All Downloads are FREE. Search and download functionalities are using the official Maven repository.

com.vividsolutions.jts.triangulate.quadedge.QuadEdgeSubdivision Maven / Gradle / Ivy

There is a newer version: 0.1.4
Show newest version
/*
 * 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.triangulate.quadedge;

import java.util.*;

import com.vividsolutions.jts.geom.*;
import com.vividsolutions.jts.io.WKTWriter;

/**
 * A class that contains the {@link QuadEdge}s representing a planar
 * subdivision that models a triangulation. 
 * The subdivision is constructed using the
 * quadedge algebra defined in the classs {@link QuadEdge}. 
 * All metric calculations
 * are done in the {@link Vertex} class.
 * In addition to a triangulation, subdivisions
 * support extraction of Voronoi diagrams.
 * This is easily accomplished, since the Voronoi diagram is the dual
 * of the Delaunay triangulation.
 * 

* Subdivisions can be provided with a tolerance value. Inserted vertices which * are closer than this value to vertices already in the subdivision will be * ignored. Using a suitable tolerance value can prevent robustness failures * from happening during Delaunay triangulation. *

* Subdivisions maintain a frame triangle around the client-created * edges. The frame is used to provide a bounded "container" for all edges * within a TIN. Normally the frame edges, frame connecting edges, and frame * triangles are not included in client processing. * * @author David Skea * @author Martin Davis */ public class QuadEdgeSubdivision { /** * Gets the edges for the triangle to the left of the given {@link QuadEdge}. * * @param startQE * @param triEdge * * @throws IllegalArgumentException * if the edges do not form a triangle */ public static void getTriangleEdges(QuadEdge startQE, QuadEdge[] triEdge) { triEdge[0] = startQE; triEdge[1] = triEdge[0].lNext(); triEdge[2] = triEdge[1].lNext(); if (triEdge[2].lNext() != triEdge[0]) throw new IllegalArgumentException("Edges do not form a triangle"); } private final static double EDGE_COINCIDENCE_TOL_FACTOR = 1000; // debugging only - preserve current subdiv statically // private static QuadEdgeSubdivision currentSubdiv; // used for edge extraction to ensure edge uniqueness private int visitedKey = 0; // private Set quadEdges = new HashSet(); private List quadEdges = new ArrayList(); private QuadEdge startingEdge; private double tolerance; private double edgeCoincidenceTolerance; private Vertex[] frameVertex = new Vertex[3]; private Envelope frameEnv; private QuadEdgeLocator locator = null; /** * Creates a new instance of a quad-edge subdivision based on a frame triangle * that encloses a supplied bounding box. A new super-bounding box that * contains the triangle is computed and stored. * * @param env * the bouding box to surround * @param tolerance * the tolerance value for determining if two sites are equal */ public QuadEdgeSubdivision(Envelope env, double tolerance) { // currentSubdiv = this; this.tolerance = tolerance; edgeCoincidenceTolerance = tolerance / EDGE_COINCIDENCE_TOL_FACTOR; createFrame(env); startingEdge = initSubdiv(); locator = new LastFoundQuadEdgeLocator(this); } private void createFrame(Envelope env) { double deltaX = env.getWidth(); double deltaY = env.getHeight(); double offset = 0.0; if (deltaX > deltaY) { offset = deltaX * 10.0; } else { offset = deltaY * 10.0; } frameVertex[0] = new Vertex((env.getMaxX() + env.getMinX()) / 2.0, env .getMaxY() + offset); frameVertex[1] = new Vertex(env.getMinX() - offset, env.getMinY() - offset); frameVertex[2] = new Vertex(env.getMaxX() + offset, env.getMinY() - offset); frameEnv = new Envelope(frameVertex[0].getCoordinate(), frameVertex[1] .getCoordinate()); frameEnv.expandToInclude(frameVertex[2].getCoordinate()); } private QuadEdge initSubdiv() { // build initial subdivision from frame QuadEdge ea = makeEdge(frameVertex[0], frameVertex[1]); QuadEdge eb = makeEdge(frameVertex[1], frameVertex[2]); QuadEdge.splice(ea.sym(), eb); QuadEdge ec = makeEdge(frameVertex[2], frameVertex[0]); QuadEdge.splice(eb.sym(), ec); QuadEdge.splice(ec.sym(), ea); return ea; } /** * Gets the vertex-equality tolerance value * used in this subdivision * * @return the tolerance value */ public double getTolerance() { return tolerance; } /** * Gets the envelope of the Subdivision (including the frame). * * @return the envelope */ public Envelope getEnvelope() { return new Envelope(frameEnv); } /** * Gets the collection of base {@link QuadEdge}s (one for every pair of * vertices which is connected). * * @return a collection of QuadEdges */ public Collection getEdges() { return quadEdges; } /** * Sets the {@link QuadEdgeLocator} to use for locating containing triangles * in this subdivision. * * @param locator * a QuadEdgeLocator */ public void setLocator(QuadEdgeLocator locator) { this.locator = locator; } /** * Creates a new quadedge, recording it in the edges list. * * @param o * @param d * @return a new quadedge */ public QuadEdge makeEdge(Vertex o, Vertex d) { QuadEdge q = QuadEdge.makeEdge(o, d); quadEdges.add(q); return q; } /** * Creates a new QuadEdge connecting the destination of a to the origin of b, * in such a way that all three have the same left face after the connection * is complete. The quadedge is recorded in the edges list. * * @param a * @param b * @return a quadedge */ public QuadEdge connect(QuadEdge a, QuadEdge b) { QuadEdge q = QuadEdge.connect(a, b); quadEdges.add(q); return q; } /** * Deletes a quadedge from the subdivision. Linked quadedges are updated to * reflect the deletion. * * @param e * the quadedge to delete */ public void delete(QuadEdge e) { QuadEdge.splice(e, e.oPrev()); QuadEdge.splice(e.sym(), e.sym().oPrev()); QuadEdge eSym = e.sym(); QuadEdge eRot = e.rot(); QuadEdge eRotSym = e.rot().sym(); // this is inefficient on an ArrayList, but this method should be called infrequently quadEdges.remove(e); quadEdges.remove(eSym); quadEdges.remove(eRot); quadEdges.remove(eRotSym); e.delete(); eSym.delete(); eRot.delete(); eRotSym.delete(); } /** * Locates an edge of a triangle which contains a location * specified by a Vertex v. * The edge returned has the * property that either v is on e, or e is an edge of a triangle containing v. * The search starts from startEdge amd proceeds on the general direction of v. *

* This locate algorithm relies on the subdivision being Delaunay. For * non-Delaunay subdivisions, this may loop for ever. * * @param v the location to search for * @param startEdge an edge of the subdivision to start searching at * @returns a QuadEdge which contains v, or is on the edge of a triangle containing v * @throws LocateFailureException * if the location algorithm fails to converge in a reasonable * number of iterations */ public QuadEdge locateFromEdge(Vertex v, QuadEdge startEdge) { int iter = 0; int maxIter = quadEdges.size(); QuadEdge e = startEdge; while (true) { iter++; /** * So far it has always been the case that failure to locate indicates an * invalid subdivision. So just fail completely. (An alternative would be * to perform an exhaustive search for the containing triangle, but this * would mask errors in the subdivision topology) * * This can also happen if two vertices are located very close together, * since the orientation predicates may experience precision failures. */ if (iter > maxIter) { throw new LocateFailureException(e.toLineSegment()); // String msg = "Locate failed to converge (at edge: " + e + "). // Possible causes include invalid Subdivision topology or very close // sites"; // System.err.println(msg); // dumpTriangles(); } if ((v.equals(e.orig())) || (v.equals(e.dest()))) { break; } else if (v.rightOf(e)) { e = e.sym(); } else if (!v.rightOf(e.oNext())) { e = e.oNext(); } else if (!v.rightOf(e.dPrev())) { e = e.dPrev(); } else { // on edge or in triangle containing edge break; } } // System.out.println("Locate count: " + iter); return e; } /** * Finds a quadedge of a triangle containing a location * specified by a {@link Vertex}, if one exists. * * @param v the vertex to locate * @return a quadedge on the edge of a triangle which touches or contains the location * or null if no such triangle exists */ public QuadEdge locate(Vertex v) { return locator.locate(v); } /** * Finds a quadedge of a triangle containing a location * specified by a {@link Coordinate}, if one exists. * * @param p the Coordinate to locate * @return a quadedge on the edge of a triangle which touches or contains the location * or null if no such triangle exists */ public QuadEdge locate(Coordinate p) { return locator.locate(new Vertex(p)); } /** * Locates the edge between the given vertices, if it exists in the * subdivision. * * @param p0 a coordinate * @param p1 another coordinate * @return the edge joining the coordinates, if present * or null if no such edge exists */ public QuadEdge locate(Coordinate p0, Coordinate p1) { // find an edge containing one of the points QuadEdge e = locator.locate(new Vertex(p0)); if (e == null) return null; // normalize so that p0 is origin of base edge QuadEdge base = e; if (e.dest().getCoordinate().equals2D(p0)) base = e.sym(); // check all edges around origin of base edge QuadEdge locEdge = base; do { if (locEdge.dest().getCoordinate().equals2D(p1)) return locEdge; locEdge = locEdge.oNext(); } while (locEdge != base); return null; } /** * Inserts a new site into the Subdivision, connecting it to the vertices of * the containing triangle (or quadrilateral, if the split point falls on an * existing edge). *

* This method does NOT maintain the Delaunay condition. If desired, this must * be checked and enforced by the caller. *

* This method does NOT check if the inserted vertex falls on an edge. This * must be checked by the caller, since this situation may cause erroneous * triangulation * * @param v * the vertex to insert * @return a new quad edge terminating in v */ public QuadEdge insertSite(Vertex v) { QuadEdge e = locate(v); if ((v.equals(e.orig(), tolerance)) || (v.equals(e.dest(), tolerance))) { return e; // point already in subdivision. } // Connect the new point to the vertices of the containing // triangle (or quadrilateral, if the new point fell on an // existing edge.) QuadEdge base = makeEdge(e.orig(), v); QuadEdge.splice(base, e); QuadEdge startEdge = base; do { base = connect(e, base.sym()); e = base.oPrev(); } while (e.lNext() != startEdge); return startEdge; } /** * Tests whether a QuadEdge is an edge incident on a frame triangle vertex. * * @param e * the edge to test * @return true if the edge is connected to the frame triangle */ public boolean isFrameEdge(QuadEdge e) { if (isFrameVertex(e.orig()) || isFrameVertex(e.dest())) return true; return false; } /** * Tests whether a QuadEdge is an edge on the border of the frame facets and * the internal facets. E.g. an edge which does not itself touch a frame * vertex, but which touches an edge which does. * * @param e * the edge to test * @return true if the edge is on the border of the frame */ public boolean isFrameBorderEdge(QuadEdge e) { // MD debugging QuadEdge[] leftTri = new QuadEdge[3]; getTriangleEdges(e, leftTri); // System.out.println(new QuadEdgeTriangle(leftTri).toString()); QuadEdge[] rightTri = new QuadEdge[3]; getTriangleEdges(e.sym(), rightTri); // System.out.println(new QuadEdgeTriangle(rightTri).toString()); // check other vertex of triangle to left of edge Vertex vLeftTriOther = e.lNext().dest(); if (isFrameVertex(vLeftTriOther)) return true; // check other vertex of triangle to right of edge Vertex vRightTriOther = e.sym().lNext().dest(); if (isFrameVertex(vRightTriOther)) return true; return false; } /** * Tests whether a vertex is a vertex of the outer triangle. * * @param v * the vertex to test * @return true if the vertex is an outer triangle vertex */ public boolean isFrameVertex(Vertex v) { if (v.equals(frameVertex[0])) return true; if (v.equals(frameVertex[1])) return true; if (v.equals(frameVertex[2])) return true; return false; } private LineSegment seg = new LineSegment(); /** * Tests whether a {@link Coordinate} lies on a {@link QuadEdge}, up to a * tolerance determined by the subdivision tolerance. * * @param e * a QuadEdge * @param p * a point * @return true if the vertex lies on the edge */ public boolean isOnEdge(QuadEdge e, Coordinate p) { seg.setCoordinates(e.orig().getCoordinate(), e.dest().getCoordinate()); double dist = seg.distance(p); // heuristic (hack?) return dist < edgeCoincidenceTolerance; } /** * Tests whether a {@link Vertex} is the start or end vertex of a * {@link QuadEdge}, up to the subdivision tolerance distance. * * @param e * @param v * @return true if the vertex is a endpoint of the edge */ public boolean isVertexOfEdge(QuadEdge e, Vertex v) { if ((v.equals(e.orig(), tolerance)) || (v.equals(e.dest(), tolerance))) { return true; } return false; } /** * Gets the unique {@link Vertex}es in the subdivision, * including the frame vertices if desired. * * @param includeFrame * true if the frame vertices should be included * @return a collection of the subdivision vertices * * @see #getVertexUniqueEdges */ public Collection getVertices(boolean includeFrame) { Set vertices = new HashSet(); for (Iterator i = quadEdges.iterator(); i.hasNext();) { QuadEdge qe = (QuadEdge) i.next(); Vertex v = qe.orig(); //System.out.println(v); if (includeFrame || ! isFrameVertex(v)) vertices.add(v); /** * Inspect the sym edge as well, since it is * possible that a vertex is only at the * dest of all tracked quadedges. */ Vertex vd = qe.dest(); //System.out.println(vd); if (includeFrame || ! isFrameVertex(vd)) vertices.add(vd); } return vertices; } /** * Gets a collection of {@link QuadEdge}s whose origin * vertices are a unique set which includes * all vertices in the subdivision. * The frame vertices can be included if required. *

* This is useful for algorithms which require traversing the * subdivision starting at all vertices. * Returning a quadedge for each vertex * is more efficient than * the alternative of finding the actual vertices * using {@link #getVertices} and then locating * quadedges attached to them. * * @param includeFrame true if the frame vertices should be included * @return a collection of QuadEdge with the vertices of the subdivision as their origins */ public List getVertexUniqueEdges(boolean includeFrame) { List edges = new ArrayList(); Set visitedVertices = new HashSet(); for (Iterator i = quadEdges.iterator(); i.hasNext();) { QuadEdge qe = (QuadEdge) i.next(); Vertex v = qe.orig(); //System.out.println(v); if (! visitedVertices.contains(v)) { visitedVertices.add(v); if (includeFrame || ! isFrameVertex(v)) { edges.add(qe); } } /** * Inspect the sym edge as well, since it is * possible that a vertex is only at the * dest of all tracked quadedges. */ QuadEdge qd = qe.sym(); Vertex vd = qd.orig(); //System.out.println(vd); if (! visitedVertices.contains(vd)) { visitedVertices.add(vd); if (includeFrame || ! isFrameVertex(vd)) { edges.add(qd); } } } return edges; } /** * Gets all primary quadedges in the subdivision. * A primary edge is a {@link QuadEdge} * which occupies the 0'th position in its array of associated quadedges. * These provide the unique geometric edges of the triangulation. * * @param includeFrame true if the frame edges are to be included * @return a List of QuadEdges */ public List getPrimaryEdges(boolean includeFrame) { visitedKey++; List edges = new ArrayList(); Stack edgeStack = new Stack(); edgeStack.push(startingEdge); Set visitedEdges = new HashSet(); while (!edgeStack.empty()) { QuadEdge edge = (QuadEdge) edgeStack.pop(); if (! visitedEdges.contains(edge)) { QuadEdge priQE = edge.getPrimary(); if (includeFrame || ! isFrameEdge(priQE)) edges.add(priQE); edgeStack.push(edge.oNext()); edgeStack.push(edge.sym().oNext()); visitedEdges.add(edge); visitedEdges.add(edge.sym()); } } return edges; } /** * A TriangleVisitor which computes and sets the * circumcentre as the origin of the dual * edges originating in each triangle. * * @author mbdavis * */ private static class TriangleCircumcentreVisitor implements TriangleVisitor { public TriangleCircumcentreVisitor() { } public void visit(QuadEdge[] triEdges) { Coordinate a = triEdges[0].orig().getCoordinate(); Coordinate b = triEdges[1].orig().getCoordinate(); Coordinate c = triEdges[2].orig().getCoordinate(); // TODO: choose the most accurate circumcentre based on the edges Coordinate cc = Triangle.circumcentre(a, b, c); Vertex ccVertex = new Vertex(cc); // save the circumcentre as the origin for the dual edges originating in this triangle for (int i = 0; i < 3; i++) { triEdges[i].rot().setOrig(ccVertex); } } } /***************************************************************************** * Visitors ****************************************************************************/ public void visitTriangles(TriangleVisitor triVisitor, boolean includeFrame) { visitedKey++; // visited flag is used to record visited edges of triangles // setVisitedAll(false); Stack edgeStack = new Stack(); edgeStack.push(startingEdge); Set visitedEdges = new HashSet(); while (!edgeStack.empty()) { QuadEdge edge = (QuadEdge) edgeStack.pop(); if (! visitedEdges.contains(edge)) { QuadEdge[] triEdges = fetchTriangleToVisit(edge, edgeStack, includeFrame, visitedEdges); if (triEdges != null) triVisitor.visit(triEdges); } } } /** * The quadedges forming a single triangle. * Only one visitor is allowed to be active at a * time, so this is safe. */ private QuadEdge[] triEdges = new QuadEdge[3]; /** * Stores the edges for a visited triangle. Also pushes sym (neighbour) edges * on stack to visit later. * * @param edge * @param edgeStack * @param includeFrame * @return the visited triangle edges * or null if the triangle should not be visited (for instance, if it is * outer) */ private QuadEdge[] fetchTriangleToVisit(QuadEdge edge, Stack edgeStack, boolean includeFrame, Set visitedEdges) { QuadEdge curr = edge; int edgeCount = 0; boolean isFrame = false; do { triEdges[edgeCount] = curr; if (isFrameEdge(curr)) isFrame = true; // push sym edges to visit next QuadEdge sym = curr.sym(); if (! visitedEdges.contains(sym)) edgeStack.push(sym); // mark this edge as visited visitedEdges.add(curr); edgeCount++; curr = curr.lNext(); } while (curr != edge); if (isFrame && !includeFrame) return null; return triEdges; } /** * Gets a list of the triangles * in the subdivision, specified as * an array of the primary quadedges around the triangle. * * @param includeFrame * true if the frame triangles should be included * @return a List of QuadEdge[3] arrays */ public List getTriangleEdges(boolean includeFrame) { TriangleEdgesListVisitor visitor = new TriangleEdgesListVisitor(); visitTriangles(visitor, includeFrame); return visitor.getTriangleEdges(); } private static class TriangleEdgesListVisitor implements TriangleVisitor { private List triList = new ArrayList(); public void visit(QuadEdge[] triEdges) { triList.add(triEdges.clone()); } public List getTriangleEdges() { return triList; } } /** * Gets a list of the triangles in the subdivision, * specified as an array of the triangle {@link Vertex}es. * * @param includeFrame * true if the frame triangles should be included * @return a List of Vertex[3] arrays */ public List getTriangleVertices(boolean includeFrame) { TriangleVertexListVisitor visitor = new TriangleVertexListVisitor(); visitTriangles(visitor, includeFrame); return visitor.getTriangleVertices(); } private static class TriangleVertexListVisitor implements TriangleVisitor { private List triList = new ArrayList(); public void visit(QuadEdge[] triEdges) { triList.add(new Vertex[] { triEdges[0].orig(), triEdges[1].orig(), triEdges[2].orig() }); } public List getTriangleVertices() { return triList; } } /** * Gets the coordinates for each triangle in the subdivision as an array. * * @param includeFrame * true if the frame triangles should be included * @return a list of Coordinate[4] representing each triangle */ public List getTriangleCoordinates(boolean includeFrame) { TriangleCoordinatesVisitor visitor = new TriangleCoordinatesVisitor(); visitTriangles(visitor, includeFrame); return visitor.getTriangles(); } private static class TriangleCoordinatesVisitor implements TriangleVisitor { private CoordinateList coordList = new CoordinateList(); private List triCoords = new ArrayList(); public TriangleCoordinatesVisitor() { } public void visit(QuadEdge[] triEdges) { coordList.clear(); for (int i = 0; i < 3; i++) { Vertex v = triEdges[i].orig(); coordList.add(v.getCoordinate()); } if (coordList.size() > 0) { coordList.closeRing(); Coordinate[] pts = coordList.toCoordinateArray(); if (pts.length != 4) { //checkTriangleSize(pts); return; } triCoords.add(pts); } } private void checkTriangleSize(Coordinate[] pts) { String loc = ""; if (pts.length >= 2) loc = WKTWriter.toLineString(pts[0], pts[1]); else { if (pts.length >= 1) loc = WKTWriter.toPoint(pts[0]); } // Assert.isTrue(pts.length == 4, "Too few points for visited triangle at " + loc); //com.vividsolutions.jts.util.Debug.println("too few points for triangle at " + loc); } public List getTriangles() { return triCoords; } } /** * Gets the geometry for the edges in the subdivision as a {@link MultiLineString} * containing 2-point lines. * * @param geomFact the GeometryFactory to use * @return a MultiLineString */ public Geometry getEdges(GeometryFactory geomFact) { List quadEdges = getPrimaryEdges(false); LineString[] edges = new LineString[quadEdges.size()]; int i = 0; for (Iterator it = quadEdges.iterator(); it.hasNext();) { QuadEdge qe = (QuadEdge) it.next(); edges[i++] = geomFact.createLineString(new Coordinate[] { qe.orig().getCoordinate(), qe.dest().getCoordinate() }); } return geomFact.createMultiLineString(edges); } /** * Gets the geometry for the triangles in a triangulated subdivision as a {@link GeometryCollection} * of triangular {@link Polygon}s. * * @param geomFact the GeometryFactory to use * @return a GeometryCollection of triangular Polygons */ public Geometry getTriangles(GeometryFactory geomFact) { List triPtsList = getTriangleCoordinates(false); Polygon[] tris = new Polygon[triPtsList.size()]; int i = 0; for (Iterator it = triPtsList.iterator(); it.hasNext();) { Coordinate[] triPt = (Coordinate[]) it.next(); tris[i++] = geomFact .createPolygon(geomFact.createLinearRing(triPt), null); } return geomFact.createGeometryCollection(tris); } /** * Gets the cells in the Voronoi diagram for this triangulation. * The cells are returned as a {@link GeometryCollection} of {@link Polygon}s *

* The userData of each polygon is set to be the {@link Coordinate} * of the cell site. This allows easily associating external * data associated with the sites to the cells. * * @param geomFact a geometry factory * @return a GeometryCollection of Polygons */ public Geometry getVoronoiDiagram(GeometryFactory geomFact) { List vorCells = getVoronoiCellPolygons(geomFact); return geomFact.createGeometryCollection(GeometryFactory.toGeometryArray(vorCells)); } /** * Gets a List of {@link Polygon}s for the Voronoi cells * of this triangulation. *

* The userData of each polygon is set to be the {@link Coordinate} * of the cell site. This allows easily associating external * data associated with the sites to the cells. * * @param geomFact a geometry factory * @return a List of Polygons */ public List getVoronoiCellPolygons(GeometryFactory geomFact) { /* * Compute circumcentres of triangles as vertices for dual edges. * Precomputing the circumcentres is more efficient, * and more importantly ensures that the computed centres * are consistent across the Voronoi cells. */ visitTriangles(new TriangleCircumcentreVisitor(), true); List cells = new ArrayList(); Collection edges = getVertexUniqueEdges(false); for (Iterator i = edges.iterator(); i.hasNext(); ) { QuadEdge qe = (QuadEdge) i.next(); cells.add(getVoronoiCellPolygon(qe, geomFact)); } return cells; } /** * Gets the Voronoi cell around a site specified * by the origin of a QuadEdge. *

* The userData of the polygon is set to be the {@link Coordinate} * of the site. This allows attaching external * data associated with the site to this cell polygon. * * @param qe a quadedge originating at the cell site * @param geomFact a factory for building the polygon * @return a polygon indicating the cell extent */ public Polygon getVoronoiCellPolygon(QuadEdge qe, GeometryFactory geomFact) { List cellPts = new ArrayList(); QuadEdge startQE = qe; do { // Coordinate cc = circumcentre(qe); // use previously computed circumcentre Coordinate cc = qe.rot().orig().getCoordinate(); cellPts.add(cc); // move to next triangle CW around vertex qe = qe.oPrev(); } while (qe != startQE); CoordinateList coordList = new CoordinateList(); coordList.addAll(cellPts, false); coordList.closeRing(); if (coordList.size() < 4) { System.out.println(coordList); coordList.add(coordList.get(coordList.size()-1), true); } Coordinate[] pts = coordList.toCoordinateArray(); Polygon cellPoly = geomFact.createPolygon(geomFact.createLinearRing(pts), null); Vertex v = startQE.orig(); cellPoly.setUserData(v.getCoordinate()); return cellPoly; } }





© 2015 - 2024 Weber Informatics LLC | Privacy Policy