429 lines
15 KiB
Java
429 lines
15 KiB
Java
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import edu.princeton.cs.introcs.StdRandom;
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/*************************************************************************
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* Compilation: javac DigraphGenerator.java
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* Execution: java DigraphGenerator V E
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* Dependencies: Digraph.java
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*
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* A digraph generator.
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*
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*************************************************************************/
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/**
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* The DigraphGenerator class provides static methods for creating
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* various digraphs, including Erdos-Renyi random digraphs, random DAGs,
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* random rooted trees, random rooted DAGs, random tournaments, path digraphs,
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* cycle digraphs, and the complete digraph.
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*
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* For additional documentation, see <a href="http://algs4.cs.princeton.edu/42digraph">Section 4.2</a> of
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* Algorithms, 4th Edition by Robert Sedgewick and Kevin Wayne.
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*
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* @author Robert Sedgewick
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* @author Kevin Wayne
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*/
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public class DigraphGenerator {
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private static final class Edge implements Comparable<Edge> {
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private int v;
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private int w;
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private Edge(int v, int w) {
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this.v = v;
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this.w = w;
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}
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public int compareTo(Edge that) {
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if (this.v < that.v) return -1;
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if (this.v > that.v) return +1;
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if (this.w < that.w) return -1;
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if (this.w > that.w) return +1;
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return 0;
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}
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}
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/**
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* Returns a random simple digraph containing V vertices and E edges.
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* @param V the number of vertices
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* @param E the number of vertices
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* @return a random simple digraph on V vertices, containing a total
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* of E edges
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* @throws IllegalArgumentException if no such simple digraph exists
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*/
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public static Digraph simple(int V, int E) {
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if (E > (long) V*(V-1)) throw new IllegalArgumentException("Too many edges");
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if (E < 0) throw new IllegalArgumentException("Too few edges");
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Digraph G = new Digraph(V);
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SET<Edge> set = new SET<Edge>();
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while (G.E() < E) {
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int v = StdRandom.uniform(V);
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int w = StdRandom.uniform(V);
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Edge e = new Edge(v, w);
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if ((v != w) && !set.contains(e)) {
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set.add(e);
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G.addEdge(v, w);
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}
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}
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return G;
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}
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/**
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* Returns a random simple digraph on V vertices, with an
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* edge between any two vertices with probability p . This is sometimes
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* referred to as the Erdos-Renyi random digraph model.
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* This implementations takes time propotional to V^2 (even if p is small).
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* @param V the number of vertices
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* @param p the probability of choosing an edge
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* @return a random simple digraph on V vertices, with an edge between
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* any two vertices with probability p
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* @throws IllegalArgumentException if probability is not between 0 and 1
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*/
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public static Digraph simple(int V, double p) {
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if (p < 0.0 || p > 1.0)
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throw new IllegalArgumentException("Probability must be between 0 and 1");
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Digraph G = new Digraph(V);
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for (int v = 0; v < V; v++)
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for (int w = 0; w < V; w++)
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if (v != w)
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if (StdRandom.bernoulli(p))
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G.addEdge(v, w);
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return G;
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}
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/**
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* Returns the complete digraph on V vertices.
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* @param V the number of vertices
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* @return the complete digraph on V vertices
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*/
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public static Digraph complete(int V) {
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return simple(V, V*(V-1));
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}
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/**
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* Returns a random simple DAG containing V vertices and E edges.
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* Note: it is not uniformly selected at random among all such DAGs.
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* @param V the number of vertices
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* @param E the number of vertices
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* @return a random simple DAG on V vertices, containing a total
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* of E edges
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* @throws IllegalArgumentException if no such simple DAG exists
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*/
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public static Digraph dag(int V, int E) {
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if (E > (long) V*(V-1) / 2) throw new IllegalArgumentException("Too many edges");
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if (E < 0) throw new IllegalArgumentException("Too few edges");
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Digraph G = new Digraph(V);
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SET<Edge> set = new SET<Edge>();
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int[] vertices = new int[V];
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for (int i = 0; i < V; i++) vertices[i] = i;
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StdRandom.shuffle(vertices);
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while (G.E() < E) {
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int v = StdRandom.uniform(V);
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int w = StdRandom.uniform(V);
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Edge e = new Edge(v, w);
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if ((v < w) && !set.contains(e)) {
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set.add(e);
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G.addEdge(vertices[v], vertices[w]);
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}
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}
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return G;
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}
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// tournament
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/**
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* Returns a random tournament digraph on V vertices. A tournament digraph
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* is a DAG in which for every two vertices, there is one direted edge.
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* A tournament is an oriented complete graph.
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* @param V the number of vertices
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* @return a random tournament digraph on V vertices
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*/
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public static Digraph tournament(int V) {
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return dag(V, V*(V-1)/2);
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}
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/**
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* Returns a random rooted-in DAG on V vertices and E edges.
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* A rooted in-tree is a DAG in which there is a single vertex
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* reachable from every other vertex.
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* The DAG returned is not chosen uniformly at random among all such DAGs.
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* @param V the number of vertices
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* @param E the number of edges
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* @return a random rooted-in DAG on V vertices and E edges
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*/
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public static Digraph rootedInDAG(int V, int E) {
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if (E > (long) V*(V-1) / 2) throw new IllegalArgumentException("Too many edges");
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if (E < V-1) throw new IllegalArgumentException("Too few edges");
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Digraph G = new Digraph(V);
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SET<Edge> set = new SET<Edge>();
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// fix a topological order
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int[] vertices = new int[V];
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for (int i = 0; i < V; i++) vertices[i] = i;
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StdRandom.shuffle(vertices);
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// one edge pointing from each vertex, other than the root = vertices[V-1]
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for (int v = 0; v < V-1; v++) {
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int w = StdRandom.uniform(v+1, V);
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Edge e = new Edge(v, w);
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set.add(e);
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G.addEdge(vertices[v], vertices[w]);
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}
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while (G.E() < E) {
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int v = StdRandom.uniform(V);
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int w = StdRandom.uniform(V);
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Edge e = new Edge(v, w);
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if ((v < w) && !set.contains(e)) {
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set.add(e);
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G.addEdge(vertices[v], vertices[w]);
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}
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}
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return G;
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}
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/**
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* Returns a random rooted-out DAG on V vertices and E edges.
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* A rooted out-tree is a DAG in which every vertex is reachable from a
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* single vertex.
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* The DAG returned is not chosen uniformly at random among all such DAGs.
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* @param V the number of vertices
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* @param E the number of edges
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* @return a random rooted-out DAG on V vertices and E edges
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*/
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public static Digraph rootedOutDAG(int V, int E) {
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if (E > (long) V*(V-1) / 2) throw new IllegalArgumentException("Too many edges");
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if (E < V-1) throw new IllegalArgumentException("Too few edges");
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Digraph G = new Digraph(V);
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SET<Edge> set = new SET<Edge>();
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// fix a topological order
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int[] vertices = new int[V];
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for (int i = 0; i < V; i++) vertices[i] = i;
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StdRandom.shuffle(vertices);
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// one edge pointing from each vertex, other than the root = vertices[V-1]
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for (int v = 0; v < V-1; v++) {
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int w = StdRandom.uniform(v+1, V);
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Edge e = new Edge(w, v);
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set.add(e);
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G.addEdge(vertices[w], vertices[v]);
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}
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while (G.E() < E) {
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int v = StdRandom.uniform(V);
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int w = StdRandom.uniform(V);
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Edge e = new Edge(w, v);
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if ((v < w) && !set.contains(e)) {
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set.add(e);
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G.addEdge(vertices[w], vertices[v]);
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}
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}
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return G;
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}
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/**
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* Returns a random rooted-in tree on V vertices.
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* A rooted in-tree is an oriented tree in which there is a single vertex
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* reachable from every other vertex.
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* The tree returned is not chosen uniformly at random among all such trees.
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* @param V the number of vertices
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* @return a random rooted-in tree on V vertices
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*/
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public static Digraph rootedInTree(int V) {
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return rootedInDAG(V, V-1);
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}
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/**
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* Returns a random rooted-out tree on V vertices. A rooted out-tree
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* is an oriented tree in which each vertex is reachable from a single vertex.
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* It is also known as a arborescence or branching .
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* The tree returned is not chosen uniformly at random among all such trees.
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* @param V the number of vertices
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* @return a random rooted-out tree on V vertices
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*/
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public static Digraph rootedOutTree(int V) {
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return rootedOutDAG(V, V-1);
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}
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/**
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* Returns a path digraph on V vertices.
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* @param V the number of vertices in the path
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* @return a digraph that is a directed path on V vertices
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*/
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public static Digraph path(int V) {
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Digraph G = new Digraph(V);
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int[] vertices = new int[V];
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for (int i = 0; i < V; i++) vertices[i] = i;
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StdRandom.shuffle(vertices);
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for (int i = 0; i < V-1; i++) {
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G.addEdge(vertices[i], vertices[i+1]);
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}
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return G;
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}
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/**
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* Returns a complete binary tree digraph on V vertices.
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* @param V the number of vertices in the binary tree
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* @return a digraph that is a complete binary tree on V vertices
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*/
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public static Digraph binaryTree(int V) {
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Digraph G = new Digraph(V);
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int[] vertices = new int[V];
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for (int i = 0; i < V; i++) vertices[i] = i;
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StdRandom.shuffle(vertices);
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for (int i = 1; i < V; i++) {
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G.addEdge(vertices[i], vertices[(i-1)/2]);
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}
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return G;
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}
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/**
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* Returns a cycle digraph on V vertices.
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* @param V the number of vertices in the cycle
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* @return a digraph that is a directed cycle on V vertices
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*/
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public static Digraph cycle(int V) {
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Digraph G = new Digraph(V);
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int[] vertices = new int[V];
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for (int i = 0; i < V; i++) vertices[i] = i;
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StdRandom.shuffle(vertices);
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for (int i = 0; i < V-1; i++) {
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G.addEdge(vertices[i], vertices[i+1]);
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}
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G.addEdge(vertices[V-1], vertices[0]);
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return G;
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}
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/**
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* Returns a random simple digraph on V vertices, E
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* edges and (at least) c strong components. The vertices are randomly
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* assigned integer labels between 0 and c-1 (corresponding to
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* strong components). Then, a strong component is creates among the vertices
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* with the same label. Next, random edges (either between two vertices with
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* the same labels or from a vetex with a smaller label to a vertex with a
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* larger label). The number of components will be equal to the number of
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* distinct labels that are assigned to vertices.
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*
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* @param V the number of vertices
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* @param E the number of edges
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* @param c the (maximum) number of strong components
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* @return a random simple digraph on V vertices and
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E edges, with (at most) c strong components
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* @throws IllegalArgumentException if c is larger than V
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*/
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public static Digraph strong(int V, int E, int c) {
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if (c >= V || c <= 0)
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throw new IllegalArgumentException("Number of components must be between 1 and V");
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if (E <= 2*(V-c))
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throw new IllegalArgumentException("Number of edges must be at least 2(V-c)");
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if (E > (long) V*(V-1) / 2)
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throw new IllegalArgumentException("Too many edges");
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// the digraph
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Digraph G = new Digraph(V);
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// edges added to G (to avoid duplicate edges)
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SET<Edge> set = new SET<Edge>();
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int[] label = new int[V];
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for (int v = 0; v < V; v++)
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label[v] = StdRandom.uniform(c);
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// make all vertices with label c a strong component by
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// combining a rooted in-tree and a rooted out-tree
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for (int i = 0; i < c; i++) {
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// how many vertices in component c
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int count = 0;
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for (int v = 0; v < G.V(); v++) {
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if (label[v] == i) count++;
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}
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// if (count == 0) System.err.println("less than desired number of strong components");
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int[] vertices = new int[count];
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int j = 0;
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for (int v = 0; v < V; v++) {
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if (label[v] == i) vertices[j++] = v;
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}
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StdRandom.shuffle(vertices);
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// rooted-in tree with root = vertices[count-1]
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for (int v = 0; v < count-1; v++) {
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int w = StdRandom.uniform(v+1, count);
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Edge e = new Edge(w, v);
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set.add(e);
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G.addEdge(vertices[w], vertices[v]);
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}
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// rooted-out tree with root = vertices[count-1]
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for (int v = 0; v < count-1; v++) {
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int w = StdRandom.uniform(v+1, count);
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Edge e = new Edge(v, w);
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set.add(e);
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G.addEdge(vertices[v], vertices[w]);
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}
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}
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while (G.E() < E) {
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int v = StdRandom.uniform(V);
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int w = StdRandom.uniform(V);
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Edge e = new Edge(v, w);
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if (!set.contains(e) && v != w && label[v] <= label[w]) {
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set.add(e);
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G.addEdge(v, w);
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}
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}
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return G;
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}
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/**
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* Unit tests the DigraphGenerator library.
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*/
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public static void main(String[] args) {
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int V = Integer.parseInt(args[0]);
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int E = Integer.parseInt(args[1]);
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System.out.println("complete graph");
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System.out.println(complete(V));
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System.out.println();
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System.out.println("simple");
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System.out.println(simple(V, E));
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System.out.println();
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System.out.println("path");
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System.out.println(path(V));
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System.out.println();
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System.out.println("cycle");
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System.out.println(cycle(V));
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System.out.println();
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System.out.println("binary tree");
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System.out.println(binaryTree(V));
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System.out.println();
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System.out.println("tournament");
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System.out.println(tournament(V));
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System.out.println();
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System.out.println("DAG");
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System.out.println(dag(V, E));
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System.out.println();
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System.out.println("rooted-in DAG");
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System.out.println(rootedInDAG(V, E));
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System.out.println();
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System.out.println("rooted-out DAG");
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System.out.println(rootedOutDAG(V, E));
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System.out.println();
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System.out.println("rooted-in tree");
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System.out.println(rootedInTree(V));
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System.out.println();
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System.out.println("rooted-out DAG");
|
||
|
System.out.println(rootedOutTree(V));
|
||
|
System.out.println();
|
||
|
}
|
||
|
|
||
|
}
|