@Test public void builder_expectedNodeCount_negative() { try { NetworkBuilder.directed().expectedNodeCount(-1); fail("Should have rejected negative expected node count."); } catch (IllegalArgumentException e) { assertThat(e.getMessage()).contains(ERROR_NEGATIVE_COUNT); } }
@Test public void createUndirected_expectedNodeCount() { MutableNetwork<Integer, String> undirectedGraph = NetworkBuilder.undirected().expectedNodeCount(NODE_COUNT).build(); assertThat(undirectedGraph.addEdge(N1, N2, E12)).isTrue(); assertThat(undirectedGraph.edgesConnecting(N1, N2)).isEqualTo(ImmutableSet.of(E12)); assertThat(undirectedGraph.edgesConnecting(N2, N1)).isEqualTo(ImmutableSet.of(E12)); }
/** Creates a mutable copy of {@code network} with the same nodes and edges. */ public static <N, E> MutableNetwork<N, E> copyOf(Network<N, E> network) { MutableNetwork<N, E> copy = NetworkBuilder.from(network) .expectedNodeCount(network.nodes().size()) .expectedEdgeCount(network.edges().size()) .build(); for (N node : network.nodes()) { copy.addNode(node); } for (E edge : network.edges()) { EndpointPair<N> endpointPair = network.incidentNodes(edge); copy.addEdge(endpointPair.nodeU(), endpointPair.nodeV(), edge); } return copy; }
@Test public void createDirected_expectedNodeCount() { MutableNetwork<Integer, String> directedGraph = NetworkBuilder.directed().expectedNodeCount(NODE_COUNT).build(); assertThat(directedGraph.addEdge(N1, N2, E12)).isTrue(); assertThat(directedGraph.edgesConnecting(N1, N2)).isEqualTo(ImmutableSet.of(E12)); assertThat(directedGraph.edgesConnecting(N2, N1)).isEmpty(); }
/** * Returns the subgraph of {@code network} induced by {@code nodes}. This subgraph is a new graph * that contains all of the nodes in {@code nodes}, and all of the {@link Network#edges() edges} * from {@code network} for which the {@link Network#incidentNodes(Object) incident nodes} are * both contained by {@code nodes}. * * @throws IllegalArgumentException if any element in {@code nodes} is not a node in the graph */ public static <N, E> MutableNetwork<N, E> inducedSubgraph( Network<N, E> network, Iterable<? extends N> nodes) { MutableNetwork<N, E> subgraph = (nodes instanceof Collection) ? NetworkBuilder.from(network).expectedNodeCount(((Collection) nodes).size()).build() : NetworkBuilder.from(network).build(); for (N node : nodes) { subgraph.addNode(node); } for (N node : subgraph.nodes()) { for (E edge : network.outEdges(node)) { N successorNode = network.incidentNodes(edge).adjacentNode(node); if (subgraph.nodes().contains(successorNode)) { subgraph.addEdge(node, successorNode, edge); } } } return subgraph; }
/** Creates a mutable copy of {@code network} with the same nodes and edges. */ public static <N, E> MutableNetwork<N, E> copyOf(Network<N, E> network) { MutableNetwork<N, E> copy = NetworkBuilder.from(network) .expectedNodeCount(network.nodes().size()) .expectedEdgeCount(network.edges().size()) .build(); for (N node : network.nodes()) { copy.addNode(node); } for (E edge : network.edges()) { EndpointPair<N> endpointPair = network.incidentNodes(edge); copy.addEdge(endpointPair.nodeU(), endpointPair.nodeV(), edge); } return copy; }
/** Creates a mutable copy of {@code network} with the same nodes and edges. */ public static <N, E> MutableNetwork<N, E> copyOf(Network<N, E> network) { MutableNetwork<N, E> copy = NetworkBuilder.from(network) .expectedNodeCount(network.nodes().size()) .expectedEdgeCount(network.edges().size()) .build(); for (N node : network.nodes()) { copy.addNode(node); } for (E edge : network.edges()) { EndpointPair<N> endpointPair = network.incidentNodes(edge); copy.addEdge(endpointPair.nodeU(), endpointPair.nodeV(), edge); } return copy; }
/** * Returns the subgraph of {@code network} induced by {@code nodes}. This subgraph is a new graph * that contains all of the nodes in {@code nodes}, and all of the {@link Network#edges() edges} * from {@code network} for which the {@link Network#incidentNodes(Object) incident nodes} are * both contained by {@code nodes}. * * @throws IllegalArgumentException if any element in {@code nodes} is not a node in the graph */ public static <N, E> MutableNetwork<N, E> inducedSubgraph( Network<N, E> network, Iterable<? extends N> nodes) { MutableNetwork<N, E> subgraph = (nodes instanceof Collection) ? NetworkBuilder.from(network).expectedNodeCount(((Collection) nodes).size()).build() : NetworkBuilder.from(network).build(); for (N node : nodes) { subgraph.addNode(node); } for (N node : subgraph.nodes()) { for (E edge : network.outEdges(node)) { N successorNode = network.incidentNodes(edge).adjacentNode(node); if (subgraph.nodes().contains(successorNode)) { subgraph.addEdge(node, successorNode, edge); } } } return subgraph; }
private static class TransposedNetwork<N, E> extends ForwardingNetwork<N, E> { private final Network<N, E> network; TransposedNetwork(Network<N, E> network) { this.network = network; } @Override protected Network<N, E> delegate() { return network; } @Override public Set<N> predecessors(N node) { return delegate().successors(node); // transpose } @Override public Set<N> successors(N node) { return delegate().predecessors(node); // transpose } @Override public int inDegree(N node) { return delegate().outDegree(node); // transpose } @Override public int outDegree(N node) { return delegate().inDegree(node); // transpose
/** * Returns an empty {@link MutableCTree} with the properties of this {@link TreeNetworkBuilder}. */ // TODO(jrtom): decide how we're going to handle different implementations. // For the graph stuff, we don't really need different implementations, but // for trees, maybe we do; at least for binary trees vs. trees with no restrictions on outgoing edges... public <N1 extends N, E1 extends E> MutableCTreeNetwork<N1, E1> build() { NetworkBuilder<Object, Object> graphBuilder = NetworkBuilder.directed().allowsSelfLoops(false).allowsParallelEdges(false); if (expectedNodeCount.isPresent()) { graphBuilder = graphBuilder.expectedNodeCount(expectedNodeCount.get()); } MutableNetwork<N1, E1> delegate = graphBuilder.nodeOrder(nodeOrder).edgeOrder(edgeOrder).build(); @SuppressWarnings("unchecked") Optional<N1> rootCast = (Optional<N1>) root; return new DelegateCTreeNetwork<N1, E1>(delegate, rootCast); }
directed ? NetworkBuilder.directed() : NetworkBuilder.undirected(); MutableNetwork<N, E> graph = builder.expectedNodeCount(node_count).expectedEdgeCount(edge_count).build();
@Test public void builder_expectedNodeCount_negative() { try { NetworkBuilder.directed().expectedNodeCount(-1); fail("Should have rejected negative expected node count."); } catch (IllegalArgumentException e) { assertThat(e.getMessage()).contains(ERROR_NEGATIVE_COUNT); } }
/** Returns the subgraph containing only {@link DependencyEdge}s that would not break a cycle. */ // TODO(dpb): Return a network containing only Binding nodes. private ImmutableNetwork<Node, DependencyEdge> nonCycleBreakingDependencyGraph( BindingGraph bindingGraph) { MutableNetwork<Node, DependencyEdge> dependencyNetwork = NetworkBuilder.from(bindingGraph.network()) .expectedNodeCount(bindingGraph.network().nodes().size()) .expectedEdgeCount(bindingGraph.dependencyEdges().size()) .build(); bindingGraph.dependencyEdges().stream() .filter(edge -> !breaksCycle(edge, bindingGraph)) .forEach( edge -> { EndpointPair<Node> endpoints = bindingGraph.network().incidentNodes(edge); dependencyNetwork.addEdge(endpoints.source(), endpoints.target(), edge); }); return ImmutableNetwork.copyOf(dependencyNetwork); }
@Test public void createUndirected_expectedNodeCount() { MutableNetwork<Integer, String> undirectedGraph = NetworkBuilder.undirected().expectedNodeCount(NODE_COUNT).build(); assertThat(undirectedGraph.addEdge(N1, N2, E12)).isTrue(); assertThat(undirectedGraph.edgesConnecting(N1, N2)).isEqualTo(ImmutableSet.of(E12)); assertThat(undirectedGraph.edgesConnecting(N2, N1)).isEqualTo(ImmutableSet.of(E12)); }
/** Creates a mutable copy of {@code network} with the same nodes and edges. */ public static <N, E> MutableNetwork<N, E> copyOf(Network<N, E> network) { MutableNetwork<N, E> copy = NetworkBuilder.from(network) .expectedNodeCount(network.nodes().size()) .expectedEdgeCount(network.edges().size()) .build(); for (N node : network.nodes()) { copy.addNode(node); } for (E edge : network.edges()) { EndpointPair<N> endpointPair = network.incidentNodes(edge); copy.addEdge(endpointPair.nodeU(), endpointPair.nodeV(), edge); } return copy; }
/** Creates a mutable copy of {@code network} with the same nodes and edges. */ public static <N, E> MutableNetwork<N, E> copyOf(Network<N, E> network) { MutableNetwork<N, E> copy = NetworkBuilder.from(network) .expectedNodeCount(network.nodes().size()) .expectedEdgeCount(network.edges().size()) .build(); for (N node : network.nodes()) { copy.addNode(node); } for (E edge : network.edges()) { EndpointPair<N> endpointPair = network.incidentNodes(edge); copy.addEdge(endpointPair.nodeU(), endpointPair.nodeV(), edge); } return copy; }
@Test public void createDirected_expectedNodeCount() { MutableNetwork<Integer, String> directedGraph = NetworkBuilder.directed().expectedNodeCount(NODE_COUNT).build(); assertThat(directedGraph.addEdge(N1, N2, E12)).isTrue(); assertThat(directedGraph.edgesConnecting(N1, N2)).isEqualTo(ImmutableSet.of(E12)); assertThat(directedGraph.edgesConnecting(N2, N1)).isEmpty(); }
/** * Returns the subgraph of {@code network} induced by {@code nodes}. This subgraph is a new graph * that contains all of the nodes in {@code nodes}, and all of the {@link Network#edges() edges} * from {@code network} for which the {@link Network#incidentNodes(Object) incident nodes} are * both contained by {@code nodes}. * * @throws IllegalArgumentException if any element in {@code nodes} is not a node in the graph */ public static <N, E> MutableNetwork<N, E> inducedSubgraph( Network<N, E> network, Iterable<? extends N> nodes) { MutableNetwork<N, E> subgraph = (nodes instanceof Collection) ? NetworkBuilder.from(network).expectedNodeCount(((Collection) nodes).size()).build() : NetworkBuilder.from(network).build(); for (N node : nodes) { subgraph.addNode(node); } for (N node : subgraph.nodes()) { for (E edge : network.outEdges(node)) { N successorNode = network.incidentNodes(edge).adjacentNode(node); if (subgraph.nodes().contains(successorNode)) { subgraph.addEdge(node, successorNode, edge); } } } return subgraph; }
/** * Returns the subgraph of {@code network} induced by {@code nodes}. This subgraph is a new graph * that contains all of the nodes in {@code nodes}, and all of the {@link Network#edges() edges} * from {@code network} for which the {@link Network#incidentNodes(Object) incident nodes} are * both contained by {@code nodes}. * * @throws IllegalArgumentException if any element in {@code nodes} is not a node in the graph */ public static <N, E> MutableNetwork<N, E> inducedSubgraph( Network<N, E> network, Iterable<? extends N> nodes) { MutableNetwork<N, E> subgraph = (nodes instanceof Collection) ? NetworkBuilder.from(network).expectedNodeCount(((Collection) nodes).size()).build() : NetworkBuilder.from(network).build(); for (N node : nodes) { subgraph.addNode(node); } for (N node : subgraph.nodes()) { for (E edge : network.outEdges(node)) { N successorNode = network.incidentNodes(edge).adjacentNode(node); if (subgraph.nodes().contains(successorNode)) { subgraph.addEdge(node, successorNode, edge); } } } return subgraph; }