OTS2DSet.java
package org.opentrafficsim.core.geometry;
import java.awt.geom.Rectangle2D;
import java.io.Serializable;
import java.util.Collection;
import java.util.HashSet;
import java.util.Iterator;
import java.util.Set;
import org.djutils.exceptions.Throw;
import com.vividsolutions.jts.geom.Envelope;
import nl.tudelft.simulation.dsol.logger.SimLogger;
/**
* Set of OTSShape objects and provides methods for fast selection of those objects that intersect an OTSShape. <br>
* An OTS2DSet internally stores the OTSShapes in a quad tree. At time of construction the minimum cell size is defined. Node
* expansion is never performed on nodes that are smaller than this limit. <br>
* Each node (even the non-leaf nodes) store a set of OTSShape. Non-leaf nodes locally store those shapes that completely cover
* the rectangular area of the node. Such shapes are <b>not</b> also stored in leaf nodes below that node. OTSShapes that
* partially cover a non-leaf node are stored in each of the leaf nodes below that node that those OTSShapes (partially) cover.
* Leaf nodes that cannot be expanded (because they are too small) also store all OTSShapes that partially cover the area of the
* node. <br>
* If removal of an OTSShape objects results in a leaf becoming empty, that leaf is removed from its parent (which may then
* itself become empty and removed in turn).
* <p>
* Copyright (c) 2013-2019 Delft University of Technology, PO Box 5, 2600 AA, Delft, the Netherlands. All rights reserved. <br>
* BSD-style license. See <a href="http://opentrafficsim.org/docs/current/license.html">OpenTrafficSim License</a>.
* <p>
* @version $Revision$, $LastChangedDate$, by $Author$, initial version Jun 20, 2016 <br>
* @author <a href="http://www.tbm.tudelft.nl/averbraeck">Alexander Verbraeck</a>
* @author <a href="http://www.tudelft.nl/pknoppers">Peter Knoppers</a>
* @author <a href="http://www.transport.citg.tudelft.nl">Wouter Schakel</a>
*/
public class OTS2DSet implements Set<OTSShape>, Serializable
{
/** */
private static final long serialVersionUID = 20170400L;
/** Set of all shapes used for iterators, etc. */
private final Set<OTSShape> allShapes = new HashSet<OTSShape>();
/** How fine will this quad tree divide. This one is copied to each sub-node which is somewhat inefficient. */
private final double minimumCellSize;
/** Spatial storage for the OTSShapes. */
private QuadTreeNode quadTree;
/**
* Construct an empty OTS2DSet for a rectangular region. Objects that do not intersect this region will never be stored in
* this OTS2DSet. (Trying to add such an OTSShape is <b>not</b> an error; the <code>add</code> method will return false,
* indicating that the set has not been modified.)
* @param boundingBox Rectangle2D; the region
* @param minimumCellSize double; resolution of the underlying quad tree
* @throws OTSGeometryException when the bounding box covers no surface
*/
public OTS2DSet(final Rectangle2D boundingBox, final double minimumCellSize) throws OTSGeometryException
{
Throw.when(null == boundingBox, NullPointerException.class, "The boundingBox may not be null");
Throw.when(boundingBox.getWidth() <= 0 || boundingBox.getHeight() <= 0, OTSGeometryException.class,
"The boundingBox must have nonzero surface (got %s", boundingBox);
Throw.when(minimumCellSize <= 0, OTSGeometryException.class, "The minimumCellSize must be > 0 (got %f)",
minimumCellSize);
this.quadTree = new QuadTreeNode(boundingBox);
this.minimumCellSize = minimumCellSize;
}
/** {@inheritDoc} */
@Override
public final int size()
{
return this.allShapes.size();
}
/** {@inheritDoc} */
@Override
public final boolean isEmpty()
{
return this.allShapes.isEmpty();
}
/** {@inheritDoc} */
@Override
public final boolean contains(final Object o)
{
return this.allShapes.contains(o);
}
/** {@inheritDoc} */
@Override
public final Iterator<OTSShape> iterator()
{
return new QuadTreeIterator();
}
/** {@inheritDoc} */
@Override
public final Object[] toArray()
{
return this.allShapes.toArray();
}
/** {@inheritDoc} */
@Override
public final <T> T[] toArray(final T[] a)
{
return this.allShapes.toArray(a);
}
/** {@inheritDoc} */
@Override
public final boolean add(final OTSShape e)
{
if (!this.quadTree.intersects(e))
{
return false;
}
if (this.allShapes.contains(e))
{
return false;
}
if (!this.quadTree.add(e))
{
SimLogger.always().error("add: ERROR object could not be added to the quad tree");
}
return this.allShapes.add(e);
}
/** {@inheritDoc} */
@Override
public final boolean remove(final Object o)
{
if (!this.allShapes.remove(o))
{
return false;
}
if (!this.quadTree.remove((OTSShape) o))
{
SimLogger.always().error("remove: ERROR object could not be removed from the quad tree");
}
return true;
}
/** {@inheritDoc} */
@Override
public final boolean containsAll(final Collection<?> c)
{
for (Object o : c)
{
if (!contains(o))
{
return false;
}
}
return true;
}
/** {@inheritDoc} */
@Override
public final boolean addAll(final Collection<? extends OTSShape> c)
{
boolean result = false;
for (OTSShape s : c)
{
if (add(s))
{
result = true;
}
}
return result;
}
/** {@inheritDoc} */
@Override
public final boolean retainAll(final Collection<?> c)
{
boolean result = false;
for (Iterator<OTSShape> it = iterator(); it.hasNext();)
{
OTSShape shape = it.next();
if (!c.contains(shape))
{
it.remove();
result = true;
}
}
return result;
}
/** {@inheritDoc} */
@Override
public final boolean removeAll(final Collection<?> c)
{
boolean result = false;
for (Iterator<OTSShape> it = iterator(); it.hasNext();)
{
OTSShape shape = it.next();
if (c.contains(shape))
{
it.remove();
result = true;
}
}
return result;
}
/** {@inheritDoc} */
@Override
public final void clear()
{
this.quadTree.clear();
this.allShapes.clear();
}
/**
* Return the set of all shapes in this OTS2DSet that intersect the given rectangle.
* @param rectangle Rectangle2D; the rectangle
* @return Set<OTSShape>; the shapes that intersect the rectangle
*/
public final Set<OTSShape> intersectingShapes(final Rectangle2D rectangle)
{
return this.quadTree.intersectingShapes(rectangle);
}
/**
* Recursively print this OTS2DSet.
* @param recursionDepth int; maximum depth to recurse
* @return String
*/
final String toString(final int recursionDepth)
{
return "OTS2DSet [contains " + size() + (1 == this.allShapes.size() ? "shape" : "shapes") + ", minimumCellSize="
+ this.minimumCellSize + ", quadTree=" + this.quadTree.toString(recursionDepth) + "]";
}
/** {@inheritDoc} */
@Override
public final String toString()
{
return toString(0);
}
/**
* Return all OTSShapes in this OTS2DSet that intersect a given OTSShape.
* @param shape OTSShape; the given OTSShape
* @return Set<OTSShape>; all OTSShapes in this OTS2DSet that intersect <code>shape</code>
*/
public final Set<OTSShape> intersectingShapes(final OTSShape shape)
{
Envelope envelope = shape.getEnvelope();
Set<OTSShape> result = intersectingShapes(
new Rectangle2D.Double(envelope.getMinX(), envelope.getMinY(), envelope.getWidth(), envelope.getHeight()));
for (Iterator<OTSShape> it = result.iterator(); it.hasNext();)
{
if (!it.next().intersects(shape))
{
it.remove();
}
}
return result;
}
/**
* Return an ASCII art rendering of this OTS2DSet.
* @param recursionDepth int; maximum recursion depth
* @return String; a somewhat human readable rendering of this OTS2DSet
*/
public final String toStringGraphic(final int recursionDepth)
{
return this.quadTree.toStringGraphic(recursionDepth);
}
/**
* Iterator for quad tree. Shall iterate over the local set of shapes and the (up to four) non-null leave nodes.
*/
class QuadTreeIterator implements Iterator<OTSShape>, Serializable
{
/** */
private static final long serialVersionUID = 20170400L;
/** Underlying iterator that traverses the allShapes Set. */
@SuppressWarnings("synthetic-access")
private final Iterator<OTSShape> theIterator = OTS2DSet.this.allShapes.iterator();
/** Remember the last returned result so we can remove it when requested. */
private OTSShape lastResult = null;
/** {@inheritDoc} */
@Override
public final boolean hasNext()
{
return this.theIterator.hasNext();
}
/** {@inheritDoc} */
@Override
public final OTSShape next()
{
this.lastResult = this.theIterator.next();
return this.lastResult;
}
/** {@inheritDoc} */
@SuppressWarnings("synthetic-access")
@Override
public final void remove()
{
this.theIterator.remove();
if (!OTS2DSet.this.quadTree.remove(this.lastResult))
{
SimLogger.always().error("iterator.remove: ERROR: could not remove {} from the quad tree", this.lastResult);
}
}
/** {@inheritDoc} */
@Override
public String toString()
{
return "QuadTreeIterator [theIterator=" + this.theIterator + ", lastResult=" + this.lastResult + "]";
}
}
/**
* Spatial-aware storage for a set of OTSShape objects.
*/
class QuadTreeNode implements Serializable
{
/** */
private static final long serialVersionUID = 20170400L;
/** The OTSShapes stored at this node. */
private Set<OTSShape> shapes = new HashSet<OTSShape>();
/** The bounding box of this QuadTreeNode. */
private final Rectangle2D boundingBox;
/** The bounding box of this QuadTreeNode as an OTSShape. */
private final OTSShape boundingShape;
/**
* The four leaves of this node in the quad tree. An empty sub tree may be represented by null. If this field is
* initialized to null; this node may not expand by adding sub-nodes.
*/
private final QuadTreeNode[] leaves;
/**
* Construct a new QuadTreeNode.
* @param boundingBox Rectangle2D; the bounding box of the area of the new QuadTreeNode
*/
@SuppressWarnings("synthetic-access")
QuadTreeNode(final Rectangle2D boundingBox)
{
this.boundingBox = boundingBox;
this.boundingShape = rectangleShape(boundingBox);
this.leaves = boundingBox.getWidth() > OTS2DSet.this.minimumCellSize
|| boundingBox.getHeight() > OTS2DSet.this.minimumCellSize ? new QuadTreeNode[4] : null;
}
/**
* Return a Set containing all OTSShapes in this QuadTreeNode that intersect a rectangular area.
* @param rectangle Rectangle2D; the area
* @return Set<OTSShape>; the set
*/
public Set<OTSShape> intersectingShapes(final Rectangle2D rectangle)
{
Set<OTSShape> result = new HashSet<OTSShape>();
if (!this.boundingBox.intersects(rectangle))
{
return result;
}
if (null == this.leaves)
{
return result;
}
for (QuadTreeNode leaf : this.leaves)
{
if (null != leaf && leaf.intersects(rectangle))
{
result.addAll(leaf.intersectingShapes(rectangle));
}
}
for (OTSShape shape : this.shapes)
{
OTSShape rectangleShape = rectangleShape(rectangle);
if (rectangleShape.intersects(shape))
{
result.add(shape);
}
}
return result;
}
/**
* Test if this QuadTreeNode intersects a rectangular area.
* @param rectangle Rectangle2D; the rectangular area
* @return boolean; true if the rectangular area intersects this QuadTreeNode; false otherwise
*/
private boolean intersects(final Rectangle2D rectangle)
{
return this.boundingBox.intersects(rectangle);
}
/**
* Remove all OTSShapes from this QuadTreeNode and cut off all leaves.
*/
public void clear()
{
this.shapes.clear();
for (int index = 0; index < this.leaves.length; index++)
{
this.leaves[index] = null;
}
}
/**
* Remove an OTSShape from this QuadTreeNode.
* @param shape OTSShape; the shape that must be removed.
* @return boolean; true if this node (or a sub-node) was altered; false otherwise
*/
public boolean remove(final OTSShape shape)
{
if (!this.boundingShape.intersects(shape))
{
return false;
}
for (OTSShape s : this.shapes)
{
if (shape.equals(s))
{
this.shapes.remove(shape);
return true;
}
}
boolean result = false;
for (int index = 0; index < this.leaves.length; index++)
{
QuadTreeNode qtn = this.leaves[index];
if (null != qtn)
{
if (qtn.remove(shape))
{
result = true;
if (qtn.isEmpty())
{
this.leaves[index] = null; // Cut off empty leaf node
}
}
}
}
return result;
}
/**
* Check if this QuadTreeNode is empty.
* @return boolean; true if this QuadTreeNode is empty
*/
private boolean isEmpty()
{
if (!this.shapes.isEmpty())
{
return false;
}
if (null == this.leaves)
{
return true;
}
for (QuadTreeNode qtn : this.leaves)
{
if (null != qtn)
{
return false;
}
}
return true;
}
/**
* Test if the area of this QuadTree intersects an OTSShape.
* @param shape OTSShape; the shape
* @return boolean; true if the area of this QuadTree intersects the shape; false otherwise
*/
public boolean intersects(final OTSShape shape)
{
return this.boundingShape.intersects(shape);
}
/**
* Construct a OTSShape from a Rectangle2D.
* @param rectangle Rectangle2D; the rectangle
* @return OTSShape; a new OTSShape
*/
private OTSShape rectangleShape(final Rectangle2D rectangle)
{
double left = rectangle.getMinX();
double bottom = rectangle.getMinY();
double right = rectangle.getMaxX();
double top = rectangle.getMaxY();
try
{
return new OTSShape(new OTSPoint3D(left, bottom), new OTSPoint3D(right, bottom), new OTSPoint3D(right, top),
new OTSPoint3D(left, top));
}
catch (OTSGeometryException exception)
{
SimLogger.always().error(exception);
return null;
}
}
/**
* Add an OTSShape to this QuadTreeNode.
* @param shape OTSShape; the shape
* @return boolean; true if this QuadTreeNode changed as a result of this operation
*/
public final boolean add(final OTSShape shape)
{
if (!this.boundingShape.intersects(shape))
{
return false;
}
if ((null == this.leaves) || shape.contains(this.boundingBox))
{
// shape belongs in the set of shapes of this node.
return this.shapes.add(shape);
}
// This node may have leaves and shape does not entirely contain this node. Add shape to all applicable leaves.
boolean result = false;
for (int index = 0; index < this.leaves.length; index++)
{
if (null == this.leaves[index])
{
double subWidth = this.boundingBox.getWidth() / 2;
double subHeight = this.boundingBox.getHeight() / 2;
if (0 == subWidth)
{
// loss of precision; degenerate into a binary tree
subWidth = this.boundingBox.getWidth();
}
if (0 == subHeight)
{
// loss of precision; degenerate into a binary tree
subHeight = this.boundingBox.getHeight();
}
double left = this.boundingBox.getMinX();
if (0 != index / 2)
{
left += subWidth;
}
double bottom = this.boundingBox.getMinY();
if (0 != index % 2)
{
bottom += subHeight;
}
Rectangle2D subBox = new Rectangle2D.Double(left, bottom, subWidth, subHeight);
if (rectangleShape(subBox).intersects(shape))
{
// Expand this node by adding a sub node.
this.leaves[index] = new QuadTreeNode(subBox);
if (this.leaves[index].add(shape))
{
result = true;
}
else
{
throw new Error("Cannot happen: new QuadTreeNode refused to add shape that intersects it");
}
}
}
else
{
// Leaf node already exists. Let the leaf determine if shape should be stored (somewhere) in it.
if (this.leaves[index].add(shape))
{
result = true;
}
}
}
return result;
}
/**
* Helper function for toString.
* @param recursionDepth int; maximum number of levels to print recursively
* @param index int; index in leaves
* @return String
*/
private String printLeaf(final int recursionDepth, final int index)
{
QuadTreeNode leaf = this.leaves[index];
if (null == leaf)
{
return "null";
}
if (recursionDepth > 0)
{
return leaf.toString(recursionDepth - 1);
}
int leafSize = leaf.shapes.size();
return leafSize + " shape" + (1 == leafSize ? "" : "s");
}
/**
* Recursively print this QuadTreeNode.
* @param recursionDepth int; maximum depth to recurse
* @return String
*/
final String toString(final int recursionDepth)
{
return "QuadTreeNode [" + this.shapes.size() + ", bounds=[LB: " + this.boundingBox.getMinX() + ","
+ this.boundingBox.getMinY() + ", RT: " + this.boundingBox.getMaxX() + "," + this.boundingBox.getMaxY()
+ "], " + subNodes(recursionDepth) + ", local " + this.shapes.size()
+ (1 == this.shapes.size() ? " shape" : " shapes") + "]";
}
/**
* Print the leaves of this QuadTreeNode.
* @param recursionDepth int; maximum depth to recurse
* @return String
*/
private String subNodes(final int recursionDepth)
{
if (null == this.leaves)
{
return "cannot have leaves";
}
return "leaves=[LB: " + printLeaf(recursionDepth, 0) + ", RB: " + printLeaf(recursionDepth, 1) + ", LT: "
+ printLeaf(recursionDepth, 2) + ", RT: " + printLeaf(recursionDepth, 3) + "]";
}
/** {@inheritDoc} */
@Override
public final String toString()
{
return toString(0);
}
/**
* Return concatenation of a number of copies of a string.
* @param count int; number of copies to concatenate
* @param string String; the string to repeat
* @return String
*/
private String repeat(final int count, final String string)
{
StringBuilder result = new StringBuilder();
for (int i = 0; i < count; i++)
{
result.append(string);
}
return result.toString();
}
/** Graphic to draw a vertical line. */
private static final String VLINE = "|";
/** Graphic to draw a horizontal line. */
private static final String HLINE = "-";
/** Graphic to draw a space. */
private static final String SPACE = " ";
/** Number of digits to print. */
private static final int NUMBERSIZE = 6;
/**
* Similar to toStringGraphic, but with QuadTreeNode argument which can be null. <br>
* This code is <b>not</b> optimized for performance; the repeated use of String.split is probably expensive.
* @param qtn QuadTreeNode; the QuadTreeNode to render. Can be null.
* @param recursionDepth int; levels to recurse
* @return String
*/
private String subStringGraphic(final QuadTreeNode qtn, final int recursionDepth)
{
StringBuffer result = new StringBuffer();
if (0 == recursionDepth)
{
if (null == qtn)
{
result.append(repeat(NUMBERSIZE, SPACE));
}
else
{
String numberBuf = String.format("%d", size());
int spare = NUMBERSIZE - numberBuf.length();
int filled = 0;
while (filled < spare / 2)
{
result.append(SPACE);
filled++;
}
result.append(numberBuf);
while (filled < spare)
{
result.append(SPACE);
filled++;
}
result.append("\n");
return result.toString();
}
}
else
{
String[] left = subStringGraphic(null == qtn || null == qtn.leaves ? null : qtn.leaves[1], recursionDepth - 1)
.split("\\n");
String[] right = subStringGraphic(null == qtn || null == qtn.leaves ? null : qtn.leaves[3], recursionDepth - 1)
.split("\\n");
String horizontalLine = null;
for (int i = 0; i < left.length; i++)
{
if (0 == i)
{
StringBuilder line = new StringBuilder();
int width = left[0].length() + 1 + right[0].length();
if (null == qtn)
{
line.append(repeat(width, SPACE));
}
else
{
String numberBuf = String.format("%d", qtn.shapes.size());
int spare = width - numberBuf.length();
line.append(repeat(spare / 2, HLINE));
line.append(numberBuf);
line.append(repeat(spare - spare / 2, HLINE));
}
horizontalLine = line.toString();
}
result.append(left[i]);
result.append(null == qtn ? SPACE : VLINE);
result.append(right[i]);
result.append("\n");
}
result.append(horizontalLine);
result.append("\n");
left = subStringGraphic(null == qtn || null == qtn.leaves ? null : qtn.leaves[0], recursionDepth - 1)
.split("\\n");
right = subStringGraphic(null == qtn || null == qtn.leaves ? null : qtn.leaves[2], recursionDepth - 1)
.split("\\n");
for (int i = 0; i < left.length; i++)
{
result.append(left[i]);
result.append(null == qtn ? SPACE : VLINE);
result.append(right[i]);
result.append("\n");
}
result.append("\n");
}
return result.toString();
}
/**
* Return a String depicting this QuadTreeNode.
* @param recursionDepth int; levels to recurse
* @return String
*/
public final String toStringGraphic(final int recursionDepth)
{
return subStringGraphic(this, recursionDepth);
}
}
}