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/*
 * Copyright (C) 2018 The Dagger 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 dagger.internal.codegen.bindinggraphvalidation;

import static com.google.common.base.Preconditions.checkArgument;
import static com.google.common.collect.Iterables.getLast;
import static com.google.common.collect.Iterables.limit;
import static com.google.common.collect.Iterables.skip;
import static com.google.common.collect.Sets.newHashSetWithExpectedSize;
import static dagger.internal.codegen.base.RequestKinds.extractKeyType;
import static dagger.internal.codegen.base.RequestKinds.getRequestKind;
import static dagger.internal.codegen.extension.DaggerGraphs.shortestPath;
import static dagger.internal.codegen.extension.DaggerStreams.instancesOf;
import static dagger.internal.codegen.extension.DaggerStreams.toImmutableList;
import static dagger.internal.codegen.extension.DaggerStreams.toImmutableSet;
import static javax.tools.Diagnostic.Kind.ERROR;

import androidx.room.compiler.processing.XType;
import com.google.auto.value.AutoValue;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.ImmutableSet;
import com.google.common.collect.Iterables;
import com.google.common.graph.EndpointPair;
import com.google.common.graph.Graphs;
import com.google.common.graph.ImmutableNetwork;
import com.google.common.graph.MutableNetwork;
import com.google.common.graph.NetworkBuilder;
import dagger.internal.codegen.base.Formatter;
import dagger.internal.codegen.base.MapType;
import dagger.internal.codegen.base.OptionalType;
import dagger.internal.codegen.binding.DependencyRequestFormatter;
import dagger.internal.codegen.javapoet.TypeNames;
import dagger.internal.codegen.model.Binding;
import dagger.internal.codegen.model.BindingGraph;
import dagger.internal.codegen.model.BindingGraph.ComponentNode;
import dagger.internal.codegen.model.BindingGraph.DependencyEdge;
import dagger.internal.codegen.model.BindingGraph.Node;
import dagger.internal.codegen.model.BindingKind;
import dagger.internal.codegen.model.DependencyRequest;
import dagger.internal.codegen.model.DiagnosticReporter;
import dagger.internal.codegen.model.RequestKind;
import dagger.internal.codegen.validation.ValidationBindingGraphPlugin;
import java.util.List;
import java.util.Optional;
import java.util.Set;
import java.util.stream.Stream;
import javax.inject.Inject;

/** Reports errors for dependency cycles. */
final class DependencyCycleValidator extends ValidationBindingGraphPlugin {

  private final DependencyRequestFormatter dependencyRequestFormatter;

  @Inject
  DependencyCycleValidator(DependencyRequestFormatter dependencyRequestFormatter) {
    this.dependencyRequestFormatter = dependencyRequestFormatter;
  }

  @Override
  public String pluginName() {
    return "Dagger/DependencyCycle";
  }

  @Override
  public void visitGraph(BindingGraph bindingGraph, DiagnosticReporter diagnosticReporter) {
    ImmutableNetwork dependencyGraph =
        nonCycleBreakingDependencyGraph(bindingGraph);
    // First check the graph for a cycle. If there is one, then we'll do more work to report where.
    if (!Graphs.hasCycle(dependencyGraph)) {
      return;
    }
    // Check each endpoint pair only once, no matter how many parallel edges connect them.
    Set> dependencyEndpointPairs = dependencyGraph.asGraph().edges();
    Set> visited = newHashSetWithExpectedSize(dependencyEndpointPairs.size());
    for (EndpointPair endpointPair : dependencyEndpointPairs) {
      cycleContainingEndpointPair(endpointPair, dependencyGraph, visited)
          .ifPresent(cycle -> reportCycle(cycle, bindingGraph, diagnosticReporter));
    }
  }

  private Optional> cycleContainingEndpointPair(
      EndpointPair endpoints,
      ImmutableNetwork dependencyGraph,
      Set> visited) {
    if (!visited.add(endpoints)) {
      // don't recheck endpoints we already know are part of a cycle
      return Optional.empty();
    }

    // If there's a path from the target back to the source, there's a cycle.
    ImmutableList cycleNodes =
        shortestPath(dependencyGraph, endpoints.target(), endpoints.source());
    if (cycleNodes.isEmpty()) {
      return Optional.empty();
    }

    Cycle cycle = Cycle.fromPath(cycleNodes);
    visited.addAll(cycle.endpointPairs()); // no need to check any edge in this cycle again
    return Optional.of(cycle);
  }

  /**
   * Reports a dependency cycle at the dependency into the cycle that is closest to an entry point.
   *
   * 

For cycles found in reachable binding graphs, looks for the shortest path from the component * that contains the cycle (all bindings in a cycle must be in the same component; see below) to * some binding in the cycle. Then looks for the last dependency in that path that is not in the * cycle; that is the dependency that will be reported, so that the dependency trace will end just * before the cycle. * *

For cycles found during full binding graph validation, just reports the component that * contains the cycle. * *

Proof (by counterexample) that all bindings in a cycle must be in the same component: Assume * one binding in the cycle is in a parent component. Bindings cannot depend on bindings in child * components, so that binding cannot depend on the next binding in the cycle. */ private void reportCycle( Cycle cycle, BindingGraph bindingGraph, DiagnosticReporter diagnosticReporter) { if (bindingGraph.isFullBindingGraph()) { diagnosticReporter.reportComponent( ERROR, bindingGraph.componentNode(cycle.nodes().asList().get(0).componentPath()).get(), errorMessage(cycle, bindingGraph)); return; } ImmutableList path = shortestPathToCycleFromAnEntryPoint(cycle, bindingGraph); Node cycleStartNode = path.get(path.size() - 1); Node previousNode = path.get(path.size() - 2); DependencyEdge dependencyToReport = chooseDependencyEdgeConnecting(previousNode, cycleStartNode, bindingGraph); diagnosticReporter.reportDependency( ERROR, dependencyToReport, errorMessage(cycle.shift(cycleStartNode), bindingGraph) // The actual dependency trace is included from the reportDependency call. + "\n\nThe cycle is requested via:"); } private ImmutableList shortestPathToCycleFromAnEntryPoint( Cycle cycle, BindingGraph bindingGraph) { Node someCycleNode = cycle.nodes().asList().get(0); ComponentNode componentContainingCycle = bindingGraph.componentNode(someCycleNode.componentPath()).get(); ImmutableList pathToCycle = shortestPath(bindingGraph.network(), componentContainingCycle, someCycleNode); return subpathToCycle(pathToCycle, cycle); } /** * Returns the subpath from the head of {@code path} to the first node in {@code path} that's in * the cycle. */ private ImmutableList subpathToCycle(ImmutableList path, Cycle cycle) { ImmutableList.Builder subpath = ImmutableList.builder(); for (Node node : path) { subpath.add(node); if (cycle.nodes().contains(node)) { return subpath.build(); } } throw new IllegalArgumentException( "path " + path + " doesn't contain any nodes in cycle " + cycle); } private String errorMessage(Cycle cycle, BindingGraph graph) { StringBuilder message = new StringBuilder("Found a dependency cycle:"); ImmutableList cycleRequests = cycle.endpointPairs().stream() // TODO(dpb): Would be nice to take the dependency graph here. .map(endpointPair -> nonCycleBreakingEdge(endpointPair, graph)) .map(DependencyEdge::dependencyRequest) .collect(toImmutableList()) .reverse(); dependencyRequestFormatter.formatIndentedList(message, cycleRequests, 0); message.append("\n") .append(dependencyRequestFormatter.format(cycleRequests.get(0))) .append("\n") .append(Formatter.INDENT).append("..."); return message.toString(); } /** * Returns one of the edges between two nodes that doesn't {@linkplain * #breaksCycle(DependencyEdge, BindingGraph) break} a cycle. */ private DependencyEdge nonCycleBreakingEdge(EndpointPair endpointPair, BindingGraph graph) { return graph.network().edgesConnecting(endpointPair.source(), endpointPair.target()).stream() .flatMap(instancesOf(DependencyEdge.class)) .filter(edge -> !breaksCycle(edge, graph)) .findFirst() .get(); } private boolean breaksCycle(DependencyEdge edge, BindingGraph graph) { // Map multibindings depend on Map> entries, but those don't break any // cycles, so ignore them. if (edge.dependencyRequest().key().multibindingContributionIdentifier().isPresent()) { return false; } if (breaksCycle( edge.dependencyRequest().key().type().xprocessing(), edge.dependencyRequest().kind())) { return true; } Node target = graph.network().incidentNodes(edge).target(); if (target instanceof Binding && ((Binding) target).kind().equals(BindingKind.OPTIONAL)) { /* For @BindsOptionalOf bindings, unwrap the type inside the Optional. If the unwrapped type * breaks the cycle, so does the optional binding. */ XType optionalValueType = OptionalType.from(edge.dependencyRequest().key()).valueType(); RequestKind requestKind = getRequestKind(optionalValueType); return breaksCycle(extractKeyType(optionalValueType), requestKind); } return false; } private boolean breaksCycle(XType requestedType, RequestKind requestKind) { switch (requestKind) { case PROVIDER: case LAZY: case PROVIDER_OF_LAZY: return true; case INSTANCE: if (MapType.isMap(requestedType)) { return MapType.from(requestedType).valuesAreTypeOf(TypeNames.PROVIDER); } // fall through default: return false; } } private DependencyEdge chooseDependencyEdgeConnecting( Node source, Node target, BindingGraph bindingGraph) { return bindingGraph.network().edgesConnecting(source, target).stream() .flatMap(instancesOf(DependencyEdge.class)) .findFirst() .get(); } /** 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 nonCycleBreakingDependencyGraph( BindingGraph bindingGraph) { MutableNetwork 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 endpoints = bindingGraph.network().incidentNodes(edge); dependencyNetwork.addEdge(endpoints.source(), endpoints.target(), edge); }); return ImmutableNetwork.copyOf(dependencyNetwork); } /** * An ordered set of endpoint pairs representing the edges in the cycle. The target of each pair * is the source of the next pair. The target of the last pair is the source of the first pair. */ @AutoValue abstract static class Cycle { /** * The ordered set of endpoint pairs representing the edges in the cycle. The target of each * pair is the source of the next pair. The target of the last pair is the source of the first * pair. */ abstract ImmutableSet> endpointPairs(); /** Returns the nodes that participate in the cycle. */ ImmutableSet nodes() { return endpointPairs().stream() .flatMap(pair -> Stream.of(pair.source(), pair.target())) .collect(toImmutableSet()); } /** Returns the number of edges in the cycle. */ int size() { return endpointPairs().size(); } /** * Shifts this cycle so that it starts with a specific node. * * @return a cycle equivalent to this one but whose first pair starts with {@code startNode} */ Cycle shift(N startNode) { int startIndex = Iterables.indexOf(endpointPairs(), pair -> pair.source().equals(startNode)); checkArgument( startIndex >= 0, "startNode (%s) is not part of this cycle: %s", startNode, this); if (startIndex == 0) { return this; } ImmutableSet.Builder> shifted = ImmutableSet.builder(); shifted.addAll(skip(endpointPairs(), startIndex)); shifted.addAll(limit(endpointPairs(), size() - startIndex)); return new AutoValue_DependencyCycleValidator_Cycle<>(shifted.build()); } @Override public final String toString() { return endpointPairs().toString(); } /** * Creates a {@link Cycle} from a nonempty list of nodes, assuming there is an edge between each * pair of nodes as well as an edge from the last node to the first. */ static Cycle fromPath(List nodes) { checkArgument(!nodes.isEmpty()); ImmutableSet.Builder> cycle = ImmutableSet.builder(); cycle.add(EndpointPair.ordered(getLast(nodes), nodes.get(0))); for (int i = 0; i < nodes.size() - 1; i++) { cycle.add(EndpointPair.ordered(nodes.get(i), nodes.get(i + 1))); } return new AutoValue_DependencyCycleValidator_Cycle<>(cycle.build()); } } }





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