utils/misc/src/test/java/org/onlab/graph/BellmanFordGraphSearchTest.java - onos - Gitiles

 package org.onlab.graph;

 import org.junit.Test;

 import java.util.HashSet;
 import java.util.Set;

 import static org.junit.Assert.assertEquals;

 /**
  * Test of the Bellman-Ford algorithm.
  */
 public class BellmanFordGraphSearchTest extends BreadthFirstSearchTest {

     @Override
     protected AbstractGraphPathSearch<TestVertex, TestEdge> graphSearch() {
         return new BellmanFordGraphSearch<>();
     }

     @Test
     @Override
     public void defaultGraphTest() {
         executeDefaultTest(7, 5, 5.0);
     }

     @Test
     public void defaultHopCountWeight() {
         weight = null;
         executeDefaultTest(10, 3, 3.0);
     }

     @Test
     public void searchGraphWithNegativeCycles() {
         Set<TestVertex> vertexes = new HashSet<>(vertices());
         vertexes.add(Z);

         Set<TestEdge> edges = new HashSet<>(edges());
         edges.add(new TestEdge(G, Z, 1.0));
         edges.add(new TestEdge(Z, G, -2.0));

         g = new AdjacencyListsGraph<>(vertexes, edges);

         GraphPathSearch<TestVertex, TestEdge> search = graphSearch();
         Set<Path<TestVertex, TestEdge>> paths = search.search(g, A, H, weight).paths();
         assertEquals("incorrect paths count", 1, paths.size());

         Path p = paths.iterator().next();
         assertEquals("incorrect src", A, p.src());
         assertEquals("incorrect dst", H, p.dst());
         assertEquals("incorrect path length", 5, p.edges().size());
         assertEquals("incorrect path cost", 5.0, p.cost(), 0.1);

         paths = search.search(g, A, G, weight).paths();
         assertEquals("incorrect paths count", 0, paths.size());

         paths = search.search(g, A, null, weight).paths();
         printPaths(paths);
         assertEquals("incorrect paths count", 6, paths.size());
     }

 }
	package org.onlab.graph;

	import org.junit.Test;

	import java.util.HashSet;
	import java.util.Set;

	import static org.junit.Assert.assertEquals;

	/**
	* Test of the Bellman-Ford algorithm.
	*/
	public class BellmanFordGraphSearchTest extends BreadthFirstSearchTest {

	@Override
	protected AbstractGraphPathSearch<TestVertex, TestEdge> graphSearch() {
	return new BellmanFordGraphSearch<>();
	}

	@Test
	@Override
	public void defaultGraphTest() {
	executeDefaultTest(7, 5, 5.0);
	}

	@Test
	public void defaultHopCountWeight() {
	weight = null;
	executeDefaultTest(10, 3, 3.0);
	}

	@Test
	public void searchGraphWithNegativeCycles() {
	Set<TestVertex> vertexes = new HashSet<>(vertices());
	vertexes.add(Z);

	Set<TestEdge> edges = new HashSet<>(edges());
	edges.add(new TestEdge(G, Z, 1.0));
	edges.add(new TestEdge(Z, G, -2.0));

	g = new AdjacencyListsGraph<>(vertexes, edges);

	GraphPathSearch<TestVertex, TestEdge> search = graphSearch();
	Set<Path<TestVertex, TestEdge>> paths = search.search(g, A, H, weight).paths();
	assertEquals("incorrect paths count", 1, paths.size());

	Path p = paths.iterator().next();
	assertEquals("incorrect src", A, p.src());
	assertEquals("incorrect dst", H, p.dst());
	assertEquals("incorrect path length", 5, p.edges().size());
	assertEquals("incorrect path cost", 5.0, p.cost(), 0.1);

	paths = search.search(g, A, G, weight).paths();
	assertEquals("incorrect paths count", 0, paths.size());

	paths = search.search(g, A, null, weight).paths();
	printPaths(paths);
	assertEquals("incorrect paths count", 6, paths.size());
	}

	}