path: root/src/main/java/com/google/devtools/build/lib/actions/ActionCacheChecker.java

// Copyright 2014 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.actions;

import com.google.auto.value.AutoValue;
import com.google.common.base.Preconditions;
import com.google.common.base.Predicate;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.ImmutableMap;
import com.google.common.collect.Iterables;
import com.google.devtools.build.lib.actions.ActionAnalysisMetadata.MiddlemanType;
import com.google.devtools.build.lib.actions.cache.ActionCache;
import com.google.devtools.build.lib.actions.cache.DigestUtils;
import com.google.devtools.build.lib.actions.cache.MetadataHandler;
import com.google.devtools.build.lib.actions.cache.Protos.ActionCacheStatistics.MissReason;
import com.google.devtools.build.lib.events.Event;
import com.google.devtools.build.lib.events.EventHandler;
import com.google.devtools.build.lib.events.EventKind;
import com.google.devtools.build.lib.vfs.Path;
import com.google.devtools.build.lib.vfs.PathFragment;
import java.io.IOException;
import java.util.ArrayList;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import javax.annotation.Nullable;

/**
 * Checks whether an {@link Action} needs to be executed, or whether it has not changed since it was
 * last stored in the action cache. Must be informed of the new Action data after execution as well.
 *
 * <p>The fingerprint, input files names, and metadata (either mtimes or MD5sums) of each action are
 * cached in the action cache to avoid unnecessary rebuilds. Middleman artifacts are handled
 * specially, avoiding the need to create actual files corresponding to the middleman artifacts.
 * Instead of that, results of MiddlemanAction dependency checks are cached internally and then
 * reused whenever an input middleman artifact is encountered.
 *
 * <p>While instances of this class hold references to action and metadata cache instances, they are
 * otherwise lightweight, and should be constructed anew and discarded for each build request.
 */
public class ActionCacheChecker {
  private static final byte[] EMPTY_DIGEST = new byte[0];
  private static final FileArtifactValue CONSTANT_METADATA = new ConstantMetadataValue();

  private final ActionCache actionCache;
  private final ActionKeyContext actionKeyContext;
  private final Predicate<? super Action> executionFilter;
  private final ArtifactResolver artifactResolver;
  private final CacheConfig cacheConfig;

  /** Cache config parameters for ActionCacheChecker. */
  @AutoValue
  public abstract static class CacheConfig {
    abstract boolean enabled();
    // True iff --verbose_explanations flag is set.
    abstract boolean verboseExplanations();

    public static Builder builder() {
      return new AutoValue_ActionCacheChecker_CacheConfig.Builder();
    }

    /** Builder for ActionCacheChecker.CacheConfig. */
    @AutoValue.Builder
    public abstract static class Builder {
      public abstract Builder setVerboseExplanations(boolean value);

      public abstract Builder setEnabled(boolean value);

      public abstract CacheConfig build();
    }
  }

  public ActionCacheChecker(
      ActionCache actionCache,
      ArtifactResolver artifactResolver,
      ActionKeyContext actionKeyContext,
      Predicate<? super Action> executionFilter,
      @Nullable CacheConfig cacheConfig) {
    this.actionCache = actionCache;
    this.executionFilter = executionFilter;
    this.actionKeyContext = actionKeyContext;
    this.artifactResolver = artifactResolver;
    this.cacheConfig =
        cacheConfig != null
            ? cacheConfig
            : CacheConfig.builder().setEnabled(true).setVerboseExplanations(false).build();
  }

  public boolean isActionExecutionProhibited(Action action) {
    return !executionFilter.apply(action);
  }

  /**
   * Checks whether one of existing output paths is already used as a key.
   * If yes, returns it - otherwise uses first output file as a key
   */
  private ActionCache.Entry getCacheEntry(Action action) {
    if (!cacheConfig.enabled()) {
      return null; // ignore existing cache when disabled.
    }
    for (Artifact output : action.getOutputs()) {
      ActionCache.Entry entry = actionCache.get(output.getExecPathString());
      if (entry != null) {
        return entry;
      }
    }
    return null;
  }

  private void removeCacheEntry(Action action) {
    for (Artifact output : action.getOutputs()) {
      actionCache.remove(output.getExecPathString());
    }
  }

  /**
   * Validate metadata state for action input or output artifacts.
   *
   * @param entry cached action information.
   * @param action action to be validated.
   * @param actionInputs the inputs of the action. Normally just the result of action.getInputs(),
   *     but if this action doesn't yet know its inputs, we check the inputs from the cache.
   * @param metadataHandler provider of metadata for the artifacts this action interacts with.
   * @param checkOutput true to validate output artifacts, Otherwise, just validate inputs.
   * @return true if at least one artifact has changed, false - otherwise.
   */
  private boolean validateArtifacts(
      ActionCache.Entry entry,
      Action action,
      Iterable<Artifact> actionInputs,
      MetadataHandler metadataHandler,
      boolean checkOutput) {
    Iterable<Artifact> artifacts = checkOutput
        ? Iterables.concat(action.getOutputs(), actionInputs)
        : actionInputs;
    Map<String, FileArtifactValue> mdMap = new HashMap<>();
    for (Artifact artifact : artifacts) {
      mdMap.put(artifact.getExecPathString(), getMetadataMaybe(metadataHandler, artifact));
    }
    return !DigestUtils.fromMetadata(mdMap).equals(entry.getFileDigest());
  }

  private void reportCommand(EventHandler handler, Action action) {
    if (handler != null) {
      if (cacheConfig.verboseExplanations()) {
        String keyDescription = action.describeKey();
        reportRebuild(handler, action, keyDescription == null
            ? "action command has changed"
            : "action command has changed.\nNew action: " + keyDescription);
      } else {
        reportRebuild(handler, action,
            "action command has changed (try --verbose_explanations for more info)");
      }
    }
  }

  private void reportClientEnv(EventHandler handler, Action action, Map<String, String> used) {
    if (handler != null) {
      if (cacheConfig.verboseExplanations()) {
        StringBuilder message = new StringBuilder();
        message.append("Effective client environment has changed. Now using\n");
        for (Map.Entry<String, String> entry : used.entrySet()) {
          message.append("  ").append(entry.getKey()).append("=").append(entry.getValue())
              .append("\n");
        }
        reportRebuild(handler, action, message.toString());
      } else {
        reportRebuild(
            handler,
            action,
            "Effective client environment has changed (try --verbose_explanations for more info)");
      }
    }
  }

  protected boolean unconditionalExecution(Action action) {
    return !isActionExecutionProhibited(action) && action.executeUnconditionally();
  }

  private static Map<String, String> computeUsedClientEnv(
      Action action, Map<String, String> clientEnv) {
    Map<String, String> used = new HashMap<>();
    for (String var : action.getClientEnvironmentVariables()) {
      String value = clientEnv.get(var);
      if (value != null) {
        used.put(var, value);
      }
    }
    return used;
  }

  /**
   * Checks whether {@code action} needs to be executed and returns a non-null Token if so.
   *
   * <p>The method checks if any of the action's inputs or outputs have changed. Returns a non-null
   * {@link Token} if the action needs to be executed, and null otherwise.
   *
   * <p>If this method returns non-null, indicating that the action will be executed, the
   * metadataHandler's {@link MetadataHandler#discardOutputMetadata} method must be called, so that
   * it does not serve stale metadata for the action's outputs after the action is executed.
   */
  // Note: the handler should only be used for DEPCHECKER events; there's no
  // guarantee it will be available for other events.
  public Token getTokenIfNeedToExecute(
      Action action,
      Iterable<Artifact> resolvedCacheArtifacts,
      Map<String, String> clientEnv,
      EventHandler handler,
      MetadataHandler metadataHandler) {
    // TODO(bazel-team): (2010) For RunfilesAction/SymlinkAction and similar actions that
    // produce only symlinks we should not check whether inputs are valid at all - all that matters
    // that inputs and outputs are still exist (and new inputs have not appeared). All other checks
    // are unnecessary. In other words, the only metadata we should check for them is file existence
    // itself.

    MiddlemanType middlemanType = action.getActionType();
    if (middlemanType.isMiddleman()) {
      // Some types of middlemen are not checked because they should not
      // propagate invalidation of their inputs.
      if (middlemanType != MiddlemanType.ERROR_PROPAGATING_MIDDLEMAN) {
        checkMiddlemanAction(action, handler, metadataHandler);
      }
      return null;
    }
    if (!cacheConfig.enabled()) {
      return new Token(getKeyString(action));
    }
    Iterable<Artifact> actionInputs = action.getInputs();
    // Resolve action inputs from cache, if necessary.
    boolean inputsDiscovered = action.inputsDiscovered();
    if (!inputsDiscovered && resolvedCacheArtifacts != null) {
      // The action doesn't know its inputs, but the caller has a good idea of what they are.
      Preconditions.checkState(action.discoversInputs(),
          "Actions that don't know their inputs must discover them: %s", action);
      actionInputs = resolvedCacheArtifacts;
    }
    ActionCache.Entry entry = getCacheEntry(action);
    if (mustExecute(action, entry, handler, metadataHandler, actionInputs, clientEnv)) {
      if (entry != null) {
        removeCacheEntry(action);
      }
      return new Token(getKeyString(action));
    }

    if (!inputsDiscovered) {
      action.updateInputs(actionInputs);
    }
    return null;
  }

  protected boolean mustExecute(
      Action action,
      @Nullable ActionCache.Entry entry,
      EventHandler handler,
      MetadataHandler metadataHandler,
      Iterable<Artifact> actionInputs,
      Map<String, String> clientEnv) {
    // Unconditional execution can be applied only for actions that are allowed to be executed.
    if (unconditionalExecution(action)) {
      Preconditions.checkState(action.isVolatile());
      reportUnconditionalExecution(handler, action);
      actionCache.accountMiss(MissReason.UNCONDITIONAL_EXECUTION);
      return true;
    }
    if (entry == null) {
      reportNewAction(handler, action);
      actionCache.accountMiss(MissReason.NOT_CACHED);
      return true;
    }

    if (entry.isCorrupted()) {
      reportCorruptedCacheEntry(handler, action);
      actionCache.accountMiss(MissReason.CORRUPTED_CACHE_ENTRY);
      return true;
    } else if (validateArtifacts(entry, action, actionInputs, metadataHandler, true)) {
      reportChanged(handler, action);
      actionCache.accountMiss(MissReason.DIFFERENT_FILES);
      return true;
    } else if (!entry.getActionKey().equals(action.getKey(actionKeyContext))) {
      reportCommand(handler, action);
      actionCache.accountMiss(MissReason.DIFFERENT_ACTION_KEY);
      return true;
    }
    Map<String, String> usedClientEnv = computeUsedClientEnv(action, clientEnv);
    if (!entry.getUsedClientEnvDigest().equals(DigestUtils.fromEnv(usedClientEnv))) {
      reportClientEnv(handler, action, usedClientEnv);
      actionCache.accountMiss(MissReason.DIFFERENT_ENVIRONMENT);
      return true;
    }

    entry.getFileDigest();
    actionCache.accountHit();
    return false;
  }

  private static FileArtifactValue getMetadataOrConstant(
      MetadataHandler metadataHandler, Artifact artifact) throws IOException {
    if (artifact.isConstantMetadata()) {
      return CONSTANT_METADATA;
    } else {
      return metadataHandler.getMetadata(artifact);
    }
  }

  // TODO(ulfjack): It's unclear to me why we're ignoring all IOExceptions. In some cases, we want
  // to trigger a re-execution, so we should catch the IOException explicitly there. In others, we
  // should propagate the exception, because it is unexpected (e.g., bad file system state).
  @Nullable
  private static FileArtifactValue getMetadataMaybe(
      MetadataHandler metadataHandler, Artifact artifact) {
    try {
      return getMetadataOrConstant(metadataHandler, artifact);
    } catch (IOException e) {
      return null;
    }
  }

  public void afterExecution(
      Action action, Token token, MetadataHandler metadataHandler, Map<String, String> clientEnv)
      throws IOException {
    if (!cacheConfig.enabled()) {
      // Action cache is disabled, don't generate digests.
      return;
    }
    Preconditions.checkArgument(token != null);
    String key = token.cacheKey;
    if (actionCache.get(key) != null) {
      // This cache entry has already been updated by a shared action. We don't need to do it again.
      return;
    }
    Map<String, String> usedClientEnv = computeUsedClientEnv(action, clientEnv);
    ActionCache.Entry entry =
        new ActionCache.Entry(
            action.getKey(actionKeyContext), usedClientEnv, action.discoversInputs());
    for (Artifact output : action.getOutputs()) {
      // Remove old records from the cache if they used different key.
      String execPath = output.getExecPathString();
      if (!key.equals(execPath)) {
        actionCache.remove(execPath);
      }
      if (!metadataHandler.artifactOmitted(output)) {
        // Output files *must* exist and be accessible after successful action execution. We use the
        // 'constant' metadata for the volatile workspace status output. The volatile output
        // contains information such as timestamps, and even when --stamp is enabled, we don't want
        // to rebuild everything if only that file changes.
        FileArtifactValue metadata = getMetadataOrConstant(metadataHandler, output);
        Preconditions.checkState(metadata != null);
        entry.addFile(output.getExecPath(), metadata);
      }
    }
    for (Artifact input : action.getInputs()) {
      entry.addFile(input.getExecPath(), getMetadataMaybe(metadataHandler, input));
    }
    entry.getFileDigest();
    actionCache.put(key, entry);
  }

  @Nullable
  public Iterable<Artifact> getCachedInputs(Action action, PackageRootResolver resolver)
      throws InterruptedException {
    ActionCache.Entry entry = getCacheEntry(action);
    if (entry == null || entry.isCorrupted()) {
      return ImmutableList.of();
    }

    List<PathFragment> outputs = new ArrayList<>();
    for (Artifact output : action.getOutputs()) {
      outputs.add(output.getExecPath());
    }
    List<PathFragment> inputExecPaths = new ArrayList<>();
    for (String path : entry.getPaths()) {
      PathFragment execPath = PathFragment.create(path);
      // Code assumes that action has only 1-2 outputs and ArrayList.contains() will be
      // most efficient.
      if (!outputs.contains(execPath)) {
        inputExecPaths.add(execPath);
      }
    }

    // Note that this method may trigger a violation of the desirable invariant that getInputs()
    // is a superset of getMandatoryInputs(). See bug about an "action not in canonical form"
    // error message and the integration test test_crosstool_change_and_failure().
    Map<PathFragment, Artifact> allowedDerivedInputsMap = new HashMap<>();
    for (Artifact derivedInput : action.getAllowedDerivedInputs()) {
      if (!derivedInput.isSourceArtifact()) {
        allowedDerivedInputsMap.put(derivedInput.getExecPath(), derivedInput);
      }
    }

    List<Artifact> inputArtifacts = new ArrayList<>();
    List<PathFragment> unresolvedPaths = new ArrayList<>();
    for (PathFragment execPath : inputExecPaths) {
      Artifact artifact = allowedDerivedInputsMap.get(execPath);
      if (artifact != null) {
        inputArtifacts.add(artifact);
      } else {
        // Remember this execPath, we will try to resolve it as a source artifact.
        unresolvedPaths.add(execPath);
      }
    }

    Map<PathFragment, Artifact> resolvedArtifacts =
        artifactResolver.resolveSourceArtifacts(unresolvedPaths, resolver);
    if (resolvedArtifacts == null) {
      // We are missing some dependencies. We need to rerun this update later.
      return null;
    }

    for (PathFragment execPath : unresolvedPaths) {
      Artifact artifact = resolvedArtifacts.get(execPath);
      // If PathFragment cannot be resolved into the artifact, ignore it. This could happen if the
      // rule has changed and the action no longer depends on, e.g., an additional source file in a
      // separate package and that package is no longer referenced anywhere else. It is safe to
      // ignore such paths because dependency checker would identify changes in inputs (ignored path
      // was used before) and will force action execution.
      if (artifact != null) {
        inputArtifacts.add(artifact);
      }
    }
    return inputArtifacts;
  }

  /**
   * Special handling for the MiddlemanAction. Since MiddlemanAction output artifacts are purely
   * fictional and used only to stay within dependency graph model limitations (action has to depend
   * on artifacts, not on other actions), we do not need to validate metadata for the outputs - only
   * for inputs. We also do not need to validate MiddlemanAction key, since action cache entry key
   * already incorporates that information for the middlemen and we will experience a cache miss
   * when it is different. Whenever it encounters middleman artifacts as input artifacts for other
   * actions, it consults with the aggregated middleman digest computed here.
   */
  protected void checkMiddlemanAction(
      Action action, EventHandler handler, MetadataHandler metadataHandler) {
    if (!cacheConfig.enabled()) {
      // Action cache is disabled, don't generate digests.
      return;
    }
    Artifact middleman = action.getPrimaryOutput();
    String cacheKey = middleman.getExecPathString();
    ActionCache.Entry entry = actionCache.get(cacheKey);
    boolean changed = false;
    if (entry != null) {
      if (entry.isCorrupted()) {
        reportCorruptedCacheEntry(handler, action);
        actionCache.accountMiss(MissReason.CORRUPTED_CACHE_ENTRY);
        changed = true;
      } else if (validateArtifacts(entry, action, action.getInputs(), metadataHandler, false)) {
        reportChanged(handler, action);
        actionCache.accountMiss(MissReason.DIFFERENT_FILES);
        changed = true;
      }
    } else {
      reportChangedDeps(handler, action);
      actionCache.accountMiss(MissReason.DIFFERENT_DEPS);
      changed = true;
    }
    if (changed) {
      // Compute the aggregated middleman digest.
      // Since we never validate action key for middlemen, we should not store
      // it in the cache entry and just use empty string instead.
      entry = new ActionCache.Entry("", ImmutableMap.<String, String>of(), false);
      for (Artifact input : action.getInputs()) {
        entry.addFile(input.getExecPath(), getMetadataMaybe(metadataHandler, input));
      }
    }

    metadataHandler.setDigestForVirtualArtifact(middleman, entry.getFileDigest());
    if (changed) {
      actionCache.put(cacheKey, entry);
    } else {
      actionCache.accountHit();
    }
  }

  /**
   * Returns an action key. It is always set to the first output exec path string.
   */
  private static String getKeyString(Action action) {
    Preconditions.checkState(!action.getOutputs().isEmpty());
    return action.getOutputs().iterator().next().getExecPathString();
  }


  /**
   * In most cases, this method should not be called directly - reportXXX() methods
   * should be used instead. This is done to avoid cost associated with building
   * the message.
   */
  private static void reportRebuild(@Nullable EventHandler handler, Action action, String message) {
    // For MiddlemanAction, do not report rebuild.
    if (handler != null && !action.getActionType().isMiddleman()) {
      handler.handle(Event.of(
          EventKind.DEPCHECKER, null, "Executing " + action.prettyPrint() + ": " + message + "."));
    }
  }

  // Called by IncrementalDependencyChecker.
  protected static void reportUnconditionalExecution(
      @Nullable EventHandler handler, Action action) {
    reportRebuild(handler, action, "unconditional execution is requested");
  }

  private static void reportChanged(@Nullable EventHandler handler, Action action) {
    reportRebuild(handler, action, "One of the files has changed");
  }

  private static void reportChangedDeps(@Nullable EventHandler handler, Action action) {
    reportRebuild(handler, action, "the set of files on which this action depends has changed");
  }

  private static void reportNewAction(@Nullable EventHandler handler, Action action) {
    reportRebuild(handler, action, "no entry in the cache (action is new)");
  }

  private static void reportCorruptedCacheEntry(@Nullable EventHandler handler, Action action) {
    reportRebuild(handler, action, "cache entry is corrupted");
  }

  /** Wrapper for all context needed by the ActionCacheChecker to handle a single action. */
  public static final class Token {
    private final String cacheKey;

    private Token(String cacheKey) {
      this.cacheKey = Preconditions.checkNotNull(cacheKey);
    }
  }

  private static final class ConstantMetadataValue extends FileArtifactValue
      implements FileArtifactValue.Singleton {
    @Override
    public FileStateType getType() {
      return FileStateType.REGULAR_FILE;
    }

    @Override
    public byte[] getDigest() {
      return EMPTY_DIGEST;
    }

    @Override
    public long getSize() {
      return 0;
    }

    @Override
    public long getModifiedTime() {
      return -1;
    }

    @Override
    public boolean wasModifiedSinceDigest(Path path) {
      throw new UnsupportedOperationException(
          "ConstantMetadataValue doesn't support wasModifiedSinceDigest " + path.toString());
    }
  }
}