// Created on: 1991-03-21 // Created by: Philippe DAUTRY // Copyright (c) 1991-1999 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 _GccAna_Circ2d2TanRad_HeaderFile #define _GccAna_Circ2d2TanRad_HeaderFile #include #include #include #include #include #include #include #include #include #include #include #include class Standard_NegativeValue; class Standard_OutOfRange; class GccEnt_BadQualifier; class StdFail_NotDone; class GccEnt_QualifiedCirc; class GccEnt_QualifiedLin; class gp_Pnt2d; class gp_Circ2d; //! This class implements the algorithms used to //! create 2d circles tangent to 2 //! points/lines/circles and with a given radius. //! For each construction methods arguments are: //! - Two Qualified elements for tangency constraints. //! (for example EnclosedCirc if we want the //! solution inside the argument EnclosedCirc). //! - Two Reals. One (Radius) for the radius and the //! other (Tolerance) for the tolerance. //! Tolerance is only used for the limit cases. //! For example : //! We want to create a circle inside a circle C1 and //! inside a circle C2 with a radius Radius and a //! tolerance Tolerance. //! If we do not use Tolerance it is impossible to //! find a solution in the following case : C2 is //! inside C1 and there is no intersection point //! between the two circles. //! With Tolerance it gives a solution if the lowest //! distance between C1 and C2 is lower than or equal //! Tolerance. class GccAna_Circ2d2TanRad { public: DEFINE_STANDARD_ALLOC //! This method implements the algorithms used to //! create 2d circles TANgent to two 2d circle with a //! radius of Radius. //! It raises NegativeValue if Radius is lower than zero. Standard_EXPORT GccAna_Circ2d2TanRad(const GccEnt_QualifiedCirc& Qualified1, const GccEnt_QualifiedCirc& Qualified2, const Standard_Real Radius, const Standard_Real Tolerance); //! This method implements the algorithms used to //! create 2d circles TANgent to a 2d circle and a 2d line //! with a radius of Radius. //! It raises NegativeValue if Radius is lower than zero. Standard_EXPORT GccAna_Circ2d2TanRad(const GccEnt_QualifiedCirc& Qualified1, const GccEnt_QualifiedLin& Qualified2, const Standard_Real Radius, const Standard_Real Tolerance); //! This method implements the algorithms used to //! create 2d circles TANgent to a 2d circle and a point //! with a radius of Radius. //! It raises NegativeValue if Radius is lower than zero. Standard_EXPORT GccAna_Circ2d2TanRad(const GccEnt_QualifiedCirc& Qualified1, const gp_Pnt2d& Point2, const Standard_Real Radius, const Standard_Real Tolerance); //! This method implements the algorithms used to //! create 2d circles TANgent to a 2d line and a point //! with a radius of Radius. //! It raises NegativeValue if Radius is lower than zero. Standard_EXPORT GccAna_Circ2d2TanRad(const GccEnt_QualifiedLin& Qualified1, const gp_Pnt2d& Point2, const Standard_Real Radius, const Standard_Real Tolerance); //! This method implements the algorithms used to //! create 2d circles TANgent to two 2d lines //! with a radius of Radius. //! It raises NegativeValue if Radius is lower than zero. Standard_EXPORT GccAna_Circ2d2TanRad(const GccEnt_QualifiedLin& Qualified1, const GccEnt_QualifiedLin& Qualified2, const Standard_Real Radius, const Standard_Real Tolerance); //! This method implements the algorithms used to //! create 2d circles passing through two points with a //! radius of Radius. //! It raises NegativeValue if Radius is lower than zero. Standard_EXPORT GccAna_Circ2d2TanRad(const gp_Pnt2d& Point1, const gp_Pnt2d& Point2, const Standard_Real Radius, const Standard_Real Tolerance); //! This method returns True if the algorithm succeeded. //! Note: IsDone protects against a failure arising from a //! more internal intersection algorithm, which has reached its numeric limits. Standard_EXPORT Standard_Boolean IsDone() const; //! This method returns the number of circles, representing solutions computed by this algorithm. //! Exceptions //! StdFail_NotDone if the construction fails. of solutions. Standard_EXPORT Standard_Integer NbSolutions() const; //! Returns the solution number Index. //! Be careful: the Index is only a way to get all the //! solutions, but is not associated to those outside the context //! of the algorithm-object. Raises OutOfRange exception if Index is greater //! than the number of solutions. //! It raises NotDone if the construction algorithm did not //! succeed. Standard_EXPORT gp_Circ2d ThisSolution (const Standard_Integer Index) const; //! Returns the information about the qualifiers of //! the tangency arguments concerning the solution number Index. //! It returns the real qualifiers (the qualifiers given to the //! constructor method in case of enclosed, enclosing and outside //! and the qualifiers computedin case of unqualified). Standard_EXPORT void WhichQualifier (const Standard_Integer Index, GccEnt_Position& Qualif1, GccEnt_Position& Qualif2) const; //! Returns information about the tangency point between the //! result number Index and the first argument. //! ParSol is the intrinsic parameter of the point PntSol on the solution. //! ParArg is the intrinsic parameter of the point PntSol on the first //! argument. Raises OutOfRange if Index is greater than the number //! of solutions. //! It raises NotDone if the construction algorithm did not succeed Standard_EXPORT void Tangency1 (const Standard_Integer Index, Standard_Real& ParSol, Standard_Real& ParArg, gp_Pnt2d& PntSol) const; //! Returns information about the tangency point between the //! result number Index and the second argument. //! ParSol is the intrinsic parameter of the point PntSol on //! the solution. //! ParArg is the intrinsic parameter of the point PntArg on //! the second argument. Raises OutOfRange if Index is greater than the number //! of solutions. //! It raises NotDone if the construction algorithm did not succeed. Standard_EXPORT void Tangency2 (const Standard_Integer Index, Standard_Real& ParSol, Standard_Real& ParArg, gp_Pnt2d& PntSol) const; //! Returns True if the solution number Index is equal to //! the first argument. Raises OutOfRange if Index is greater than the number //! of solutions. //! It raises NotDone if the construction algorithm did not //! succeed. Standard_EXPORT Standard_Boolean IsTheSame1 (const Standard_Integer Index) const; //! Returns True if the solution number Index is equal to //! the second argument. Raises OutOfRange if Index is greater than the number //! of solutions. //! It raises NotDone if the construction algorithm did not succeed. Standard_EXPORT Standard_Boolean IsTheSame2 (const Standard_Integer Index) const; protected: private: Standard_Boolean WellDone; GccEnt_Array1OfPosition qualifier1; GccEnt_Array1OfPosition qualifier2; TColStd_Array1OfInteger TheSame1; TColStd_Array1OfInteger TheSame2; Standard_Integer NbrSol; TColgp_Array1OfCirc2d cirsol; TColgp_Array1OfPnt2d pnttg1sol; TColgp_Array1OfPnt2d pnttg2sol; TColStd_Array1OfReal par1sol; TColStd_Array1OfReal par2sol; TColStd_Array1OfReal pararg1; TColStd_Array1OfReal pararg2; }; #endif // _GccAna_Circ2d2TanRad_HeaderFile