utils/misc/src/main/java/org/onlab/graph/BellmanFordGraphSearch.java - onos - Gitiles

 package org.onlab.graph;

 /**
  * Bellman-Ford graph search algorithm for locating shortest-paths in
  * directed graphs that may contain negative cycles.
  */
 public class BellmanFordGraphSearch<V extends Vertex, E extends Edge<V>>
         extends AbstractGraphPathSearch<V, E> {

     @Override
     public Result<V, E> search(Graph<V, E> graph, V src, V dst,
                                EdgeWeight<V, E> weight) {
         checkArguments(graph, src, dst);

         // Prepare the graph search result.
         DefaultResult result = new DefaultResult(src, dst);

         // The source vertex has cost 0, of course.
         result.updateVertex(src, null, 0.0, true);

         int max = graph.getVertexes().size() - 1;
         for (int i = 0; i < max; i++) {
             // Relax, if possible, all egress edges of the current vertex.
             for (E edge : graph.getEdges()) {
                 if (result.hasCost(edge.src())) {
                     result.relaxEdge(edge, result.cost(edge.src()), weight);
                 }
             }
         }

         // Remove any vertexes reached by traversing edges with negative weights.
         for (E edge : graph.getEdges()) {
             if (result.hasCost(edge.src())) {
                 if (result.relaxEdge(edge, result.cost(edge.src()), weight)) {
                     result.removeVertex(edge.dst());
                 }
             }
         }

         // Finally, but the paths on the search result and return.
         result.buildPaths();
         return result;
     }

 }
	package org.onlab.graph;

	/**
	* Bellman-Ford graph search algorithm for locating shortest-paths in
	* directed graphs that may contain negative cycles.
	*/
	public class BellmanFordGraphSearch<V extends Vertex, E extends Edge<V>>
	extends AbstractGraphPathSearch<V, E> {

	@Override
	public Result<V, E> search(Graph<V, E> graph, V src, V dst,
	EdgeWeight<V, E> weight) {
	checkArguments(graph, src, dst);

	// Prepare the graph search result.
	DefaultResult result = new DefaultResult(src, dst);

	// The source vertex has cost 0, of course.
	result.updateVertex(src, null, 0.0, true);

	int max = graph.getVertexes().size() - 1;
	for (int i = 0; i < max; i++) {
	// Relax, if possible, all egress edges of the current vertex.
	for (E edge : graph.getEdges()) {
	if (result.hasCost(edge.src())) {
	result.relaxEdge(edge, result.cost(edge.src()), weight);
	}
	}
	}

	// Remove any vertexes reached by traversing edges with negative weights.
	for (E edge : graph.getEdges()) {
	if (result.hasCost(edge.src())) {
	if (result.relaxEdge(edge, result.cost(edge.src()), weight)) {
	result.removeVertex(edge.dst());
	}
	}
	}

	// Finally, but the paths on the search result and return.
	result.buildPaths();
	return result;
	}

	}