void compute_ibl_bssrdf_sampling( SamplingContext& sampling_context, const ShadingContext& shading_context, const EnvironmentEDF& environment_edf, const BSSRDF& bssrdf, const void* bssrdf_data, const ShadingPoint& incoming_point, const ShadingPoint& outgoing_point, const Dual3d& outgoing, const size_t bssrdf_sample_count, const size_t env_sample_count, Spectrum& radiance) { assert(is_normalized(outgoing.get_value())); radiance.set(0.0f); sampling_context.split_in_place(2, bssrdf_sample_count); for (size_t i = 0; i < bssrdf_sample_count; ++i) { // Generate a uniform sample in [0,1)^2. const Vector2d s = sampling_context.next_vector2<2>(); // Sample the BSSRDF (hemisphere cosine). Vector3d incoming = sample_hemisphere_cosine(s); const double cos_in = incoming.y; const double bssrdf_prob = cos_in * RcpPi; incoming = incoming_point.get_shading_basis().transform_to_parent(incoming); if (incoming_point.get_side() == ObjectInstance::BackSide) incoming = -incoming; assert(is_normalized(incoming)); // Discard occluded samples. const double transmission = shading_context.get_tracer().trace( incoming_point, incoming, VisibilityFlags::ShadowRay); if (transmission == 0.0) continue; // Evaluate the BSSRDF. Spectrum bssrdf_value; bssrdf.evaluate( bssrdf_data, outgoing_point, outgoing.get_value(), incoming_point, incoming, bssrdf_value); // Evaluate the environment's EDF. InputEvaluator input_evaluator(shading_context.get_texture_cache()); Spectrum env_value; double env_prob; environment_edf.evaluate( shading_context, input_evaluator, incoming, env_value, env_prob); // Compute MIS weight. const double mis_weight = mis_power2( bssrdf_sample_count * bssrdf_prob, env_sample_count * env_prob); // Add the contribution of this sample to the illumination. env_value *= static_cast<float>(transmission * cos_in / bssrdf_prob * mis_weight); env_value *= bssrdf_value; radiance += env_value; } if (bssrdf_sample_count > 1) radiance /= static_cast<float>(bssrdf_sample_count); }
void compute_ibl_bsdf_sampling( SamplingContext& sampling_context, const ShadingContext& shading_context, const EnvironmentEDF& environment_edf, const ShadingPoint& shading_point, const Vector3d& outgoing, const BSDF& bsdf, const void* bsdf_data, const int bsdf_sampling_modes, const size_t bsdf_sample_count, const size_t env_sample_count, Spectrum& radiance) { assert(is_normalized(outgoing)); const Vector3d& geometric_normal = shading_point.get_geometric_normal(); const Basis3d& shading_basis = shading_point.get_shading_basis(); radiance.set(0.0f); for (size_t i = 0; i < bsdf_sample_count; ++i) { // Sample the BSDF. // todo: rendering will be incorrect if the BSDF value returned by the sample() method // includes the contribution of a specular component since these are explicitly rejected // afterward. We need a mechanism to indicate that we want the contribution of some of // the components only. Vector3d incoming; Spectrum bsdf_value; double bsdf_prob; const BSDF::Mode bsdf_mode = bsdf.sample( sampling_context, bsdf_data, false, // not adjoint true, // multiply by |cos(incoming, normal)| geometric_normal, shading_basis, outgoing, incoming, bsdf_value, bsdf_prob); // Filter scattering modes. if (!(bsdf_sampling_modes & bsdf_mode)) return; // Discard occluded samples. const double transmission = shading_context.get_tracer().trace( shading_point, incoming, ShadingRay::ShadowRay); if (transmission == 0.0) continue; // Evaluate the environment's EDF. InputEvaluator input_evaluator(shading_context.get_texture_cache()); Spectrum env_value; double env_prob; environment_edf.evaluate( input_evaluator, incoming, env_value, env_prob); // Apply all weights, including MIS weight. if (bsdf_mode == BSDF::Specular) env_value *= static_cast<float>(transmission); else { const double mis_weight = mis_power2( bsdf_sample_count * bsdf_prob, env_sample_count * env_prob); env_value *= static_cast<float>(transmission / bsdf_prob * mis_weight); } // Add the contribution of this sample to the illumination. env_value *= bsdf_value; radiance += env_value; } if (bsdf_sample_count > 1) radiance /= static_cast<float>(bsdf_sample_count); }
void compute_ibl_bsdf_sampling( SamplingContext& sampling_context, const ShadingContext& shading_context, const EnvironmentEDF& environment_edf, const ShadingPoint& shading_point, const Dual3d& outgoing, const BSDF& bsdf, const void* bsdf_data, const int bsdf_sampling_modes, const size_t bsdf_sample_count, const size_t env_sample_count, Spectrum& radiance) { assert(is_normalized(outgoing.get_value())); radiance.set(0.0f); for (size_t i = 0; i < bsdf_sample_count; ++i) { // Sample the BSDF. // todo: rendering will be incorrect if the BSDF value returned by the sample() method // includes the contribution of a specular component since these are explicitly rejected // afterward. We need a mechanism to indicate that we want the contribution of some of // the components only. BSDFSample sample(shading_point, outgoing); bsdf.sample( sampling_context, bsdf_data, false, // not adjoint true, // multiply by |cos(incoming, normal)| sample); // Filter scattering modes. if (!(bsdf_sampling_modes & sample.m_mode)) continue; // Discard occluded samples. const float transmission = shading_context.get_tracer().trace( shading_point, Vector3d(sample.m_incoming.get_value()), VisibilityFlags::ShadowRay); if (transmission == 0.0f) continue; // Evaluate the environment's EDF. InputEvaluator input_evaluator(shading_context.get_texture_cache()); Spectrum env_value; float env_prob; environment_edf.evaluate( shading_context, input_evaluator, sample.m_incoming.get_value(), env_value, env_prob); // Apply all weights, including MIS weight. if (sample.m_mode == ScatteringMode::Specular) env_value *= transmission; else { const float mis_weight = mis_power2( bsdf_sample_count * sample.m_probability, env_sample_count * env_prob); env_value *= transmission / sample.m_probability * mis_weight; } // Add the contribution of this sample to the illumination. env_value *= sample.m_value; radiance += env_value; } if (bsdf_sample_count > 1) radiance /= static_cast<float>(bsdf_sample_count); }