// 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_SurfaceOfRevolution_HeaderFile #define _Geom_SurfaceOfRevolution_HeaderFile #include #include #include #include #include #include #include #include class Standard_ConstructionError; class Standard_RangeError; class Geom_UndefinedDerivative; class Geom_Curve; class gp_Ax1; class gp_Dir; class gp_Pnt; class gp_Ax2; class gp_Trsf; class gp_GTrsf2d; class gp_Vec; class Geom_Geometry; class Geom_SurfaceOfRevolution; DEFINE_STANDARD_HANDLE(Geom_SurfaceOfRevolution, Geom_SweptSurface) //! Describes a surface of revolution (revolved surface). //! Such a surface is obtained by rotating a curve (called //! the "meridian") through a complete revolution about //! an axis (referred to as the "axis of revolution"). The //! curve and the axis must be in the same plane (the //! "reference plane" of the surface). //! Rotation around the axis of revolution in the //! trigonometric sense defines the u parametric //! direction. So the u parameter is an angle, and its //! origin is given by the position of the meridian on the surface. //! The parametric range for the u parameter is: [ 0, 2.*Pi ] //! The v parameter is that of the meridian. //! Note: A surface of revolution is built from a copy of the //! original meridian. As a result the original meridian is //! not modified when the surface is modified. //! The form of a surface of revolution is typically a //! general revolution surface //! (GeomAbs_RevolutionForm). It can be: //! - a conical surface, if the meridian is a line or a //! trimmed line (GeomAbs_ConicalForm), //! - a cylindrical surface, if the meridian is a line or a //! trimmed line parallel to the axis of revolution //! (GeomAbs_CylindricalForm), //! - a planar surface if the meridian is a line or a //! trimmed line perpendicular to the axis of revolution //! of the surface (GeomAbs_PlanarForm), //! - a toroidal surface, if the meridian is a circle or a //! trimmed circle (GeomAbs_ToroidalForm), or //! - a spherical surface, if the meridian is a circle, the //! center of which is located on the axis of the //! revolved surface (GeomAbs_SphericalForm). //! Warning //! Be careful not to construct a surface of revolution //! where the curve and the axis or revolution are not //! defined in the same plane. If you do not have a //! correct configuration, you can correct your initial //! curve, using a cylindrical projection in the reference plane. class Geom_SurfaceOfRevolution : public Geom_SweptSurface { public: //! C : is the meridian or the referenced curve. //! A1 is the axis of revolution. //! The form of a SurfaceOfRevolution can be : //! . a general revolution surface (RevolutionForm), //! . a conical surface if the meridian is a line or a trimmed line //! (ConicalForm), //! . a cylindrical surface if the meridian is a line or a trimmed //! line parallel to the revolution axis (CylindricalForm), //! . a planar surface if the meridian is a line perpendicular to //! the revolution axis of the surface (PlanarForm). //! . a spherical surface, //! . a toroidal surface, //! . a quadric surface. //! Warnings : //! It is not checked that the curve C is planar and that the //! surface axis is in the plane of the curve. //! It is not checked that the revolved curve C doesn't //! self-intersects. Standard_EXPORT Geom_SurfaceOfRevolution(const Handle(Geom_Curve)& C, const gp_Ax1& A1); //! Changes the axis of revolution. //! Warnings : //! It is not checked that the axis is in the plane of the //! revolved curve. Standard_EXPORT void SetAxis (const gp_Ax1& A1); //! Changes the direction of the revolution axis. //! Warnings : //! It is not checked that the axis is in the plane of the //! revolved curve. Standard_EXPORT void SetDirection (const gp_Dir& V); //! Changes the revolved curve of the surface. //! Warnings : //! It is not checked that the curve C is planar and that the //! surface axis is in the plane of the curve. //! It is not checked that the revolved curve C doesn't //! self-intersects. Standard_EXPORT void SetBasisCurve (const Handle(Geom_Curve)& C); //! Changes the location point of the revolution axis. //! Warnings : //! It is not checked that the axis is in the plane of the //! revolved curve. Standard_EXPORT void SetLocation (const gp_Pnt& P); //! Returns the revolution axis of the surface. Standard_EXPORT gp_Ax1 Axis() const; //! Returns the location point of the axis of revolution. Standard_EXPORT const gp_Pnt& Location() const; //! Computes the position of the reference plane of the surface //! defined by the basis curve and the symmetry axis. //! The location point is the location point of the revolution's //! axis, the XDirection of the plane is given by the revolution's //! axis and the orientation of the normal to the plane is given //! by the sense of revolution. //! //! Raised if the revolved curve is not planar or if the revolved //! curve and the symmetry axis are not in the same plane or if //! the maximum of distance between the axis and the revolved //! curve is lower or equal to Resolution from gp. Standard_EXPORT gp_Ax2 ReferencePlane() const; //! Changes the orientation of this surface of revolution //! 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. //! As a consequence: //! - UReverse reverses the direction of the axis of //! revolution of this surface, Standard_EXPORT void UReverse(); //! Computes the u parameter on the modified //! surface, when reversing its u parametric //! direction, for any point of u parameter U on this surface of revolution. //! In the case of a revolved surface: //! - UReversedParameter returns 2.*Pi - U Standard_EXPORT Standard_Real UReversedParameter (const Standard_Real U) const; //! Changes the orientation of this surface of revolution //! 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. //! As a consequence: //! - VReverse reverses the meridian of this surface of revolution. Standard_EXPORT void VReverse(); //! Computes the v parameter on the modified //! surface, when reversing its v parametric //! direction, for any point of v parameter V on this surface of revolution. //! In the case of a revolved surface: //! - VReversedParameter returns the reversed //! parameter given by the function //! ReversedParameter called with V on the meridian. Standard_EXPORT Standard_Real VReversedParameter (const Standard_Real V) const; //! Computes the parameters on the transformed surface for //! the transform of the point of parameters U,V on . //! //! 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 V by //! BasisCurve()->ParametricTransformation(T) 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 centered on the //! U axis with BasisCurve()->ParametricTransformation(T) Standard_EXPORT virtual gp_GTrsf2d ParametricTransformation (const gp_Trsf& T) const Standard_OVERRIDE; //! Returns the parametric bounds U1, U2 , V1 and V2 of this surface. //! A surface of revolution is always complete, so U1 = 0, U2 = 2*PI. Standard_EXPORT void Bounds (Standard_Real& U1, Standard_Real& U2, Standard_Real& V1, Standard_Real& V2) const; //! IsUClosed always returns true. Standard_EXPORT Standard_Boolean IsUClosed() const; //! IsVClosed returns true if the meridian of this //! surface of revolution is closed. Standard_EXPORT Standard_Boolean IsVClosed() const; //! IsCNu always returns true. Standard_EXPORT Standard_Boolean IsCNu (const Standard_Integer N) const; //! IsCNv returns true if the degree of continuity of the //! meridian of this surface of revolution is at least N. //! Raised if N < 0. Standard_EXPORT Standard_Boolean IsCNv (const Standard_Integer N) const; //! Returns True. Standard_EXPORT Standard_Boolean IsUPeriodic() const; //! IsVPeriodic returns true if the meridian of this //! surface of revolution is periodic. Standard_EXPORT Standard_Boolean IsVPeriodic() const; //! Computes the U isoparametric curve of this surface //! of revolution. It is the curve obtained by rotating the //! meridian through an angle U about the axis of revolution. Standard_EXPORT Handle(Geom_Curve) UIso (const Standard_Real U) const; //! Computes the U isoparametric curve of this surface //! of revolution. It is the curve obtained by rotating the //! meridian through an angle U about the axis of revolution. Standard_EXPORT Handle(Geom_Curve) VIso (const Standard_Real V) const; //! Computes the point P (U, V) on the surface. //! U is the angle of the rotation around the revolution axis. //! The direction of this axis gives the sense of rotation. //! V is the parameter of the revolved curve. Standard_EXPORT void D0 (const Standard_Real U, const Standard_Real V, gp_Pnt& P) const; //! Computes the current point and the first derivatives //! in the directions U and V. //! Raised 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; //! Computes the current point, the first and the second derivatives //! in the directions U and V. //! Raised 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; //! Computes the current point, the first,the second and the third //! derivatives in the directions U and V. //! Raised 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; //! Computes the derivative of order Nu in the direction u and //! Nv in the direction v. //! //! Raised if the continuity of the surface is not CNu in the u //! direction and CNv in the v direction. //! Raised if Nu + Nv < 1 or Nu < 0 or Nv < 0. //! The following functions evaluates the local //! derivatives on surface. Useful to manage discontinuities //! on the surface. //! if Side = 1 -> P = S( U+,V ) //! if Side = -1 -> P = S( U-,V ) //! else P is betveen discontinuities //! can be evaluated using methods of //! global evaluations P = S( U ,V ) Standard_EXPORT gp_Vec DN (const Standard_Real U, const Standard_Real V, const Standard_Integer Nu, const Standard_Integer Nv) const; //! Applies the transformation T to this surface of revolution. Standard_EXPORT void Transform (const gp_Trsf& T); //! Creates a new object which is a copy of this surface of revolution. Standard_EXPORT Handle(Geom_Geometry) Copy() const; DEFINE_STANDARD_RTTI(Geom_SurfaceOfRevolution,Geom_SweptSurface) private: Handle(GeomEvaluator_SurfaceOfRevolution) myEvaluator; gp_Pnt loc; }; #endif // _Geom_SurfaceOfRevolution_HeaderFile