Jacques Lucke
bf47fb40fd
This implements the initial core framework for fields and anonymous attributes (also see T91274). The new functionality is hidden behind the "Geometry Nodes Fields" feature flag. When enabled in the user preferences, the following new nodes become available: `Position`, `Index`, `Normal`, `Set Position` and `Attribute Capture`. Socket inspection has not been updated to work with fields yet. Besides these changes at the user level, this patch contains the ground work for: * building and evaluating fields at run-time (`FN_fields.hh`) and * creating and accessing anonymous attributes on geometry (`BKE_anonymous_attribute.h`). For evaluating fields we use a new so called multi-function procedure (`FN_multi_function_procedure.hh`). It allows composing multi-functions in arbitrary ways and supports efficient evaluation as is required by fields. See `FN_multi_function_procedure.hh` for more details on how this evaluation mechanism can be used. A new `AttributeIDRef` has been added which allows handling named and anonymous attributes in the same way in many places. Hans and I worked on this patch together. Differential Revision: https://developer.blender.org/D12414
292 lines
10 KiB
C++
292 lines
10 KiB
C++
/*
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* This program is free software; you can redistribute it and/or
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* modify it under the terms of the GNU General Public License
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* as published by the Free Software Foundation; either version 2
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* of the License, or (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software Foundation,
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* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
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*/
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#pragma once
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/** \file
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* \ingroup fn
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*
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* This file provides an MFParams and MFParamsBuilder structure.
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*
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* `MFParamsBuilder` is used by a function caller to be prepare all parameters that are passed into
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* the function. `MFParams` is then used inside the called function to access the parameters.
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*/
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#include "BLI_resource_scope.hh"
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#include "FN_generic_pointer.hh"
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#include "FN_generic_vector_array.hh"
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#include "FN_generic_virtual_vector_array.hh"
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#include "FN_multi_function_signature.hh"
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namespace blender::fn {
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class MFParamsBuilder {
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private:
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ResourceScope scope_;
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const MFSignature *signature_;
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int64_t min_array_size_;
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Vector<const GVArray *> virtual_arrays_;
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Vector<GMutableSpan> mutable_spans_;
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Vector<const GVVectorArray *> virtual_vector_arrays_;
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Vector<GVectorArray *> vector_arrays_;
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friend class MFParams;
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public:
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MFParamsBuilder(const MFSignature &signature, int64_t min_array_size)
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: signature_(&signature), min_array_size_(min_array_size)
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{
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}
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MFParamsBuilder(const class MultiFunction &fn, int64_t min_array_size);
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template<typename T> void add_readonly_single_input_value(T value, StringRef expected_name = "")
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{
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T *value_ptr = &scope_.add_value<T>(std::move(value), __func__);
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this->add_readonly_single_input(value_ptr, expected_name);
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}
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template<typename T> void add_readonly_single_input(const T *value, StringRef expected_name = "")
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{
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this->add_readonly_single_input(scope_.construct<GVArray_For_SingleValueRef>(
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__func__, CPPType::get<T>(), min_array_size_, value),
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expected_name);
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}
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void add_readonly_single_input(const GSpan span, StringRef expected_name = "")
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{
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this->add_readonly_single_input(scope_.construct<GVArray_For_GSpan>(__func__, span),
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expected_name);
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}
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void add_readonly_single_input(GPointer value, StringRef expected_name = "")
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{
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this->add_readonly_single_input(scope_.construct<GVArray_For_SingleValueRef>(
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__func__, *value.type(), min_array_size_, value.get()),
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expected_name);
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}
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void add_readonly_single_input(const GVArray &ref, StringRef expected_name = "")
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{
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this->assert_current_param_type(MFParamType::ForSingleInput(ref.type()), expected_name);
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BLI_assert(ref.size() >= min_array_size_);
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virtual_arrays_.append(&ref);
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}
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void add_readonly_vector_input(const GVectorArray &vector_array, StringRef expected_name = "")
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{
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this->add_readonly_vector_input(
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scope_.construct<GVVectorArray_For_GVectorArray>(__func__, vector_array), expected_name);
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}
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void add_readonly_vector_input(const GSpan single_vector, StringRef expected_name = "")
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{
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this->add_readonly_vector_input(
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scope_.construct<GVVectorArray_For_SingleGSpan>(__func__, single_vector, min_array_size_),
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expected_name);
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}
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void add_readonly_vector_input(const GVVectorArray &ref, StringRef expected_name = "")
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{
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this->assert_current_param_type(MFParamType::ForVectorInput(ref.type()), expected_name);
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BLI_assert(ref.size() >= min_array_size_);
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virtual_vector_arrays_.append(&ref);
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}
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template<typename T> void add_uninitialized_single_output(T *value, StringRef expected_name = "")
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{
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this->add_uninitialized_single_output(GMutableSpan(CPPType::get<T>(), value, 1),
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expected_name);
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}
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void add_uninitialized_single_output(GMutableSpan ref, StringRef expected_name = "")
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{
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this->assert_current_param_type(MFParamType::ForSingleOutput(ref.type()), expected_name);
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BLI_assert(ref.size() >= min_array_size_);
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mutable_spans_.append(ref);
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}
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void add_vector_output(GVectorArray &vector_array, StringRef expected_name = "")
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{
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this->assert_current_param_type(MFParamType::ForVectorOutput(vector_array.type()),
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expected_name);
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BLI_assert(vector_array.size() >= min_array_size_);
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vector_arrays_.append(&vector_array);
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}
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void add_single_mutable(GMutableSpan ref, StringRef expected_name = "")
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{
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this->assert_current_param_type(MFParamType::ForMutableSingle(ref.type()), expected_name);
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BLI_assert(ref.size() >= min_array_size_);
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mutable_spans_.append(ref);
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}
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void add_vector_mutable(GVectorArray &vector_array, StringRef expected_name = "")
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{
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this->assert_current_param_type(MFParamType::ForMutableVector(vector_array.type()),
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expected_name);
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BLI_assert(vector_array.size() >= min_array_size_);
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vector_arrays_.append(&vector_array);
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}
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GMutableSpan computed_array(int param_index)
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{
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BLI_assert(ELEM(signature_->param_types[param_index].category(),
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MFParamType::SingleOutput,
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MFParamType::SingleMutable));
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int data_index = signature_->data_index(param_index);
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return mutable_spans_[data_index];
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}
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GVectorArray &computed_vector_array(int param_index)
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{
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BLI_assert(ELEM(signature_->param_types[param_index].category(),
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MFParamType::VectorOutput,
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MFParamType::VectorMutable));
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int data_index = signature_->data_index(param_index);
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return *vector_arrays_[data_index];
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}
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ResourceScope &resource_scope()
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{
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return scope_;
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}
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private:
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void assert_current_param_type(MFParamType param_type, StringRef expected_name = "")
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{
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UNUSED_VARS_NDEBUG(param_type, expected_name);
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#ifdef DEBUG
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int param_index = this->current_param_index();
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if (expected_name != "") {
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StringRef actual_name = signature_->param_names[param_index];
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BLI_assert(actual_name == expected_name);
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}
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MFParamType expected_type = signature_->param_types[param_index];
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BLI_assert(expected_type == param_type);
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#endif
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}
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int current_param_index() const
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{
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return virtual_arrays_.size() + mutable_spans_.size() + virtual_vector_arrays_.size() +
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vector_arrays_.size();
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}
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};
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class MFParams {
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private:
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MFParamsBuilder *builder_;
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public:
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MFParams(MFParamsBuilder &builder) : builder_(&builder)
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{
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}
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template<typename T> const VArray<T> &readonly_single_input(int param_index, StringRef name = "")
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{
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const GVArray &array = this->readonly_single_input(param_index, name);
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return builder_->scope_.construct<GVArray_Typed<T>>(__func__, array);
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}
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const GVArray &readonly_single_input(int param_index, StringRef name = "")
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{
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this->assert_correct_param(param_index, name, MFParamType::SingleInput);
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int data_index = builder_->signature_->data_index(param_index);
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return *builder_->virtual_arrays_[data_index];
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}
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template<typename T>
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MutableSpan<T> uninitialized_single_output(int param_index, StringRef name = "")
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{
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return this->uninitialized_single_output(param_index, name).typed<T>();
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}
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GMutableSpan uninitialized_single_output(int param_index, StringRef name = "")
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{
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this->assert_correct_param(param_index, name, MFParamType::SingleOutput);
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int data_index = builder_->signature_->data_index(param_index);
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return builder_->mutable_spans_[data_index];
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}
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template<typename T>
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const VVectorArray<T> &readonly_vector_input(int param_index, StringRef name = "")
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{
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const GVVectorArray &vector_array = this->readonly_vector_input(param_index, name);
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return builder_->scope_.construct<VVectorArray_For_GVVectorArray<T>>(__func__, vector_array);
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}
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const GVVectorArray &readonly_vector_input(int param_index, StringRef name = "")
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{
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this->assert_correct_param(param_index, name, MFParamType::VectorInput);
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int data_index = builder_->signature_->data_index(param_index);
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return *builder_->virtual_vector_arrays_[data_index];
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}
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template<typename T>
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GVectorArray_TypedMutableRef<T> vector_output(int param_index, StringRef name = "")
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{
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return {this->vector_output(param_index, name)};
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}
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GVectorArray &vector_output(int param_index, StringRef name = "")
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{
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this->assert_correct_param(param_index, name, MFParamType::VectorOutput);
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int data_index = builder_->signature_->data_index(param_index);
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return *builder_->vector_arrays_[data_index];
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}
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template<typename T> MutableSpan<T> single_mutable(int param_index, StringRef name = "")
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{
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return this->single_mutable(param_index, name).typed<T>();
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}
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GMutableSpan single_mutable(int param_index, StringRef name = "")
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{
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this->assert_correct_param(param_index, name, MFParamType::SingleMutable);
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int data_index = builder_->signature_->data_index(param_index);
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return builder_->mutable_spans_[data_index];
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}
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template<typename T>
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GVectorArray_TypedMutableRef<T> vector_mutable(int param_index, StringRef name = "")
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{
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return {this->vector_mutable(param_index, name)};
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}
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GVectorArray &vector_mutable(int param_index, StringRef name = "")
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{
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this->assert_correct_param(param_index, name, MFParamType::VectorMutable);
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int data_index = builder_->signature_->data_index(param_index);
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return *builder_->vector_arrays_[data_index];
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}
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private:
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void assert_correct_param(int param_index, StringRef name, MFParamType param_type)
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{
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UNUSED_VARS_NDEBUG(param_index, name, param_type);
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#ifdef DEBUG
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BLI_assert(builder_->signature_->param_types[param_index] == param_type);
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if (name.size() > 0) {
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BLI_assert(builder_->signature_->param_names[param_index] == name);
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}
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#endif
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}
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void assert_correct_param(int param_index, StringRef name, MFParamType::Category category)
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{
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UNUSED_VARS_NDEBUG(param_index, name, category);
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#ifdef DEBUG
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BLI_assert(builder_->signature_->param_types[param_index].category() == category);
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if (name.size() > 0) {
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BLI_assert(builder_->signature_->param_names[param_index] == name);
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}
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#endif
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}
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};
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} // namespace blender::fn
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