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d350976ba06d4ef93aa53fc4cd9da57be46ae924
test/intern/cycles/hydra/light.cpp
Patrick Mours d350976ba0 Cycles: Add Hydra render delegate 
This patch adds a Hydra render delegate to Cycles, allowing Cycles to be used for rendering
in applications that provide a Hydra viewport. The implementation was written from scratch
against Cycles X, for integration into the Blender repository to make it possible to continue
developing it in step with the rest of Cycles. For this purpose it follows the style of the rest of
the Cycles code and can be built with a CMake option
(`WITH_CYCLES_HYDRA_RENDER_DELEGATE=1`) similar to the existing standalone version
of Cycles.

Since Hydra render delegates need to be built against the exact USD version and other
dependencies as the target application is using, this is intended to be built separate from
Blender (`WITH_BLENDER=0` CMake option) and with support for library versions different
from what Blender is using. As such the CMake build scripts for Windows had to be modified
slightly, so that the Cycles Hydra render delegate can e.g. be built with MSVC 2017 again
even though Blender requires MSVC 2019 now, and it's possible to specify custom paths to
the USD SDK etc. The codebase supports building against the latest USD release 22.03 and all
the way back to USD 20.08 (with some limitations).

Reviewed By: brecht, LazyDodo

Differential Revision: https://developer.blender.org/D14398
2022-03-23 16:39:05 +01:00

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/* SPDX-License-Identifier: Apache-2.0
* Copyright 2022 NVIDIA Corporation
* Copyright 2022 Blender Foundation */
#include "hydra/light.h"
#include "hydra/session.h"
#include "scene/light.h"
#include "scene/scene.h"
#include "scene/shader.h"
#include "scene/shader_graph.h"
#include "scene/shader_nodes.h"
#include "util/hash.h"
#include <pxr/imaging/hd/sceneDelegate.h>
#include <pxr/usd/sdf/assetPath.h>
HDCYCLES_NAMESPACE_OPEN_SCOPE
extern Transform convert_transform(const GfMatrix4d &matrix);
// clang-format off
TF_DEFINE_PRIVATE_TOKENS(_tokens,
(visibleInPrimaryRay)
);
// clang-format on
HdCyclesLight::HdCyclesLight(const SdfPath &sprimId, const TfToken &lightType)
: HdLight(sprimId), _lightType(lightType)
{
}
HdCyclesLight::~HdCyclesLight()
{
}
HdDirtyBits HdCyclesLight::GetInitialDirtyBitsMask() const
{
return DirtyBits::DirtyTransform | DirtyBits::DirtyParams;
}
void HdCyclesLight::Sync(HdSceneDelegate *sceneDelegate,
HdRenderParam *renderParam,
HdDirtyBits *dirtyBits)
{
if (*dirtyBits == DirtyBits::Clean) {
return;
}
Initialize(renderParam);
const SceneLock lock(renderParam);
VtValue value;
const SdfPath &id = GetId();
if (*dirtyBits & DirtyBits::DirtyTransform) {
#if PXR_VERSION >= 2011
const Transform tfm = convert_transform(sceneDelegate->GetTransform(id));
#else
const Transform tfm = convert_transform(
sceneDelegate->GetLightParamValue(id, HdTokens->transform).Get<GfMatrix4d>());
#endif
_light->set_tfm(tfm);
_light->set_co(transform_get_column(&tfm, 3));
_light->set_dir(-transform_get_column(&tfm, 2));
if (_lightType == HdPrimTypeTokens->diskLight || _lightType == HdPrimTypeTokens->rectLight) {
_light->set_axisu(transform_get_column(&tfm, 0));
_light->set_axisv(transform_get_column(&tfm, 1));
}
}
if (*dirtyBits & DirtyBits::DirtyParams) {
float3 strength = make_float3(1.0f, 1.0f, 1.0f);
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->color);
if (!value.IsEmpty()) {
const auto color = value.Get<GfVec3f>();
strength = make_float3(color[0], color[1], color[2]);
}
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->exposure);
if (!value.IsEmpty()) {
strength *= exp2(value.Get<float>());
}
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->intensity);
if (!value.IsEmpty()) {
strength *= value.Get<float>();
}
// Cycles lights are normalized by default, so need to scale intensity if Hydra light is not
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->normalize);
const bool normalize = value.IsHolding<bool>() && value.UncheckedGet<bool>();
value = sceneDelegate->GetLightParamValue(id, _tokens->visibleInPrimaryRay);
if (!value.IsEmpty()) {
_light->set_use_camera(value.Get<bool>());
}
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->shadowEnable);
if (!value.IsEmpty()) {
_light->set_cast_shadow(value.Get<bool>());
}
if (_lightType == HdPrimTypeTokens->distantLight) {
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->angle);
if (!value.IsEmpty()) {
_light->set_angle(GfDegreesToRadians(value.Get<float>()));
}
}
else if (_lightType == HdPrimTypeTokens->diskLight) {
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->radius);
if (!value.IsEmpty()) {
const float size = value.Get<float>() * 2.0f;
_light->set_sizeu(size);
_light->set_sizev(size);
}
if (!normalize) {
const float radius = _light->get_sizeu() * 0.5f;
strength *= M_PI * radius * radius;
}
}
else if (_lightType == HdPrimTypeTokens->rectLight) {
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->width);
if (!value.IsEmpty()) {
_light->set_sizeu(value.Get<float>());
}
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->height);
if (!value.IsEmpty()) {
_light->set_sizev(value.Get<float>());
}
if (!normalize) {
strength *= _light->get_sizeu() * _light->get_sizeu();
}
}
else if (_lightType == HdPrimTypeTokens->sphereLight) {
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->radius);
if (!value.IsEmpty()) {
_light->set_size(value.Get<float>());
}
bool shaping = false;
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->shapingConeAngle);
if (!value.IsEmpty()) {
_light->set_spot_angle(GfDegreesToRadians(value.Get<float>()) * 2.0f);
shaping = true;
}
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->shapingConeSoftness);
if (!value.IsEmpty()) {
_light->set_spot_smooth(value.Get<float>());
shaping = true;
}
_light->set_light_type(shaping ? LIGHT_SPOT : LIGHT_POINT);
if (!normalize) {
const float radius = _light->get_size();
strength *= M_PI * radius * radius * 4.0f;
}
}
const bool visible = sceneDelegate->GetVisible(id);
// Disable invisible lights by zeroing the strength
// So 'LightManager::test_enabled_lights' updates the enabled flag correctly
if (!visible) {
strength = zero_float3();
}
_light->set_strength(strength);
_light->set_is_enabled(visible);
PopulateShaderGraph(sceneDelegate);
}
// Need to update shader graph when transform changes in case transform was baked into it
else if (_light->tfm_is_modified() && (_lightType == HdPrimTypeTokens->domeLight ||
_light->get_shader()->has_surface_spatial_varying)) {
PopulateShaderGraph(sceneDelegate);
}
if (_light->is_modified()) {
_light->tag_update(lock.scene);
}
*dirtyBits = DirtyBits::Clean;
}
void HdCyclesLight::PopulateShaderGraph(HdSceneDelegate *sceneDelegate)
{
auto graph = new ShaderGraph();
ShaderNode *outputNode = nullptr;
if (_lightType == HdPrimTypeTokens->domeLight) {
BackgroundNode *bgNode = graph->create_node<BackgroundNode>();
// Bake strength into shader graph, since only the shader is used for background lights
bgNode->set_color(_light->get_strength());
graph->add(bgNode);
graph->connect(bgNode->output("Background"), graph->output()->input("Surface"));
outputNode = bgNode;
}
else {
EmissionNode *emissionNode = graph->create_node<EmissionNode>();
emissionNode->set_color(one_float3());
emissionNode->set_strength(1.0f);
graph->add(emissionNode);
graph->connect(emissionNode->output("Emission"), graph->output()->input("Surface"));
outputNode = emissionNode;
}
VtValue value;
const SdfPath &id = GetId();
bool hasSpatialVarying = false;
bool hasColorTemperature = false;
if (sceneDelegate != nullptr) {
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->enableColorTemperature);
const bool enableColorTemperature = value.IsHolding<bool>() && value.UncheckedGet<bool>();
if (enableColorTemperature) {
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->colorTemperature);
if (value.IsHolding<float>()) {
BlackbodyNode *blackbodyNode = graph->create_node<BlackbodyNode>();
blackbodyNode->set_temperature(value.UncheckedGet<float>());
graph->add(blackbodyNode);
if (_lightType == HdPrimTypeTokens->domeLight) {
VectorMathNode *mathNode = graph->create_node<VectorMathNode>();
mathNode->set_math_type(NODE_VECTOR_MATH_MULTIPLY);
mathNode->set_vector2(_light->get_strength());
graph->add(mathNode);
graph->connect(blackbodyNode->output("Color"), mathNode->input("Vector1"));
graph->connect(mathNode->output("Vector"), outputNode->input("Color"));
}
else {
graph->connect(blackbodyNode->output("Color"), outputNode->input("Color"));
}
hasColorTemperature = true;
}
}
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->shapingIesFile);
if (value.IsHolding<SdfAssetPath>()) {
std::string filename = value.UncheckedGet<SdfAssetPath>().GetResolvedPath();
if (filename.empty()) {
filename = value.UncheckedGet<SdfAssetPath>().GetAssetPath();
}
TextureCoordinateNode *coordNode = graph->create_node<TextureCoordinateNode>();
coordNode->set_ob_tfm(_light->get_tfm());
coordNode->set_use_transform(true);
graph->add(coordNode);
IESLightNode *iesNode = graph->create_node<IESLightNode>();
iesNode->set_filename(ustring(filename));
graph->connect(coordNode->output("Normal"), iesNode->input("Vector"));
graph->connect(iesNode->output("Fac"), outputNode->input("Strength"));
hasSpatialVarying = true;
}
value = sceneDelegate->GetLightParamValue(id, HdLightTokens->textureFile);
if (value.IsHolding<SdfAssetPath>()) {
std::string filename = value.UncheckedGet<SdfAssetPath>().GetResolvedPath();
if (filename.empty()) {
filename = value.UncheckedGet<SdfAssetPath>().GetAssetPath();
}
ImageSlotTextureNode *textureNode = nullptr;
if (_lightType == HdPrimTypeTokens->domeLight) {
Transform tfm = _light->get_tfm();
transform_set_column(&tfm, 3, zero_float3()); // Remove translation
TextureCoordinateNode *coordNode = graph->create_node<TextureCoordinateNode>();
coordNode->set_ob_tfm(tfm);
coordNode->set_use_transform(true);
graph->add(coordNode);
textureNode = graph->create_node<EnvironmentTextureNode>();
static_cast<EnvironmentTextureNode *>(textureNode)->set_filename(ustring(filename));
graph->add(textureNode);
graph->connect(coordNode->output("Object"), textureNode->input("Vector"));
hasSpatialVarying = true;
}
else {
GeometryNode *coordNode = graph->create_node<GeometryNode>();
graph->add(coordNode);
textureNode = graph->create_node<ImageTextureNode>();
static_cast<ImageTextureNode *>(textureNode)->set_filename(ustring(filename));
graph->add(textureNode);
graph->connect(coordNode->output("Parametric"), textureNode->input("Vector"));
}
if (hasColorTemperature) {
VectorMathNode *mathNode = graph->create_node<VectorMathNode>();
mathNode->set_math_type(NODE_VECTOR_MATH_MULTIPLY);
graph->add(mathNode);
graph->connect(textureNode->output("Color"), mathNode->input("Vector1"));
ShaderInput *const outputNodeInput = outputNode->input("Color");
graph->connect(outputNodeInput->link, mathNode->input("Vector2"));
graph->disconnect(outputNodeInput);
graph->connect(mathNode->output("Vector"), outputNodeInput);
}
else if (_lightType == HdPrimTypeTokens->domeLight) {
VectorMathNode *mathNode = graph->create_node<VectorMathNode>();
mathNode->set_math_type(NODE_VECTOR_MATH_MULTIPLY);
mathNode->set_vector2(_light->get_strength());
graph->add(mathNode);
graph->connect(textureNode->output("Color"), mathNode->input("Vector1"));
graph->connect(mathNode->output("Vector"), outputNode->input("Color"));
}
else {
graph->connect(textureNode->output("Color"), outputNode->input("Color"));
}
}
}
Shader *const shader = _light->get_shader();
shader->set_graph(graph);
shader->tag_update((Scene *)_light->get_owner());
shader->has_surface_spatial_varying = hasSpatialVarying;
}
void HdCyclesLight::Finalize(HdRenderParam *renderParam)
{
if (!_light) {
return;
}
const SceneLock lock(renderParam);
lock.scene->delete_node(_light);
_light = nullptr;
}
void HdCyclesLight::Initialize(HdRenderParam *renderParam)
{
if (_light) {
return;
}
const SceneLock lock(renderParam);
_light = lock.scene->create_node<Light>();
_light->name = GetId().GetString();
_light->set_random_id(hash_uint2(hash_string(_light->name.c_str()), 0));
if (_lightType == HdPrimTypeTokens->domeLight) {
_light->set_light_type(LIGHT_BACKGROUND);
}
else if (_lightType == HdPrimTypeTokens->distantLight) {
_light->set_light_type(LIGHT_DISTANT);
}
else if (_lightType == HdPrimTypeTokens->diskLight) {
_light->set_light_type(LIGHT_AREA);
_light->set_round(true);
_light->set_size(1.0f);
}
else if (_lightType == HdPrimTypeTokens->rectLight) {
_light->set_light_type(LIGHT_AREA);
_light->set_round(false);
_light->set_size(1.0f);
}
else if (_lightType == HdPrimTypeTokens->sphereLight) {
_light->set_light_type(LIGHT_POINT);
_light->set_size(1.0f);
}
_light->set_use_mis(true);
_light->set_use_camera(false);
Shader *const shader = lock.scene->create_node<Shader>();
_light->set_shader(shader);
// Create default shader graph
PopulateShaderGraph(nullptr);
}
HDCYCLES_NAMESPACE_CLOSE_SCOPE
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