Examples with EdgeWeightedGraph chapter4.section3.EdgeWeightedGraph used on opensource projects

Example 1 with EdgeWeightedGraph

use of chapter4.section3.EdgeWeightedGraph in project algorithms-sedgewick-wayne by reneargento.

the class Exercise26_CriticalEdges method findCriticalEdges.

/**
 * An edge e is critical if and only if it is a bridge in the subgraph containing all edges with weights
 * less than or equal to the weight of edge e.
 *
 * Proof:
 * 1st part: If an edge e is critical then it is a bridge in the subgraph containing all edges with weights
 * less than or equal to the weight of edge e.
 * Consider by contradiction that edge e is not a bridge in such subgraph. If it is not a bridge, then there is another
 * edge f that connects the same components as e in the subgraph and it has weight less than or equal to e.
 * In this case, edge e could be replaced by edge f in an MST and the MST weight would not increase.
 * However, since e is critical and cannot be replaced by an edge with weight less than or equal to it,
 * it must be a bridge in the subgraph.
 *
 * 2nd part: If an edge e is a bridge in the subgraph containing all edges with weights less than or equal to its
 * weight then e is critical.
 * Consider by contradiction that e is not critical. If e is not critical, then there must be another edge that
 * could replace it in an MST and would not cause the MST weight to increase.
 * However, if this edge existed, it would be part of the subgraph containing all edges with weights
 * less than or equal to the weight of edge e. It would also connect both components C1 and C2 that are connected
 * by edge e. However, e is a bridge and its removal would split components C1 and C2. So no such edge exists.
 * Therefore, edge e is critical.
 */
// O(E lg E)
public Queue<Edge> findCriticalEdges(EdgeWeightedGraph edgeWeightedGraph) {
    Queue<Edge> criticalEdges = new Queue<>();
    // Modified Kruskal's algorithm
    Queue<Edge> minimumSpanningTree = new Queue<>();
    PriorityQueueResize<Edge> priorityQueue = new PriorityQueueResize<>(PriorityQueueResize.Orientation.MIN);
    for (Edge edge : edgeWeightedGraph.edges()) {
        priorityQueue.insert(edge);
    }
    UnionFind unionFind = new UnionFind(edgeWeightedGraph.vertices());
    // Subgraph with components
    EdgeWeightedGraphWithDelete componentsSubGraph = new EdgeWeightedGraphWithDelete(unionFind.count());
    while (!priorityQueue.isEmpty() && minimumSpanningTree.size() < edgeWeightedGraph.vertices() - 1) {
        Edge edge = priorityQueue.deleteTop();
        int vertex1 = edge.either();
        int vertex2 = edge.other(vertex1);
        // Ineligible edges are never critical edges
        if (unionFind.connected(vertex1, vertex2)) {
            continue;
        }
        // Get next equal-weight edge block
        double currentWeight = edge.weight();
        HashSet<Edge> equalWeightEdges = new HashSet<>();
        equalWeightEdges.add(edge);
        while (!priorityQueue.isEmpty() && priorityQueue.peek().weight() == currentWeight) {
            equalWeightEdges.add(priorityQueue.deleteTop());
        }
        if (equalWeightEdges.size() == 1) {
            // There is no cycle, so this is a critical edge
            criticalEdges.enqueue(edge);
            unionFind.union(vertex1, vertex2);
            minimumSpanningTree.enqueue(edge);
            continue;
        }
        List<Edge> edgesToAddToComponentsSubGraph = new ArrayList<>();
        // Map to make the mapping between edges in the components subgraph and the original graph
        int averageMapListSize = Math.max(2, equalWeightEdges.size() / 20);
        SeparateChainingHashTable<Edge, Edge> subGraphToGraphEdgeMap = new SeparateChainingHashTable<>(equalWeightEdges.size(), averageMapListSize);
        HashSet<Integer> verticesInSubGraph = new HashSet<>();
        // Generate subgraph with the current components
        for (Edge edgeInCurrentBlock : equalWeightEdges.keys()) {
            vertex1 = edgeInCurrentBlock.either();
            vertex2 = edgeInCurrentBlock.other(vertex1);
            int component1 = unionFind.find(vertex1);
            int component2 = unionFind.find(vertex2);
            Edge subGraphEdge = new Edge(component1, component2, currentWeight);
            edgesToAddToComponentsSubGraph.add(subGraphEdge);
            subGraphToGraphEdgeMap.put(subGraphEdge, edgeInCurrentBlock);
            verticesInSubGraph.add(component1);
            verticesInSubGraph.add(component2);
        }
        for (Edge edgeToAddToComponentSubGraph : edgesToAddToComponentsSubGraph) {
            componentsSubGraph.addEdge(edgeToAddToComponentSubGraph);
        }
        // Run DFS to check if there is a cycle. Any edges in the cycle are non-critical.
        // Every edge in the original graph will be visited by a DFS at most once.
        HashSet<Edge> nonCriticalEdges = new HashSet<>();
        // Use a different constructor for EdgeWeightedCycle to avoid O(E * V) runtime
        EdgeWeightedCycle edgeWeightedCycle = new EdgeWeightedCycle(componentsSubGraph, verticesInSubGraph);
        if (edgeWeightedCycle.hasCycle()) {
            for (Edge edgeInCycle : edgeWeightedCycle.cycle()) {
                Edge edgeInGraph = subGraphToGraphEdgeMap.get(edgeInCycle);
                nonCriticalEdges.add(edgeInGraph);
            }
        }
        // Clear components subgraph edges
        for (Edge edgeToAddToComponentSubGraph : edgesToAddToComponentsSubGraph) {
            componentsSubGraph.deleteEdge(edgeToAddToComponentSubGraph);
        }
        // Add all edges that belong to an MST to the MST
        for (Edge edgeInCurrentBlock : equalWeightEdges.keys()) {
            if (!nonCriticalEdges.contains(edgeInCurrentBlock)) {
                criticalEdges.enqueue(edgeInCurrentBlock);
            }
            vertex1 = edgeInCurrentBlock.either();
            vertex2 = edgeInCurrentBlock.other(vertex1);
            if (!unionFind.connected(vertex1, vertex2)) {
                unionFind.union(vertex1, vertex2);
                // Add edge to the minimum spanning tree
                minimumSpanningTree.enqueue(edge);
            }
        }
    }
    return criticalEdges;
}

Example 2 with EdgeWeightedGraph

use of chapter4.section3.EdgeWeightedGraph in project algorithms-sedgewick-wayne by reneargento.

the class Exercise31_AllPairsShortestPathsOnALine method main.

public static void main(String[] args) {
    EdgeWeightedGraph edgeWeightedGraph = new EdgeWeightedGraph(5);
    edgeWeightedGraph.addEdge(new Edge(0, 1, 2));
    edgeWeightedGraph.addEdge(new Edge(1, 2, 3));
    edgeWeightedGraph.addEdge(new Edge(2, 3, 4));
    edgeWeightedGraph.addEdge(new Edge(3, 4, 1));
    AllPairsShortestPathsOnALine allPairsShortestPathsOnALine = new Exercise31_AllPairsShortestPathsOnALine().new AllPairsShortestPathsOnALine(edgeWeightedGraph);
    double[][] expectedDistances = { { 0, 2, 5, 9, 10 }, { 2, 0, 3, 7, 8 }, { 5, 3, 0, 4, 5 }, { 9, 7, 4, 0, 1 }, { 10, 8, 5, 1, 0 } };
    for (int source = 0; source < edgeWeightedGraph.vertices(); source++) {
        for (int target = 0; target < edgeWeightedGraph.vertices(); target++) {
            StdOut.println("Distance from " + source + " to " + target + ": " + allPairsShortestPathsOnALine.dist(source, target) + " Expected: " + expectedDistances[source][target]);
        }
    }
}