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package algs41;
import stdlib.*;
import algs13.Queue;
import algs13.Stack;
/******************************************************************************
* Compilation: javac EulerianPath.java
* Execution: java EulerianPath V E
* Dependencies: Graph.java Stack.java StdOut.java
*
* Find an Eulerian path in a graph, if one exists.
*
******************************************************************************/
/**
* The {@code EulerianPath} class represents a data type
* for finding an Eulerian path in a graph.
* An <em>Eulerian path</em> is a path (not necessarily simple) that
* uses every edge in the graph exactly once.
* <p>
* This implementation uses a nonrecursive depth-first search.
* The constructor runs in O(<em>E</em> + <em>V</em>) time,
* and uses O(<em>E</em> + <em>V</em>) extra space,
* where <em>E</em> is the number of edges and <em>V</em> the number of vertices
* All other methods take O(1) time.
* <p>
* To compute Eulerian cycles in graphs, see {@link EulerianCycle}.
* To compute Eulerian cycles and paths in digraphs, see
* {@link algs42.DirectedEulerianCycle} and {@link algs42.DirectedEulerianPath}.
* <p>
* For additional documentation,
* see <a href="https://algs4.cs.princeton.edu/41graph">Section 4.1</a> of
* <i>Algorithms, 4th Edition</i> by Robert Sedgewick and Kevin Wayne.
*
* @author Robert Sedgewick
* @author Kevin Wayne
* @author Nate Liu
*/
public class EulerianPath {
private Stack<Integer> path = null; // Eulerian path; null if no suh path
// an undirected edge, with a field to indicate whether the edge has already been used
private static class Edge {
private final int v;
private final int w;
private boolean isUsed;
public Edge(int v, int w) {
this.v = v;
this.w = w;
isUsed = false;
}
// returns the other vertex of the edge
public int other(int vertex) {
if (vertex == v) return w;
else if (vertex == w) return v;
else throw new IllegalArgumentException("Illegal endpoint");
}
}
/**
* Computes an Eulerian path in the specified graph, if one exists.
*
* @param G the graph
*/
public EulerianPath(Graph G) {
// find vertex from which to start potential Eulerian path:
// a vertex v with odd degree(v) if it exits;
// otherwise a vertex with degree(v) > 0
int oddDegreeVertices = 0;
int s = nonIsolatedVertex(G);
for (int v = 0; v < G.V(); v++) {
if (G.degree(v) % 2 != 0) {
oddDegreeVertices++;
s = v;
}
}
// graph can't have an Eulerian path
// (this condition is needed for correctness)
if (oddDegreeVertices > 2) return;
// special case for graph with zero edges (has a degenerate Eulerian path)
if (s == -1) s = 0;
// create local view of adjacency lists, to iterate one vertex at a time
// the helper Edge data type is used to avoid exploring both copies of an edge v-w
@SuppressWarnings("unchecked")
Queue<Edge>[] adj = new Queue[G.V()];
for (int v = 0; v < G.V(); v++)
adj[v] = new Queue<Edge>();
for (int v = 0; v < G.V(); v++) {
int selfLoops = 0;
for (int w : G.adj(v)) {
// careful with self loops
if (v == w) {
if (selfLoops % 2 == 0) {
Edge e = new Edge(v, w);
adj[v].enqueue(e);
adj[w].enqueue(e);
}
selfLoops++;
}
else if (v < w) {
Edge e = new Edge(v, w);
adj[v].enqueue(e);
adj[w].enqueue(e);
}
}
}
// initialize stack with any non-isolated vertex
Stack<Integer> stack = new Stack<Integer>();
stack.push(s);
// greedily search through edges in iterative DFS style
path = new Stack<Integer>();
while (!stack.isEmpty()) {
int v = stack.pop();
while (!adj[v].isEmpty()) {
Edge edge = adj[v].dequeue();
if (edge.isUsed) continue;
edge.isUsed = true;
stack.push(v);
v = edge.other(v);
}
// push vertex with no more leaving edges to path
path.push(v);
}
// check if all edges are used
if (path.size() != G.E() + 1)
path = null;
assert certifySolution(G);
}
/**
* Returns the sequence of vertices on an Eulerian path.
*
* @return the sequence of vertices on an Eulerian path;
* {@code null} if no such path
*/
public Iterable<Integer> path() {
return path;
}
/**
* Returns true if the graph has an Eulerian path.
*
* @return {@code true} if the graph has an Eulerian path;
* {@code false} otherwise
*/
public boolean hasEulerianPath() {
return path != null;
}
// returns any non-isolated vertex; -1 if no such vertex
private static int nonIsolatedVertex(Graph G) {
for (int v = 0; v < G.V(); v++)
if (G.degree(v) > 0)
return v;
return -1;
}
/**************************************************************************
*
* The code below is solely for testing correctness of the data type.
*
**************************************************************************/
// Determines whether a graph has an Eulerian path using necessary
// and sufficient conditions (without computing the path itself):
// - degree(v) is even for every vertex, except for possibly two
// - the graph is connected (ignoring isolated vertices)
// This method is solely for unit testing.
private static boolean satisfiesNecessaryAndSufficientConditions(Graph G) {
if (G.E() == 0) return true;
// Condition 1: degree(v) is even except for possibly two
int oddDegreeVertices = 0;
for (int v = 0; v < G.V(); v++)
if (G.degree(v) % 2 != 0)
oddDegreeVertices++;
if (oddDegreeVertices > 2) return false;
// Condition 2: graph is connected, ignoring isolated vertices
int s = nonIsolatedVertex(G);
BreadthFirstPaths bfs = new BreadthFirstPaths(G, s);
for (int v = 0; v < G.V(); v++)
if (G.degree(v) > 0 && !bfs.hasPathTo(v))
return false;
return true;
}
// check that solution is correct
private boolean certifySolution(Graph G) {
// internal consistency check
if (hasEulerianPath() == (path() == null)) return false;
// hashEulerianPath() returns correct value
if (hasEulerianPath() != satisfiesNecessaryAndSufficientConditions(G)) return false;
// nothing else to check if no Eulerian path
if (path == null) return true;
// check that path() uses correct number of edges
if (path.size() != G.E() + 1) return false;
// check that path() is a path in G
// TODO
return true;
}
private static void unitTest(Graph G, String description) {
StdOut.println(description);
StdOut.println("-------------------------------------");
StdOut.print(G);
EulerianPath euler = new EulerianPath(G);
StdOut.print("Eulerian path: ");
if (euler.hasEulerianPath()) {
for (int v : euler.path()) {
StdOut.print(v + " ");
}
StdOut.println();
}
else {
StdOut.println("none");
}
StdOut.println();
}
/**
* Unit tests the {@code EulerianPath} data type.
*
* @param args the command-line arguments
*/
public static void main(String[] args) {
int V = Integer.parseInt(args[0]);
int E = Integer.parseInt(args[1]);
// Eulerian cycle
Graph G1 = GraphGenerator.eulerianCycle(V, E);
unitTest(G1, "Eulerian cycle");
// Eulerian path
Graph G2 = GraphGenerator.eulerianPath(V, E);
unitTest(G2, "Eulerian path");
// add one random edge
Graph G3 = GraphGenerator.copy(G2);
G3.addEdge(StdRandom.uniform(V), StdRandom.uniform(V));
unitTest(G3, "one random edge added to Eulerian path");
// self loop
Graph G4 = new Graph(V);
int v4 = StdRandom.uniform(V);
G4.addEdge(v4, v4);
unitTest(G4, "single self loop");
// single edge
Graph G5 = new Graph(V);
G5.addEdge(StdRandom.uniform(V), StdRandom.uniform(V));
unitTest(G5, "single edge");
// empty graph
Graph G6 = new Graph(V);
unitTest(G6, "empty graph");
// random graph
Graph G7 = GraphGenerator.simple(V, E);
unitTest(G7, "simple graph");
}
}
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