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// std lib related includes
#include <tuple>
// pybind 11 related includes
#include <pybind11/pybind11.h>
#include <pybind11/stl.h>
namespace py = pybind11;
// Standard Handle
#include <Standard_Handle.hxx>
// includes to resolve forward declarations
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Geom2d_BezierCurve.hxx>
#include <Geom2d_BSplineCurve.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Geom2d_BezierCurve.hxx>
#include <Geom2d_BSplineCurve.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Geom2d_BezierCurve.hxx>
#include <Geom2d_BSplineCurve.hxx>
// module includes
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor2d_Line2d.hxx>
#include <Adaptor2d_OffsetCurve.hxx>
// template related includes
// user-defined pre
#include "OCP_specific.inc"
// user-defined inclusion per module
// Module definiiton
void register_Adaptor2d(py::module &main_module) {
py::module m = static_cast<py::module>(main_module.attr("Adaptor2d"));
py::object klass;
//Python trampoline classes
// classes
// Class Adaptor2d_Curve2d from ./opencascade/Adaptor2d_Curve2d.hxx
klass = m.attr("Adaptor2d_Curve2d");
// default constructor
register_default_constructor<Adaptor2d_Curve2d ,opencascade::handle<Adaptor2d_Curve2d>>(m,"Adaptor2d_Curve2d");
// nested enums
static_cast<py::class_<Adaptor2d_Curve2d ,opencascade::handle<Adaptor2d_Curve2d> , Standard_Transient >>(klass)
// constructors
// custom constructors
// methods
.def("ShallowCopy",
(opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Curve2d::*)() const) static_cast<opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::ShallowCopy),
R"#(Shallow copy of adaptor)#"
)
.def("FirstParameter",
(Standard_Real (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Real (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::FirstParameter),
R"#(None)#"
)
.def("LastParameter",
(Standard_Real (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Real (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::LastParameter),
R"#(None)#"
)
.def("Continuity",
(GeomAbs_Shape (Adaptor2d_Curve2d::*)() const) static_cast<GeomAbs_Shape (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Continuity),
R"#(None)#"
)
.def("NbIntervals",
(Standard_Integer (Adaptor2d_Curve2d::*)( const GeomAbs_Shape ) const) static_cast<Standard_Integer (Adaptor2d_Curve2d::*)( const GeomAbs_Shape ) const>(&Adaptor2d_Curve2d::NbIntervals),
R"#(If necessary, breaks the curve in intervals of continuity <S>. And returns the number of intervals.)#" , py::arg("S")
)
.def("Intervals",
(void (Adaptor2d_Curve2d::*)( NCollection_Array1<Standard_Real> & , const GeomAbs_Shape ) const) static_cast<void (Adaptor2d_Curve2d::*)( NCollection_Array1<Standard_Real> & , const GeomAbs_Shape ) const>(&Adaptor2d_Curve2d::Intervals),
R"#(Stores in <T> the parameters bounding the intervals of continuity <S>.)#" , py::arg("T"), py::arg("S")
)
.def("Trim",
(opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Curve2d::*)( const Standard_Real , const Standard_Real , const Standard_Real ) const) static_cast<opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Curve2d::*)( const Standard_Real , const Standard_Real , const Standard_Real ) const>(&Adaptor2d_Curve2d::Trim),
R"#(Returns a curve equivalent of <me> between parameters <First> and <Last>. <Tol> is used to test for 3d points confusion. If <First> >= <Last>)#" , py::arg("First"), py::arg("Last"), py::arg("Tol")
)
.def("IsClosed",
(Standard_Boolean (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Boolean (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::IsClosed),
R"#(None)#"
)
.def("IsPeriodic",
(Standard_Boolean (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Boolean (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::IsPeriodic),
R"#(None)#"
)
.def("Period",
(Standard_Real (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Real (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Period),
R"#(None)#"
)
.def("Value",
(gp_Pnt2d (Adaptor2d_Curve2d::*)( const Standard_Real ) const) static_cast<gp_Pnt2d (Adaptor2d_Curve2d::*)( const Standard_Real ) const>(&Adaptor2d_Curve2d::Value),
R"#(Computes the point of parameter U on the curve.)#" , py::arg("U")
)
.def("D0",
(void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & ) const) static_cast<void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & ) const>(&Adaptor2d_Curve2d::D0),
R"#(Computes the point of parameter U on the curve.)#" , py::arg("U"), py::arg("P")
)
.def("D1",
(void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & ) const>(&Adaptor2d_Curve2d::D1),
R"#(Computes the point of parameter U on the curve with its first derivative. Raised if the continuity of the current interval is not C1.)#" , py::arg("U"), py::arg("P"), py::arg("V")
)
.def("D2",
(void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & ) const>(&Adaptor2d_Curve2d::D2),
R"#(Returns the point P of parameter U, the first and second derivatives V1 and V2. Raised if the continuity of the current interval is not C2.)#" , py::arg("U"), py::arg("P"), py::arg("V1"), py::arg("V2")
)
.def("D3",
(void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_Curve2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & , gp_Vec2d & ) const>(&Adaptor2d_Curve2d::D3),
R"#(Returns the point P of parameter U, the first, the second and the third derivative. Raised if the continuity of the current interval is not C3.)#" , py::arg("U"), py::arg("P"), py::arg("V1"), py::arg("V2"), py::arg("V3")
)
.def("DN",
(gp_Vec2d (Adaptor2d_Curve2d::*)( const Standard_Real , const Standard_Integer ) const) static_cast<gp_Vec2d (Adaptor2d_Curve2d::*)( const Standard_Real , const Standard_Integer ) const>(&Adaptor2d_Curve2d::DN),
R"#(The returned vector gives the value of the derivative for the order of derivation N. Raised if the continuity of the current interval is not CN. Raised if N < 1.)#" , py::arg("U"), py::arg("N")
)
.def("Resolution",
(Standard_Real (Adaptor2d_Curve2d::*)( const Standard_Real ) const) static_cast<Standard_Real (Adaptor2d_Curve2d::*)( const Standard_Real ) const>(&Adaptor2d_Curve2d::Resolution),
R"#(Returns the parametric resolution corresponding to the real space resolution <R3d>.)#" , py::arg("R3d")
)
.def("GetType",
(GeomAbs_CurveType (Adaptor2d_Curve2d::*)() const) static_cast<GeomAbs_CurveType (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::GetType),
R"#(Returns the type of the curve in the current interval : Line, Circle, Ellipse, Hyperbola, Parabola, BezierCurve, BSplineCurve, OtherCurve.)#"
)
.def("Line",
(gp_Lin2d (Adaptor2d_Curve2d::*)() const) static_cast<gp_Lin2d (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Line),
R"#(None)#"
)
.def("Circle",
(gp_Circ2d (Adaptor2d_Curve2d::*)() const) static_cast<gp_Circ2d (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Circle),
R"#(None)#"
)
.def("Ellipse",
(gp_Elips2d (Adaptor2d_Curve2d::*)() const) static_cast<gp_Elips2d (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Ellipse),
R"#(None)#"
)
.def("Hyperbola",
(gp_Hypr2d (Adaptor2d_Curve2d::*)() const) static_cast<gp_Hypr2d (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Hyperbola),
R"#(None)#"
)
.def("Parabola",
(gp_Parab2d (Adaptor2d_Curve2d::*)() const) static_cast<gp_Parab2d (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Parabola),
R"#(None)#"
)
.def("Degree",
(Standard_Integer (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Integer (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Degree),
R"#(None)#"
)
.def("IsRational",
(Standard_Boolean (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Boolean (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::IsRational),
R"#(None)#"
)
.def("NbPoles",
(Standard_Integer (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Integer (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::NbPoles),
R"#(None)#"
)
.def("NbKnots",
(Standard_Integer (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Integer (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::NbKnots),
R"#(None)#"
)
.def("NbSamples",
(Standard_Integer (Adaptor2d_Curve2d::*)() const) static_cast<Standard_Integer (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::NbSamples),
R"#(None)#"
)
.def("Bezier",
(opencascade::handle<Geom2d_BezierCurve> (Adaptor2d_Curve2d::*)() const) static_cast<opencascade::handle<Geom2d_BezierCurve> (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::Bezier),
R"#(None)#"
)
.def("BSpline",
(opencascade::handle<Geom2d_BSplineCurve> (Adaptor2d_Curve2d::*)() const) static_cast<opencascade::handle<Geom2d_BSplineCurve> (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::BSpline),
R"#(None)#"
)
// methods using call by reference i.s.o. return
// static methods
.def_static("get_type_name_s",
(const char * (*)() ) static_cast<const char * (*)() >(&Adaptor2d_Curve2d::get_type_name),
R"#(None)#"
)
.def_static("get_type_descriptor_s",
(const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&Adaptor2d_Curve2d::get_type_descriptor),
R"#(None)#"
)
// static methods using call by reference i.s.o. return
// operators
// additional methods and static methods
// properties
// methods returning by ref wrapped as properties
.def("DynamicType",
(const opencascade::handle<Standard_Type> & (Adaptor2d_Curve2d::*)() const) static_cast<const opencascade::handle<Standard_Type> & (Adaptor2d_Curve2d::*)() const>(&Adaptor2d_Curve2d::DynamicType),
R"#(None)#"
)
;
// Class Adaptor2d_Line2d from ./opencascade/Adaptor2d_Line2d.hxx
klass = m.attr("Adaptor2d_Line2d");
// nested enums
static_cast<py::class_<Adaptor2d_Line2d ,opencascade::handle<Adaptor2d_Line2d> , Adaptor2d_Curve2d >>(klass)
// constructors
.def(py::init< >() )
.def(py::init< const gp_Pnt2d &,const gp_Dir2d &,const Standard_Real,const Standard_Real >() , py::arg("P"), py::arg("D"), py::arg("UFirst"), py::arg("ULast") )
// custom constructors
// methods
.def("ShallowCopy",
(opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Line2d::*)() const) static_cast<opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::ShallowCopy),
R"#(Shallow copy of adaptor)#"
)
.def("Load",
(void (Adaptor2d_Line2d::*)( const gp_Lin2d & ) ) static_cast<void (Adaptor2d_Line2d::*)( const gp_Lin2d & ) >(&Adaptor2d_Line2d::Load),
R"#(None)#" , py::arg("L")
)
.def("Load",
(void (Adaptor2d_Line2d::*)( const gp_Lin2d & , const Standard_Real , const Standard_Real ) ) static_cast<void (Adaptor2d_Line2d::*)( const gp_Lin2d & , const Standard_Real , const Standard_Real ) >(&Adaptor2d_Line2d::Load),
R"#(None)#" , py::arg("L"), py::arg("UFirst"), py::arg("ULast")
)
.def("FirstParameter",
(Standard_Real (Adaptor2d_Line2d::*)() const) static_cast<Standard_Real (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::FirstParameter),
R"#(None)#"
)
.def("LastParameter",
(Standard_Real (Adaptor2d_Line2d::*)() const) static_cast<Standard_Real (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::LastParameter),
R"#(None)#"
)
.def("Continuity",
(GeomAbs_Shape (Adaptor2d_Line2d::*)() const) static_cast<GeomAbs_Shape (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Continuity),
R"#(None)#"
)
.def("NbIntervals",
(Standard_Integer (Adaptor2d_Line2d::*)( const GeomAbs_Shape ) const) static_cast<Standard_Integer (Adaptor2d_Line2d::*)( const GeomAbs_Shape ) const>(&Adaptor2d_Line2d::NbIntervals),
R"#(If necessary, breaks the curve in intervals of continuity <S>. And returns the number of intervals.)#" , py::arg("S")
)
.def("Intervals",
(void (Adaptor2d_Line2d::*)( NCollection_Array1<Standard_Real> & , const GeomAbs_Shape ) const) static_cast<void (Adaptor2d_Line2d::*)( NCollection_Array1<Standard_Real> & , const GeomAbs_Shape ) const>(&Adaptor2d_Line2d::Intervals),
R"#(Stores in <T> the parameters bounding the intervals of continuity <S>.)#" , py::arg("T"), py::arg("S")
)
.def("Trim",
(opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Line2d::*)( const Standard_Real , const Standard_Real , const Standard_Real ) const) static_cast<opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_Line2d::*)( const Standard_Real , const Standard_Real , const Standard_Real ) const>(&Adaptor2d_Line2d::Trim),
R"#(Returns a curve equivalent of <me> between parameters <First> and <Last>. <Tol> is used to test for 3d points confusion. If <First> >= <Last>)#" , py::arg("First"), py::arg("Last"), py::arg("Tol")
)
.def("IsClosed",
(Standard_Boolean (Adaptor2d_Line2d::*)() const) static_cast<Standard_Boolean (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::IsClosed),
R"#(None)#"
)
.def("IsPeriodic",
(Standard_Boolean (Adaptor2d_Line2d::*)() const) static_cast<Standard_Boolean (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::IsPeriodic),
R"#(None)#"
)
.def("Period",
(Standard_Real (Adaptor2d_Line2d::*)() const) static_cast<Standard_Real (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Period),
R"#(None)#"
)
.def("Value",
(gp_Pnt2d (Adaptor2d_Line2d::*)( const Standard_Real ) const) static_cast<gp_Pnt2d (Adaptor2d_Line2d::*)( const Standard_Real ) const>(&Adaptor2d_Line2d::Value),
R"#(None)#" , py::arg("X")
)
.def("D0",
(void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & ) const) static_cast<void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & ) const>(&Adaptor2d_Line2d::D0),
R"#(None)#" , py::arg("X"), py::arg("P")
)
.def("D1",
(void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & ) const>(&Adaptor2d_Line2d::D1),
R"#(None)#" , py::arg("X"), py::arg("P"), py::arg("V")
)
.def("D2",
(void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & ) const>(&Adaptor2d_Line2d::D2),
R"#(None)#" , py::arg("X"), py::arg("P"), py::arg("V1"), py::arg("V2")
)
.def("D3",
(void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_Line2d::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & , gp_Vec2d & ) const>(&Adaptor2d_Line2d::D3),
R"#(None)#" , py::arg("X"), py::arg("P"), py::arg("V1"), py::arg("V2"), py::arg("V3")
)
.def("DN",
(gp_Vec2d (Adaptor2d_Line2d::*)( const Standard_Real , const Standard_Integer ) const) static_cast<gp_Vec2d (Adaptor2d_Line2d::*)( const Standard_Real , const Standard_Integer ) const>(&Adaptor2d_Line2d::DN),
R"#(None)#" , py::arg("U"), py::arg("N")
)
.def("Resolution",
(Standard_Real (Adaptor2d_Line2d::*)( const Standard_Real ) const) static_cast<Standard_Real (Adaptor2d_Line2d::*)( const Standard_Real ) const>(&Adaptor2d_Line2d::Resolution),
R"#(None)#" , py::arg("R3d")
)
.def("GetType",
(GeomAbs_CurveType (Adaptor2d_Line2d::*)() const) static_cast<GeomAbs_CurveType (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::GetType),
R"#(None)#"
)
.def("Line",
(gp_Lin2d (Adaptor2d_Line2d::*)() const) static_cast<gp_Lin2d (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Line),
R"#(None)#"
)
.def("Circle",
(gp_Circ2d (Adaptor2d_Line2d::*)() const) static_cast<gp_Circ2d (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Circle),
R"#(None)#"
)
.def("Ellipse",
(gp_Elips2d (Adaptor2d_Line2d::*)() const) static_cast<gp_Elips2d (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Ellipse),
R"#(None)#"
)
.def("Hyperbola",
(gp_Hypr2d (Adaptor2d_Line2d::*)() const) static_cast<gp_Hypr2d (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Hyperbola),
R"#(None)#"
)
.def("Parabola",
(gp_Parab2d (Adaptor2d_Line2d::*)() const) static_cast<gp_Parab2d (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Parabola),
R"#(None)#"
)
.def("Degree",
(Standard_Integer (Adaptor2d_Line2d::*)() const) static_cast<Standard_Integer (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Degree),
R"#(None)#"
)
.def("IsRational",
(Standard_Boolean (Adaptor2d_Line2d::*)() const) static_cast<Standard_Boolean (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::IsRational),
R"#(None)#"
)
.def("NbPoles",
(Standard_Integer (Adaptor2d_Line2d::*)() const) static_cast<Standard_Integer (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::NbPoles),
R"#(None)#"
)
.def("NbKnots",
(Standard_Integer (Adaptor2d_Line2d::*)() const) static_cast<Standard_Integer (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::NbKnots),
R"#(None)#"
)
.def("Bezier",
(opencascade::handle<Geom2d_BezierCurve> (Adaptor2d_Line2d::*)() const) static_cast<opencascade::handle<Geom2d_BezierCurve> (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::Bezier),
R"#(None)#"
)
.def("BSpline",
(opencascade::handle<Geom2d_BSplineCurve> (Adaptor2d_Line2d::*)() const) static_cast<opencascade::handle<Geom2d_BSplineCurve> (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::BSpline),
R"#(None)#"
)
// methods using call by reference i.s.o. return
// static methods
.def_static("get_type_name_s",
(const char * (*)() ) static_cast<const char * (*)() >(&Adaptor2d_Line2d::get_type_name),
R"#(None)#"
)
.def_static("get_type_descriptor_s",
(const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&Adaptor2d_Line2d::get_type_descriptor),
R"#(None)#"
)
// static methods using call by reference i.s.o. return
// operators
// additional methods and static methods
// properties
// methods returning by ref wrapped as properties
.def("DynamicType",
(const opencascade::handle<Standard_Type> & (Adaptor2d_Line2d::*)() const) static_cast<const opencascade::handle<Standard_Type> & (Adaptor2d_Line2d::*)() const>(&Adaptor2d_Line2d::DynamicType),
R"#(None)#"
)
;
// Class Adaptor2d_OffsetCurve from ./opencascade/Adaptor2d_OffsetCurve.hxx
klass = m.attr("Adaptor2d_OffsetCurve");
// nested enums
static_cast<py::class_<Adaptor2d_OffsetCurve ,opencascade::handle<Adaptor2d_OffsetCurve> , Adaptor2d_Curve2d >>(klass)
// constructors
.def(py::init< >() )
.def(py::init< const opencascade::handle<Adaptor2d_Curve2d> & >() , py::arg("C") )
.def(py::init< const opencascade::handle<Adaptor2d_Curve2d> &,const Standard_Real >() , py::arg("C"), py::arg("Offset") )
.def(py::init< const opencascade::handle<Adaptor2d_Curve2d> &,const Standard_Real,const Standard_Real,const Standard_Real >() , py::arg("C"), py::arg("Offset"), py::arg("WFirst"), py::arg("WLast") )
// custom constructors
// methods
.def("ShallowCopy",
(opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_OffsetCurve::*)() const) static_cast<opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::ShallowCopy),
R"#(Shallow copy of adaptor)#"
)
.def("Load",
(void (Adaptor2d_OffsetCurve::*)( const opencascade::handle<Adaptor2d_Curve2d> & ) ) static_cast<void (Adaptor2d_OffsetCurve::*)( const opencascade::handle<Adaptor2d_Curve2d> & ) >(&Adaptor2d_OffsetCurve::Load),
R"#(Changes the curve. The Offset is reset to 0.)#" , py::arg("S")
)
.def("Load",
(void (Adaptor2d_OffsetCurve::*)( const Standard_Real ) ) static_cast<void (Adaptor2d_OffsetCurve::*)( const Standard_Real ) >(&Adaptor2d_OffsetCurve::Load),
R"#(Changes the Offset on the current Curve.)#" , py::arg("Offset")
)
.def("Load",
(void (Adaptor2d_OffsetCurve::*)( const Standard_Real , const Standard_Real , const Standard_Real ) ) static_cast<void (Adaptor2d_OffsetCurve::*)( const Standard_Real , const Standard_Real , const Standard_Real ) >(&Adaptor2d_OffsetCurve::Load),
R"#(Changes the Offset Curve on the current Curve.)#" , py::arg("Offset"), py::arg("WFirst"), py::arg("WLast")
)
.def("Offset",
(Standard_Real (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Real (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Offset),
R"#(None)#"
)
.def("FirstParameter",
(Standard_Real (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Real (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::FirstParameter),
R"#(None)#"
)
.def("LastParameter",
(Standard_Real (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Real (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::LastParameter),
R"#(None)#"
)
.def("Continuity",
(GeomAbs_Shape (Adaptor2d_OffsetCurve::*)() const) static_cast<GeomAbs_Shape (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Continuity),
R"#(None)#"
)
.def("NbIntervals",
(Standard_Integer (Adaptor2d_OffsetCurve::*)( const GeomAbs_Shape ) const) static_cast<Standard_Integer (Adaptor2d_OffsetCurve::*)( const GeomAbs_Shape ) const>(&Adaptor2d_OffsetCurve::NbIntervals),
R"#(If necessary, breaks the curve in intervals of continuity <S>. And returns the number of intervals.)#" , py::arg("S")
)
.def("Intervals",
(void (Adaptor2d_OffsetCurve::*)( NCollection_Array1<Standard_Real> & , const GeomAbs_Shape ) const) static_cast<void (Adaptor2d_OffsetCurve::*)( NCollection_Array1<Standard_Real> & , const GeomAbs_Shape ) const>(&Adaptor2d_OffsetCurve::Intervals),
R"#(Stores in <T> the parameters bounding the intervals of continuity <S>.)#" , py::arg("T"), py::arg("S")
)
.def("Trim",
(opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_OffsetCurve::*)( const Standard_Real , const Standard_Real , const Standard_Real ) const) static_cast<opencascade::handle<Adaptor2d_Curve2d> (Adaptor2d_OffsetCurve::*)( const Standard_Real , const Standard_Real , const Standard_Real ) const>(&Adaptor2d_OffsetCurve::Trim),
R"#(Returns a curve equivalent of <me> between parameters <First> and <Last>. <Tol> is used to test for 3d points confusion. If <First> >= <Last>)#" , py::arg("First"), py::arg("Last"), py::arg("Tol")
)
.def("IsClosed",
(Standard_Boolean (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Boolean (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::IsClosed),
R"#(None)#"
)
.def("IsPeriodic",
(Standard_Boolean (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Boolean (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::IsPeriodic),
R"#(None)#"
)
.def("Period",
(Standard_Real (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Real (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Period),
R"#(None)#"
)
.def("Value",
(gp_Pnt2d (Adaptor2d_OffsetCurve::*)( const Standard_Real ) const) static_cast<gp_Pnt2d (Adaptor2d_OffsetCurve::*)( const Standard_Real ) const>(&Adaptor2d_OffsetCurve::Value),
R"#(Computes the point of parameter U on the curve.)#" , py::arg("U")
)
.def("D0",
(void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & ) const) static_cast<void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & ) const>(&Adaptor2d_OffsetCurve::D0),
R"#(Computes the point of parameter U on the curve.)#" , py::arg("U"), py::arg("P")
)
.def("D1",
(void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & ) const>(&Adaptor2d_OffsetCurve::D1),
R"#(Computes the point of parameter U on the curve with its first derivative. Raised if the continuity of the current interval is not C1.)#" , py::arg("U"), py::arg("P"), py::arg("V")
)
.def("D2",
(void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & ) const>(&Adaptor2d_OffsetCurve::D2),
R"#(Returns the point P of parameter U, the first and second derivatives V1 and V2. Raised if the continuity of the current interval is not C2.)#" , py::arg("U"), py::arg("P"), py::arg("V1"), py::arg("V2")
)
.def("D3",
(void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & , gp_Vec2d & ) const) static_cast<void (Adaptor2d_OffsetCurve::*)( const Standard_Real , gp_Pnt2d & , gp_Vec2d & , gp_Vec2d & , gp_Vec2d & ) const>(&Adaptor2d_OffsetCurve::D3),
R"#(Returns the point P of parameter U, the first, the second and the third derivative. Raised if the continuity of the current interval is not C3.)#" , py::arg("U"), py::arg("P"), py::arg("V1"), py::arg("V2"), py::arg("V3")
)
.def("DN",
(gp_Vec2d (Adaptor2d_OffsetCurve::*)( const Standard_Real , const Standard_Integer ) const) static_cast<gp_Vec2d (Adaptor2d_OffsetCurve::*)( const Standard_Real , const Standard_Integer ) const>(&Adaptor2d_OffsetCurve::DN),
R"#(The returned vector gives the value of the derivative for the order of derivation N. Raised if the continuity of the current interval is not CN. Raised if N < 1.)#" , py::arg("U"), py::arg("N")
)
.def("Resolution",
(Standard_Real (Adaptor2d_OffsetCurve::*)( const Standard_Real ) const) static_cast<Standard_Real (Adaptor2d_OffsetCurve::*)( const Standard_Real ) const>(&Adaptor2d_OffsetCurve::Resolution),
R"#(Returns the parametric resolution corresponding to the real space resolution <R3d>.)#" , py::arg("R3d")
)
.def("GetType",
(GeomAbs_CurveType (Adaptor2d_OffsetCurve::*)() const) static_cast<GeomAbs_CurveType (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::GetType),
R"#(Returns the type of the curve in the current interval : Line, Circle, Ellipse, Hyperbola, Parabola, BezierCurve, BSplineCurve, OtherCurve.)#"
)
.def("Line",
(gp_Lin2d (Adaptor2d_OffsetCurve::*)() const) static_cast<gp_Lin2d (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Line),
R"#(None)#"
)
.def("Circle",
(gp_Circ2d (Adaptor2d_OffsetCurve::*)() const) static_cast<gp_Circ2d (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Circle),
R"#(None)#"
)
.def("Ellipse",
(gp_Elips2d (Adaptor2d_OffsetCurve::*)() const) static_cast<gp_Elips2d (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Ellipse),
R"#(None)#"
)
.def("Hyperbola",
(gp_Hypr2d (Adaptor2d_OffsetCurve::*)() const) static_cast<gp_Hypr2d (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Hyperbola),
R"#(None)#"
)
.def("Parabola",
(gp_Parab2d (Adaptor2d_OffsetCurve::*)() const) static_cast<gp_Parab2d (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Parabola),
R"#(None)#"
)
.def("Degree",
(Standard_Integer (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Integer (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Degree),
R"#(None)#"
)
.def("IsRational",
(Standard_Boolean (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Boolean (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::IsRational),
R"#(None)#"
)
.def("NbPoles",
(Standard_Integer (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Integer (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::NbPoles),
R"#(None)#"
)
.def("NbKnots",
(Standard_Integer (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Integer (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::NbKnots),
R"#(None)#"
)
.def("Bezier",
(opencascade::handle<Geom2d_BezierCurve> (Adaptor2d_OffsetCurve::*)() const) static_cast<opencascade::handle<Geom2d_BezierCurve> (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Bezier),
R"#(None)#"
)
.def("BSpline",
(opencascade::handle<Geom2d_BSplineCurve> (Adaptor2d_OffsetCurve::*)() const) static_cast<opencascade::handle<Geom2d_BSplineCurve> (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::BSpline),
R"#(None)#"
)
.def("NbSamples",
(Standard_Integer (Adaptor2d_OffsetCurve::*)() const) static_cast<Standard_Integer (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::NbSamples),
R"#(None)#"
)
// methods using call by reference i.s.o. return
// static methods
.def_static("get_type_name_s",
(const char * (*)() ) static_cast<const char * (*)() >(&Adaptor2d_OffsetCurve::get_type_name),
R"#(None)#"
)
.def_static("get_type_descriptor_s",
(const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&Adaptor2d_OffsetCurve::get_type_descriptor),
R"#(None)#"
)
// static methods using call by reference i.s.o. return
// operators
// additional methods and static methods
// properties
// methods returning by ref wrapped as properties
.def("DynamicType",
(const opencascade::handle<Standard_Type> & (Adaptor2d_OffsetCurve::*)() const) static_cast<const opencascade::handle<Standard_Type> & (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::DynamicType),
R"#(None)#"
)
.def("Curve",
(const opencascade::handle<Adaptor2d_Curve2d> & (Adaptor2d_OffsetCurve::*)() const) static_cast<const opencascade::handle<Adaptor2d_Curve2d> & (Adaptor2d_OffsetCurve::*)() const>(&Adaptor2d_OffsetCurve::Curve),
R"#(None)#"
)
;
// functions
// ./opencascade/Adaptor2d_Curve2d.hxx
// ./opencascade/Adaptor2d_Line2d.hxx
// ./opencascade/Adaptor2d_OffsetCurve.hxx
// Additional functions
// operators
// register typdefs
// exceptions
// user-defined post-inclusion per module in the body
};
// user-defined post-inclusion per module
// user-defined post
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