Open CASCADE Technology 7.8.0
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Circular Blend Function to approximate by SweepApproximation from Approx. More...
#include <GeomFill_CircularBlendFunc.hxx>
Public Member Functions | |
GeomFill_CircularBlendFunc (const Handle< Adaptor3d_Curve > &Path, const Handle< Adaptor3d_Curve > &Curve1, const Handle< Adaptor3d_Curve > &Curve2, const Standard_Real Radius, const Standard_Boolean Polynomial=Standard_False) | |
Create a Blend with a constant radius with 2 guide-line. <FShape> sets the type of fillet surface. The – default value is Convert_TgtThetaOver2 (classical – nurbs – representation of circles). ChFi3d_QuasiAngular – corresponds to a nurbs representation of circles – which parameterisation matches the circle one. – ChFi3d_Polynomial corresponds to a polynomial – representation of circles. | |
virtual Standard_Boolean | D0 (const Standard_Real Param, const Standard_Real First, const Standard_Real Last, TColgp_Array1OfPnt &Poles, TColgp_Array1OfPnt2d &Poles2d, TColStd_Array1OfReal &Weigths) override |
compute the section for v = param | |
virtual Standard_Boolean | D1 (const Standard_Real Param, const Standard_Real First, const Standard_Real Last, TColgp_Array1OfPnt &Poles, TColgp_Array1OfVec &DPoles, TColgp_Array1OfPnt2d &Poles2d, TColgp_Array1OfVec2d &DPoles2d, TColStd_Array1OfReal &Weigths, TColStd_Array1OfReal &DWeigths) override |
compute the first derivative in v direction of the section for v = param | |
virtual Standard_Boolean | D2 (const Standard_Real Param, const Standard_Real First, const Standard_Real Last, TColgp_Array1OfPnt &Poles, TColgp_Array1OfVec &DPoles, TColgp_Array1OfVec &D2Poles, TColgp_Array1OfPnt2d &Poles2d, TColgp_Array1OfVec2d &DPoles2d, TColgp_Array1OfVec2d &D2Poles2d, TColStd_Array1OfReal &Weigths, TColStd_Array1OfReal &DWeigths, TColStd_Array1OfReal &D2Weigths) override |
compute the second derivative in v direction of the section for v = param | |
virtual Standard_Integer | Nb2dCurves () const override |
get the number of 2d curves to approximate. | |
virtual void | SectionShape (Standard_Integer &NbPoles, Standard_Integer &NbKnots, Standard_Integer &Degree) const override |
get the format of an section | |
virtual void | Knots (TColStd_Array1OfReal &TKnots) const override |
get the Knots of the section | |
virtual void | Mults (TColStd_Array1OfInteger &TMults) const override |
get the Multplicities of the section | |
virtual Standard_Boolean | IsRational () const override |
Returns if the section is rationnal or not. | |
virtual Standard_Integer | NbIntervals (const GeomAbs_Shape S) const override |
Returns the number of intervals for continuity | |
virtual void | Intervals (TColStd_Array1OfReal &T, const GeomAbs_Shape S) const override |
Stores in <T> the parameters bounding the intervals of continuity | |
virtual void | SetInterval (const Standard_Real First, const Standard_Real Last) override |
Sets the bounds of the parametric interval on the fonction This determines the derivatives in these values if the function is not Cn. | |
virtual void | GetTolerance (const Standard_Real BoundTol, const Standard_Real SurfTol, const Standard_Real AngleTol, TColStd_Array1OfReal &Tol3d) const override |
Returns the tolerance to reach in approximation to respecte BoundTol error at the Boundary AngleTol tangent error at the Boundary (in radian) SurfTol error inside the surface. | |
virtual void | SetTolerance (const Standard_Real Tol3d, const Standard_Real Tol2d) override |
Is usfull, if (me) have to be run numerical algorithme to perform D0, D1 or D2. | |
virtual gp_Pnt | BarycentreOfSurf () const override |
Get the barycentre of Surface. An very poor estimation is sufficient. This information is useful to perform well conditioned rational approximation. | |
virtual Standard_Real | MaximalSection () const override |
Returns the length of the maximum section. This information is useful to perform well conditioned rational approximation. | |
virtual void | GetMinimalWeight (TColStd_Array1OfReal &Weigths) const override |
Compute the minimal value of weight for each poles of all sections. This information is useful to perform well conditioned rational approximation. | |
Public Member Functions inherited from Approx_SweepFunction | |
virtual void | Resolution (const Standard_Integer Index, const Standard_Real Tol, Standard_Real &TolU, Standard_Real &TolV) const |
Returns the resolutions in the sub-space 2d <Index> This information is usfull to find an good tolerance in 2d approximation. | |
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 () |
Destructor must be virtual. | |
virtual const opencascade::handle< Standard_Type > & | DynamicType () const |
Returns a type descriptor about this object. | |
Standard_Boolean | IsInstance (const opencascade::handle< Standard_Type > &theType) const |
Returns a true value if this is an instance of Type. | |
Standard_Boolean | IsInstance (const Standard_CString theTypeName) const |
Returns a true value if this is an instance of TypeName. | |
Standard_Boolean | 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. | |
Standard_Boolean | IsKind (const Standard_CString 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. | |
Standard_Integer | GetRefCount () const noexcept |
Get the reference counter of this object. | |
void | IncrementRefCounter () noexcept |
Increments the reference counter of this object. | |
Standard_Integer | DecrementRefCounter () noexcept |
Decrements the reference counter of this object; returns the decremented value. | |
virtual void | Delete () const |
Memory deallocator for transient classes. | |
Additional Inherited Members | |
Public Types inherited from Standard_Transient | |
typedef void | base_type |
Returns a type descriptor about this object. | |
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. | |
Circular Blend Function to approximate by SweepApproximation from Approx.
GeomFill_CircularBlendFunc::GeomFill_CircularBlendFunc | ( | const Handle< Adaptor3d_Curve > & | Path, |
const Handle< Adaptor3d_Curve > & | Curve1, | ||
const Handle< Adaptor3d_Curve > & | Curve2, | ||
const Standard_Real | Radius, | ||
const Standard_Boolean | Polynomial = Standard_False |
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) |
Create a Blend with a constant radius with 2 guide-line. <FShape> sets the type of fillet surface. The – default value is Convert_TgtThetaOver2 (classical – nurbs – representation of circles). ChFi3d_QuasiAngular – corresponds to a nurbs representation of circles – which parameterisation matches the circle one. – ChFi3d_Polynomial corresponds to a polynomial – representation of circles.
Get the barycentre of Surface. An very poor estimation is sufficient. This information is useful to perform well conditioned rational approximation.
Reimplemented from Approx_SweepFunction.
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overridevirtual |
compute the section for v = param
Implements Approx_SweepFunction.
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overridevirtual |
compute the first derivative in v direction of the section for v = param
Reimplemented from Approx_SweepFunction.
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overridevirtual |
compute the second derivative in v direction of the section for v = param
Reimplemented from Approx_SweepFunction.
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overridevirtual |
Compute the minimal value of weight for each poles of all sections. This information is useful to perform well conditioned rational approximation.
Reimplemented from Approx_SweepFunction.
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overridevirtual |
Returns the tolerance to reach in approximation to respecte BoundTol error at the Boundary AngleTol tangent error at the Boundary (in radian) SurfTol error inside the surface.
Implements Approx_SweepFunction.
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overridevirtual |
Stores in <T> the parameters bounding the intervals of continuity .
The array must provide enough room to accommodate for the parameters. i.e. T.Length() > NbIntervals()
Implements Approx_SweepFunction.
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overridevirtual |
Returns if the section is rationnal or not.
Implements Approx_SweepFunction.
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overridevirtual |
get the Knots of the section
Implements Approx_SweepFunction.
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overridevirtual |
Returns the length of the maximum section. This information is useful to perform well conditioned rational approximation.
Reimplemented from Approx_SweepFunction.
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overridevirtual |
get the Multplicities of the section
Implements Approx_SweepFunction.
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overridevirtual |
get the number of 2d curves to approximate.
Implements Approx_SweepFunction.
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overridevirtual |
Returns the number of intervals for continuity . May be one if Continuity(me) >=
Implements Approx_SweepFunction.
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overridevirtual |
get the format of an section
Implements Approx_SweepFunction.
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overridevirtual |
Sets the bounds of the parametric interval on the fonction This determines the derivatives in these values if the function is not Cn.
Implements Approx_SweepFunction.
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overridevirtual |
Is usfull, if (me) have to be run numerical algorithme to perform D0, D1 or D2.
Implements Approx_SweepFunction.