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android / platform / external / guava / eac7e2cd5f76f0b61712e386cf50085ba8de78c7 / . / android / guava-tests / test / com / google / common / graph / AbstractStandardUndirectedNetworkTest.java
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/*
* Copyright (C) 2014 The Guava Authors
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package com.google.common.graph;
import static com.google.common.truth.Truth.assertThat;
import static com.google.common.truth.TruthJUnit.assume;
import static org.junit.Assert.assertTrue;
import static org.junit.Assert.fail;
import com.google.common.collect.ImmutableSet;
import com.google.common.testing.EqualsTester;
import java.util.Set;
import org.junit.After;
import org.junit.Test;
/**
* Abstract base class for testing undirected {@link Network} implementations defined in this
* package.
*/
public abstract class AbstractStandardUndirectedNetworkTest extends AbstractNetworkTest {
private static final EndpointPair<Integer> ENDPOINTS_N1N2 = EndpointPair.ordered(N1, N2);
private static final EndpointPair<Integer> ENDPOINTS_N2N1 = EndpointPair.ordered(N2, N1);
@After
public void validateUndirectedEdges() {
for (Integer node : network.nodes()) {
new EqualsTester()
.addEqualityGroup(
network.inEdges(node), network.outEdges(node), network.incidentEdges(node))
.testEquals();
new EqualsTester()
.addEqualityGroup(
network.predecessors(node), network.successors(node), network.adjacentNodes(node))
.testEquals();
for (Integer adjacentNode : network.adjacentNodes(node)) {
assertThat(network.edgesConnecting(node, adjacentNode))
.containsExactlyElementsIn(network.edgesConnecting(adjacentNode, node));
}
}
}
@Override
@Test
public void nodes_checkReturnedSetMutability() {
Set<Integer> nodes = network.nodes();
try {
nodes.add(N2);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addNode(N1);
assertThat(network.nodes()).containsExactlyElementsIn(nodes);
}
}
@Override
@Test
public void edges_checkReturnedSetMutability() {
Set<String> edges = network.edges();
try {
edges.add(E12);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.edges()).containsExactlyElementsIn(edges);
}
}
@Override
@Test
public void incidentEdges_checkReturnedSetMutability() {
addNode(N1);
Set<String> incidentEdges = network.incidentEdges(N1);
try {
incidentEdges.add(E12);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.incidentEdges(N1)).containsExactlyElementsIn(incidentEdges);
}
}
@Override
@Test
public void adjacentNodes_checkReturnedSetMutability() {
addNode(N1);
Set<Integer> adjacentNodes = network.adjacentNodes(N1);
try {
adjacentNodes.add(N2);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.adjacentNodes(N1)).containsExactlyElementsIn(adjacentNodes);
}
}
@Override
public void adjacentEdges_checkReturnedSetMutability() {
addEdge(N1, N2, E12);
Set<String> adjacentEdges = network.adjacentEdges(E12);
try {
adjacentEdges.add(E23);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N2, N3, E23);
assertThat(network.adjacentEdges(E12)).containsExactlyElementsIn(adjacentEdges);
}
}
@Override
@Test
public void edgesConnecting_checkReturnedSetMutability() {
addNode(N1);
addNode(N2);
Set<String> edgesConnecting = network.edgesConnecting(N1, N2);
try {
edgesConnecting.add(E23);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.edgesConnecting(N1, N2)).containsExactlyElementsIn(edgesConnecting);
}
}
@Override
@Test
public void inEdges_checkReturnedSetMutability() {
addNode(N2);
Set<String> inEdges = network.inEdges(N2);
try {
inEdges.add(E12);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.inEdges(N2)).containsExactlyElementsIn(inEdges);
}
}
@Override
@Test
public void outEdges_checkReturnedSetMutability() {
addNode(N1);
Set<String> outEdges = network.outEdges(N1);
try {
outEdges.add(E12);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.outEdges(N1)).containsExactlyElementsIn(outEdges);
}
}
@Override
@Test
public void predecessors_checkReturnedSetMutability() {
addNode(N2);
Set<Integer> predecessors = network.predecessors(N2);
try {
predecessors.add(N1);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.predecessors(N2)).containsExactlyElementsIn(predecessors);
}
}
@Override
@Test
public void successors_checkReturnedSetMutability() {
addNode(N1);
Set<Integer> successors = network.successors(N1);
try {
successors.add(N2);
fail(ERROR_MODIFIABLE_COLLECTION);
} catch (UnsupportedOperationException e) {
addEdge(N1, N2, E12);
assertThat(network.successors(N1)).containsExactlyElementsIn(successors);
}
}
@Test
public void edges_containsOrderMismatch() {
addEdge(N1, N2, E12);
assertThat(network.asGraph().edges()).contains(ENDPOINTS_N2N1);
assertThat(network.asGraph().edges()).contains(ENDPOINTS_N1N2);
}
@Test
public void edgeConnectingOrNull_orderMismatch() {
addEdge(N1, N2, E12);
assertThat(network.edgeConnectingOrNull(ENDPOINTS_N2N1)).isEqualTo(E12);
assertThat(network.edgeConnectingOrNull(ENDPOINTS_N1N2)).isEqualTo(E12);
}
@Test
public void edgesConnecting_oneEdge() {
addEdge(N1, N2, E12);
assertThat(network.edgesConnecting(N1, N2)).containsExactly(E12);
assertThat(network.edgesConnecting(N2, N1)).containsExactly(E12);
}
@Test
public void inEdges_oneEdge() {
addEdge(N1, N2, E12);
assertThat(network.inEdges(N2)).containsExactly(E12);
assertThat(network.inEdges(N1)).containsExactly(E12);
}
@Test
public void outEdges_oneEdge() {
addEdge(N1, N2, E12);
assertThat(network.outEdges(N2)).containsExactly(E12);
assertThat(network.outEdges(N1)).containsExactly(E12);
}
@Test
public void predecessors_oneEdge() {
addEdge(N1, N2, E12);
assertThat(network.predecessors(N2)).containsExactly(N1);
assertThat(network.predecessors(N1)).containsExactly(N2);
}
@Test
public void successors_oneEdge() {
addEdge(N1, N2, E12);
assertThat(network.successors(N1)).containsExactly(N2);
assertThat(network.successors(N2)).containsExactly(N1);
}
@Test
public void inDegree_oneEdge() {
addEdge(N1, N2, E12);
assertThat(network.inDegree(N2)).isEqualTo(1);
assertThat(network.inDegree(N1)).isEqualTo(1);
}
@Test
public void outDegree_oneEdge() {
addEdge(N1, N2, E12);
assertThat(network.outDegree(N1)).isEqualTo(1);
assertThat(network.outDegree(N2)).isEqualTo(1);
}
@Test
public void edges_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.edges()).containsExactly(E11);
}
@Test
public void incidentEdges_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.incidentEdges(N1)).containsExactly(E11);
}
@Test
public void incidentNodes_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.incidentNodes(E11).nodeU()).isEqualTo(N1);
assertThat(network.incidentNodes(E11).nodeV()).isEqualTo(N1);
}
@Test
public void adjacentNodes_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
addEdge(N1, N2, E12);
assertThat(network.adjacentNodes(N1)).containsExactly(N1, N2);
}
@Test
public void adjacentEdges_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
addEdge(N1, N2, E12);
assertThat(network.adjacentEdges(E11)).containsExactly(E12);
}
@Test
public void edgesConnecting_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.edgesConnecting(N1, N1)).containsExactly(E11);
addEdge(N1, N2, E12);
assertThat(network.edgesConnecting(N1, N2)).containsExactly(E12);
assertThat(network.edgesConnecting(N2, N1)).containsExactly(E12);
assertThat(network.edgesConnecting(N1, N1)).containsExactly(E11);
}
@Test
public void inEdges_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.inEdges(N1)).containsExactly(E11);
addEdge(N1, N2, E12);
assertThat(network.inEdges(N1)).containsExactly(E11, E12);
}
@Test
public void outEdges_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.outEdges(N1)).containsExactly(E11);
addEdge(N2, N1, E12);
assertThat(network.outEdges(N1)).containsExactly(E11, E12);
}
@Test
public void predecessors_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.predecessors(N1)).containsExactly(N1);
addEdge(N1, N2, E12);
assertThat(network.predecessors(N1)).containsExactly(N1, N2);
}
@Test
public void successors_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.successors(N1)).containsExactly(N1);
addEdge(N2, N1, E12);
assertThat(network.successors(N1)).containsExactly(N1, N2);
}
@Test
public void degree_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.degree(N1)).isEqualTo(2);
addEdge(N1, N2, E12);
assertThat(network.degree(N1)).isEqualTo(3);
}
@Test
public void inDegree_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.inDegree(N1)).isEqualTo(2);
addEdge(N1, N2, E12);
assertThat(network.inDegree(N1)).isEqualTo(3);
}
@Test
public void outDegree_selfLoop() {
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(network.outDegree(N1)).isEqualTo(2);
addEdge(N2, N1, E12);
assertThat(network.outDegree(N1)).isEqualTo(3);
}
// Element Mutation
@Test
public void addEdge_existingNodes() {
assume().that(graphIsMutable()).isTrue();
// Adding nodes initially for safety (insulating from possible future
// modifications to proxy methods)
addNode(N1);
addNode(N2);
assertThat(networkAsMutableNetwork.addEdge(N1, N2, E12)).isTrue();
assertThat(network.edges()).contains(E12);
assertThat(network.edgesConnecting(N1, N2)).containsExactly(E12);
assertThat(network.edgesConnecting(N2, N1)).containsExactly(E12);
}
@Test
public void addEdge_existingEdgeBetweenSameNodes() {
assume().that(graphIsMutable()).isTrue();
assertThat(networkAsMutableNetwork.addEdge(N1, N2, E12)).isTrue();
ImmutableSet<String> edges = ImmutableSet.copyOf(network.edges());
assertThat(networkAsMutableNetwork.addEdge(N1, N2, E12)).isFalse();
assertThat(network.edges()).containsExactlyElementsIn(edges);
assertThat(networkAsMutableNetwork.addEdge(N2, N1, E12)).isFalse();
assertThat(network.edges()).containsExactlyElementsIn(edges);
}
@Test
public void addEdge_existingEdgeBetweenDifferentNodes() {
assume().that(graphIsMutable()).isTrue();
addEdge(N1, N2, E12);
try {
// Edge between totally different nodes
networkAsMutableNetwork.addEdge(N4, N5, E12);
fail(ERROR_ADDED_EXISTING_EDGE);
} catch (IllegalArgumentException e) {
assertThat(e.getMessage()).contains(ERROR_REUSE_EDGE);
}
}
@Test
public void addEdge_parallelEdge_notAllowed() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsParallelEdges()).isFalse();
addEdge(N1, N2, E12);
try {
networkAsMutableNetwork.addEdge(N1, N2, EDGE_NOT_IN_GRAPH);
fail(ERROR_ADDED_PARALLEL_EDGE);
} catch (IllegalArgumentException e) {
assertThat(e.getMessage()).contains(ERROR_PARALLEL_EDGE);
}
try {
networkAsMutableNetwork.addEdge(N2, N1, EDGE_NOT_IN_GRAPH);
fail(ERROR_ADDED_PARALLEL_EDGE);
} catch (IllegalArgumentException e) {
assertThat(e.getMessage()).contains(ERROR_PARALLEL_EDGE);
}
}
@Test
public void addEdge_parallelEdge_allowsParallelEdges() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsParallelEdges()).isTrue();
assertTrue(networkAsMutableNetwork.addEdge(N1, N2, E12));
assertTrue(networkAsMutableNetwork.addEdge(N2, N1, E21));
assertTrue(networkAsMutableNetwork.addEdge(N1, N2, E12_A));
assertThat(network.edgesConnecting(N1, N2)).containsExactly(E12, E12_A, E21);
}
@Test
public void addEdge_orderMismatch() {
assume().that(graphIsMutable()).isTrue();
EndpointPair<Integer> endpoints = EndpointPair.ordered(N1, N2);
assertThat(networkAsMutableNetwork.addEdge(endpoints, E12)).isTrue();
}
@Test
public void addEdge_selfLoop_notAllowed() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isFalse();
try {
networkAsMutableNetwork.addEdge(N1, N1, E11);
fail(ERROR_ADDED_SELF_LOOP);
} catch (IllegalArgumentException e) {
assertThat(e).hasMessageThat().contains(ERROR_SELF_LOOP);
}
}
/**
* This test checks an implementation dependent feature. It tests that the method {@code addEdge}
* will silently add the missing nodes to the graph, then add the edge connecting them. We are not
* using the proxy methods here as we want to test {@code addEdge} when the end-points are not
* elements of the graph.
*/
@Test
public void addEdge_nodesNotInGraph() {
assume().that(graphIsMutable()).isTrue();
networkAsMutableNetwork.addNode(N1);
assertTrue(networkAsMutableNetwork.addEdge(N1, N5, E15));
assertTrue(networkAsMutableNetwork.addEdge(N4, N1, E41));
assertTrue(networkAsMutableNetwork.addEdge(N2, N3, E23));
assertThat(network.nodes()).containsExactly(N1, N5, N4, N2, N3);
assertThat(network.edges()).containsExactly(E15, E41, E23);
assertThat(network.edgesConnecting(N1, N5)).containsExactly(E15);
assertThat(network.edgesConnecting(N4, N1)).containsExactly(E41);
assertThat(network.edgesConnecting(N2, N3)).containsExactly(E23);
assertThat(network.edgesConnecting(N3, N2)).containsExactly(E23);
}
@Test
public void addEdge_selfLoop() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isTrue();
assertThat(networkAsMutableNetwork.addEdge(N1, N1, E11)).isTrue();
assertThat(network.edges()).contains(E11);
assertThat(network.edgesConnecting(N1, N1)).containsExactly(E11);
}
@Test
public void addEdge_existingSelfLoopEdgeBetweenSameNodes() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
ImmutableSet<String> edges = ImmutableSet.copyOf(network.edges());
assertThat(networkAsMutableNetwork.addEdge(N1, N1, E11)).isFalse();
assertThat(network.edges()).containsExactlyElementsIn(edges);
}
@Test
public void addEdge_existingEdgeBetweenDifferentNodes_selfLoops() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
try {
networkAsMutableNetwork.addEdge(N1, N2, E11);
fail("Reusing an existing self-loop edge to connect different nodes succeeded");
} catch (IllegalArgumentException e) {
assertThat(e.getMessage()).contains(ERROR_REUSE_EDGE);
}
try {
networkAsMutableNetwork.addEdge(N2, N2, E11);
fail("Reusing an existing self-loop edge to make a different self-loop edge succeeded");
} catch (IllegalArgumentException e) {
assertThat(e.getMessage()).contains(ERROR_REUSE_EDGE);
}
addEdge(N1, N2, E12);
try {
networkAsMutableNetwork.addEdge(N1, N1, E12);
fail("Reusing an existing edge to add a self-loop edge between different nodes succeeded");
} catch (IllegalArgumentException e) {
assertThat(e.getMessage()).contains(ERROR_REUSE_EDGE);
}
}
@Test
public void addEdge_parallelSelfLoopEdge_notAllowed() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isTrue();
assume().that(network.allowsParallelEdges()).isFalse();
addEdge(N1, N1, E11);
try {
networkAsMutableNetwork.addEdge(N1, N1, EDGE_NOT_IN_GRAPH);
fail("Adding a parallel self-loop edge succeeded");
} catch (IllegalArgumentException e) {
assertThat(e.getMessage()).contains(ERROR_PARALLEL_EDGE);
}
}
@Test
public void addEdge_parallelSelfLoopEdge_allowsParallelEdges() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isTrue();
assume().that(network.allowsParallelEdges()).isTrue();
assertTrue(networkAsMutableNetwork.addEdge(N1, N1, E11));
assertTrue(networkAsMutableNetwork.addEdge(N1, N1, E11_A));
assertThat(network.edgesConnecting(N1, N1)).containsExactly(E11, E11_A);
}
@Test
public void removeNode_existingNodeWithSelfLoopEdge() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isTrue();
addNode(N1);
addEdge(N1, N1, E11);
assertThat(networkAsMutableNetwork.removeNode(N1)).isTrue();
assertThat(network.nodes()).isEmpty();
assertThat(network.edges()).doesNotContain(E11);
}
@Test
public void removeEdge_existingSelfLoopEdge() {
assume().that(graphIsMutable()).isTrue();
assume().that(network.allowsSelfLoops()).isTrue();
addEdge(N1, N1, E11);
assertThat(networkAsMutableNetwork.removeEdge(E11)).isTrue();
assertThat(network.edges()).doesNotContain(E11);
assertThat(network.edgesConnecting(N1, N1)).isEmpty();
}
}