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d350976ba06d4ef93aa53fc4cd9da57be46ae924
test/intern/cycles/hydra/node_util.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/node_util.h"
#include "util/transform.h"
#include <pxr/base/gf/matrix3d.h>
#include <pxr/base/gf/matrix3f.h>
#include <pxr/base/gf/matrix4d.h>
#include <pxr/base/gf/matrix4f.h>
#include <pxr/base/gf/vec2f.h>
#include <pxr/base/gf/vec3f.h>
#include <pxr/base/vt/array.h>
#include <pxr/usd/sdf/assetPath.h>
HDCYCLES_NAMESPACE_OPEN_SCOPE
namespace {
template<typename DstType> DstType convertToCycles(const VtValue &value)
{
if (value.IsHolding<DstType>()) {
return value.UncheckedGet<DstType>();
}
VtValue castedValue = VtValue::Cast<DstType>(value);
if (castedValue.IsHolding<DstType>()) {
return castedValue.UncheckedGet<DstType>();
}
TF_WARN("Could not convert VtValue to Cycles type");
return DstType(0);
}
template<> float2 convertToCycles<float2>(const VtValue &value)
{
const GfVec2f convertedValue = convertToCycles<GfVec2f>(value);
return make_float2(convertedValue[0], convertedValue[1]);
}
template<> float3 convertToCycles<float3>(const VtValue &value)
{
if (value.IsHolding<GfVec3f>()) {
const GfVec3f convertedValue = value.UncheckedGet<GfVec3f>();
return make_float3(convertedValue[0], convertedValue[1], convertedValue[2]);
}
if (value.IsHolding<GfVec4f>()) {
const GfVec4f convertedValue = value.UncheckedGet<GfVec4f>();
return make_float3(convertedValue[0], convertedValue[1], convertedValue[2]);
}
if (value.CanCast<GfVec3f>()) {
const GfVec3f convertedValue = VtValue::Cast<GfVec3f>(value).UncheckedGet<GfVec3f>();
return make_float3(convertedValue[0], convertedValue[1], convertedValue[2]);
}
if (value.CanCast<GfVec4f>()) {
const GfVec4f convertedValue = VtValue::Cast<GfVec4f>(value).UncheckedGet<GfVec4f>();
return make_float3(convertedValue[0], convertedValue[1], convertedValue[2]);
}
TF_WARN("Could not convert VtValue to float3");
return zero_float3();
}
template<> ustring convertToCycles<ustring>(const VtValue &value)
{
if (value.IsHolding<TfToken>()) {
return ustring(value.UncheckedGet<TfToken>().GetString());
}
if (value.IsHolding<std::string>()) {
return ustring(value.UncheckedGet<std::string>());
}
if (value.IsHolding<SdfAssetPath>()) {
const SdfAssetPath &path = value.UncheckedGet<SdfAssetPath>();
return ustring(path.GetResolvedPath());
}
if (value.CanCast<TfToken>()) {
return convertToCycles<ustring>(VtValue::Cast<TfToken>(value));
}
if (value.CanCast<std::string>()) {
return convertToCycles<ustring>(VtValue::Cast<std::string>(value));
}
if (value.CanCast<SdfAssetPath>()) {
return convertToCycles<ustring>(VtValue::Cast<SdfAssetPath>(value));
}
TF_WARN("Could not convert VtValue to ustring");
return ustring();
}
template<typename Matrix>
Transform convertMatrixToCycles(
const typename std::enable_if<Matrix::numRows == 3 && Matrix::numColumns == 3, Matrix>::type
&matrix)
{
return make_transform(matrix[0][0],
matrix[1][0],
matrix[2][0],
0,
matrix[0][1],
matrix[1][1],
matrix[2][1],
0,
matrix[0][2],
matrix[1][2],
matrix[2][2],
0);
}
template<typename Matrix>
Transform convertMatrixToCycles(
const typename std::enable_if<Matrix::numRows == 4 && Matrix::numColumns == 4, Matrix>::type
&matrix)
{
return make_transform(matrix[0][0],
matrix[1][0],
matrix[2][0],
matrix[3][0],
matrix[0][1],
matrix[1][1],
matrix[2][1],
matrix[3][1],
matrix[0][2],
matrix[1][2],
matrix[2][2],
matrix[3][2]);
}
template<> Transform convertToCycles<Transform>(const VtValue &value)
{
if (value.IsHolding<GfMatrix4f>()) {
return convertMatrixToCycles<GfMatrix4f>(value.UncheckedGet<GfMatrix4f>());
}
if (value.IsHolding<GfMatrix3f>()) {
return convertMatrixToCycles<GfMatrix3f>(value.UncheckedGet<GfMatrix3f>());
}
if (value.IsHolding<GfMatrix4d>()) {
return convertMatrixToCycles<GfMatrix4d>(value.UncheckedGet<GfMatrix4d>());
}
if (value.IsHolding<GfMatrix3d>()) {
return convertMatrixToCycles<GfMatrix3d>(value.UncheckedGet<GfMatrix3d>());
}
if (value.CanCast<GfMatrix4f>()) {
return convertToCycles<Transform>(VtValue::Cast<GfMatrix4f>(value));
}
if (value.CanCast<GfMatrix3f>()) {
return convertToCycles<Transform>(VtValue::Cast<GfMatrix3f>(value));
}
if (value.CanCast<GfMatrix4d>()) {
return convertToCycles<Transform>(VtValue::Cast<GfMatrix4d>(value));
}
if (value.CanCast<GfMatrix3d>()) {
return convertToCycles<Transform>(VtValue::Cast<GfMatrix3d>(value));
}
TF_WARN("Could not convert VtValue to Transform");
return transform_identity();
}
template<typename DstType, typename SrcType = DstType>
array<DstType> convertToCyclesArray(const VtValue &value)
{
static_assert(sizeof(DstType) == sizeof(SrcType),
"Size mismatch between VtArray and array base type");
using SrcArray = VtArray<SrcType>;
if (value.IsHolding<SrcArray>()) {
const auto &valueData = value.UncheckedGet<SrcArray>();
array<DstType> cyclesArray;
cyclesArray.resize(valueData.size());
std::memcpy(cyclesArray.data(), valueData.data(), valueData.size() * sizeof(DstType));
return cyclesArray;
}
if (value.CanCast<SrcArray>()) {
VtValue castedValue = VtValue::Cast<SrcArray>(value);
const auto &valueData = castedValue.UncheckedGet<SrcArray>();
array<DstType> cyclesArray;
cyclesArray.resize(valueData.size());
std::memcpy(cyclesArray.data(), valueData.data(), valueData.size() * sizeof(DstType));
return cyclesArray;
}
return array<DstType>();
}
template<> array<float3> convertToCyclesArray<float3, GfVec3f>(const VtValue &value)
{
if (value.IsHolding<VtVec3fArray>()) {
const auto &valueData = value.UncheckedGet<VtVec3fArray>();
array<float3> cyclesArray;
cyclesArray.reserve(valueData.size());
for (const GfVec3f &vec : valueData) {
cyclesArray.push_back_reserved(make_float3(vec[0], vec[1], vec[2]));
}
return cyclesArray;
}
if (value.IsHolding<VtVec4fArray>()) {
const auto &valueData = value.UncheckedGet<VtVec4fArray>();
array<float3> cyclesArray;
cyclesArray.reserve(valueData.size());
for (const GfVec4f &vec : valueData) {
cyclesArray.push_back_reserved(make_float3(vec[0], vec[1], vec[2]));
}
return cyclesArray;
}
if (value.CanCast<VtVec3fArray>()) {
return convertToCyclesArray<float3, GfVec3f>(VtValue::Cast<VtVec3fArray>(value));
}
if (value.CanCast<VtVec4fArray>()) {
return convertToCyclesArray<float3, GfVec3f>(VtValue::Cast<VtVec4fArray>(value));
}
return array<float3>();
}
template<> array<ustring> convertToCyclesArray<ustring, void>(const VtValue &value)
{
using SdfPathArray = VtArray<SdfAssetPath>;
if (value.IsHolding<VtStringArray>()) {
const auto &valueData = value.UncheckedGet<VtStringArray>();
array<ustring> cyclesArray;
cyclesArray.reserve(valueData.size());
for (const auto &element : valueData) {
cyclesArray.push_back_reserved(ustring(element));
}
return cyclesArray;
}
if (value.IsHolding<VtTokenArray>()) {
const auto &valueData = value.UncheckedGet<VtTokenArray>();
array<ustring> cyclesArray;
cyclesArray.reserve(valueData.size());
for (const auto &element : valueData) {
cyclesArray.push_back_reserved(ustring(element.GetString()));
}
return cyclesArray;
}
if (value.IsHolding<SdfPathArray>()) {
const auto &valueData = value.UncheckedGet<SdfPathArray>();
array<ustring> cyclesArray;
cyclesArray.reserve(valueData.size());
for (const auto &element : valueData) {
cyclesArray.push_back_reserved(ustring(element.GetResolvedPath()));
}
return cyclesArray;
}
if (value.CanCast<VtStringArray>()) {
return convertToCyclesArray<ustring, void>(VtValue::Cast<VtStringArray>(value));
}
if (value.CanCast<VtTokenArray>()) {
return convertToCyclesArray<ustring, void>(VtValue::Cast<VtTokenArray>(value));
}
if (value.CanCast<SdfPathArray>()) {
return convertToCyclesArray<ustring, void>(VtValue::Cast<SdfPathArray>(value));
}
TF_WARN("Could not convert VtValue to array<ustring>");
return array<ustring>();
}
template<typename MatrixArray> array<Transform> convertToCyclesTransformArray(const VtValue &value)
{
assert(value.IsHolding<MatrixArray>());
const auto &valueData = value.UncheckedGet<MatrixArray>();
array<Transform> cyclesArray;
cyclesArray.reserve(valueData.size());
for (const auto &element : valueData) {
cyclesArray.push_back_reserved(convertMatrixToCycles<MatrixArray::value_type>(element));
}
return cyclesArray;
}
template<> array<Transform> convertToCyclesArray<Transform, void>(const VtValue &value)
{
if (value.IsHolding<VtMatrix4fArray>()) {
return convertToCyclesTransformArray<VtMatrix4fArray>(value);
}
if (value.IsHolding<VtMatrix3fArray>()) {
return convertToCyclesTransformArray<VtMatrix3fArray>(value);
}
if (value.IsHolding<VtMatrix4dArray>()) {
return convertToCyclesTransformArray<VtMatrix4dArray>(value);
}
if (value.IsHolding<VtMatrix3dArray>()) {
return convertToCyclesTransformArray<VtMatrix3dArray>(value);
}
if (value.CanCast<VtMatrix4fArray>()) {
return convertToCyclesTransformArray<VtMatrix4fArray>(VtValue::Cast<VtMatrix4fArray>(value));
}
if (value.CanCast<VtMatrix3fArray>()) {
return convertToCyclesTransformArray<VtMatrix3fArray>(VtValue::Cast<VtMatrix3fArray>(value));
}
if (value.CanCast<VtMatrix4dArray>()) {
return convertToCyclesTransformArray<VtMatrix4dArray>(VtValue::Cast<VtMatrix4dArray>(value));
}
if (value.CanCast<VtMatrix3dArray>()) {
return convertToCyclesTransformArray<VtMatrix3dArray>(VtValue::Cast<VtMatrix3dArray>(value));
}
TF_WARN("Could not convert VtValue to array<Transform>");
return array<Transform>();
}
template<typename SrcType> VtValue convertFromCycles(const SrcType &value)
{
return VtValue(value);
}
template<> VtValue convertFromCycles<float2>(const float2 &value)
{
const GfVec2f convertedValue(value.x, value.y);
return VtValue(convertedValue);
}
template<> VtValue convertFromCycles<float3>(const float3 &value)
{
const GfVec3f convertedValue(value.x, value.y, value.z);
return VtValue(convertedValue);
}
template<> VtValue convertFromCycles<ustring>(const ustring &value)
{
return VtValue(value.string());
}
GfMatrix4f convertMatrixFromCycles(const Transform &matrix)
{
return GfMatrix4f(matrix[0][0],
matrix[1][0],
matrix[2][0],
0.0f,
matrix[0][1],
matrix[1][1],
matrix[2][1],
0.0f,
matrix[0][2],
matrix[1][2],
matrix[2][2],
0.0f,
0.0f,
0.0f,
0.0f,
1.0f);
}
template<> VtValue convertFromCycles<Transform>(const Transform &value)
{
return VtValue(convertMatrixFromCycles(value));
}
template<typename SrcType, typename DstType = SrcType>
VtValue convertFromCyclesArray(const array<SrcType> &value)
{
static_assert(sizeof(DstType) == sizeof(SrcType),
"Size mismatch between VtArray and array base type");
VtArray<DstType> convertedValue;
convertedValue.resize(value.size());
std::memcpy(convertedValue.data(), value.data(), value.size() * sizeof(SrcType));
return VtValue(convertedValue);
}
template<> VtValue convertFromCyclesArray<float3, GfVec3f>(const array<float3> &value)
{
VtVec3fArray convertedValue;
convertedValue.reserve(value.size());
for (const auto &element : value) {
convertedValue.push_back(GfVec3f(element.x, element.y, element.z));
}
return VtValue(convertedValue);
}
template<> VtValue convertFromCyclesArray<ustring, void>(const array<ustring> &value)
{
VtStringArray convertedValue;
convertedValue.reserve(value.size());
for (const auto &element : value) {
convertedValue.push_back(element.string());
}
return VtValue(convertedValue);
}
template<> VtValue convertFromCyclesArray<Transform, void>(const array<Transform> &value)
{
VtMatrix4fArray convertedValue;
convertedValue.reserve(value.size());
for (const auto &element : value) {
convertedValue.push_back(convertMatrixFromCycles(element));
}
return VtValue(convertedValue);
}
} // namespace
void SetNodeValue(Node *node, const SocketType &socket, const VtValue &value)
{
switch (socket.type) {
default:
case SocketType::UNDEFINED:
TF_RUNTIME_ERROR("Unexpected conversion: SocketType::UNDEFINED");
break;
case SocketType::BOOLEAN:
node->set(socket, convertToCycles<bool>(value));
break;
case SocketType::FLOAT:
node->set(socket, convertToCycles<float>(value));
break;
case SocketType::INT:
node->set(socket, convertToCycles<int>(value));
break;
case SocketType::UINT:
node->set(socket, convertToCycles<unsigned int>(value));
break;
case SocketType::COLOR:
case SocketType::VECTOR:
case SocketType::POINT:
case SocketType::NORMAL:
node->set(socket, convertToCycles<float3>(value));
break;
case SocketType::POINT2:
node->set(socket, convertToCycles<float2>(value));
break;
case SocketType::CLOSURE:
// Handled by node connections
break;
case SocketType::STRING:
node->set(socket, convertToCycles<ustring>(value));
break;
case SocketType::ENUM:
// Enum's can accept a string or an int
if (value.IsHolding<TfToken>() || value.IsHolding<std::string>()) {
node->set(socket, convertToCycles<ustring>(value));
}
else {
node->set(socket, convertToCycles<int>(value));
}
break;
case SocketType::TRANSFORM:
node->set(socket, convertToCycles<Transform>(value));
break;
case SocketType::NODE:
// TODO: renderIndex->GetRprim()->cycles_node ?
TF_WARN("Unimplemented conversion: SocketType::NODE");
break;
case SocketType::BOOLEAN_ARRAY: {
auto cyclesArray = convertToCyclesArray<bool>(value);
node->set(socket, cyclesArray);
break;
}
case SocketType::FLOAT_ARRAY: {
auto cyclesArray = convertToCyclesArray<float>(value);
node->set(socket, cyclesArray);
break;
}
case SocketType::INT_ARRAY: {
auto cyclesArray = convertToCyclesArray<int>(value);
node->set(socket, cyclesArray);
break;
}
case SocketType::COLOR_ARRAY:
case SocketType::VECTOR_ARRAY:
case SocketType::POINT_ARRAY:
case SocketType::NORMAL_ARRAY: {
auto cyclesArray = convertToCyclesArray<float3, GfVec3f>(value);
node->set(socket, cyclesArray);
break;
}
case SocketType::POINT2_ARRAY: {
auto cyclesArray = convertToCyclesArray<float2, GfVec2f>(value);
node->set(socket, cyclesArray);
break;
}
case SocketType::STRING_ARRAY: {
auto cyclesArray = convertToCyclesArray<ustring, void>(value);
node->set(socket, cyclesArray);
break;
}
case SocketType::TRANSFORM_ARRAY: {
auto cyclesArray = convertToCyclesArray<Transform, void>(value);
node->set(socket, cyclesArray);
break;
}
case SocketType::NODE_ARRAY: {
// TODO: renderIndex->GetRprim()->cycles_node ?
TF_WARN("Unimplemented conversion: SocketType::NODE_ARRAY");
break;
}
}
}
VtValue GetNodeValue(const Node *node, const SocketType &socket)
{
switch (socket.type) {
default:
case SocketType::UNDEFINED:
TF_RUNTIME_ERROR("Unexpected conversion: SocketType::UNDEFINED");
return VtValue();
case SocketType::BOOLEAN:
return convertFromCycles(node->get_bool(socket));
case SocketType::FLOAT:
return convertFromCycles(node->get_float(socket));
case SocketType::INT:
return convertFromCycles(node->get_int(socket));
case SocketType::UINT:
return convertFromCycles(node->get_uint(socket));
case SocketType::COLOR:
case SocketType::VECTOR:
case SocketType::POINT:
case SocketType::NORMAL:
return convertFromCycles(node->get_float3(socket));
case SocketType::POINT2:
return convertFromCycles(node->get_float2(socket));
case SocketType::CLOSURE:
return VtValue();
case SocketType::STRING:
return convertFromCycles(node->get_string(socket));
case SocketType::ENUM:
return convertFromCycles(node->get_int(socket));
case SocketType::TRANSFORM:
return convertFromCycles(node->get_transform(socket));
case SocketType::NODE:
TF_WARN("Unimplemented conversion: SocketType::NODE");
return VtValue();
case SocketType::BOOLEAN_ARRAY:
return convertFromCyclesArray(node->get_bool_array(socket));
case SocketType::FLOAT_ARRAY:
return convertFromCyclesArray(node->get_float_array(socket));
case SocketType::INT_ARRAY:
return convertFromCyclesArray(node->get_int_array(socket));
case SocketType::COLOR_ARRAY:
case SocketType::VECTOR_ARRAY:
case SocketType::POINT_ARRAY:
case SocketType::NORMAL_ARRAY:
return convertFromCyclesArray<float3, GfVec3f>(node->get_float3_array(socket));
case SocketType::POINT2_ARRAY:
return convertFromCyclesArray<float2, GfVec2f>(node->get_float2_array(socket));
case SocketType::STRING_ARRAY:
return convertFromCyclesArray<ustring, void>(node->get_string_array(socket));
case SocketType::TRANSFORM_ARRAY:
return convertFromCyclesArray<Transform, void>(node->get_transform_array(socket));
case SocketType::NODE_ARRAY: {
TF_WARN("Unimplemented conversion: SocketType::NODE_ARRAY");
return VtValue();
}
}
}
HDCYCLES_NAMESPACE_CLOSE_SCOPE
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