// 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 <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDF_Label.hxx>
#include <gp_Lin.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDataStd_Real.hxx>
#include <Standard_GUID.hxx>
#include <TNaming_NamedShape.hxx>
#include <TDF_RelocationTable.hxx>
#include <TDF_DataSet.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDF_Label.hxx>
#include <TNaming_NamedShape.hxx>
#include <gp_Pnt.hxx>
#include <gp_Ax1.hxx>
#include <gp_Lin.hxx>
#include <gp_Circ.hxx>
#include <gp_Elips.hxx>
#include <gp_Pln.hxx>
#include <gp_Cylinder.hxx>
#include <Standard_GUID.hxx>
#include <TDF_RelocationTable.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Standard_GUID.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TNaming_NamedShape.hxx>
#include <TDataStd_Real.hxx>
#include <TDataStd_Integer.hxx>
#include <Standard_GUID.hxx>
#include <TDF_Label.hxx>
#include <TDF_RelocationTable.hxx>
#include <TDF_DataSet.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDF_Label.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDF_Label.hxx>
#include <gp_Pln.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDF_Label.hxx>
#include <gp_Pnt.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDF_Label.hxx>
#include <Standard_GUID.hxx>
#include <TDF_RelocationTable.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TDF_Label.hxx>
#include <TDF_RelocationTable.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <TopoDS_Shape.hxx>
#include <TDF_DataSet.hxx>
#include <Adaptor2d_Curve2d.hxx>
#include <Adaptor3d_Curve.hxx>
#include <Adaptor3d_Surface.hxx>
#include <Standard_GUID.hxx>
#include <TDF_Label.hxx>
#include <TDF_RelocationTable.hxx>

// module includes
#include <TDataXtd.hxx>
#include <TDataXtd_Array1OfTrsf.hxx>
#include <TDataXtd_Axis.hxx>
#include <TDataXtd_Constraint.hxx>
#include <TDataXtd_ConstraintEnum.hxx>
#include <TDataXtd_Geometry.hxx>
#include <TDataXtd_GeometryEnum.hxx>
#include <TDataXtd_HArray1OfTrsf.hxx>
#include <TDataXtd_Pattern.hxx>
#include <TDataXtd_PatternStd.hxx>
#include <TDataXtd_Placement.hxx>
#include <TDataXtd_Plane.hxx>
#include <TDataXtd_Point.hxx>
#include <TDataXtd_Position.hxx>
#include <TDataXtd_Presentation.hxx>
#include <TDataXtd_Shape.hxx>
#include <TDataXtd_Triangulation.hxx>

// template related includes

// ./opencascade/TDataXtd_Array1OfTrsf.hxx
#include "NCollection_tmpl.hxx"


// user-defined pre
#include "OCP_specific.inc"

// user-defined inclusion per module

// Module definiiton
void register_TDataXtd(py::module &main_module) {


py::module m = static_cast<py::module>(main_module.attr("TDataXtd"));
py::object klass;

//Python trampoline classes
    class Py_TDataXtd_Pattern : public TDataXtd_Pattern{
    public:
        using TDataXtd_Pattern::TDataXtd_Pattern;


        // public pure virtual
        const Standard_GUID & PatternID() const  override { PYBIND11_OVERLOAD_PURE(const Standard_GUID &,TDataXtd_Pattern,PatternID,) };
        Standard_Integer NbTrsfs() const  override { PYBIND11_OVERLOAD_PURE(Standard_Integer,TDataXtd_Pattern,NbTrsfs,) };
        void ComputeTrsfs(NCollection_Array1<gp_Trsf> & Trsfs) const  override { PYBIND11_OVERLOAD_PURE(void,TDataXtd_Pattern,ComputeTrsfs,Trsfs) };

        void Restore(const opencascade::handle<TDF_Attribute> & anAttribute) override { PYBIND11_OVERLOAD_PURE(void,TDF_Attribute,Restore,anAttribute) };
        opencascade::handle<TDF_Attribute> NewEmpty() const  override { PYBIND11_OVERLOAD_PURE(opencascade::handle<TDF_Attribute>,TDF_Attribute,NewEmpty,) };
        void Paste(const opencascade::handle<TDF_Attribute> & intoAttribute,const opencascade::handle<TDF_RelocationTable> & aRelocationTable) const  override { PYBIND11_OVERLOAD_PURE(void,TDF_Attribute,Paste,intoAttribute,aRelocationTable) };

        // protected pure virtual


        // private pure virtual

    };

// classes

    // Class TDataXtd from ./opencascade/TDataXtd.hxx
    klass = m.attr("TDataXtd");

    // default constructor
    register_default_constructor<TDataXtd , shared_ptr<TDataXtd>>(m,"TDataXtd");

    // nested enums

    static_cast<py::class_<TDataXtd , shared_ptr<TDataXtd>  >>(klass)
    // constructors
    // custom constructors
    // methods
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("IDList_s",
                    (void (*)( NCollection_List<Standard_GUID> &  ) ) static_cast<void (*)( NCollection_List<Standard_GUID> &  ) >(&TDataXtd::IDList),
                    R"#(Appends to <anIDList> the list of the attributes IDs of this package. CAUTION: <anIDList> is NOT cleared before use. Print of TDataExt enumeration =============================)#"  , py::arg("anIDList")
          )
        .def_static("Print_s",
                    (Standard_OStream & (*)( const TDataXtd_GeometryEnum ,  std::ostream &  ) ) static_cast<Standard_OStream & (*)( const TDataXtd_GeometryEnum ,  std::ostream &  ) >(&TDataXtd::Print),
                    R"#(Prints the name of the geometry dimension <GEO> as a String on the Stream <S> and returns <S>.)#"  , py::arg("GEO"),  py::arg("S")
          )
        .def_static("Print_s",
                    (Standard_OStream & (*)( const TDataXtd_ConstraintEnum ,  std::ostream &  ) ) static_cast<Standard_OStream & (*)( const TDataXtd_ConstraintEnum ,  std::ostream &  ) >(&TDataXtd::Print),
                    R"#(Prints the name of the constraint <CTR> as a String on the Stream <S> and returns <S>.)#"  , py::arg("CTR"),  py::arg("S")
          )
    // static methods using call by reference i.s.o. return
    // operators
    // additional methods and static methods
    // properties
    // methods returning by ref wrapped as properties
;

    // Class TDataXtd_Axis from ./opencascade/TDataXtd_Axis.hxx
    klass = m.attr("TDataXtd_Axis");


    // nested enums

    static_cast<py::class_<TDataXtd_Axis ,opencascade::handle<TDataXtd_Axis>  , TDataStd_GenericEmpty >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Dump",
             (Standard_OStream & (TDataXtd_Axis::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Axis::*)( std::ostream &  ) const>(&TDataXtd_Axis::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Axis::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Axis::*)() const>(&TDataXtd_Axis::NewEmpty),
             R"#(None)#" 
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Axis::GetID),
                    R"#(class methods ============= Returns the GUID for an axis.)#" 
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Axis> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Axis> (*)( const TDF_Label &  ) >(&TDataXtd_Axis::Set),
                    R"#(Finds or creates an axis attribute defined by the label. In the case of a creation of an axis, a compatible named shape should already be associated with label. Exceptions Standard_NullObject if no compatible named shape is associated with the label.)#"  , py::arg("label")
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Axis> (*)( const TDF_Label & ,  const gp_Lin &  ) ) static_cast<opencascade::handle<TDataXtd_Axis> (*)( const TDF_Label & ,  const gp_Lin &  ) >(&TDataXtd_Axis::Set),
                    R"#(Find, or create, an Axis attribute and set <P> as generated in the associated NamedShape. Axis methods ============)#"  , py::arg("label"),  py::arg("L")
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Axis::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Axis::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("ID",
             (const Standard_GUID & (TDataXtd_Axis::*)() const) static_cast<const Standard_GUID & (TDataXtd_Axis::*)() const>(&TDataXtd_Axis::ID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Axis::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Axis::*)() const>(&TDataXtd_Axis::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Constraint from ./opencascade/TDataXtd_Constraint.hxx
    klass = m.attr("TDataXtd_Constraint");


    // nested enums

    static_cast<py::class_<TDataXtd_Constraint ,opencascade::handle<TDataXtd_Constraint>  , TDF_Attribute >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Set",
             (void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_Constraint::Set),
             R"#(Finds or creates the constraint attribute defined by the topological attribute G1 and the constraint type type.)#"  , py::arg("type"),  py::arg("G1")
          )
        .def("Set",
             (void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_Constraint::Set),
             R"#(Finds or creates the constraint attribute defined by the topological attributes G1 and G2, and by the constraint type type.)#"  , py::arg("type"),  py::arg("G1"),  py::arg("G2")
          )
        .def("Set",
             (void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_Constraint::Set),
             R"#(Finds or creates the constraint attribute defined by the topological attributes G1, G2 and G3, and by the constraint type type.)#"  , py::arg("type"),  py::arg("G1"),  py::arg("G2"),  py::arg("G3")
          )
        .def("Set",
             (void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> & ,  const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_Constraint::Set),
             R"#(Finds or creates the constraint attribute defined by the topological attributes G1, G2, G3 and G4, and by the constraint type type. methods to read constraint fields =================================)#"  , py::arg("type"),  py::arg("G1"),  py::arg("G2"),  py::arg("G3"),  py::arg("G4")
          )
        .def("Verified",
             (Standard_Boolean (TDataXtd_Constraint::*)() const) static_cast<Standard_Boolean (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::Verified),
             R"#(Returns true if this constraint attribute is valid. By default, true is returned. When the value of a dimension is changed or when a geometry is moved, false is returned until the solver sets it back to true.)#" 
          )
        .def("GetType",
             (TDataXtd_ConstraintEnum (TDataXtd_Constraint::*)() const) static_cast<TDataXtd_ConstraintEnum (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::GetType),
             R"#(Returns the type of constraint. This will be an element of the TDataXtd_ConstraintEnum enumeration.)#" 
          )
        .def("IsPlanar",
             (Standard_Boolean (TDataXtd_Constraint::*)() const) static_cast<Standard_Boolean (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::IsPlanar),
             R"#(Returns true if this constraint attribute is two-dimensional.)#" 
          )
        .def("IsDimension",
             (Standard_Boolean (TDataXtd_Constraint::*)() const) static_cast<Standard_Boolean (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::IsDimension),
             R"#(Returns true if this constraint attribute is a dimension, and therefore has a value.)#" 
          )
        .def("NbGeometries",
             (Standard_Integer (TDataXtd_Constraint::*)() const) static_cast<Standard_Integer (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::NbGeometries),
             R"#(Returns the number of geometry attributes in this constraint attribute. This number will be between 1 and 4.)#" 
          )
        .def("GetGeometry",
             (opencascade::handle<TNaming_NamedShape> (TDataXtd_Constraint::*)( const Standard_Integer  ) const) static_cast<opencascade::handle<TNaming_NamedShape> (TDataXtd_Constraint::*)( const Standard_Integer  ) const>(&TDataXtd_Constraint::GetGeometry),
             R"#(Returns the integer index Index used to access the array of the constraint or stored geometries of a dimension Index has a value between 1 and 4. methods to write constraint fields (use builder) ==================================)#"  , py::arg("Index")
          )
        .def("ClearGeometries",
             (void (TDataXtd_Constraint::*)() ) static_cast<void (TDataXtd_Constraint::*)() >(&TDataXtd_Constraint::ClearGeometries),
             R"#(Removes the geometries involved in the constraint or dimension from the array of topological attributes where they are stored.)#" 
          )
        .def("SetType",
             (void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum  ) ) static_cast<void (TDataXtd_Constraint::*)( const TDataXtd_ConstraintEnum  ) >(&TDataXtd_Constraint::SetType),
             R"#(Finds or creates the type of constraint CTR.)#"  , py::arg("CTR")
          )
        .def("SetPlane",
             (void (TDataXtd_Constraint::*)( const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_Constraint::SetPlane),
             R"#(Finds or creates the plane of the 2D constraint attribute, defined by the planar topological attribute plane.)#"  , py::arg("plane")
          )
        .def("SetValue",
             (void (TDataXtd_Constraint::*)( const opencascade::handle<TDataStd_Real> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const opencascade::handle<TDataStd_Real> &  ) >(&TDataXtd_Constraint::SetValue),
             R"#(Finds or creates the real number value V of the dimension constraint attribute.)#"  , py::arg("V")
          )
        .def("SetGeometry",
             (void (TDataXtd_Constraint::*)( const Standard_Integer ,  const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const Standard_Integer ,  const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_Constraint::SetGeometry),
             R"#(Finds or creates the underlying geometry of the constraint defined by the topological attribute G and the integer index Index.)#"  , py::arg("Index"),  py::arg("G")
          )
        .def("Verified",
             (void (TDataXtd_Constraint::*)( const Standard_Boolean  ) ) static_cast<void (TDataXtd_Constraint::*)( const Standard_Boolean  ) >(&TDataXtd_Constraint::Verified),
             R"#(Returns true if this constraint attribute defined by status is valid. By default, true is returned. When the value of a dimension is changed or when a geometry is moved, false is returned until the solver sets it back to true. If status is false, Verified is set to false.)#"  , py::arg("status")
          )
        .def("Inverted",
             (void (TDataXtd_Constraint::*)( const Standard_Boolean  ) ) static_cast<void (TDataXtd_Constraint::*)( const Standard_Boolean  ) >(&TDataXtd_Constraint::Inverted),
             R"#(None)#"  , py::arg("status")
          )
        .def("Inverted",
             (Standard_Boolean (TDataXtd_Constraint::*)() const) static_cast<Standard_Boolean (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::Inverted),
             R"#(None)#" 
          )
        .def("Reversed",
             (void (TDataXtd_Constraint::*)( const Standard_Boolean  ) ) static_cast<void (TDataXtd_Constraint::*)( const Standard_Boolean  ) >(&TDataXtd_Constraint::Reversed),
             R"#(None)#"  , py::arg("status")
          )
        .def("Reversed",
             (Standard_Boolean (TDataXtd_Constraint::*)() const) static_cast<Standard_Boolean (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::Reversed),
             R"#(None)#" 
          )
        .def("Restore",
             (void (TDataXtd_Constraint::*)( const opencascade::handle<TDF_Attribute> &  ) ) static_cast<void (TDataXtd_Constraint::*)( const opencascade::handle<TDF_Attribute> &  ) >(&TDataXtd_Constraint::Restore),
             R"#(None)#"  , py::arg("With")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Constraint::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::NewEmpty),
             R"#(None)#" 
          )
        .def("Paste",
             (void (TDataXtd_Constraint::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const) static_cast<void (TDataXtd_Constraint::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const>(&TDataXtd_Constraint::Paste),
             R"#(None)#"  , py::arg("Into"),  py::arg("RT")
          )
        .def("Dump",
             (Standard_OStream & (TDataXtd_Constraint::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Constraint::*)( std::ostream &  ) const>(&TDataXtd_Constraint::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
        .def("References",
             (void (TDataXtd_Constraint::*)( const opencascade::handle<TDF_DataSet> &  ) const) static_cast<void (TDataXtd_Constraint::*)( const opencascade::handle<TDF_DataSet> &  ) const>(&TDataXtd_Constraint::References),
             R"#(None)#"  , py::arg("DS")
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Constraint::GetID),
                    R"#(Returns the GUID for constraints.)#" 
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Constraint> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Constraint> (*)( const TDF_Label &  ) >(&TDataXtd_Constraint::Set),
                    R"#(Finds or creates the 2D constraint attribute defined by the planar topological attribute plane and the label label. Constraint methods ==================)#"  , py::arg("label")
          )
        .def_static("CollectChildConstraints_s",
                    (void (*)( const TDF_Label & ,  NCollection_List<TDF_Label> &  ) ) static_cast<void (*)( const TDF_Label & ,  NCollection_List<TDF_Label> &  ) >(&TDataXtd_Constraint::CollectChildConstraints),
                    R"#(collects constraints on Childs for label <aLabel>)#"  , py::arg("aLabel"),  py::arg("TheList")
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Constraint::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Constraint::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("GetPlane",
             (const opencascade::handle<TNaming_NamedShape> & (TDataXtd_Constraint::*)() const) static_cast<const opencascade::handle<TNaming_NamedShape> & (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::GetPlane),
             R"#(Returns the topological attribute of the plane used for planar - i.e., 2D - constraints. This plane is attached to another label. If the constraint is not planar, in other words, 3D, this function will return a null handle.)#"
             
         )
       .def("GetValue",
             (const opencascade::handle<TDataStd_Real> & (TDataXtd_Constraint::*)() const) static_cast<const opencascade::handle<TDataStd_Real> & (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::GetValue),
             R"#(Returns the value of a dimension. This value is a reference to a TDataStd_Real attribute. If the attribute is not a dimension, this value will be 0. Use IsDimension to test this condition.)#"
             
         )
       .def("ID",
             (const Standard_GUID & (TDataXtd_Constraint::*)() const) static_cast<const Standard_GUID & (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::ID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Constraint::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Constraint::*)() const>(&TDataXtd_Constraint::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Geometry from ./opencascade/TDataXtd_Geometry.hxx
    klass = m.attr("TDataXtd_Geometry");


    // nested enums

    static_cast<py::class_<TDataXtd_Geometry ,opencascade::handle<TDataXtd_Geometry>  , TDF_Attribute >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("SetType",
             (void (TDataXtd_Geometry::*)( const TDataXtd_GeometryEnum  ) ) static_cast<void (TDataXtd_Geometry::*)( const TDataXtd_GeometryEnum  ) >(&TDataXtd_Geometry::SetType),
             R"#(Returns the type of geometric construction T of this attribute. T will be a value of the enumeration TDataXtd_GeometryEnum.)#"  , py::arg("T")
          )
        .def("GetType",
             (TDataXtd_GeometryEnum (TDataXtd_Geometry::*)() const) static_cast<TDataXtd_GeometryEnum (TDataXtd_Geometry::*)() const>(&TDataXtd_Geometry::GetType),
             R"#(Returns the type of geometric construction.)#" 
          )
        .def("Restore",
             (void (TDataXtd_Geometry::*)( const opencascade::handle<TDF_Attribute> &  ) ) static_cast<void (TDataXtd_Geometry::*)( const opencascade::handle<TDF_Attribute> &  ) >(&TDataXtd_Geometry::Restore),
             R"#(None)#"  , py::arg("with")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Geometry::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Geometry::*)() const>(&TDataXtd_Geometry::NewEmpty),
             R"#(None)#" 
          )
        .def("Paste",
             (void (TDataXtd_Geometry::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const) static_cast<void (TDataXtd_Geometry::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const>(&TDataXtd_Geometry::Paste),
             R"#(None)#"  , py::arg("into"),  py::arg("RT")
          )
        .def("Dump",
             (Standard_OStream & (TDataXtd_Geometry::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Geometry::*)( std::ostream &  ) const>(&TDataXtd_Geometry::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Geometry> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Geometry> (*)( const TDF_Label &  ) >(&TDataXtd_Geometry::Set),
                    R"#(API class methods ================= Finds, or creates, a Geometry attribute defined by the label label. The default type of geometry is the value ANY_GEOM of the enumeration TDataXtd_GeometryEnum. To specify another value of this enumeration, use the function SetType.)#"  , py::arg("label")
          )
        .def_static("Type_s",
                    (TDataXtd_GeometryEnum (*)( const TDF_Label &  ) ) static_cast<TDataXtd_GeometryEnum (*)( const TDF_Label &  ) >(&TDataXtd_Geometry::Type),
                    R"#(Returns the label L used to define the type of geometric construction for the geometry attribute.)#"  , py::arg("L")
          )
        .def_static("Type_s",
                    (TDataXtd_GeometryEnum (*)( const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<TDataXtd_GeometryEnum (*)( const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_Geometry::Type),
                    R"#(Returns the topological attribute S used to define the type of geometric construction for the geometry attribute.)#"  , py::arg("S")
          )
        .def_static("Point_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Pnt &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Pnt &  ) >(&TDataXtd_Geometry::Point),
                    R"#(Returns the point attribute defined by the label L and the point G.)#"  , py::arg("L"),  py::arg("G")
          )
        .def_static("Point_s",
                    (Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Pnt &  ) ) static_cast<Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Pnt &  ) >(&TDataXtd_Geometry::Point),
                    R"#(Returns the point attribute defined by the topological attribute S and the point G.)#"  , py::arg("S"),  py::arg("G")
          )
        .def_static("Axis_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Ax1 &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Ax1 &  ) >(&TDataXtd_Geometry::Axis),
                    R"#(Returns the axis attribute defined by the label L and the axis G.)#"  , py::arg("L"),  py::arg("G")
          )
        .def_static("Axis_s",
                    (Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Ax1 &  ) ) static_cast<Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Ax1 &  ) >(&TDataXtd_Geometry::Axis),
                    R"#(Returns the axis attribute defined by the topological attribute S and the axis G.)#"  , py::arg("S"),  py::arg("G")
          )
        .def_static("Line_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Lin &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Lin &  ) >(&TDataXtd_Geometry::Line),
                    R"#(Returns the line attribute defined by the label L and the line G.)#"  , py::arg("L"),  py::arg("G")
          )
        .def_static("Line_s",
                    (Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Lin &  ) ) static_cast<Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Lin &  ) >(&TDataXtd_Geometry::Line),
                    R"#(Returns the line attribute defined by the topological attribute S and the line G.)#"  , py::arg("S"),  py::arg("G")
          )
        .def_static("Circle_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Circ &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Circ &  ) >(&TDataXtd_Geometry::Circle),
                    R"#(Returns the circle attribute defined by the label L and the circle G.)#"  , py::arg("L"),  py::arg("G")
          )
        .def_static("Circle_s",
                    (Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Circ &  ) ) static_cast<Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Circ &  ) >(&TDataXtd_Geometry::Circle),
                    R"#(Returns the circle attribute defined by the topological attribute S and the circle G.)#"  , py::arg("S"),  py::arg("G")
          )
        .def_static("Ellipse_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Elips &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Elips &  ) >(&TDataXtd_Geometry::Ellipse),
                    R"#(Returns the ellipse attribute defined by the label L and the ellipse G.)#"  , py::arg("L"),  py::arg("G")
          )
        .def_static("Ellipse_s",
                    (Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Elips &  ) ) static_cast<Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Elips &  ) >(&TDataXtd_Geometry::Ellipse),
                    R"#(Returns the ellipse attribute defined by the topological attribute S and the ellipse G.)#"  , py::arg("S"),  py::arg("G")
          )
        .def_static("Plane_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Pln &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Pln &  ) >(&TDataXtd_Geometry::Plane),
                    R"#(Returns the plane attribute defined by the label L and the plane G.)#"  , py::arg("L"),  py::arg("G")
          )
        .def_static("Plane_s",
                    (Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Pln &  ) ) static_cast<Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Pln &  ) >(&TDataXtd_Geometry::Plane),
                    R"#(Returns the plane attribute defined by the topological attribute S and the plane G.)#"  , py::arg("S"),  py::arg("G")
          )
        .def_static("Cylinder_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Cylinder &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Cylinder &  ) >(&TDataXtd_Geometry::Cylinder),
                    R"#(Returns the cylinder attribute defined by the label L and the cylinder G.)#"  , py::arg("L"),  py::arg("G")
          )
        .def_static("Cylinder_s",
                    (Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Cylinder &  ) ) static_cast<Standard_Boolean (*)( const opencascade::handle<TNaming_NamedShape> & ,  gp_Cylinder &  ) >(&TDataXtd_Geometry::Cylinder),
                    R"#(Returns the cylinder attribute defined by the topological attribute S and the cylinder G.)#"  , py::arg("S"),  py::arg("G")
          )
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Geometry::GetID),
                    R"#(Returns the GUID for geometry attributes.)#" 
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Geometry::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Geometry::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("ID",
             (const Standard_GUID & (TDataXtd_Geometry::*)() const) static_cast<const Standard_GUID & (TDataXtd_Geometry::*)() const>(&TDataXtd_Geometry::ID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Geometry::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Geometry::*)() const>(&TDataXtd_Geometry::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_HArray1OfTrsf from ./opencascade/TDataXtd_HArray1OfTrsf.hxx
    klass = m.attr("TDataXtd_HArray1OfTrsf");


    // nested enums

    static_cast<py::class_<TDataXtd_HArray1OfTrsf ,opencascade::handle<TDataXtd_HArray1OfTrsf>  , TDataXtd_Array1OfTrsf , Standard_Transient >>(klass)
    // constructors
        .def(py::init<  >()  )
        .def(py::init< const Standard_Integer,const Standard_Integer >()  , py::arg("theLower"),  py::arg("theUpper") )
        .def(py::init< const Standard_Integer,const Standard_Integer, const gp_Trsf & >()  , py::arg("theLower"),  py::arg("theUpper"),  py::arg("theValue") )
        .def(py::init<  const gp_Trsf &,const Standard_Integer,const Standard_Integer,const bool >()  , py::arg("theBegin"),  py::arg("theLower"),  py::arg("theUpper"),  py::arg("arg") )
        .def(py::init<  const NCollection_Array1<gp_Trsf> & >()  , py::arg("theOther") )
    // custom constructors
    // methods
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_HArray1OfTrsf::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_HArray1OfTrsf::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("Array1",
             (const TDataXtd_Array1OfTrsf & (TDataXtd_HArray1OfTrsf::*)() const) static_cast<const TDataXtd_Array1OfTrsf & (TDataXtd_HArray1OfTrsf::*)() const>(&TDataXtd_HArray1OfTrsf::Array1),
             R"#(None)#"
             
         )
       .def("ChangeArray1",
             (TDataXtd_Array1OfTrsf & (TDataXtd_HArray1OfTrsf::*)() ) static_cast<TDataXtd_Array1OfTrsf & (TDataXtd_HArray1OfTrsf::*)() >(&TDataXtd_HArray1OfTrsf::ChangeArray1),
             R"#(None)#"
             
             , py::return_value_policy::reference_internal
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_HArray1OfTrsf::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_HArray1OfTrsf::*)() const>(&TDataXtd_HArray1OfTrsf::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Pattern from ./opencascade/TDataXtd_Pattern.hxx
    klass = m.attr("TDataXtd_Pattern");


    // nested enums

    static_cast<py::class_<TDataXtd_Pattern ,opencascade::handle<TDataXtd_Pattern> ,Py_TDataXtd_Pattern , TDF_Attribute >>(klass)
    // constructors
    // custom constructors
    // methods
        .def("PatternID",
             (const Standard_GUID & (TDataXtd_Pattern::*)() const) static_cast<const Standard_GUID & (TDataXtd_Pattern::*)() const>(&TDataXtd_Pattern::PatternID),
             R"#(Returns the ID of the attribute.)#" 
          )
        .def("NbTrsfs",
             (Standard_Integer (TDataXtd_Pattern::*)() const) static_cast<Standard_Integer (TDataXtd_Pattern::*)() const>(&TDataXtd_Pattern::NbTrsfs),
             R"#(Give the number of transformation)#" 
          )
        .def("ComputeTrsfs",
             (void (TDataXtd_Pattern::*)( NCollection_Array1<gp_Trsf> &  ) const) static_cast<void (TDataXtd_Pattern::*)( NCollection_Array1<gp_Trsf> &  ) const>(&TDataXtd_Pattern::ComputeTrsfs),
             R"#(Give the transformations)#"  , py::arg("Trsfs")
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Pattern::GetID),
                    R"#(None)#" 
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Pattern::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Pattern::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("ID",
             (const Standard_GUID & (TDataXtd_Pattern::*)() const) static_cast<const Standard_GUID & (TDataXtd_Pattern::*)() const>(&TDataXtd_Pattern::ID),
             R"#(Returns the ID of the attribute.)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Pattern::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Pattern::*)() const>(&TDataXtd_Pattern::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Placement from ./opencascade/TDataXtd_Placement.hxx
    klass = m.attr("TDataXtd_Placement");


    // nested enums

    static_cast<py::class_<TDataXtd_Placement ,opencascade::handle<TDataXtd_Placement>  , TDataStd_GenericEmpty >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Dump",
             (Standard_OStream & (TDataXtd_Placement::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Placement::*)( std::ostream &  ) const>(&TDataXtd_Placement::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Placement::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Placement::*)() const>(&TDataXtd_Placement::NewEmpty),
             R"#(None)#" 
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Placement::GetID),
                    R"#(class methods =============)#" 
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Placement> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Placement> (*)( const TDF_Label &  ) >(&TDataXtd_Placement::Set),
                    R"#(Find, or create, an Placement attribute. the Placement attribute is returned. Placement methods =================)#"  , py::arg("label")
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Placement::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Placement::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("ID",
             (const Standard_GUID & (TDataXtd_Placement::*)() const) static_cast<const Standard_GUID & (TDataXtd_Placement::*)() const>(&TDataXtd_Placement::ID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Placement::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Placement::*)() const>(&TDataXtd_Placement::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Plane from ./opencascade/TDataXtd_Plane.hxx
    klass = m.attr("TDataXtd_Plane");


    // nested enums

    static_cast<py::class_<TDataXtd_Plane ,opencascade::handle<TDataXtd_Plane>  , TDataStd_GenericEmpty >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Dump",
             (Standard_OStream & (TDataXtd_Plane::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Plane::*)( std::ostream &  ) const>(&TDataXtd_Plane::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Plane::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Plane::*)() const>(&TDataXtd_Plane::NewEmpty),
             R"#(None)#" 
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Plane::GetID),
                    R"#(class methods =============)#" 
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Plane> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Plane> (*)( const TDF_Label &  ) >(&TDataXtd_Plane::Set),
                    R"#(Finds or creates the plane attribute defined by the label label. Warning If you are creating the attribute with this syntax, a planar face should already be associated with label.)#"  , py::arg("label")
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Plane> (*)( const TDF_Label & ,  const gp_Pln &  ) ) static_cast<opencascade::handle<TDataXtd_Plane> (*)( const TDF_Label & ,  const gp_Pln &  ) >(&TDataXtd_Plane::Set),
                    R"#(Finds, or creates, a Plane attribute and sets <P> as generated the associated NamedShape. Plane methods =============)#"  , py::arg("label"),  py::arg("P")
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Plane::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Plane::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("ID",
             (const Standard_GUID & (TDataXtd_Plane::*)() const) static_cast<const Standard_GUID & (TDataXtd_Plane::*)() const>(&TDataXtd_Plane::ID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Plane::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Plane::*)() const>(&TDataXtd_Plane::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Point from ./opencascade/TDataXtd_Point.hxx
    klass = m.attr("TDataXtd_Point");


    // nested enums

    static_cast<py::class_<TDataXtd_Point ,opencascade::handle<TDataXtd_Point>  , TDataStd_GenericEmpty >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Dump",
             (Standard_OStream & (TDataXtd_Point::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Point::*)( std::ostream &  ) const>(&TDataXtd_Point::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Point::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Point::*)() const>(&TDataXtd_Point::NewEmpty),
             R"#(None)#" 
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Point::GetID),
                    R"#(class methods =============)#" 
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Point> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Point> (*)( const TDF_Label &  ) >(&TDataXtd_Point::Set),
                    R"#(Sets the label Label as a point attribute. If no object is found, a point attribute is created.)#"  , py::arg("label")
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Point> (*)( const TDF_Label & ,  const gp_Pnt &  ) ) static_cast<opencascade::handle<TDataXtd_Point> (*)( const TDF_Label & ,  const gp_Pnt &  ) >(&TDataXtd_Point::Set),
                    R"#(Sets the label Label as a point attribute containing the point P. If no object is found, a point attribute is created. Point methods =============)#"  , py::arg("label"),  py::arg("P")
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Point::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Point::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("ID",
             (const Standard_GUID & (TDataXtd_Point::*)() const) static_cast<const Standard_GUID & (TDataXtd_Point::*)() const>(&TDataXtd_Point::ID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Point::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Point::*)() const>(&TDataXtd_Point::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Position from ./opencascade/TDataXtd_Position.hxx
    klass = m.attr("TDataXtd_Position");


    // nested enums

    static_cast<py::class_<TDataXtd_Position ,opencascade::handle<TDataXtd_Position>  , TDF_Attribute >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Restore",
             (void (TDataXtd_Position::*)( const opencascade::handle<TDF_Attribute> &  ) ) static_cast<void (TDataXtd_Position::*)( const opencascade::handle<TDF_Attribute> &  ) >(&TDataXtd_Position::Restore),
             R"#(Restores the contents from <anAttribute> into this one. It is used when aborting a transaction.)#"  , py::arg("anAttribute")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Position::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Position::*)() const>(&TDataXtd_Position::NewEmpty),
             R"#(Returns an new empty attribute from the good end type. It is used by the copy algorithm.)#" 
          )
        .def("Paste",
             (void (TDataXtd_Position::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const) static_cast<void (TDataXtd_Position::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const>(&TDataXtd_Position::Paste),
             R"#(This method is different from the "Copy" one, because it is used when copying an attribute from a source structure into a target structure. This method pastes the current attribute to the label corresponding to the insertor. The pasted attribute may be a brand new one or a new version of the previous one.)#"  , py::arg("intoAttribute"),  py::arg("aRelocTationable")
          )
        .def("SetPosition",
             (void (TDataXtd_Position::*)( const gp_Pnt &  ) ) static_cast<void (TDataXtd_Position::*)( const gp_Pnt &  ) >(&TDataXtd_Position::SetPosition),
             R"#(None)#"  , py::arg("aPos")
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("Set_s",
                    (void (*)( const TDF_Label & ,  const gp_Pnt &  ) ) static_cast<void (*)( const TDF_Label & ,  const gp_Pnt &  ) >(&TDataXtd_Position::Set),
                    R"#(Create if not found the TDataXtd_Position attribute set its position to <aPos>)#"  , py::arg("aLabel"),  py::arg("aPos")
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Position> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Position> (*)( const TDF_Label &  ) >(&TDataXtd_Position::Set),
                    R"#(Find an existing, or create an empty, Position. the Position attribute is returned.)#"  , py::arg("aLabel")
          )
        .def_static("Get_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  gp_Pnt &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  gp_Pnt &  ) >(&TDataXtd_Position::Get),
                    R"#(Search label <aLabel) for the TDataXtd_Position attribute and get its position if found returns True)#"  , py::arg("aLabel"),  py::arg("aPos")
          )
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Position::GetID),
                    R"#(Returns the ID of the attribute.)#" 
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Position::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Position::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("ID",
             (const Standard_GUID & (TDataXtd_Position::*)() const) static_cast<const Standard_GUID & (TDataXtd_Position::*)() const>(&TDataXtd_Position::ID),
             R"#(Returns the ID of the attribute.)#"
             
         )
       .def("GetPosition",
             (const gp_Pnt & (TDataXtd_Position::*)() const) static_cast<const gp_Pnt & (TDataXtd_Position::*)() const>(&TDataXtd_Position::GetPosition),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Position::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Position::*)() const>(&TDataXtd_Position::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Presentation from ./opencascade/TDataXtd_Presentation.hxx
    klass = m.attr("TDataXtd_Presentation");


    // nested enums

    static_cast<py::class_<TDataXtd_Presentation ,opencascade::handle<TDataXtd_Presentation>  , TDF_Attribute >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Restore",
             (void (TDataXtd_Presentation::*)( const opencascade::handle<TDF_Attribute> &  ) ) static_cast<void (TDataXtd_Presentation::*)( const opencascade::handle<TDF_Attribute> &  ) >(&TDataXtd_Presentation::Restore),
             R"#(Restores the contents from <anAttribute> into this one. It is used when aborting a transaction.)#"  , py::arg("anAttribute")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Presentation::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::NewEmpty),
             R"#(Returns an new empty attribute from the good end type. It is used by the copy algorithm.)#" 
          )
        .def("Paste",
             (void (TDataXtd_Presentation::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const) static_cast<void (TDataXtd_Presentation::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const>(&TDataXtd_Presentation::Paste),
             R"#(This method is different from the "Copy" one, because it is used when copying an attribute from a source structure into a target structure. This method pastes the current attribute to the label corresponding to the insertor. The pasted attribute may be a brand new one or a new version of the previous one.)#"  , py::arg("intoAttribute"),  py::arg("aRelocTationable")
          )
        .def("BackupCopy",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Presentation::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::BackupCopy),
             R"#(None)#" 
          )
        .def("GetDriverGUID",
             (Standard_GUID (TDataXtd_Presentation::*)() const) static_cast<Standard_GUID (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::GetDriverGUID),
             R"#(Returns the GUID of the driver managing display of associated AIS object)#" 
          )
        .def("SetDriverGUID",
             (void (TDataXtd_Presentation::*)( const Standard_GUID &  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_GUID &  ) >(&TDataXtd_Presentation::SetDriverGUID),
             R"#(Sets the GUID of the driver managing display of associated AIS object)#"  , py::arg("theGUID")
          )
        .def("IsDisplayed",
             (Standard_Boolean (TDataXtd_Presentation::*)() const) static_cast<Standard_Boolean (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::IsDisplayed),
             R"#(None)#" 
          )
        .def("HasOwnMaterial",
             (Standard_Boolean (TDataXtd_Presentation::*)() const) static_cast<Standard_Boolean (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::HasOwnMaterial),
             R"#(None)#" 
          )
        .def("HasOwnTransparency",
             (Standard_Boolean (TDataXtd_Presentation::*)() const) static_cast<Standard_Boolean (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::HasOwnTransparency),
             R"#(None)#" 
          )
        .def("HasOwnColor",
             (Standard_Boolean (TDataXtd_Presentation::*)() const) static_cast<Standard_Boolean (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::HasOwnColor),
             R"#(None)#" 
          )
        .def("HasOwnWidth",
             (Standard_Boolean (TDataXtd_Presentation::*)() const) static_cast<Standard_Boolean (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::HasOwnWidth),
             R"#(None)#" 
          )
        .def("HasOwnMode",
             (Standard_Boolean (TDataXtd_Presentation::*)() const) static_cast<Standard_Boolean (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::HasOwnMode),
             R"#(None)#" 
          )
        .def("HasOwnSelectionMode",
             (Standard_Boolean (TDataXtd_Presentation::*)() const) static_cast<Standard_Boolean (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::HasOwnSelectionMode),
             R"#(None)#" 
          )
        .def("SetDisplayed",
             (void (TDataXtd_Presentation::*)( const Standard_Boolean  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_Boolean  ) >(&TDataXtd_Presentation::SetDisplayed),
             R"#(None)#"  , py::arg("theIsDisplayed")
          )
        .def("SetMaterialIndex",
             (void (TDataXtd_Presentation::*)( const Standard_Integer  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_Integer  ) >(&TDataXtd_Presentation::SetMaterialIndex),
             R"#(None)#"  , py::arg("theMaterialIndex")
          )
        .def("SetTransparency",
             (void (TDataXtd_Presentation::*)( const Standard_Real  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_Real  ) >(&TDataXtd_Presentation::SetTransparency),
             R"#(None)#"  , py::arg("theValue")
          )
        .def("SetColor",
             (void (TDataXtd_Presentation::*)( const Quantity_NameOfColor  ) ) static_cast<void (TDataXtd_Presentation::*)( const Quantity_NameOfColor  ) >(&TDataXtd_Presentation::SetColor),
             R"#(None)#"  , py::arg("theColor")
          )
        .def("SetWidth",
             (void (TDataXtd_Presentation::*)( const Standard_Real  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_Real  ) >(&TDataXtd_Presentation::SetWidth),
             R"#(None)#"  , py::arg("theWidth")
          )
        .def("SetMode",
             (void (TDataXtd_Presentation::*)( const Standard_Integer  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_Integer  ) >(&TDataXtd_Presentation::SetMode),
             R"#(None)#"  , py::arg("theMode")
          )
        .def("GetNbSelectionModes",
             (Standard_Integer (TDataXtd_Presentation::*)() const) static_cast<Standard_Integer (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::GetNbSelectionModes),
             R"#(Returns the number of selection modes of the attribute. It starts with 1 .. GetNbSelectionModes().)#" 
          )
        .def("SetSelectionMode",
             (void (TDataXtd_Presentation::*)( const Standard_Integer ,  const Standard_Boolean  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_Integer ,  const Standard_Boolean  ) >(&TDataXtd_Presentation::SetSelectionMode),
             R"#(Sets selection mode. If "theTransaction" flag is OFF, modification of the attribute doesn't influence the transaction mechanism (the attribute doesn't participate in undo/redo because of this modification). Certainly, if any other data of the attribute is modified (display mode, color, ...), the attribute will be included into undo/redo.)#"  , py::arg("theSelectionMode"),  py::arg("theTransaction")=static_cast<const Standard_Boolean>(Standard_True)
          )
        .def("AddSelectionMode",
             (void (TDataXtd_Presentation::*)( const Standard_Integer ,  const Standard_Boolean  ) ) static_cast<void (TDataXtd_Presentation::*)( const Standard_Integer ,  const Standard_Boolean  ) >(&TDataXtd_Presentation::AddSelectionMode),
             R"#(None)#"  , py::arg("theSelectionMode"),  py::arg("theTransaction")=static_cast<const Standard_Boolean>(Standard_True)
          )
        .def("MaterialIndex",
             (Standard_Integer (TDataXtd_Presentation::*)() const) static_cast<Standard_Integer (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::MaterialIndex),
             R"#(None)#" 
          )
        .def("Transparency",
             (Standard_Real (TDataXtd_Presentation::*)() const) static_cast<Standard_Real (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::Transparency),
             R"#(None)#" 
          )
        .def("Color",
             (Quantity_NameOfColor (TDataXtd_Presentation::*)() const) static_cast<Quantity_NameOfColor (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::Color),
             R"#(None)#" 
          )
        .def("Width",
             (Standard_Real (TDataXtd_Presentation::*)() const) static_cast<Standard_Real (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::Width),
             R"#(None)#" 
          )
        .def("Mode",
             (Standard_Integer (TDataXtd_Presentation::*)() const) static_cast<Standard_Integer (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::Mode),
             R"#(None)#" 
          )
        .def("SelectionMode",
             (Standard_Integer (TDataXtd_Presentation::*)( const int  ) const) static_cast<Standard_Integer (TDataXtd_Presentation::*)( const int  ) const>(&TDataXtd_Presentation::SelectionMode),
             R"#(None)#"  , py::arg("index")=static_cast<const int>(1)
          )
        .def("UnsetMaterial",
             (void (TDataXtd_Presentation::*)() ) static_cast<void (TDataXtd_Presentation::*)() >(&TDataXtd_Presentation::UnsetMaterial),
             R"#(None)#" 
          )
        .def("UnsetTransparency",
             (void (TDataXtd_Presentation::*)() ) static_cast<void (TDataXtd_Presentation::*)() >(&TDataXtd_Presentation::UnsetTransparency),
             R"#(None)#" 
          )
        .def("UnsetColor",
             (void (TDataXtd_Presentation::*)() ) static_cast<void (TDataXtd_Presentation::*)() >(&TDataXtd_Presentation::UnsetColor),
             R"#(None)#" 
          )
        .def("UnsetWidth",
             (void (TDataXtd_Presentation::*)() ) static_cast<void (TDataXtd_Presentation::*)() >(&TDataXtd_Presentation::UnsetWidth),
             R"#(None)#" 
          )
        .def("UnsetMode",
             (void (TDataXtd_Presentation::*)() ) static_cast<void (TDataXtd_Presentation::*)() >(&TDataXtd_Presentation::UnsetMode),
             R"#(None)#" 
          )
        .def("UnsetSelectionMode",
             (void (TDataXtd_Presentation::*)() ) static_cast<void (TDataXtd_Presentation::*)() >(&TDataXtd_Presentation::UnsetSelectionMode),
             R"#(None)#" 
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Presentation> (*)( const TDF_Label & ,  const Standard_GUID &  ) ) static_cast<opencascade::handle<TDataXtd_Presentation> (*)( const TDF_Label & ,  const Standard_GUID &  ) >(&TDataXtd_Presentation::Set),
                    R"#(Create if not found the TDataXtd_Presentation attribute and set its driver GUID)#"  , py::arg("theLabel"),  py::arg("theDriverId")
          )
        .def_static("Unset_s",
                    (void (*)( const TDF_Label &  ) ) static_cast<void (*)( const TDF_Label &  ) >(&TDataXtd_Presentation::Unset),
                    R"#(Remove attribute of this type from the label)#"  , py::arg("theLabel")
          )
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Presentation::GetID),
                    R"#(Returns the ID of the attribute.)#" 
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Presentation::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Presentation::get_type_descriptor),
                    R"#(None)#" 
          )
        .def_static("getColorNameFromOldEnum_s",
                    (Quantity_NameOfColor (*)( Standard_Integer  ) ) static_cast<Quantity_NameOfColor (*)( Standard_Integer  ) >(&TDataXtd_Presentation::getColorNameFromOldEnum),
                    R"#(Convert values of old Quantity_NameOfColor to new enumeration for reading old documents after #0030969 (Coding Rules - refactor Quantity_Color.cxx color table definition).)#"  , py::arg("theOld")
          )
        .def_static("getOldColorNameFromNewEnum_s",
                    (Standard_Integer (*)( Quantity_NameOfColor  ) ) static_cast<Standard_Integer (*)( Quantity_NameOfColor  ) >(&TDataXtd_Presentation::getOldColorNameFromNewEnum),
                    R"#(Convert Quantity_NameOfColor to old enumeration value for writing documents in compatible format.)#"  , py::arg("theNew")
          )
    // 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("ID",
             (const Standard_GUID & (TDataXtd_Presentation::*)() const) static_cast<const Standard_GUID & (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::ID),
             R"#(Returns the ID of the attribute.)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Presentation::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Presentation::*)() const>(&TDataXtd_Presentation::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Shape from ./opencascade/TDataXtd_Shape.hxx
    klass = m.attr("TDataXtd_Shape");


    // nested enums

    static_cast<py::class_<TDataXtd_Shape ,opencascade::handle<TDataXtd_Shape>  , TDataStd_GenericEmpty >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("References",
             (void (TDataXtd_Shape::*)( const opencascade::handle<TDF_DataSet> &  ) const) static_cast<void (TDataXtd_Shape::*)( const opencascade::handle<TDF_DataSet> &  ) const>(&TDataXtd_Shape::References),
             R"#(None)#"  , py::arg("DS")
          )
        .def("Dump",
             (Standard_OStream & (TDataXtd_Shape::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Shape::*)( std::ostream &  ) const>(&TDataXtd_Shape::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Shape::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Shape::*)() const>(&TDataXtd_Shape::NewEmpty),
             R"#(None)#" 
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("Find_s",
                    (Standard_Boolean (*)( const TDF_Label & ,  opencascade::handle<TDataXtd_Shape> &  ) ) static_cast<Standard_Boolean (*)( const TDF_Label & ,  opencascade::handle<TDataXtd_Shape> &  ) >(&TDataXtd_Shape::Find),
                    R"#(class methods ============= try to retrieve a Shape attribute at <current> label or in fathers label of <current>. Returns True if found and set <S>.)#"  , py::arg("current"),  py::arg("S")
          )
        .def_static("New_s",
                    (opencascade::handle<TDataXtd_Shape> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Shape> (*)( const TDF_Label &  ) >(&TDataXtd_Shape::New),
                    R"#(Find, or create, a Shape attribute. the Shape attribute is returned. Raises if <label> has attribute.)#"  , py::arg("label")
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Shape> (*)( const TDF_Label & ,  const TopoDS_Shape &  ) ) static_cast<opencascade::handle<TDataXtd_Shape> (*)( const TDF_Label & ,  const TopoDS_Shape &  ) >(&TDataXtd_Shape::Set),
                    R"#(Create or update associated NamedShape attribute. the Shape attribute is returned.)#"  , py::arg("label"),  py::arg("shape")
          )
        .def_static("Get_s",
                    (TopoDS_Shape (*)( const TDF_Label &  ) ) static_cast<TopoDS_Shape (*)( const TDF_Label &  ) >(&TDataXtd_Shape::Get),
                    R"#(the Shape from associated NamedShape attribute is returned.)#"  , py::arg("label")
          )
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Shape::GetID),
                    R"#(Shape methods ============)#" 
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Shape::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Shape::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("ID",
             (const Standard_GUID & (TDataXtd_Shape::*)() const) static_cast<const Standard_GUID & (TDataXtd_Shape::*)() const>(&TDataXtd_Shape::ID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Shape::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Shape::*)() const>(&TDataXtd_Shape::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_Triangulation from ./opencascade/TDataXtd_Triangulation.hxx
    klass = m.attr("TDataXtd_Triangulation");


    // nested enums

    static_cast<py::class_<TDataXtd_Triangulation ,opencascade::handle<TDataXtd_Triangulation>  , TDF_Attribute >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Set",
             (void (TDataXtd_Triangulation::*)( const opencascade::handle<Poly_Triangulation> &  ) ) static_cast<void (TDataXtd_Triangulation::*)( const opencascade::handle<Poly_Triangulation> &  ) >(&TDataXtd_Triangulation::Set),
             R"#(Sets the triangulation.)#"  , py::arg("theTriangulation")
          )
        .def("Deflection",
             (Standard_Real (TDataXtd_Triangulation::*)() const) static_cast<Standard_Real (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::Deflection),
             R"#(Returns the deflection of this triangulation.)#" 
          )
        .def("Deflection",
             (void (TDataXtd_Triangulation::*)( const Standard_Real  ) ) static_cast<void (TDataXtd_Triangulation::*)( const Standard_Real  ) >(&TDataXtd_Triangulation::Deflection),
             R"#(Sets the deflection of this triangulation to theDeflection. See more on deflection in Polygon2D)#"  , py::arg("theDeflection")
          )
        .def("RemoveUVNodes",
             (void (TDataXtd_Triangulation::*)() ) static_cast<void (TDataXtd_Triangulation::*)() >(&TDataXtd_Triangulation::RemoveUVNodes),
             R"#(Deallocates the UV nodes.)#" 
          )
        .def("NbNodes",
             (Standard_Integer (TDataXtd_Triangulation::*)() const) static_cast<Standard_Integer (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::NbNodes),
             R"#(Returns the number of nodes for this triangulation.)#" 
          )
        .def("NbTriangles",
             (Standard_Integer (TDataXtd_Triangulation::*)() const) static_cast<Standard_Integer (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::NbTriangles),
             R"#(Returns the number of triangles for this triangulation.)#" 
          )
        .def("HasUVNodes",
             (Standard_Boolean (TDataXtd_Triangulation::*)() const) static_cast<Standard_Boolean (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::HasUVNodes),
             R"#(Returns Standard_True if 2D nodes are associated with 3D nodes for this triangulation.)#" 
          )
        .def("Node",
             (gp_Pnt (TDataXtd_Triangulation::*)( const Standard_Integer  ) const) static_cast<gp_Pnt (TDataXtd_Triangulation::*)( const Standard_Integer  ) const>(&TDataXtd_Triangulation::Node),
             R"#(Returns node at the given index. Raises Standard_OutOfRange exception if theIndex is less than 1 or greater than NbNodes.)#"  , py::arg("theIndex")
          )
        .def("SetNode",
             (void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const gp_Pnt &  ) ) static_cast<void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const gp_Pnt &  ) >(&TDataXtd_Triangulation::SetNode),
             R"#(The method differs from Poly_Triangulation! Sets a node at the given index. Raises Standard_OutOfRange exception if theIndex is less than 1 or greater than NbNodes.)#"  , py::arg("theIndex"),  py::arg("theNode")
          )
        .def("UVNode",
             (gp_Pnt2d (TDataXtd_Triangulation::*)( const Standard_Integer  ) const) static_cast<gp_Pnt2d (TDataXtd_Triangulation::*)( const Standard_Integer  ) const>(&TDataXtd_Triangulation::UVNode),
             R"#(Returns UVNode at the given index. Raises Standard_OutOfRange exception if theIndex is less than 1 or greater than NbNodes.)#"  , py::arg("theIndex")
          )
        .def("SetUVNode",
             (void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const gp_Pnt2d &  ) ) static_cast<void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const gp_Pnt2d &  ) >(&TDataXtd_Triangulation::SetUVNode),
             R"#(The method differs from Poly_Triangulation! Sets a UVNode at the given index. Raises Standard_OutOfRange exception if theIndex is less than 1 or greater than NbNodes.)#"  , py::arg("theIndex"),  py::arg("theUVNode")
          )
        .def("Triangle",
             (Poly_Triangle (TDataXtd_Triangulation::*)( const Standard_Integer  ) const) static_cast<Poly_Triangle (TDataXtd_Triangulation::*)( const Standard_Integer  ) const>(&TDataXtd_Triangulation::Triangle),
             R"#(Returns triangle at the given index. Raises Standard_OutOfRange exception if theIndex is less than 1 or greater than NbTriangles.)#"  , py::arg("theIndex")
          )
        .def("SetTriangle",
             (void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const Poly_Triangle &  ) ) static_cast<void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const Poly_Triangle &  ) >(&TDataXtd_Triangulation::SetTriangle),
             R"#(The method differs from Poly_Triangulation! Sets a triangle at the given index. Raises Standard_OutOfRange exception if theIndex is less than 1 or greater than NbTriangles.)#"  , py::arg("theIndex"),  py::arg("theTriangle")
          )
        .def("SetNormal",
             (void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const gp_Dir &  ) ) static_cast<void (TDataXtd_Triangulation::*)( const Standard_Integer ,  const gp_Dir &  ) >(&TDataXtd_Triangulation::SetNormal),
             R"#(Changes normal at the given index. Raises Standard_OutOfRange exception.)#"  , py::arg("theIndex"),  py::arg("theNormal")
          )
        .def("HasNormals",
             (Standard_Boolean (TDataXtd_Triangulation::*)() const) static_cast<Standard_Boolean (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::HasNormals),
             R"#(Returns Standard_True if nodal normals are defined.)#" 
          )
        .def("Normal",
             (gp_Dir (TDataXtd_Triangulation::*)( const Standard_Integer  ) const) static_cast<gp_Dir (TDataXtd_Triangulation::*)( const Standard_Integer  ) const>(&TDataXtd_Triangulation::Normal),
             R"#(Returns normal at the given index. Raises Standard_OutOfRange exception.)#"  , py::arg("theIndex")
          )
        .def("Restore",
             (void (TDataXtd_Triangulation::*)( const opencascade::handle<TDF_Attribute> &  ) ) static_cast<void (TDataXtd_Triangulation::*)( const opencascade::handle<TDF_Attribute> &  ) >(&TDataXtd_Triangulation::Restore),
             R"#(None)#"  , py::arg("theAttribute")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_Triangulation::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::NewEmpty),
             R"#(None)#" 
          )
        .def("Paste",
             (void (TDataXtd_Triangulation::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const) static_cast<void (TDataXtd_Triangulation::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const>(&TDataXtd_Triangulation::Paste),
             R"#(None)#"  , py::arg("Into"),  py::arg("RT")
          )
        .def("Dump",
             (Standard_OStream & (TDataXtd_Triangulation::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_Triangulation::*)( std::ostream &  ) const>(&TDataXtd_Triangulation::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_Triangulation::GetID),
                    R"#(Returns the ID of the triangulation attribute.)#" 
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Triangulation> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_Triangulation> (*)( const TDF_Label &  ) >(&TDataXtd_Triangulation::Set),
                    R"#(Finds or creates a triangulation attribute.)#"  , py::arg("theLabel")
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_Triangulation> (*)( const TDF_Label & ,  const opencascade::handle<Poly_Triangulation> &  ) ) static_cast<opencascade::handle<TDataXtd_Triangulation> (*)( const TDF_Label & ,  const opencascade::handle<Poly_Triangulation> &  ) >(&TDataXtd_Triangulation::Set),
                    R"#(Finds or creates a triangulation attribute. Initializes the attribute by a Poly_Triangulation object.)#"  , py::arg("theLabel"),  py::arg("theTriangulation")
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_Triangulation::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_Triangulation::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("Get",
             (const opencascade::handle<Poly_Triangulation> & (TDataXtd_Triangulation::*)() const) static_cast<const opencascade::handle<Poly_Triangulation> & (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::Get),
             R"#(Returns the underlying triangulation.)#"
             
         )
       .def("ID",
             (const Standard_GUID & (TDataXtd_Triangulation::*)() const) static_cast<const Standard_GUID & (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::ID),
             R"#(Inherited attribute methods)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_Triangulation::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_Triangulation::*)() const>(&TDataXtd_Triangulation::DynamicType),
             R"#(None)#"
             
         )
;

    // Class TDataXtd_PatternStd from ./opencascade/TDataXtd_PatternStd.hxx
    klass = m.attr("TDataXtd_PatternStd");


    // nested enums

    static_cast<py::class_<TDataXtd_PatternStd ,opencascade::handle<TDataXtd_PatternStd>  , TDataXtd_Pattern >>(klass)
    // constructors
        .def(py::init<  >()  )
    // custom constructors
    // methods
        .def("Signature",
             (void (TDataXtd_PatternStd::*)( const Standard_Integer  ) ) static_cast<void (TDataXtd_PatternStd::*)( const Standard_Integer  ) >(&TDataXtd_PatternStd::Signature),
             R"#(None)#"  , py::arg("signature")
          )
        .def("Axis1",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_PatternStd::Axis1),
             R"#(None)#"  , py::arg("Axis1")
          )
        .def("Axis2",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_PatternStd::Axis2),
             R"#(None)#"  , py::arg("Axis2")
          )
        .def("Axis1Reversed",
             (void (TDataXtd_PatternStd::*)( const Standard_Boolean  ) ) static_cast<void (TDataXtd_PatternStd::*)( const Standard_Boolean  ) >(&TDataXtd_PatternStd::Axis1Reversed),
             R"#(None)#"  , py::arg("Axis1Reversed")
          )
        .def("Axis2Reversed",
             (void (TDataXtd_PatternStd::*)( const Standard_Boolean  ) ) static_cast<void (TDataXtd_PatternStd::*)( const Standard_Boolean  ) >(&TDataXtd_PatternStd::Axis2Reversed),
             R"#(None)#"  , py::arg("Axis2Reversed")
          )
        .def("Value1",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Real> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Real> &  ) >(&TDataXtd_PatternStd::Value1),
             R"#(None)#"  , py::arg("value")
          )
        .def("Value2",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Real> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Real> &  ) >(&TDataXtd_PatternStd::Value2),
             R"#(None)#"  , py::arg("value")
          )
        .def("NbInstances1",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Integer> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Integer> &  ) >(&TDataXtd_PatternStd::NbInstances1),
             R"#(None)#"  , py::arg("NbInstances1")
          )
        .def("NbInstances2",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Integer> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TDataStd_Integer> &  ) >(&TDataXtd_PatternStd::NbInstances2),
             R"#(None)#"  , py::arg("NbInstances2")
          )
        .def("Mirror",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TNaming_NamedShape> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TNaming_NamedShape> &  ) >(&TDataXtd_PatternStd::Mirror),
             R"#(None)#"  , py::arg("plane")
          )
        .def("Signature",
             (Standard_Integer (TDataXtd_PatternStd::*)() const) static_cast<Standard_Integer (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Signature),
             R"#(None)#" 
          )
        .def("Axis1",
             (opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis1),
             R"#(None)#" 
          )
        .def("Axis2",
             (opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis2),
             R"#(None)#" 
          )
        .def("Axis1Reversed",
             (Standard_Boolean (TDataXtd_PatternStd::*)() const) static_cast<Standard_Boolean (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis1Reversed),
             R"#(None)#" 
          )
        .def("Axis2Reversed",
             (Standard_Boolean (TDataXtd_PatternStd::*)() const) static_cast<Standard_Boolean (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis2Reversed),
             R"#(None)#" 
          )
        .def("Value1",
             (opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Value1),
             R"#(None)#" 
          )
        .def("Value2",
             (opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Value2),
             R"#(None)#" 
          )
        .def("NbInstances1",
             (opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::NbInstances1),
             R"#(None)#" 
          )
        .def("NbInstances2",
             (opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::NbInstances2),
             R"#(None)#" 
          )
        .def("Mirror",
             (opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Mirror),
             R"#(None)#" 
          )
        .def("NbTrsfs",
             (Standard_Integer (TDataXtd_PatternStd::*)() const) static_cast<Standard_Integer (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::NbTrsfs),
             R"#(None)#" 
          )
        .def("ComputeTrsfs",
             (void (TDataXtd_PatternStd::*)( NCollection_Array1<gp_Trsf> &  ) const) static_cast<void (TDataXtd_PatternStd::*)( NCollection_Array1<gp_Trsf> &  ) const>(&TDataXtd_PatternStd::ComputeTrsfs),
             R"#(None)#"  , py::arg("Trsfs")
          )
        .def("Restore",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TDF_Attribute> &  ) ) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TDF_Attribute> &  ) >(&TDataXtd_PatternStd::Restore),
             R"#(None)#"  , py::arg("With")
          )
        .def("NewEmpty",
             (opencascade::handle<TDF_Attribute> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDF_Attribute> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::NewEmpty),
             R"#(None)#" 
          )
        .def("Paste",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TDF_Attribute> & ,  const opencascade::handle<TDF_RelocationTable> &  ) const>(&TDataXtd_PatternStd::Paste),
             R"#(None)#"  , py::arg("Into"),  py::arg("RT")
          )
        .def("References",
             (void (TDataXtd_PatternStd::*)( const opencascade::handle<TDF_DataSet> &  ) const) static_cast<void (TDataXtd_PatternStd::*)( const opencascade::handle<TDF_DataSet> &  ) const>(&TDataXtd_PatternStd::References),
             R"#(None)#"  , py::arg("aDataSet")
          )
        .def("Dump",
             (Standard_OStream & (TDataXtd_PatternStd::*)( std::ostream &  ) const) static_cast<Standard_OStream & (TDataXtd_PatternStd::*)( std::ostream &  ) const>(&TDataXtd_PatternStd::Dump),
             R"#(None)#"  , py::arg("anOS")
          )
        .def("Signature",
             (Standard_Integer (TDataXtd_PatternStd::*)() const) static_cast<Standard_Integer (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Signature),
             R"#(None)#" 
          )
        .def("Axis1",
             (opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis1),
             R"#(None)#" 
          )
        .def("Axis2",
             (opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis2),
             R"#(None)#" 
          )
        .def("Axis1Reversed",
             (Standard_Boolean (TDataXtd_PatternStd::*)() const) static_cast<Standard_Boolean (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis1Reversed),
             R"#(None)#" 
          )
        .def("Axis2Reversed",
             (Standard_Boolean (TDataXtd_PatternStd::*)() const) static_cast<Standard_Boolean (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Axis2Reversed),
             R"#(None)#" 
          )
        .def("Value1",
             (opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Value1),
             R"#(None)#" 
          )
        .def("Value2",
             (opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Real> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Value2),
             R"#(None)#" 
          )
        .def("NbInstances1",
             (opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::NbInstances1),
             R"#(None)#" 
          )
        .def("NbInstances2",
             (opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TDataStd_Integer> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::NbInstances2),
             R"#(None)#" 
          )
        .def("Mirror",
             (opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const) static_cast<opencascade::handle<TNaming_NamedShape> (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::Mirror),
             R"#(None)#" 
          )
    // methods using call by reference i.s.o. return
    // static methods
        .def_static("GetPatternID_s",
                    (const Standard_GUID & (*)() ) static_cast<const Standard_GUID & (*)() >(&TDataXtd_PatternStd::GetPatternID),
                    R"#(None)#" 
          )
        .def_static("Set_s",
                    (opencascade::handle<TDataXtd_PatternStd> (*)( const TDF_Label &  ) ) static_cast<opencascade::handle<TDataXtd_PatternStd> (*)( const TDF_Label &  ) >(&TDataXtd_PatternStd::Set),
                    R"#(Find, or create, a PatternStd attribute)#"  , py::arg("label")
          )
        .def_static("get_type_name_s",
                    (const char * (*)() ) static_cast<const char * (*)() >(&TDataXtd_PatternStd::get_type_name),
                    R"#(None)#" 
          )
        .def_static("get_type_descriptor_s",
                    (const opencascade::handle<Standard_Type> & (*)() ) static_cast<const opencascade::handle<Standard_Type> & (*)() >(&TDataXtd_PatternStd::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("PatternID",
             (const Standard_GUID & (TDataXtd_PatternStd::*)() const) static_cast<const Standard_GUID & (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::PatternID),
             R"#(None)#"
             
         )
       .def("DynamicType",
             (const opencascade::handle<Standard_Type> & (TDataXtd_PatternStd::*)() const) static_cast<const opencascade::handle<Standard_Type> & (TDataXtd_PatternStd::*)() const>(&TDataXtd_PatternStd::DynamicType),
             R"#(None)#"
             
         )
;

// functions
// ./opencascade/TDataXtd.hxx
// ./opencascade/TDataXtd_Array1OfTrsf.hxx
// ./opencascade/TDataXtd_Axis.hxx
// ./opencascade/TDataXtd_Constraint.hxx
// ./opencascade/TDataXtd_ConstraintEnum.hxx
// ./opencascade/TDataXtd_Geometry.hxx
// ./opencascade/TDataXtd_GeometryEnum.hxx
// ./opencascade/TDataXtd_HArray1OfTrsf.hxx
// ./opencascade/TDataXtd_Pattern.hxx
// ./opencascade/TDataXtd_PatternStd.hxx
// ./opencascade/TDataXtd_Placement.hxx
// ./opencascade/TDataXtd_Plane.hxx
// ./opencascade/TDataXtd_Point.hxx
// ./opencascade/TDataXtd_Position.hxx
// ./opencascade/TDataXtd_Presentation.hxx
// ./opencascade/TDataXtd_Shape.hxx
// ./opencascade/TDataXtd_Triangulation.hxx

// Additional functions

// operators

// register typdefs
    register_template_NCollection_Array1<gp_Trsf>(m,"TDataXtd_Array1OfTrsf");


// exceptions

// user-defined post-inclusion per module in the body

};

// user-defined post-inclusion per module

// user-defined post