/* * 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.binding; import static com.google.auto.common.MoreTypes.asTypeElement; import static com.google.common.base.Verify.verify; import static dagger.internal.codegen.binding.BindingRequest.bindingRequest; import static dagger.internal.codegen.extension.DaggerGraphs.unreachableNodes; import static dagger.internal.codegen.extension.DaggerStreams.toImmutableList; import static dagger.model.BindingKind.SUBCOMPONENT_CREATOR; import com.google.auto.value.AutoValue; import com.google.auto.value.extension.memoized.Memoized; import com.google.common.collect.ImmutableList; import com.google.common.collect.ImmutableSet; import com.google.common.collect.Iterables; import com.google.common.collect.Iterators; import com.google.common.graph.ImmutableNetwork; import com.google.common.graph.MutableNetwork; import com.google.common.graph.Network; import com.google.common.graph.NetworkBuilder; import dagger.internal.codegen.binding.BindingGraph.TopLevelBindingGraph; import dagger.internal.codegen.binding.ComponentDescriptor.ComponentMethodDescriptor; import dagger.model.BindingGraph.ComponentNode; import dagger.model.BindingGraph.DependencyEdge; import dagger.model.BindingGraph.Edge; import dagger.model.BindingGraph.MissingBinding; import dagger.model.BindingGraph.Node; import dagger.model.ComponentPath; import dagger.model.DependencyRequest; import dagger.model.Key; import java.util.ArrayDeque; import java.util.Deque; import java.util.HashMap; import java.util.HashSet; import java.util.Map; import java.util.Set; import javax.inject.Inject; import javax.lang.model.element.ExecutableElement; import javax.lang.model.element.TypeElement; import javax.lang.model.type.TypeMirror; /** Converts {@link BindingGraph}s to {@link dagger.model.BindingGraph}s. */ final class BindingGraphConverter { private final BindingDeclarationFormatter bindingDeclarationFormatter; @Inject BindingGraphConverter(BindingDeclarationFormatter bindingDeclarationFormatter) { this.bindingDeclarationFormatter = bindingDeclarationFormatter; } /** * Creates the external {@link dagger.model.BindingGraph} representing the given internal {@link * BindingGraph}. */ BindingGraph convert(LegacyBindingGraph legacyBindingGraph, boolean isFullBindingGraph) { MutableNetwork network = asNetwork(legacyBindingGraph); ComponentNode rootNode = rootComponentNode(network); // When bindings are copied down into child graphs because they transitively depend on local // multibindings or optional bindings, the parent-owned binding is still there. If that // parent-owned binding is not reachable from its component, it doesn't need to be in the graph // because it will never be used. So remove all nodes that are not reachable from the root // component—unless we're converting a full binding graph. if (!isFullBindingGraph) { unreachableNodes(network.asGraph(), rootNode).forEach(network::removeNode); } TopLevelBindingGraph topLevelBindingGraph = TopLevelBindingGraph.create(ImmutableNetwork.copyOf(network), isFullBindingGraph); return BindingGraph.create(rootNode, topLevelBindingGraph); } private MutableNetwork asNetwork(LegacyBindingGraph graph) { Converter converter = new Converter(bindingDeclarationFormatter); converter.visitRootComponent(graph); return converter.network; } // TODO(dpb): Example of BindingGraph logic applied to derived networks. private ComponentNode rootComponentNode(Network network) { return (ComponentNode) Iterables.find( network.nodes(), node -> node instanceof ComponentNode && node.componentPath().atRoot()); } /** * Used as a cache key to make sure resolved bindings are cached per component path. * This is required so that binding nodes are not reused across different branches of the * graph since the ResolvedBindings class only contains the component and not the path. */ @AutoValue abstract static class ResolvedBindingsWithPath { abstract ResolvedBindings resolvedBindings(); abstract ComponentPath componentPath(); static ResolvedBindingsWithPath create( ResolvedBindings resolvedBindings, ComponentPath componentPath) { return new AutoValue_BindingGraphConverter_ResolvedBindingsWithPath( resolvedBindings, componentPath); } } private static final class Converter { /** The path from the root graph to the currently visited graph. */ private final Deque bindingGraphPath = new ArrayDeque<>(); /** The {@link ComponentPath} for each component in {@link #bindingGraphPath}. */ private final Deque componentPaths = new ArrayDeque<>(); private final BindingDeclarationFormatter bindingDeclarationFormatter; private final MutableNetwork network = NetworkBuilder.directed().allowsParallelEdges(true).allowsSelfLoops(true).build(); private final Set bindings = new HashSet<>(); private final Map> resolvedBindingsMap = new HashMap<>(); /** Constructs a converter for a root (component, not subcomponent) binding graph. */ private Converter(BindingDeclarationFormatter bindingDeclarationFormatter) { this.bindingDeclarationFormatter = bindingDeclarationFormatter; } private void visitRootComponent(LegacyBindingGraph graph) { visitComponent(graph, null); } /** * Called once for each component in a component hierarchy. * *

This implementation does the following: * *

    *
  1. If this component is installed in its parent by a subcomponent factory method, calls * {@link #visitSubcomponentFactoryMethod(ComponentNode, ComponentNode, * ExecutableElement)}. *
  2. For each entry point in the component, calls {@link #visitEntryPoint(ComponentNode, * DependencyRequest)}. *
  3. For each child component, calls {@link #visitComponent(LegacyBindingGraph, * ComponentNode)}, updating the traversal state. *
* * @param graph the currently visited graph */ private void visitComponent(LegacyBindingGraph graph, ComponentNode parentComponent) { bindingGraphPath.addLast(graph); ComponentPath graphPath = ComponentPath.create( bindingGraphPath.stream() .map(LegacyBindingGraph::componentDescriptor) .map(ComponentDescriptor::typeElement) .collect(toImmutableList())); componentPaths.addLast(graphPath); ComponentNode currentComponent = ComponentNodeImpl.create(componentPath(), graph.componentDescriptor()); network.addNode(currentComponent); for (ComponentMethodDescriptor entryPointMethod : graph.componentDescriptor().entryPointMethods()) { visitEntryPoint(currentComponent, entryPointMethod.dependencyRequest().get()); } for (ResolvedBindings resolvedBindings : graph.resolvedBindings()) { for (BindingNode binding : bindingNodes(resolvedBindings)) { if (bindings.add(binding)) { network.addNode(binding); for (DependencyRequest dependencyRequest : binding.dependencies()) { addDependencyEdges(binding, dependencyRequest); } } if (binding.kind().equals(SUBCOMPONENT_CREATOR) && binding.componentPath().equals(currentComponent.componentPath())) { network.addEdge( binding, subcomponentNode(binding.key().type(), graph), new SubcomponentCreatorBindingEdgeImpl( resolvedBindings.subcomponentDeclarations())); } } } if (bindingGraphPath.size() > 1) { LegacyBindingGraph parent = Iterators.get(bindingGraphPath.descendingIterator(), 1); parent .componentDescriptor() .getFactoryMethodForChildComponent(graph.componentDescriptor()) .ifPresent( childFactoryMethod -> visitSubcomponentFactoryMethod( parentComponent, currentComponent, childFactoryMethod.methodElement())); } for (LegacyBindingGraph child : graph.subgraphs()) { visitComponent(child, currentComponent); } verify(bindingGraphPath.removeLast().equals(graph)); verify(componentPaths.removeLast().equals(graphPath)); } /** * Called once for each entry point in a component. * * @param componentNode the component that contains the entry point * @param entryPoint the entry point to visit */ private void visitEntryPoint(ComponentNode componentNode, DependencyRequest entryPoint) { addDependencyEdges(componentNode, entryPoint); } /** * Called if this component was installed in its parent by a subcomponent factory method. * * @param parentComponent the parent graph * @param currentComponent the currently visited graph * @param factoryMethod the factory method in the parent component that declares that the * current component is a child */ private void visitSubcomponentFactoryMethod( ComponentNode parentComponent, ComponentNode currentComponent, ExecutableElement factoryMethod) { network.addEdge( parentComponent, currentComponent, new ChildFactoryMethodEdgeImpl(factoryMethod)); } /** * Returns an immutable snapshot of the path from the root component to the currently visited * component. */ private ComponentPath componentPath() { return componentPaths.getLast(); } /** * Returns the subpath from the root component to the matching {@code ancestor} of the current * component. */ private ComponentPath pathFromRootToAncestor(TypeElement ancestor) { for (ComponentPath componentPath : componentPaths) { if (componentPath.currentComponent().equals(ancestor)) { return componentPath; } } throw new IllegalArgumentException( String.format( "%s is not in the current path: %s", ancestor.getQualifiedName(), componentPath())); } /** * Returns the LegacyBindingGraph for {@code ancestor}, where {@code ancestor} is in the * component path of the current traversal. */ private LegacyBindingGraph graphForAncestor(TypeElement ancestor) { for (LegacyBindingGraph graph : bindingGraphPath) { if (graph.componentDescriptor().typeElement().equals(ancestor)) { return graph; } } throw new IllegalArgumentException( String.format( "%s is not in the current path: %s", ancestor.getQualifiedName(), componentPath())); } /** * Adds a {@link dagger.model.BindingGraph.DependencyEdge} from a node to the binding(s) that * satisfy a dependency request. */ private void addDependencyEdges(Node source, DependencyRequest dependencyRequest) { ResolvedBindings dependencies = resolvedDependencies(source, dependencyRequest); if (dependencies.isEmpty()) { addDependencyEdge(source, dependencyRequest, missingBindingNode(dependencies)); } else { for (BindingNode dependency : bindingNodes(dependencies)) { addDependencyEdge(source, dependencyRequest, dependency); } } } private void addDependencyEdge( Node source, DependencyRequest dependencyRequest, Node dependency) { network.addNode(dependency); if (!hasDependencyEdge(source, dependency, dependencyRequest)) { network.addEdge( source, dependency, new DependencyEdgeImpl(dependencyRequest, source instanceof ComponentNode)); } } private boolean hasDependencyEdge( Node source, Node dependency, DependencyRequest dependencyRequest) { // An iterative approach is used instead of a Stream because this method is called in a hot // loop, and the Stream calculates the size of network.edgesConnecting(), which is slow. This // seems to be because caculating the edges connecting two nodes in a Network that supports // parallel edges is must check the equality of many nodes, and BindingNode's equality // semantics drag in the equality of many other expensive objects for (Edge edge : network.edgesConnecting(source, dependency)) { if (edge instanceof DependencyEdge) { if (((DependencyEdge) edge).dependencyRequest().equals(dependencyRequest)) { return true; } } } return false; } private ResolvedBindings resolvedDependencies( Node source, DependencyRequest dependencyRequest) { return graphForAncestor(source.componentPath().currentComponent()) .resolvedBindings(bindingRequest(dependencyRequest)); } private ImmutableSet bindingNodes(ResolvedBindings resolvedBindings) { ResolvedBindingsWithPath resolvedBindingsWithPath = ResolvedBindingsWithPath.create(resolvedBindings, componentPath()); return resolvedBindingsMap.computeIfAbsent( resolvedBindingsWithPath, this::uncachedBindingNodes); } private ImmutableSet uncachedBindingNodes( ResolvedBindingsWithPath resolvedBindingsWithPath) { ImmutableSet.Builder bindingNodes = ImmutableSet.builder(); resolvedBindingsWithPath.resolvedBindings() .allBindings() .asMap() .forEach( (component, bindings) -> { for (Binding binding : bindings) { bindingNodes.add( bindingNode(resolvedBindingsWithPath.resolvedBindings(), binding, component)); } }); return bindingNodes.build(); } private BindingNode bindingNode( ResolvedBindings resolvedBindings, Binding binding, TypeElement owningComponent) { return BindingNode.create( pathFromRootToAncestor(owningComponent), binding, resolvedBindings.multibindingDeclarations(), resolvedBindings.optionalBindingDeclarations(), resolvedBindings.subcomponentDeclarations(), bindingDeclarationFormatter); } private MissingBinding missingBindingNode(ResolvedBindings dependencies) { // Put all missing binding nodes in the root component. This simplifies the binding graph // and produces better error messages for users since all dependents point to the same node. return MissingBindingImpl.create( ComponentPath.create(ImmutableList.of(componentPath().rootComponent())), dependencies.key()); } private ComponentNode subcomponentNode( TypeMirror subcomponentBuilderType, LegacyBindingGraph graph) { TypeElement subcomponentBuilderElement = asTypeElement(subcomponentBuilderType); ComponentDescriptor subcomponent = graph.componentDescriptor().getChildComponentWithBuilderType(subcomponentBuilderElement); return ComponentNodeImpl.create( componentPath().childPath(subcomponent.typeElement()), subcomponent); } } @AutoValue abstract static class MissingBindingImpl extends MissingBinding { static MissingBinding create(ComponentPath component, Key key) { return new AutoValue_BindingGraphConverter_MissingBindingImpl(component, key); } @Memoized @Override public abstract int hashCode(); @Override public abstract boolean equals(Object o); } }