// This file is generated by WOK (CPPExt). // Please do not edit this file; modify original file instead. // The copyright and license terms as defined for the original file apply to // this header file considered to be the "object code" form of the original source. #ifndef _GccAna_Circ2dTanOnRad_HeaderFile #define _GccAna_Circ2dTanOnRad_HeaderFile #ifndef _Standard_HeaderFile #include #endif #ifndef _Standard_Macro_HeaderFile #include #endif #ifndef _Standard_Boolean_HeaderFile #include #endif #ifndef _Standard_Integer_HeaderFile #include #endif #ifndef _TColgp_Array1OfCirc2d_HeaderFile #include #endif #ifndef _GccEnt_Array1OfPosition_HeaderFile #include #endif #ifndef _TColStd_Array1OfInteger_HeaderFile #include #endif #ifndef _TColgp_Array1OfPnt2d_HeaderFile #include #endif #ifndef _TColStd_Array1OfReal_HeaderFile #include #endif #ifndef _Standard_Real_HeaderFile #include #endif #ifndef _GccEnt_Position_HeaderFile #include #endif class Standard_NegativeValue; class Standard_OutOfRange; class StdFail_NotDone; class GccEnt_BadQualifier; class GccEnt_QualifiedCirc; class gp_Lin2d; class GccEnt_QualifiedLin; class gp_Pnt2d; class gp_Circ2d; //! This class implements the algorithms used to
//! create a 2d circle tangent to a 2d entity,
//! centered on a curv and with a given radius.
//! The arguments of all construction methods are :
//! - The qualified element for the tangency constrains
//! (QualifiedCirc, QualifiedLin, Points).
//! - The Center element (circle, line).
//! - A real Tolerance.
//! Tolerance is only used in the limits cases.
//! For example :
//! We want to create a circle tangent to an OutsideCirc C1
//! centered on a line OnLine with a radius Radius and with
//! a tolerance Tolerance.
//! If we did not use Tolerance it is impossible to
//! find a solution in the the following case : OnLine is
//! outside C1. There is no intersection point between C1
//! and OnLine. The distance between the line and the
//! circle is greater than Radius.
//! With Tolerance we will give a solution if the
//! distance between C1 and OnLine is lower than or
//! equal Tolerance.
class GccAna_Circ2dTanOnRad { public: void* operator new(size_t,void* anAddress) { return anAddress; } void* operator new(size_t size) { return Standard::Allocate(size); } void operator delete(void *anAddress) { if (anAddress) Standard::Free((Standard_Address&)anAddress); } //! This methods implements the algorithms used to create
//! 2d Circles tangent to a circle and centered on a 2d Line
//! with a given radius.
//! Tolerance is used to find solution in every limit cases.
//! For example Tolerance is used in the case of EnclosedCirc when
//! Radius-R1+dist is greater Tolerance (dist is the distance
//! between the line and the location of the circ, R1 is the
//! radius of the circ) because there is no solution.
//! raises NegativeValue in case of NegativeRadius.
Standard_EXPORT GccAna_Circ2dTanOnRad(const GccEnt_QualifiedCirc& Qualified1,const gp_Lin2d& OnLine,const Standard_Real Radius,const Standard_Real Tolerance); //! This methods implements the algorithms used to create
//! 2d Circles tangent to a 2d Line and centered on a 2d Line
//! with a given radius.
//! Tolerance is used to find solution in every limit cases.
//! raises NegativeValue in case of NegativeRadius.
Standard_EXPORT GccAna_Circ2dTanOnRad(const GccEnt_QualifiedLin& Qualified1,const gp_Lin2d& OnLine,const Standard_Real Radius,const Standard_Real Tolerance); //! This methods implements the algorithms used to create
//! 2d Circles passing through a 2d Point and centered on a
//! 2d Line with a given radius.
//! Tolerance is used to find solution in every limit cases.
Standard_EXPORT GccAna_Circ2dTanOnRad(const gp_Pnt2d& Point1,const gp_Lin2d& OnLine,const Standard_Real Radius,const Standard_Real Tolerance); //! This methods implements the algorithms used to create
//! 2d Circles tangent to a circle and centered on a 2d Circle
//! with a given radius.
//! Tolerance is used to find solution in every limit cases.
//! raises NegativeValue in case of NegativeRadius.
Standard_EXPORT GccAna_Circ2dTanOnRad(const GccEnt_QualifiedCirc& Qualified1,const gp_Circ2d& OnCirc,const Standard_Real Radius,const Standard_Real Tolerance); //! This methods implements the algorithms used to create
//! 2d Circles tangent to a 2d Line and centered on a 2d Line
//! with a given radius.
//! Tolerance is used to find solution in every limit cases.
//! raises NegativeValue in case of NegativeRadius.
Standard_EXPORT GccAna_Circ2dTanOnRad(const GccEnt_QualifiedLin& Qualified1,const gp_Circ2d& OnCirc,const Standard_Real Radius,const Standard_Real Tolerance); //! This methods implements the algorithms used to create
//! 2d Circles passing through a 2d Point and centered on a
//! 2d Line with a given radius.
//! Tolerance is used to find solution in every limit cases.
//! raises NegativeValue in case of NegativeRadius.
Standard_EXPORT GccAna_Circ2dTanOnRad(const gp_Pnt2d& Point1,const gp_Circ2d& OnCirc,const Standard_Real Radius,const Standard_Real Tolerance); //! Returns true if the construction algorithm does not fail
//! (even if it finds no solution).
//! 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.
//! Raises NotDone if the construction algorithm didn't succeed.
Standard_EXPORT Standard_Integer NbSolutions() const; //! Returns the solution number Index and raises OutOfRange
//! exception if Index is greater than the number of solutions.
//! Be careful: the Index is only a way to get all the
//! solutions, but is not associated to theses outside the
//! context of the algorithm-object.
//! Raises NotDone if the construction algorithm didn't succeed.
//! It raises OutOfRange if Index is greater than the
//! number of solutions
Standard_EXPORT gp_Circ2d ThisSolution(const Standard_Integer Index) const; //! Returns the qualifier Qualif1 of the tangency argument
//! for the solution of index Index computed by this algorithm.
//! The returned qualifier is:
//! - that specified at the start of construction when the
//! solutions are defined as enclosed, enclosing or
//! outside with respect to the argument, or
//! - that computed during construction (i.e. enclosed,
//! enclosing or outside) when the solutions are defined
//! as unqualified with respect to the argument, or
//! - GccEnt_noqualifier if the tangency argument is a point.
//! Exceptions
//! Standard_OutOfRange if Index is less than zero or
//! greater than the number of solutions computed by this algorithm.
//! StdFail_NotDone if the construction fails.
Standard_EXPORT void WhichQualifier(const Standard_Integer Index,GccEnt_Position& Qualif1) const; //! Returns informations about the tangency point between the
//! result number Index and the first argument.
//! ParSol is the intrinsic parameter of the point on the
//! solution curv.
//! ParArg is the intrinsic parameter of the point on the
//! argument curv.
//! PntSol is the tangency point on the solution curv.
//! PntArg is the tangency point on the argument curv.
//! Raises NotDone if the construction algorithm didn't succeed.
//! It raises OutOfRange if Index is greater than the
//! number of solutions.
Standard_EXPORT void Tangency1(const Standard_Integer Index,Standard_Real& ParSol,Standard_Real& ParArg,gp_Pnt2d& PntSol) const; //! Returns informations about the center (on the curv)
//! of the result.
//! ParArg is the intrinsic parameter of the point on
//! the argument curv.
//! PntSol is the center point of the solution curv.
//! Raises NotDone if the construction algorithm didn't succeed.
//! It raises OutOfRange if Index is greater than the
//! number of solutions.
Standard_EXPORT void CenterOn3(const Standard_Integer Index,Standard_Real& ParArg,gp_Pnt2d& PntSol) const; //! Returns True if the solution number Index is equal to
//! the first argument and False in the other cases.
//! Raises NotDone if the construction algorithm didn't succeed.
//! It raises OutOfRange if Index is greater than the
//! number of solutions.
Standard_EXPORT Standard_Boolean IsTheSame1(const Standard_Integer Index) const; protected: private: Standard_Boolean WellDone; Standard_Integer NbrSol; TColgp_Array1OfCirc2d cirsol; GccEnt_Array1OfPosition qualifier1; TColStd_Array1OfInteger TheSame1; TColgp_Array1OfPnt2d pnttg1sol; TColgp_Array1OfPnt2d pntcen3; TColStd_Array1OfReal par1sol; TColStd_Array1OfReal pararg1; TColStd_Array1OfReal parcen3; }; // other Inline functions and methods (like "C++: function call" methods) #endif