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JTS Topology Suite 1.14 with additional functions for GeoSpark
/*
* The JTS Topology Suite is a collection of Java classes that
* implement the fundamental operations required to validate a given
* geo-spatial data set to a known topological specification.
*
* Copyright (C) 2001 Vivid Solutions
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
* For more information, contact:
*
* Vivid Solutions
* Suite #1A
* 2328 Government Street
* Victoria BC V8T 5G5
* Canada
*
* (250)385-6040
* www.vividsolutions.com
*/
package com.vividsolutions.jts.geomgraph;
import java.util.*;
import com.vividsolutions.jts.algorithm.*;
import com.vividsolutions.jts.algorithm.locate.*;
import com.vividsolutions.jts.geom.*;
import com.vividsolutions.jts.geomgraph.index.*;
import com.vividsolutions.jts.util.*;
/**
* A GeometryGraph is a graph that models a given Geometry
* @version 1.7
*/
public class GeometryGraph
extends PlanarGraph
{
/**
* This method implements the Boundary Determination Rule
* for determining whether
* a component (node or edge) that appears multiple times in elements
* of a MultiGeometry is in the boundary or the interior of the Geometry
*
* The SFS uses the "Mod-2 Rule", which this function implements
*
* An alternative (and possibly more intuitive) rule would be
* the "At Most One Rule":
* isInBoundary = (componentCount == 1)
*/
/*
public static boolean isInBoundary(int boundaryCount)
{
// the "Mod-2 Rule"
return boundaryCount % 2 == 1;
}
public static int determineBoundary(int boundaryCount)
{
return isInBoundary(boundaryCount) ? Location.BOUNDARY : Location.INTERIOR;
}
*/
public static int determineBoundary(BoundaryNodeRule boundaryNodeRule, int boundaryCount)
{
return boundaryNodeRule.isInBoundary(boundaryCount)
? Location.BOUNDARY : Location.INTERIOR;
}
private Geometry parentGeom;
/**
* The lineEdgeMap is a map of the linestring components of the
* parentGeometry to the edges which are derived from them.
* This is used to efficiently perform findEdge queries
*/
private Map lineEdgeMap = new HashMap();
private BoundaryNodeRule boundaryNodeRule = null;
/**
* If this flag is true, the Boundary Determination Rule will used when deciding
* whether nodes are in the boundary or not
*/
private boolean useBoundaryDeterminationRule = true;
private int argIndex; // the index of this geometry as an argument to a spatial function (used for labelling)
private Collection boundaryNodes;
private boolean hasTooFewPoints = false;
private Coordinate invalidPoint = null;
private PointOnGeometryLocator areaPtLocator = null;
// for use if geometry is not Polygonal
private final PointLocator ptLocator = new PointLocator();
private EdgeSetIntersector createEdgeSetIntersector()
{
// various options for computing intersections, from slowest to fastest
//private EdgeSetIntersector esi = new SimpleEdgeSetIntersector();
//private EdgeSetIntersector esi = new MonotoneChainIntersector();
//private EdgeSetIntersector esi = new NonReversingChainIntersector();
//private EdgeSetIntersector esi = new SimpleSweepLineIntersector();
//private EdgeSetIntersector esi = new MCSweepLineIntersector();
//return new SimpleEdgeSetIntersector();
return new SimpleMCSweepLineIntersector();
}
public GeometryGraph(int argIndex, Geometry parentGeom)
{
this(argIndex, parentGeom,
BoundaryNodeRule.OGC_SFS_BOUNDARY_RULE
);
}
public GeometryGraph(int argIndex, Geometry parentGeom, BoundaryNodeRule boundaryNodeRule) {
this.argIndex = argIndex;
this.parentGeom = parentGeom;
this.boundaryNodeRule = boundaryNodeRule;
if (parentGeom != null) {
// precisionModel = parentGeom.getPrecisionModel();
// SRID = parentGeom.getSRID();
add(parentGeom);
}
}
/**
* This constructor is used by clients that wish to add Edges explicitly,
* rather than adding a Geometry. (An example is BufferOp).
*/
// no longer used
// public GeometryGraph(int argIndex, PrecisionModel precisionModel, int SRID) {
// this(argIndex, null);
// this.precisionModel = precisionModel;
// this.SRID = SRID;
// }
// public PrecisionModel getPrecisionModel()
// {
// return precisionModel;
// }
// public int getSRID() { return SRID; }
public boolean hasTooFewPoints() { return hasTooFewPoints; }
public Coordinate getInvalidPoint() { return invalidPoint; }
public Geometry getGeometry() { return parentGeom; }
public BoundaryNodeRule getBoundaryNodeRule() { return boundaryNodeRule; }
public Collection getBoundaryNodes()
{
if (boundaryNodes == null)
boundaryNodes = nodes.getBoundaryNodes(argIndex);
return boundaryNodes;
}
public Coordinate[] getBoundaryPoints()
{
Collection coll = getBoundaryNodes();
Coordinate[] pts = new Coordinate[coll.size()];
int i = 0;
for (Iterator it = coll.iterator(); it.hasNext(); ) {
Node node = (Node) it.next();
pts[i++] = (Coordinate) node.getCoordinate().clone();
}
return pts;
}
public Edge findEdge(LineString line)
{
return (Edge) lineEdgeMap.get(line);
}
public void computeSplitEdges(List edgelist)
{
for (Iterator i = edges.iterator(); i.hasNext(); ) {
Edge e = (Edge) i.next();
e.eiList.addSplitEdges(edgelist);
}
}
private void add(Geometry g)
{
if (g.isEmpty()) return;
// check if this Geometry should obey the Boundary Determination Rule
// all collections except MultiPolygons obey the rule
if (g instanceof MultiPolygon)
useBoundaryDeterminationRule = false;
if (g instanceof Polygon) addPolygon((Polygon) g);
// LineString also handles LinearRings
else if (g instanceof LineString) addLineString((LineString) g);
else if (g instanceof Point) addPoint((Point) g);
else if (g instanceof MultiPoint) addCollection((MultiPoint) g);
else if (g instanceof MultiLineString) addCollection((MultiLineString) g);
else if (g instanceof MultiPolygon) addCollection((MultiPolygon) g);
else if (g instanceof GeometryCollection) addCollection((GeometryCollection) g);
else throw new UnsupportedOperationException(g.getClass().getName());
}
private void addCollection(GeometryCollection gc)
{
for (int i = 0; i < gc.getNumGeometries(); i++) {
Geometry g = gc.getGeometryN(i);
add(g);
}
}
/**
* Add a Point to the graph.
*/
private void addPoint(Point p)
{
Coordinate coord = p.getCoordinate();
insertPoint(argIndex, coord, Location.INTERIOR);
}
/**
* Adds a polygon ring to the graph.
* Empty rings are ignored.
*
* The left and right topological location arguments assume that the ring is oriented CW.
* If the ring is in the opposite orientation,
* the left and right locations must be interchanged.
*/
private void addPolygonRing(LinearRing lr, int cwLeft, int cwRight)
{
// don't bother adding empty holes
if (lr.isEmpty()) return;
Coordinate[] coord = CoordinateArrays.removeRepeatedPoints(lr.getCoordinates());
if (coord.length < 4) {
hasTooFewPoints = true;
invalidPoint = coord[0];
return;
}
int left = cwLeft;
int right = cwRight;
if (CGAlgorithms.isCCW(coord)) {
left = cwRight;
right = cwLeft;
}
Edge e = new Edge(coord,
new Label(argIndex, Location.BOUNDARY, left, right));
lineEdgeMap.put(lr, e);
insertEdge(e);
// insert the endpoint as a node, to mark that it is on the boundary
insertPoint(argIndex, coord[0], Location.BOUNDARY);
}
private void addPolygon(Polygon p)
{
addPolygonRing(
(LinearRing) p.getExteriorRing(),
Location.EXTERIOR,
Location.INTERIOR);
for (int i = 0; i < p.getNumInteriorRing(); i++) {
LinearRing hole = (LinearRing) p.getInteriorRingN(i);
// Holes are topologically labelled opposite to the shell, since
// the interior of the polygon lies on their opposite side
// (on the left, if the hole is oriented CW)
addPolygonRing(
hole,
Location.INTERIOR,
Location.EXTERIOR);
}
}
private void addLineString(LineString line)
{
Coordinate[] coord = CoordinateArrays.removeRepeatedPoints(line.getCoordinates());
if (coord.length < 2) {
hasTooFewPoints = true;
invalidPoint = coord[0];
return;
}
// add the edge for the LineString
// line edges do not have locations for their left and right sides
Edge e = new Edge(coord, new Label(argIndex, Location.INTERIOR));
lineEdgeMap.put(line, e);
insertEdge(e);
/**
* Add the boundary points of the LineString, if any.
* Even if the LineString is closed, add both points as if they were endpoints.
* This allows for the case that the node already exists and is a boundary point.
*/
Assert.isTrue(coord.length >= 2, "found LineString with single point");
insertBoundaryPoint(argIndex, coord[0]);
insertBoundaryPoint(argIndex, coord[coord.length - 1]);
}
/**
* Add an Edge computed externally. The label on the Edge is assumed
* to be correct.
*/
public void addEdge(Edge e)
{
insertEdge(e);
Coordinate[] coord = e.getCoordinates();
// insert the endpoint as a node, to mark that it is on the boundary
insertPoint(argIndex, coord[0], Location.BOUNDARY);
insertPoint(argIndex, coord[coord.length - 1], Location.BOUNDARY);
}
/**
* Add a point computed externally. The point is assumed to be a
* Point Geometry part, which has a location of INTERIOR.
*/
public void addPoint(Coordinate pt)
{
insertPoint(argIndex, pt, Location.INTERIOR);
}
/**
* Compute self-nodes, taking advantage of the Geometry type to
* minimize the number of intersection tests. (E.g. rings are
* not tested for self-intersection, since they are assumed to be valid).
* @param li the LineIntersector to use
* @param computeRingSelfNodes if , intersection checks are optimized to not test rings for self-intersection
* @return the SegmentIntersector used, containing information about the intersections found
*/
public SegmentIntersector computeSelfNodes(LineIntersector li, boolean computeRingSelfNodes)
{
SegmentIntersector si = new SegmentIntersector(li, true, false);
EdgeSetIntersector esi = createEdgeSetIntersector();
// optimized test for Polygons and Rings
if (! computeRingSelfNodes
&& (parentGeom instanceof LinearRing
|| parentGeom instanceof Polygon
|| parentGeom instanceof MultiPolygon)) {
esi.computeIntersections(edges, si, false);
}
else {
esi.computeIntersections(edges, si, true);
}
//System.out.println("SegmentIntersector # tests = " + si.numTests);
addSelfIntersectionNodes(argIndex);
return si;
}
public SegmentIntersector computeEdgeIntersections(
GeometryGraph g,
LineIntersector li,
boolean includeProper)
{
SegmentIntersector si = new SegmentIntersector(li, includeProper, true);
si.setBoundaryNodes(this.getBoundaryNodes(), g.getBoundaryNodes());
EdgeSetIntersector esi = createEdgeSetIntersector();
esi.computeIntersections(edges, g.edges, si);
/*
for (Iterator i = g.edges.iterator(); i.hasNext();) {
Edge e = (Edge) i.next();
Debug.print(e.getEdgeIntersectionList());
}
*/
return si;
}
private void insertPoint(int argIndex, Coordinate coord, int onLocation)
{
Node n = nodes.addNode(coord);
Label lbl = n.getLabel();
if (lbl == null) {
n.label = new Label(argIndex, onLocation);
}
else
lbl.setLocation(argIndex, onLocation);
}
/**
* Adds candidate boundary points using the current {@link BoundaryNodeRule}.
* This is used to add the boundary
* points of dim-1 geometries (Curves/MultiCurves).
*/
private void insertBoundaryPoint(int argIndex, Coordinate coord)
{
Node n = nodes.addNode(coord);
// nodes always have labels
Label lbl = n.getLabel();
// the new point to insert is on a boundary
int boundaryCount = 1;
// determine the current location for the point (if any)
int loc = Location.NONE;
loc = lbl.getLocation(argIndex, Position.ON);
if (loc == Location.BOUNDARY) boundaryCount++;
// determine the boundary status of the point according to the Boundary Determination Rule
int newLoc = determineBoundary(boundaryNodeRule, boundaryCount);
lbl.setLocation(argIndex, newLoc);
}
private void addSelfIntersectionNodes(int argIndex)
{
for (Iterator i = edges.iterator(); i.hasNext(); ) {
Edge e = (Edge) i.next();
int eLoc = e.getLabel().getLocation(argIndex);
for (Iterator eiIt = e.eiList.iterator(); eiIt.hasNext(); ) {
EdgeIntersection ei = (EdgeIntersection) eiIt.next();
addSelfIntersectionNode(argIndex, ei.coord, eLoc);
}
}
}
/**
* Add a node for a self-intersection.
* If the node is a potential boundary node (e.g. came from an edge which
* is a boundary) then insert it as a potential boundary node.
* Otherwise, just add it as a regular node.
*/
private void addSelfIntersectionNode(int argIndex, Coordinate coord, int loc)
{
// if this node is already a boundary node, don't change it
if (isBoundaryNode(argIndex, coord)) return;
if (loc == Location.BOUNDARY && useBoundaryDeterminationRule)
insertBoundaryPoint(argIndex, coord);
else
insertPoint(argIndex, coord, loc);
}
// MD - experimental for now
/**
* Determines the {@link Location} of the given {@link Coordinate}
* in this geometry.
*
* @param p the point to test
* @return the location of the point in the geometry
*/
public int locate(Coordinate pt)
{
if (parentGeom instanceof Polygonal && parentGeom.getNumGeometries() > 50) {
// lazily init point locator
if (areaPtLocator == null) {
areaPtLocator = new IndexedPointInAreaLocator(parentGeom);
}
return areaPtLocator.locate(pt);
}
return ptLocator.locate(pt, parentGeom);
}
}
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