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/* SPDX-License-Identifier: GPL-2.0-or-later */
#include "BKE_curves.hh"
#include "node_geometry_util.hh"
namespace blender::nodes::node_geo_curve_topology_curve_of_point_cc {
static void node_declare(NodeDeclarationBuilder &b)
{
b.add_input<decl::Int>(N_("Point Index"))
.implicit_field(implicit_field_inputs::index)
.description(N_("The control point to retrieve data from"));
b.add_output<decl::Int>(N_("Curve Index"))
.dependent_field()
.description(N_("The curve the control point is part of"));
b.add_output<decl::Int>(N_("Index in Curve"))
.dependent_field()
.description(N_("How far along the control point is along its curve"));
}
class CurveOfPointInput final : public bke::CurvesFieldInput {
public:
CurveOfPointInput() : bke::CurvesFieldInput(CPPType::get<int>(), "Point Curve Index")
{
category_ = Category::Generated;
}
GVArray get_varray_for_context(const bke::CurvesGeometry &curves,
const eAttrDomain domain,
const IndexMask /*mask*/) const final
{
if (domain != ATTR_DOMAIN_POINT) {
return {};
}
return VArray<int>::ForContainer(curves.point_to_curve_map());
}
uint64_t hash() const override
{
return 413209687345908697;
}
bool is_equal_to(const fn::FieldNode &other) const override
{
if (dynamic_cast<const CurveOfPointInput *>(&other)) {
return true;
}
return false;
}
};
class PointIndexInCurveInput final : public bke::CurvesFieldInput {
public:
PointIndexInCurveInput() : bke::CurvesFieldInput(CPPType::get<int>(), "Point Index in Curve")
{
category_ = Category::Generated;
}
GVArray get_varray_for_context(const bke::CurvesGeometry &curves,
const eAttrDomain domain,
const IndexMask /*mask*/) const final
{
if (domain != ATTR_DOMAIN_POINT) {
return {};
}
const Span<int> offsets = curves.offsets();
Array<int> point_to_curve_map = curves.point_to_curve_map();
return VArray<int>::ForFunc(
curves.points_num(),
[offsets, point_to_curve_map = std::move(point_to_curve_map)](const int point_i) {
const int curve_i = point_to_curve_map[point_i];
return point_i - offsets[curve_i];
});
}
uint64_t hash() const final
{
return 9834765987345677;
}
bool is_equal_to(const fn::FieldNode &other) const final
{
if (dynamic_cast<const PointIndexInCurveInput *>(&other)) {
return true;
}
return false;
}
};
static void node_geo_exec(GeoNodeExecParams params)
{
const Field<int> point_index = params.extract_input<Field<int>>("Point Index");
if (params.output_is_required("Curve Index")) {
params.set_output(
"Curve Index",
Field<int>(std::make_shared<FieldAtIndexInput>(
point_index, Field<int>(std::make_shared<CurveOfPointInput>()), ATTR_DOMAIN_POINT)));
}
if (params.output_is_required("Index in Curve")) {
params.set_output("Index in Curve",
Field<int>(std::make_shared<FieldAtIndexInput>(
point_index,
Field<int>(std::make_shared<PointIndexInCurveInput>()),
ATTR_DOMAIN_POINT)));
}
}
} // namespace blender::nodes::node_geo_curve_topology_curve_of_point_cc
void register_node_type_geo_curve_topology_curve_of_point()
{
namespace file_ns = blender::nodes::node_geo_curve_topology_curve_of_point_cc;
static bNodeType ntype;
geo_node_type_base(
&ntype, GEO_NODE_CURVE_TOPOLOGY_CURVE_OF_POINT, "Curve of Point", NODE_CLASS_INPUT);
ntype.geometry_node_execute = file_ns::node_geo_exec;
ntype.declare = file_ns::node_declare;
nodeRegisterType(&ntype);
}
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