Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Hi awesome person!

I have a problem... I get a NullPointerException when my test case reaches allEdges.add(newEdge); in the connectNodes method.

I think it has something to do with Edge newEdge = new Edge( n1, n2, weight ); previously in that same method.

Is the problem my use of generics in the Edge class or something like that?. I previously got an error directing me at the Edge newEdge = new Edge( n1, n2, weight ); line, saying something like "class not found". But now i seem to get the NullPointerException at allEdges.add(newEdge); instead without having changed anything.

Very thankful for every bit of help!

import java.util.*;

public class MyMiniGraph<T extends Comparable<? super T>> implements MiniGraph<T>
{
      // The Graph containing all the nodes and their edges
    private Map< T, HashSet<Edge> > theGraph = new HashMap< T, HashSet<Edge> >( );
      // Keeps track of theGraphs current size
    private int currentSize = 0;
      // Keeps track of the current Edge quantity
    private int numEdges;
      // TreeSet containing all edges
    private TreeSet<Edge> allEdges;
      // edge representing class with its associated nodes and weight
    private class Edge implements Comparable<Edge>
    {
        public int cost;
        public T n1;
        public T n2;
        public Edge(T n1, T n2 , int cost)
        {
            this.n1 = n1;
            this.n2 = n2;
            this.cost = cost;
        }

    public int compareTo(Edge e)
    {
          // returns 0 if edges are equal
        if(e.cost == cost)
            return 0;
          // returns 1 if edge is greater than other edge,
          // -1 if edge is smaller than other edge
        return e.cost < cost ? 1 : -1; 
    }

}

/** 
 *  Method for adding a node to the graph.
 *  Silently ignores any duplicates
 *
 *  @param n    The node to add to the graph.
 */
public void addNode(T n)
{
    if(n == null)
        throw new IllegalStateException("Invalid Node");
    if(!theGraph.containsKey(n))
    {   
        theGraph.put(n,new HashSet<Edge>());
        ++currentSize;
    }
}

/**
 *  Method for removing a node from the graph. 
 *  Before the node is removed, all edges associated with the node
 *  must be removed.
 *  Silently ignores any nodes not already in the graph.
 */
public void removeNode(T n)
{
    if(theGraph.containsKey(n))
    {
      // If node n has edges, remove all those edges. 
      // Firstly, remove the edges connecting to this 
      // node from other nodes, then, remove this node  
      // and its edges with it.
        if( !theGraph.get(n).isEmpty() )
        {
              //iterator to iterate over the edges of node n
            Iterator<Edge> edgeIt = theGraph.get(n).iterator();

              // remove this node from all its connecting nodes edge lists
            Edge localEdge;
            /**Edge foreignEdge;*/
            while(edgeIt.hasNext())
            {
                localEdge = edgeIt.next();
                T foreignNode = localEdge.n2 == n ? localEdge.n1 : localEdge.n2;
                  // iterator to iterate over the edges of adjacent node of n (foreignNode)
                /**Iterator<Edge> forEdgeIt = 
                    theGraph.get(foreignNode).iterator();

                while(forEdgeIt.hasNext())
                {
                    foreignEdge = forEdgeIt.next();
                    if( foreignEdge.equals( localEdge ) )
                        forEdgeIt.remove();
                }*/
                  // removes all edges occurring in n from all foreign nodes
                theGraph.get(foreignNode).remove(localEdge);
                allEdges.remove(localEdge);
                --numEdges;
            }
        }
          //remove the node itself thereby also removing its local edge list
        theGraph.remove(n);
        --currentSize;
    }
}

/**
 *  Method for creating an unidirectional edge between two nodes. 
 *
 *  @param  n1  The first node to create an edge between
 *  @param  n2  The second node to create an edge between
 *  @param  weight  The cost for traversing the edge
 */
public void connectNodes(T n1, T n2, int weight)
{
    if(!contains(n1) || !contains(n2))
        throw new IllegalStateException("node not in graph");

    if(!edgeExistsBetween(n1,n2))
    {
        Edge newEdge = new Edge( n1, n2, weight );
        theGraph.get(n1).add( newEdge );
        theGraph.get(n2).add( newEdge );

        allEdges.add(newEdge);
        ++numEdges;
    }
}

/**
 *  Method for removing an edge between two nodes.
 *
 *  @param  n1  The first node that identifies the edge.
 *  @param  n2  The second node that identifies the edge.
 */
public void disconnectNodes(T n1, T n2)
{
    if(!contains(n1) || !contains(n2))
        throw new IllegalStateException("node not in graph");

    boolean n1n2EdgeExists = true;

  // iterates over n1, removing all edges containing n2 from n2
    Iterator<Edge> edgeIt = theGraph.get(n1).iterator();

    Edge deadEdge = null;
    while(edgeIt.hasNext())
    {
        deadEdge = edgeIt.next();

        if( deadEdge.n1.equals(n1) )
            theGraph.get(n2).remove(deadEdge);

        else if( deadEdge.n2.equals(n1) )
            theGraph.get(n1).remove(deadEdge);

        else
            n1n2EdgeExists = false;
    }
    if(n1n2EdgeExists){
          // removes the n1-n2 edge from n1
        theGraph.get(n1).remove(deadEdge);

        allEdges.remove(deadEdge);
        --numEdges;
    }

}

/**
 *  Method for searching the graph for a certain node.
 *  If the node is present in the graph, the method returns 
 *  true, otherwise, it returns false.
 * 
 *  @return boolean     true if the graph contains n, otherwise false. 
 */
public boolean contains(T n)
{
    return theGraph.containsKey(n);
}

/**
 *  Method for finding the number of nodes in the graph.
 * 
 *  @returns int    The number of nodes in the graph.
 */
public int size()
{
    return currentSize;
}

/**
 * Checks if there exists and edge between nodes n1 and n2.
 * Used for testing purposes.
 * 
 * @param n1    The first node that identifies the edge.
 * @param n2    The second node that identifies the edge.
 * @return true if and edge exists between n1 and n2, otherwise false.
 */
public boolean edgeExistsBetween(T n1, T n2)
{
    if(contains(n1))
    {
        boolean n1ContainsN2 = false;

        Iterator<Edge> edgeIt = theGraph.get(n1).iterator();

        Edge adjToN1;
        while(edgeIt.hasNext())
        {
            adjToN1 = edgeIt.next();
            if( adjToN1.n1.equals(n2) )
                n1ContainsN2 = true;
            else if( adjToN1.n2.equals(n2) )
                n1ContainsN2 = true;
            else
                ;
        }// while n1 has next edge
        return n1ContainsN2;
    }// if n1 in graph
    return false;
}

/**
 * Gets the number of edges in the graph.
 * Used for testing purposes.
 * 
 * @return the number of edges in the graph.
 */
public int getNumberOfEdges()
{
    return numEdges;
}

/**
 *  Method for calculating a minimum spanning tree for the graph.
 *  The method is supposed to returning a String representing the
 *  minimum spanning tree. The method is not allowed to modify the
 *  graph during the calculation, ie. the original graph must be
 *  identical to how the graph looked before the invocation of
 *  the method.
 *
 *  The minimum spanning tree is calculated using Kruskal's algorithm.
 *
 *  @return Graph A new instance of the Graph class, representing a
 *      minimal spanning tree.
 */
public MyMiniGraph<T> generateMinimumSpanningTree()
{
    int edgesAccepted = 0;
      //give all nodes to a class representing disjoint sets
    DisjSet<T> ds = new DisjSet<T>( theGraph.keySet() );

      //set up a new graph to represent the minimum spanning tree
    MyMiniGraph<T> minSpanTree = new MyMiniGraph<T>();
      //initialize minSpanTree with all theGraphs nodes
    Iterator<T> nodeIter = theGraph.keySet().iterator();
    while(nodeIter.hasNext())
        minSpanTree.addNode(nodeIter.next());

      //order all edges in theGraph in a priority queue
    PriorityQueue<Edge> pq = new PriorityQueue<Edge>(allEdges);
    Edge e;

      // Kruskals algorithm. Accepts the smallest edges in order
      // if they are not part of the same set which would cause a cycle. 
    while(edgesAccepted < currentSize -1)
    {
        e = pq.poll( );
        T uset = ds.find( e.n1 );
        T vset = ds.find( e.n2 );

        if(uset != vset)
        {
            // Accept the edge
            edgesAccepted++;
            ds.union(uset, vset);

             //if the edge is accepted, add it to minSpanTree
            minSpanTree.connectNodes(e.n1, e.n2, e.cost);
        }
    }
    return minSpanTree;
}

}

share|improve this question
2  
you have posted an entire class, can you strip it to just the bits we need to answer the question? –  Chimoo Feb 27 '11 at 17:39
    
And the actual stack-trace might help too. –  Boris Feb 27 '11 at 17:40

1 Answer 1

up vote 2 down vote accepted

I don't find any place where you initialize the member allEdges to a valid TreeSet object. Try to initialize (proper place seems like just where you define it)

share|improve this answer
    
thank you duduamar. that was the problem. –  Alexander E Feb 27 '11 at 18:09

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.