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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.operation.linemerge;

import java.util.*;

import com.vividsolutions.jts.geom.*;
import com.vividsolutions.jts.planargraph.*;
import com.vividsolutions.jts.planargraph.algorithm.ConnectedSubgraphFinder;
import com.vividsolutions.jts.util.Assert;

/**
 * Builds a sequence from a set of LineStrings so that
 * they are ordered end to end.
 * A sequence is a complete non-repeating list of the linear
 * components of the input.  Each linestring is oriented
 * so that identical endpoints are adjacent in the list.
 * 

* A typical use case is to convert a set of * unoriented geometric links * from a linear network * (e.g. such as block faces on a bus route) * into a continuous oriented path through the network. *

* The input linestrings may form one or more connected sets. * The input linestrings should be correctly noded, or the results may * not be what is expected. * The computed output is a single {@link MultiLineString} containing the ordered * linestrings in the sequence. *

* The sequencing employs the classic Eulerian path graph algorithm. * Since Eulerian paths are not uniquely determined, * further rules are used to * make the computed sequence preserve as much as possible of the input * ordering. * Within a connected subset of lines, the ordering rules are: *

    *
  • If there is degree-1 node which is the start * node of an linestring, use that node as the start of the sequence *
  • If there is a degree-1 node which is the end * node of an linestring, use that node as the end of the sequence *
  • If the sequence has no degree-1 nodes, use any node as the start *
* * Note that not all arrangements of lines can be sequenced. * For a connected set of edges in a graph, * Euler's Theorem states that there is a sequence containing each edge once * if and only if there are no more than 2 nodes of odd degree. * If it is not possible to find a sequence, the {@link #isSequenceable()} method * will return false. * * @version 1.7 */ public class LineSequencer { public static Geometry sequence(Geometry geom) { LineSequencer sequencer = new LineSequencer(); sequencer.add(geom); return sequencer.getSequencedLineStrings(); } /** * Tests whether a {@link Geometry} is sequenced correctly. * {@link LineString}s are trivially sequenced. * {@link MultiLineString}s are checked for correct sequencing. * Otherwise, isSequenced is defined * to be true for geometries that are not lineal. * * @param geom the geometry to test * @return true if the geometry is sequenced or is not lineal */ public static boolean isSequenced(Geometry geom) { if (! (geom instanceof MultiLineString)) { return true; } MultiLineString mls = (MultiLineString) geom; // the nodes in all subgraphs which have been completely scanned Set prevSubgraphNodes = new TreeSet(); Coordinate lastNode = null; List currNodes = new ArrayList(); for (int i = 0; i < mls.getNumGeometries(); i++) { LineString line = (LineString) mls.getGeometryN(i); Coordinate startNode = line.getCoordinateN(0); Coordinate endNode = line.getCoordinateN(line.getNumPoints() - 1); /** * If this linestring is connected to a previous subgraph, geom is not sequenced */ if (prevSubgraphNodes.contains(startNode)) return false; if (prevSubgraphNodes.contains(endNode)) return false; if (lastNode != null) { if (! startNode.equals(lastNode)) { // start new connected sequence prevSubgraphNodes.addAll(currNodes); currNodes.clear(); } } currNodes.add(startNode); currNodes.add(endNode); lastNode = endNode; } return true; } private LineMergeGraph graph = new LineMergeGraph(); // initialize with default, in case no lines are input private GeometryFactory factory = new GeometryFactory(); private int lineCount = 0; private boolean isRun = false; private Geometry sequencedGeometry = null; private boolean isSequenceable = false; /** * Adds a {@link Collection} of {@link Geometry}s to be sequenced. * May be called multiple times. * Any dimension of Geometry may be added; the constituent linework will be * extracted. * * @param geometries a Collection of geometries to add */ public void add(Collection geometries) { for (Iterator i = geometries.iterator(); i.hasNext(); ) { Geometry geometry = (Geometry) i.next(); add(geometry); } } /** * Adds a {@link Geometry} to be sequenced. * May be called multiple times. * Any dimension of Geometry may be added; the constituent linework will be * extracted. * * @param geometry the geometry to add */ public void add(Geometry geometry) { geometry.apply(new GeometryComponentFilter() { public void filter(Geometry component) { if (component instanceof LineString) { addLine((LineString)component); } } }); } private void addLine(LineString lineString) { if (factory == null) { this.factory = lineString.getFactory(); } graph.addEdge(lineString); lineCount++; } /** * Tests whether the arrangement of linestrings has a valid * sequence. * * @return true if a valid sequence exists. */ public boolean isSequenceable() { computeSequence(); return isSequenceable; } /** * Returns the {@link LineString} or {@link MultiLineString} * built by the sequencing process, if one exists. * * @return the sequenced linestrings, * or null if a valid sequence does not exist */ public Geometry getSequencedLineStrings() { computeSequence(); return sequencedGeometry; } private void computeSequence() { if (isRun) { return; } isRun = true; List sequences = findSequences(); if (sequences == null) return; sequencedGeometry = buildSequencedGeometry(sequences); isSequenceable = true; int finalLineCount = sequencedGeometry.getNumGeometries(); Assert.isTrue(lineCount == finalLineCount, "Lines were missing from result"); Assert.isTrue(sequencedGeometry instanceof LineString || sequencedGeometry instanceof MultiLineString, "Result is not lineal"); } private List findSequences() { List sequences = new ArrayList(); ConnectedSubgraphFinder csFinder = new ConnectedSubgraphFinder(graph); List subgraphs = csFinder.getConnectedSubgraphs(); for (Iterator i = subgraphs.iterator(); i.hasNext(); ) { Subgraph subgraph = (Subgraph) i.next(); if (hasSequence(subgraph)) { List seq = findSequence(subgraph); sequences.add(seq); } else { // if any subgraph cannot be sequenced, abort return null; } } return sequences; } /** * Tests whether a complete unique path exists in a graph * using Euler's Theorem. * * @param graph the subgraph containing the edges * @return true if a sequence exists */ private boolean hasSequence(Subgraph graph) { int oddDegreeCount = 0; for (Iterator i = graph.nodeIterator(); i.hasNext(); ) { Node node = (Node) i.next(); if (node.getDegree() % 2 == 1) oddDegreeCount++; } return oddDegreeCount <= 2; } private List findSequence(Subgraph graph) { GraphComponent.setVisited(graph.edgeIterator(), false); Node startNode = findLowestDegreeNode(graph); DirectedEdge startDE = (DirectedEdge) startNode.getOutEdges().iterator().next(); DirectedEdge startDESym = startDE.getSym(); List seq = new LinkedList(); ListIterator lit = seq.listIterator(); addReverseSubpath(startDESym, lit, false); while (lit.hasPrevious()) { DirectedEdge prev = (DirectedEdge) lit.previous(); DirectedEdge unvisitedOutDE = findUnvisitedBestOrientedDE(prev.getFromNode()); if (unvisitedOutDE != null) addReverseSubpath(unvisitedOutDE.getSym(), lit, true); } /** * At this point, we have a valid sequence of graph DirectedEdges, but it * is not necessarily appropriately oriented relative to the underlying * geometry. */ List orientedSeq = orient(seq); return orientedSeq; } /** * Finds an {@link DirectedEdge} for an unvisited edge (if any), * choosing the dirEdge which preserves orientation, if possible. * * @param node the node to examine * @return the dirEdge found, or null if none were unvisited */ private static DirectedEdge findUnvisitedBestOrientedDE(Node node) { DirectedEdge wellOrientedDE = null; DirectedEdge unvisitedDE = null; for (Iterator i = node.getOutEdges().iterator(); i.hasNext(); ) { DirectedEdge de = (DirectedEdge) i.next(); if (! de.getEdge().isVisited()) { unvisitedDE = de; if (de.getEdgeDirection()) wellOrientedDE = de; } } if (wellOrientedDE != null) return wellOrientedDE; return unvisitedDE; } private void addReverseSubpath(DirectedEdge de, ListIterator lit, boolean expectedClosed) { // trace an unvisited path *backwards* from this de Node endNode = de.getToNode(); Node fromNode = null; while (true) { lit.add(de.getSym()); de.getEdge().setVisited(true); fromNode = de.getFromNode(); DirectedEdge unvisitedOutDE = findUnvisitedBestOrientedDE(fromNode); // this must terminate, since we are continually marking edges as visited if (unvisitedOutDE == null) break; de = unvisitedOutDE.getSym(); } if (expectedClosed) { // the path should end at the toNode of this de, otherwise we have an error Assert.isTrue(fromNode == endNode, "path not contiguous"); } } private static Node findLowestDegreeNode(Subgraph graph) { int minDegree = Integer.MAX_VALUE; Node minDegreeNode = null; for (Iterator i = graph.nodeIterator(); i.hasNext(); ) { Node node = (Node) i.next(); if (minDegreeNode == null || node.getDegree() < minDegree) { minDegree = node.getDegree(); minDegreeNode = node; } } return minDegreeNode; } /** * Computes a version of the sequence which is optimally * oriented relative to the underlying geometry. *

* Heuristics used are: *

    *
  • If the path has a degree-1 node which is the start * node of an linestring, use that node as the start of the sequence *
  • If the path has a degree-1 node which is the end * node of an linestring, use that node as the end of the sequence *
  • If the sequence has no degree-1 nodes, use any node as the start * (NOTE: in this case could orient the sequence according to the majority of the * linestring orientations) *
* * @param seq a List of DirectedEdges * @return a List of DirectedEdges oriented appropriately */ private List orient(List seq) { DirectedEdge startEdge = (DirectedEdge) seq.get(0); DirectedEdge endEdge = (DirectedEdge) seq.get(seq.size() - 1); Node startNode = startEdge.getFromNode(); Node endNode = endEdge.getToNode(); boolean flipSeq = false; boolean hasDegree1Node = startNode.getDegree() == 1 || endNode.getDegree() == 1; if (hasDegree1Node) { boolean hasObviousStartNode = false; // test end edge before start edge, to make result stable // (ie. if both are good starts, pick the actual start if (endEdge.getToNode().getDegree() == 1 && endEdge.getEdgeDirection() == false) { hasObviousStartNode = true; flipSeq = true; } if (startEdge.getFromNode().getDegree() == 1 && startEdge.getEdgeDirection() == true) { hasObviousStartNode = true; flipSeq = false; } // since there is no obvious start node, use any node of degree 1 if (! hasObviousStartNode) { // check if the start node should actually be the end node if (startEdge.getFromNode().getDegree() == 1) flipSeq = true; // if the end node is of degree 1, it is properly the end node } } // if there is no degree 1 node, just use the sequence as is // (Could insert heuristic of taking direction of majority of lines as overall direction) if (flipSeq) return reverse(seq); return seq; } /** * Reverse the sequence. * This requires reversing the order of the dirEdges, and flipping * each dirEdge as well * * @param seq a List of DirectedEdges, in sequential order * @return the reversed sequence */ private List reverse(List seq) { LinkedList newSeq = new LinkedList(); for (Iterator i = seq.iterator(); i.hasNext(); ) { DirectedEdge de = (DirectedEdge) i.next(); newSeq.addFirst(de.getSym()); } return newSeq; } /** * Builds a geometry ({@link LineString} or {@link MultiLineString} ) * representing the sequence. * * @param sequences a List of Lists of DirectedEdges with * LineMergeEdges as their parent edges. * @return the sequenced geometry, or null if no sequence exists */ private Geometry buildSequencedGeometry(List sequences) { List lines = new ArrayList(); for (Iterator i1 = sequences.iterator(); i1.hasNext(); ) { List seq = (List) i1.next(); for (Iterator i2 = seq.iterator(); i2.hasNext(); ) { DirectedEdge de = (DirectedEdge) i2.next(); LineMergeEdge e = (LineMergeEdge) de.getEdge(); LineString line = e.getLine(); LineString lineToAdd = line; if (! de.getEdgeDirection() && ! line.isClosed()) lineToAdd = reverse(line); lines.add(lineToAdd); } } if (lines.size() == 0) return factory.createMultiLineString(new LineString[0]); return factory.buildGeometry(lines); } private static LineString reverse(LineString line) { Coordinate[] pts = line.getCoordinates(); Coordinate[] revPts = new Coordinate[pts.length]; int len = pts.length; for (int i = 0; i < len; i++) { revPts[len - 1 - i] = new Coordinate(pts[i]); } return line.getFactory().createLineString(revPts); } }




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