The root class for bounded surfaces in 3D space. A bounded surface is defined by a rectangle in its 2D parametric space, i.e. More...

#include <Geom_BoundedSurface.hxx>

Inheritance diagram for Geom_BoundedSurface:

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Additional Inherited Members
Public Types inherited from Standard_Transient
typedef void	base_type
	Returns a type descriptor about this object.

Public Member Functions inherited from Geom_Surface
virtual void	UReverse ()=0
	Reverses the U direction of parametrization of <me>. The bounds of the surface are not modified.

occ::handle< Geom_Surface >	UReversed () const
	Reverses the U direction of parametrization of <me>. The bounds of the surface are not modified. A copy of <me> is returned.

virtual double	UReversedParameter (const double U) const =0
	Returns the parameter on the Ureversed surface for the point of parameter U on <me>.

virtual void	VReverse ()=0
	Reverses the V direction of parametrization of <me>. The bounds of the surface are not modified.

occ::handle< Geom_Surface >	VReversed () const
	Reverses the V direction of parametrization of <me>. The bounds of the surface are not modified. A copy of <me> is returned.

virtual double	VReversedParameter (const double V) const =0
	Returns the parameter on the Vreversed surface for the point of parameter V on <me>.

virtual void	TransformParameters (double &U, double &V, const gp_Trsf &T) const
	Computes the parameters on the transformed surface for the transform of the point of parameters U,V on <me>.

virtual gp_GTrsf2d	ParametricTransformation (const gp_Trsf &T) const
	Returns a 2d transformation used to find the new parameters of a point on the transformed surface.

virtual void	Bounds (double &U1, double &U2, double &V1, double &V2) const =0
	Returns the parametric bounds U1, U2, V1 and V2 of this surface. If the surface is infinite, this function can return a value equal to Precision::Infinite: instead of double::LastReal.

virtual bool	IsUClosed () const =0
	Checks whether this surface is closed in the u parametric direction. Returns true if, in the u parametric direction: taking uFirst and uLast as the parametric bounds in the u parametric direction, for each parameter v, the distance between the points P(uFirst, v) and P(uLast, v) is less than or equal to gp::Resolution().

virtual bool	IsVClosed () const =0
	Checks whether this surface is closed in the u parametric direction. Returns true if, in the v parametric direction: taking vFirst and vLast as the parametric bounds in the v parametric direction, for each parameter u, the distance between the points P(u, vFirst) and P(u, vLast) is less than or equal to gp::Resolution().

virtual bool	IsUPeriodic () const =0
	Checks if this surface is periodic in the u parametric direction. Returns true if:

virtual double	UPeriod () const
	Returns the period of this surface in the u parametric direction. Raises if the surface is not uperiodic.

virtual bool	IsVPeriodic () const =0
	Checks if this surface is periodic in the v parametric direction. Returns true if:

virtual double	VPeriod () const
	Returns the period of this surface in the v parametric direction. raises if the surface is not vperiodic.

virtual occ::handle< Geom_Curve >	UIso (const double U) const =0
	Computes the U isoparametric curve.

virtual occ::handle< Geom_Curve >	VIso (const double V) const =0
	Computes the V isoparametric curve.

virtual GeomAbs_Shape	Continuity () const =0
	Returns the Global Continuity of the surface in direction U and V :

virtual bool	IsCNu (const int N) const =0
	Returns the order of continuity of the surface in the U parametric direction. Raised if N < 0.

virtual bool	IsCNv (const int N) const =0
	Returns the order of continuity of the surface in the V parametric direction. Raised if N < 0.

virtual gp_Pnt	EvalD0 (const double U, const double V) const =0
	Computes the point of parameter (U, V) on the surface. Raises an exception on failure.

virtual ResD1	EvalD1 (const double U, const double V) const =0
	Computes the point and first partial derivatives at (U, V). Raises an exception if the surface continuity is not C1.

virtual ResD2	EvalD2 (const double U, const double V) const =0
	Computes the point and partial derivatives up to 2nd order at (U, V). Raises an exception if the surface continuity is not C2.

virtual ResD3	EvalD3 (const double U, const double V) const =0
	Computes the point and partial derivatives up to 3rd order at (U, V). Raises an exception if the surface continuity is not C3.

virtual gp_Vec	EvalDN (const double U, const double V, const int Nu, const int Nv) const =0
	Computes the derivative of order Nu in U and Nv in V at the point (U, V). Raises an exception on failure.

void	D0 (const double U, const double V, gp_Pnt &P) const
	Computes the point of parameter (U, V).

void	D1 (const double U, const double V, gp_Pnt &P, gp_Vec &D1U, gp_Vec &D1V) const
	Computes the point and first partial derivatives.

void	D2 (const double U, const double V, gp_Pnt &P, gp_Vec &D1U, gp_Vec &D1V, gp_Vec &D2U, gp_Vec &D2V, gp_Vec &D2UV) const
	Computes the point and partial derivatives up to 2nd order.

void	D3 (const double U, const double 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 point and partial derivatives up to 3rd order.

gp_Vec	DN (const double U, const double V, const int Nu, const int Nv) const
	Computes the derivative of order Nu in U and Nv in V.

gp_Pnt	Value (const double U, const double V) const
	Computes the point of parameter (U, V) on the surface.

void	DumpJson (Standard_OStream &theOStream, int theDepth=-1) const override
	Dumps the content of me into the stream.

Public Member Functions inherited from Geom_Geometry
void	Mirror (const gp_Pnt &P)
	Performs the symmetrical transformation of a Geometry with respect to the point P which is the center of the symmetry.

void	Mirror (const gp_Ax1 &A1)
	Performs the symmetrical transformation of a Geometry with respect to an axis placement which is the axis of the symmetry.

void	Mirror (const gp_Ax2 &A2)
	Performs the symmetrical transformation of a Geometry with respect to a plane. The axis placement A2 locates the plane of the symmetry : (Location, XDirection, YDirection).

void	Rotate (const gp_Ax1 &A1, const double Ang)
	Rotates a Geometry. A1 is the axis of the rotation. Ang is the angular value of the rotation in radians.

void	Scale (const gp_Pnt &P, const double S)
	Scales a Geometry. S is the scaling value.

void	Translate (const gp_Vec &V)
	Translates a Geometry. V is the vector of the translation.

void	Translate (const gp_Pnt &P1, const gp_Pnt &P2)
	Translates a Geometry from the point P1 to the point P2.

virtual void	Transform (const gp_Trsf &T)=0
	Transformation of a geometric object. This transformation can be a translation, a rotation, a symmetry, a scaling or a complex transformation obtained by combination of the previous elementaries transformations. (see class Transformation of the package Geom).

occ::handle< Geom_Geometry >	Mirrored (const gp_Pnt &P) const

occ::handle< Geom_Geometry >	Mirrored (const gp_Ax1 &A1) const

occ::handle< Geom_Geometry >	Mirrored (const gp_Ax2 &A2) const

occ::handle< Geom_Geometry >	Rotated (const gp_Ax1 &A1, const double Ang) const

occ::handle< Geom_Geometry >	Scaled (const gp_Pnt &P, const double S) const

occ::handle< Geom_Geometry >	Transformed (const gp_Trsf &T) const

occ::handle< Geom_Geometry >	Translated (const gp_Vec &V) const

occ::handle< Geom_Geometry >	Translated (const gp_Pnt &P1, const gp_Pnt &P2) const

virtual occ::handle< Geom_Geometry >	Copy () const =0
	Creates a new object which is a copy of this geometric object.

Public Member Functions inherited from Standard_Transient
	Standard_Transient ()
	Empty constructor.

	Standard_Transient (const Standard_Transient &)
	Copy constructor – does nothing.

Standard_Transient &	operator= (const Standard_Transient &)
	Assignment operator, needed to avoid copying reference counter.

virtual	~Standard_Transient ()=default
	Destructor must be virtual.

virtual const opencascade::handle< Standard_Type > &	DynamicType () const
	Returns a type descriptor about this object.

bool	IsInstance (const opencascade::handle< Standard_Type > &theType) const
	Returns a true value if this is an instance of Type.

bool	IsInstance (const char *const theTypeName) const
	Returns a true value if this is an instance of TypeName.

bool	IsKind (const opencascade::handle< Standard_Type > &theType) const
	Returns true if this is an instance of Type or an instance of any class that inherits from Type. Note that multiple inheritance is not supported by OCCT RTTI mechanism.

bool	IsKind (const char *const theTypeName) const
	Returns true if this is an instance of TypeName or an instance of any class that inherits from TypeName. Note that multiple inheritance is not supported by OCCT RTTI mechanism.

Standard_Transient *	This () const
	Returns non-const pointer to this object (like const_cast). For protection against creating handle to objects allocated in stack or call from constructor, it will raise exception Standard_ProgramError if reference counter is zero.

int	GetRefCount () const noexcept
	Get the reference counter of this object.

void	IncrementRefCounter () noexcept
	Increments the reference counter of this object. Uses relaxed memory ordering since incrementing only requires atomicity, not synchronization with other memory operations.

int	DecrementRefCounter () noexcept
	Decrements the reference counter of this object; returns the decremented value. Uses release ordering for the decrement to ensure all writes to the object are visible before the count reaches zero. An acquire fence is added only when the count reaches zero, ensuring proper synchronization before deletion. This is more efficient than using acq_rel for every decrement.

virtual void	Delete () const
	Memory deallocator for transient classes.

Static Public Member Functions inherited from Standard_Transient
static constexpr const char *	get_type_name ()
	Returns a type descriptor about this object.

static const opencascade::handle< Standard_Type > &	get_type_descriptor ()
	Returns type descriptor of Standard_Transient class.

Detailed Description

The root class for bounded surfaces in 3D space. A bounded surface is defined by a rectangle in its 2D parametric space, i.e.

its u parameter, which ranges between two finite values u0 and u1, referred to as "First u parameter" and "Last u parameter" respectively, and
its v parameter, which ranges between two finite values v0 and v1, referred to as "First v parameter" and the "Last v parameter" respectively. The surface is limited by four curves which are the boundaries of the surface:
its u0 and u1 isoparametric curves in the u parametric direction, and
its v0 and v1 isoparametric curves in the v parametric direction. A bounded surface is finite. The common behavior of all bounded surfaces is described by the Geom_Surface class. The Geom package provides three concrete implementations of bounded surfaces:
Geom_BezierSurface,
Geom_BSplineSurface, and
Geom_RectangularTrimmedSurface. The first two of these implement well known mathematical definitions of complex surfaces, the third trims a surface using four isoparametric curves, i.e. it limits the variation of its parameters to a rectangle in 2D parametric space.

The documentation for this class was generated from the following file:

Geom_BoundedSurface.hxx

Additional Inherited Members

Detailed Description