/usr/include/vtk-6.3/vtkParametricFunction.h is in libvtk6-dev 6.3.0+dfsg1-5.
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Program: Visualization Toolkit
Module: vtkParametricFunction.h
Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
All rights reserved.
See Copyright.txt or http://www.kitware.com/Copyright.htm for details.
This software is distributed WITHOUT ANY WARRANTY; without even
the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
PURPOSE. See the above copyright notice for more information.
=========================================================================*/
// .NAME vtkParametricFunction - abstract interface for parametric functions
// .SECTION Description
// vtkParametricFunction is an abstract interface for functions
// defined by parametric mapping i.e. f(u,v,w)->(x,y,z) where
// u_min <= u < u_max, v_min <= v < v_max, w_min <= w < w_max. (For
// notational convenience, we will write f(u)->x and assume that
// u means (u,v,w) and x means (x,y,z).)
//
// The interface contains the pure virtual function, Evaluate(), that
// generates a point and the derivatives at that point which are then used to
// construct the surface. A second pure virtual function, EvaluateScalar(),
// can be used to generate a scalar for the surface. Finally, the
// GetDimension() virtual function is used to differentiate 1D, 2D, and 3D
// parametric functions. Since this abstract class defines a pure virtual
// API, its subclasses must implement the pure virtual functions
// GetDimension(), Evaluate() and EvaluateScalar().
//
// This class has also methods for defining a range of parametric values (u,v,w).
//
// .SECTION Thanks
// Andrew Maclean andrew.amaclean@gmail.com for creating and contributing the
// class.
//
// .SECTION See Also
// vtkParametricFunctionSource - tessellates a parametric function
//
// Implementations of derived classes implementing non-orentable surfaces:
// vtkParametricBoy vtkParametricCrossCap vtkParametricFigure8Klein
// vtkParametricKlein vtkParametricMobius vtkParametricRoman
//
// Implementations of derived classes implementing orientable surfaces:
// vtkParametricConicSpiral vtkParametricDini vtkParametricEllipsoid
// vtkParametricEnneper vtkParametricRandomHills vtkParametricSuperEllipsoid
// vtkParametricSuperToroid vtkParametricTorus
//
#ifndef vtkParametricFunction_h
#define vtkParametricFunction_h
#include "vtkCommonComputationalGeometryModule.h" // For export macro
#include "vtkObject.h"
class VTKCOMMONCOMPUTATIONALGEOMETRY_EXPORT vtkParametricFunction : public vtkObject
{
public:
vtkTypeMacro(vtkParametricFunction, vtkObject);
void PrintSelf(ostream& os, vtkIndent indent);
// Description
// Return the dimension of parametric space. Depending on the dimension,
// then the (u,v,w) parameters and associated information (e.g., derivates)
// have meaning. For example, if the dimension of the function is one, then
// u[0] and Duvw[0...2] have meaning.
// This is a pure virtual function that must be instantiated in
// a derived class.
virtual int GetDimension() = 0;
// Description:
// Performs the mapping \$f(uvw)->(Pt,Duvw)\$f.
// This is a pure virtual function that must be instantiated in
// a derived class.
//
// uvw are the parameters, with u corresponding to uvw[0],
// v to uvw[1] and w to uvw[2] respectively. Pt is the returned Cartesian point,
// Duvw are the derivatives of this point with respect to u, v and w.
// Note that the first three values in Duvw are Du, the next three are Dv,
// and the final three are Dw. Du Dv Dw are the partial derivatives of the
// function at the point Pt with respect to u, v and w respectively.
virtual void Evaluate(double uvw[3], double Pt[3], double Duvw[9]) = 0;
// Description:
// Calculate a user defined scalar using one or all of uvw, Pt, Duvw.
// This is a pure virtual function that must be instantiated in
// a derived class.
//
// uvw are the parameters with Pt being the the cartesian point,
// Duvw are the derivatives of this point with respect to u, v, and w.
// Pt, Duvw are obtained from Evaluate().
virtual double EvaluateScalar(double uvw[3], double Pt[3], double Duvw[9]) = 0;
// Description:
// Set/Get the minimum u-value.
vtkSetMacro(MinimumU,double);
vtkGetMacro(MinimumU,double);
// Description:
// Set/Get the maximum u-value.
vtkSetMacro(MaximumU,double);
vtkGetMacro(MaximumU,double);
// Description:
// Set/Get the minimum v-value.
vtkSetMacro(MinimumV,double);
vtkGetMacro(MinimumV,double);
// Description:
// Set/Get the maximum v-value.
vtkSetMacro(MaximumV,double);
vtkGetMacro(MaximumV,double);
// Description:
// Set/Get the minimum w-value.
vtkSetMacro(MinimumW,double);
vtkGetMacro(MinimumW,double);
// Description:
// Set/Get the maximum w-value.
vtkSetMacro(MaximumW,double);
vtkGetMacro(MaximumW,double);
// Description:
// Set/Get the flag which joins the first triangle strip to the last one.
vtkSetClampMacro(JoinU,int,0,1);
vtkGetMacro(JoinU,int);
vtkBooleanMacro(JoinU,int);
// Description:
// Set/Get the flag which joins the the ends of the triangle strips.
vtkSetClampMacro(JoinV, int, 0, 1);
vtkGetMacro(JoinV, int);
vtkBooleanMacro(JoinV, int);
// Description:
// Set/Get the flag which joins the the ends of the triangle strips.
vtkSetClampMacro(JoinW, int, 0, 1);
vtkGetMacro(JoinW, int);
vtkBooleanMacro(JoinW, int);
// Description:
// Set/Get the flag which joins the first triangle strip to
// the last one with a twist.
// JoinU must also be set if this is set.
// Used when building some non-orientable surfaces.
vtkSetClampMacro(TwistU,int,0,1);
vtkGetMacro(TwistU,int);
vtkBooleanMacro(TwistU,int);
// Description:
// Set/Get the flag which joins the ends of the
// triangle strips with a twist.
// JoinV must also be set if this is set.
// Used when building some non-orientable surfaces.
vtkSetClampMacro(TwistV, int, 0, 1);
vtkGetMacro(TwistV, int);
vtkBooleanMacro(TwistV, int);
// Description:
// Set/Get the flag which joins the ends of the
// triangle strips with a twist.
// JoinW must also be set if this is set.
// Used when building some non-orientable surfaces.
vtkSetClampMacro(TwistW, int, 0, 1);
vtkGetMacro(TwistW, int);
vtkBooleanMacro(TwistW, int);
// Description:
// Set/Get the flag which determines the ordering of the the
// vertices forming the triangle strips. The ordering of the
// points being inserted into the triangle strip is important
// because it determines the direction of the normals for the
// lighting. If set, the ordering is clockwise, otherwise the
// ordering is anti-clockwise. Default is true (i.e. clockwise
// ordering).
vtkSetClampMacro(ClockwiseOrdering,int,0,1);
vtkGetMacro(ClockwiseOrdering,int);
vtkBooleanMacro(ClockwiseOrdering,int);
// Description:
// Set/Get the flag which determines whether derivatives are available
// from the parametric function (i.e., whether the Evaluate() method
// returns valid derivatives).
vtkSetClampMacro(DerivativesAvailable,int,0,1);
vtkGetMacro(DerivativesAvailable,int);
vtkBooleanMacro(DerivativesAvailable,int);
protected:
vtkParametricFunction();
virtual ~vtkParametricFunction();
// Variables
double MinimumU;
double MaximumU;
double MinimumV;
double MaximumV;
double MinimumW;
double MaximumW;
int JoinU;
int JoinV;
int JoinW;
int TwistU;
int TwistV;
int TwistW;
int ClockwiseOrdering;
int DerivativesAvailable;
private:
vtkParametricFunction(const vtkParametricFunction&); // Not implemented.
void operator=(const vtkParametricFunction&); // Not implemented.
};
#endif
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