path: root/inc/gp_Ax2d.hxx

// 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 _gp_Ax2d_HeaderFile
#define _gp_Ax2d_HeaderFile

#ifndef _Standard_HeaderFile
#include <Standard.hxx>
#endif
#ifndef _Standard_Macro_HeaderFile
#include <Standard_Macro.hxx>
#endif

#ifndef _gp_Pnt2d_HeaderFile
#include <gp_Pnt2d.hxx>
#endif
#ifndef _gp_Dir2d_HeaderFile
#include <gp_Dir2d.hxx>
#endif
#ifndef _Standard_Storable_HeaderFile
#include <Standard_Storable.hxx>
#endif
#ifndef _Standard_Boolean_HeaderFile
#include <Standard_Boolean.hxx>
#endif
#ifndef _Standard_Real_HeaderFile
#include <Standard_Real.hxx>
#endif
#ifndef _Standard_PrimitiveTypes_HeaderFile
#include <Standard_PrimitiveTypes.hxx>
#endif
class gp_Pnt2d;
class gp_Dir2d;
class gp_Trsf2d;
class gp_Vec2d;


Standard_EXPORT const Handle(Standard_Type)& STANDARD_TYPE(gp_Ax2d);


//! Describes an axis in the plane (2D space). <br>
//! An axis is defined by: <br>
//! -   its origin (also referred to as its "Location point"),   and <br>
//! -   its unit vector (referred to as its "Direction"). <br>
//! An axis implicitly defines a direct, right-handed <br>
//! coordinate system in 2D space by: <br>
//! -   its origin, <br>
//! - its "Direction" (giving the "X Direction" of the coordinate system), and <br>
//! -   the unit vector normal to "Direction" (positive angle <br>
//!   measured in the trigonometric sense). <br>
//! An axis is used: <br>
//! -   to describe 2D geometric entities (for example, the <br>
//!   axis which defines angular coordinates on a circle). <br>
//!   It serves for the same purpose as the STEP function <br>
//!   "axis placement one axis", or <br>
//! -   to define geometric transformations (axis of <br>
//!   symmetry, axis of rotation, and so on). <br>
//! Note: to define a left-handed 2D coordinate system, use gp_Ax22d. <br>
class gp_Ax2d  {

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); 
  }

  //! Creates an axis object representing X axis of <br>
//!            the reference co-ordinate system. <br>
      gp_Ax2d();
  
//!  Creates an Ax2d. <P> is the "Location" point of <br>
//!  the axis placement and V is the "Direction" of <br>
//!  the axis placement. <br>
      gp_Ax2d(const gp_Pnt2d& P,const gp_Dir2d& V);
  //!  Changes the "Location" point (origin) of <me>. <br>
        void SetLocation(const gp_Pnt2d& Locat) ;
  //! Changes the direction of <me>. <br>
        void SetDirection(const gp_Dir2d& V) ;
  //! Returns the origin of <me>. <br>
       const gp_Pnt2d& Location() const;
  //! Returns the direction of <me>. <br>
       const gp_Dir2d& Direction() const;
  
//!  Returns True if  : <br>
//!  . the angle between <me> and <Other> is lower or equal <br>
//!    to <AngularTolerance> and <br>
//!  . the distance between <me>.Location() and <Other> is lower <br>
//!    or equal to <LinearTolerance> and <br>
//!  . the distance between <Other>.Location() and <me> is lower <br>
//!    or equal to LinearTolerance. <br>
  Standard_EXPORT     Standard_Boolean IsCoaxial(const gp_Ax2d& Other,const Standard_Real AngularTolerance,const Standard_Real LinearTolerance) const;
  //! Returns true if this axis and the axis Other are normal to <br>
//! each other. That is, if the angle between the two axes is equal to Pi/2 or -Pi/2. <br>
//! Note: the tolerance criterion is given by AngularTolerance. <br>
        Standard_Boolean IsNormal(const gp_Ax2d& Other,const Standard_Real AngularTolerance) const;
  //! Returns true if this axis and the axis Other are parallel, <br>
//! and have opposite orientations. That is, if the angle <br>
//! between the two axes is equal to Pi or -Pi. <br>
//! Note: the tolerance criterion is given by AngularTolerance. <br>
        Standard_Boolean IsOpposite(const gp_Ax2d& Other,const Standard_Real AngularTolerance) const;
  //!  Returns true if this axis and the axis Other are parallel, <br>
//! and have either the same or opposite orientations. That <br>
//! is, if the angle between the two axes is equal to 0, Pi or -Pi. <br>
//! Note: the tolerance criterion is given by AngularTolerance. <br>
        Standard_Boolean IsParallel(const gp_Ax2d& Other,const Standard_Real AngularTolerance) const;
  
//! Computes the angle, in radians, between this axis and <br>
//! the axis Other. The value of the angle is between -Pi and Pi. <br>
        Standard_Real Angle(const gp_Ax2d& Other) const;
  //! Reverses the direction of <me> and assigns the result to this axis. <br>
        void Reverse() ;
  
//!  Computes a new axis placement with a direction opposite to <br>
//!  the direction of <me>. <br>
        gp_Ax2d Reversed() const;
  
  Standard_EXPORT     void Mirror(const gp_Pnt2d& P) ;
  
//!  Performs the symmetrical transformation of an axis <br>
//!  placement with respect to the point P which is the <br>
//!  center of the symmetry. <br>
  Standard_EXPORT     gp_Ax2d Mirrored(const gp_Pnt2d& P) const;
  
  Standard_EXPORT     void Mirror(const gp_Ax2d& A) ;
  
//!  Performs the symmetrical transformation of an axis <br>
//!  placement with respect to an axis placement which <br>
//!  is the axis of the symmetry. <br>
  Standard_EXPORT     gp_Ax2d Mirrored(const gp_Ax2d& A) const;
  
        void Rotate(const gp_Pnt2d& P,const Standard_Real Ang) ;
  
//!  Rotates an axis placement. <P> is the center of the <br>
//!  rotation . Ang is the angular value of the rotation <br>
//!  in radians. <br>
        gp_Ax2d Rotated(const gp_Pnt2d& P,const Standard_Real Ang) const;
  
  Standard_EXPORT     void Scale(const gp_Pnt2d& P,const Standard_Real S) ;
  
//!  Applies a scaling transformation on the axis placement. <br>
//!  The "Location" point of the axisplacement is modified. <br>
//!  The "Direction" is reversed if the scale is negative. <br>
        gp_Ax2d Scaled(const gp_Pnt2d& P,const Standard_Real S) const;
  
        void Transform(const gp_Trsf2d& T) ;
  //!  Transforms an axis placement with a Trsf. <br>
        gp_Ax2d Transformed(const gp_Trsf2d& T) const;
  
        void Translate(const gp_Vec2d& V) ;
  
//!  Translates an axis placement in the direction of the vector <br>
//!  <V>. The magnitude of the translation is the vector's magnitude. <br>
        gp_Ax2d Translated(const gp_Vec2d& V) const;
  
        void Translate(const gp_Pnt2d& P1,const gp_Pnt2d& P2) ;
  
//!  Translates an axis placement from the point <P1> to the <br>
//!  point <P2>. <br>
        gp_Ax2d Translated(const gp_Pnt2d& P1,const gp_Pnt2d& P2) const;
    const gp_Pnt2d& _CSFDB_Getgp_Ax2dloc() const { return loc; }
    const gp_Dir2d& _CSFDB_Getgp_Ax2dvdir() const { return vdir; }



protected:




private: 


gp_Pnt2d loc;
gp_Dir2d vdir;


};


#include <gp_Ax2d.lxx>



// other Inline functions and methods (like "C++: function call" methods)


#endif