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/*
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you 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 org.apache.zookeeper.server.watch;
import java.io.PrintWriter;
import java.util.BitSet;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Set;
import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.locks.ReentrantReadWriteLock;
import org.apache.zookeeper.WatchedEvent;
import org.apache.zookeeper.Watcher;
import org.apache.zookeeper.Watcher.Event.EventType;
import org.apache.zookeeper.Watcher.Event.KeeperState;
import org.apache.zookeeper.server.ServerCnxn;
import org.apache.zookeeper.server.ServerMetrics;
import org.apache.zookeeper.server.util.BitHashSet;
import org.apache.zookeeper.server.util.BitMap;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
/**
* Optimized in memory and time complexity, compared to WatchManager, both the
* memory consumption and time complexity improved a lot, but it cannot
* efficiently remove the watcher when the session or socket is closed, for
* majority use case this is not a problem.
*
* Changed made compared to WatchManager:
*
* - Use HashSet and BitSet to store the watchers to find a balance between
* memory usage and time complexity
* - Use ReadWriteLock instead of synchronized to reduce lock retention
* - Lazily clean up the closed watchers
*/
public class WatchManagerOptimized implements IWatchManager, IDeadWatcherListener {
private static final Logger LOG = LoggerFactory.getLogger(WatchManagerOptimized.class);
private final ConcurrentHashMap pathWatches = new ConcurrentHashMap();
// watcher to bit id mapping
private final BitMap watcherBitIdMap = new BitMap();
// used to lazily remove the dead watchers
private final WatcherCleaner watcherCleaner;
private final ReentrantReadWriteLock addRemovePathRWLock = new ReentrantReadWriteLock();
public WatchManagerOptimized() {
watcherCleaner = new WatcherCleaner(this);
watcherCleaner.start();
}
@Override
public boolean addWatch(String path, Watcher watcher) {
boolean result = false;
// Need readLock to exclusively lock with removeWatcher, otherwise we
// may add a dead watch whose connection was just closed.
//
// Creating new watcher bit and adding it to the BitHashSet has it's
// own lock to minimize the write lock scope
addRemovePathRWLock.readLock().lock();
try {
// avoid race condition of adding a on flying dead watcher
if (isDeadWatcher(watcher)) {
LOG.debug("Ignoring addWatch with closed cnxn");
} else {
Integer bit = watcherBitIdMap.add(watcher);
BitHashSet watchers = pathWatches.get(path);
if (watchers == null) {
watchers = new BitHashSet();
BitHashSet existingWatchers = pathWatches.putIfAbsent(path, watchers);
// it's possible multiple thread might add to pathWatches
// while we're holding read lock, so we need this check
// here
if (existingWatchers != null) {
watchers = existingWatchers;
}
}
result = watchers.add(bit);
}
} finally {
addRemovePathRWLock.readLock().unlock();
}
return result;
}
/**
* Used in the OpCode.checkWatches, which is a read operation, since read
* and write requests are exclusively processed, we don't need to hold
* lock here.
*
* Different from addWatch this method doesn't mutate any state, so we don't
* need to hold read lock to avoid dead watcher (cnxn closed) being added
* to the watcher manager.
*
* It's possible that before we lazily clean up the dead watcher, this will
* return true, but since the cnxn is closed, the response will dropped as
* well, so it doesn't matter.
*/
@Override
public boolean containsWatcher(String path, Watcher watcher) {
BitHashSet watchers = pathWatches.get(path);
return watchers != null && watchers.contains(watcherBitIdMap.getBit(watcher));
}
@Override
public boolean removeWatcher(String path, Watcher watcher) {
// Hold write lock directly because removeWatcher request is more
// likely to be invoked when the watcher is actually exist and
// haven't fired yet, so instead of having read lock to check existence
// before switching to write one, it's actually cheaper to hold write
// lock directly here.
addRemovePathRWLock.writeLock().lock();
try {
BitHashSet list = pathWatches.get(path);
if (list == null || !list.remove(watcherBitIdMap.getBit(watcher))) {
return false;
}
if (list.isEmpty()) {
pathWatches.remove(path);
}
return true;
} finally {
addRemovePathRWLock.writeLock().unlock();
}
}
@Override
public void removeWatcher(Watcher watcher) {
Integer watcherBit;
// Use exclusive lock with addWatcher to guarantee that we won't add
// watch for a cnxn which is already closed.
addRemovePathRWLock.writeLock().lock();
try {
// do nothing if the watcher is not tracked
watcherBit = watcherBitIdMap.getBit(watcher);
if (watcherBit == null) {
return;
}
} finally {
addRemovePathRWLock.writeLock().unlock();
}
// We can guarantee that when this line is executed, the cnxn of this
// watcher has already been marked as stale (this method is only called
// from ServerCnxn.close after we set stale), which means no watches
// will be added to the watcher manager with this watcher, so that we
// can safely clean up this dead watcher.
//
// So it's not necessary to have this line in the addRemovePathRWLock.
// And moving the addDeadWatcher out of the locking block to avoid
// holding the write lock while we're blocked on adding dead watchers
// into the watcherCleaner.
watcherCleaner.addDeadWatcher(watcherBit);
}
/**
* Entry for WatcherCleaner to remove dead watchers
*
* @param deadWatchers the watchers need to be removed
*/
@Override
public void processDeadWatchers(Set deadWatchers) {
// All the watchers being processed here are guaranteed to be dead,
// no watches will be added for those dead watchers, that's why I
// don't need to have addRemovePathRWLock here.
BitSet bits = new BitSet();
for (int dw : deadWatchers) {
bits.set(dw);
}
// The value iterator will reflect the state when it was
// created, don't need to synchronize.
for (BitHashSet watchers : pathWatches.values()) {
watchers.remove(deadWatchers, bits);
}
// Better to remove the empty path from pathWatches, but it will add
// lot of lock contention and affect the throughput of addWatch,
// let's rely on the triggerWatch to delete it.
for (Integer wbit : deadWatchers) {
watcherBitIdMap.remove(wbit);
}
}
@Override
public WatcherOrBitSet triggerWatch(String path, EventType type) {
return triggerWatch(path, type, null);
}
@Override
public WatcherOrBitSet triggerWatch(String path, EventType type, WatcherOrBitSet suppress) {
WatchedEvent e = new WatchedEvent(type, KeeperState.SyncConnected, path);
BitHashSet watchers = remove(path);
if (watchers == null) {
return null;
}
int triggeredWatches = 0;
// Avoid race condition between dead watcher cleaner in
// WatcherCleaner and iterating here
synchronized (watchers) {
for (Integer wBit : watchers) {
if (suppress != null && suppress.contains(wBit)) {
continue;
}
Watcher w = watcherBitIdMap.get(wBit);
// skip dead watcher
if (w == null || isDeadWatcher(w)) {
continue;
}
w.process(e);
triggeredWatches++;
}
}
updateMetrics(type, triggeredWatches);
return new WatcherOrBitSet(watchers);
}
@Override
public int size() {
int size = 0;
for (BitHashSet watches : pathWatches.values()) {
size += watches.size();
}
return size;
}
@Override
public void shutdown() {
if (watcherCleaner != null) {
watcherCleaner.shutdown();
}
}
private BitHashSet remove(String path) {
addRemovePathRWLock.writeLock().lock();
try {
return pathWatches.remove(path);
} finally {
addRemovePathRWLock.writeLock().unlock();
}
}
void updateMetrics(final EventType type, int size) {
switch (type) {
case NodeCreated:
ServerMetrics.getMetrics().NODE_CREATED_WATCHER.add(size);
break;
case NodeDeleted:
ServerMetrics.getMetrics().NODE_DELETED_WATCHER.add(size);
break;
case NodeDataChanged:
ServerMetrics.getMetrics().NODE_CHANGED_WATCHER.add(size);
break;
case NodeChildrenChanged:
ServerMetrics.getMetrics().NODE_CHILDREN_WATCHER.add(size);
break;
default:
// Other types not logged.
break;
}
}
boolean isDeadWatcher(Watcher watcher) {
return watcher instanceof ServerCnxn && ((ServerCnxn) watcher).isStale();
}
int pathSize() {
return pathWatches.size();
}
@Override
public WatchesSummary getWatchesSummary() {
return new WatchesSummary(watcherBitIdMap.size(), pathSize(), size());
}
@Override
public WatchesReport getWatches() {
Map> id2paths = new HashMap>();
for (Entry> e : getWatcher2PathesMap().entrySet()) {
Long id = ((ServerCnxn) e.getKey()).getSessionId();
Set paths = new HashSet(e.getValue());
id2paths.put(id, paths);
}
return new WatchesReport(id2paths);
}
/**
* Iterate through ConcurrentHashMap is 'safe', it will reflect the state
* of the map at the time iteration began, may miss update while iterating,
* given this is used in the commands to get a general idea of the watches
* state, we don't care about missing some update.
*/
@Override
public WatchesPathReport getWatchesByPath() {
Map> path2ids = new HashMap>();
for (Entry e : pathWatches.entrySet()) {
BitHashSet watchers = e.getValue();
synchronized (watchers) {
Set ids = new HashSet(watchers.size());
path2ids.put(e.getKey(), ids);
for (Integer wbit : watchers) {
Watcher watcher = watcherBitIdMap.get(wbit);
if (watcher instanceof ServerCnxn) {
ids.add(((ServerCnxn) watcher).getSessionId());
}
}
}
}
return new WatchesPathReport(path2ids);
}
/**
* May cause OOM if there are lots of watches, might better to forbid
* it in this class.
*/
public Map> getWatcher2PathesMap() {
Map> watcher2paths = new HashMap>();
for (Entry e : pathWatches.entrySet()) {
String path = e.getKey();
BitHashSet watchers = e.getValue();
// avoid race condition with add/remove
synchronized (watchers) {
for (Integer wbit : watchers) {
Watcher w = watcherBitIdMap.get(wbit);
if (w == null) {
continue;
}
if (!watcher2paths.containsKey(w)) {
watcher2paths.put(w, new HashSet());
}
watcher2paths.get(w).add(path);
}
}
}
return watcher2paths;
}
@Override
public void dumpWatches(PrintWriter pwriter, boolean byPath) {
if (byPath) {
for (Entry e : pathWatches.entrySet()) {
pwriter.println(e.getKey());
BitHashSet watchers = e.getValue();
synchronized (watchers) {
for (Integer wbit : watchers) {
Watcher w = watcherBitIdMap.get(wbit);
if (!(w instanceof ServerCnxn)) {
continue;
}
pwriter.print("\t0x");
pwriter.print(Long.toHexString(((ServerCnxn) w).getSessionId()));
pwriter.print("\n");
}
}
}
} else {
for (Entry> e : getWatcher2PathesMap().entrySet()) {
pwriter.print("0x");
pwriter.println(Long.toHexString(((ServerCnxn) e.getKey()).getSessionId()));
for (String path : e.getValue()) {
pwriter.print("\t");
pwriter.println(path);
}
}
}
}
@Override
public String toString() {
StringBuilder sb = new StringBuilder();
sb.append(watcherBitIdMap.size()).append(" connections watching ").append(pathSize()).append(" paths\n");
sb.append("Total watches:").append(size());
return sb.toString();
}
}