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I've been working through a book on java, and have to represent a directed graph, distances between nodes etc.

Here's what i have (from previous publications)

import java.io.*;
import java.util.*;

public class BFSAlgorithm {

    private Graph graph;

    /**
     * Constructor.
     */
    public BFSAlgorithm(Graph g) {
        graph = g;
    }

    /**
     * 1 - Create a stack to store all the vertices of our path on.
     * 2 - First push the 'end' vertex on our stack.
     * 3 - Now loop from the highest level back to the first level and
     *     a. loop through each level and
     *     b. check each vertex in that level if it's connected to the
     *        vertex on the top of our stack, if we find a match, push that
     *        match on the stack and break out of the loop.
     * 4 - Now we only need to reverse the collection (stack) before returning 
     *     the path in the "correct" order (from start to finish).
     * 
     * Here's an example ASCII drawing of backtracking from the end vertex "n" 
     * to the starting vertex "g". The arrows, <-, denote the path that was 
     * found.
     * 
     * level:  0      1      2      3       4      5      6    7     8
     *        ---------------------------------------------------------
     *         g <-+  IV     e      I       a   +- III <- o <- VI <- n 
     *             +- V <-+  f   +- II <-+  b   |         p
     *                    +- c <-+       |  d   |
     *                       j           +- h <-+
     *                                      q
     *                                      r
     */
    private List<String> backTrack(List<List<String>> container, String end) {
        Stack<String> path = new Stack<String>();                     // 1
        path.push(end);                                               // 2
        for(int i = container.size()-1; i >= 0; i--) {                // 3
            List<String> level = container.get(i);
            String last = path.peek();
            for(String s : level) {                                   // a
                if(graph.isConnectedTo(last, s)) {                    // b
                    path.push(s);
                    break;
                }
            }
        }
        Collections.reverse(path);                                    // 4
        return path;
    }

    /**
     * 1 - Get the level from the 'container' which was added last.
     * 2 - Create a new level to store (possible) unexplored verices in.
     * 3 - Loop through each of the vertices from the last added level, and
     *     a. get the neighboring vertices connected to each vertex,
     *     b. loop through each connecting vertex and if the connecting vertex
     *        has not yet been visited,
     *     c. only then add it to the newly created level-list and mark it as 
     *        visited in our set.
     * 4 - We don't need to search any further if we stumble upon the 'end' 
     *     vertex. In that case, just "return" from this method.
     * 5 - Only make the recursive call if we have found vertices which have 
     *     not been explored yet.
     */
    private void bfs(List<List<String>> container, 
            String end, Set<String> visited) {

        List<String> lastLevel = container.get(container.size()-1);   // 1
        List<String> newLevel = new ArrayList<String>();              // 2

        for(String vertex : lastLevel) {                              // 3
            List<String> edges = graph.getEdges(vertex);              // a
            for(String edge : edges) {                                // b
                if(!visited.contains(edge)) {                         // c
                    visited.add(edge);
                    newLevel.add(edge);
                }
                if(edge.equals(end)) return;                          // 4
            }
        }  
        if(newLevel.size() > 0) {                                     // 5
            container.add(newLevel);
            bfs(container, end, visited);
        }
    }

    /**
     * 1 - Create an empty 'container' to store all the levels from the 
     *     'start'-vertex in. A level is also a list with one or more vertices.
     * 2 - The first level only holds the 'start' vertex, which is added first,
     *     this is the 'init' list.
     * 3 - The 'start' vertex is also stored in a Set which keeps track of all 
     *     the vertices we have encountered so that we don't traverse vertices
     *     twice (or more).
     * 4 - Once we initialized the steps 1-3, we can call the actual BFS-
     *     algorithm.
     * 5 - Once the BFS-algorithm is done, we call the backTrack(...) method 
     *     to find the shortest path between 'end' and 'start' between the 
     *     explored levels of the graph. 
     */
    public List<String> getShortestPath(String start, String end) {
        List<List<String>> container = new ArrayList<List<String>>(); // 1
        List<String> init = new ArrayList<String>();                  // 2
        init.add(start);
        container.add(init);
        Set<String> visited = new HashSet<String>();                  // 3
        visited.add(start);
        bfs(container, end, visited);                                 // 4
        return backTrack(container, end);                             // 5
    }

    /**
     * Main method:
     *  1 - Create a Graph.
     *  2 - Get a shortest path between two vertices.
     *  3 - Print the shortest path.
     */
    public static void main(String[] args) throws FileNotFoundException {
        Graph graph = new Graph("data.txt");                          // 1
        BFSAlgorithm bfsAlgorithm = new BFSAlgorithm(graph);
        List<String> shortestPath = 
            bfsAlgorithm.getShortestPath("g", "n");                   // 2
        for(int i = 0; i < shortestPath.size(); i++) {
            System.out.print(shortestPath.get(i));                    // 3
            System.out.print(i < shortestPath.size()-1 ? "\n -> " : "\n");
        }
    }
}

However I get the following errors:

reverse(java.util.List<?>) in
java.util.Collections cannot be
applied to (Stack<java.lang.String>)

incompatible types found   :
Stack<java.lang.String> required:
java.util.List<java.lang.String>

which is in relation to this (first error first line, second error second line):

Collections.reverse(path);                                    // 4
        return path;

Any ideas? Many thanks!

share|improve this question

1 Answer 1

Judging by that error message, Stack does not refer to java.util.Stack (which implements java.util.List and is presumably what you want.) Instead it refers to a class called Stack in the default package (which is not included in your sample.) If this is intentional then please add the code from your Stack class to the question.

share|improve this answer
    
Thanks for your reply! The only other class is Graph –  Chris Edwards Jan 10 '11 at 22:54
    
@Chris Edwards, could there be a Stack.class file left over from another project in the same directory? –  finnw Jan 10 '11 at 22:55
    
No :( this was built on its own... –  Chris Edwards Jan 11 '11 at 0:21
    
@Chris Edwards, Well you definitely have a class called Stack (not java.util.Stack) somewhere. If you are using Eclipse click on "Stack" and press F3. If you are building from the command line try "javap Stack" and see what turns up. –  finnw Jan 11 '11 at 1:52

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