FreeMat
vtkOctreePointLocatorNode

Section: Visualization Toolkit Filtering Classes

Usage

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.

To create an instance of class vtkOctreePointLocatorNode, simply invoke its constructor as follows

  obj = vtkOctreePointLocatorNode

Methods

The class vtkOctreePointLocatorNode has several methods that can be used. They are listed below. Note that the documentation is translated automatically from the VTK sources, and may not be completely intelligible. When in doubt, consult the VTK website. In the methods listed below, obj is an instance of the vtkOctreePointLocatorNode class.

  • string = obj.GetClassName ()
  • int = obj.IsA (string name)
  • vtkOctreePointLocatorNode = obj.NewInstance ()
  • vtkOctreePointLocatorNode = obj.SafeDownCast (vtkObject o)
  • obj.SetNumberOfPoints (int numberOfPoints) - Set/Get the number of points contained in this region.
  • int = obj.GetNumberOfPoints () - Set/Get the number of points contained in this region.
  • obj.SetBounds (double xMin, double xMax, double yMin, double yMax, double zMin, double zMax) - Set/Get the bounds of the spatial region represented by this node. Caller allocates storage for 6-vector in GetBounds.
  • obj.SetBounds (double b[6]) - Set/Get the bounds of the spatial region represented by this node. Caller allocates storage for 6-vector in GetBounds.
  • obj.GetBounds (double b) const - Set/Get the bounds of the spatial region represented by this node. Caller allocates storage for 6-vector in GetBounds.
  • obj.SetDataBounds (double xMin, double xMax, double yMin, double yMax, double zMin, double zMax) - 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.
  • obj.GetDataBounds (double b) const - 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.
  • obj.SetMinBounds (double minBounds[3]) - Set the xmax, ymax and zmax value of the bounds of this region
  • obj.SetMaxBounds (double maxBounds[3]) - Set the xmin, ymin and zmin value of the bounds of this data within this region.
  • obj.SetMinDataBounds (double minDataBounds[3]) - Set the xmax, ymax and zmax value of the bounds of this data within this region.
  • obj.SetMaxDataBounds (double maxDataBounds[3]) - Get the ID associated with the region described by this node. If this is not a leaf node, this value should be -1.
  • int = obj.GetID () - Get the ID associated with the region described by this node. If this is not a leaf node, this value should be -1.
  • int = obj.GetMinID () - 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.
  • obj.CreateChildNodes () - Add the 8 children.
  • obj.DeleteChildNodes () - Delete the 8 children.
  • vtkOctreePointLocatorNode = obj.GetChild (int i) - Get a pointer to the ith child of this node.
  • int = obj.IntersectsRegion (vtkPlanesIntersection pi, int useDataBounds) - 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 = obj.ContainsPoint (double x, double y, double z, int useDataBounds) - 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.
  • double = obj.GetDistance2ToBoundary (double x, double y, double z, vtkOctreePointLocatorNode top, int useDataBounds) - 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 = obj.GetDistance2ToBoundary (double x, double y, double z, double boundaryPt, vtkOctreePointLocatorNode top, int useDataBounds) - 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 = obj.GetDistance2ToInnerBoundary (double x, double y, double z, vtkOctreePointLocatorNode top) - 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.
  • int = obj.GetSubOctantIndex (double point, int CheckContainment) - 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.