Java tutorial
package cl.ucn.disc.zoome.zui.layout; /* * Created on Apr 15, 2007 * * Copyright (c) 2007, the JUNG Project and the Regents of the University * of California * All rights reserved. * * This software is open-source under the BSD license; see either * "license.txt" or * http://jung.sourceforge.net/license.txt for a description. */ // This class derived from SparseGraph was modified to keep the order or vertices and edges import java.util.ArrayList; import java.util.Collection; import java.util.Collections; import java.util.HashMap; import java.util.HashSet; import java.util.LinkedHashMap; import java.util.Map; import org.apache.commons.collections15.Factory; import edu.uci.ics.jung.graph.AbstractGraph; import edu.uci.ics.jung.graph.Graph; import edu.uci.ics.jung.graph.util.EdgeType; import edu.uci.ics.jung.graph.util.Pair; /** * An implementation of <code>Graph</code> that is suitable for sparse graphs and * permits both directed and undirected edges. */ @SuppressWarnings("serial") public class OrderedSparseGraph<V, E> extends AbstractGraph<V, E> implements Graph<V, E> { /** * Returns a {@code Factory} that creates an instance of this graph type. * @param <V> the vertex type for the graph factory * @param <E> the edge type for the graph factory */ public static <V, E> Factory<Graph<V, E>> getFactory() { return new Factory<Graph<V, E>>() { public Graph<V, E> create() { return new OrderedSparseGraph<V, E>(); } }; } protected static final int INCOMING = 0; protected static final int OUTGOING = 1; protected static final int INCIDENT = 2; protected Map<V, Map<V, E>[]> vertex_maps; // Map of vertices to adjacency maps of vertices to {incoming, outgoing, incident} edges protected Map<E, Pair<V>> directed_edges; // Map of directed edges to incident vertex sets protected Map<E, Pair<V>> undirected_edges; // Map of undirected edges to incident vertex sets /** * Creates an instance. */ public OrderedSparseGraph() { vertex_maps = new LinkedHashMap<V, Map<V, E>[]>(); directed_edges = new LinkedHashMap<E, Pair<V>>(); undirected_edges = new LinkedHashMap<E, Pair<V>>(); } @Override public E findEdge(V v1, V v2) { if (!containsVertex(v1) || !containsVertex(v2)) return null; E edge = vertex_maps.get(v1)[OUTGOING].get(v2); if (edge == null) edge = vertex_maps.get(v1)[INCIDENT].get(v2); return edge; } @Override public Collection<E> findEdgeSet(V v1, V v2) { if (!containsVertex(v1) || !containsVertex(v2)) return null; Collection<E> edges = new ArrayList<E>(2); E e1 = vertex_maps.get(v1)[OUTGOING].get(v2); if (e1 != null) edges.add(e1); E e2 = vertex_maps.get(v1)[INCIDENT].get(v2); if (e1 != null) edges.add(e2); return edges; } @Override public boolean addEdge(E edge, Pair<? extends V> endpoints, EdgeType edgeType) { Pair<V> new_endpoints = getValidatedEndpoints(edge, endpoints); if (new_endpoints == null) return false; V v1 = new_endpoints.getFirst(); V v2 = new_endpoints.getSecond(); // undirected edges and directed edges are not considered to be parallel to each other, // so as long as anything that's returned by findEdge is not of the same type as // edge, we're fine E connection = findEdge(v1, v2); if (connection != null && getEdgeType(connection) == edgeType) return false; if (!containsVertex(v1)) this.addVertex(v1); if (!containsVertex(v2)) this.addVertex(v2); // map v1 to <v2, edge> and vice versa if (edgeType == EdgeType.DIRECTED) { vertex_maps.get(v1)[OUTGOING].put(v2, edge); vertex_maps.get(v2)[INCOMING].put(v1, edge); directed_edges.put(edge, new_endpoints); } else { vertex_maps.get(v1)[INCIDENT].put(v2, edge); vertex_maps.get(v2)[INCIDENT].put(v1, edge); undirected_edges.put(edge, new_endpoints); } return true; } public Collection<E> getInEdges(V vertex) { if (!containsVertex(vertex)) return null; // combine directed inedges and undirected Collection<E> in = new HashSet<E>(vertex_maps.get(vertex)[INCOMING].values()); in.addAll(vertex_maps.get(vertex)[INCIDENT].values()); return Collections.unmodifiableCollection(in); } public Collection<E> getOutEdges(V vertex) { if (!containsVertex(vertex)) return null; // combine directed outedges and undirected Collection<E> out = new HashSet<E>(vertex_maps.get(vertex)[OUTGOING].values()); out.addAll(vertex_maps.get(vertex)[INCIDENT].values()); return Collections.unmodifiableCollection(out); } public Collection<V> getPredecessors(V vertex) { if (!containsVertex(vertex)) return null; // consider directed inedges and undirected Collection<V> preds = new HashSet<V>(vertex_maps.get(vertex)[INCOMING].keySet()); preds.addAll(vertex_maps.get(vertex)[INCIDENT].keySet()); return Collections.unmodifiableCollection(preds); } public Collection<V> getSuccessors(V vertex) { if (!containsVertex(vertex)) return null; // consider directed outedges and undirected Collection<V> succs = new HashSet<V>(vertex_maps.get(vertex)[OUTGOING].keySet()); succs.addAll(vertex_maps.get(vertex)[INCIDENT].keySet()); return Collections.unmodifiableCollection(succs); } public Collection<E> getEdges(EdgeType edgeType) { if (edgeType == EdgeType.DIRECTED) return Collections.unmodifiableCollection(directed_edges.keySet()); else if (edgeType == EdgeType.UNDIRECTED) return Collections.unmodifiableCollection(undirected_edges.keySet()); else return null; } public Pair<V> getEndpoints(E edge) { Pair<V> endpoints; endpoints = directed_edges.get(edge); if (endpoints == null) return undirected_edges.get(edge); else return endpoints; } public EdgeType getEdgeType(E edge) { if (directed_edges.containsKey(edge)) return EdgeType.DIRECTED; else if (undirected_edges.containsKey(edge)) return EdgeType.UNDIRECTED; else return null; } public V getSource(E directed_edge) { if (getEdgeType(directed_edge) == EdgeType.DIRECTED) return directed_edges.get(directed_edge).getFirst(); else return null; } public V getDest(E directed_edge) { if (getEdgeType(directed_edge) == EdgeType.DIRECTED) return directed_edges.get(directed_edge).getSecond(); else return null; } public boolean isSource(V vertex, E edge) { if (!containsVertex(vertex) || !containsEdge(edge)) return false; V source = getSource(edge); if (source != null) return source.equals(vertex); else return false; } public boolean isDest(V vertex, E edge) { if (!containsVertex(vertex) || !containsEdge(edge)) return false; V dest = getDest(edge); if (dest != null) return dest.equals(vertex); else return false; } public Collection<E> getEdges() { Collection<E> edges = new ArrayList<E>(directed_edges.keySet()); edges.addAll(undirected_edges.keySet()); return Collections.unmodifiableCollection(edges); } public Collection<V> getVertices() { return Collections.unmodifiableCollection(vertex_maps.keySet()); } public boolean containsVertex(V vertex) { return vertex_maps.containsKey(vertex); } public boolean containsEdge(E edge) { return directed_edges.containsKey(edge) || undirected_edges.containsKey(edge); } public int getEdgeCount() { return directed_edges.size() + undirected_edges.size(); } public int getVertexCount() { return vertex_maps.size(); } public Collection<V> getNeighbors(V vertex) { if (!containsVertex(vertex)) return null; // consider directed edges and undirected edges Collection<V> neighbors = new HashSet<V>(vertex_maps.get(vertex)[INCOMING].keySet()); neighbors.addAll(vertex_maps.get(vertex)[OUTGOING].keySet()); neighbors.addAll(vertex_maps.get(vertex)[INCIDENT].keySet()); return Collections.unmodifiableCollection(neighbors); } public Collection<E> getIncidentEdges(V vertex) { if (!containsVertex(vertex)) return null; Collection<E> incident = new HashSet<E>(vertex_maps.get(vertex)[INCOMING].values()); incident.addAll(vertex_maps.get(vertex)[OUTGOING].values()); incident.addAll(vertex_maps.get(vertex)[INCIDENT].values()); return Collections.unmodifiableCollection(incident); } @SuppressWarnings("unchecked") public boolean addVertex(V vertex) { if (vertex == null) { throw new IllegalArgumentException("vertex may not be null"); } if (!containsVertex(vertex)) { vertex_maps.put(vertex, new HashMap[] { new HashMap<V, E>(), new HashMap<V, E>(), new HashMap<V, E>() }); return true; } else { return false; } } public boolean removeVertex(V vertex) { if (!containsVertex(vertex)) return false; // copy to avoid concurrent modification in removeEdge Collection<E> incident = new ArrayList<E>(getIncidentEdges(vertex)); for (E edge : incident) removeEdge(edge); vertex_maps.remove(vertex); return true; } public boolean removeEdge(E edge) { if (!containsEdge(edge)) return false; Pair<V> endpoints = getEndpoints(edge); V v1 = endpoints.getFirst(); V v2 = endpoints.getSecond(); // remove edge from incident vertices' adjacency maps if (getEdgeType(edge) == EdgeType.DIRECTED) { vertex_maps.get(v1)[OUTGOING].remove(v2); vertex_maps.get(v2)[INCOMING].remove(v1); directed_edges.remove(edge); } else { vertex_maps.get(v1)[INCIDENT].remove(v2); vertex_maps.get(v2)[INCIDENT].remove(v1); undirected_edges.remove(edge); } return true; } public int getEdgeCount(EdgeType edge_type) { if (edge_type == EdgeType.DIRECTED) return directed_edges.size(); if (edge_type == EdgeType.UNDIRECTED) return undirected_edges.size(); return 0; } public EdgeType getDefaultEdgeType() { return EdgeType.UNDIRECTED; } }