Example #1
0
 public Graph(Cons lst) {
   //   System.out.println("Entering Graph()");
   //   for (Cons ptr = lst; ptr != null; ptr = Cons.rest(ptr) ) {
   //       if ( Cons.first(ptr) != null )
   //    System.out.println(Cons.first(ptr).toString()); }
   vertices = new TreeMap<String, Vertex>();
   // put all vertices in first
   for (Cons ptr = lst; ptr != null; ptr = Cons.rest(ptr)) {
     Cons item = (Cons) Cons.first(ptr);
     //         System.out.println("item = " + item.toString());
     Vertex node =
         vert((String) Cons.first(item), (Double) Cons.second(item), (Double) Cons.third(item));
   }
   for (Cons ptr = lst; ptr != null; ptr = Cons.rest(ptr)) {
     Cons item = (Cons) Cons.first(ptr);
     //         System.out.println("item = " + item.toString());
     Cons conns = (Cons) Cons.fourth(item);
     Vertex node = vertices.get((String) Cons.first(item));
     for (; conns != null; conns = Cons.rest(conns)) {
       Cons conn = (Cons) Cons.first(conns);
       //      System.out.println("conn = " + conn.toString());
       Vertex target = vertices.get((String) Cons.first(conn));
       node.add(target, (Integer) Cons.second(conn));
       target.add(node, (Integer) Cons.second(conn));
     }
   }
 }
Example #2
0
 public boolean hasEdge(Vertex v0, Vertex v1) {
   /* Validates that there is an Edge(v0,v1) in this graph.
   Returns true if adjMatric[v0][v1] is true. */
   int origin = v0.getId();
   int dest = v1.getId();
   return adjMatrix[origin][dest];
 }
Example #3
0
  public Flexible copyToGroup(String group) {

    String newName;
    if (group.equals(nullString)) newName = Group.substractObjectName(getName());
    else newName = group + Constants.GROUP_SEPARATOR + Group.substractObjectName(getName());

    // object with new name already exists, add suffix ///!!!
    while (Group.getRoot().findObject(newName, true) != null)
      newName = StringUtils.incrementName(newName, Constants.COPY_SUFFIX);

    Box grBox =
        new Box(
            newName,
            null,
            startVertex.getX(),
            startVertex.getY(),
            endVertex.getX(),
            endVertex.getY());
    grBox.setColor(getColor());
    Group.getRoot().addSubObject(newName, grBox, true);

    // ViewState view = ViewState.getInstance();
    // grBox.move(20 - view.getRx(), 20 - view.getRy());

    unconditionalValidation();
    return grBox;
  }
Example #4
0
 /**
  * This returns an enumeration of all Darts in Graph G in a canonical order starting with
  * firstDart. The order is canonical in the sense that it only depends on the oriented isomorphism
  * class of G (and firstDart). That is, if there is an oriented iso G <-> G' sending firstDart <->
  * firstDart', then that bijection will send getDarts <-> getDarts'.
  *
  * <p>This enumeration is useful in finding explicit bijections of isomorphic graphs.
  */
 public static Dart[] getDarts(Dart firstDart, Graph G) {
   /**
    * Description of algorithm: Return all the couples around V0=firstDart.V, then all couples
    * around V1, .... The order for couples around firstDart.V is counterclockwise starting with
    * firstDart.F. clockwise around V1,... So we need to order the vertices V0,V1,... and pick the
    * first face to use at each vertex and the rest is determined. Order on V0,... = first
    * encountered. Order on faces at vertex = first encountered.
    */
   distinctFIFO vQueue = new distinctFIFO();
   util.ConditionGetter fQueue = new util.ConditionGetter();
   fQueue.add(firstDart.getF());
   vQueue.put(firstDart.getV());
   Collection coups = new ArrayList();
   int coupsIndex = 0;
   Vertex V;
   while ((V = (Vertex) vQueue.remove()) != null) {
     Face F = (Face) fQueue.get(new incidence(V));
     for (int i = 0; i < V.size(); i++) {
       Face Fx = V.next(F, i);
       coups.add(new Dart(V, Fx));
       vQueue.put(Fx.next(V, 1));
       fQueue.add(Fx);
     }
   }
   return (Dart[]) coups.toArray(new Dart[coups.size()]);
 }
Example #5
0
  public GraphIndex(Graph graph) {
    LOG.info("Indexing graph...");

    for (String feedId : graph.getFeedIds()) {
      for (Agency agency : graph.getAgencies(feedId)) {
        Map<String, Agency> agencyForId = agenciesForFeedId.getOrDefault(feedId, new HashMap<>());
        agencyForId.put(agency.getId(), agency);
        this.agenciesForFeedId.put(feedId, agencyForId);
      }
    }

    Collection<Edge> edges = graph.getEdges();
    /* We will keep a separate set of all vertices in case some have the same label.
     * Maybe we should just guarantee unique labels. */
    Set<Vertex> vertices = Sets.newHashSet();
    for (Edge edge : edges) {
      vertices.add(edge.getFromVertex());
      vertices.add(edge.getToVertex());
      if (edge instanceof TablePatternEdge) {
        TablePatternEdge patternEdge = (TablePatternEdge) edge;
        TripPattern pattern = patternEdge.getPattern();
        patternForId.put(pattern.code, pattern);
      }
    }
    for (Vertex vertex : vertices) {
      vertexForId.put(vertex.getLabel(), vertex);
      if (vertex instanceof TransitStop) {
        TransitStop transitStop = (TransitStop) vertex;
        Stop stop = transitStop.getStop();
        stopForId.put(stop.getId(), stop);
        stopVertexForStop.put(stop, transitStop);
        stopsForParentStation.put(stop.getParentStation(), stop);
      }
    }
    for (TransitStop stopVertex : stopVertexForStop.values()) {
      Envelope envelope = new Envelope(stopVertex.getCoordinate());
      stopSpatialIndex.insert(envelope, stopVertex);
    }
    for (TripPattern pattern : patternForId.values()) {
      patternsForFeedId.put(pattern.getFeedId(), pattern);
      patternsForRoute.put(pattern.route, pattern);

      for (Trip trip : pattern.getTrips()) {
        patternForTrip.put(trip, pattern);
        tripForId.put(trip.getId(), trip);
      }
      for (Stop stop : pattern.getStops()) {
        patternsForStop.put(stop, pattern);
      }
    }
    for (Route route : patternsForRoute.asMap().keySet()) {
      routeForId.put(route.getId(), route);
    }

    // Copy these two service indexes from the graph until we have better ones.
    calendarService = graph.getCalendarService();
    serviceCodes = graph.serviceCodes;
    this.graph = graph;
    LOG.info("Done indexing graph.");
  }
Example #6
0
  /**
   * This constructor accepts an ArrayList<Vertex> and populates this.vertices. If multiple Vertex
   * objects have the same label, then the last Vertex with the given label is used.
   *
   * @param vertices The initial Vertices to populate this Graph
   */
  public Graph(ArrayList<Vertex> vertices) {
    this.vertices = new HashMap<String, Vertex>();
    this.edges = new HashMap<Integer, Edge>();

    for (Vertex v : vertices) {
      this.vertices.put(v.getLabel(), v);
    }
  }
Example #7
0
 public boolean addVertex(Vertex<T> v) {
   boolean added = false;
   if (!verticesHash.containsKey(v.getName())) {
     added = vertices.add(v);
     verticesHash.put(v.getName(), v);
   }
   return added;
 }
Example #8
0
 public boolean removeEdge(Vertex<T> from, Vertex<T> to) {
   Edge<T> e = from.findEdge(to);
   if (e == null) return false;
   else {
     from.remove(e);
     return true;
   }
 }
Example #9
0
  public void destroy() {
    super.destroy();
    if (getParent() != null) getParent().removeObject(Group.substractObjectName(name));

    if (!startVertex.isDestroyed()) startVertex.destroy();

    if (!endVertex.isDestroyed()) endVertex.destroy();
  }
Example #10
0
 public void print() {
   Collection c = vertices.values();
   Iterator itr = c.iterator();
   while (itr.hasNext()) {
     Vertex v = (Vertex) itr.next();
     v.print();
   }
 }
Example #11
0
 public int pathcost(Vertex v) {
   int pathcost = v.cost;
   while (v.parent()
       != null) { // walks from the v to the root and sums the cost of each edge in between
     pathcost += v.parent().cost();
     v = v.parent();
   }
   return pathcost;
 }
Example #12
0
  /**
   * @param label The label of the Vertex to remove
   * @return Vertex The removed Vertex object
   */
  public Vertex removeVertex(String label) {
    Vertex v = vertices.remove(label);

    while (v.getNeighborCount() > 0) {
      this.removeEdge(v.getNeighbor((0)));
    }

    return v;
  }
Example #13
0
  public void revalidatePosition() {
    startVertex.revalidatePosition();
    endVertex.revalidatePosition();

    double rscale = getRscale();

    setRx((int) (getX() * rscale));
    setRy((int) (getY() * rscale));
  }
Example #14
0
 public void addEdge(Vertex v0, Vertex v1) {
   /* Adds an edge to the adjacency matrix */
   if (hasVertex(v0) && hasVertex(v1)) {
     int origin = v0.getId();
     int dest = v1.getId();
     adjMatrix[origin][dest] = true;
     edges++;
   }
 }
  /** Code to test the correctness of the SimpleGraph methods. */
  public static void main(String[] args) {
    // create graph a----b-----c,
    //                X     Y
    // X and Y are objects stored at edges. .

    // All Objects stored will be strings.

    SimpleGraph G = new SimpleGraph();
    Vertex v, w, a, b, c;
    Edge e, x, y;
    v = G.insertVertex(null, "a");
    a = v;
    w = G.insertVertex(null, "b");
    b = w;
    e = G.insertEdge(a, b, null, "X");
    x = e;
    v = G.insertVertex(null, "c");
    c = v;
    e = G.insertEdge(b, c, null, "Y");
    y = e;

    Iterator i;

    System.out.println("Iterating through vertices...");
    for (i = G.vertices(); i.hasNext(); ) {
      v = (Vertex) i.next();
      System.out.println("found vertex " + v.getName());
    }

    System.out.println("Iterating through adjacency lists...");
    for (i = G.vertices(); i.hasNext(); ) {
      v = (Vertex) i.next();
      System.out.println("Vertex " + v.getName());
      Iterator j;

      for (j = G.incidentEdges(v); j.hasNext(); ) {
        e = (Edge) j.next();
        System.out.println("  found edge " + e.getName());
      }
    }

    System.out.println("Testing opposite...");
    System.out.println("aXbYc is ");
    System.out.println(a);
    System.out.println(x);
    System.out.println(b);
    System.out.println(y);
    System.out.println(c);

    System.out.println("opposite(a,x) is " + G.opposite(a, x));
    System.out.println("opposite(a,y) is " + G.opposite(a, y));
    System.out.println("opposite(b,x) is " + G.opposite(b, x));
    System.out.println("opposite(b,y) is " + G.opposite(b, y));
    System.out.println("opposite(c,x) is " + G.opposite(c, x));
    System.out.println("opposite(c,y) is " + G.opposite(c, y));
  }
 private void computeMatchSet() {
   for (Vertex v : LV) {
     for (Vertex neighb : v.getNeighbors()) {
       if (neighb.getId() != SOURCE_ID && getFlow(v, neighb) > 0) {
         matches.add(v);
         matches.add(neighb);
       }
     }
   }
 }
Example #17
0
  @Override
  public Iterable<String> findRelatedEdges(
      Iterable<String> vertexIds, Authorizations authorizations) {
    Set<String> results = new HashSet<String>();
    List<Vertex> vertices = toList(getVertices(vertexIds, authorizations));

    // since we are checking bi-directional edges we should only have to check v1->v2 and not v2->v1
    Map<String, String> checkedCombinations = new HashMap<String, String>();

    for (Vertex sourceVertex : vertices) {
      for (Vertex destVertex : vertices) {
        if (checkedCombinations.containsKey(sourceVertex.getId() + destVertex.getId())) {
          continue;
        }
        Iterable<String> edgeIds =
            sourceVertex.getEdgeIds(destVertex, Direction.BOTH, authorizations);
        for (String edgeId : edgeIds) {
          results.add(edgeId);
        }
        checkedCombinations.put(sourceVertex.getId() + destVertex.getId(), "");
        checkedCombinations.put(destVertex.getId() + sourceVertex.getId(), "");
      }
    }
    return results;
  }
Example #18
0
 @Override
 public Vertex getVertex(
     String vertexId, EnumSet<FetchHint> fetchHints, Authorizations authorizations) {
   LOGGER.warn("Performing scan of all vertices! Override getVertex.");
   for (Vertex vertex : getVertices(fetchHints, authorizations)) {
     if (vertex.getId().equals(vertexId)) {
       return vertex;
     }
   }
   return null;
 }
Example #19
0
  protected void validate() {
    startVertex.validate();
    endVertex.validate();

    revalidatePosition();

    double rscale = getRscale();

    setRwidth((int) (getWidth() * rscale));
    setRheight((int) (getHeight() * rscale));
  }
Example #20
0
 public String verticesToString() {
   String result = "List of vertices\n";
   Iterator it = this.vertices.iterator();
   int cont = 0;
   while (it.hasNext()) {
     Vertex v = (Vertex) it.next();
     result = result + "v" + cont + " " + v.getPoint().toString() + "\n";
     cont++;
   }
   return result;
 }
Example #21
0
  /**
   * creates a new triangle facet within the hole incident to h by connecting the tip of h with two
   * new halfedges and a new vertex. Returns the halfedge of the new edge that is incident to the
   * new facet and the new vertex.
   */
  public Halfedge<X> addTriangleToBorder(Halfedge h, X point) {
    if (h.face != null) throw new Error("no border edge");
    System.out.println("adding triangle to " + h);

    Face<X> newFace = new Face<X>();
    Vertex<X> newVertex = new Vertex<X>(point);
    Halfedge<X> hPrev = new Halfedge<X>();
    Halfedge<X> hNext = new Halfedge<X>();
    Halfedge<X> hPrevOpp = new Halfedge<X>();
    Halfedge<X> hNextOpp = new Halfedge<X>();

    // setting the new face
    newFace.setEdge(h);
    // setting hPrev (halfedge preceding h in the new face)
    hPrev.setFace(newFace);
    hPrev.setVertex(h.getOpposite().getVertex());
    hPrev.setPrev(hNext);
    hPrev.setNext(h);
    hPrev.setOpposite(hPrevOpp);
    // setting hNext (halfedge following h in the new face)
    hNext.setFace(newFace);
    hNext.setVertex(newVertex);
    hNext.setPrev(h);
    hNext.setNext(hPrev);
    hNext.setOpposite(hNextOpp);
    // setting hPrevOpp (new boundary halfedge)
    hPrevOpp.setFace(null);
    hPrevOpp.setVertex(newVertex);
    hPrevOpp.setPrev(h.getPrev());
    hPrevOpp.setNext(hNextOpp);
    hPrevOpp.setOpposite(hPrev);
    // setting hNextOpp (the other new boundary halfedge)
    hNextOpp.setFace(null);
    hNextOpp.setVertex(h.getVertex());
    hNextOpp.setPrev(hPrevOpp);
    hNextOpp.setNext(h.getNext());
    hNextOpp.setOpposite(hNext);
    // updating old boundary halfedge informations
    h.setFace(newFace);
    h.setPrev(hPrev);
    h.setNext(hNext);
    // setting newVertex
    newVertex.setEdge(hPrev); // LCA: a controler si c'est hPrev ou hNext

    // adding new facet, vertex and the four halfedges
    this.vertices.add(newVertex);
    this.facets.add(newFace);
    this.halfedges.add(hPrev);
    this.halfedges.add(hNext);
    this.halfedges.add(hPrevOpp);
    this.halfedges.add(hNextOpp);

    return hNext;
  }
Example #22
0
 public void relaxEdges(FibonacciHeap<Vertex> unvisited) {
   Vertex[] vertices = Graph.this.vertices;
   for (Edge edge : edges) {
     Vertex to = vertices[edge.to];
     int newDistance = distance + edge.cost;
     if (newDistance < to.distance) {
       to.distance = newDistance;
       unvisited.decreaseKey(to.heapEntry, newDistance);
     }
   }
 }
Example #23
0
 /**
  * Method to find the DFS traversal for the Graph
  *
  * @param G : Input Graph G - undirected graph
  * @return : Returns the count for checking connected components
  */
 static int dfsUtil(Graph<Vertex> G) {
   for (Vertex u : G) {
     u.seen = false;
     u.parent = null;
   }
   int cno = 0; // Initializing count variable to check for connected components
   for (Vertex u : G) {
     if (!u.seen) dfsVisit(u, ++cno);
   }
   return cno;
 }
Example #24
0
 /**
  * Method to do the DFS traversal - Recursive call
  *
  * @param u: Vertex for which the DFS checks the adjacency list.
  * @param cno: Count variable to keep the number of connected components.
  */
 static void dfsVisit(Vertex u, int cno) {
   u.seen = true;
   u.cno = cno;
   for (Edge e : u.Adj) {
     Vertex v = e.otherEnd(u);
     if (!v.seen) {
       v.parent = u;
       dfsVisit(v, cno);
     }
   }
 }
Example #25
0
  public boolean move(int dx, int dy) {
    if (checkMove(dx, dy)) {
      startVertex.move(dx, dy);
      endVertex.move(dx, dy);

      revalidatePosition();

      return true;
    }

    return false;
  }
Example #26
0
 public boolean addEdge(Vertex<T> from, Vertex<T> to, int cost) throws IllegalArgumentException {
   if (!verticesHash.containsKey(from.getName()))
     throw new IllegalArgumentException("from is not in graph");
   if (!verticesHash.containsKey(to.getName()))
     throw new IllegalArgumentException("to is not in graph");
   Edge<T> e = new Edge<T>(from, to, cost);
   if (from.findEdge(to) != null) return false;
   else {
     from.addEdge(e);
     return true;
   }
 }
Example #27
0
  private static List<Vertex> getPath(Vertex target) {
    List<Vertex> path = new LinkedList<Vertex>();

    path.add(target);
    Vertex next = target;
    while (next.getPrevious().getMinDistance() != 0) {
      path.add(next.getPrevious());
      next = next.getPrevious();
    }

    Collections.reverse(path);
    return path;
  }
 public VertexInfoDialog(Vertex vertex) {
   v = vertex;
   setTitle("Vertex: " + v.getName());
   Container cp = getContentPane();
   JPanel p = new JPanel();
   p.setLayout(new GridLayout(1, 1));
   opis = new TextArea(v.getInfo());
   opis.setEditable(false);
   p.add(opis, new FlowLayout());
   cp.add(p);
   setSize(200, 300);
   setDefaultCloseOperation(DISPOSE_ON_CLOSE);
 }
  private void konigDFS(Set<Vertex> konigSet, Vertex v, boolean edgesInMatch) {
    if (!konigSet.contains(v)) {
      konigSet.add(v);

      for (Vertex neighb : v.getNeighbors()) {
        if (neighb.getId() != SOURCE_ID && neighb.getId() != SINK_ID) {
          if (edgesInMatch == (getFlow(v, neighb) > 0 || getFlow(neighb, v) > 0)) {
            konigDFS(konigSet, neighb, !edgesInMatch);
          }
        }
      }
    }
  }
  private void setupSinkSide(Set<Employee> emps) {
    for (Employee e : emps) {
      Vertex u = Vertex.vertexFromEmployee(e);
      RV.add(u);

      sink.addToNeighbors(u);
      u.addToNeighbors(sink);

      setCapacity(u, sink, 1);
      setFlow(u, sink, 0);
      V.add(u);
    }
  }