src/main/java/com/google/devtools/build/lib/skyframe/FilesetEntryFunction.java - bazel - Git at Google

 // Copyright 2015 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.skyframe;

 import com.google.common.base.Function;
 import com.google.common.base.Preconditions;
 import com.google.common.base.Predicate;
 import com.google.common.collect.ImmutableList;
 import com.google.common.collect.ImmutableSet;
 import com.google.common.collect.Iterables;
 import com.google.common.collect.Sets;
 import com.google.devtools.build.lib.actions.FilesetOutputSymlink;
 import com.google.devtools.build.lib.actions.FilesetTraversalParams;
 import com.google.devtools.build.lib.actions.FilesetTraversalParams.DirectTraversal;
 import com.google.devtools.build.lib.skyframe.RecursiveFilesystemTraversalFunction.DanglingSymlinkException;
 import com.google.devtools.build.lib.skyframe.RecursiveFilesystemTraversalFunction.RecursiveFilesystemTraversalException;
 import com.google.devtools.build.lib.skyframe.RecursiveFilesystemTraversalValue.ResolvedFile;
 import com.google.devtools.build.lib.vfs.PathFragment;
 import com.google.devtools.build.skyframe.SkyFunction;
 import com.google.devtools.build.skyframe.SkyFunctionException;
 import com.google.devtools.build.skyframe.SkyKey;
 import com.google.devtools.build.skyframe.SkyValue;
 import java.util.LinkedHashMap;
 import java.util.Map;
 import java.util.Map.Entry;
 import java.util.Set;
 import java.util.TreeMap;

 /** SkyFunction for {@link FilesetEntryValue}. */
 public final class FilesetEntryFunction implements SkyFunction {

   private static final class MissingDepException extends Exception {}

   private static final class FilesetEntryFunctionException extends SkyFunctionException {
     FilesetEntryFunctionException(RecursiveFilesystemTraversalException e) {
       super(e, Transience.PERSISTENT);
     }
   }

   @Override
   public SkyValue compute(SkyKey key, Environment env)
       throws FilesetEntryFunctionException, InterruptedException {
     FilesetTraversalParams t = (FilesetTraversalParams) key.argument();
     if (t.getDirectTraversal().isPresent()) {
       Preconditions.checkState(
           t.getNestedTraversal().isEmpty(),
           "NestedTraversal must be empty if directTraversal is present: %s", t);
     }

     // Create the set of excluded files. Only top-level files can be excluded, i.e. ones that are
     // directly under the root if the root is a directory.
     Set<String> exclusions = createExclusionSet(t.getExcludedFiles());

     // The map of output symlinks. Each key is the path of a output symlink that the Fileset must
     // create, relative to the Fileset.out directory, and each value specifies extra information
     // about the link (its target, associated metadata and again its name).
     Map<PathFragment, FilesetOutputSymlink> outputSymlinks = new LinkedHashMap<>();

     if (!t.getDirectTraversal().isPresent()) {
       // The absence of "direct" traversal indicates the presence of a "nested" fileset and
       // getNestedTraversal will return the list FilesetTraversalParams corresponding to each
       // FilesetEntry of the nested Fileset.
       ImmutableList<SkyKey> nestedKeys = FilesetEntryKey.keys(t.getNestedTraversal());
       Map<SkyKey, SkyValue> results = env.getValues(nestedKeys);
       if (env.valuesMissing()) {
         return null;
       }

       for (SkyKey nestedKey : nestedKeys) {
         FilesetEntryValue nested = (FilesetEntryValue) results.get(nestedKey);
         for (FilesetOutputSymlink s : nested.getSymlinks()) {
           if (!exclusions.contains(s.name.getPathString())) {
             maybeStoreSymlink(s, t.getDestPath(), outputSymlinks);
           }
         }
       }
     } else {
       // The "direct" traversal params are present, which is the case when the FilesetEntry
       // specifies a package's BUILD file, a directory or a list of files.

       // The root of the direct traversal is defined as follows.
       //
       // If FilesetEntry.files is specified, then a TraversalRequest is created for each entry, the
       // root being the respective entry itself. These are all traversed for they may be
       // directories or symlinks to directories, and we need to establish Skyframe dependencies on
       // their contents for incremental correctness. If an entry is indeed a directory (but not when
       // it's a symlink to one) then we have to create symlinks to each of their childen.
       // (NB: there seems to be no good reason for this, it's just how legacy Fileset works. We may
       // want to consider creating a symlink just for the directory and not for its child elements.)
       //
       // If FilesetEntry.files is not specified, then srcdir refers to either a BUILD file or a
       // directory. For the former, the root will be the parent of the BUILD file. For the latter,
       // the root will be srcdir itself.
       DirectTraversal direct = t.getDirectTraversal().get();

       RecursiveFilesystemTraversalValue rftv;
       try {
         // Traverse the filesystem to establish skyframe dependencies.
         rftv = traverse(env, createErrorInfo(t), direct);
       } catch (MissingDepException e) {
         return null;
       }

       // The root can only be absent for the EMPTY rftv instance.
       if (!rftv.getResolvedRoot().isPresent()) {
         return FilesetEntryValue.EMPTY;
       }

       ResolvedFile resolvedRoot = rftv.getResolvedRoot().get();

       // Handle dangling symlinks gracefully be returning empty results.
       if (!resolvedRoot.getType().exists()) {
         return FilesetEntryValue.EMPTY;
       }

       // The prefix to remove is the entire path of the root. This is OK:
       // - when the root is a file, this removes the entire path, but the traversal's destination
       //   path is actually the name of the output symlink, so this works out correctly
       // - when the root is a directory or a symlink to one then we need to strip off the
       //   directory's path from every result (this is how the output symlinks must be created)
       //   before making them relative to the destination path
       PathFragment prefixToRemove = direct.getRoot().getRelativePart();

       Iterable<ResolvedFile> results = null;

       if (direct.isRecursive()
           || (resolvedRoot.getType().isDirectory() && !resolvedRoot.getType().isSymlink())) {
         // The traversal is recursive (requested for an entire FilesetEntry.srcdir) or it was
         // requested for a FilesetEntry.files entry which turned out to be a directory. We need to
         // create an output symlink for every file in it and all of its subdirectories. Only
         // exception is when the subdirectory is really a symlink to a directory -- no output
         // shall be created for the contents of those.
         // Now we create Dir objects to model the filesystem tree. The object employs a trick to
         // find directory symlinks: directory symlinks have corresponding ResolvedFile entries and
         // are added as files too, while their children, also added as files, contain the path of
         // the parent. Finding and discarding the children is easy if we traverse the tree from
         // root to leaf.
         DirectoryTree root = new DirectoryTree();
         for (ResolvedFile f : rftv.getTransitiveFiles().toCollection()) {
           PathFragment path = f.getNameInSymlinkTree().relativeTo(prefixToRemove);
           if (path.segmentCount() > 0) {
             path = t.getDestPath().getRelative(path);
             DirectoryTree dir = root;
             for (int i = 0; i < path.segmentCount() - 1; ++i) {
               dir = dir.addOrGetSubdir(path.getSegment(i));
             }
             dir.maybeAddFile(f);
           }
         }
         // Here's where the magic happens. The returned iterable will yield all files in the
         // directory that are not under symlinked directories, as well as all directory symlinks.
         results = root.iterateFiles();
       } else {
         // If we're on this branch then the traversal was done for just one entry in
         // FilesetEntry.files (which was not a directory, so it was either a file, a symlink to one
         // or a symlink to a directory), meaning we'll have only one output symlink.
         results = ImmutableList.of(resolvedRoot);
       }

       // Create one output symlink for each entry in the results.
       for (ResolvedFile f : results) {
         // The linkName has to be under the traversal's root, which is also the prefix to remove.
         PathFragment linkName = f.getNameInSymlinkTree().relativeTo(prefixToRemove);

         // Check whether the symlink is excluded before attempting to resolve it.
         // It may be dangling, but excluding it is still fine.
         // TODO(b/64754128): Investigate if we could have made the exclude earlier before
         //                   unnecessarily iterating over all the files in an excluded directory.
         if (linkName.segmentCount() > 0 && exclusions.contains(linkName.getSegment(0))) {
           continue;
         }

         PathFragment targetName;
         try {
           targetName = f.getTargetInSymlinkTree(direct.isFollowingSymlinks());
         } catch (DanglingSymlinkException e) {
           throw new FilesetEntryFunctionException(e);
         }

         // Metadata field must be present. It can only be absent when stripped by tests.
         String metadata = Integer.toHexString(f.getMetadataHash());
         maybeStoreSymlink(linkName, targetName, metadata, t.getDestPath(), outputSymlinks);
       }
     }

     return FilesetEntryValue.of(ImmutableSet.copyOf(outputSymlinks.values()));
   }

   /** Stores an output symlink unless it would overwrite an existing one. */
   private static void maybeStoreSymlink(
       FilesetOutputSymlink nestedLink,
       PathFragment destPath,
       Map<PathFragment, FilesetOutputSymlink> result) {
     maybeStoreSymlink(nestedLink.name, nestedLink.target, nestedLink.metadata, destPath, result);
   }

   /** Stores an output symlink unless it would overwrite an existing one. */
   private static void maybeStoreSymlink(
       PathFragment linkName,
       PathFragment linkTarget,
       String metadata,
       PathFragment destPath,
       Map<PathFragment, FilesetOutputSymlink> result) {
     linkName = destPath.getRelative(linkName);
     if (!result.containsKey(linkName)) {
       result.put(linkName, new FilesetOutputSymlink(linkName, linkTarget, metadata));
     }
   }

   private static Set<String> createExclusionSet(Set<String> input) {
     return Sets.filter(input, new Predicate<String>() {
       @Override
       public boolean apply(String e) {
         // Keep the top-level exclusions only. Do not look for "/" but count the path segments
         // instead, in anticipation of future Windows support.
         return PathFragment.create(e).segmentCount() == 1;
       }
     });
   }

   @Override
   public String extractTag(SkyKey skyKey) {
     return null;
   }

   private static RecursiveFilesystemTraversalValue traverse(
       Environment env, String errorInfo, DirectTraversal traversal)
       throws MissingDepException, InterruptedException {
     SkyKey depKey = RecursiveFilesystemTraversalValue.key(
         new RecursiveFilesystemTraversalValue.TraversalRequest(traversal.getRoot().asRootedPath(),
             traversal.isGenerated(), traversal.getPackageBoundaryMode(), traversal.isPackage(),
             errorInfo, /*pattern=*/null));
     RecursiveFilesystemTraversalValue v = (RecursiveFilesystemTraversalValue) env.getValue(depKey);
     if (env.valuesMissing()) {
       throw new MissingDepException();
     }
     return v;
   }

   private static String createErrorInfo(FilesetTraversalParams t) {
     if (t.getDirectTraversal().isPresent()) {
       DirectTraversal direct = t.getDirectTraversal().get();
       return String.format(
           "Fileset '%s' traversing %s '%s'",
           t.getOwnerLabelForErrorMessages(),
           direct.isPackage() ? "package" : "file (or directory)",
           direct.getRoot().getRelativePart().getPathString());
     } else {
       return String.format(
           "Fileset '%s' traversing another Fileset", t.getOwnerLabelForErrorMessages());
     }
   }

   /**
    * Models a FilesetEntryFunction's portion of the symlink output tree created by a Fileset rule.
    *
    * <p>A Fileset rule's output is computed by zero or more {@link FilesetEntryFunction}s, resulting
    * in one {@link FilesetEntryValue} for each. Each of those represents a portion of the grand
    * output tree of the Fileset. These portions are later merged and written to the fileset manifest
    * file, which is then consumed by a tool that ultimately creates the symlinks in the filesystem.
    *
    * <p>Because the Fileset doesn't process the lists in the FilesetEntryValues any further than
    * merging them, they have to adhere to the conventions of the manifest file. One of these is that
    * files are alphabetically ordered (enables the consumer of the manifest to work faster than
    * otherwise) and another is that the contents of regular directories are listed, but contents
    * of directory symlinks are not, only the symlinks are. (Other details of the manifest file are
    * not relevant here.)
    *
    * <p>See {@link DirectoryTree#iterateFiles()} for more details.
    */
   private static final class DirectoryTree {
     // Use TreeMaps for the benefit of alphabetically ordered iteration.
     public final Map<String, ResolvedFile> files = new TreeMap<>();
     public final Map<String, DirectoryTree> dirs = new TreeMap<>();

     DirectoryTree addOrGetSubdir(String name) {
       DirectoryTree result = dirs.get(name);
       if (result == null) {
         result = new DirectoryTree();
         dirs.put(name, result);
       }
       return result;
     }

     void maybeAddFile(ResolvedFile r) {
       String name = r.getNameInSymlinkTree().getBaseName();
       if (!files.containsKey(name)) {
         files.put(name, r);
       }
     }

     /**
      * Lazily yields all files in this directory and all of its subdirectories.
      *
      * <p>The function first yields all the files directly under this directory, in alphabetical
      * order. Then come the contents of subdirectories, processed recursively in the same fashion
      * as this directory, and also in alphabetical order.
      *
      * <p>If a directory symlink is encountered its contents are not listed, only the symlink is.
      */
     Iterable<ResolvedFile> iterateFiles() {
       // 1. Filter directory symlinks. If the symlink target contains files, those were added
       // as normal files so their parent directory (the symlink) would show up in the dirs map
       // (as a directory) as well as in the files map (as a symlink to a directory).
       final Set<String> fileNames = files.keySet();
       Iterable<Map.Entry<String, DirectoryTree>> noDirSymlinkes = Iterables.filter(dirs.entrySet(),
           new Predicate<Map.Entry<String, DirectoryTree>>() {
             @Override
             public boolean apply(Map.Entry<String, DirectoryTree> input) {
               return !fileNames.contains(input.getKey());
             }
           });

       // 2. Extract the iterables of the true subdirectories.
       Iterable<Iterable<ResolvedFile>> subdirIters = Iterables.transform(noDirSymlinkes,
           new Function<Map.Entry<String, DirectoryTree>, Iterable<ResolvedFile>>() {
             @Override
             public Iterable<ResolvedFile> apply(Entry<String, DirectoryTree> input) {
               return input.getValue().iterateFiles();
             }
           });

       // 3. Just concat all subdirectory iterations for one, seamless iteration.
       Iterable<ResolvedFile> dirsIter = Iterables.concat(subdirIters);

       return Iterables.concat(files.values(), dirsIter);
     }
   }
 }
	// Copyright 2015 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.skyframe;

	import com.google.common.base.Function;
	import com.google.common.base.Preconditions;
	import com.google.common.base.Predicate;
	import com.google.common.collect.ImmutableList;
	import com.google.common.collect.ImmutableSet;
	import com.google.common.collect.Iterables;
	import com.google.common.collect.Sets;
	import com.google.devtools.build.lib.actions.FilesetOutputSymlink;
	import com.google.devtools.build.lib.actions.FilesetTraversalParams;
	import com.google.devtools.build.lib.actions.FilesetTraversalParams.DirectTraversal;
	import com.google.devtools.build.lib.skyframe.RecursiveFilesystemTraversalFunction.DanglingSymlinkException;
	import com.google.devtools.build.lib.skyframe.RecursiveFilesystemTraversalFunction.RecursiveFilesystemTraversalException;
	import com.google.devtools.build.lib.skyframe.RecursiveFilesystemTraversalValue.ResolvedFile;
	import com.google.devtools.build.lib.vfs.PathFragment;
	import com.google.devtools.build.skyframe.SkyFunction;
	import com.google.devtools.build.skyframe.SkyFunctionException;
	import com.google.devtools.build.skyframe.SkyKey;
	import com.google.devtools.build.skyframe.SkyValue;
	import java.util.LinkedHashMap;
	import java.util.Map;
	import java.util.Map.Entry;
	import java.util.Set;
	import java.util.TreeMap;

	/** SkyFunction for {@link FilesetEntryValue}. */
	public final class FilesetEntryFunction implements SkyFunction {

	private static final class MissingDepException extends Exception {}

	private static final class FilesetEntryFunctionException extends SkyFunctionException {
	FilesetEntryFunctionException(RecursiveFilesystemTraversalException e) {
	super(e, Transience.PERSISTENT);
	}
	}

	@Override
	public SkyValue compute(SkyKey key, Environment env)
	throws FilesetEntryFunctionException, InterruptedException {
	FilesetTraversalParams t = (FilesetTraversalParams) key.argument();
	if (t.getDirectTraversal().isPresent()) {
	Preconditions.checkState(
	t.getNestedTraversal().isEmpty(),
	"NestedTraversal must be empty if directTraversal is present: %s", t);
	}

	// Create the set of excluded files. Only top-level files can be excluded, i.e. ones that are
	// directly under the root if the root is a directory.
	Set<String> exclusions = createExclusionSet(t.getExcludedFiles());

	// The map of output symlinks. Each key is the path of a output symlink that the Fileset must
	// create, relative to the Fileset.out directory, and each value specifies extra information
	// about the link (its target, associated metadata and again its name).
	Map<PathFragment, FilesetOutputSymlink> outputSymlinks = new LinkedHashMap<>();

	if (!t.getDirectTraversal().isPresent()) {
	// The absence of "direct" traversal indicates the presence of a "nested" fileset and
	// getNestedTraversal will return the list FilesetTraversalParams corresponding to each
	// FilesetEntry of the nested Fileset.
	ImmutableList<SkyKey> nestedKeys = FilesetEntryKey.keys(t.getNestedTraversal());
	Map<SkyKey, SkyValue> results = env.getValues(nestedKeys);
	if (env.valuesMissing()) {
	return null;
	}

	for (SkyKey nestedKey : nestedKeys) {
	FilesetEntryValue nested = (FilesetEntryValue) results.get(nestedKey);
	for (FilesetOutputSymlink s : nested.getSymlinks()) {
	if (!exclusions.contains(s.name.getPathString())) {
	maybeStoreSymlink(s, t.getDestPath(), outputSymlinks);
	}
	}
	}
	} else {
	// The "direct" traversal params are present, which is the case when the FilesetEntry
	// specifies a package's BUILD file, a directory or a list of files.

	// The root of the direct traversal is defined as follows.
	//
	// If FilesetEntry.files is specified, then a TraversalRequest is created for each entry, the
	// root being the respective entry itself. These are all traversed for they may be
	// directories or symlinks to directories, and we need to establish Skyframe dependencies on
	// their contents for incremental correctness. If an entry is indeed a directory (but not when
	// it's a symlink to one) then we have to create symlinks to each of their childen.
	// (NB: there seems to be no good reason for this, it's just how legacy Fileset works. We may
	// want to consider creating a symlink just for the directory and not for its child elements.)
	//
	// If FilesetEntry.files is not specified, then srcdir refers to either a BUILD file or a
	// directory. For the former, the root will be the parent of the BUILD file. For the latter,
	// the root will be srcdir itself.
	DirectTraversal direct = t.getDirectTraversal().get();

	RecursiveFilesystemTraversalValue rftv;
	try {
	// Traverse the filesystem to establish skyframe dependencies.
	rftv = traverse(env, createErrorInfo(t), direct);
	} catch (MissingDepException e) {
	return null;
	}

	// The root can only be absent for the EMPTY rftv instance.
	if (!rftv.getResolvedRoot().isPresent()) {
	return FilesetEntryValue.EMPTY;
	}

	ResolvedFile resolvedRoot = rftv.getResolvedRoot().get();

	// Handle dangling symlinks gracefully be returning empty results.
	if (!resolvedRoot.getType().exists()) {
	return FilesetEntryValue.EMPTY;
	}

	// The prefix to remove is the entire path of the root. This is OK:
	// - when the root is a file, this removes the entire path, but the traversal's destination
	// path is actually the name of the output symlink, so this works out correctly
	// - when the root is a directory or a symlink to one then we need to strip off the
	// directory's path from every result (this is how the output symlinks must be created)
	// before making them relative to the destination path
	PathFragment prefixToRemove = direct.getRoot().getRelativePart();

	Iterable<ResolvedFile> results = null;

	if (direct.isRecursive()
	\|\| (resolvedRoot.getType().isDirectory() && !resolvedRoot.getType().isSymlink())) {
	// The traversal is recursive (requested for an entire FilesetEntry.srcdir) or it was
	// requested for a FilesetEntry.files entry which turned out to be a directory. We need to
	// create an output symlink for every file in it and all of its subdirectories. Only
	// exception is when the subdirectory is really a symlink to a directory -- no output
	// shall be created for the contents of those.
	// Now we create Dir objects to model the filesystem tree. The object employs a trick to
	// find directory symlinks: directory symlinks have corresponding ResolvedFile entries and
	// are added as files too, while their children, also added as files, contain the path of
	// the parent. Finding and discarding the children is easy if we traverse the tree from
	// root to leaf.
	DirectoryTree root = new DirectoryTree();
	for (ResolvedFile f : rftv.getTransitiveFiles().toCollection()) {
	PathFragment path = f.getNameInSymlinkTree().relativeTo(prefixToRemove);
	if (path.segmentCount() > 0) {
	path = t.getDestPath().getRelative(path);
	DirectoryTree dir = root;
	for (int i = 0; i < path.segmentCount() - 1; ++i) {
	dir = dir.addOrGetSubdir(path.getSegment(i));
	}
	dir.maybeAddFile(f);
	}
	}
	// Here's where the magic happens. The returned iterable will yield all files in the
	// directory that are not under symlinked directories, as well as all directory symlinks.
	results = root.iterateFiles();
	} else {
	// If we're on this branch then the traversal was done for just one entry in
	// FilesetEntry.files (which was not a directory, so it was either a file, a symlink to one
	// or a symlink to a directory), meaning we'll have only one output symlink.
	results = ImmutableList.of(resolvedRoot);
	}

	// Create one output symlink for each entry in the results.
	for (ResolvedFile f : results) {
	// The linkName has to be under the traversal's root, which is also the prefix to remove.
	PathFragment linkName = f.getNameInSymlinkTree().relativeTo(prefixToRemove);

	// Check whether the symlink is excluded before attempting to resolve it.
	// It may be dangling, but excluding it is still fine.
	// TODO(b/64754128): Investigate if we could have made the exclude earlier before
	// unnecessarily iterating over all the files in an excluded directory.
	if (linkName.segmentCount() > 0 && exclusions.contains(linkName.getSegment(0))) {
	continue;
	}

	PathFragment targetName;
	try {
	targetName = f.getTargetInSymlinkTree(direct.isFollowingSymlinks());
	} catch (DanglingSymlinkException e) {
	throw new FilesetEntryFunctionException(e);
	}

	// Metadata field must be present. It can only be absent when stripped by tests.
	String metadata = Integer.toHexString(f.getMetadataHash());
	maybeStoreSymlink(linkName, targetName, metadata, t.getDestPath(), outputSymlinks);
	}
	}

	return FilesetEntryValue.of(ImmutableSet.copyOf(outputSymlinks.values()));
	}

	/** Stores an output symlink unless it would overwrite an existing one. */
	private static void maybeStoreSymlink(
	FilesetOutputSymlink nestedLink,
	PathFragment destPath,
	Map<PathFragment, FilesetOutputSymlink> result) {
	maybeStoreSymlink(nestedLink.name, nestedLink.target, nestedLink.metadata, destPath, result);
	}

	/** Stores an output symlink unless it would overwrite an existing one. */
	private static void maybeStoreSymlink(
	PathFragment linkName,
	PathFragment linkTarget,
	String metadata,
	PathFragment destPath,
	Map<PathFragment, FilesetOutputSymlink> result) {
	linkName = destPath.getRelative(linkName);
	if (!result.containsKey(linkName)) {
	result.put(linkName, new FilesetOutputSymlink(linkName, linkTarget, metadata));
	}
	}

	private static Set<String> createExclusionSet(Set<String> input) {
	return Sets.filter(input, new Predicate<String>() {
	@Override
	public boolean apply(String e) {
	// Keep the top-level exclusions only. Do not look for "/" but count the path segments
	// instead, in anticipation of future Windows support.
	return PathFragment.create(e).segmentCount() == 1;
	}
	});
	}

	@Override
	public String extractTag(SkyKey skyKey) {
	return null;
	}

	private static RecursiveFilesystemTraversalValue traverse(
	Environment env, String errorInfo, DirectTraversal traversal)
	throws MissingDepException, InterruptedException {
	SkyKey depKey = RecursiveFilesystemTraversalValue.key(
	new RecursiveFilesystemTraversalValue.TraversalRequest(traversal.getRoot().asRootedPath(),
	traversal.isGenerated(), traversal.getPackageBoundaryMode(), traversal.isPackage(),
	errorInfo, /pattern=/null));
	RecursiveFilesystemTraversalValue v = (RecursiveFilesystemTraversalValue) env.getValue(depKey);
	if (env.valuesMissing()) {
	throw new MissingDepException();
	}
	return v;
	}

	private static String createErrorInfo(FilesetTraversalParams t) {
	if (t.getDirectTraversal().isPresent()) {
	DirectTraversal direct = t.getDirectTraversal().get();
	return String.format(
	"Fileset '%s' traversing %s '%s'",
	t.getOwnerLabelForErrorMessages(),
	direct.isPackage() ? "package" : "file (or directory)",
	direct.getRoot().getRelativePart().getPathString());
	} else {
	return String.format(
	"Fileset '%s' traversing another Fileset", t.getOwnerLabelForErrorMessages());
	}
	}

	/**
	* Models a FilesetEntryFunction's portion of the symlink output tree created by a Fileset rule.
	*
	* <p>A Fileset rule's output is computed by zero or more {@link FilesetEntryFunction}s, resulting
	* in one {@link FilesetEntryValue} for each. Each of those represents a portion of the grand
	* output tree of the Fileset. These portions are later merged and written to the fileset manifest
	* file, which is then consumed by a tool that ultimately creates the symlinks in the filesystem.
	*
	* <p>Because the Fileset doesn't process the lists in the FilesetEntryValues any further than
	* merging them, they have to adhere to the conventions of the manifest file. One of these is that
	* files are alphabetically ordered (enables the consumer of the manifest to work faster than
	* otherwise) and another is that the contents of regular directories are listed, but contents
	* of directory symlinks are not, only the symlinks are. (Other details of the manifest file are
	* not relevant here.)
	*
	* <p>See {@link DirectoryTree#iterateFiles()} for more details.
	*/
	private static final class DirectoryTree {
	// Use TreeMaps for the benefit of alphabetically ordered iteration.
	public final Map<String, ResolvedFile> files = new TreeMap<>();
	public final Map<String, DirectoryTree> dirs = new TreeMap<>();

	DirectoryTree addOrGetSubdir(String name) {
	DirectoryTree result = dirs.get(name);
	if (result == null) {
	result = new DirectoryTree();
	dirs.put(name, result);
	}
	return result;
	}

	void maybeAddFile(ResolvedFile r) {
	String name = r.getNameInSymlinkTree().getBaseName();
	if (!files.containsKey(name)) {
	files.put(name, r);
	}
	}

	/**
	* Lazily yields all files in this directory and all of its subdirectories.
	*
	* <p>The function first yields all the files directly under this directory, in alphabetical
	* order. Then come the contents of subdirectories, processed recursively in the same fashion
	* as this directory, and also in alphabetical order.
	*
	* <p>If a directory symlink is encountered its contents are not listed, only the symlink is.
	*/
	Iterable<ResolvedFile> iterateFiles() {
	// 1. Filter directory symlinks. If the symlink target contains files, those were added
	// as normal files so their parent directory (the symlink) would show up in the dirs map
	// (as a directory) as well as in the files map (as a symlink to a directory).
	final Set<String> fileNames = files.keySet();
	Iterable<Map.Entry<String, DirectoryTree>> noDirSymlinkes = Iterables.filter(dirs.entrySet(),
	new Predicate<Map.Entry<String, DirectoryTree>>() {
	@Override
	public boolean apply(Map.Entry<String, DirectoryTree> input) {
	return !fileNames.contains(input.getKey());
	}
	});

	// 2. Extract the iterables of the true subdirectories.
	Iterable<Iterable<ResolvedFile>> subdirIters = Iterables.transform(noDirSymlinkes,
	new Function<Map.Entry<String, DirectoryTree>, Iterable<ResolvedFile>>() {
	@Override
	public Iterable<ResolvedFile> apply(Entry<String, DirectoryTree> input) {
	return input.getValue().iterateFiles();
	}
	});

	// 3. Just concat all subdirectory iterations for one, seamless iteration.
	Iterable<ResolvedFile> dirsIter = Iterables.concat(subdirIters);

	return Iterables.concat(files.values(), dirsIter);
	}
	}
	}