[i]; L += rho * INV_PI * E.Clamp(); return L; }
void IGIIntegrator::Preprocess(const Scene *scene, const Camera *camera, const Renderer *renderer) { if (scene->lights.size() == 0) return; MemoryArena arena; RNG rng; // Compute samples for emitted rays from lights vector<float> lightNum(nLightPaths * nLightSets); vector<float> lightSampPos(2 * nLightPaths * nLightSets, 0.f); vector<float> lightSampComp(nLightPaths * nLightSets, 0.f); vector<float> lightSampDir(2 * nLightPaths * nLightSets, 0.f); LDShuffleScrambled1D(nLightPaths, nLightSets, &lightNum[0], rng); LDShuffleScrambled2D(nLightPaths, nLightSets, &lightSampPos[0], rng); LDShuffleScrambled1D(nLightPaths, nLightSets, &lightSampComp[0], rng); LDShuffleScrambled2D(nLightPaths, nLightSets, &lightSampDir[0], rng); // Precompute information for light sampling densities Distribution1D *lightDistribution = ComputeLightSamplingCDF(scene); for (uint32_t s = 0; s < nLightSets; ++s) { for (uint32_t i = 0; i < nLightPaths; ++i) { // Follow path _i_ from light to create virtual lights int sampOffset = s*nLightPaths + i; // Choose light source to trace virtual light path from float lightPdf; int ln = lightDistribution->SampleDiscrete(lightNum[sampOffset], &lightPdf); Light *light = scene->lights[ln]; // Sample ray leaving light source for virtual light path RayDifferential ray; float pdf; LightSample ls(lightSampPos[2*sampOffset], lightSampPos[2*sampOffset+1], lightSampComp[sampOffset]); Normal Nl; Spectrum alpha = light->Sample_L(scene, ls, lightSampDir[2*sampOffset], lightSampDir[2*sampOffset+1], camera->shutterOpen, &ray, &Nl, &pdf); if (pdf == 0.f || alpha.IsBlack()) continue; alpha /= pdf * lightPdf; Intersection isect; while (scene->Intersect(ray, &isect) && !alpha.IsBlack()) { // Create virtual light and sample new ray for path alpha *= renderer->Transmittance(scene, RayDifferential(ray), NULL, rng, arena); Vector wo = -ray.d; BSDF *bsdf = isect.GetBSDF(ray, arena); // Create virtual light at ray intersection point Spectrum contrib = alpha * bsdf->rho(wo, rng) / M_PI; virtualLights[s].push_back(VirtualLight(isect.dg.p, isect.dg.nn, contrib, isect.rayEpsilon)); // Sample new ray direction and update weight for virtual light path Vector wi; float pdf; BSDFSample bsdfSample(rng); Spectrum fr = bsdf->Sample_f(wo, &wi, bsdfSample, &pdf); if (fr.IsBlack() || pdf == 0.f) break; Spectrum contribScale = fr * AbsDot(wi, bsdf->dgShading.nn) / pdf; // Possibly terminate virtual light path with Russian roulette float rrProb = min(1.f, contribScale.y()); if (rng.RandomFloat() > rrProb) break; alpha *= contribScale / rrProb; ray = RayDifferential(isect.dg.p, wi, ray, isect.rayEpsilon); } arena.FreeAll(); } } delete lightDistribution; }
Spectrum IrradianceCache::IndirectLo(const Point &p, const Normal &n, const Vector &wo, BSDF *bsdf, BxDFType flags, const Sample *sample, const Scene *scene) const { if (bsdf->NumComponents(flags) == 0) return Spectrum(0.); Spectrum E; if (!InterpolateIrradiance(scene, p, n, &E)) { // Compute irradiance at current point u_int scramble[2] = { RandomUInt(), RandomUInt() }; float sumInvDists = 0.; for (int i = 0; i < nSamples; ++i) { // Trace ray to sample radiance for irradiance estimate // Update irradiance statistics for rays traced static StatsCounter nIrradiancePaths("Irradiance Cache", "Paths followed for irradiance estimates"); ++nIrradiancePaths; float u[2]; Sample02(i, scramble, u); Vector w = CosineSampleHemisphere(u[0], u[1]); RayDifferential r(p, bsdf->LocalToWorld(w)); if (Dot(r.d, n) < 0) r.d = -r.d; Spectrum L(0.); // Do path tracing to compute radiance along ray for estimate { // Declare common path integration variables Spectrum pathThroughput = 1.; RayDifferential ray(r); bool specularBounce = false; for (int pathLength = 0; ; ++pathLength) { // Find next vertex of path Intersection isect; if (!scene->Intersect(ray, &isect)) break; if (pathLength == 0) r.maxt = ray.maxt; pathThroughput *= scene->Transmittance(ray); // Possibly add emitted light at path vertex if (specularBounce) L += pathThroughput * isect.Le(-ray.d); // Evaluate BSDF at hit point BSDF *bsdf = isect.GetBSDF(ray); // Sample illumination from lights to find path contribution const Point &p = bsdf->dgShading.p; const Normal &n = bsdf->dgShading.nn; Vector wo = -ray.d; L += pathThroughput * UniformSampleOneLight(scene, p, n, wo, bsdf, sample); if (pathLength+1 == maxIndirectDepth) break; // Sample BSDF to get new path direction // Get random numbers for sampling new direction, \mono{bs1}, \mono{bs2}, and \mono{bcs} float bs1 = RandomFloat(), bs2 = RandomFloat(), bcs = RandomFloat(); Vector wi; float pdf; BxDFType flags; Spectrum f = bsdf->Sample_f(wo, &wi, bs1, bs2, bcs, &pdf, BSDF_ALL, &flags); if (f.Black() || pdf == 0.) break; specularBounce = (flags & BSDF_SPECULAR) != 0; pathThroughput *= f * AbsDot(wi, n) / pdf; ray = RayDifferential(p, wi); // Possibly terminate the path if (pathLength > 3) { float continueProbability = .5f; if (RandomFloat() > continueProbability) break; pathThroughput /= continueProbability; } } } E += L; float dist = r.maxt * r.d.Length(); sumInvDists += 1.f / dist; } E *= M_PI / float(nSamples); // Add computed irradiance value to cache // Update statistics for new irradiance sample static StatsCounter nSamplesComputed("Irradiance Cache", "Irradiance estimates computed"); ++nSamplesComputed; // Compute bounding box of irradiance sample's contribution region static float minMaxDist = .001f * powf(scene->WorldBound().Volume(), 1.f/3.f); static float maxMaxDist = .125f * powf(scene->WorldBound().Volume(), 1.f/3.f); float maxDist = nSamples / sumInvDists; if (minMaxDist > 0.f) maxDist = Clamp(maxDist, minMaxDist, maxMaxDist); maxDist *= maxError; BBox sampleExtent(p); sampleExtent.Expand(maxDist); octree->Add(IrradianceSample(E, p, n, maxDist), sampleExtent); } return .5f * bsdf->rho(wo, flags) * E; }
void PhotonShootingTask::Run() { // Declare local variables for _PhotonShootingTask_ MemoryArena arena; RNG rng(31 * taskNum); vector<Photon> localDirectPhotons, localIndirectPhotons, localCausticPhotons; vector<RadiancePhoton> localRadiancePhotons; uint32_t totalPaths = 0; bool causticDone = (integrator->nCausticPhotonsWanted == 0); bool indirectDone = (integrator->nIndirectPhotonsWanted == 0); PermutedHalton halton(6, rng); vector<Spectrum> localRpReflectances, localRpTransmittances; while (true) { // Follow photon paths for a block of samples const uint32_t blockSize = 4096; for (uint32_t i = 0; i < blockSize; ++i) { float u[6]; halton.Sample(++totalPaths, u); // Choose light to shoot photon from float lightPdf; int lightNum = lightDistribution->SampleDiscrete(u[0], &lightPdf); const Light *light = scene->lights[lightNum]; // Generate _photonRay_ from light source and initialize _alpha_ RayDifferential photonRay; float pdf; LightSample ls(u[1], u[2], u[3]); Normal Nl; Spectrum Le = light->Sample_L(scene, ls, u[4], u[5], time, &photonRay, &Nl, &pdf); if (pdf == 0.f || Le.IsBlack()) continue; Spectrum alpha = (AbsDot(Nl, photonRay.d) * Le) / (pdf * lightPdf); if (!alpha.IsBlack()) { // Follow photon path through scene and record intersections PBRT_PHOTON_MAP_STARTED_RAY_PATH(&photonRay, &alpha); bool specularPath = true; Intersection photonIsect; int nIntersections = 0; while (scene->Intersect(photonRay, &photonIsect)) { ++nIntersections; // Handle photon/surface intersection alpha *= renderer->Transmittance(scene, photonRay, NULL, rng, arena); BSDF *photonBSDF = photonIsect.GetBSDF(photonRay, arena); BxDFType specularType = BxDFType(BSDF_REFLECTION | BSDF_TRANSMISSION | BSDF_SPECULAR); bool hasNonSpecular = (photonBSDF->NumComponents() > photonBSDF->NumComponents(specularType)); Vector wo = -photonRay.d; if (hasNonSpecular) { // Deposit photon at surface Photon photon(photonIsect.dg.p, alpha, wo); bool depositedPhoton = false; if (specularPath && nIntersections > 1) { if (!causticDone) { PBRT_PHOTON_MAP_DEPOSITED_CAUSTIC_PHOTON(&photonIsect.dg, &alpha, &wo); depositedPhoton = true; localCausticPhotons.push_back(photon); } } else { // Deposit either direct or indirect photon // stop depositing direct photons once indirectDone is true; don't // want to waste memory storing too many if we're going a long time // trying to get enough caustic photons desposited. if (nIntersections == 1 && !indirectDone && integrator->finalGather) { PBRT_PHOTON_MAP_DEPOSITED_DIRECT_PHOTON(&photonIsect.dg, &alpha, &wo); depositedPhoton = true; localDirectPhotons.push_back(photon); } else if (nIntersections > 1 && !indirectDone) { PBRT_PHOTON_MAP_DEPOSITED_INDIRECT_PHOTON(&photonIsect.dg, &alpha, &wo); depositedPhoton = true; localIndirectPhotons.push_back(photon); } } // Possibly create radiance photon at photon intersection point if (depositedPhoton && integrator->finalGather && rng.RandomFloat() < .125f) { Normal n = photonIsect.dg.nn; n = Faceforward(n, -photonRay.d); localRadiancePhotons.push_back(RadiancePhoton(photonIsect.dg.p, n)); Spectrum rho_r = photonBSDF->rho(rng, BSDF_ALL_REFLECTION); localRpReflectances.push_back(rho_r); Spectrum rho_t = photonBSDF->rho(rng, BSDF_ALL_TRANSMISSION); localRpTransmittances.push_back(rho_t); } } if (nIntersections >= integrator->maxPhotonDepth) break; // Sample new photon ray direction Vector wi; float pdf; BxDFType flags; Spectrum fr = photonBSDF->Sample_f(wo, &wi, BSDFSample(rng), &pdf, BSDF_ALL, &flags); if (fr.IsBlack() || pdf == 0.f) break; Spectrum anew = alpha * fr * AbsDot(wi, photonBSDF->dgShading.nn) / pdf; // Possibly terminate photon path with Russian roulette float continueProb = min(1.f, anew.y() / alpha.y()); if (rng.RandomFloat() > continueProb) break; alpha = anew / continueProb; specularPath &= ((flags & BSDF_SPECULAR) != 0); if (indirectDone && !specularPath) break; photonRay = RayDifferential(photonIsect.dg.p, wi, photonRay, photonIsect.rayEpsilon); } PBRT_PHOTON_MAP_FINISHED_RAY_PATH(&photonRay, &alpha); } arena.FreeAll(); } // Merge local photon data with data in _PhotonIntegrator_ { MutexLock lock(mutex); // Give up if we're not storing enough photons if (abortTasks) return; if (nshot > 500000 && (unsuccessful(integrator->nCausticPhotonsWanted, causticPhotons.size(), blockSize) || unsuccessful(integrator->nIndirectPhotonsWanted, indirectPhotons.size(), blockSize))) { Error("Unable to store enough photons. Giving up.\n"); causticPhotons.erase(causticPhotons.begin(), causticPhotons.end()); indirectPhotons.erase(indirectPhotons.begin(), indirectPhotons.end()); radiancePhotons.erase(radiancePhotons.begin(), radiancePhotons.end()); abortTasks = true; return; } progress.Update(localIndirectPhotons.size() + localCausticPhotons.size()); nshot += blockSize; // Merge indirect photons into shared array if (!indirectDone) { integrator->nIndirectPaths += blockSize; for (uint32_t i = 0; i < localIndirectPhotons.size(); ++i) indirectPhotons.push_back(localIndirectPhotons[i]); localIndirectPhotons.erase(localIndirectPhotons.begin(), localIndirectPhotons.end()); if (indirectPhotons.size() >= integrator->nIndirectPhotonsWanted) indirectDone = true; nDirectPaths += blockSize; for (uint32_t i = 0; i < localDirectPhotons.size(); ++i) directPhotons.push_back(localDirectPhotons[i]); localDirectPhotons.erase(localDirectPhotons.begin(), localDirectPhotons.end()); } // Merge direct, caustic, and radiance photons into shared array if (!causticDone) { integrator->nCausticPaths += blockSize; for (uint32_t i = 0; i < localCausticPhotons.size(); ++i) causticPhotons.push_back(localCausticPhotons[i]); localCausticPhotons.erase(localCausticPhotons.begin(), localCausticPhotons.end()); if (causticPhotons.size() >= integrator->nCausticPhotonsWanted) causticDone = true; } for (uint32_t i = 0; i < localRadiancePhotons.size(); ++i) radiancePhotons.push_back(localRadiancePhotons[i]); localRadiancePhotons.erase(localRadiancePhotons.begin(), localRadiancePhotons.end()); for (uint32_t i = 0; i < localRpReflectances.size(); ++i) rpReflectances.push_back(localRpReflectances[i]); localRpReflectances.erase(localRpReflectances.begin(), localRpReflectances.end()); for (uint32_t i = 0; i < localRpTransmittances.size(); ++i) rpTransmittances.push_back(localRpTransmittances[i]); localRpTransmittances.erase(localRpTransmittances.begin(), localRpTransmittances.end()); } // Exit task if enough photons have been found if (indirectDone && causticDone) break; } }
void ExPhotonIntegrator::Preprocess(const Scene *scene) { if (scene->lights.size() == 0) return; ProgressReporter progress(nCausticPhotons+ // NOBOOK nIndirectPhotons, "Shooting photons"); // NOBOOK vector<Photon> causticPhotons; vector<Photon> indirectPhotons; vector<Photon> directPhotons; vector<RadiancePhoton> radiancePhotons; causticPhotons.reserve(nCausticPhotons); // NOBOOK indirectPhotons.reserve(nIndirectPhotons); // NOBOOK // Initialize photon shooting statistics static StatsCounter nshot("Photon Map", "Number of photons shot from lights"); bool causticDone = (nCausticPhotons == 0); bool indirectDone = (nIndirectPhotons == 0); // Compute light power CDF for photon shooting int nLights = int(scene->lights.size()); float *lightPower = (float *)alloca(nLights * sizeof(float)); float *lightCDF = (float *)alloca((nLights+1) * sizeof(float)); for (int i = 0; i < nLights; ++i) lightPower[i] = scene->lights[i]->Power(scene).y(); float totalPower; ComputeStep1dCDF(lightPower, nLights, &totalPower, lightCDF); // Declare radiance photon reflectance arrays vector<Spectrum> rpReflectances, rpTransmittances; while (!causticDone || !indirectDone) { ++nshot; // Give up if we're not storing enough photons if (nshot > 500000 && (unsuccessful(nCausticPhotons, causticPhotons.size(), nshot) || unsuccessful(nIndirectPhotons, indirectPhotons.size(), nshot))) { Error("Unable to store enough photons. Giving up.\n"); return; } // Trace a photon path and store contribution // Choose 4D sample values for photon float u[4]; u[0] = RadicalInverse((int)nshot+1, 2); u[1] = RadicalInverse((int)nshot+1, 3); u[2] = RadicalInverse((int)nshot+1, 5); u[3] = RadicalInverse((int)nshot+1, 7); // Choose light to shoot photon from float lightPdf; float uln = RadicalInverse((int)nshot+1, 11); int lightNum = Floor2Int(SampleStep1d(lightPower, lightCDF, totalPower, nLights, uln, &lightPdf) * nLights); lightNum = min(lightNum, nLights-1); const Light *light = scene->lights[lightNum]; // Generate _photonRay_ from light source and initialize _alpha_ RayDifferential photonRay; float pdf; Spectrum alpha = light->Sample_L(scene, u[0], u[1], u[2], u[3], &photonRay, &pdf); if (pdf == 0.f || alpha.Black()) continue; alpha /= pdf * lightPdf; if (!alpha.Black()) { // Follow photon path through scene and record intersections bool specularPath = false; Intersection photonIsect; int nIntersections = 0; while (scene->Intersect(photonRay, &photonIsect)) { ++nIntersections; // Handle photon/surface intersection alpha *= scene->Transmittance(photonRay); Vector wo = -photonRay.d; BSDF *photonBSDF = photonIsect.GetBSDF(photonRay); BxDFType specularType = BxDFType(BSDF_REFLECTION | BSDF_TRANSMISSION | BSDF_SPECULAR); bool hasNonSpecular = (photonBSDF->NumComponents() > photonBSDF->NumComponents(specularType)); if (hasNonSpecular) { // Deposit photon at surface Photon photon(photonIsect.dg.p, alpha, wo); if (nIntersections == 1) { // Deposit direct photon directPhotons.push_back(photon); } else { // Deposit either caustic or indirect photon if (specularPath) { // Process caustic photon intersection if (!causticDone) { causticPhotons.push_back(photon); if (causticPhotons.size() == nCausticPhotons) { causticDone = true; nCausticPaths = (int)nshot; causticMap = new KdTree<Photon, PhotonProcess>(causticPhotons); } progress.Update(); } } else { // Process indirect lighting photon intersection if (!indirectDone) { indirectPhotons.push_back(photon); if (indirectPhotons.size() == nIndirectPhotons) { indirectDone = true; nIndirectPaths = (int)nshot; indirectMap = new KdTree<Photon, PhotonProcess>(indirectPhotons); } progress.Update(); } } } if (finalGather && RandomFloat() < .125f) { // Store data for radiance photon static StatsCounter rp("Photon Map", "Radiance photons created"); // NOBOOK ++rp; // NOBOOK Normal n = photonIsect.dg.nn; if (Dot(n, photonRay.d) > 0.f) n = -n; radiancePhotons.push_back(RadiancePhoton(photonIsect.dg.p, n)); Spectrum rho_r = photonBSDF->rho(BSDF_ALL_REFLECTION); rpReflectances.push_back(rho_r); Spectrum rho_t = photonBSDF->rho(BSDF_ALL_TRANSMISSION); rpTransmittances.push_back(rho_t); } } // Sample new photon ray direction Vector wi; float pdf; BxDFType flags; // Get random numbers for sampling outgoing photon direction float u1, u2, u3; if (nIntersections == 1) { u1 = RadicalInverse((int)nshot+1, 13); u2 = RadicalInverse((int)nshot+1, 17); u3 = RadicalInverse((int)nshot+1, 19); } else { u1 = RandomFloat(); u2 = RandomFloat(); u3 = RandomFloat(); } // Compute new photon weight and possibly terminate with RR Spectrum fr = photonBSDF->Sample_f(wo, &wi, u1, u2, u3, &pdf, BSDF_ALL, &flags); if (fr.Black() || pdf == 0.f) break; Spectrum anew = alpha * fr * AbsDot(wi, photonBSDF->dgShading.nn) / pdf; float continueProb = min(1.f, anew.y() / alpha.y()); if (RandomFloat() > continueProb || nIntersections > 10) break; alpha = anew / continueProb; specularPath = (nIntersections == 1 || specularPath) && ((flags & BSDF_SPECULAR) != 0); photonRay = RayDifferential(photonIsect.dg.p, wi); } } BSDF::FreeAll(); } progress.Done(); // NOBOOK // Precompute radiance at a subset of the photons KdTree<Photon, PhotonProcess> directMap(directPhotons); int nDirectPaths = nshot; if (finalGather) { ProgressReporter p2(radiancePhotons.size(), "Computing photon radiances"); // NOBOOK for (u_int i = 0; i < radiancePhotons.size(); ++i) { // Compute radiance for radiance photon _i_ RadiancePhoton &rp = radiancePhotons[i]; const Spectrum &rho_r = rpReflectances[i]; const Spectrum &rho_t = rpTransmittances[i]; Spectrum E; Point p = rp.p; Normal n = rp.n; if (!rho_r.Black()) { E = estimateE(&directMap, nDirectPaths, p, n) + estimateE(indirectMap, nIndirectPaths, p, n) + estimateE(causticMap, nCausticPaths, p, n); rp.Lo += E * INV_PI * rho_r; } if (!rho_t.Black()) { E = estimateE(&directMap, nDirectPaths, p, -n) + estimateE(indirectMap, nIndirectPaths, p, -n) + estimateE(causticMap, nCausticPaths, p, -n); rp.Lo += E * INV_PI * rho_t; } p2.Update(); // NOBOOK } radianceMap = new KdTree<RadiancePhoton, RadiancePhotonProcess>(radiancePhotons); p2.Done(); // NOBOOK } }
void IGIIntegrator::Preprocess(const Scene *scene) { if (scene->lights.size() == 0) return; // Compute samples for emitted rays from lights float *lightNum = new float[nLightPaths * nLightSets]; float *lightSamp0 = new float[2 * nLightPaths * nLightSets]; float *lightSamp1 = new float[2 * nLightPaths * nLightSets]; LDShuffleScrambled1D(nLightPaths, nLightSets, lightNum); LDShuffleScrambled2D(nLightPaths, nLightSets, lightSamp0); LDShuffleScrambled2D(nLightPaths, nLightSets, lightSamp1); // Precompute information for light sampling densities int nLights = int(scene->lights.size()); float *lightPower = (float *)alloca(nLights * sizeof(float)); float *lightCDF = (float *)alloca((nLights+1) * sizeof(float)); for (int i = 0; i < nLights; ++i) lightPower[i] = scene->lights[i]->Power(scene).y(); float totalPower; ComputeStep1dCDF(lightPower, nLights, &totalPower, lightCDF); for (u_int s = 0; s < nLightSets; ++s) { for (u_int i = 0; i < nLightPaths; ++i) { // Follow path _i_ from light to create virtual lights int sampOffset = s*nLightPaths + i; // Choose light source to trace path from float lightPdf; int lNum = Floor2Int(SampleStep1d(lightPower, lightCDF, totalPower, nLights, lightNum[sampOffset], &lightPdf) * nLights); // fprintf(stderr, "samp %f -> num %d\n", lightNum[sampOffset], lNum); Light *light = scene->lights[lNum]; // Sample ray leaving light source RayDifferential ray; float pdf; Spectrum alpha = light->Sample_L(scene, lightSamp0[2*sampOffset], lightSamp0[2*sampOffset+1], lightSamp1[2*sampOffset], lightSamp1[2*sampOffset+1], &ray, &pdf); if (pdf == 0.f || alpha.Black()) continue; alpha /= pdf * lightPdf; // fprintf(stderr, "initial alpha %f, light # %d\n", alpha.y(), lNum); Intersection isect; int nIntersections = 0; while (scene->Intersect(ray, &isect) && !alpha.Black()) { ++nIntersections; alpha *= scene->Transmittance(ray); Vector wo = -ray.d; BSDF *bsdf = isect.GetBSDF(ray); // Create virtual light at ray intersection point static StatsCounter vls("IGI Integrator", "Virtual Lights Created"); //NOBOOK ++vls; //NOBOOK Spectrum Le = alpha * bsdf->rho(wo) / M_PI; // fprintf(stderr, "\tmade light with le y %f\n", Le.y()); virtualLights[s].push_back(VirtualLight(isect.dg.p, isect.dg.nn, Le)); // Sample new ray direction and update weight Vector wi; float pdf; BxDFType flags; Spectrum fr = bsdf->Sample_f(wo, &wi, RandomFloat(), RandomFloat(), RandomFloat(), &pdf, BSDF_ALL, &flags); if (fr.Black() || pdf == 0.f) break; Spectrum anew = alpha * fr * AbsDot(wi, bsdf->dgShading.nn) / pdf; float r = anew.y() / alpha.y(); // fprintf(stderr, "\tr = %f\n", r); if (RandomFloat() > r) break; alpha = anew / r; // fprintf(stderr, "\tnew alpha %f\n", alpha.y()); ray = RayDifferential(isect.dg.p, wi); } BSDF::FreeAll(); } } delete[] lightNum; // NOBOOK delete[] lightSamp0; // NOBOOK delete[] lightSamp1; // NOBOOK }