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test/intern/cycles/kernel/osl/closures_setup.h
Alaska 9b3699db67 Fix: Cycles invalid normals in various situations 
Fix issues related to NaN normals in some situations by trying
to detect when these cases might occur and just reverting back
to default normals.

As a side effect of these changes, OSL now behaves correctly
when given a non-normalized normal.

Pull Request: https://projects.blender.org/blender/blender/pulls/114960
2024-01-02 16:24:04 +01:00

1005 lines
33 KiB
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/* SPDX-FileCopyrightText: 2009-2010 Sony Pictures Imageworks Inc., et al. All Rights Reserved.
* SPDX-FileCopyrightText: 2011-2022 Blender Foundation
*
* SPDX-License-Identifier: BSD-3-Clause
*
* Adapted code from Open Shading Language. */
#pragma once
#include "kernel/closure/alloc.h"
#include "kernel/closure/bsdf.h"
#include "kernel/closure/emissive.h"
CCL_NAMESPACE_BEGIN
#define OSL_CLOSURE_STRUCT_BEGIN(Upper, lower) \
struct ccl_align(8) Upper##Closure \
{ \
const char *label;
#define OSL_CLOSURE_STRUCT_END(Upper, lower) \
} \
;
#define OSL_CLOSURE_STRUCT_MEMBER(Upper, TYPE, type, name, key) type name;
#define OSL_CLOSURE_STRUCT_ARRAY_MEMBER(Upper, TYPE, type, name, key, size) type name[size];
#include "closures_template.h"
struct ccl_align(8) LayerClosure
{
ccl_private const OSLClosure *base;
ccl_private const OSLClosure *top;
};
/* If we failed to allocate a layer-able closure, we need to zero out the albedo
* so that lower layers aren't falsely blocked.
* Therefore, to keep the code clean, set it to zero at the start and overwrite
* later if it succeeded. */
ccl_device_forceinline void osl_zero_albedo(float3 *layer_albedo)
{
if (layer_albedo != NULL) {
*layer_albedo = zero_float3();
}
}
ccl_device_forceinline bool osl_closure_skip(KernelGlobals kg,
ccl_private const ShaderData *sd,
uint32_t path_flag,
int scattering)
{
/* caustic options */
if ((scattering & LABEL_GLOSSY) && (path_flag & PATH_RAY_DIFFUSE)) {
if ((!kernel_data.integrator.caustics_reflective && (scattering & LABEL_REFLECT)) ||
(!kernel_data.integrator.caustics_refractive && (scattering & LABEL_TRANSMIT)))
{
return true;
}
}
return false;
}
/* Diffuse */
ccl_device void osl_closure_diffuse_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const DiffuseClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_DIFFUSE)) {
return;
}
ccl_private DiffuseBsdf *bsdf = (ccl_private DiffuseBsdf *)bsdf_alloc(
sd, sizeof(DiffuseBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = safe_normalize_fallback(closure->N, sd->N);
sd->flag |= bsdf_diffuse_setup(bsdf);
}
ccl_device void osl_closure_oren_nayar_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const OrenNayarClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_DIFFUSE)) {
return;
}
ccl_private OrenNayarBsdf *bsdf = (ccl_private OrenNayarBsdf *)bsdf_alloc(
sd, sizeof(OrenNayarBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = safe_normalize_fallback(closure->N, sd->N);
bsdf->roughness = closure->roughness;
sd->flag |= bsdf_oren_nayar_setup(bsdf);
}
ccl_device void osl_closure_translucent_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const TranslucentClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_DIFFUSE)) {
return;
}
ccl_private DiffuseBsdf *bsdf = (ccl_private DiffuseBsdf *)bsdf_alloc(
sd, sizeof(DiffuseBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = safe_normalize_fallback(closure->N, sd->N);
sd->flag |= bsdf_translucent_setup(bsdf);
}
ccl_device void osl_closure_reflection_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const ReflectionClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_SINGULAR)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = bsdf->alpha_y = 0.0f;
sd->flag |= bsdf_microfacet_ggx_setup(bsdf);
}
ccl_device void osl_closure_refraction_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const RefractionClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_SINGULAR)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->ior = closure->ior;
bsdf->alpha_x = bsdf->alpha_y = 0.0f;
sd->flag |= bsdf_microfacet_ggx_refraction_setup(bsdf);
}
ccl_device void osl_closure_transparent_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const TransparentClosure *closure,
float3 *layer_albedo)
{
bsdf_transparent_setup(sd, rgb_to_spectrum(weight), path_flag);
}
/* MaterialX closures */
ccl_device void osl_closure_dielectric_bsdf_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const DielectricBSDFClosure *closure,
float3 *layer_albedo)
{
osl_zero_albedo(layer_albedo);
const bool has_reflection = !is_zero(closure->reflection_tint);
const bool has_transmission = !is_zero(closure->transmission_tint);
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY | LABEL_REFLECT)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
ccl_private FresnelDielectricTint *fresnel = (ccl_private FresnelDielectricTint *)
closure_alloc_extra(sd, sizeof(FresnelDielectricTint));
if (!fresnel) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = closure->alpha_x;
bsdf->alpha_y = closure->alpha_y;
bsdf->ior = closure->ior;
bsdf->T = closure->T;
bool preserve_energy = false;
/* Beckmann */
if (closure->distribution == make_string("beckmann", 14712237670914973463ull)) {
if (has_reflection && has_transmission) {
sd->flag |= bsdf_microfacet_beckmann_glass_setup(bsdf);
}
else if (has_transmission) {
sd->flag |= bsdf_microfacet_beckmann_refraction_setup(bsdf);
}
else {
sd->flag |= bsdf_microfacet_beckmann_setup(bsdf);
}
}
/* GGX (either single- or multi-scattering). */
else {
if (has_reflection && has_transmission) {
sd->flag |= bsdf_microfacet_ggx_glass_setup(bsdf);
}
else if (has_transmission) {
sd->flag |= bsdf_microfacet_ggx_refraction_setup(bsdf);
}
else {
sd->flag |= bsdf_microfacet_ggx_setup(bsdf);
}
preserve_energy = (closure->distribution == make_string("multi_ggx", 16842698693386468366ull));
}
fresnel->reflection_tint = rgb_to_spectrum(closure->reflection_tint);
fresnel->transmission_tint = rgb_to_spectrum(closure->transmission_tint);
bsdf_microfacet_setup_fresnel_dielectric_tint(kg, bsdf, sd, fresnel, preserve_energy);
if (layer_albedo != NULL) {
if (has_reflection && !has_transmission) {
*layer_albedo = bsdf_albedo(kg, sd, (ccl_private ShaderClosure *)bsdf, true, false);
}
else {
*layer_albedo = one_float3();
}
}
}
ccl_device void osl_closure_conductor_bsdf_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const ConductorBSDFClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY | LABEL_REFLECT)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
ccl_private FresnelConductor *fresnel = (ccl_private FresnelConductor *)closure_alloc_extra(
sd, sizeof(FresnelConductor));
if (!fresnel) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = closure->alpha_x;
bsdf->alpha_y = closure->alpha_y;
bsdf->ior = 0.0f;
bsdf->T = closure->T;
bool preserve_energy = false;
/* Beckmann */
if (closure->distribution == make_string("beckmann", 14712237670914973463ull)) {
sd->flag |= bsdf_microfacet_beckmann_setup(bsdf);
}
/* GGX (either single- or multi-scattering) */
else {
sd->flag |= bsdf_microfacet_ggx_setup(bsdf);
preserve_energy = (closure->distribution == make_string("multi_ggx", 16842698693386468366ull));
}
fresnel->n = rgb_to_spectrum(closure->ior);
fresnel->k = rgb_to_spectrum(closure->extinction);
bsdf_microfacet_setup_fresnel_conductor(kg, bsdf, sd, fresnel, preserve_energy);
}
ccl_device void osl_closure_generalized_schlick_bsdf_setup(
KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const GeneralizedSchlickBSDFClosure *closure,
float3 *layer_albedo)
{
osl_zero_albedo(layer_albedo);
const bool has_reflection = !is_zero(closure->reflection_tint);
const bool has_transmission = !is_zero(closure->transmission_tint);
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY | LABEL_REFLECT)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
ccl_private FresnelGeneralizedSchlick *fresnel = (ccl_private FresnelGeneralizedSchlick *)
closure_alloc_extra(sd, sizeof(FresnelGeneralizedSchlick));
if (!fresnel) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = closure->alpha_x;
bsdf->alpha_y = closure->alpha_y;
bsdf->T = closure->T;
if (closure->exponent < 0.0f) {
/* Trick for principled BSDF: Since we use the real Fresnel equation and remap
* to the F0...F90 range, this allows us to use the real IOR.
* Computing it back from F0 might give a different result in case of specular
* tinting. */
bsdf->ior = -closure->exponent;
}
else {
bsdf->ior = ior_from_F0(average(closure->f0));
}
bool preserve_energy = false;
/* Beckmann */
if (closure->distribution == make_string("beckmann", 14712237670914973463ull)) {
if (has_reflection && has_transmission) {
sd->flag |= bsdf_microfacet_beckmann_glass_setup(bsdf);
}
else if (has_transmission) {
sd->flag |= bsdf_microfacet_beckmann_refraction_setup(bsdf);
}
else {
sd->flag |= bsdf_microfacet_beckmann_setup(bsdf);
}
}
/* GGX (either single- or multi-scattering) */
else {
if (has_reflection && has_transmission) {
sd->flag |= bsdf_microfacet_ggx_glass_setup(bsdf);
}
else if (has_transmission) {
sd->flag |= bsdf_microfacet_ggx_refraction_setup(bsdf);
}
else {
sd->flag |= bsdf_microfacet_ggx_setup(bsdf);
}
preserve_energy = (closure->distribution == make_string("multi_ggx", 16842698693386468366ull));
}
fresnel->reflection_tint = rgb_to_spectrum(closure->reflection_tint);
fresnel->transmission_tint = rgb_to_spectrum(closure->transmission_tint);
fresnel->f0 = rgb_to_spectrum(closure->f0);
fresnel->f90 = rgb_to_spectrum(closure->f90);
fresnel->exponent = closure->exponent;
bsdf_microfacet_setup_fresnel_generalized_schlick(kg, bsdf, sd, fresnel, preserve_energy);
if (layer_albedo != NULL) {
if (has_reflection && !has_transmission) {
*layer_albedo = bsdf_albedo(kg, sd, (ccl_private ShaderClosure *)bsdf, true, false);
}
else {
*layer_albedo = one_float3();
}
}
}
/* Standard microfacet closures */
ccl_device void osl_closure_microfacet_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const MicrofacetClosure *closure,
float3 *layer_albedo)
{
osl_zero_albedo(layer_albedo);
const int label = (closure->refract) ? LABEL_TRANSMIT : LABEL_REFLECT;
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY | label)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = closure->alpha_x;
bsdf->alpha_y = closure->alpha_y;
bsdf->ior = closure->ior;
bsdf->T = closure->T;
/* Beckmann */
if (closure->distribution == make_string("beckmann", 14712237670914973463ull)) {
if (closure->refract == 1) {
sd->flag |= bsdf_microfacet_beckmann_refraction_setup(bsdf);
}
else if (closure->refract == 2) {
sd->flag |= bsdf_microfacet_beckmann_glass_setup(bsdf);
}
else {
sd->flag |= bsdf_microfacet_beckmann_setup(bsdf);
}
}
/* Ashikhmin-Shirley */
else if (closure->distribution == make_string("ashikhmin_shirley", 11318482998918370922ull)) {
sd->flag |= bsdf_ashikhmin_shirley_setup(bsdf);
}
/* GGX (either single- or multi-scattering) */
else {
if (closure->refract == 1) {
sd->flag |= bsdf_microfacet_ggx_refraction_setup(bsdf);
}
else if (closure->refract == 2) {
sd->flag |= bsdf_microfacet_ggx_glass_setup(bsdf);
}
else {
sd->flag |= bsdf_microfacet_ggx_setup(bsdf);
}
if (closure->distribution == make_string("multi_ggx", 16842698693386468366ull)) {
/* Since there's no dedicated color input, the weight is the best we got. */
bsdf_microfacet_setup_fresnel_constant(kg, bsdf, sd, rgb_to_spectrum(weight));
}
}
if (layer_albedo != NULL) {
if (closure->refract == 0) {
*layer_albedo = bsdf_albedo(kg, sd, (ccl_private ShaderClosure *)bsdf, true, false);
}
else {
*layer_albedo = one_float3();
}
}
}
/* Special-purpose Microfacet closures */
ccl_device void osl_closure_microfacet_f82_tint_setup(
KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const MicrofacetF82TintClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY | LABEL_REFLECT)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
ccl_private FresnelF82Tint *fresnel = (ccl_private FresnelF82Tint *)closure_alloc_extra(
sd, sizeof(FresnelF82Tint));
if (!fresnel) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = closure->alpha_x;
bsdf->alpha_y = closure->alpha_y;
bsdf->ior = 0.0f;
bsdf->T = closure->T;
bool preserve_energy = false;
/* Beckmann */
if (closure->distribution == make_string("beckmann", 14712237670914973463ull)) {
sd->flag |= bsdf_microfacet_beckmann_setup(bsdf);
}
/* GGX (either single- or multi-scattering) */
else {
sd->flag |= bsdf_microfacet_ggx_setup(bsdf);
preserve_energy = (closure->distribution == make_string("multi_ggx", 16842698693386468366ull));
}
fresnel->f0 = rgb_to_spectrum(closure->f0);
bsdf_microfacet_setup_fresnel_f82_tint(
kg, bsdf, sd, fresnel, rgb_to_spectrum(closure->f82), preserve_energy);
}
ccl_device void osl_closure_microfacet_multi_ggx_glass_setup(
KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const MicrofacetMultiGGXGlassClosure *closure,
float3 *layer_albedo)
{
/* Technically, the MultiGGX closure may also transmit. However,
* since this is set statically and only used for caustic flags, this
* is probably as good as it gets. */
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY | LABEL_REFLECT)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = closure->alpha_x;
bsdf->alpha_y = bsdf->alpha_x;
bsdf->ior = closure->ior;
bsdf->T = zero_float3();
sd->flag |= bsdf_microfacet_ggx_glass_setup(bsdf);
bsdf_microfacet_setup_fresnel_constant(kg, bsdf, sd, rgb_to_spectrum(closure->color));
}
ccl_device void osl_closure_microfacet_multi_ggx_aniso_setup(
KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const MicrofacetMultiGGXClosure *closure,
float3 *layer_albedo)
{
osl_zero_albedo(layer_albedo);
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY | LABEL_REFLECT)) {
return;
}
ccl_private MicrofacetBsdf *bsdf = (ccl_private MicrofacetBsdf *)bsdf_alloc(
sd, sizeof(MicrofacetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->alpha_x = closure->alpha_x;
bsdf->alpha_y = closure->alpha_y;
bsdf->ior = 1.0f;
bsdf->T = closure->T;
sd->flag |= bsdf_microfacet_ggx_setup(bsdf);
bsdf_microfacet_setup_fresnel_constant(kg, bsdf, sd, rgb_to_spectrum(closure->color));
if (layer_albedo != NULL) {
*layer_albedo = bsdf_albedo(kg, sd, (ccl_private ShaderClosure *)bsdf, true, false);
}
}
/* Ashikhmin Velvet */
ccl_device void osl_closure_ashikhmin_velvet_setup(
KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const AshikhminVelvetClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_DIFFUSE)) {
return;
}
ccl_private VelvetBsdf *bsdf = (ccl_private VelvetBsdf *)bsdf_alloc(
sd, sizeof(VelvetBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->sigma = closure->sigma;
sd->flag |= bsdf_ashikhmin_velvet_setup(bsdf);
}
/* Sheen */
ccl_device void osl_closure_sheen_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const SheenClosure *closure,
float3 *layer_albedo)
{
osl_zero_albedo(layer_albedo);
if (osl_closure_skip(kg, sd, path_flag, LABEL_DIFFUSE)) {
return;
}
ccl_private SheenBsdf *bsdf = (ccl_private SheenBsdf *)bsdf_alloc(
sd, sizeof(SheenBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = safe_normalize_fallback(closure->N, sd->N);
bsdf->roughness = closure->roughness;
const int sheen_flag = bsdf_sheen_setup(kg, sd, bsdf);
if (sheen_flag) {
sd->flag |= sheen_flag;
if (layer_albedo != NULL) {
*layer_albedo = bsdf->weight;
}
}
}
ccl_device void osl_closure_diffuse_toon_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const DiffuseToonClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_DIFFUSE)) {
return;
}
ccl_private ToonBsdf *bsdf = (ccl_private ToonBsdf *)bsdf_alloc(
sd, sizeof(ToonBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->size = closure->size;
bsdf->smooth = closure->smooth;
sd->flag |= bsdf_diffuse_toon_setup(bsdf);
}
ccl_device void osl_closure_glossy_toon_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const GlossyToonClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY)) {
return;
}
ccl_private ToonBsdf *bsdf = (ccl_private ToonBsdf *)bsdf_alloc(
sd, sizeof(ToonBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->size = closure->size;
bsdf->smooth = closure->smooth;
sd->flag |= bsdf_glossy_toon_setup(bsdf);
}
/* Variable cone emissive closure
*
* This primitive emits in a cone having a configurable penumbra area where the light decays to 0
* reaching the outer_angle limit. It can also behave as a lambertian emitter if the provided
* angles are PI/2, which is the default
*/
ccl_device void osl_closure_emission_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t /* path_flag */,
float3 weight,
ccl_private const GenericEmissiveClosure *closure,
float3 *layer_albedo)
{
emission_setup(sd, rgb_to_spectrum(weight));
}
/* Generic background closure
*
* We only have a background closure for the shaders to return a color in background shaders. No
* methods, only the weight is taking into account
*/
ccl_device void osl_closure_background_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t /* path_flag */,
float3 weight,
ccl_private const GenericBackgroundClosure *closure,
float3 *layer_albedo)
{
background_setup(sd, rgb_to_spectrum(weight));
}
/* Holdout closure
*
* This will be used by the shader to mark the amount of holdout for the current shading point. No
* parameters, only the weight will be used
*/
ccl_device void osl_closure_holdout_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t /* path_flag */,
float3 weight,
ccl_private const HoldoutClosure *closure,
float3 *layer_albedo)
{
closure_alloc(sd, sizeof(ShaderClosure), CLOSURE_HOLDOUT_ID, rgb_to_spectrum(weight));
sd->flag |= SD_HOLDOUT;
}
ccl_device void osl_closure_diffuse_ramp_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t /* path_flag */,
float3 weight,
ccl_private const DiffuseRampClosure *closure,
float3 *layer_albedo)
{
ccl_private DiffuseRampBsdf *bsdf = (ccl_private DiffuseRampBsdf *)bsdf_alloc(
sd, sizeof(DiffuseRampBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = safe_normalize_fallback(closure->N, sd->N);
bsdf->colors = (float3 *)closure_alloc_extra(sd, sizeof(float3) * 8);
if (!bsdf->colors) {
return;
}
for (int i = 0; i < 8; i++) {
bsdf->colors[i] = closure->colors[i];
}
sd->flag |= bsdf_diffuse_ramp_setup(bsdf);
}
ccl_device void osl_closure_phong_ramp_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t /* path_flag */,
float3 weight,
ccl_private const PhongRampClosure *closure,
float3 *layer_albedo)
{
ccl_private PhongRampBsdf *bsdf = (ccl_private PhongRampBsdf *)bsdf_alloc(
sd, sizeof(PhongRampBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->exponent = closure->exponent;
bsdf->colors = (float3 *)closure_alloc_extra(sd, sizeof(float3) * 8);
if (!bsdf->colors) {
return;
}
for (int i = 0; i < 8; i++) {
bsdf->colors[i] = closure->colors[i];
}
sd->flag |= bsdf_phong_ramp_setup(bsdf);
}
ccl_device void osl_closure_bssrdf_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const BSSRDFClosure *closure,
float3 *layer_albedo)
{
ClosureType type;
if (closure->method == make_string("burley", 186330084368958868ull)) {
type = CLOSURE_BSSRDF_BURLEY_ID;
}
else if (closure->method == make_string("random_walk", 5695810351010063150ull)) {
type = CLOSURE_BSSRDF_RANDOM_WALK_ID;
}
else if (closure->method == make_string("random_walk_skin", 11360609267673527222ull)) {
type = CLOSURE_BSSRDF_RANDOM_WALK_SKIN_ID;
}
else {
return;
}
ccl_private Bssrdf *bssrdf = bssrdf_alloc(sd, rgb_to_spectrum(weight));
if (!bssrdf) {
return;
}
bssrdf->radius = closure->radius;
/* create one closure per color channel */
bssrdf->albedo = closure->albedo;
bssrdf->N = maybe_ensure_valid_specular_reflection(sd,
safe_normalize_fallback(closure->N, sd->N));
bssrdf->alpha = closure->roughness;
bssrdf->ior = closure->ior;
bssrdf->anisotropy = closure->anisotropy;
sd->flag |= bssrdf_setup(sd, bssrdf, path_flag, type);
}
/* Hair */
ccl_device void osl_closure_hair_reflection_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const HairReflectionClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY)) {
return;
}
ccl_private HairBsdf *bsdf = (ccl_private HairBsdf *)bsdf_alloc(
sd, sizeof(HairBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->T = closure->T;
bsdf->roughness1 = closure->roughness1;
bsdf->roughness2 = closure->roughness2;
bsdf->offset = closure->offset;
sd->flag |= bsdf_hair_reflection_setup(bsdf);
}
ccl_device void osl_closure_hair_transmission_setup(
KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const HairTransmissionClosure *closure,
float3 *layer_albedo)
{
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY)) {
return;
}
ccl_private HairBsdf *bsdf = (ccl_private HairBsdf *)bsdf_alloc(
sd, sizeof(HairBsdf), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->T = closure->T;
bsdf->roughness1 = closure->roughness1;
bsdf->roughness2 = closure->roughness2;
bsdf->offset = closure->offset;
sd->flag |= bsdf_hair_transmission_setup(bsdf);
}
ccl_device void osl_closure_hair_chiang_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const ChiangHairClosure *closure,
float3 *layer_albedo)
{
#ifdef __HAIR__
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY)) {
return;
}
ccl_private ChiangHairBSDF *bsdf = (ccl_private ChiangHairBSDF *)bsdf_alloc(
sd, sizeof(ChiangHairBSDF), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
bsdf->N = maybe_ensure_valid_specular_reflection(sd, safe_normalize_fallback(closure->N, sd->N));
bsdf->sigma = closure->sigma;
bsdf->v = closure->v;
bsdf->s = closure->s;
bsdf->alpha = closure->alpha;
bsdf->eta = closure->eta;
bsdf->m0_roughness = closure->m0_roughness;
sd->flag |= bsdf_hair_chiang_setup(sd, bsdf);
#endif
}
ccl_device void osl_closure_hair_huang_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const HuangHairClosure *closure,
float3 *layer_albedo)
{
#ifdef __HAIR__
if (osl_closure_skip(kg, sd, path_flag, LABEL_GLOSSY)) {
return;
}
if (closure->r_lobe <= 0.0f && closure->tt_lobe <= 0.0f && closure->trt_lobe <= 0.0f) {
return;
}
ccl_private HuangHairBSDF *bsdf = (ccl_private HuangHairBSDF *)bsdf_alloc(
sd, sizeof(HuangHairBSDF), rgb_to_spectrum(weight));
if (!bsdf) {
return;
}
ccl_private HuangHairExtra *extra = (ccl_private HuangHairExtra *)closure_alloc_extra(
sd, sizeof(HuangHairExtra));
if (!extra) {
return;
}
bsdf->N = safe_normalize_fallback(closure->N, sd->N);
bsdf->sigma = closure->sigma;
bsdf->roughness = closure->roughness;
bsdf->tilt = closure->tilt;
bsdf->eta = closure->eta;
bsdf->aspect_ratio = closure->aspect_ratio;
bsdf->extra = extra;
bsdf->extra->R = closure->r_lobe;
bsdf->extra->TT = closure->tt_lobe;
bsdf->extra->TRT = closure->trt_lobe;
sd->flag |= bsdf_hair_huang_setup(sd, bsdf, path_flag);
#endif
}
/* Volume */
ccl_device void osl_closure_absorption_setup(KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const VolumeAbsorptionClosure *closure,
float3 *layer_albedo)
{
volume_extinction_setup(sd, rgb_to_spectrum(weight));
}
ccl_device void osl_closure_henyey_greenstein_setup(
KernelGlobals kg,
ccl_private ShaderData *sd,
uint32_t path_flag,
float3 weight,
ccl_private const VolumeHenyeyGreensteinClosure *closure,
float3 *layer_albedo)
{
volume_extinction_setup(sd, rgb_to_spectrum(weight));
ccl_private HenyeyGreensteinVolume *volume = (ccl_private HenyeyGreensteinVolume *)bsdf_alloc(
sd, sizeof(HenyeyGreensteinVolume), rgb_to_spectrum(weight));
if (!volume) {
return;
}
volume->g = closure->g;
sd->flag |= volume_henyey_greenstein_setup(volume);
}
CCL_NAMESPACE_END
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