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Program: Visualization Toolkit
Module: vtkOctreePointLocatorNode.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.
=========================================================================*/
/*----------------------------------------------------------------------------
Copyright (c) Sandia Corporation
See Copyright.txt or http://www.paraview.org/HTML/Copyright.html for details.
----------------------------------------------------------------------------*/
// .NAME vtkOctreePointLocatorNode - Octree node that has 8 children each of equal size
//
// .SECTION Description
// This class represents a single spatial region in a 3D axis octant
// partitioning. It is intended to work efficiently with the
// vtkOctreePointLocator and is not meant for general use. It is assumed
// the region bounds some set of points. The ordering of the children is
// (-x,-y,-z),(+x,-y,-z),(-x,+y,-z),(+x,+y,-z),(-x,-y,+z),(+x,-y,+z),
// (-x,+y,+z),(+x,+y,+z). The portion of the domain assigned to an
// octant is Min < x <= Max.
//
// .SECTION See Also
// vtkOctreePointLocator
#ifndef __vtkOctreePointLocatorNode_h
#define __vtkOctreePointLocatorNode_h
#include "vtkObject.h"
class vtkCell;
class vtkPlanesIntersection;
class VTK_FILTERING_EXPORT vtkOctreePointLocatorNode : public vtkObject
{
public:
vtkTypeMacro(vtkOctreePointLocatorNode, vtkObject);
void PrintSelf(ostream& os, vtkIndent indent);
static vtkOctreePointLocatorNode *New();
// Description:
// Set/Get the number of points contained in this region.
void SetNumberOfPoints(int numberOfPoints)
{
this->NumberOfPoints = numberOfPoints;
}
vtkGetMacro(NumberOfPoints, int);
// Description:
// Set/Get the bounds of the spatial region represented by this node.
// Caller allocates storage for 6-vector in GetBounds.
void SetBounds(double xMin, double xMax, double yMin,
double yMax, double zMin, double zMax);
void SetBounds(double b[6])
{
this->SetBounds(b[0], b[1], b[2], b[3], b[4], b[5]);
}
void GetBounds(double *b) const;
// Description:
// Set/Get the bounds of the points contained in this spatial region.
// This may be smaller than the bounds of the region itself.
// Caller allocates storage for 6-vector in GetDataBounds.
void SetDataBounds(double xMin, double xMax, double yMin,
double yMax, double zMin, double zMax);
void GetDataBounds(double *b) const;
//BTX
// Description:
// Get a pointer to the 3 bound minima (xmin, ymin and zmin) or the
// 3 bound maxima (xmax, ymax, zmax). Don't free this pointer.
vtkGetMacro(MinBounds, double*);
vtkGetMacro(MaxBounds, double*);
//ETX
// Description:
// Set the xmin, ymin and zmin value of the bounds of this region
void SetMinBounds(double minBounds[3])
{
this->MinBounds[0] = minBounds[0];
this->MinBounds[1] = minBounds[1];
this->MinBounds[2] = minBounds[2];
}
// Description:
// Set the xmax, ymax and zmax value of the bounds of this region
void SetMaxBounds(double maxBounds[3])
{
this->MaxBounds[0] = maxBounds[0];
this->MaxBounds[1] = maxBounds[1];
this->MaxBounds[2] = maxBounds[2];
}
//BTX
// Description:
// Get a pointer to the 3 data bound minima (xmin, ymin and zmin) or the
// 3 data bound maxima (xmax, ymax, zmax). Don't free this pointer.
vtkGetMacro(MinDataBounds, double*);
vtkGetMacro(MaxDataBounds, double*);
//ETX
// Description:
// Set the xmin, ymin and zmin value of the bounds of this
// data within this region.
void SetMinDataBounds(double minDataBounds[3])
{
this->MinDataBounds[0] = minDataBounds[0];
this->MinDataBounds[1] = minDataBounds[1];
this->MinDataBounds[2] = minDataBounds[2];
}
// Description:
// Set the xmax, ymax and zmax value of the bounds of this
// data within this region.
void SetMaxDataBounds(double maxDataBounds[3])
{
this->MaxDataBounds[0] = maxDataBounds[0];
this->MaxDataBounds[1] = maxDataBounds[1];
this->MaxDataBounds[2] = maxDataBounds[2];
}
// Description:
// Get the ID associated with the region described by this node. If
// this is not a leaf node, this value should be -1.
vtkGetMacro(ID, int);
// Description:
// If this node is not a leaf node, there are leaf nodes below it whose
// regions represent a partitioning of this region. The IDs of these
// leaf nodes form a contigous set. Get the first of the first point's
// ID that is contained in this node.
vtkGetMacro(MinID, int);
// Description:
// Add the 8 children.
void CreateChildNodes();
// Description:
// Delete the 8 children.
void DeleteChildNodes();
// Description:
// Get a pointer to the ith child of this node.
vtkOctreePointLocatorNode* GetChild(int i);
// Description:
// A vtkPlanesIntersection object represents a convex 3D region bounded
// by planes, and it is capable of computing intersections of
// boxes with itself. Return 1 if this spatial region intersects
// the spatial region described by the vtkPlanesIntersection object.
// Use the possibly smaller bounds of the points within the region
// if useDataBounds is non-zero.
int IntersectsRegion(vtkPlanesIntersection *pi, int useDataBounds);
// Description:
// Return 1 if this spatial region entirely contains the given point.
// Use the possibly smaller bounds of the points within the region
// if useDataBounds is non-zero.
int ContainsPoint(double x, double y, double z, int useDataBounds);
// Description:
// Calculate the distance squared from any point to the boundary of this
// region. Use the boundary of the points within the region if useDataBounds
// is non-zero.
double GetDistance2ToBoundary(double x, double y, double z,
vtkOctreePointLocatorNode* top, int useDataBounds);
// Description:
// Calculate the distance squared from any point to the boundary of this
// region. Use the boundary of the points within the region if useDataBounds
// is non-zero. Set boundaryPt to the point on the boundary.
double GetDistance2ToBoundary(double x, double y, double z,
double *boundaryPt, vtkOctreePointLocatorNode* top,
int useDataBounds);
// Description:
// Calculate the distance from the specified point (which is required to
// be inside this spatial region) to an interior boundary. An interior
// boundary is one that is not also an boundary of the entire space
// partitioned by the tree of vtkOctreePointLocatorNode's.
double GetDistance2ToInnerBoundary(double x, double y, double z,
vtkOctreePointLocatorNode* top);
// Description:
// Return the id of the suboctant that a given point is in.
// If CheckContainment is non-zero then it checks whether
// the point is in the actual bounding box of the suboctant,
// otherwise it only checks which octant the point is in
// that is created from the axis-aligned partitioning of
// the domain at this octant's center.
int GetSubOctantIndex(double* point, int CheckContainment);
// Description:
// Recursive function to compute ID, MinVal, MaxVal, and MinID.
// Parent is used for MinVal and MaxVal in the case that no
// points are in the leaf node.
void ComputeOctreeNodeInformation(vtkOctreePointLocatorNode* Parent,
int& NextLeafId, int & NextMinId,
float* coordinates);
protected:
vtkOctreePointLocatorNode();
~vtkOctreePointLocatorNode();
private:
double _GetDistance2ToBoundary(
double x, double y, double z, double *boundaryPt,
int innerBoundaryOnly, vtkOctreePointLocatorNode* top,
int useDataBounds);
// Description:
// The minimum coordinate location of the node.
double MinBounds[3];
// Description:
// The maximum coordinate location of the node.
double MaxBounds[3];
// Description:
// The minimum coordinate location of the points contained
// within this node.
double MinDataBounds[3];
// Description:
// The maximum coordinate location of the points contained
// within this node.
double MaxDataBounds[3];
// Description:
// Get the number of points associated with this octant.
// The octant does not have to be a leaf octant. For example,
// for the root octant NumberOfPoints is equal to the number
// of points in the dataset.
int NumberOfPoints;
// Description:
// A pointer to the 8 children of this node.
vtkOctreePointLocatorNode** Children;
// Description:
// The ID of this octant. If it is not a leaf octant then ID=-1.
int ID;
// Description:
// The minimum Id of the ordered points in this octant (note that
// this Id is different than the vtkIdType used for referencing
// the point in the data set.
int MinID;
vtkOctreePointLocatorNode(const vtkOctreePointLocatorNode&); // Not implemented
void operator=(const vtkOctreePointLocatorNode&); // Not implemented
};
#endif
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