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/*
 * Copyright 2012 The Netty Project
 *
 * The Netty Project 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.jboss.netty.util;

import org.jboss.netty.channel.ChannelPipelineFactory;
import org.jboss.netty.logging.InternalLogger;
import org.jboss.netty.logging.InternalLoggerFactory;
import org.jboss.netty.util.internal.DetectionUtil;
import org.jboss.netty.util.internal.SharedResourceMisuseDetector;

import java.util.Collections;
import java.util.HashSet;
import java.util.Queue;
import java.util.Set;
import java.util.concurrent.ConcurrentLinkedQueue;
import java.util.concurrent.CountDownLatch;
import java.util.concurrent.Executors;
import java.util.concurrent.ThreadFactory;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicIntegerFieldUpdater;

/**
 * A {@link Timer} optimized for approximated I/O timeout scheduling.
 *
 * 

Tick Duration

* * As described with 'approximated', this timer does not execute the scheduled * {@link TimerTask} on time. {@link HashedWheelTimer}, on every tick, will * check if there are any {@link TimerTask}s behind the schedule and execute * them. *

* You can increase or decrease the accuracy of the execution timing by * specifying smaller or larger tick duration in the constructor. In most * network applications, I/O timeout does not need to be accurate. Therefore, * the default tick duration is 100 milliseconds and you will not need to try * different configurations in most cases. * *

Ticks per Wheel (Wheel Size)

* * {@link HashedWheelTimer} maintains a data structure called 'wheel'. * To put simply, a wheel is a hash table of {@link TimerTask}s whose hash * function is 'dead line of the task'. The default number of ticks per wheel * (i.e. the size of the wheel) is 512. You could specify a larger value * if you are going to schedule a lot of timeouts. * *

Do not create many instances.

* * {@link HashedWheelTimer} creates a new thread whenever it is instantiated and * started. Therefore, you should make sure to create only one instance and * share it across your application. One of the common mistakes, that makes * your application unresponsive, is to create a new instance in * {@link ChannelPipelineFactory}, which results in the creation of a new thread * for every connection. * *

Implementation Details

* * {@link HashedWheelTimer} is based on * George Varghese and * Tony Lauck's paper, * 'Hashed * and Hierarchical Timing Wheels: data structures to efficiently implement a * timer facility'. More comprehensive slides are located * here. */ public class HashedWheelTimer implements Timer { static final InternalLogger logger = InternalLoggerFactory.getInstance(HashedWheelTimer.class); private static final AtomicInteger id = new AtomicInteger(); private static final SharedResourceMisuseDetector misuseDetector = new SharedResourceMisuseDetector(HashedWheelTimer.class); private static final AtomicIntegerFieldUpdater WORKER_STATE_UPDATER = AtomicIntegerFieldUpdater.newUpdater(HashedWheelTimer.class, "workerState"); private final Worker worker = new Worker(); private final Thread workerThread; public static final int WORKER_STATE_INIT = 0; public static final int WORKER_STATE_STARTED = 1; public static final int WORKER_STATE_SHUTDOWN = 2; @SuppressWarnings({ "unused", "FieldMayBeFinal", "RedundantFieldInitialization" }) private volatile int workerState = WORKER_STATE_INIT; // 0 - init, 1 - started, 2 - shut down private final long tickDuration; private final HashedWheelBucket[] wheel; private final int mask; private final CountDownLatch startTimeInitialized = new CountDownLatch(1); private final Queue timeouts = new ConcurrentLinkedQueue(); private volatile long startTime; /** * Creates a new timer with the default thread factory * ({@link Executors#defaultThreadFactory()}), default tick duration, and * default number of ticks per wheel. */ public HashedWheelTimer() { this(Executors.defaultThreadFactory()); } /** * Creates a new timer with the default thread factory * ({@link Executors#defaultThreadFactory()}) and default number of ticks * per wheel. * * @param tickDuration the duration between tick * @param unit the time unit of the {@code tickDuration} */ public HashedWheelTimer(long tickDuration, TimeUnit unit) { this(Executors.defaultThreadFactory(), tickDuration, unit); } /** * Creates a new timer with the default thread factory * ({@link Executors#defaultThreadFactory()}). * * @param tickDuration the duration between tick * @param unit the time unit of the {@code tickDuration} * @param ticksPerWheel the size of the wheel */ public HashedWheelTimer(long tickDuration, TimeUnit unit, int ticksPerWheel) { this(Executors.defaultThreadFactory(), tickDuration, unit, ticksPerWheel); } /** * Creates a new timer with the default tick duration and default number of * ticks per wheel. * * @param threadFactory a {@link ThreadFactory} that creates a * background {@link Thread} which is dedicated to * {@link TimerTask} execution. */ public HashedWheelTimer(ThreadFactory threadFactory) { this(threadFactory, 100, TimeUnit.MILLISECONDS); } /** * Creates a new timer with the default number of ticks per wheel. * * @param threadFactory a {@link ThreadFactory} that creates a * background {@link Thread} which is dedicated to * {@link TimerTask} execution. * @param tickDuration the duration between tick * @param unit the time unit of the {@code tickDuration} */ public HashedWheelTimer( ThreadFactory threadFactory, long tickDuration, TimeUnit unit) { this(threadFactory, tickDuration, unit, 512); } /** * Creates a new timer. * * @param threadFactory a {@link ThreadFactory} that creates a * background {@link Thread} which is dedicated to * {@link TimerTask} execution. * @param tickDuration the duration between tick * @param unit the time unit of the {@code tickDuration} * @param ticksPerWheel the size of the wheel */ public HashedWheelTimer( ThreadFactory threadFactory, long tickDuration, TimeUnit unit, int ticksPerWheel) { this(threadFactory, null, tickDuration, unit, ticksPerWheel); } /** * Creates a new timer. * * @param threadFactory a {@link ThreadFactory} that creates a * background {@link Thread} which is dedicated to * {@link TimerTask} execution. * @param determiner thread name determiner to control thread name. * @param tickDuration the duration between tick * @param unit the time unit of the {@code tickDuration} * @param ticksPerWheel the size of the wheel */ public HashedWheelTimer( ThreadFactory threadFactory, ThreadNameDeterminer determiner, long tickDuration, TimeUnit unit, int ticksPerWheel) { if (threadFactory == null) { throw new NullPointerException("threadFactory"); } if (unit == null) { throw new NullPointerException("unit"); } if (tickDuration <= 0) { throw new IllegalArgumentException( "tickDuration must be greater than 0: " + tickDuration); } if (ticksPerWheel <= 0) { throw new IllegalArgumentException( "ticksPerWheel must be greater than 0: " + ticksPerWheel); } // Normalize ticksPerWheel to power of two and initialize the wheel. wheel = createWheel(ticksPerWheel); mask = wheel.length - 1; // Convert tickDuration to nanos. this.tickDuration = unit.toNanos(tickDuration); // Prevent overflow. if (this.tickDuration >= Long.MAX_VALUE / wheel.length) { throw new IllegalArgumentException(String.format( "tickDuration: %d (expected: 0 < tickDuration in nanos < %d", tickDuration, Long.MAX_VALUE / wheel.length)); } workerThread = threadFactory.newThread(new ThreadRenamingRunnable( worker, "Hashed wheel timer #" + id.incrementAndGet(), determiner)); // Misuse check misuseDetector.increase(); } @SuppressWarnings("unchecked") private static HashedWheelBucket[] createWheel(int ticksPerWheel) { if (ticksPerWheel <= 0) { throw new IllegalArgumentException( "ticksPerWheel must be greater than 0: " + ticksPerWheel); } if (ticksPerWheel > 1073741824) { throw new IllegalArgumentException( "ticksPerWheel may not be greater than 2^30: " + ticksPerWheel); } ticksPerWheel = normalizeTicksPerWheel(ticksPerWheel); HashedWheelBucket[] wheel = new HashedWheelBucket[ticksPerWheel]; for (int i = 0; i < wheel.length; i ++) { wheel[i] = new HashedWheelBucket(); } return wheel; } private static int normalizeTicksPerWheel(int ticksPerWheel) { int normalizedTicksPerWheel = 1; while (normalizedTicksPerWheel < ticksPerWheel) { normalizedTicksPerWheel <<= 1; } return normalizedTicksPerWheel; } /** * Starts the background thread explicitly. The background thread will * start automatically on demand even if you did not call this method. * * @throws IllegalStateException if this timer has been * {@linkplain #stop() stopped} already */ public void start() { switch (WORKER_STATE_UPDATER.get(this)) { case WORKER_STATE_INIT: if (WORKER_STATE_UPDATER.compareAndSet(this, WORKER_STATE_INIT, WORKER_STATE_STARTED)) { workerThread.start(); } break; case WORKER_STATE_STARTED: break; case WORKER_STATE_SHUTDOWN: throw new IllegalStateException("cannot be started once stopped"); default: throw new Error("Invalid WorkerState"); } // Wait until the startTime is initialized by the worker. while (startTime == 0) { try { startTimeInitialized.await(); } catch (InterruptedException ignore) { // Ignore - it will be ready very soon. } } } public Set stop() { if (Thread.currentThread() == workerThread) { throw new IllegalStateException( HashedWheelTimer.class.getSimpleName() + ".stop() cannot be called from " + TimerTask.class.getSimpleName()); } if (!WORKER_STATE_UPDATER.compareAndSet(this, WORKER_STATE_STARTED, WORKER_STATE_SHUTDOWN)) { // workerState can be 0 or 2 at this moment - let it always be 2. WORKER_STATE_UPDATER.set(this, WORKER_STATE_SHUTDOWN); misuseDetector.decrease(); return Collections.emptySet(); } boolean interrupted = false; while (workerThread.isAlive()) { workerThread.interrupt(); try { workerThread.join(100); } catch (InterruptedException e) { interrupted = true; } } if (interrupted) { Thread.currentThread().interrupt(); } misuseDetector.decrease(); return worker.unprocessedTimeouts(); } public Timeout newTimeout(TimerTask task, long delay, TimeUnit unit) { if (task == null) { throw new NullPointerException("task"); } if (unit == null) { throw new NullPointerException("unit"); } start(); // Add the timeout to the timeout queue which will be processed on the next tick. // During processing all the queued HashedWheelTimeouts will be added to the correct HashedWheelBucket. long deadline = System.nanoTime() + unit.toNanos(delay) - startTime; HashedWheelTimeout timeout = new HashedWheelTimeout(this, task, deadline); timeouts.add(timeout); return timeout; } private final class Worker implements Runnable { private final Set unprocessedTimeouts = new HashSet(); private long tick; public void run() { // Initialize the startTime. startTime = System.nanoTime(); if (startTime == 0) { // We use 0 as an indicator for the uninitialized value here, so make sure it's not 0 when initialized. startTime = 1; } // Notify the other threads waiting for the initialization at start(). startTimeInitialized.countDown(); do { final long deadline = waitForNextTick(); if (deadline > 0) { transferTimeoutsToBuckets(); HashedWheelBucket bucket = wheel[(int) (tick & mask)]; bucket.expireTimeouts(deadline); tick++; } } while (WORKER_STATE_UPDATER.get(HashedWheelTimer.this) == WORKER_STATE_STARTED); // Fill the unprocessedTimeouts so we can return them from stop() method. for (HashedWheelBucket bucket: wheel) { bucket.clearTimeouts(unprocessedTimeouts); } for (;;) { HashedWheelTimeout timeout = timeouts.poll(); if (timeout == null) { break; } unprocessedTimeouts.add(timeout); } } private void transferTimeoutsToBuckets() { // transfer only max. 100000 timeouts per tick to prevent a thread to stale the workerThread when it just // adds new timeouts in a loop. for (int i = 0; i < 100000; i++) { HashedWheelTimeout timeout = timeouts.poll(); if (timeout == null) { // all processed break; } if (timeout.state() == HashedWheelTimeout.ST_CANCELLED || !timeout.compareAndSetState(HashedWheelTimeout.ST_INIT, HashedWheelTimeout.ST_IN_BUCKET)) { // Was cancelled in the meantime. So just remove it and continue with next HashedWheelTimeout // in the queue timeout.remove(); continue; } long calculated = timeout.deadline / tickDuration; long remainingRounds = (calculated - tick) / wheel.length; timeout.remainingRounds = remainingRounds; final long ticks = Math.max(calculated, tick); // Ensure we don't schedule for past. int stopIndex = (int) (ticks & mask); HashedWheelBucket bucket = wheel[stopIndex]; bucket.addTimeout(timeout); } } /** * calculate goal nanoTime from startTime and current tick number, * then wait until that goal has been reached. * @return Long.MIN_VALUE if received a shutdown request, * current time otherwise (with Long.MIN_VALUE changed by +1) */ private long waitForNextTick() { long deadline = tickDuration * (tick + 1); for (;;) { final long currentTime = System.nanoTime() - startTime; long sleepTimeMs = (deadline - currentTime + 999999) / 1000000; if (sleepTimeMs <= 0) { if (currentTime == Long.MIN_VALUE) { return -Long.MAX_VALUE; } else { return currentTime; } } // Check if we run on windows, as if thats the case we will need // to round the sleepTime as workaround for a bug that only affect // the JVM if it runs on windows. // // See https://github.com/netty/netty/issues/356 if (DetectionUtil.isWindows()) { sleepTimeMs = sleepTimeMs / 10 * 10; } try { Thread.sleep(sleepTimeMs); } catch (InterruptedException e) { if (WORKER_STATE_UPDATER.get(HashedWheelTimer.this) == WORKER_STATE_SHUTDOWN) { return Long.MIN_VALUE; } } } } public Set unprocessedTimeouts() { return Collections.unmodifiableSet(unprocessedTimeouts); } } private static final class HashedWheelTimeout implements Timeout { private static final int ST_INIT = 0; private static final int ST_IN_BUCKET = 1; private static final int ST_CANCELLED = 2; private static final int ST_EXPIRED = 3; private static final AtomicIntegerFieldUpdater STATE_UPDATER = AtomicIntegerFieldUpdater.newUpdater(HashedWheelTimeout.class, "state"); private final HashedWheelTimer timer; private final TimerTask task; private final long deadline; @SuppressWarnings({"unused", "FieldMayBeFinal", "RedundantFieldInitialization" }) private volatile int state = ST_INIT; // remainingRounds will be calculated and set by Worker.transferTimeoutsToBuckets() before the // HashedWheelTimeout will be added to the correct HashedWheelBucket. long remainingRounds; // This will be used to chain timeouts in HashedWheelTimerBucket via a double-linked-list. // As only the workerThread will act on it there is no need for synchronization / volatile. HashedWheelTimeout next; HashedWheelTimeout prev; // The bucket to which the timeout was added HashedWheelBucket bucket; HashedWheelTimeout(HashedWheelTimer timer, TimerTask task, long deadline) { this.timer = timer; this.task = task; this.deadline = deadline; } public Timer getTimer() { return timer; } public TimerTask getTask() { return task; } public void cancel() { int state = state(); if (state >= ST_CANCELLED) { // fail fast if the task was cancelled or expired before. return; } if (state != ST_IN_BUCKET && compareAndSetState(ST_INIT, ST_CANCELLED)) { // Was cancelled before the HashedWheelTimeout was added to its HashedWheelBucket. // In this case we can just return here as it will be discarded by the WorkerThread when handling // the adding of HashedWheelTimeout to the HashedWheelBuckets. return; } // only update the state it will be removed from HashedWheelBucket on next tick. if (!compareAndSetState(ST_IN_BUCKET, ST_CANCELLED)) { return; } // Add the HashedWheelTimeout back to the timeouts queue so it will be picked up on the next tick // and remove this HashedTimeTask from the HashedWheelBucket. After this is done it is ready to get // GC'ed once the user has no reference to it anymore. timer.timeouts.add(this); } public void remove() { if (bucket != null) { bucket.remove(this); } } public boolean compareAndSetState(int expected, int state) { return STATE_UPDATER.compareAndSet(this, expected, state); } public int state() { return state; } public boolean isCancelled() { return state == ST_CANCELLED; } public boolean isExpired() { return state > ST_IN_BUCKET; } public HashedWheelTimeout value() { return this; } public void expire() { if (!compareAndSetState(ST_IN_BUCKET, ST_EXPIRED)) { assert state() != ST_INIT; return; } try { task.run(this); } catch (Throwable t) { if (logger.isWarnEnabled()) { logger.warn("An exception was thrown by " + TimerTask.class.getSimpleName() + '.', t); } } } @Override public String toString() { final long currentTime = System.nanoTime(); long remaining = deadline - currentTime + timer.startTime; StringBuilder buf = new StringBuilder(192); buf.append(getClass().getSimpleName()); buf.append('('); buf.append("deadline: "); if (remaining > 0) { buf.append(remaining); buf.append(" ns later"); } else if (remaining < 0) { buf.append(-remaining); buf.append(" ns ago"); } else { buf.append("now"); } if (isCancelled()) { buf.append(", cancelled"); } buf.append(", task: "); buf.append(getTask()); return buf.append(')').toString(); } } /** * Bucket that stores HashedWheelTimeouts. These are stored in a linked-list like datastructure to allow easy * removal of HashedWheelTimeouts in the middle. Also the HashedWheelTimeout act as nodes themself and so no * extra object creation is needed. */ private static final class HashedWheelBucket { // Used for the linked-list datastructure private HashedWheelTimeout head; private HashedWheelTimeout tail; /** * Add {@link HashedWheelTimeout} to this bucket. */ public void addTimeout(HashedWheelTimeout timeout) { assert timeout.bucket == null; timeout.bucket = this; if (head == null) { head = tail = timeout; } else { tail.next = timeout; timeout.prev = tail; tail = timeout; } } /** * Expire all {@link HashedWheelTimeout}s for the given {@code deadline}. */ public void expireTimeouts(long deadline) { HashedWheelTimeout timeout = head; // process all timeouts while (timeout != null) { boolean remove = false; if (timeout.remainingRounds <= 0) { if (timeout.deadline <= deadline) { timeout.expire(); } else { // The timeout was placed into a wrong slot. This should never happen. throw new IllegalStateException(String.format( "timeout.deadline (%d) > deadline (%d)", timeout.deadline, deadline)); } remove = true; } else if (timeout.isCancelled()) { remove = true; } else { timeout.remainingRounds --; } // store reference to next as we may null out timeout.next in the remove block. HashedWheelTimeout next = timeout.next; if (remove) { remove(timeout); } timeout = next; } } public void remove(HashedWheelTimeout timeout) { HashedWheelTimeout next = timeout.next; // remove timeout that was either processed or cancelled by updating the linked-list if (timeout.prev != null) { timeout.prev.next = next; } if (timeout.next != null) { timeout.next.prev = timeout.prev; } if (timeout == head) { // if timeout is also the tail we need to adjust the entry too if (timeout == tail) { tail = null; head = null; } else { head = next; } } else if (timeout == tail) { // if the timeout is the tail modify the tail to be the prev node. tail = timeout.prev; } // null out prev, next and bucket to allow for GC. timeout.prev = null; timeout.next = null; timeout.bucket = null; } /** * Clear this bucket and return all not expired / cancelled {@link Timeout}s. */ public void clearTimeouts(Set set) { for (;;) { HashedWheelTimeout timeout = pollTimeout(); if (timeout == null) { return; } if (timeout.isExpired() || timeout.isCancelled()) { continue; } set.add(timeout); } } private HashedWheelTimeout pollTimeout() { HashedWheelTimeout head = this.head; if (head == null) { return null; } HashedWheelTimeout next = head.next; if (next == null) { tail = this.head = null; } else { this.head = next; next.prev = null; } // null out prev and next to allow for GC. head.next = null; head.prev = null; return head; } } }




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