[occt.git] / src / Geom / Geom_SurfaceOfLinearExtrusion.hxx

// Created on: 1993-03-10
// Created by: JCV
// Copyright (c) 1993-1999 Matra Datavision
// Copyright (c) 1999-2014 OPEN CASCADE SAS
//
// This file is part of Open CASCADE Technology software library.
//
// This library is free software; you can redistribute it and/or modify it under
// the terms of the GNU Lesser General Public License version 2.1 as published
// by the Free Software Foundation, with special exception defined in the file
// OCCT_LGPL_EXCEPTION.txt. Consult the file LICENSE_LGPL_21.txt included in OCCT
// distribution for complete text of the license and disclaimer of any warranty.
//
// Alternatively, this file may be used under the terms of Open CASCADE
// commercial license or contractual agreement.

#ifndef _Geom_SurfaceOfLinearExtrusion_HeaderFile
#define _Geom_SurfaceOfLinearExtrusion_HeaderFile

#include <Standard.hxx>
#include <Standard_Type.hxx>

#include <Geom_SweptSurface.hxx>
#include <GeomEvaluator_SurfaceOfExtrusion.hxx>
#include <Standard_Real.hxx>
#include <Standard_Boolean.hxx>
#include <Standard_Integer.hxx>
class Standard_RangeError;
class Geom_UndefinedDerivative;
class Geom_Curve;
class gp_Dir;
class gp_Pnt;
class gp_Vec;
class gp_Trsf;
class gp_GTrsf2d;
class Geom_Geometry;


class Geom_SurfaceOfLinearExtrusion;
DEFINE_STANDARD_HANDLE(Geom_SurfaceOfLinearExtrusion, Geom_SweptSurface)

//! Describes a surface of linear extrusion ("extruded
//! surface"), e.g. a generalized cylinder. Such a surface
//! is obtained by sweeping a curve (called the "extruded
//! curve" or "basis") in a given direction (referred to as
//! the "direction of extrusion" and defined by a unit vector).
//! The u parameter is along the extruded curve. The v
//! parameter is along the direction of extrusion.
//! The parameter range for the u parameter is defined
//! by the reference curve.
//! The parameter range for the v parameter is ] -
//! infinity, + infinity [.
//! The position of the curve gives the origin of the v parameter.
//! The surface is "CN" in the v parametric direction.
//! The form of a surface of linear extrusion is generally a
//! ruled surface (GeomAbs_RuledForm). It can be:
//! - a cylindrical surface, if the extruded curve is a circle,
//! or a trimmed circle, with an axis parallel to the
//! direction of extrusion (GeomAbs_CylindricalForm), or
//! - a planar surface, if the extruded curve is a line
//! (GeomAbs_PlanarForm).
//! Note: The surface of extrusion is built from a copy of
//! the original basis curve, so the original curve is not
//! modified when the surface is modified.
//! Warning
//! Degenerate surfaces are not detected. A degenerate
//! surface is obtained, for example, when the extruded
//! curve is a line and the direction of extrusion is parallel
//! to that line.
class Geom_SurfaceOfLinearExtrusion : public Geom_SweptSurface
{

public:

  
  //! V is the direction of extrusion.
  //! C is the extruded curve.
  //! The form of a SurfaceOfLinearExtrusion can be :
  //! . ruled surface (RuledForm),
  //! . a cylindrical surface if the extruded curve is a circle or
  //! a trimmed circle (CylindricalForm),
  //! . a plane surface if the extruded curve is a Line (PlanarForm).
  //! Warnings :
  //! Degenerated surface cases are not detected. For example if the
  //! curve C is a line and V is parallel to the direction of this
  //! line.
  Standard_EXPORT Geom_SurfaceOfLinearExtrusion(const Handle(Geom_Curve)& C, const gp_Dir& V);
  
  //! Assigns V as the "direction of extrusion" for this
  //! surface of linear extrusion.
  Standard_EXPORT void SetDirection (const gp_Dir& V);
  
  //! Modifies this surface of linear extrusion by redefining
  //! its "basis curve" (the "extruded curve").
  Standard_EXPORT void SetBasisCurve (const Handle(Geom_Curve)& C);
  
  //! Changes the orientation of this surface of linear
  //! extrusion in the u  parametric direction. The
  //! bounds of the surface are not changed, but the given
  //! parametric direction is reversed. Hence the
  //! orientation of the surface is reversed.
  //! In the case of a surface of linear extrusion:
  //! - UReverse reverses the basis curve, and
  //! - VReverse reverses the direction of linear extrusion.
  Standard_EXPORT void UReverse() Standard_OVERRIDE;
  
  //! Computes the u parameter on the modified
  //! surface, produced by reversing its u  parametric
  //! direction, for any point of u parameter U  on this surface of linear extrusion.
  //! In the case of an extruded surface:
  //! - UReverseParameter returns the reversed
  //! parameter given by the function
  //! ReversedParameter called with U on the basis   curve,
  Standard_EXPORT Standard_Real UReversedParameter (const Standard_Real U) const Standard_OVERRIDE;
  
  //! Changes the orientation of this surface of linear
  //! extrusion in the v parametric direction. The
  //! bounds of the surface are not changed, but the given
  //! parametric direction is reversed. Hence the
  //! orientation of the surface is reversed.
  //! In the case of a surface of linear extrusion:
  //! - UReverse reverses the basis curve, and
  //! - VReverse reverses the direction of linear extrusion.
  Standard_EXPORT void VReverse() Standard_OVERRIDE;
  
  //! Computes the v parameter on the modified
  //! surface, produced by reversing its u v parametric
  //! direction, for any point of v parameter V on this surface of linear extrusion.
  //! In the case of an extruded surface VReverse returns -V.
  Standard_EXPORT Standard_Real VReversedParameter (const Standard_Real V) const Standard_OVERRIDE;
  
  //! Returns the parametric bounds U1, U2, V1 and V2 of
  //! this surface of linear extrusion.
  //! A surface of linear extrusion is infinite in the v
  //! parametric direction, so:
  //! - V1 = Standard_Real::RealFirst()
  //! - V2 = Standard_Real::RealLast().
  Standard_EXPORT void Bounds (Standard_Real& U1, Standard_Real& U2, Standard_Real& V1, Standard_Real& V2) const Standard_OVERRIDE;
  
  //! IsUClosed returns true if the "basis curve" of this
  //! surface of linear extrusion is closed.
  Standard_EXPORT Standard_Boolean IsUClosed() const Standard_OVERRIDE;
  
  //! IsVClosed always returns false.
  Standard_EXPORT Standard_Boolean IsVClosed() const Standard_OVERRIDE;
  
  //! IsCNu returns true if the degree of continuity for the
  //! "basis curve" of this surface of linear extrusion is at least N.
  //! Raises RangeError if N < 0.
  Standard_EXPORT Standard_Boolean IsCNu (const Standard_Integer N) const Standard_OVERRIDE;
  
  //! IsCNv always returns true.
  Standard_EXPORT Standard_Boolean IsCNv (const Standard_Integer N) const Standard_OVERRIDE;
  
  //! IsUPeriodic returns true if the "basis curve" of this
  //! surface of linear extrusion is periodic.
  Standard_EXPORT Standard_Boolean IsUPeriodic() const Standard_OVERRIDE;
  
  //! IsVPeriodic always returns false.
  Standard_EXPORT Standard_Boolean IsVPeriodic() const Standard_OVERRIDE;
  
  //! Computes the U isoparametric curve of this surface
  //! of linear extrusion. This is the line parallel to the
  //! direction of extrusion, passing through the point of
  //! parameter U of the basis curve.
  Standard_EXPORT Handle(Geom_Curve) UIso (const Standard_Real U) const Standard_OVERRIDE;
  
  //! Computes the V isoparametric curve of this surface
  //! of linear extrusion. This curve is obtained by
  //! translating the extruded curve in the direction of
  //! extrusion, with the magnitude V.
  Standard_EXPORT Handle(Geom_Curve) VIso (const Standard_Real V) const Standard_OVERRIDE;
  

  //! Computes the  point P (U, V) on the surface.
  //! The parameter U is the parameter on the extruded curve.
  //! The parametrization V is a linear parametrization, and
  //! the direction of parametrization is the direction of
  //! extrusion. If the point is on the extruded curve, V = 0.0
  Standard_EXPORT void D0 (const Standard_Real U, const Standard_Real V, gp_Pnt& P) const Standard_OVERRIDE;
  

  //! Computes the current point and the first derivatives in the
  //! directions U and V.
  //! Raises UndefinedDerivative if the continuity of the surface is not C1.
  Standard_EXPORT void D1 (const Standard_Real U, const Standard_Real V, gp_Pnt& P, gp_Vec& D1U, gp_Vec& D1V) const Standard_OVERRIDE;
  
  //! --- Purpose ;
  //! Computes the current point, the first and the second derivatives
  //! in the directions U and V.
  //! Raises UndefinedDerivative if the continuity of the surface is not C2.
  Standard_EXPORT void D2 (const Standard_Real U, const Standard_Real V, gp_Pnt& P, gp_Vec& D1U, gp_Vec& D1V, gp_Vec& D2U, gp_Vec& D2V, gp_Vec& D2UV) const Standard_OVERRIDE;
  

  //! Computes the current point, the first,the second and the third
  //! derivatives in the directions U and V.
  //! Raises UndefinedDerivative if the continuity of the surface is not C3.
  Standard_EXPORT void D3 (const Standard_Real U, const Standard_Real V, gp_Pnt& P, gp_Vec& D1U, gp_Vec& D1V, gp_Vec& D2U, gp_Vec& D2V, gp_Vec& D2UV, gp_Vec& D3U, gp_Vec& D3V, gp_Vec& D3UUV, gp_Vec& D3UVV) const Standard_OVERRIDE;
  

  //! Computes the derivative of order Nu in the direction u
  //! and Nv in the direction v.
  //! Raises UndefinedDerivative if the continuity of the surface is not CNu in the u
  //! direction and CNv in the v direction.
  //! Raises RangeError if Nu + Nv < 1 or Nu < 0 or Nv < 0.
  Standard_EXPORT gp_Vec DN (const Standard_Real U, const Standard_Real V, const Standard_Integer Nu, const Standard_Integer Nv) const Standard_OVERRIDE;

  //! Applies the transformation T to this surface of linear extrusion.
  Standard_EXPORT void Transform (const gp_Trsf& T) Standard_OVERRIDE;
  
  //! Computes the  parameters on the  transformed  surface for
  //! the transform of the point of parameters U,V on <me>.
  //!
  //! me->Transformed(T)->Value(U',V')
  //!
  //! is the same point as
  //!
  //! me->Value(U,V).Transformed(T)
  //!
  //! Where U',V' are the new values of U,V after calling
  //!
  //! me->TranformParameters(U,V,T)
  //!
  //! This methods multiplies :
  //! U by BasisCurve()->ParametricTransformation(T)
  //! V by T.ScaleFactor()
  Standard_EXPORT virtual void TransformParameters (Standard_Real& U, Standard_Real& V, const gp_Trsf& T) const Standard_OVERRIDE;
  
  //! Returns a 2d transformation  used to find the  new
  //! parameters of a point on the transformed surface.
  //!
  //! me->Transformed(T)->Value(U',V')
  //!
  //! is the same point as
  //!
  //! me->Value(U,V).Transformed(T)
  //!
  //! Where U',V' are  obtained by transforming U,V with
  //! th 2d transformation returned by
  //!
  //! me->ParametricTransformation(T)
  //!
  //! This  methods  returns  a scale
  //! U by BasisCurve()->ParametricTransformation(T)
  //! V by T.ScaleFactor()
  Standard_EXPORT virtual gp_GTrsf2d ParametricTransformation (const gp_Trsf& T) const Standard_OVERRIDE;
  
  //! Creates a new object which is a copy of this surface of linear extrusion.
  Standard_EXPORT Handle(Geom_Geometry) Copy() const Standard_OVERRIDE;


  DEFINE_STANDARD_RTTIEXT(Geom_SurfaceOfLinearExtrusion,Geom_SweptSurface)

protected:


private:
  Handle(GeomEvaluator_SurfaceOfExtrusion) myEvaluator;


};


#endif // _Geom_SurfaceOfLinearExtrusion_HeaderFile
Commit	Line	Data
42cf5bc1	1	// Created on: 1993-03-10
	2	// Created by: JCV
	3	// Copyright (c) 1993-1999 Matra Datavision
	4	// Copyright (c) 1999-2014 OPEN CASCADE SAS
	5	//
	6	// This file is part of Open CASCADE Technology software library.
	7	//
	8	// This library is free software; you can redistribute it and/or modify it under
	9	// the terms of the GNU Lesser General Public License version 2.1 as published
	10	// by the Free Software Foundation, with special exception defined in the file
	11	// OCCT_LGPL_EXCEPTION.txt. Consult the file LICENSE_LGPL_21.txt included in OCCT
	12	// distribution for complete text of the license and disclaimer of any warranty.
	13	//
	14	// Alternatively, this file may be used under the terms of Open CASCADE
	15	// commercial license or contractual agreement.
	16
	17	#ifndef _Geom_SurfaceOfLinearExtrusion_HeaderFile
	18	#define _Geom_SurfaceOfLinearExtrusion_HeaderFile
	19
	20	#include <Standard.hxx>
	21	#include <Standard_Type.hxx>
	22
	23	#include <Geom_SweptSurface.hxx>
6b84c3f7	24	#include <GeomEvaluator_SurfaceOfExtrusion.hxx>
42cf5bc1	25	#include <Standard_Real.hxx>
	26	#include <Standard_Boolean.hxx>
	27	#include <Standard_Integer.hxx>
	28	class Standard_RangeError;
	29	class Geom_UndefinedDerivative;
	30	class Geom_Curve;
	31	class gp_Dir;
	32	class gp_Pnt;
	33	class gp_Vec;
	34	class gp_Trsf;
	35	class gp_GTrsf2d;
	36	class Geom_Geometry;
	37
	38
	39	class Geom_SurfaceOfLinearExtrusion;
	40	DEFINE_STANDARD_HANDLE(Geom_SurfaceOfLinearExtrusion, Geom_SweptSurface)
	41
	42	//! Describes a surface of linear extrusion ("extruded
	43	//! surface"), e.g. a generalized cylinder. Such a surface
	44	//! is obtained by sweeping a curve (called the "extruded
	45	//! curve" or "basis") in a given direction (referred to as
	46	//! the "direction of extrusion" and defined by a unit vector).
	47	//! The u parameter is along the extruded curve. The v
	48	//! parameter is along the direction of extrusion.
	49	//! The parameter range for the u parameter is defined
	50	//! by the reference curve.
	51	//! The parameter range for the v parameter is ] -
	52	//! infinity, + infinity [.
	53	//! The position of the curve gives the origin of the v parameter.
	54	//! The surface is "CN" in the v parametric direction.
	55	//! The form of a surface of linear extrusion is generally a
	56	//! ruled surface (GeomAbs_RuledForm). It can be:
	57	//! - a cylindrical surface, if the extruded curve is a circle,
	58	//! or a trimmed circle, with an axis parallel to the
	59	//! direction of extrusion (GeomAbs_CylindricalForm), or
	60	//! - a planar surface, if the extruded curve is a line
	61	//! (GeomAbs_PlanarForm).
	62	//! Note: The surface of extrusion is built from a copy of
	63	//! the original basis curve, so the original curve is not
	64	//! modified when the surface is modified.
	65	//! Warning
	66	//! Degenerate surfaces are not detected. A degenerate
	67	//! surface is obtained, for example, when the extruded
	68	//! curve is a line and the direction of extrusion is parallel
	69	//! to that line.
	70	class Geom_SurfaceOfLinearExtrusion : public Geom_SweptSurface
	71	{
	72
	73	public:
	74
	75
	76
	77	//! V is the direction of extrusion.
	78	//! C is the extruded curve.
	79	//! The form of a SurfaceOfLinearExtrusion can be :
	80	//! . ruled surface (RuledForm),
	81	//! . a cylindrical surface if the extruded curve is a circle or
	82	//! a trimmed circle (CylindricalForm),
	83	//! . a plane surface if the extruded curve is a Line (PlanarForm).
	84	//! Warnings :
	85	//! Degenerated surface cases are not detected. For example if the
	86	//! curve C is a line and V is parallel to the direction of this
	87	//! line.
	88	Standard_EXPORT Geom_SurfaceOfLinearExtrusion(const Handle(Geom_Curve)& C, const gp_Dir& V);
89
90	//! Assigns V as the "direction of extrusion" for this
91	//! surface of linear extrusion.
92	Standard_EXPORT void SetDirection (const gp_Dir& V);
93
94	//! Modifies this surface of linear extrusion by redefining
95	//! its "basis curve" (the "extruded curve").
96	Standard_EXPORT void SetBasisCurve (const Handle(Geom_Curve)& C);
97
98	//! Changes the orientation of this surface of linear
99	//! extrusion in the u parametric direction. The
100	//! bounds of the surface are not changed, but the given
101	//! parametric direction is reversed. Hence the
102	//! orientation of the surface is reversed.
103	//! In the case of a surface of linear extrusion:
104	//! - UReverse reverses the basis curve, and
105	//! - VReverse reverses the direction of linear extrusion.
79104795	106	Standard_EXPORT void UReverse() Standard_OVERRIDE;
42cf5bc1	107
	108	//! Computes the u parameter on the modified
	109	//! surface, produced by reversing its u parametric
	110	//! direction, for any point of u parameter U on this surface of linear extrusion.
	111	//! In the case of an extruded surface:
	112	//! - UReverseParameter returns the reversed
	113	//! parameter given by the function
	114	//! ReversedParameter called with U on the basis curve,
79104795	115	Standard_EXPORT Standard_Real UReversedParameter (const Standard_Real U) const Standard_OVERRIDE;
42cf5bc1	116
	117	//! Changes the orientation of this surface of linear
	118	//! extrusion in the v parametric direction. The
	119	//! bounds of the surface are not changed, but the given
	120	//! parametric direction is reversed. Hence the
	121	//! orientation of the surface is reversed.
	122	//! In the case of a surface of linear extrusion:
	123	//! - UReverse reverses the basis curve, and
	124	//! - VReverse reverses the direction of linear extrusion.
79104795	125	Standard_EXPORT void VReverse() Standard_OVERRIDE;
42cf5bc1	126
	127	//! Computes the v parameter on the modified
	128	//! surface, produced by reversing its u v parametric
	129	//! direction, for any point of v parameter V on this surface of linear extrusion.
	130	//! In the case of an extruded surface VReverse returns -V.
79104795	131	Standard_EXPORT Standard_Real VReversedParameter (const Standard_Real V) const Standard_OVERRIDE;
42cf5bc1	132
	133	//! Returns the parametric bounds U1, U2, V1 and V2 of
	134	//! this surface of linear extrusion.
	135	//! A surface of linear extrusion is infinite in the v
	136	//! parametric direction, so:
	137	//! - V1 = Standard_Real::RealFirst()
	138	//! - V2 = Standard_Real::RealLast().
79104795	139	Standard_EXPORT void Bounds (Standard_Real& U1, Standard_Real& U2, Standard_Real& V1, Standard_Real& V2) const Standard_OVERRIDE;
42cf5bc1	140
	141	//! IsUClosed returns true if the "basis curve" of this
	142	//! surface of linear extrusion is closed.
79104795	143	Standard_EXPORT Standard_Boolean IsUClosed() const Standard_OVERRIDE;
42cf5bc1	144
42cf5bc1	145	//! IsVClosed always returns false.
79104795	146	Standard_EXPORT Standard_Boolean IsVClosed() const Standard_OVERRIDE;
42cf5bc1	147
	148	//! IsCNu returns true if the degree of continuity for the
	149	//! "basis curve" of this surface of linear extrusion is at least N.
	150	//! Raises RangeError if N < 0.
79104795	151	Standard_EXPORT Standard_Boolean IsCNu (const Standard_Integer N) const Standard_OVERRIDE;
42cf5bc1	152
42cf5bc1	153	//! IsCNv always returns true.
79104795	154	Standard_EXPORT Standard_Boolean IsCNv (const Standard_Integer N) const Standard_OVERRIDE;
42cf5bc1	155
	156	//! IsUPeriodic returns true if the "basis curve" of this
	157	//! surface of linear extrusion is periodic.
79104795	158	Standard_EXPORT Standard_Boolean IsUPeriodic() const Standard_OVERRIDE;
42cf5bc1	159
42cf5bc1	160	//! IsVPeriodic always returns false.
79104795	161	Standard_EXPORT Standard_Boolean IsVPeriodic() const Standard_OVERRIDE;
42cf5bc1	162
	163	//! Computes the U isoparametric curve of this surface
	164	//! of linear extrusion. This is the line parallel to the
	165	//! direction of extrusion, passing through the point of
	166	//! parameter U of the basis curve.
79104795	167	Standard_EXPORT Handle(Geom_Curve) UIso (const Standard_Real U) const Standard_OVERRIDE;
42cf5bc1	168
	169	//! Computes the V isoparametric curve of this surface
	170	//! of linear extrusion. This curve is obtained by
	171	//! translating the extruded curve in the direction of
	172	//! extrusion, with the magnitude V.
79104795	173	Standard_EXPORT Handle(Geom_Curve) VIso (const Standard_Real V) const Standard_OVERRIDE;
42cf5bc1	174
	175
	176	//! Computes the point P (U, V) on the surface.
	177	//! The parameter U is the parameter on the extruded curve.
	178	//! The parametrization V is a linear parametrization, and
	179	//! the direction of parametrization is the direction of
	180	//! extrusion. If the point is on the extruded curve, V = 0.0
79104795	181	Standard_EXPORT void D0 (const Standard_Real U, const Standard_Real V, gp_Pnt& P) const Standard_OVERRIDE;
42cf5bc1	182
	183
	184	//! Computes the current point and the first derivatives in the
	185	//! directions U and V.
	186	//! Raises UndefinedDerivative if the continuity of the surface is not C1.
79104795	187	Standard_EXPORT void D1 (const Standard_Real U, const Standard_Real V, gp_Pnt& P, gp_Vec& D1U, gp_Vec& D1V) const Standard_OVERRIDE;
42cf5bc1	188
	189	//! --- Purpose ;
	190	//! Computes the current point, the first and the second derivatives
	191	//! in the directions U and V.
	192	//! Raises UndefinedDerivative if the continuity of the surface is not C2.
79104795	193	Standard_EXPORT void D2 (const Standard_Real U, const Standard_Real V, gp_Pnt& P, gp_Vec& D1U, gp_Vec& D1V, gp_Vec& D2U, gp_Vec& D2V, gp_Vec& D2UV) const Standard_OVERRIDE;
42cf5bc1	194
	195
	196	//! Computes the current point, the first,the second and the third
	197	//! derivatives in the directions U and V.
	198	//! Raises UndefinedDerivative if the continuity of the surface is not C3.
79104795	199	Standard_EXPORT void D3 (const Standard_Real U, const Standard_Real V, gp_Pnt& P, gp_Vec& D1U, gp_Vec& D1V, gp_Vec& D2U, gp_Vec& D2V, gp_Vec& D2UV, gp_Vec& D3U, gp_Vec& D3V, gp_Vec& D3UUV, gp_Vec& D3UVV) const Standard_OVERRIDE;
42cf5bc1	200
	201
	202	//! Computes the derivative of order Nu in the direction u
	203	//! and Nv in the direction v.
	204	//! Raises UndefinedDerivative if the continuity of the surface is not CNu in the u
	205	//! direction and CNv in the v direction.
	206	//! Raises RangeError if Nu + Nv < 1 or Nu < 0 or Nv < 0.
79104795	207	Standard_EXPORT gp_Vec DN (const Standard_Real U, const Standard_Real V, const Standard_Integer Nu, const Standard_Integer Nv) const Standard_OVERRIDE;
6b84c3f7	208
42cf5bc1	209	//! Applies the transformation T to this surface of linear extrusion.
79104795	210	Standard_EXPORT void Transform (const gp_Trsf& T) Standard_OVERRIDE;
42cf5bc1	211
	212	//! Computes the parameters on the transformed surface for
	213	//! the transform of the point of parameters U,V on <me>.
	214	//!
	215	//! me->Transformed(T)->Value(U',V')
	216	//!
	217	//! is the same point as
	218	//!
	219	//! me->Value(U,V).Transformed(T)
	220	//!
	221	//! Where U',V' are the new values of U,V after calling
	222	//!
	223	//! me->TranformParameters(U,V,T)
	224	//!
	225	//! This methods multiplies :
	226	//! U by BasisCurve()->ParametricTransformation(T)
	227	//! V by T.ScaleFactor()
	228	Standard_EXPORT virtual void TransformParameters (Standard_Real& U, Standard_Real& V, const gp_Trsf& T) const Standard_OVERRIDE;
	229
	230	//! Returns a 2d transformation used to find the new
	231	//! parameters of a point on the transformed surface.
	232	//!
	233	//! me->Transformed(T)->Value(U',V')
	234	//!
	235	//! is the same point as
	236	//!
	237	//! me->Value(U,V).Transformed(T)
	238	//!
	239	//! Where U',V' are obtained by transforming U,V with
	240	//! th 2d transformation returned by
	241	//!
	242	//! me->ParametricTransformation(T)
	243	//!
	244	//! This methods returns a scale
	245	//! U by BasisCurve()->ParametricTransformation(T)
	246	//! V by T.ScaleFactor()
	247	Standard_EXPORT virtual gp_GTrsf2d ParametricTransformation (const gp_Trsf& T) const Standard_OVERRIDE;
	248
	249	//! Creates a new object which is a copy of this surface of linear extrusion.
79104795	250	Standard_EXPORT Handle(Geom_Geometry) Copy() const Standard_OVERRIDE;
42cf5bc1	251
	252
	253
	254
92efcf78	255	DEFINE_STANDARD_RTTIEXT(Geom_SurfaceOfLinearExtrusion,Geom_SweptSurface)
42cf5bc1	256
	257	protected:
	258
	259
	260
	261
	262	private:
6b84c3f7	263	Handle(GeomEvaluator_SurfaceOfExtrusion) myEvaluator;
42cf5bc1	264
	265
	266
	267	};
	268
	269
	270
	271
	272
	273
	274
	275	#endif // _Geom_SurfaceOfLinearExtrusion_HeaderFile