void Film::AddSplat(const Point2f &p, const Spectrum &v) { if (v.HasNaNs()) { Warning("Film ignoring splatted spectrum with NaN values"); return; } ProfilePhase pp(Prof::SplatFilm); if (!InsideExclusive((Point2i)p, croppedPixelBounds)) return; Float xyz[3]; v.ToXYZ(xyz); Pixel &pixel = GetPixel((Point2i)p); for (int i = 0; i < 3; ++i) pixel.splatXYZ[i].Add(xyz[i]); }
void BDPTIntegrator::Render(const Scene &scene) { std::unique_ptr<LightDistribution> lightDistribution = CreateLightSampleDistribution(lightSampleStrategy, scene); // Compute a reverse mapping from light pointers to offsets into the // scene lights vector (and, equivalently, offsets into // lightDistr). Added after book text was finalized; this is critical // to reasonable performance with 100s+ of light sources. std::unordered_map<const Light *, size_t> lightToIndex; for (size_t i = 0; i < scene.lights.size(); ++i) lightToIndex[scene.lights[i].get()] = i; // Partition the image into tiles Film *film = camera->film; const Bounds2i sampleBounds = film->GetSampleBounds(); const Vector2i sampleExtent = sampleBounds.Diagonal(); const int tileSize = 16; const int nXTiles = (sampleExtent.x + tileSize - 1) / tileSize; const int nYTiles = (sampleExtent.y + tileSize - 1) / tileSize; ProgressReporter reporter(nXTiles * nYTiles, "Rendering"); // Allocate buffers for debug visualization const int bufferCount = (1 + maxDepth) * (6 + maxDepth) / 2; std::vector<std::unique_ptr<Film>> weightFilms(bufferCount); if (visualizeStrategies || visualizeWeights) { for (int depth = 0; depth <= maxDepth; ++depth) { for (int s = 0; s <= depth + 2; ++s) { int t = depth + 2 - s; if (t == 0 || (s == 1 && t == 1)) continue; std::string filename = StringPrintf("bdpt_d%02i_s%02i_t%02i.exr", depth, s, t); weightFilms[BufferIndex(s, t)] = std::unique_ptr<Film>(new Film( film->fullResolution, Bounds2f(Point2f(0, 0), Point2f(1, 1)), std::unique_ptr<Filter>(CreateBoxFilter(ParamSet())), film->diagonal * 1000, filename, 1.f)); } } } // Render and write the output image to disk if (scene.lights.size() > 0) { ParallelFor2D([&](const Point2i tile) { // Render a single tile using BDPT MemoryArena arena; int seed = tile.y * nXTiles + tile.x; std::unique_ptr<Sampler> tileSampler = sampler->Clone(seed); int x0 = sampleBounds.pMin.x + tile.x * tileSize; int x1 = std::min(x0 + tileSize, sampleBounds.pMax.x); int y0 = sampleBounds.pMin.y + tile.y * tileSize; int y1 = std::min(y0 + tileSize, sampleBounds.pMax.y); Bounds2i tileBounds(Point2i(x0, y0), Point2i(x1, y1)); std::unique_ptr<FilmTile> filmTile = camera->film->GetFilmTile(tileBounds); for (Point2i pPixel : tileBounds) { tileSampler->StartPixel(pPixel); if (!InsideExclusive(pPixel, pixelBounds)) continue; do { // Generate a single sample using BDPT Point2f pFilm = (Point2f)pPixel + tileSampler->Get2D(); // Trace the camera subpath Vertex *cameraVertices = arena.Alloc<Vertex>(maxDepth + 2); Vertex *lightVertices = arena.Alloc<Vertex>(maxDepth + 1); int nCamera = GenerateCameraSubpath( scene, *tileSampler, arena, maxDepth + 2, *camera, pFilm, cameraVertices); // Get a distribution for sampling the light at the // start of the light subpath. Because the light path // follows multiple bounces, basing the sampling // distribution on any of the vertices of the camera // path is unlikely to be a good strategy. We use the // PowerLightDistribution by default here, which // doesn't use the point passed to it. const Distribution1D *lightDistr = lightDistribution->Lookup(cameraVertices[0].p()); // Now trace the light subpath int nLight = GenerateLightSubpath( scene, *tileSampler, arena, maxDepth + 1, cameraVertices[0].time(), *lightDistr, lightToIndex, lightVertices); // Execute all BDPT connection strategies Spectrum L(0.f); for (int t = 1; t <= nCamera; ++t) { for (int s = 0; s <= nLight; ++s) { int depth = t + s - 2; if ((s == 1 && t == 1) || depth < 0 || depth > maxDepth) continue; // Execute the $(s, t)$ connection strategy and // update _L_ Point2f pFilmNew = pFilm; Float misWeight = 0.f; Spectrum Lpath = ConnectBDPT( scene, lightVertices, cameraVertices, s, t, *lightDistr, lightToIndex, *camera, *tileSampler, &pFilmNew, &misWeight); VLOG(2) << "Connect bdpt s: " << s <<", t: " << t << ", Lpath: " << Lpath << ", misWeight: " << misWeight; if (visualizeStrategies || visualizeWeights) { Spectrum value; if (visualizeStrategies) value = misWeight == 0 ? 0 : Lpath / misWeight; if (visualizeWeights) value = Lpath; weightFilms[BufferIndex(s, t)]->AddSplat( pFilmNew, value); } if (t != 1) L += Lpath; else film->AddSplat(pFilmNew, Lpath); } } VLOG(2) << "Add film sample pFilm: " << pFilm << ", L: " << L << ", (y: " << L.y() << ")"; filmTile->AddSample(pFilm, L); arena.Reset(); } while (tileSampler->StartNextSample()); } film->MergeFilmTile(std::move(filmTile)); reporter.Update(); }, Point2i(nXTiles, nYTiles)); reporter.Done(); } film->WriteImage(1.0f / sampler->samplesPerPixel); // Write buffers for debug visualization if (visualizeStrategies || visualizeWeights) { const Float invSampleCount = 1.0f / sampler->samplesPerPixel; for (size_t i = 0; i < weightFilms.size(); ++i) if (weightFilms[i]) weightFilms[i]->WriteImage(invSampleCount); } }
void BDPTIntegrator::Render(const Scene &scene) { ProfilePhase p(Prof::IntegratorRender); // Compute _lightDistr_ for sampling lights proportional to power std::unique_ptr<Distribution1D> lightDistr = ComputeLightPowerDistribution(scene); // Partition the image into tiles Film *film = camera->film; const Bounds2i sampleBounds = film->GetSampleBounds(); const Vector2i sampleExtent = sampleBounds.Diagonal(); const int tileSize = 16; const int nXTiles = (sampleExtent.x + tileSize - 1) / tileSize; const int nYTiles = (sampleExtent.y + tileSize - 1) / tileSize; ProgressReporter reporter(nXTiles * nYTiles, "Rendering"); // Allocate buffers for debug visualization const int bufferCount = (1 + maxDepth) * (6 + maxDepth) / 2; std::vector<std::unique_ptr<Film>> weightFilms(bufferCount); if (visualizeStrategies || visualizeWeights) { for (int depth = 0; depth <= maxDepth; ++depth) { for (int s = 0; s <= depth + 2; ++s) { int t = depth + 2 - s; if (t == 0 || (s == 1 && t == 1)) continue; std::string filename = StringPrintf("bdpt_d%02i_s%02i_t%02i.exr", depth, s, t); weightFilms[BufferIndex(s, t)] = std::unique_ptr<Film>(new Film( film->fullResolution, Bounds2f(Point2f(0, 0), Point2f(1, 1)), std::unique_ptr<Filter>(CreateBoxFilter(ParamSet())), film->diagonal * 1000, filename, 1.f)); } } } // Render and write the output image to disk if (scene.lights.size() > 0) { StatTimer timer(&renderingTime); ParallelFor2D([&](const Point2i tile) { // Render a single tile using BDPT MemoryArena arena; int seed = tile.y * nXTiles + tile.x; std::unique_ptr<Sampler> tileSampler = sampler->Clone(seed); int x0 = sampleBounds.pMin.x + tile.x * tileSize; int x1 = std::min(x0 + tileSize, sampleBounds.pMax.x); int y0 = sampleBounds.pMin.y + tile.y * tileSize; int y1 = std::min(y0 + tileSize, sampleBounds.pMax.y); Bounds2i tileBounds(Point2i(x0, y0), Point2i(x1, y1)); std::unique_ptr<FilmTile> filmTile = camera->film->GetFilmTile(tileBounds); for (Point2i pPixel : tileBounds) { tileSampler->StartPixel(pPixel); if (!InsideExclusive(pPixel, pixelBounds)) continue; do { // Generate a single sample using BDPT Point2f pFilm = (Point2f)pPixel + tileSampler->Get2D(); // Trace the camera and light subpaths Vertex *cameraVertices = arena.Alloc<Vertex>(maxDepth + 2); Vertex *lightVertices = arena.Alloc<Vertex>(maxDepth + 1); int nCamera = GenerateCameraSubpath( scene, *tileSampler, arena, maxDepth + 2, *camera, pFilm, cameraVertices); int nLight = GenerateLightSubpath( scene, *tileSampler, arena, maxDepth + 1, cameraVertices[0].time(), *lightDistr, lightVertices); // Execute all BDPT connection strategies Spectrum L(0.f); for (int t = 1; t <= nCamera; ++t) { for (int s = 0; s <= nLight; ++s) { int depth = t + s - 2; if ((s == 1 && t == 1) || depth < 0 || depth > maxDepth) continue; // Execute the $(s, t)$ connection strategy and // update _L_ Point2f pFilmNew = pFilm; Float misWeight = 0.f; Spectrum Lpath = ConnectBDPT( scene, lightVertices, cameraVertices, s, t, *lightDistr, *camera, *tileSampler, &pFilmNew, &misWeight); if (visualizeStrategies || visualizeWeights) { Spectrum value; if (visualizeStrategies) value = misWeight == 0 ? 0 : Lpath / misWeight; if (visualizeWeights) value = Lpath; weightFilms[BufferIndex(s, t)]->AddSplat( pFilmNew, value); } if (t != 1) L += Lpath; else film->AddSplat(pFilmNew, Lpath); } } filmTile->AddSample(pFilm, L); arena.Reset(); } while (tileSampler->StartNextSample()); } film->MergeFilmTile(std::move(filmTile)); reporter.Update(); }, Point2i(nXTiles, nYTiles)); reporter.Done(); } film->WriteImage(1.0f / sampler->samplesPerPixel); // Write buffers for debug visualization if (visualizeStrategies || visualizeWeights) { const Float invSampleCount = 1.0f / sampler->samplesPerPixel; for (size_t i = 0; i < weightFilms.size(); ++i) if (weightFilms[i]) weightFilms[i]->WriteImage(invSampleCount); } }