494 lines
14 KiB
Java
494 lines
14 KiB
Java
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/*This is a java program to find the minimum spanning tree of a graph. Given a connected, undirected graph, a spanning tree of that graph is a subgraph that is a tree and connects all the vertices together. A single graph can have many different spanning trees. We can also assign a weight to each edge, which is a number representing how unfavorable it is, and use this to assign a weight to a spanning tree by computing the sum of the weights of the edges in that spanning tree. A minimum spanning tree (MST) or minimum weight spanning tree is then a spanning tree with weight less than or equal to the weight of every other spanning tree. More generally, any undirected graph (not necessarily connected) has a minimum spanning forest, which is a union of minimum spanning trees for its connected components.*/
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import java.util.Iterator;
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import java.util.NoSuchElementException;
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import java.util.Scanner;
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public class BoruvkasMST
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{
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private Bag<Edge> mst = new Bag<Edge>(); // Edge in MST
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private double weight; // weight of MST
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public BoruvkasMST(EdgeWeightedGraph G)
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{
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UF uf = new UF(G.V());
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// repeat at most log V times or until we have V-1 Edge
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for (int t = 1; t < G.V() && mst.size() < G.V() - 1; t = t + t)
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{
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// foreach tree in forest, find closest edge
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// if edge weights are equal, ties are broken in favor of first edge
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// in G.Edge()
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Edge[] closest = new Edge[G.V()];
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for (Edge e : G.Edge())
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{
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int v = e.either(), w = e.other(v);
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int i = uf.find(v), j = uf.find(w);
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if (i == j)
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continue; // same tree
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if (closest[i] == null || less(e, closest[i]))
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closest[i] = e;
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if (closest[j] == null || less(e, closest[j]))
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closest[j] = e;
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}
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// add newly discovered Edge to MST
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for (int i = 0; i < G.V(); i++)
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{
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Edge e = closest[i];
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if (e != null)
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{
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int v = e.either(), w = e.other(v);
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// don't add the same edge twice
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if (!uf.connected(v, w))
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{
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mst.add(e);
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weight += e.weight();
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uf.union(v, w);
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}
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}
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}
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}
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// check optimality conditions
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assert check(G);
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}
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public Iterable<Edge> Edge()
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{
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return mst;
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}
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public double weight()
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{
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return weight;
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}
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// is the weight of edge e strictly less than that of edge f?
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private static boolean less(Edge e, Edge f)
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{
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return e.weight() < f.weight();
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}
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// check optimality conditions (takes time proportional to E V lg* V)
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private boolean check(EdgeWeightedGraph G)
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{
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// check weight
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double totalWeight = 0.0;
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for (Edge e : Edge())
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{
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totalWeight += e.weight();
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}
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double EPSILON = 1E-12;
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if (Math.abs(totalWeight - weight()) > EPSILON)
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{
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System.err.printf(
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"Weight of Edge does not equal weight(): %f vs. %f\n",
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totalWeight, weight());
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return false;
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}
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// check that it is acyclic
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UF uf = new UF(G.V());
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for (Edge e : Edge())
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{
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int v = e.either(), w = e.other(v);
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if (uf.connected(v, w))
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{
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System.err.println("Not a forest");
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return false;
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}
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uf.union(v, w);
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}
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// check that it is a spanning forest
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for (Edge e : G.Edge())
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{
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int v = e.either(), w = e.other(v);
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if (!uf.connected(v, w))
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{
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System.err.println("Not a spanning forest");
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return false;
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}
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}
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// check that it is a minimal spanning forest (cut optimality
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// conditions)
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for (Edge e : Edge())
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{
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// all Edge in MST except e
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uf = new UF(G.V());
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for (Edge f : mst)
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{
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int x = f.either(), y = f.other(x);
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if (f != e)
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uf.union(x, y);
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}
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// check that e is min weight edge in crossing cut
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for (Edge f : G.Edge())
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{
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int x = f.either(), y = f.other(x);
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if (!uf.connected(x, y))
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{
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if (f.weight() < e.weight())
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{
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System.err.println("Edge " + f
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+ " violates cut optimality conditions");
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return false;
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}
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}
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}
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}
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return true;
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}
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public static void main(String[] args)
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{
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Scanner sc = new Scanner(System.in);
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System.out.println("Enter the number of verties: ");
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EdgeWeightedGraph G = new EdgeWeightedGraph(sc.nextInt());
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BoruvkasMST mst = new BoruvkasMST(G);
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System.out.println("MST: ");
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for (Edge e : mst.Edge())
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{
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System.out.println(e);
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}
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System.out.printf("Total weight of MST: %.5f\n", mst.weight());
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sc.close();
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}
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}
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class BagOfItems<Item> implements Iterable<Item>
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{
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private int N; // number of elements in bag
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private Node<Item> first; // beginning of bag
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// helper linked list class
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private static class Node<Item>
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{
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private Item item;
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private Node<Item> next;
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}
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public BagOfItems()
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{
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first = null;
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N = 0;
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}
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public boolean isEmpty()
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{
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return first == null;
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}
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public int size()
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{
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return N;
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}
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public void add(Item item)
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{
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Node<Item> oldfirst = first;
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first = new Node<Item>();
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first.item = item;
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first.next = oldfirst;
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N++;
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}
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public Iterator<Item> iterator()
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{
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return new ListIterator<Item>(first);
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}
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// an iterator, doesn't implement remove() since it's optional
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@SuppressWarnings("hiding")
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private class ListIterator<Item> implements Iterator<Item>
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{
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private Node<Item> current;
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public ListIterator(Node<Item> first)
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{
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current = first;
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}
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public boolean hasNext()
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{
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return current != null;
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}
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public void remove()
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{
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throw new UnsupportedOperationException();
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}
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public Item next()
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{
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if (!hasNext())
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throw new NoSuchElementException();
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Item item = current.item;
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current = current.next;
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return item;
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}
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}
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}
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class EdgeWeightedGraph
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{
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private final int V;
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private final int E;
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private Bag<Edge>[] adj;
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@SuppressWarnings("unchecked")
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public EdgeWeightedGraph(int V)
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{
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Scanner sc = new Scanner(System.in);
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if (V < 0)
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{
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sc.close();
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throw new IllegalArgumentException(
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"Number of vertices must be nonnegative");
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}
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this.V = V;
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adj = (Bag<Edge>[]) new Bag[V];
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for (int v = 0; v < V; v++)
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{
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adj[v] = new Bag<Edge>();
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}
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System.out.println("Enter the number of Edge: ");
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E = sc.nextInt();
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if (E < 0)
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{
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sc.close();
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throw new IllegalArgumentException(
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"Number of Edge must be nonnegative");
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}
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System.out.println("Enter the Edge: <from> <to>");
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for (int i = 0; i < E; i++)
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{
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int v = sc.nextInt();
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int w = sc.nextInt();
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double weight = Math.round(100 * Math.random()) / 100.0;
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System.out.println(weight);
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Edge e = new Edge(v, w, weight);
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addEdge(e);
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}
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sc.close();
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}
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public int V()
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{
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return V;
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}
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public int E()
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{
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return E;
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}
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public void addEdge(Edge e)
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{
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int v = e.either();
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int w = e.other(v);
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if (v < 0 || v >= V)
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throw new IndexOutOfBoundsException("vertex " + v
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+ " is not between 0 and " + (V - 1));
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if (w < 0 || w >= V)
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throw new IndexOutOfBoundsException("vertex " + w
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+ " is not between 0 and " + (V - 1));
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adj[v].add(e);
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adj[w].add(e);
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}
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public Iterable<Edge> adj(int v)
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{
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if (v < 0 || v >= V)
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throw new IndexOutOfBoundsException("vertex " + v
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+ " is not between 0 and " + (V - 1));
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return adj[v];
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}
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public Iterable<Edge> Edge()
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{
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Bag<Edge> list = new Bag<Edge>();
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for (int v = 0; v < V; v++)
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{
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int selfLoops = 0;
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for (Edge e : adj(v))
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{
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if (e.other(v) > v)
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{
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list.add(e);
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}
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// only add one copy of each self loop (self loops will be
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// consecutive)
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else if (e.other(v) == v)
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{
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if (selfLoops % 2 == 0)
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list.add(e);
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selfLoops++;
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}
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}
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}
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return list;
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}
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public String toString()
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{
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String NEWLINE = System.getProperty("line.separator");
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StringBuilder s = new StringBuilder();
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s.append(V + " " + E + NEWLINE);
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for (int v = 0; v < V; v++)
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{
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s.append(v + ": ");
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for (Edge e : adj[v])
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{
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s.append(e + " ");
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}
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s.append(NEWLINE);
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}
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return s.toString();
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}
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}
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class Edge implements Comparable<Edge>
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{
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private final int v;
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private final int w;
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private final double weight;
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public Edge(int v, int w, double weight)
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{
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if (v < 0)
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throw new IndexOutOfBoundsException(
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"Vertex name must be a nonnegative integer");
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if (w < 0)
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throw new IndexOutOfBoundsException(
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"Vertex name must be a nonnegative integer");
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if (Double.isNaN(weight))
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throw new IllegalArgumentException("Weight is NaN");
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this.v = v;
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this.w = w;
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this.weight = weight;
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}
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public double weight()
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{
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return weight;
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}
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public int either()
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{
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return v;
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}
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public int other(int vertex)
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{
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if (vertex == v)
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return w;
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else if (vertex == w)
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return v;
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else
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throw new IllegalArgumentException("Illegal endpoint");
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}
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public int compareTo(Edge that)
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{
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if (this.weight() < that.weight())
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return -1;
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else if (this.weight() > that.weight())
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return +1;
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else
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return 0;
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}
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public String toString()
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{
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return String.format("%d-%d %.5f", v, w, weight);
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}
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}
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class UF
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{
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private int[] id; // id[i] = parent of i
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private byte[] rank; // rank[i] = rank of subtree rooted at i (cannot be
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// more than 31)
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private int count; // number of components
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public UF(int N)
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{
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if (N < 0)
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throw new IllegalArgumentException();
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count = N;
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id = new int[N];
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rank = new byte[N];
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for (int i = 0; i < N; i++)
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{
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id[i] = i;
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rank[i] = 0;
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}
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}
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public int find(int p)
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{
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if (p < 0 || p >= id.length)
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throw new IndexOutOfBoundsException();
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while (p != id[p])
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{
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id[p] = id[id[p]]; // path compression by halving
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p = id[p];
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}
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return p;
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}
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public int count()
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{
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return count;
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}
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public boolean connected(int p, int q)
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{
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return find(p) == find(q);
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}
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public void union(int p, int q)
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{
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int i = find(p);
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int j = find(q);
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if (i == j)
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return;
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// make root of smaller rank point to root of larger rank
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if (rank[i] < rank[j])
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id[i] = j;
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else if (rank[i] > rank[j])
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id[j] = i;
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else
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{
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id[j] = i;
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rank[i]++;
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}
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count--;
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}
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}
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/*
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Enter the number of verties:
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6
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Enter the number of Edge:
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7
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Enter the Edge: <from> <to>
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0 1
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0.09
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1 2
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0.48
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1 3
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0.52
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3 4
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0.43
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4 5
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0.98
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5 3
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0.07
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5 2
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0.1
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MST:
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1-2 0.48000
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3-4 0.43000
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5-3 0.07000
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5-2 0.10000
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0-1 0.09000
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Total weight of MST: 1.17000
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