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/*
 * 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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