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176 lines
6.4 KiB
C++
176 lines
6.4 KiB
C++
/*=========================================================================
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Program: Visualization Toolkit
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Module: vtkBiQuadraticQuadraticWedge.h
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Copyright (c) Ken Martin, Will Schroeder, Bill Lorensen
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All rights reserved.
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See Copyright.txt or http://www.kitware.com/Copyright.htm for details.
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This software is distributed WITHOUT ANY WARRANTY; without even
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the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
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PURPOSE. See the above copyright notice for more information.
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=========================================================================*/
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/**
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* @class vtkBiQuadraticQuadraticWedge
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* @brief cell represents a parabolic, 18-node isoparametric wedge
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*
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* vtkBiQuadraticQuadraticWedge is a concrete implementation of vtkNonLinearCell to
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* represent a three-dimensional, 18-node isoparametric biquadratic
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* wedge. The interpolation is the standard finite element,
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* biquadratic-quadratic isoparametric shape function plus the linear functions.
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* The cell includes a mid-edge node. The
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* ordering of the 18 points defining the cell is point ids (0-5,6-15, 16-18)
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* where point ids 0-5 are the six corner vertices of the wedge; followed by
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* nine midedge nodes (6-15) and 3 center-face nodes. Note that these midedge
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* nodes correspond lie
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* on the edges defined by (0,1), (1,2), (2,0), (3,4), (4,5), (5,3), (0,3),
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* (1,4), (2,5), and the center-face nodes are laying in quads 16-(0,1,4,3),
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* 17-(1,2,5,4) and (2,0,3,5).
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*
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* @sa
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* vtkQuadraticEdge vtkQuadraticTriangle vtkQuadraticTetra
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* vtkQuadraticHexahedron vtkQuadraticQuad vtkQuadraticPyramid
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*
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* @par Thanks:
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* Thanks to Soeren Gebbert who developed this class and
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* integrated it into VTK 5.0.
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*/
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#ifndef vtkBiQuadraticQuadraticWedge_h
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#define vtkBiQuadraticQuadraticWedge_h
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#include "vtkCommonDataModelModule.h" // For export macro
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#include "vtkNonLinearCell.h"
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class vtkQuadraticEdge;
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class vtkBiQuadraticQuad;
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class vtkQuadraticTriangle;
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class vtkWedge;
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class vtkDoubleArray;
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class VTKCOMMONDATAMODEL_EXPORT vtkBiQuadraticQuadraticWedge : public vtkNonLinearCell
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{
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public:
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static vtkBiQuadraticQuadraticWedge *New ();
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vtkTypeMacro(vtkBiQuadraticQuadraticWedge,vtkNonLinearCell);
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void PrintSelf (ostream & os, vtkIndent indent) VTK_OVERRIDE;
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//@{
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/**
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* Implement the vtkCell API. See the vtkCell API for descriptions
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* of these methods.
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*/
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int GetCellType() VTK_OVERRIDE { return VTK_BIQUADRATIC_QUADRATIC_WEDGE; }
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int GetCellDimension() VTK_OVERRIDE { return 3; }
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int GetNumberOfEdges() VTK_OVERRIDE { return 9; }
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int GetNumberOfFaces() VTK_OVERRIDE { return 5; }
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vtkCell *GetEdge (int edgeId) VTK_OVERRIDE;
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vtkCell *GetFace (int faceId) VTK_OVERRIDE;
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//@}
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int CellBoundary (int subId, double pcoords[3], vtkIdList * pts) VTK_OVERRIDE;
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void Contour (double value, vtkDataArray * cellScalars,
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vtkIncrementalPointLocator * locator, vtkCellArray * verts,
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vtkCellArray * lines, vtkCellArray * polys,
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vtkPointData * inPd, vtkPointData * outPd, vtkCellData * inCd,
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vtkIdType cellId, vtkCellData * outCd) VTK_OVERRIDE;
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int EvaluatePosition (double x[3], double *closestPoint,
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int &subId, double pcoords[3], double &dist2,
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double *weights) VTK_OVERRIDE;
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void EvaluateLocation (int &subId, double pcoords[3], double x[3],
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double *weights) VTK_OVERRIDE;
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int Triangulate (int index, vtkIdList * ptIds, vtkPoints * pts) VTK_OVERRIDE;
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void Derivatives (int subId, double pcoords[3], double *values, int dim,
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double *derivs) VTK_OVERRIDE;
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double *GetParametricCoords () VTK_OVERRIDE;
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/**
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* Clip this quadratic Wedge using scalar value provided. Like
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* contouring, except that it cuts the hex to produce linear
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* tetrahedron.
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*/
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void Clip (double value, vtkDataArray * cellScalars,
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vtkIncrementalPointLocator * locator, vtkCellArray * tetras,
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vtkPointData * inPd, vtkPointData * outPd,
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vtkCellData * inCd, vtkIdType cellId, vtkCellData * outCd,
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int insideOut) VTK_OVERRIDE;
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/**
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* Line-edge intersection. Intersection has to occur within [0,1] parametric
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* coordinates and with specified tolerance.
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*/
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int IntersectWithLine (double p1[3], double p2[3], double tol, double &t,
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double x[3], double pcoords[3], int &subId) VTK_OVERRIDE;
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/**
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* Return the center of the quadratic wedge in parametric coordinates.
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*/
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int GetParametricCenter (double pcoords[3]) VTK_OVERRIDE;
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/**
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* @deprecated Replaced by vtkBiQuadraticQuadraticWedge::InterpolateFunctions as of VTK 5.2
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*/
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static void InterpolationFunctions (double pcoords[3], double weights[15]);
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/**
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* @deprecated Replaced by vtkBiQuadraticQuadraticWedge::InterpolateDerivs as of VTK 5.2
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*/
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static void InterpolationDerivs (double pcoords[3], double derivs[45]);
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//@{
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/**
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* Compute the interpolation functions/derivatives
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* (aka shape functions/derivatives)
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*/
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void InterpolateFunctions (double pcoords[3], double weights[15]) VTK_OVERRIDE
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{
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vtkBiQuadraticQuadraticWedge::InterpolationFunctions(pcoords,weights);
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}
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void InterpolateDerivs (double pcoords[3], double derivs[45]) VTK_OVERRIDE
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{
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vtkBiQuadraticQuadraticWedge::InterpolationDerivs(pcoords,derivs);
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}
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//@}
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//@{
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/**
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* Return the ids of the vertices defining edge/face (`edgeId`/`faceId').
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* Ids are related to the cell, not to the dataset.
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*/
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static int *GetEdgeArray(int edgeId);
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static int *GetFaceArray(int faceId);
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//@}
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/**
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* Given parametric coordinates compute inverse Jacobian transformation
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* matrix. Returns 9 elements of 3x3 inverse Jacobian plus interpolation
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* function derivatives.
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*/
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void JacobianInverse (double pcoords[3], double **inverse, double derivs[45]);
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protected:
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vtkBiQuadraticQuadraticWedge ();
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~vtkBiQuadraticQuadraticWedge () VTK_OVERRIDE;
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vtkQuadraticEdge *Edge;
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vtkQuadraticTriangle *TriangleFace;
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vtkBiQuadraticQuad *Face;
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vtkWedge *Wedge;
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vtkDoubleArray *Scalars; //used to avoid New/Delete in contouring/clipping
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private:
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vtkBiQuadraticQuadraticWedge (const vtkBiQuadraticQuadraticWedge &) VTK_DELETE_FUNCTION;
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void operator = (const vtkBiQuadraticQuadraticWedge &) VTK_DELETE_FUNCTION;
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};
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//----------------------------------------------------------------------------
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// Return the center of the quadratic wedge in parametric coordinates.
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inline int vtkBiQuadraticQuadraticWedge::GetParametricCenter(double pcoords[3])
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{
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pcoords[0] = pcoords[1] = 1./3;
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pcoords[2] = 0.5;
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return 0;
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}
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#endif
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