src/main/java/com/google/devtools/build/lib/analysis/AspectCollection.java - bazel - Git at Google

 // Copyright 2017 The Bazel Authors. All rights reserved.
 //
 // 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.devtools.build.lib.analysis;

 import com.google.auto.value.AutoValue;
 import com.google.common.collect.ImmutableList;
 import com.google.common.collect.ImmutableSet;
 import com.google.devtools.build.lib.concurrent.ThreadSafety.Immutable;
 import com.google.devtools.build.lib.packages.Aspect;
 import com.google.devtools.build.lib.packages.AspectDescriptor;
 import com.google.devtools.build.lib.skyframe.AspectKeyCreator;
 import com.google.devtools.build.lib.skyframe.AspectKeyCreator.AspectKey;
 import com.google.devtools.build.lib.skyframe.ConfiguredTargetKey;
 import com.google.errorprone.annotations.CanIgnoreReturnValue;
 import java.util.ArrayList;
 import java.util.HashMap;
 import java.util.LinkedHashMap;
 import java.util.Map;

 /**
  * Represents aspects that should be applied to a configured target as part of {@link Dependency}.
  *
  * <p>One can consider the configured target graph as being a DAG in two dimensions: one is the DAG
  * analogous to the target graph and the other is a DAG between aspects applied to the same
  * configured target. This class represents the latter. The full "aspect dependency graph" is
  * computed when traversing the configured target graph. The analysis of the aspects attached to the
  * same configured target is done by simply unwrapping the graph of {@link AspectDeps} instances.
  *
  * <p>{@link Dependency} encapsulates all information that is needed to analyze an edge between an
  * AspectValue or a ConfiguredTargetValue and their direct dependencies, and {@link
  * AspectCollection} represents an aspect-related part of this information.
  *
  * <p>Analysis arrives to a particular node in target graph with an ordered list of aspects that
  * need to be applied. Some of those aspects should visible to the node in question; some of them
  * are not directly visible, but are visible to other aspects, as specified by {@link
  * com.google.devtools.build.lib.packages.AspectDefinition#getRequiredProvidersForAspects()}.
  *
  * <p>As an example, of all these things in interplay, consider android_binary rule depending on
  * java_proto_library rule depending on proto_library rule; consider further that we analyze the
  * android_binary with some ide_info aspect:
  *
  * <pre>
  *    proto_library(name = "pl") + ide_info_aspect
  *       ^
  *       | [java_proto_aspect]
  *    java_proto_library(name = "jpl") + ide_info_aspect
  *       ^
  *       | [DexArchiveAspect]
  *    android_binary(name = "ab") + ide_info_aspect
  * </pre>
  *
  * ide_info_aspect is interested in java_proto_aspect, but not in DexArchiveAspect.
  *
  * <p>Let's look is the {@link AspectCollection} for a Dependency representing a jpl->pl edge for
  * ide_info_aspect application to target <code>jpl</code>:
  *
  * <ul>
  *   <li>the full list of aspects is [java_proto_aspect, DexArchiveAspect, ide_info_aspect] in this
  *       order (the order is determined by the order in which aspects originate on {@code
  *       ab->...->pl} path).
  *   <li>however, DexArchiveAspect is not visible to either ide_info_aspect or java_proto_aspect, so
  *       the reduced list(and a result of {@link #getUsedAspects()} ) will be [java_proto_aspect,
  *       ide_info_aspect]
  *   <li>both java_proto_aspect and ide_info_aspect will be visible to <code>jpl + ide_info_aspect
  *       </code> node: the former because java_proto_library originates java_proto_aspect, and the
  *       aspect applied to the node sees the same dependencies; and the latter because the aspect
  *       sees itself on all targets it propagates to. So {@link #getUsedAspects()} will return both
  *       of them.
  *   <li>Since ide_info_aspect declared its interest in java_proto_aspect and the latter comes
  *       before it in the order, {@link AspectDeps} for ide_info_aspect will contain
  *       java_proto_aspect (so the application of ide_info_aspect to <code>pl</code> target will see
  *       java_proto_aspect as well).
  * </ul>
  *
  * More details on members of {@link AspectCollection} follow, as well as more examples of aspect
  * visibility rules.
  *
  * <p>{@link AspectDeps} is a class that represents an aspect and all aspects that are directly
  * visible to it.
  *
  * <p>{@link #getUsedAspects()} return all aspects that should be applied to the target, in
  * topological order.
  *
  * <p>In the following scenario, consider rule r<sub>i</sub> sending an aspect a<sub>i</sub> to its
  * dependency:
  *
  * <pre>
  *      [r0]
  *       ^
  *  (a1) |
  *      [r1]
  *  (a2) |
  *      [r2]
  *  (a3) |
  *      [r3]
  * </pre>
  *
  * When a3 is propagated to target r0, the analysis arrives there with a path [a1, a2, a3]. Since we
  * analyse the propagation of aspect a3, the only visible aspect is a3.
  *
  * <p>Let's first assume that aspect a3 wants to see aspects a1 and a2, but aspects a1 and a2 are
  * not interested in each other (according to their {@link
  * com.google.devtools.build.lib.packages.AspectDefinition#getRequiredProvidersForAspects()}).
  *
  * <p>Since a3 is interested in all aspects, the result of {@link #getUsedAspects()} will be [a1,
  * a2, a3], and {@link AspectCollection} will be:
  *
  * <ul>
  *   <li>a3 -> [a1, a2]
  *   <li>a2 -> []
  *   <li>a1 -> []
  * </ul>
  *
  * <p>Now what happens if a3 is interested in a2 but not a1, and a2 is interested in a1? Again, all
  * aspects are transitively interesting to a visible a3, so {@link #getUsedAspects()} will be [a1,
  * a2, a3], but {@link AspectCollection} will now be:
  *
  * <ul>
  *   <li>a3 -> [a2]
  *   <li>a2 -> [a1]
  *   <li>a1 -> []
  * </ul>
  *
  * <p>As a final example, what happens if a3 is interested in a1, and a1 is interested in a2, but a3
  * is not interested in a2? Now the result of {@link #getUsedAspects()} will be [a1, a3]. a1 is
  * interested in a2, but a2 comes later in the path than a1, so a1 does not see it (a1 only started
  * propagating on r1 -> r0 edge, and there is now a2 originating on that path). And {@link
  * AspectCollection} will now be:
  *
  * <ul>
  *   <li>a3 -> [a1]
  *   <li>a1 -> []
  * </ul>
  *
  * Note that is does not matter if a2 is interested in a1 or not - since no one after it in the path
  * is interested in it, a2 is filtered out.
  */
 @Immutable
 public final class AspectCollection {
   /** aspects that should be visible to a dependency */
   private final ImmutableSet<AspectDeps> usedAspects;

   public static final AspectCollection EMPTY = new AspectCollection(ImmutableSet.<AspectDeps>of());

   private AspectCollection(ImmutableSet<AspectDeps> usedAspects) {
     this.usedAspects = usedAspects;
   }

   public ImmutableSet<AspectDeps> getUsedAspects() {
     return usedAspects;
   }

   public boolean isEmpty() {
     return usedAspects.isEmpty();
   }

   @Override
   public String toString() {
     return "AspectCollection{" + usedAspects + "}";
   }

   @Override
   public int hashCode() {
     return usedAspects.hashCode();
   }

   @Override
   public boolean equals(Object obj) {
     if (!(obj instanceof AspectCollection that)) {
       return false;
     }
     return this.usedAspects.equals(that.usedAspects);
   }

   /**
    * Represents an aspect with all the aspects it depends on (within an {@link AspectCollection}.
    *
    * <p>We preserve the order of aspects to correspond to the order originally specified in the call
    * to {@link AspectCollection#create}, although that is not strictly needed semantically.
    *
    * <p>This data structure cannot be a simple list. Consider the case when four aspects [a1, a2,
    * a3, a4] are attached and a4 is interested in a3, a3 in a2 and a2 in a1.
    *
    * <p>In this case, when analyzing a3, only a2 will be in its direct dependencies (since we don't
    * want to merge in the dependencies of a1), but then a2 would have no way of knowing that a1 was
    * also propagated.
    *
    * <p>(a list of (dependent aspect, visible) pairs would work, though and the code would probably
    * be somewhat simpler)
    */
   @AutoValue
   public abstract static class AspectDeps {
     public abstract AspectDescriptor getAspect();

     public abstract ImmutableList<AspectDeps> getUsedAspects();

     private static AspectDeps create(
         AspectDescriptor aspect, ImmutableList<AspectDeps> usedAspects) {
       return new AutoValue_AspectCollection_AspectDeps(aspect, usedAspects);
     }
   }

   /**
    * Creates an {@link AspectKey} for the given root aspect, {@code aspectDeps}.
    *
    * <p>Converts the DAG of {@link AspectDescriptor}s rooted at {@code aspectDeps} into an
    * isomorphic DAG of {@link AspectKey} with corresponding {@link AspectKey#getAspectDescriptor}
    * values. All resulting {@link AspectKey}s have {@link AspectKey#getBaseConfiguredTargetKey}
    * equal to {@code baseKey}.
    *
    * <p>As a side effect, {@code visited} is populated with all the DAG nodes with each map entry
    * value's descriptor matching the map entry key.
    */
   @CanIgnoreReturnValue
   public static AspectKey buildAspectKey(
       AspectDeps aspectDeps,
       Map<AspectDescriptor, AspectKey> visited,
       ConfiguredTargetKey baseKey) {
     AspectDescriptor aspect = aspectDeps.getAspect();
     AspectKey aspectKey = visited.get(aspect);
     if (aspectKey != null) {
       return aspectKey;
     }

     ImmutableList<AspectDeps> usedAspects = aspectDeps.getUsedAspects();
     var usedAspectKeys = ImmutableList.<AspectKey>builderWithExpectedSize(usedAspects.size());
     for (AspectCollection.AspectDeps usedAspect : usedAspects) {
       usedAspectKeys.add(buildAspectKey(usedAspect, visited, baseKey));
     }

     aspectKey = AspectKeyCreator.createAspectKey(aspect, usedAspectKeys.build(), baseKey);
     visited.put(aspect, aspectKey);
     return aspectKey;
   }

   public static AspectCollection createForTests(AspectDescriptor... descriptors) {
     return createForTests(ImmutableSet.copyOf(descriptors));
   }

   public static AspectCollection createForTests(ImmutableSet<AspectDescriptor> descriptors) {
     ImmutableSet.Builder<AspectDeps> depsBuilder = ImmutableSet.builder();
     for (AspectDescriptor descriptor : descriptors) {
       depsBuilder.add(AspectDeps.create(descriptor, ImmutableList.<AspectDeps>of()));
     }
     return new AspectCollection(depsBuilder.build());
   }

   /**
    * Creates an {@link AspectCollection} from an ordered list of aspects and a set of visible
    * aspects.
    *
    * <p>The order of aspects is reverse to the order in which they originated, with the earliest
    * originating occurring last in the list.
    */
   public static AspectCollection create(Iterable<Aspect> aspectPath)
       throws AspectCycleOnPathException {
     LinkedHashMap<AspectDescriptor, Aspect> aspectMap = deduplicateAspects(aspectPath);
     LinkedHashMap<AspectDescriptor, ArrayList<AspectDescriptor>> deps =
         new LinkedHashMap<>();

     // Calculate all needed aspects. Already discovered aspects are in key set of deps.
     // 1) Start from the end of the path. The aspect only sees other aspects that are
     //    before it
     // 2) Otherwise, check whether 'aspect' is visible to or required by any already seen aspects.
     // If it is visible to 'depAspect' or explicitly required by it, add the 'aspect' to a list of
     // aspects visible to 'depAspect'.
     // At the end of this algorithm, key set of 'deps' contains the original aspect list in reverse
     // (since we iterate the original list in reverse).
     //
     // deps[aspect] contains all aspects that 'aspect' needs, in reverse order.
     for (Map.Entry<AspectDescriptor, Aspect> aspect :
         ImmutableList.copyOf(aspectMap.entrySet()).reverse()) {
       for (AspectDescriptor depAspectDescriptor : deps.keySet()) {
         Aspect depAspect = aspectMap.get(depAspectDescriptor);
         if (depAspect
                 .getDefinition()
                 .getRequiredProvidersForAspects()
                 .isSatisfiedBy(aspect.getValue().getDefinition().getAdvertisedProviders())
             || depAspect.getDefinition().requires(aspect.getValue())) {
           deps.get(depAspectDescriptor).add(aspect.getKey());
         }
       }

       deps.put(aspect.getKey(), new ArrayList<>());
     }

     // Calculate the path for every directly required aspect
     HashMap<AspectDescriptor, AspectDeps> aspectPaths = new HashMap<>();
     ImmutableSet.Builder<AspectDeps> result = ImmutableSet.builder();
     for (AspectDescriptor aspect : aspectMap.keySet()) {
       result.add(buildAspectDeps(aspect, aspectPaths, deps));
     }
     return new AspectCollection(result.build());
   }

   /**
    * Deduplicate aspects in path.
    *
    * @throws AspectCycleOnPathException if an aspect occurs twice on the path and
    *         the second occurrence sees a different set of aspects.
    */
   private static LinkedHashMap<AspectDescriptor, Aspect> deduplicateAspects(
       Iterable<Aspect> aspectPath) throws AspectCycleOnPathException {

     LinkedHashMap<AspectDescriptor, Aspect> aspectMap = new LinkedHashMap<>();
     ArrayList<Aspect> seenAspects = new ArrayList<>();
     for (Aspect aspect : aspectPath) {
       if (!aspectMap.containsKey(aspect.getDescriptor())) {
         aspectMap.put(aspect.getDescriptor(), aspect);
         seenAspects.add(aspect);
       } else {
         validateDuplicateAspect(aspect, seenAspects);
       }
     }
     return aspectMap;
   }

   /**
    * Detect inconsistent duplicate occurrence of an aspect on the path. There is a previous
    * occurrence of {@code aspect} in {@code seenAspects}.
    *
    * <p>If in between that previous occurrence and the newly discovered occurrence there is an
    * aspect that is visible to or required by {@code aspect}, then the second occurrence is
    * inconsistent - the set of aspects it sees is different from the first one.
    */
   private static void validateDuplicateAspect(Aspect aspect, ArrayList<Aspect> seenAspects)
       throws AspectCycleOnPathException {
     for (int i = seenAspects.size() - 1; i >= 0; i--) {
       Aspect seenAspect = seenAspects.get(i);
       if (aspect.getDescriptor().equals(seenAspect.getDescriptor())) {
         // This is a previous occurrence of the same aspect.
         return;
       }

       if (aspect
               .getDefinition()
               .getRequiredProvidersForAspects()
               .isSatisfiedBy(seenAspect.getDefinition().getAdvertisedProviders())
           || aspect.getDefinition().requires(seenAspect)) {
         throw new AspectCycleOnPathException(aspect.getDescriptor(), seenAspect.getDescriptor());
       }
     }
   }

   private static AspectDeps buildAspectDeps(AspectDescriptor descriptor,
       HashMap<AspectDescriptor, AspectDeps> aspectPaths,
       LinkedHashMap<AspectDescriptor, ArrayList<AspectDescriptor>> deps) {
     if (aspectPaths.containsKey(descriptor)) {
       return aspectPaths.get(descriptor);
     }

     ImmutableList.Builder<AspectDeps> aspectPathBuilder = ImmutableList.builder();
     ArrayList<AspectDescriptor> depList = deps.get(descriptor);

     // deps[aspect] contains all aspects visible to 'aspect' in reverse order.
     for (int i = depList.size() - 1; i >= 0; i--) {
       aspectPathBuilder.add(buildAspectDeps(depList.get(i), aspectPaths, deps));
     }
     AspectDeps aspectPath = AspectDeps.create(descriptor, aspectPathBuilder.build());
     aspectPaths.put(descriptor, aspectPath);
     return aspectPath;
   }

   /**
    * Signals an inconsistency on aspect path: an aspect occurs twice on the path and the second
    * occurrence sees a different set of aspects.
    *
    * <p>{@link #getAspect()} is the aspect occurring twice, and {@link #getPreviousAspect()} is the
    * aspect that the second occurrence sees but the first does not.
    */
   public static class AspectCycleOnPathException extends Exception {

     private final AspectDescriptor aspect;
     private final AspectDescriptor previousAspect;

     public AspectCycleOnPathException(AspectDescriptor aspect, AspectDescriptor previousAspect) {
       super(String.format("Aspect %s is applied twice, both before and after aspect %s",
           aspect.getDescription(), previousAspect.getDescription()
       ));
       this.aspect = aspect;
       this.previousAspect = previousAspect;
     }

     public AspectDescriptor getAspect() {
       return aspect;
     }

     public AspectDescriptor getPreviousAspect() {
       return previousAspect;
     }
   }
 }
	// Copyright 2017 The Bazel Authors. All rights reserved.
	//
	// 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.devtools.build.lib.analysis;

	import com.google.auto.value.AutoValue;
	import com.google.common.collect.ImmutableList;
	import com.google.common.collect.ImmutableSet;
	import com.google.devtools.build.lib.concurrent.ThreadSafety.Immutable;
	import com.google.devtools.build.lib.packages.Aspect;
	import com.google.devtools.build.lib.packages.AspectDescriptor;
	import com.google.devtools.build.lib.skyframe.AspectKeyCreator;
	import com.google.devtools.build.lib.skyframe.AspectKeyCreator.AspectKey;
	import com.google.devtools.build.lib.skyframe.ConfiguredTargetKey;
	import com.google.errorprone.annotations.CanIgnoreReturnValue;
	import java.util.ArrayList;
	import java.util.HashMap;
	import java.util.LinkedHashMap;
	import java.util.Map;

	/**
	* Represents aspects that should be applied to a configured target as part of {@link Dependency}.
	*
	* <p>One can consider the configured target graph as being a DAG in two dimensions: one is the DAG
	* analogous to the target graph and the other is a DAG between aspects applied to the same
	* configured target. This class represents the latter. The full "aspect dependency graph" is
	* computed when traversing the configured target graph. The analysis of the aspects attached to the
	* same configured target is done by simply unwrapping the graph of {@link AspectDeps} instances.
	*
	* <p>{@link Dependency} encapsulates all information that is needed to analyze an edge between an
	* AspectValue or a ConfiguredTargetValue and their direct dependencies, and {@link
	* AspectCollection} represents an aspect-related part of this information.
	*
	* <p>Analysis arrives to a particular node in target graph with an ordered list of aspects that
	* need to be applied. Some of those aspects should visible to the node in question; some of them
	* are not directly visible, but are visible to other aspects, as specified by {@link
	* com.google.devtools.build.lib.packages.AspectDefinition#getRequiredProvidersForAspects()}.
	*
	* <p>As an example, of all these things in interplay, consider android_binary rule depending on
	* java_proto_library rule depending on proto_library rule; consider further that we analyze the
	* android_binary with some ide_info aspect:
	*
	* <pre>
	* proto_library(name = "pl") + ide_info_aspect
	* ^
	* \| [java_proto_aspect]
	* java_proto_library(name = "jpl") + ide_info_aspect
	* ^
	* \| [DexArchiveAspect]
	* android_binary(name = "ab") + ide_info_aspect
	* </pre>
	*
	* ide_info_aspect is interested in java_proto_aspect, but not in DexArchiveAspect.
	*
	* <p>Let's look is the {@link AspectCollection} for a Dependency representing a jpl->pl edge for
	* ide_info_aspect application to target <code>jpl</code>:
	*
	* <ul>
	* <li>the full list of aspects is [java_proto_aspect, DexArchiveAspect, ide_info_aspect] in this
	* order (the order is determined by the order in which aspects originate on {@code
	* ab->...->pl} path).
	* <li>however, DexArchiveAspect is not visible to either ide_info_aspect or java_proto_aspect, so
	* the reduced list(and a result of {@link #getUsedAspects()} ) will be [java_proto_aspect,
	* ide_info_aspect]
	* <li>both java_proto_aspect and ide_info_aspect will be visible to <code>jpl + ide_info_aspect
	* </code> node: the former because java_proto_library originates java_proto_aspect, and the
	* aspect applied to the node sees the same dependencies; and the latter because the aspect
	* sees itself on all targets it propagates to. So {@link #getUsedAspects()} will return both
	* of them.
	* <li>Since ide_info_aspect declared its interest in java_proto_aspect and the latter comes
	* before it in the order, {@link AspectDeps} for ide_info_aspect will contain
	* java_proto_aspect (so the application of ide_info_aspect to <code>pl</code> target will see
	* java_proto_aspect as well).
	* </ul>
	*
	* More details on members of {@link AspectCollection} follow, as well as more examples of aspect
	* visibility rules.
	*
	* <p>{@link AspectDeps} is a class that represents an aspect and all aspects that are directly
	* visible to it.
	*
	* <p>{@link #getUsedAspects()} return all aspects that should be applied to the target, in
	* topological order.
	*
	* <p>In the following scenario, consider rule r<sub>i</sub> sending an aspect a<sub>i</sub> to its
	* dependency:
	*
	* <pre>
	* [r0]
	* ^
	* (a1) \|
	* [r1]
	* (a2) \|
	* [r2]
	* (a3) \|
	* [r3]
	* </pre>
	*
	* When a3 is propagated to target r0, the analysis arrives there with a path [a1, a2, a3]. Since we
	* analyse the propagation of aspect a3, the only visible aspect is a3.
	*
	* <p>Let's first assume that aspect a3 wants to see aspects a1 and a2, but aspects a1 and a2 are
	* not interested in each other (according to their {@link
	* com.google.devtools.build.lib.packages.AspectDefinition#getRequiredProvidersForAspects()}).
	*
	* <p>Since a3 is interested in all aspects, the result of {@link #getUsedAspects()} will be [a1,
	* a2, a3], and {@link AspectCollection} will be:
	*
	* <ul>
	* <li>a3 -> [a1, a2]
	* <li>a2 -> []
	* <li>a1 -> []
	* </ul>
	*
	* <p>Now what happens if a3 is interested in a2 but not a1, and a2 is interested in a1? Again, all
	* aspects are transitively interesting to a visible a3, so {@link #getUsedAspects()} will be [a1,
	* a2, a3], but {@link AspectCollection} will now be:
	*
	* <ul>
	* <li>a3 -> [a2]
	* <li>a2 -> [a1]
	* <li>a1 -> []
	* </ul>
	*
	* <p>As a final example, what happens if a3 is interested in a1, and a1 is interested in a2, but a3
	* is not interested in a2? Now the result of {@link #getUsedAspects()} will be [a1, a3]. a1 is
	* interested in a2, but a2 comes later in the path than a1, so a1 does not see it (a1 only started
	* propagating on r1 -> r0 edge, and there is now a2 originating on that path). And {@link
	* AspectCollection} will now be:
	*
	* <ul>
	* <li>a3 -> [a1]
	* <li>a1 -> []
	* </ul>
	*
	* Note that is does not matter if a2 is interested in a1 or not - since no one after it in the path
	* is interested in it, a2 is filtered out.
	*/
	@Immutable
	public final class AspectCollection {
	/** aspects that should be visible to a dependency */
	private final ImmutableSet<AspectDeps> usedAspects;

	public static final AspectCollection EMPTY = new AspectCollection(ImmutableSet.<AspectDeps>of());

	private AspectCollection(ImmutableSet<AspectDeps> usedAspects) {
	this.usedAspects = usedAspects;
	}

	public ImmutableSet<AspectDeps> getUsedAspects() {
	return usedAspects;
	}

	public boolean isEmpty() {
	return usedAspects.isEmpty();
	}

	@Override
	public String toString() {
	return "AspectCollection{" + usedAspects + "}";
	}

	@Override
	public int hashCode() {
	return usedAspects.hashCode();
	}

	@Override
	public boolean equals(Object obj) {
	if (!(obj instanceof AspectCollection that)) {
	return false;
	}
	return this.usedAspects.equals(that.usedAspects);
	}

	/**
	* Represents an aspect with all the aspects it depends on (within an {@link AspectCollection}.
	*
	* <p>We preserve the order of aspects to correspond to the order originally specified in the call
	* to {@link AspectCollection#create}, although that is not strictly needed semantically.
	*
	* <p>This data structure cannot be a simple list. Consider the case when four aspects [a1, a2,
	* a3, a4] are attached and a4 is interested in a3, a3 in a2 and a2 in a1.
	*
	* <p>In this case, when analyzing a3, only a2 will be in its direct dependencies (since we don't
	* want to merge in the dependencies of a1), but then a2 would have no way of knowing that a1 was
	* also propagated.
	*
	* <p>(a list of (dependent aspect, visible) pairs would work, though and the code would probably
	* be somewhat simpler)
	*/
	@AutoValue
	public abstract static class AspectDeps {
	public abstract AspectDescriptor getAspect();

	public abstract ImmutableList<AspectDeps> getUsedAspects();

	private static AspectDeps create(
	AspectDescriptor aspect, ImmutableList<AspectDeps> usedAspects) {
	return new AutoValue_AspectCollection_AspectDeps(aspect, usedAspects);
	}
	}

	/**
	* Creates an {@link AspectKey} for the given root aspect, {@code aspectDeps}.
	*
	* <p>Converts the DAG of {@link AspectDescriptor}s rooted at {@code aspectDeps} into an
	* isomorphic DAG of {@link AspectKey} with corresponding {@link AspectKey#getAspectDescriptor}
	* values. All resulting {@link AspectKey}s have {@link AspectKey#getBaseConfiguredTargetKey}
	* equal to {@code baseKey}.
	*
	* <p>As a side effect, {@code visited} is populated with all the DAG nodes with each map entry
	* value's descriptor matching the map entry key.
	*/
	@CanIgnoreReturnValue
	public static AspectKey buildAspectKey(
	AspectDeps aspectDeps,
	Map<AspectDescriptor, AspectKey> visited,
	ConfiguredTargetKey baseKey) {
	AspectDescriptor aspect = aspectDeps.getAspect();
	AspectKey aspectKey = visited.get(aspect);
	if (aspectKey != null) {
	return aspectKey;
	}

	ImmutableList<AspectDeps> usedAspects = aspectDeps.getUsedAspects();
	var usedAspectKeys = ImmutableList.<AspectKey>builderWithExpectedSize(usedAspects.size());
	for (AspectCollection.AspectDeps usedAspect : usedAspects) {
	usedAspectKeys.add(buildAspectKey(usedAspect, visited, baseKey));
	}

	aspectKey = AspectKeyCreator.createAspectKey(aspect, usedAspectKeys.build(), baseKey);
	visited.put(aspect, aspectKey);
	return aspectKey;
	}

	public static AspectCollection createForTests(AspectDescriptor... descriptors) {
	return createForTests(ImmutableSet.copyOf(descriptors));
	}

	public static AspectCollection createForTests(ImmutableSet<AspectDescriptor> descriptors) {
	ImmutableSet.Builder<AspectDeps> depsBuilder = ImmutableSet.builder();
	for (AspectDescriptor descriptor : descriptors) {
	depsBuilder.add(AspectDeps.create(descriptor, ImmutableList.<AspectDeps>of()));
	}
	return new AspectCollection(depsBuilder.build());
	}

	/**
	* Creates an {@link AspectCollection} from an ordered list of aspects and a set of visible
	* aspects.
	*
	* <p>The order of aspects is reverse to the order in which they originated, with the earliest
	* originating occurring last in the list.
	*/
	public static AspectCollection create(Iterable<Aspect> aspectPath)
	throws AspectCycleOnPathException {
	LinkedHashMap<AspectDescriptor, Aspect> aspectMap = deduplicateAspects(aspectPath);
	LinkedHashMap<AspectDescriptor, ArrayList<AspectDescriptor>> deps =
	new LinkedHashMap<>();

	// Calculate all needed aspects. Already discovered aspects are in key set of deps.
	// 1) Start from the end of the path. The aspect only sees other aspects that are
	// before it
	// 2) Otherwise, check whether 'aspect' is visible to or required by any already seen aspects.
	// If it is visible to 'depAspect' or explicitly required by it, add the 'aspect' to a list of
	// aspects visible to 'depAspect'.
	// At the end of this algorithm, key set of 'deps' contains the original aspect list in reverse
	// (since we iterate the original list in reverse).
	//
	// deps[aspect] contains all aspects that 'aspect' needs, in reverse order.
	for (Map.Entry<AspectDescriptor, Aspect> aspect :
	ImmutableList.copyOf(aspectMap.entrySet()).reverse()) {
	for (AspectDescriptor depAspectDescriptor : deps.keySet()) {
	Aspect depAspect = aspectMap.get(depAspectDescriptor);
	if (depAspect
	.getDefinition()
	.getRequiredProvidersForAspects()
	.isSatisfiedBy(aspect.getValue().getDefinition().getAdvertisedProviders())
	\|\| depAspect.getDefinition().requires(aspect.getValue())) {
	deps.get(depAspectDescriptor).add(aspect.getKey());
	}
	}

	deps.put(aspect.getKey(), new ArrayList<>());
	}

	// Calculate the path for every directly required aspect
	HashMap<AspectDescriptor, AspectDeps> aspectPaths = new HashMap<>();
	ImmutableSet.Builder<AspectDeps> result = ImmutableSet.builder();
	for (AspectDescriptor aspect : aspectMap.keySet()) {
	result.add(buildAspectDeps(aspect, aspectPaths, deps));
	}
	return new AspectCollection(result.build());
	}

	/**
	* Deduplicate aspects in path.
	*
	* @throws AspectCycleOnPathException if an aspect occurs twice on the path and
	* the second occurrence sees a different set of aspects.
	*/
	private static LinkedHashMap<AspectDescriptor, Aspect> deduplicateAspects(
	Iterable<Aspect> aspectPath) throws AspectCycleOnPathException {

	LinkedHashMap<AspectDescriptor, Aspect> aspectMap = new LinkedHashMap<>();
	ArrayList<Aspect> seenAspects = new ArrayList<>();
	for (Aspect aspect : aspectPath) {
	if (!aspectMap.containsKey(aspect.getDescriptor())) {
	aspectMap.put(aspect.getDescriptor(), aspect);
	seenAspects.add(aspect);
	} else {
	validateDuplicateAspect(aspect, seenAspects);
	}
	}
	return aspectMap;
	}

	/**
	* Detect inconsistent duplicate occurrence of an aspect on the path. There is a previous
	* occurrence of {@code aspect} in {@code seenAspects}.
	*
	* <p>If in between that previous occurrence and the newly discovered occurrence there is an
	* aspect that is visible to or required by {@code aspect}, then the second occurrence is
	* inconsistent - the set of aspects it sees is different from the first one.
	*/
	private static void validateDuplicateAspect(Aspect aspect, ArrayList<Aspect> seenAspects)
	throws AspectCycleOnPathException {
	for (int i = seenAspects.size() - 1; i >= 0; i--) {
	Aspect seenAspect = seenAspects.get(i);
	if (aspect.getDescriptor().equals(seenAspect.getDescriptor())) {
	// This is a previous occurrence of the same aspect.
	return;
	}

	if (aspect
	.getDefinition()
	.getRequiredProvidersForAspects()
	.isSatisfiedBy(seenAspect.getDefinition().getAdvertisedProviders())
	\|\| aspect.getDefinition().requires(seenAspect)) {
	throw new AspectCycleOnPathException(aspect.getDescriptor(), seenAspect.getDescriptor());
	}
	}
	}

	private static AspectDeps buildAspectDeps(AspectDescriptor descriptor,
	HashMap<AspectDescriptor, AspectDeps> aspectPaths,
	LinkedHashMap<AspectDescriptor, ArrayList<AspectDescriptor>> deps) {
	if (aspectPaths.containsKey(descriptor)) {
	return aspectPaths.get(descriptor);
	}

	ImmutableList.Builder<AspectDeps> aspectPathBuilder = ImmutableList.builder();
	ArrayList<AspectDescriptor> depList = deps.get(descriptor);

	// deps[aspect] contains all aspects visible to 'aspect' in reverse order.
	for (int i = depList.size() - 1; i >= 0; i--) {
	aspectPathBuilder.add(buildAspectDeps(depList.get(i), aspectPaths, deps));
	}
	AspectDeps aspectPath = AspectDeps.create(descriptor, aspectPathBuilder.build());
	aspectPaths.put(descriptor, aspectPath);
	return aspectPath;
	}

	/**
	* Signals an inconsistency on aspect path: an aspect occurs twice on the path and the second
	* occurrence sees a different set of aspects.
	*
	* <p>{@link #getAspect()} is the aspect occurring twice, and {@link #getPreviousAspect()} is the
	* aspect that the second occurrence sees but the first does not.
	*/
	public static class AspectCycleOnPathException extends Exception {

	private final AspectDescriptor aspect;
	private final AspectDescriptor previousAspect;

	public AspectCycleOnPathException(AspectDescriptor aspect, AspectDescriptor previousAspect) {
	super(String.format("Aspect %s is applied twice, both before and after aspect %s",
	aspect.getDescription(), previousAspect.getDescription()
	));
	this.aspect = aspect;
	this.previousAspect = previousAspect;
	}

	public AspectDescriptor getAspect() {
	return aspect;
	}

	public AspectDescriptor getPreviousAspect() {
	return previousAspect;
	}
	}
	}