blob: 418f0058909fab84669983c93103fd4619a5c737 [file] [log] [blame]
// 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.vfs;
import com.google.common.annotations.VisibleForTesting;
import com.google.common.base.Joiner;
import com.google.common.base.Preconditions;
import com.google.common.base.Predicate;
import com.google.common.base.Predicates;
import com.google.common.base.Splitter;
import com.google.common.base.Throwables;
import com.google.common.collect.ImmutableList;
import com.google.common.collect.Iterables;
import com.google.common.collect.Lists;
import com.google.common.collect.Sets;
import com.google.common.util.concurrent.ForwardingListenableFuture;
import com.google.common.util.concurrent.Futures;
import com.google.common.util.concurrent.ListenableFuture;
import com.google.common.util.concurrent.SettableFuture;
import com.google.common.util.concurrent.Uninterruptibles;
import com.google.devtools.build.lib.profiler.Profiler;
import com.google.devtools.build.lib.profiler.ProfilerTask;
import com.google.devtools.build.lib.profiler.SilentCloseable;
import java.io.IOException;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import java.util.Objects;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ExecutionException;
import java.util.concurrent.Executor;
import java.util.concurrent.Future;
import java.util.concurrent.atomic.AtomicLong;
import java.util.concurrent.atomic.AtomicReference;
import java.util.regex.Pattern;
/**
* Implementation of a subset of UNIX-style file globbing, expanding "*" and "?" as wildcards, but
* not [a-z] ranges.
*
* <p><code>**</code> gets special treatment in include patterns. If it is used as a complete path
* segment it matches the filenames in subdirectories recursively.
*
* <p>Importantly, note that the glob matches are in an unspecified order.
*/
public final class UnixGlob {
private UnixGlob() {}
private static List<Path> globInternal(
Path base,
Collection<String> patterns,
boolean excludeDirectories,
Predicate<Path> dirPred,
FilesystemCalls syscalls,
Executor executor)
throws IOException, InterruptedException {
GlobVisitor visitor = new GlobVisitor(executor);
return visitor.glob(base, patterns, excludeDirectories, dirPred, syscalls);
}
private static List<Path> globInternalUninterruptible(
Path base,
Collection<String> patterns,
boolean excludeDirectories,
Predicate<Path> dirPred,
FilesystemCalls syscalls,
Executor executor)
throws IOException {
GlobVisitor visitor = new GlobVisitor(executor);
return visitor.globUninterruptible(base, patterns, excludeDirectories, dirPred, syscalls);
}
private static long globInternalAndReturnNumGlobTasksForTesting(
Path base,
Collection<String> patterns,
boolean excludeDirectories,
Predicate<Path> dirPred,
FilesystemCalls syscalls,
Executor executor)
throws IOException, InterruptedException {
GlobVisitor visitor = new GlobVisitor(executor);
visitor.glob(base, patterns, excludeDirectories, dirPred, syscalls);
return visitor.getNumGlobTasksForTesting();
}
private static Future<List<Path>> globAsyncInternal(
Path base,
Collection<String> patterns,
boolean excludeDirectories,
Predicate<Path> dirPred,
FilesystemCalls syscalls,
Executor executor) {
Preconditions.checkNotNull(executor, "%s %s", base, patterns);
return new GlobVisitor(executor)
.globAsync(base, patterns, excludeDirectories, dirPred, syscalls);
}
/**
* Checks that each pattern is valid, splits it into segments and checks
* that each segment contains only valid wildcards.
*
* @return list of segment arrays
*/
private static List<String[]> checkAndSplitPatterns(Collection<String> patterns) {
List<String[]> list = Lists.newArrayListWithCapacity(patterns.size());
for (String pattern : patterns) {
String error = checkPatternForError(pattern);
if (error != null) {
throw new IllegalArgumentException(error + " (in glob pattern '" + pattern + "')");
}
Iterable<String> segments = Splitter.on('/').split(pattern);
list.add(Iterables.toArray(segments, String.class));
}
return list;
}
/**
* @return whether or not {@code pattern} contains illegal characters
*/
public static String checkPatternForError(String pattern) {
if (pattern.isEmpty()) {
return "pattern cannot be empty";
}
if (pattern.charAt(0) == '/') {
return "pattern cannot be absolute";
}
Iterable<String> segments = Splitter.on('/').split(pattern);
for (String segment : segments) {
if (segment.isEmpty()) {
return "empty segment not permitted";
}
if (segment.equals(".") || segment.equals("..")) {
return "segment '" + segment + "' not permitted";
}
if (segment.contains("**") && !segment.equals("**")) {
return "recursive wildcard must be its own segment";
}
}
return null;
}
/** Calls {@link #matches(String, String, Map) matches(pattern, str, null)} */
public static boolean matches(String pattern, String str) {
return matches(pattern, str, null);
}
/**
* Returns whether {@code str} matches the glob pattern {@code pattern}. This method may use the
* {@code patternCache} to speed up the matching process.
*
* @param pattern a glob pattern
* @param str the string to match
* @param patternCache a cache from patterns to compiled Pattern objects, or {@code null} to skip
* caching
*/
public static boolean matches(String pattern, String str, Map<String, Pattern> patternCache) {
if (pattern.length() == 0 || str.length() == 0) {
return false;
}
// Common case: **
if (pattern.equals("**")) {
return true;
}
// Common case: *
if (pattern.equals("*")) {
return true;
}
// If a filename starts with '.', this char must be matched explicitly.
if (str.charAt(0) == '.' && pattern.charAt(0) != '.') {
return false;
}
// Common case: *.xyz
if (pattern.charAt(0) == '*' && pattern.lastIndexOf('*') == 0) {
return str.endsWith(pattern.substring(1));
}
// Common case: xyz*
int lastIndex = pattern.length() - 1;
// The first clause of this if statement is unnecessary, but is an
// optimization--charAt runs faster than indexOf.
if (pattern.charAt(lastIndex) == '*' && pattern.indexOf('*') == lastIndex) {
return str.startsWith(pattern.substring(0, lastIndex));
}
Pattern regex =
patternCache == null
? makePatternFromWildcard(pattern)
: patternCache.computeIfAbsent(pattern, p -> makePatternFromWildcard(p));
return regex.matcher(str).matches();
}
/**
* Returns a regular expression implementing a matcher for "pattern", in which
* "*" and "?" are wildcards.
*
* <p>e.g. "foo*bar?.java" -> "foo.*bar.\\.java"
*/
private static Pattern makePatternFromWildcard(String pattern) {
StringBuilder regexp = new StringBuilder();
for(int i = 0, len = pattern.length(); i < len; i++) {
char c = pattern.charAt(i);
switch(c) {
case '*':
int toIncrement = 0;
if (len > i + 1 && pattern.charAt(i + 1) == '*') {
// The pattern '**' is interpreted to match 0 or more directory separators, not 1 or
// more. We skip the next * and then find a trailing/leading '/' and get rid of it.
toIncrement = 1;
if (len > i + 2 && pattern.charAt(i + 2) == '/') {
// We have '**/' -- skip the '/'.
toIncrement = 2;
} else if (len == i + 2 && i > 0 && pattern.charAt(i - 1) == '/') {
// We have '/**' -- remove the '/'.
regexp.delete(regexp.length() - 1, regexp.length());
}
}
regexp.append(".*");
i += toIncrement;
break;
case '?':
regexp.append('.');
break;
//escape the regexp special characters that are allowed in wildcards
case '^': case '$': case '|': case '+':
case '{': case '}': case '[': case ']':
case '\\': case '.':
regexp.append('\\');
regexp.append(c);
break;
default:
regexp.append(c);
break;
}
}
return Pattern.compile(regexp.toString());
}
/**
* Filesystem calls required for glob().
*/
public interface FilesystemCalls {
/** Get directory entries and their types. */
Collection<Dirent> readdir(Path path, Symlinks symlinks) throws IOException;
/** Return the stat() for the given path, or null. */
FileStatus statIfFound(Path path, Symlinks symlinks) throws IOException;
/**
* Return the type of a specific file. This may be answered using stat() or readdir(). Returns
* null if the path does not exist.
*/
Dirent.Type getType(Path path, Symlinks symlinks) throws IOException;
}
public static final FilesystemCalls DEFAULT_SYSCALLS =
new FilesystemCalls() {
@Override
public Collection<Dirent> readdir(Path path, Symlinks symlinks) throws IOException {
return path.readdir(symlinks);
}
@Override
public FileStatus statIfFound(Path path, Symlinks symlinks) throws IOException {
return path.statIfFound(symlinks);
}
@Override
public Dirent.Type getType(Path path, Symlinks symlinks) throws IOException {
return statusToDirentType(statIfFound(path, symlinks));
}
};
public static Dirent.Type statusToDirentType(FileStatus status) {
if (status == null) {
return null;
} else if (status.isFile()) {
return Dirent.Type.FILE;
} else if (status.isDirectory()) {
return Dirent.Type.DIRECTORY;
} else if (status.isSymbolicLink()) {
return Dirent.Type.SYMLINK;
}
return Dirent.Type.UNKNOWN;
}
public static final AtomicReference<FilesystemCalls> DEFAULT_SYSCALLS_REF =
new AtomicReference<>(DEFAULT_SYSCALLS);
public static Builder forPath(Path path) {
return new Builder(path);
}
/**
* Builder class for UnixGlob.
*
*
*/
public static class Builder {
private Path base;
private List<String> patterns;
private boolean excludeDirectories;
private Predicate<Path> pathFilter;
private Executor executor;
private AtomicReference<? extends FilesystemCalls> syscalls =
new AtomicReference<>(DEFAULT_SYSCALLS);
/**
* Creates a glob builder with the given base path.
*/
public Builder(Path base) {
this.base = base;
this.patterns = Lists.newArrayList();
this.excludeDirectories = false;
this.pathFilter = Predicates.alwaysTrue();
}
/**
* Adds a pattern to include to the glob builder.
*
* <p>For a description of the syntax of the patterns, see {@link UnixGlob}.
*/
public Builder addPattern(String pattern) {
this.patterns.add(pattern);
return this;
}
/**
* Adds a pattern to include to the glob builder.
*
* <p>For a description of the syntax of the patterns, see {@link UnixGlob}.
*/
public Builder addPatterns(String... patterns) {
Collections.addAll(this.patterns, patterns);
return this;
}
/**
* Adds a pattern to include to the glob builder.
*
* <p>For a description of the syntax of the patterns, see {@link UnixGlob}.
*/
public Builder addPatterns(Collection<String> patterns) {
this.patterns.addAll(patterns);
return this;
}
/**
* Sets the FilesystemCalls interface to use on this glob().
*/
public Builder setFilesystemCalls(AtomicReference<? extends FilesystemCalls> syscalls) {
this.syscalls = (syscalls == null)
? new AtomicReference<FilesystemCalls>(DEFAULT_SYSCALLS)
: syscalls;
return this;
}
/**
* If set to true, directories are not returned in the glob result.
*/
public Builder setExcludeDirectories(boolean excludeDirectories) {
this.excludeDirectories = excludeDirectories;
return this;
}
/**
* Sets the executor to use for parallel glob evaluation. If unset, evaluation is done
* in-thread.
*/
public Builder setExecutor(Executor pool) {
this.executor = pool;
return this;
}
/**
* If set, the given predicate is called for every directory
* encountered. If it returns false, the corresponding item is not
* returned in the output and directories are not traversed either.
*/
public Builder setDirectoryFilter(Predicate<Path> pathFilter) {
this.pathFilter = pathFilter;
return this;
}
/**
* Executes the glob.
*/
public List<Path> glob() throws IOException {
return globInternalUninterruptible(
base, patterns, excludeDirectories, pathFilter, syscalls.get(), executor);
}
/**
* Executes the glob and returns the result.
*
* @throws InterruptedException if the thread is interrupted.
*/
public List<Path> globInterruptible() throws IOException, InterruptedException {
return globInternal(base, patterns, excludeDirectories, pathFilter, syscalls.get(), executor);
}
@VisibleForTesting
public long globInterruptibleAndReturnNumGlobTasksForTesting()
throws IOException, InterruptedException {
return globInternalAndReturnNumGlobTasksForTesting(
base, patterns, excludeDirectories, pathFilter, syscalls.get(), executor);
}
/**
* Executes the glob asynchronously. {@link #setExecutor} must have been called already with a
* non-null argument.
*/
public Future<List<Path>> globAsync() {
return globAsyncInternal(
base, patterns, excludeDirectories, pathFilter, syscalls.get(), executor);
}
}
/**
* Adapts the result of the glob visitation as a Future.
*/
private static class GlobFuture extends ForwardingListenableFuture<List<Path>> {
private final GlobVisitor visitor;
private final SettableFuture<List<Path>> delegate = SettableFuture.create();
public GlobFuture(GlobVisitor visitor) {
this.visitor = visitor;
}
@Override
protected ListenableFuture<List<Path>> delegate() {
return delegate;
}
public void setException(Throwable throwable) {
delegate.setException(throwable);
}
public void set(List<Path> paths) {
delegate.set(paths);
}
@Override
public boolean cancel(boolean mayInterruptIfRunning) {
// Best-effort interrupt of the in-flight visitation.
visitor.cancel();
return true;
}
public void markCanceled() {
super.cancel(true);
}
}
/**
* GlobVisitor executes a glob using parallelism, which is useful when
* the glob() requires many readdir() calls on high latency filesystems.
*/
private static final class GlobVisitor {
// These collections are used across workers and must therefore be thread-safe.
private final Collection<Path> results = Sets.newConcurrentHashSet();
private final ConcurrentHashMap<String, Pattern> cache = new ConcurrentHashMap<>();
private final GlobFuture result;
private final Executor executor;
private final AtomicLong totalOps = new AtomicLong(0);
private final AtomicLong pendingOps = new AtomicLong(0);
private final AtomicReference<IOException> ioException = new AtomicReference<>();
private final AtomicReference<RuntimeException> runtimeException = new AtomicReference<>();
private final AtomicReference<Error> error = new AtomicReference<>();
private volatile boolean canceled = false;
GlobVisitor(Executor executor) {
this.executor = executor;
this.result = new GlobFuture(this);
}
/**
* Performs wildcard globbing: returns the list of filenames that match any of {@code patterns}
* relative to {@code base}. Directories are traversed if and only if they match {@code
* dirPred}. The predicate is also called for the root of the traversal. The order of the
* returned list is unspecified.
*
* <p>Patterns may include "*" and "?", but not "[a-z]".
*
* <p><code>**</code> gets special treatment in include patterns. If it is used as a complete
* path segment it matches the filenames in subdirectories recursively.
*
* @throws IllegalArgumentException if any glob pattern {@linkplain
* #checkPatternForError(String) contains errors} or if any include pattern segment contains
* <code>**</code> but not equal to it.
*/
List<Path> glob(Path base, Collection<String> patterns, boolean excludeDirectories,
Predicate<Path> dirPred, FilesystemCalls syscalls)
throws IOException, InterruptedException {
try {
return globAsync(base, patterns, excludeDirectories, dirPred, syscalls).get();
} catch (ExecutionException e) {
Throwable cause = e.getCause();
Throwables.propagateIfPossible(cause, IOException.class);
throw new RuntimeException(e);
}
}
List<Path> globUninterruptible(Path base, Collection<String> patterns,
boolean excludeDirectories, Predicate<Path> dirPred, FilesystemCalls syscalls)
throws IOException {
try {
return Uninterruptibles.getUninterruptibly(
globAsync(base, patterns, excludeDirectories, dirPred, syscalls));
} catch (ExecutionException e) {
Throwable cause = e.getCause();
Throwables.propagateIfPossible(cause, IOException.class);
throw new RuntimeException(e);
}
}
private static boolean isRecursivePattern(String pattern) {
return "**".equals(pattern);
}
/**
* Same as {@link #glob}, except does so asynchronously and returns a {@link Future} for the
* result.
*/
Future<List<Path>> globAsync(
Path base,
Collection<String> patterns,
boolean excludeDirectories,
Predicate<Path> dirPred,
FilesystemCalls syscalls) {
FileStatus baseStat;
try {
baseStat = syscalls.statIfFound(base, Symlinks.FOLLOW);
} catch (IOException e) {
return Futures.immediateFailedFuture(e);
}
if (baseStat == null || patterns.isEmpty()) {
return Futures.immediateFuture(Collections.<Path>emptyList());
}
List<String[]> splitPatterns = checkAndSplitPatterns(patterns);
// We do a dumb loop, even though it will likely duplicate logical work (note that the
// physical filesystem operations are cached). In order to optimize, we would need to keep
// track of which patterns shared sub-patterns and which did not (for example consider the
// glob [*/*.java, sub/*.java, */*.txt]).
pendingOps.incrementAndGet();
try {
for (String[] splitPattern : splitPatterns) {
int numRecursivePatterns = 0;
for (String pattern : splitPattern) {
if (isRecursivePattern(pattern)) {
++numRecursivePatterns;
}
}
GlobTaskContext context = numRecursivePatterns > 1
? new RecursiveGlobTaskContext(splitPattern, excludeDirectories, dirPred, syscalls)
: new GlobTaskContext(splitPattern, excludeDirectories, dirPred, syscalls);
context.queueGlob(base, baseStat.isDirectory(), 0);
}
} finally {
decrementAndCheckDone();
}
return result;
}
private Throwable getMostSeriousThrowableSoFar() {
if (error.get() != null) {
return error.get();
}
if (runtimeException.get() != null) {
return runtimeException.get();
}
if (ioException.get() != null) {
return ioException.get();
}
return null;
}
/** Should only be called by link {@GlobTaskContext}. */
private void queueGlob(final Path base, final boolean baseIsDir, final int idx,
final GlobTaskContext context) {
enqueue(
new Runnable() {
@Override
public void run() {
try (SilentCloseable c =
Profiler.instance().profile(ProfilerTask.VFS_GLOB, base.getPathString())) {
reallyGlob(base, baseIsDir, idx, context);
} catch (IOException e) {
ioException.set(e);
} catch (RuntimeException e) {
runtimeException.set(e);
} catch (Error e) {
error.set(e);
}
}
@Override
public String toString() {
return String.format(
"%s glob(include=[%s], exclude_directories=%s)",
base.getPathString(),
"\"" + Joiner.on("\", \"").join(context.patternParts) + "\"",
context.excludeDirectories);
}
});
}
/** Should only be called by link {@GlobTaskContext}. */
private void queueTask(Runnable runnable) {
enqueue(runnable);
}
protected void enqueue(final Runnable r) {
totalOps.incrementAndGet();
pendingOps.incrementAndGet();
Runnable wrapped =
() -> {
try {
if (!canceled && getMostSeriousThrowableSoFar() == null) {
r.run();
}
} finally {
decrementAndCheckDone();
}
};
if (executor == null) {
wrapped.run();
} else {
executor.execute(wrapped);
}
}
private long getNumGlobTasksForTesting() {
return totalOps.get();
}
protected void cancel() {
this.canceled = true;
}
private void decrementAndCheckDone() {
if (pendingOps.decrementAndGet() == 0) {
// We get to 0 iff we are done all the relevant work. This is because we always increment
// the pending ops count as we're enqueuing, and don't decrement until the task is complete
// (which includes accounting for any additional tasks that one enqueues).
Throwable mostSeriousThrowable = getMostSeriousThrowableSoFar();
if (canceled) {
result.markCanceled();
} else if (mostSeriousThrowable != null) {
result.setException(mostSeriousThrowable);
} else {
result.set(ImmutableList.copyOf(results));
}
}
}
/** A context for evaluating all the subtasks of a single top-level glob task. */
private class GlobTaskContext {
private final String[] patternParts;
private final boolean excludeDirectories;
private final Predicate<Path> dirPred;
private final FilesystemCalls syscalls;
GlobTaskContext(
String[] patternParts,
boolean excludeDirectories,
Predicate<Path> dirPred,
FilesystemCalls syscalls) {
this.patternParts = patternParts;
this.excludeDirectories = excludeDirectories;
this.dirPred = dirPred;
this.syscalls = syscalls;
}
protected void queueGlob(Path base, boolean baseIsDir, int patternIdx) {
GlobVisitor.this.queueGlob(base, baseIsDir, patternIdx, this);
}
protected void queueTask(Runnable runnable) {
GlobVisitor.this.queueTask(runnable);
}
}
/**
* A special implementation of {@link GlobTaskContext} that dedupes glob subtasks. Our naive
* implementation of recursive patterns means there are multiple ways to enqueue the same
* logical subtask.
*/
private class RecursiveGlobTaskContext extends GlobTaskContext {
private class GlobTask {
private final Path base;
private final int patternIdx;
private GlobTask(Path base, int patternIdx) {
this.base = base;
this.patternIdx = patternIdx;
}
@Override
public boolean equals(Object obj) {
if (!(obj instanceof GlobTask)) {
return false;
}
GlobTask other = (GlobTask) obj;
return base.equals(other.base) && patternIdx == other.patternIdx;
}
@Override
public int hashCode() {
return Objects.hash(base, patternIdx);
}
}
private final Set<GlobTask> visitedGlobSubTasks = Sets.newConcurrentHashSet();
private RecursiveGlobTaskContext(
String[] patternParts,
boolean excludeDirectories,
Predicate<Path> dirPred,
FilesystemCalls syscalls) {
super(patternParts, excludeDirectories, dirPred, syscalls);
}
@Override
protected void queueGlob(Path base, boolean baseIsDir, int patternIdx) {
if (visitedGlobSubTasks.add(new GlobTask(base, patternIdx))) {
// This is a unique glob task. For example of how duplicates can arise, consider:
// glob(['**/a/**/foo.txt'])
// with the only file being
// a/a/foo.txt
//
// there are multiple ways to reach a/a/foo.txt: one route starts by recursively globbing
// 'a/**/foo.txt' in the base directory of the package, and another route starts by
// recursively globbing '**/a/**/foo.txt' in subdirectory 'a'.
super.queueGlob(base, baseIsDir, patternIdx);
}
}
}
/**
* Expressed in Haskell:
*
* <pre>
* reallyGlob base [] = { base }
* reallyGlob base [x:xs] = union { reallyGlob(f, xs) | f results "base/x" }
* </pre>
*/
private void reallyGlob(Path base, boolean baseIsDir, int idx, GlobTaskContext context)
throws IOException {
if (baseIsDir && !context.dirPred.apply(base)) {
return;
}
if (idx == context.patternParts.length) { // Base case.
if (!(context.excludeDirectories && baseIsDir)) {
results.add(base);
}
return;
}
if (!baseIsDir) {
// Nothing to find here.
return;
}
String pattern = context.patternParts[idx];
// ** is special: it can match nothing at all.
// For example, x/** matches x, **/y matches y, and x/**/y matches x/y.
if (isRecursivePattern(pattern)) {
context.queueGlob(base, baseIsDir, idx + 1);
}
if (!pattern.contains("*") && !pattern.contains("?")) {
// We do not need to do a readdir in this case, just a stat.
Path child = base.getChild(pattern);
FileStatus status = context.syscalls.statIfFound(child, Symlinks.FOLLOW);
if (status == null || (!status.isDirectory() && !status.isFile())) {
// The file is a dangling symlink, fifo, does not exist, etc.
return;
}
context.queueGlob(child, status.isDirectory(), idx + 1);
return;
}
Collection<Dirent> dents = context.syscalls.readdir(base, Symlinks.NOFOLLOW);
for (Dirent dent : dents) {
Dirent.Type childType = dent.getType();
if (childType == Dirent.Type.UNKNOWN) {
// The file is a special file (fifo, etc.). No need to even match against the pattern.
continue;
}
if (matches(pattern, dent.getName(), cache)) {
Path child = base.getChild(dent.getName());
if (childType == Dirent.Type.SYMLINK) {
processSymlink(child, idx, context);
} else {
processFileOrDirectory(child, childType == Dirent.Type.DIRECTORY, idx, context);
}
}
}
}
/**
* Process symlinks asynchronously. If we should used readdir(..., Symlinks.FOLLOW), that would
* result in a sequential symlink resolution with many file system implementations. If the
* underlying file system is networked and a single directory contains many symlinks, that can
* lead to substantial slowness.
*/
private void processSymlink(Path path, int idx, GlobTaskContext context) {
context.queueTask(
() -> {
try {
FileStatus status = context.syscalls.statIfFound(path, Symlinks.FOLLOW);
if (status != null) {
processFileOrDirectory(path, status.isDirectory(), idx, context);
}
} catch (IOException e) {
// Intentionally empty. Just ignore symlinks that cannot be stat'ed to leave
// historical behavior of readdir(..., Symlinks.FOLLOW).
}
});
}
private void processFileOrDirectory(
Path path, boolean isDir, int idx, GlobTaskContext context) {
boolean isRecursivePattern = isRecursivePattern(context.patternParts[idx]);
if (isDir) {
context.queueGlob(path, /* baseIsDir= */ true, idx + (isRecursivePattern ? 0 : 1));
} else if (idx + 1 == context.patternParts.length) {
results.add(path);
}
}
}
/**
* Filters out exclude patterns from a Set of paths. Common cases such as wildcard-free patterns
* or suffix patterns are special-cased to make this function efficient.
*/
public static void removeExcludes(Set<String> paths, Collection<String> excludes) {
ArrayList<String> complexPatterns = new ArrayList<>(excludes.size());
Map<String, List<String>> starstarSlashStarHeadTailPairs = new HashMap<>();
for (String exclude : excludes) {
if (isWildcardFree(exclude)) {
paths.remove(exclude);
continue;
}
int patternPos = exclude.indexOf("**/*");
if (patternPos != -1) {
String head = exclude.substring(0, patternPos);
String tail = exclude.substring(patternPos + 4);
if (isWildcardFree(head) && isWildcardFree(tail)) {
starstarSlashStarHeadTailPairs.computeIfAbsent(head, h -> new ArrayList<>()).add(tail);
continue;
}
}
complexPatterns.add(exclude);
}
for (Map.Entry<String, List<String>> headTailPair : starstarSlashStarHeadTailPairs.entrySet()) {
paths.removeIf(
path -> {
if (path.startsWith(headTailPair.getKey())) {
for (String tail : headTailPair.getValue()) {
if (path.endsWith(tail)) {
return true;
}
}
}
return false;
});
}
if (complexPatterns.isEmpty()) {
return;
}
List<String[]> splitPatterns = checkAndSplitPatterns(complexPatterns);
HashMap<String, Pattern> patternCache = new HashMap<>();
paths.removeIf(
path -> {
String[] segments = Iterables.toArray(Splitter.on('/').split(path), String.class);
for (String[] splitPattern : splitPatterns) {
if (matchesPattern(splitPattern, segments, 0, 0, patternCache)) {
return true;
}
}
return false;
});
}
/** Returns true if {@code pattern} matches {@code path} starting from the given segments. */
private static boolean matchesPattern(
String[] pattern, String[] path, int i, int j, Map<String, Pattern> patternCache) {
if (i == pattern.length) {
return j == path.length;
}
if (pattern[i].equals("**")) {
return matchesPattern(pattern, path, i + 1, j, patternCache)
|| (j < path.length && matchesPattern(pattern, path, i, j + 1, patternCache));
}
if (j == path.length) {
return false;
}
if (matches(pattern[i], path[j], patternCache)) {
return matchesPattern(pattern, path, i + 1, j + 1, patternCache);
}
return false;
}
private static boolean isWildcardFree(String pattern) {
return !pattern.contains("*") && !pattern.contains("?");
}
}