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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 io.netty.handler.timeout;

import io.netty.bootstrap.ServerBootstrap;
import io.netty.channel.Channel;
import io.netty.channel.Channel.Unsafe;
import io.netty.channel.ChannelDuplexHandler;
import io.netty.channel.ChannelFuture;
import io.netty.channel.ChannelFutureListener;
import io.netty.channel.ChannelHandlerContext;
import io.netty.channel.ChannelInitializer;
import io.netty.channel.ChannelOutboundBuffer;
import io.netty.channel.ChannelPromise;
import io.netty.util.concurrent.EventExecutor;

import java.util.concurrent.ScheduledFuture;
import java.util.concurrent.TimeUnit;

/**
 * Triggers an {@link IdleStateEvent} when a {@link Channel} has not performed
 * read, write, or both operation for a while.
 *
 * 

Supported idle states

* * * * * * * * * * * * * * * * *
PropertyMeaning
{@code readerIdleTime}an {@link IdleStateEvent} whose state is {@link IdleState#READER_IDLE} * will be triggered when no read was performed for the specified period of * time. Specify {@code 0} to disable.
{@code writerIdleTime}an {@link IdleStateEvent} whose state is {@link IdleState#WRITER_IDLE} * will be triggered when no write was performed for the specified period of * time. Specify {@code 0} to disable.
{@code allIdleTime}an {@link IdleStateEvent} whose state is {@link IdleState#ALL_IDLE} * will be triggered when neither read nor write was performed for the * specified period of time. Specify {@code 0} to disable.
* *
 * // An example that sends a ping message when there is no outbound traffic
 * // for 30 seconds.  The connection is closed when there is no inbound traffic
 * // for 60 seconds.
 *
 * public class MyChannelInitializer extends {@link ChannelInitializer}<{@link Channel}> {
 *     {@code @Override}
 *     public void initChannel({@link Channel} channel) {
 *         channel.pipeline().addLast("idleStateHandler", new {@link IdleStateHandler}(60, 30, 0));
 *         channel.pipeline().addLast("myHandler", new MyHandler());
 *     }
 * }
 *
 * // Handler should handle the {@link IdleStateEvent} triggered by {@link IdleStateHandler}.
 * public class MyHandler extends {@link ChannelDuplexHandler} {
 *     {@code @Override}
 *     public void userEventTriggered({@link ChannelHandlerContext} ctx, {@link Object} evt) throws {@link Exception} {
 *         if (evt instanceof {@link IdleStateEvent}) {
 *             {@link IdleStateEvent} e = ({@link IdleStateEvent}) evt;
 *             if (e.state() == {@link IdleState}.READER_IDLE) {
 *                 ctx.close();
 *             } else if (e.state() == {@link IdleState}.WRITER_IDLE) {
 *                 ctx.writeAndFlush(new PingMessage());
 *             }
 *         }
 *     }
 * }
 *
 * {@link ServerBootstrap} bootstrap = ...;
 * ...
 * bootstrap.childHandler(new MyChannelInitializer());
 * ...
 * 
* * @see ReadTimeoutHandler * @see WriteTimeoutHandler */ public class IdleStateHandler extends ChannelDuplexHandler { private static final long MIN_TIMEOUT_NANOS = TimeUnit.MILLISECONDS.toNanos(1); // Not create a new ChannelFutureListener per write operation to reduce GC pressure. private final ChannelFutureListener writeListener = new ChannelFutureListener() { @Override public void operationComplete(ChannelFuture future) throws Exception { lastWriteTime = ticksInNanos(); firstWriterIdleEvent = firstAllIdleEvent = true; } }; private final boolean observeOutput; private final long readerIdleTimeNanos; private final long writerIdleTimeNanos; private final long allIdleTimeNanos; private ScheduledFuture readerIdleTimeout; private long lastReadTime; private boolean firstReaderIdleEvent = true; private ScheduledFuture writerIdleTimeout; private long lastWriteTime; private boolean firstWriterIdleEvent = true; private ScheduledFuture allIdleTimeout; private boolean firstAllIdleEvent = true; private byte state; // 0 - none, 1 - initialized, 2 - destroyed private boolean reading; private long lastChangeCheckTimeStamp; private int lastMessageHashCode; private long lastPendingWriteBytes; /** * Creates a new instance firing {@link IdleStateEvent}s. * * @param readerIdleTimeSeconds * an {@link IdleStateEvent} whose state is {@link IdleState#READER_IDLE} * will be triggered when no read was performed for the specified * period of time. Specify {@code 0} to disable. * @param writerIdleTimeSeconds * an {@link IdleStateEvent} whose state is {@link IdleState#WRITER_IDLE} * will be triggered when no write was performed for the specified * period of time. Specify {@code 0} to disable. * @param allIdleTimeSeconds * an {@link IdleStateEvent} whose state is {@link IdleState#ALL_IDLE} * will be triggered when neither read nor write was performed for * the specified period of time. Specify {@code 0} to disable. */ public IdleStateHandler( int readerIdleTimeSeconds, int writerIdleTimeSeconds, int allIdleTimeSeconds) { this(readerIdleTimeSeconds, writerIdleTimeSeconds, allIdleTimeSeconds, TimeUnit.SECONDS); } /** * @see #IdleStateHandler(boolean, long, long, long, TimeUnit) */ public IdleStateHandler( long readerIdleTime, long writerIdleTime, long allIdleTime, TimeUnit unit) { this(false, readerIdleTime, writerIdleTime, allIdleTime, unit); } /** * Creates a new instance firing {@link IdleStateEvent}s. * * @param observeOutput * whether or not the consumption of {@code bytes} should be taken into * consideration when assessing write idleness. The default is {@code false}. * @param readerIdleTime * an {@link IdleStateEvent} whose state is {@link IdleState#READER_IDLE} * will be triggered when no read was performed for the specified * period of time. Specify {@code 0} to disable. * @param writerIdleTime * an {@link IdleStateEvent} whose state is {@link IdleState#WRITER_IDLE} * will be triggered when no write was performed for the specified * period of time. Specify {@code 0} to disable. * @param allIdleTime * an {@link IdleStateEvent} whose state is {@link IdleState#ALL_IDLE} * will be triggered when neither read nor write was performed for * the specified period of time. Specify {@code 0} to disable. * @param unit * the {@link TimeUnit} of {@code readerIdleTime}, * {@code writeIdleTime}, and {@code allIdleTime} */ public IdleStateHandler(boolean observeOutput, long readerIdleTime, long writerIdleTime, long allIdleTime, TimeUnit unit) { if (unit == null) { throw new NullPointerException("unit"); } this.observeOutput = observeOutput; if (readerIdleTime <= 0) { readerIdleTimeNanos = 0; } else { readerIdleTimeNanos = Math.max(unit.toNanos(readerIdleTime), MIN_TIMEOUT_NANOS); } if (writerIdleTime <= 0) { writerIdleTimeNanos = 0; } else { writerIdleTimeNanos = Math.max(unit.toNanos(writerIdleTime), MIN_TIMEOUT_NANOS); } if (allIdleTime <= 0) { allIdleTimeNanos = 0; } else { allIdleTimeNanos = Math.max(unit.toNanos(allIdleTime), MIN_TIMEOUT_NANOS); } } /** * Return the readerIdleTime that was given when instance this class in milliseconds. * */ public long getReaderIdleTimeInMillis() { return TimeUnit.NANOSECONDS.toMillis(readerIdleTimeNanos); } /** * Return the writerIdleTime that was given when instance this class in milliseconds. * */ public long getWriterIdleTimeInMillis() { return TimeUnit.NANOSECONDS.toMillis(writerIdleTimeNanos); } /** * Return the allIdleTime that was given when instance this class in milliseconds. * */ public long getAllIdleTimeInMillis() { return TimeUnit.NANOSECONDS.toMillis(allIdleTimeNanos); } @Override public void handlerAdded(ChannelHandlerContext ctx) throws Exception { if (ctx.channel().isActive() && ctx.channel().isRegistered()) { // channelActive() event has been fired already, which means this.channelActive() will // not be invoked. We have to initialize here instead. initialize(ctx); } else { // channelActive() event has not been fired yet. this.channelActive() will be invoked // and initialization will occur there. } } @Override public void handlerRemoved(ChannelHandlerContext ctx) throws Exception { destroy(); } @Override public void channelRegistered(ChannelHandlerContext ctx) throws Exception { // Initialize early if channel is active already. if (ctx.channel().isActive()) { initialize(ctx); } super.channelRegistered(ctx); } @Override public void channelActive(ChannelHandlerContext ctx) throws Exception { // This method will be invoked only if this handler was added // before channelActive() event is fired. If a user adds this handler // after the channelActive() event, initialize() will be called by beforeAdd(). initialize(ctx); super.channelActive(ctx); } @Override public void channelInactive(ChannelHandlerContext ctx) throws Exception { destroy(); super.channelInactive(ctx); } @Override public void channelRead(ChannelHandlerContext ctx, Object msg) throws Exception { if (readerIdleTimeNanos > 0 || allIdleTimeNanos > 0) { reading = true; firstReaderIdleEvent = firstAllIdleEvent = true; } ctx.fireChannelRead(msg); } @Override public void channelReadComplete(ChannelHandlerContext ctx) throws Exception { if ((readerIdleTimeNanos > 0 || allIdleTimeNanos > 0) && reading) { lastReadTime = ticksInNanos(); reading = false; } ctx.fireChannelReadComplete(); } @Override public void write(ChannelHandlerContext ctx, Object msg, ChannelPromise promise) throws Exception { // Allow writing with void promise if handler is only configured for read timeout events. if (writerIdleTimeNanos > 0 || allIdleTimeNanos > 0) { promise.addListener(writeListener); } ctx.write(msg, promise); } private void initialize(ChannelHandlerContext ctx) { // Avoid the case where destroy() is called before scheduling timeouts. // See: https://github.com/netty/netty/issues/143 switch (state) { case 1: case 2: return; } state = 1; initOutputChanged(ctx); lastReadTime = lastWriteTime = ticksInNanos(); if (readerIdleTimeNanos > 0) { readerIdleTimeout = schedule(ctx, new ReaderIdleTimeoutTask(ctx), readerIdleTimeNanos, TimeUnit.NANOSECONDS); } if (writerIdleTimeNanos > 0) { writerIdleTimeout = schedule(ctx, new WriterIdleTimeoutTask(ctx), writerIdleTimeNanos, TimeUnit.NANOSECONDS); } if (allIdleTimeNanos > 0) { allIdleTimeout = schedule(ctx, new AllIdleTimeoutTask(ctx), allIdleTimeNanos, TimeUnit.NANOSECONDS); } } /** * This method is visible for testing! */ long ticksInNanos() { return System.nanoTime(); } /** * This method is visible for testing! */ ScheduledFuture schedule(ChannelHandlerContext ctx, Runnable task, long delay, TimeUnit unit) { return ctx.executor().schedule(task, delay, unit); } private void destroy() { state = 2; if (readerIdleTimeout != null) { readerIdleTimeout.cancel(false); readerIdleTimeout = null; } if (writerIdleTimeout != null) { writerIdleTimeout.cancel(false); writerIdleTimeout = null; } if (allIdleTimeout != null) { allIdleTimeout.cancel(false); allIdleTimeout = null; } } /** * Is called when an {@link IdleStateEvent} should be fired. This implementation calls * {@link ChannelHandlerContext#fireUserEventTriggered(Object)}. */ protected void channelIdle(ChannelHandlerContext ctx, IdleStateEvent evt) throws Exception { ctx.fireUserEventTriggered(evt); } /** * Returns a {@link IdleStateEvent}. */ protected IdleStateEvent newIdleStateEvent(IdleState state, boolean first) { switch (state) { case ALL_IDLE: return first ? IdleStateEvent.FIRST_ALL_IDLE_STATE_EVENT : IdleStateEvent.ALL_IDLE_STATE_EVENT; case READER_IDLE: return first ? IdleStateEvent.FIRST_READER_IDLE_STATE_EVENT : IdleStateEvent.READER_IDLE_STATE_EVENT; case WRITER_IDLE: return first ? IdleStateEvent.FIRST_WRITER_IDLE_STATE_EVENT : IdleStateEvent.WRITER_IDLE_STATE_EVENT; default: throw new IllegalArgumentException("Unhandled: state=" + state + ", first=" + first); } } /** * @see #hasOutputChanged(ChannelHandlerContext, boolean) */ private void initOutputChanged(ChannelHandlerContext ctx) { if (observeOutput) { Channel channel = ctx.channel(); Unsafe unsafe = channel.unsafe(); ChannelOutboundBuffer buf = unsafe.outboundBuffer(); if (buf != null) { lastMessageHashCode = System.identityHashCode(buf.current()); lastPendingWriteBytes = buf.totalPendingWriteBytes(); } } } /** * Returns {@code true} if and only if the {@link IdleStateHandler} was constructed * with {@link #observeOutput} enabled and there has been an observed change in the * {@link ChannelOutboundBuffer} between two consecutive calls of this method. * * https://github.com/netty/netty/issues/6150 */ private boolean hasOutputChanged(ChannelHandlerContext ctx, boolean first) { if (observeOutput) { // We can take this shortcut if the ChannelPromises that got passed into write() // appear to complete. It indicates "change" on message level and we simply assume // that there's change happening on byte level. If the user doesn't observe channel // writability events then they'll eventually OOME and there's clearly a different // problem and idleness is least of their concerns. if (lastChangeCheckTimeStamp != lastWriteTime) { lastChangeCheckTimeStamp = lastWriteTime; // But this applies only if it's the non-first call. if (!first) { return true; } } Channel channel = ctx.channel(); Unsafe unsafe = channel.unsafe(); ChannelOutboundBuffer buf = unsafe.outboundBuffer(); if (buf != null) { int messageHashCode = System.identityHashCode(buf.current()); long pendingWriteBytes = buf.totalPendingWriteBytes(); if (messageHashCode != lastMessageHashCode || pendingWriteBytes != lastPendingWriteBytes) { lastMessageHashCode = messageHashCode; lastPendingWriteBytes = pendingWriteBytes; if (!first) { return true; } } } } return false; } private abstract static class AbstractIdleTask implements Runnable { private final ChannelHandlerContext ctx; AbstractIdleTask(ChannelHandlerContext ctx) { this.ctx = ctx; } @Override public void run() { if (!ctx.channel().isOpen()) { return; } run(ctx); } protected abstract void run(ChannelHandlerContext ctx); } private final class ReaderIdleTimeoutTask extends AbstractIdleTask { ReaderIdleTimeoutTask(ChannelHandlerContext ctx) { super(ctx); } @Override protected void run(ChannelHandlerContext ctx) { long nextDelay = readerIdleTimeNanos; if (!reading) { nextDelay -= ticksInNanos() - lastReadTime; } if (nextDelay <= 0) { // Reader is idle - set a new timeout and notify the callback. readerIdleTimeout = schedule(ctx, this, readerIdleTimeNanos, TimeUnit.NANOSECONDS); boolean first = firstReaderIdleEvent; firstReaderIdleEvent = false; try { IdleStateEvent event = newIdleStateEvent(IdleState.READER_IDLE, first); channelIdle(ctx, event); } catch (Throwable t) { ctx.fireExceptionCaught(t); } } else { // Read occurred before the timeout - set a new timeout with shorter delay. readerIdleTimeout = schedule(ctx, this, nextDelay, TimeUnit.NANOSECONDS); } } } private final class WriterIdleTimeoutTask extends AbstractIdleTask { WriterIdleTimeoutTask(ChannelHandlerContext ctx) { super(ctx); } @Override protected void run(ChannelHandlerContext ctx) { long lastWriteTime = IdleStateHandler.this.lastWriteTime; long nextDelay = writerIdleTimeNanos - (ticksInNanos() - lastWriteTime); if (nextDelay <= 0) { // Writer is idle - set a new timeout and notify the callback. writerIdleTimeout = schedule(ctx, this, writerIdleTimeNanos, TimeUnit.NANOSECONDS); boolean first = firstWriterIdleEvent; firstWriterIdleEvent = false; try { if (hasOutputChanged(ctx, first)) { return; } IdleStateEvent event = newIdleStateEvent(IdleState.WRITER_IDLE, first); channelIdle(ctx, event); } catch (Throwable t) { ctx.fireExceptionCaught(t); } } else { // Write occurred before the timeout - set a new timeout with shorter delay. writerIdleTimeout = schedule(ctx, this, nextDelay, TimeUnit.NANOSECONDS); } } } private final class AllIdleTimeoutTask extends AbstractIdleTask { AllIdleTimeoutTask(ChannelHandlerContext ctx) { super(ctx); } @Override protected void run(ChannelHandlerContext ctx) { long nextDelay = allIdleTimeNanos; if (!reading) { nextDelay -= ticksInNanos() - Math.max(lastReadTime, lastWriteTime); } if (nextDelay <= 0) { // Both reader and writer are idle - set a new timeout and // notify the callback. allIdleTimeout = schedule(ctx, this, allIdleTimeNanos, TimeUnit.NANOSECONDS); boolean first = firstAllIdleEvent; firstAllIdleEvent = false; try { if (hasOutputChanged(ctx, first)) { return; } IdleStateEvent event = newIdleStateEvent(IdleState.ALL_IDLE, first); channelIdle(ctx, event); } catch (Throwable t) { ctx.fireExceptionCaught(t); } } else { // Either read or write occurred before the timeout - set a new // timeout with shorter delay. allIdleTimeout = schedule(ctx, this, nextDelay, TimeUnit.NANOSECONDS); } } } }




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