/////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2002-2019, Open Design Alliance (the "Alliance"). // All rights reserved. // // This software and its documentation and related materials are owned by // the Alliance. The software may only be incorporated into application // programs owned by members of the Alliance, subject to a signed // Membership Agreement and Supplemental Software License Agreement with the // Alliance. The structure and organization of this software are the valuable // trade secrets of the Alliance and its suppliers. The software is also // protected by copyright law and international treaty provisions. Application // programs incorporating this software must include the following statement // with their copyright notices: // // This application incorporates Open Design Alliance software pursuant to a license // agreement with Open Design Alliance. // Open Design Alliance Copyright (C) 2002-2019 by Open Design Alliance. // All rights reserved. // // By use of this software, its documentation or related materials, you // acknowledge and accept the above terms. /////////////////////////////////////////////////////////////////////////////// #ifndef OD_GENURB3D_H #define OD_GENURB3D_H /*!DOM*/ class OdGeEllipArc3d; class OdGeLineSeg3d; class OdGePolyline3d; class OdGeKnotVector; class OdGeNurbCurve3dImpl; #include "Ge/GeSplineEnt3d.h" #include "OdPlatformSettings.h" #include "TD_PackPush.h" /** \details This class represents non-uniform rational B-splines (NURBS) in 3D space. Corresponding C++ library: TD_Ge \sa */ class GE_TOOLKIT_EXPORT OdGeNurbCurve3d : public OdGeSplineEnt3d { public: /** \details Default constructor for the OdGeNurbCurve3d class. \remarks With this constructor no actual data is stored in the object. */ OdGeNurbCurve3d(); /** \details Copy constructor for the OdGeNurbCurve3d class. \param source [in] Object to be copied. */ OdGeNurbCurve3d( const OdGeNurbCurve3d& source); /** \details Constructor for the OdGeNurbCurve3d class. \param degree [in] Degree of curve. \param knots [in] Knot vector. \param controlPoints [in] Array of 3D control points. \param isPeriodic [in] True if and only if this spline is to be periodic. \remarks High degree values make curve more flexible. For example degree 1 is used to define a polyline, degree 2 is used to define a nurb circle, etc. A knot vector defines a sequence of parameter values that determine where and how the control points affect the curve curve. The knot vector is a sequence of parameter values and divides the parametric space into intervals, usually called knot spans. Values of knot vector must be provided in ascending order, for example: (0, 0, 0, 1, 2, 3, 3, 3) can be valid while (0, 0, 2, 0, 3, 1, 3, 3) cannot be valid. The control points specify the placement of the curve and adjust its shape. The quantity of control points must be at least the degree + 1. If isPeriodic is false, then knots.length() must equal controlPoints.length() + degree + 1 If isPeriodic is true, then knots.length() must equal controlPoints.length(), the first and last controlPoints must be equal. */ OdGeNurbCurve3d( int degree, const OdGeKnotVector& knots, const OdGePoint3dArray& controlPoints, bool isPeriodic = false); /** \details Constructor for the OdGeNurbCurve3d class. \param degree [in] Degree of curve. \param knots [in] Knot vector. \param controlPoints [in] Array of 3D control points. \param weights [in] Array of 3D control points. \param isPeriodic [in] True if and only if the curve is periodic. \remarks High degree values make curve more flexible. For example degree 1 is used to define a polyline, degree 2 is used to define a nurb circle, etc. A knot vector defines a sequence of parameter values that determine where and how the control points affect the curve. The knot vector is a sequence of parameter values and divides the parametric space into intervals, usually called knot spans. Values of knot vector must be provided in ascending order, for example: (0, 0, 0, 1, 2, 3, 3, 3) can be valid while (0, 0, 2, 0, 3, 1, 3, 3) cannot be valid. Knot vector does not affect the form of the nurb curve, it only affects its parameterization. The control points specify the placement of the curve and adjust its shape. The quantity of control points must be at least the degree + 1. The closer the weight value is to zero, the closer the curve is to a straight line near the corresponding control point. If the weight increases, the curve pulls toward the corresponding control point. If the weight decreases, the curve pushes from the corresponding control point. If isPeriodic is false, then knots.length() must equal controlPoints.length() + degree + 1 If isPeriodic is true, then knots.length() must equal controlPoints.length(), the first and last controlPoints must be equal. */ OdGeNurbCurve3d( int degree, const OdGeKnotVector& knots, const OdGePoint3dArray& controlPoints, const OdGeDoubleArray& weights, bool isPeriodic = false); // TD Special /** \details Constructor for the OdGeNurbCurve3d class. \param degree [in] Degree of curve. \param knots [in] Knot vector. \param controlPoints [in] A pointer to an array of 3D control points. \param numControlPoints [in] A number of control points in the passed array. \param weights [in] Array of 3D control points. \param numWeights [in] A number of weight values in the passed array. \param isPeriodic [in] True if and only if the curve is periodic. \remarks High degree values make curve more flexible. For example degree 1 is used to define a polyline, degree 2 is used to define a nurb circle, etc. A knot vector defines a sequence of parameter values that determine where and how the control points affect the curve. The knot vector is a sequence of parameter values and divides the parametric space into intervals, usually called knot spans. Values of knot vector must be provided in ascending order, for example: (0, 0, 0, 1, 2, 3, 3, 3) can be valid while (0, 0, 2, 0, 3, 1, 3, 3) cannot be valid. Knot vector does not affect the form of the nurb curve, it only affects its parameterization. The control points specify the placement of the curve and adjust its shape. The quantity of control points must be at least the degree + 1. The closer the weight value is to zero, the closer the curve is to a straight line near the corresponding control point. If the weight increases, the curve pulls toward the corresponding control point. If the weight decreases, the curve pushes from the corresponding control point. If isPeriodic is false, then knots.length() must equal controlPoints.length() + degree + 1 If isPeriodic is true, then knots.length() must equal controlPoints.length(), the first and last controlPoints must be equal. */ OdGeNurbCurve3d( int degree, const OdGeKnotVector& knots, const OdGePoint3d* controlPoints, OdUInt32 numControlPoints, const double* weights, OdUInt32 numWeights, bool isPeriodic = false); // /** \details Constructor for the OdGeNurbCurve3d class. \param degree [in] Degree of curve. \param fitPolyline [in] Input polyline fit points of which are interpolated by the curve. \param isPeriodic [in] True if and only if the curve is periodic. \remarks Constructs a 3D spline by a degree and fit points provided by a polyline. If isPeriodic is true then the first and the last fitPoints from fitPolyLine must be identical. High degree values make curve more flexible. For example degree 1 is used to define a segment, degree 2 is used to define a nurb circle, etc. */ OdGeNurbCurve3d( int degree, const OdGePolyline3d& fitPolyline, bool isPeriodic = false); /** \details Constructor for the OdGeNurbCurve3d class. \param fitPoints [in] Array of points through which to fit the curve. \param startTangent [in] Input start tangent vector. \param endTangent [in] Input end tangent vector. \param startTangentDefined [in] Input flag indicating whether startTangent should be used. \param endTangentDefined [in] Input flag indicating whether endTangent should be used. \param fitTol [in] Tolerance to which the curve should approximate fitPoints. \remarks Constructs a 3D curve interpolating a given array of 3D points within given tolerance and having given derivatives at the start point and endpoint. If startTangentDefined is 0, then startTangent will be ignored and the constructor will compute the start tangent vector. The same is true for endTangentDefined. */ OdGeNurbCurve3d( const OdGePoint3dArray& fitPoints, const OdGeVector3d& startTangent, const OdGeVector3d& endTangent, bool startTangentDefined = true, bool endTangentDefined = true, const OdGeTol& fitTol = OdGeContext::gTol); /** \details Constructor for the OdGeNurbCurve3d class. \param fitPoints [in] Array of points through which to fit the curve. \param fitTolerance [in] Input maximal deviation of the curve from the fitPoints. \remarks Constructs a 3D curve interpolating a given array of 3D points within given tolerance. */ OdGeNurbCurve3d( const OdGePoint3dArray& fitPoints, const OdGeTol& fitTolerance = OdGeContext::gTol); /** \details Constructor for the OdGeNurbCurve3d class. \param fitPoints [in] Array of points through which to fit the curve. \param fitTangents [in] Input vectors interpolating the curve's derivatives at fitPoints. \param fitTolerance [in] Tolerance to which the curve should approximate fitPoints. \param isPeriodic [in] True if and only if the curve is periodic. \remarks Constructs a 3D curve interpolating a given array of 3D points within given tolerance. If isPeriodic is true, then the first and the last fitPoints must be identical. Same must be true for fitTangents. */ OdGeNurbCurve3d( const OdGePoint3dArray& fitPoints, const OdGeVector3dArray& fitTangents, const OdGeTol& fitTolerance = OdGeContext::gTol, bool isPeriodic = false); /** \details Constructor for the OdGeNurbCurve3d class. \param fitPoints [in] Array of points through which to fit the curve. \param startTangent [in] Input start tangent vector. \param endTangent [in] Input end tangent vector. \param startTangentDefined [in] Input flag indicating whether startTangent should be used. \param endTangentDefined [in] Input flag indicating whether endTangent should be used. \param knotParam [in] knot parameterization which defines the knot values. \param fitTolerance [in] Tolerance to which the curve should approximate fitPoints. \remarks Constructs a 3D curve interpolating a given array of 3D points within given tolerance and having given derivatives at the start point and endpoint. If startTangentDefined is 0, then startTangent will be ignored and the constructor will compute the start tangent vector. The same is true for endTangentDefined. If fitTolerance is not 0, then the constructed spline may not pass through the fit points, but the maximum distance from any fit point to the constructed spline will be no greater than fitTolerance. */ OdGeNurbCurve3d( const OdGePoint3dArray& fitPoints, const OdGeVector3d& startTangent, const OdGeVector3d& endTangent, bool startTangentDefined, bool endTangentDefined, OdGeKnotParameterization knotParam, const OdGeTol& fitTolerance = OdGeContext::gTol); // numSpans - the number of knot spans in nurbs curve // if numSpans == 0 (default) it is automatically calculated from // ellipse domain /** \details Constructor for the OdGeNurbCurve3d class. \param ellipse [in] Input elliptic arc from which nurb curve is constructed. \param numSpans [in] The number of knot spans in nurb curve. \remarks Constructs curve geometrically identical to an elliptic arc. If numSpans == 0 (default) it is automatically calculated from ellipse domain. */ OdGeNurbCurve3d( const OdGeEllipArc3d& ellipse, int numSpans = 0); /** \details Constructor for the OdGeNurbCurve3d class. \param lineSeg [in] Input line segment from which nurb curve is constructed. \remarks Constructs curve geometrically identical to a line segment. */ OdGeNurbCurve3d( const OdGeLineSeg3d& lineSeg); /** \details Returns the number of fit points. */ int numFitPoints() const; /** \details Gets the knot parametrization of the spline created with fit points and returns true if successful. \param knotParam [out] Receives the knot parametrization. */ bool getFitKnotParameterization(OdGeKnotParameterization& knotParam) const; /** \details Returns true if and only if 0 <= index < numFitPoints(), and returns the fit point at the specified index. \param fitPointIndex [in] Fit point index. \param point [out] Receives the fit point. */ bool getFitPointAt( int fitPointIndex, OdGePoint3d& point) const; /** \details Returns true if and only if this spline was constructed with fit points, and gets the fit tolerance that is used to construct this spline. \param fitTolerance [out] Recieves the geometric tolerance. */ bool getFitTolerance( OdGeTol& fitTolerance) const; /** \details Returns true if and only if this spline was constructed with fit data, and returns the starting and ending tangents. \param startTangent [out] Receives the starting tangent \param endTangent [out] Receives the ending tangent. */ bool getFitTangents( OdGeVector3d& startTangent, OdGeVector3d& endTangent) const; /** \details Returns true if and only if this spline was constructed with fit data, and returns the starting and ending tangents. \param startTangent [out] Receives the starting tangent \param endTangent [out] Receives the ending tangent. \param startTangentDefined [out] Receives the if true, startTangent was used. \param endTangentDefined [out] Receives the if true, endTangent was used. */ bool getFitTangents( OdGeVector3d& startTangent, OdGeVector3d& endTangent, bool& startTangentDefined, bool& endTangentDefined) const; /** \details Returns true if and only if this spline was constructed with fit data, and returns all the fit data used to construct this spline. \param fitPoints [out] Receives the onterpolation points. \param fitTolerance [out] Receives the geometric tolerance. \param tangentsExist [out] Receives true if and only if tangents were used in constructing this spline. \param startTangent [out] Receives the starting tangent \param endTangent [out] Receives the ending tangent. \remarks startTangent and endTangent are meaningful if and only if tangentsExist == true. */ bool getFitData( OdGePoint3dArray& fitPoints, OdGeTol& fitTolerance, bool& tangentsExist, OdGeVector3d& startTangent, OdGeVector3d& endTangent) const; /** \details Returns true if and only if this spline was constructed with fit data, and returns all the fit data used to construct this spline. \param fitPoints [out] Receives the interpolation points. \param fitTolerance [out] Receives the geometric tolerance. \param tangentsExist [out] Receives true if and only if tangents were used in constructing this spline. \param startTangent [out] Receives the starting tangent \param endTangent [out] Receives the ending tangent. \param knotParam [out] Receives the knot parameterization. \remarks startTangent and endTangent are meaningful if and only if tangentsExist == true. */ bool getFitData( OdGePoint3dArray& fitPoints, OdGeTol& fitTolerance, bool& tangentsExist, OdGeVector3d& startTangent, OdGeVector3d& endTangent, OdGeKnotParameterization& knotParam) const; // NURBS data query functions /** \details Returns the data used to define this spline. \param degree [out] Receives the degree of spline. \param periodic [out] Receives true if and only if this spline is periodic. \param rational [out] Receives true if and only if this spline is rational. \param knots [out] Receives the knot vector. \param controlPoints [out] Receives an array of 3D control points. \param weights [out] Receives an array of weights \remarks High degree values represent flexible curves. For example degree 1 is used to define a polyline, degree 2 is used to define a nurb circle, etc. A knot vector defines a sequence of parameter values that determine where and how the control points affect the curve. The knot vector is a sequence of parameter values and divides the parametric space into intervals, usually called knot spans. Values of knot vector must be provided in ascending order, for example: (0, 0, 0, 1, 2, 3, 3, 3) can be valid while (0, 0, 2, 0, 3, 1, 3, 3) cannot be valid. Knot vector does not affect the form of the nurb curve, it only affects its parameterization. The control points specify the placement of the curve and adjust its shape. The quantity of control points must be at least the degree + 1. The closer the weight value is to zero, the closer the curve is to a straight line near the corresponding control point. If the weight increases, the curve pulls toward the corresponding control point. If the weight decreases, the curve pushes from the corresponding control point. The weights array will be empty if the spline is not rational. */ void getDefinitionData( int& degree, bool& rational, bool& periodic, OdGeKnotVector& knots, OdGePoint3dArray& controlPoints, OdGeDoubleArray& weights) const; /** \details Returns the number of weights in the spline. \remarks Returns numCurves() if this spline is rational, 0 if it is not. */ int numWeights() const; /** \details Returns the weight at the specified index. \param weightIndex [in] Weight index. */ double weightAt( int weightIndex) const; /** \details Returns the current evaluation mode. \remarks If the method returns false, there is no optimization of an internal evaluator. This mode generally should be used if only one or two values per interval between two consecutive knots are evaluated. If the method returns true, then the evaluator optimization is turned on. This provides better performance if three or more values per knot interval are computed. */ bool evalMode() const; /** \remarks Currently not implemented. */ bool getParamsOfC1Discontinuity( OdGeDoubleArray& params, const OdGeTol& tol = OdGeContext::gTol) const; /** \remarks Currently not implemented. */ bool getParamsOfG1Discontinuity( OdGeDoubleArray& params, const OdGeTol& tol = OdGeContext::gTol) const; // Fit data edit functions /** \details Sets the fit point at the specified index. \param fitPointIndex [in] Fit point index. \param point [in] Fit point. \returns Returns true if the fit point has successfully been set and false otherwise. */ bool setFitPointAt( int fitPointIndex, const OdGePoint3d& point); /** \details Returns true if and only if this spline was created with fit data, and inserts the fit point at the specified index. \param fitPointIndex [in] Fit point index. \param point [in] Fit point. */ bool addFitPointAt( int fitPointIndex, const OdGePoint3d& point); /** \details Adds a control point at the specified knot. \param newKnot [in] The knot parameter to add the control point at. \param point [in] Coordinates of the control point to be added. \param weight [in] The weight to be assigned to the control point. \remarks When called for a non-rational spline, weight is ignored. \returns Returns true if the control point has successfully been added and false otherwise. */ bool addControlPointAt(double newKnot, const OdGePoint3d& point, double weight = 1.0); /** \details Deletes a control point at the specified index. \param index [in] The index of the control point to be deleted. \returns Returns true if the control point has successfully been deleted and false otherwise. */ bool deleteControlPointAt(int index); /** \details Removes a fit point with the specified index. The index must be greater than or equal to 0 and less than or equal to the number of fit points. \param index [in] The index of fit point that is to be removed. \returns Returns true if the fit point is successfully deleted and false otherwise. */ bool deleteFitPointAt( int fitPointIndex); /** \details Sets the specified knot parameterization if the spline is created by fit points and returns true if the knot parameterization has successfully been set. \param knotParam [in] The knot parameterization to be set. */ bool setFitKnotParameterization(OdGeKnotParameterization knotParam); /** \details Sets the fit tolerance that is used for interpolating fit points. \param fitTol [in] Geometric tolerance. \returns Returns true if and only if this spline was constructed with fit data. */ bool setFitTolerance( const OdGeTol& fitTol = OdGeContext::gTol); /** \details Sets the fit tangents for this spline. \param startTangent [in] Starting tangent. \param endTangent [in] Ending tangent. \returns Returns true if and only if this spline was constructed with fit data. */ bool setFitTangents( const OdGeVector3d& startTangent, const OdGeVector3d& endTangent); /** \details Sets the fit tangents for this spline. \param startTangent [in] Starting tangent. \param endTangent [in] Ending tangent. \param startTangentDefined [in] Defines if the specified value of starting tangent is to be used. \param endTangentDefined [in] Defines if the specified value of starting tangent is to be used. \returns Returns true if and only if this spline was constructed with fit data. */ bool setFitTangents( const OdGeVector3d& startTangent, const OdGeVector3d& endTangent, bool startTangentDefined, bool endTangentDefined); /** \details Sets the fit data for this spline. \param fitPoints [in] Interpolation points. \param fitTol [in] Geometric tolerance. \param startTangent [in] Starting tangent. \param endTangent [in] Ending tangent. */ OdGeNurbCurve3d& setFitData( const OdGePoint3dArray& fitPoints, const OdGeVector3d& startTangent, const OdGeVector3d& endTangent, const OdGeTol& fitTol = OdGeContext::gTol); /** \details Sets the fit data for this spline. \param fitKnots [in] Fit knots. \param fitPoints [in] Interpolation points. \param startTangent [in] Starting tangent. \param endTangent [in] Ending tangent. \param fitTol [in] Geometric tolerance. \param isPeriodic [in] True if and only if this spline is to be periodic. \remarks Recomputes the spline from the input fit points, start and end tangents, and fit tolerance. The first parameter specifies the knot vector for the new spline. If fitTol is not 0, then the constructed spline may not pass through the fit points but the maximum distance from any fit point to the constructed spline will be no greater than fitTol. */ OdGeNurbCurve3d& setFitData( const OdGeKnotVector& fitKnots, const OdGePoint3dArray& fitPoints, const OdGeVector3d& startTangent, const OdGeVector3d& endTangent, const OdGeTol& fitTol = OdGeContext::gTol, bool isPeriodic = false); /** \details Sets the fit data for this spline. \param degree [in] Degree of curve. \param fitPoints [in] Interpolation points. \param fitTol [in] Geometric tolerance. \remarks High degree values make curve more flexible. For example degree 1 is used to define a polyline, degree 2 is used to define a nurb circle, etc. */ OdGeNurbCurve3d& setFitData( int degree, const OdGePoint3dArray& fitPoints, const OdGeTol& fitTol = OdGeContext::gTol); /** \details Sets the fit data for this spline. \param fitPoints [in] Interpolation points. \param startTangent [in] Starting tangent. \param endTangent [in] Ending tangent. \param knotParam [in] The knot parameterization method to be set. \param fitTol [in] Geometric tolerance. \remarks Replaces any existing spline data (fit or NURBS) with the fit data fitPoints, startTangent, endTangent, knot parameterization, fitTolerance. fitPoints must contain 2 or more points. */ OdGeNurbCurve3d& setFitData( const OdGePoint3dArray& fitPoints, const OdGeVector3d& startTangent, const OdGeVector3d& endTangent, OdGeKnotParameterization knotParam, const OdGeTol& fitTol = OdGeContext::gTol); /** \details Purges the fit data defining this spline. \remarks The fit data consists of the fit points, fit tolerance, start tangent, and end tangent. */ bool purgeFitData(); /** \details Adds new knot to the spline knot array and returns reference to this spline object. \param newKnot [in] New knot. */ OdGeNurbCurve3d& addKnot(double newKnot); /** \details Inserts new knot to the spline knot array and returns reference to this spline object. If there is already such knot, then the multiplicity of the knot is increased by 1. \param newKnot [in] New knot. */ OdGeNurbCurve3d& insertKnot(double newKnot); /** \details Sets the weight at the specified index. \param fitPointIndex [in] Fit point index. \param weight [in] Weight at the specified fit point. */ OdGeSplineEnt3d& setWeightAt( int fitPointIndex, double weight); /** \details Sets the evaluation mode. \param evalMode [in] Input state of the evaluation mode. \remarks Sets the state of the evaluation mode in order to turn the internal optimization on or off. */ OdGeNurbCurve3d& setEvalMode( bool evalMode = false); /** \details Joins the specified spline with this spline and returns a reference to the recomputed spline. Both splines must be open and the start point of the input spline must be equal to the endpoint of the initial spline. \param curve [in] Spline to be joined with this spline. */ OdGeNurbCurve3d& joinWith( const OdGeNurbCurve3d& curve, const OdGeTol &iTolerance = OdGeContext::gTol); /** \details Trims the spline by the new start and end parameters, and returns a reference to the recalculated spline. \param newStartParam [in] New start parameter. \param newEndParam [in] New end parameter. */ OdGeNurbCurve3d& hardTrimByParams( double newStartParam, double newEndParam); /** \details Makes this spline rational (if it is not), and returns a reference to this spline. \param weight [in] Weight to be applied to each control point. \remarks If this spline was already rational, the weight at each control point is multiplied by the specified weight. */ OdGeNurbCurve3d& makeRational( double weight = 1.0); /** \details Makes the opened spline closed, and returns a reference to this spline. Closed spline is made by creating a smooth spline between the first and the end points and joining it with the initial spline. \remarks If this spline is already closed, then the method does nothing. */ OdGeNurbCurve3d& makeClosed(); /** \details Makes non-periodic spline periodic. \remarks Currently not implemented. */ OdGeNurbCurve3d& makePeriodic(); /** \details Makes periodic spline non-periodic. \remarks Currently not implemented. */ OdGeNurbCurve3d& makeNonPeriodic(); /** \details Makes closed spline open. \remarks Currently not implemented. */ OdGeNurbCurve3d& makeOpen(); /** \details Increases spline degree by the specified value and returns a reference to this spline object. \param plusDegree [in] Degree increment value. */ OdGeNurbCurve3d& elevateDegree(int plusDegree); /** \details Assignment operator for the OdGeNurbCurve3d object. */ OdGeNurbCurve3d& operator =( const OdGeNurbCurve3d& spline); /////////////////////////////////////////////////////////////////////////// // TD Special : TD_USING(OdGeSplineEnt3d::evalPoint); // This is only for internal use //DOM-IGNORE-BEGIN OdGePoint3d evalPoint( double param, int hint) const; // This is need in surface (for rational case only) void evalPointDivider( double param, OdGePoint3d& point, double& divider, int hint) const; //DOM-IGNORE-BEGIN // NURBS data edit functions /** \details Sets the parameters for this spline according to the arguments. \param degree [in] Degree of spline. \param knots [in] Knot vector. \param controlPoints [in] Array of 3D control points. \param weights [in] Array of weights \param isPeriodic [in] True if and only if this spline is to be periodic. \remarks High degree values make curve more flexible. For example degree 1 is used to define a polyline, degree 2 is used to define a nurb circle, etc. A knot vector defines a sequence of parameter values that determine where and how the control points affect the curve curve. The knot vector is a sequence of parameter values and divides the parametric space into intervals, usually called knot spans. Values of knot vector must be provided in ascending order, for example: (0, 0, 0, 1, 2, 3, 3, 3) can be valid while (0, 0, 2, 0, 3, 1, 3, 3) cannot be valid. Knot vector does not affect the form of the nurb curve, it only affects its parameterization. The control points specify the placement of the curve and adjust its shape. A rational spline is constructed, and controlPoints.length() must equal weights.length() If isPeriodic is false, then knots.length() must equal controlPoints.length() + degree + 1 If isPeriodic is true, then knots.length() must equal controlPoints.length(), the first and last controlPoints must be equal and the first and last weights (if provided) must be equal. */ void set( int degree, const OdGeKnotVector& knots, const OdGePoint3dArray& controlPoints, const OdGeDoubleArray& weights, bool isPeriodic = false); /** \details Calculates fit data for the spline constructed by control points. \remarks Currently the method calculates fit data only for NURB curves of degree less than or equal to three. \returns Returns true if and only if fit data have successfully been calculated. */ bool buildFitData(OdGeKnotParameterization knotParam = OdGe::kChord); /** \details Converts source curve to spline with given tolerance and parametrization settings. Returns raw pointer to converted spline or null pointer if conversion failed. \param source [in] Source curve to convert. \param domain [in] Interval of source curve to convert. \param tol [in] Accuracy of conversion. \param sameParametrization [in] Necessity of parametrization preserving during conversion. \returns Returns raw pointer to converted spline or null pointer if conversion failed. \remarks * If source curve already is spline, a copy is returned. * If provided null-pointer to source curve or curve has no analytic representation, a null-pointer is returned */ static OdGeNurbCurve3d* convertFrom(const OdGeCurve3d* source, const OdGeInterval& domain, const OdGeTol& tol = OdGeContext::gTol, bool sameParametrization = false); /** \details Converts source curve to spline with given tolerance and parametrization settings in native range of source curve. \param source [in] Source curve to convert. \param tol [in] Accuracy of conversion. \param sameParametrization [in] Necessity of parametrization preserving during conversion. \returns Returns raw pointer to converted spline or null pointer if conversion failed. \remarks * If source curve already is spline, a copy is returned. * If provided null-pointer to source curve or curve has no analytic representation, a null-pointer is returned */ static OdGeNurbCurve3d* convertFrom(const OdGeCurve3d* source, const OdGeTol& tol = OdGeContext::gTol, bool sameParametrization = false); //DOM-IGNORE-BEGIN protected: /** \details Modifies the position and tangent of the point with a specified parameter. \param param [in] Parameter value of the point. \param point [in] New position of the point. \param deriv [in] New value of the tangent vector at the point. \returns Returns true if and only if the point has successfully been adjusted. */ bool modifyPositionAndTangent(double param, const OdGePoint3d& point, const OdGeVector3d* deriv); void makeClosedFit(); protected: void setData(int degree, const OdGePoint3dArray& controlPoints, const OdGeKnotVector& knots, const OdGeDoubleArray& weights , const OdGePoint3dArray& fitPoints, const OdGeVector3d& startTangent, const OdGeVector3d& endTangent , bool isStartTangentDefined, bool isEndTangentDefined, bool isPeriodic, const OdGeTol& fitTol); void setKnotTolerance(double tol); //DOM-IGNORE-END }; #include "TD_PackPop.h" #endif // OD_GENURB3D_H