io.netty.handler.traffic.ChannelTrafficShapingHandler Maven / Gradle / Ivy
/*
* 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:
*
* https://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.traffic;
import io.netty.buffer.ByteBuf;
import io.netty.channel.ChannelHandlerContext;
import io.netty.channel.ChannelPromise;
import java.util.ArrayDeque;
import java.util.concurrent.TimeUnit;
/**
* This implementation of the {@link AbstractTrafficShapingHandler} is for channel
* traffic shaping, that is to say a per channel limitation of the bandwidth.
* Note the index used in {@code OutboundBuffer.setUserDefinedWritability(index, boolean)} is 1.
*
* The general use should be as follow:
*
* Add in your pipeline a new ChannelTrafficShapingHandler.
* ChannelTrafficShapingHandler myHandler = new ChannelTrafficShapingHandler();
* pipeline.addLast(myHandler);
*
* Note that this handler has a Pipeline Coverage of "one" which means a new handler must be created
* for each new channel as the counter cannot be shared among all channels..
*
* Other arguments can be passed like write or read limitation (in bytes/s where 0 means no limitation)
* or the check interval (in millisecond) that represents the delay between two computations of the
* bandwidth and so the call back of the doAccounting method (0 means no accounting at all).
*
* A value of 0 means no accounting for checkInterval. If you need traffic shaping but no such accounting,
* it is recommended to set a positive value, even if it is high since the precision of the
* Traffic Shaping depends on the period where the traffic is computed. The highest the interval,
* the less precise the traffic shaping will be. It is suggested as higher value something close
* to 5 or 10 minutes.
*
* maxTimeToWait, by default set to 15s, allows to specify an upper bound of time shaping.
* - In your handler, you should consider to use the {@code channel.isWritable()} and
* {@code channelWritabilityChanged(ctx)} to handle writability, or through
* {@code future.addListener(new GenericFutureListener())} on the future returned by
* {@code ctx.write()}.
* You shall also consider to have object size in read or write operations relatively adapted to
* the bandwidth you required: for instance having 10 MB objects for 10KB/s will lead to burst effect,
* while having 100 KB objects for 1 MB/s should be smoothly handle by this TrafficShaping handler.
Some configuration methods will be taken as best effort, meaning
* that all already scheduled traffics will not be
* changed, but only applied to new traffics.
* So the expected usage of those methods are to be used not too often,
* accordingly to the traffic shaping configuration.
*/
public class ChannelTrafficShapingHandler extends AbstractTrafficShapingHandler {
private final ArrayDeque messagesQueue = new ArrayDeque();
private long queueSize;
/**
* Create a new instance.
*
* @param writeLimit
* 0 or a limit in bytes/s
* @param readLimit
* 0 or a limit in bytes/s
* @param checkInterval
* The delay between two computations of performances for
* channels or 0 if no stats are to be computed.
* @param maxTime
* The maximum delay to wait in case of traffic excess.
*/
public ChannelTrafficShapingHandler(long writeLimit, long readLimit,
long checkInterval, long maxTime) {
super(writeLimit, readLimit, checkInterval, maxTime);
}
/**
* Create a new instance using default
* max time as delay allowed value of 15000 ms.
*
* @param writeLimit
* 0 or a limit in bytes/s
* @param readLimit
* 0 or a limit in bytes/s
* @param checkInterval
* The delay between two computations of performances for
* channels or 0 if no stats are to be computed.
*/
public ChannelTrafficShapingHandler(long writeLimit,
long readLimit, long checkInterval) {
super(writeLimit, readLimit, checkInterval);
}
/**
* Create a new instance using default Check Interval value of 1000 ms and
* max time as delay allowed value of 15000 ms.
*
* @param writeLimit
* 0 or a limit in bytes/s
* @param readLimit
* 0 or a limit in bytes/s
*/
public ChannelTrafficShapingHandler(long writeLimit,
long readLimit) {
super(writeLimit, readLimit);
}
/**
* Create a new instance using
* default max time as delay allowed value of 15000 ms and no limit.
*
* @param checkInterval
* The delay between two computations of performances for
* channels or 0 if no stats are to be computed.
*/
public ChannelTrafficShapingHandler(long checkInterval) {
super(checkInterval);
}
@Override
public void handlerAdded(ChannelHandlerContext ctx) throws Exception {
TrafficCounter trafficCounter = new TrafficCounter(this, ctx.executor(), "ChannelTC" +
ctx.channel().hashCode(), checkInterval);
setTrafficCounter(trafficCounter);
trafficCounter.start();
super.handlerAdded(ctx);
}
@Override
public void handlerRemoved(ChannelHandlerContext ctx) throws Exception {
trafficCounter.stop();
// write order control
synchronized (this) {
if (ctx.channel().isActive()) {
for (ToSend toSend : messagesQueue) {
long size = calculateSize(toSend.toSend);
trafficCounter.bytesRealWriteFlowControl(size);
queueSize -= size;
ctx.write(toSend.toSend, toSend.promise);
}
} else {
for (ToSend toSend : messagesQueue) {
if (toSend.toSend instanceof ByteBuf) {
((ByteBuf) toSend.toSend).release();
}
}
}
messagesQueue.clear();
}
releaseWriteSuspended(ctx);
releaseReadSuspended(ctx);
super.handlerRemoved(ctx);
}
private static final class ToSend {
final long relativeTimeAction;
final Object toSend;
final ChannelPromise promise;
private ToSend(final long delay, final Object toSend, final ChannelPromise promise) {
relativeTimeAction = delay;
this.toSend = toSend;
this.promise = promise;
}
}
@Override
void submitWrite(final ChannelHandlerContext ctx, final Object msg,
final long size, final long delay, final long now,
final ChannelPromise promise) {
final ToSend newToSend;
// write order control
synchronized (this) {
if (delay == 0 && messagesQueue.isEmpty()) {
trafficCounter.bytesRealWriteFlowControl(size);
ctx.write(msg, promise);
return;
}
newToSend = new ToSend(delay + now, msg, promise);
messagesQueue.addLast(newToSend);
queueSize += size;
checkWriteSuspend(ctx, delay, queueSize);
}
final long futureNow = newToSend.relativeTimeAction;
ctx.executor().schedule(new Runnable() {
@Override
public void run() {
sendAllValid(ctx, futureNow);
}
}, delay, TimeUnit.MILLISECONDS);
}
private void sendAllValid(final ChannelHandlerContext ctx, final long now) {
// write order control
synchronized (this) {
ToSend newToSend = messagesQueue.pollFirst();
for (; newToSend != null; newToSend = messagesQueue.pollFirst()) {
if (newToSend.relativeTimeAction <= now) {
long size = calculateSize(newToSend.toSend);
trafficCounter.bytesRealWriteFlowControl(size);
queueSize -= size;
ctx.write(newToSend.toSend, newToSend.promise);
} else {
messagesQueue.addFirst(newToSend);
break;
}
}
if (messagesQueue.isEmpty()) {
releaseWriteSuspended(ctx);
}
}
ctx.flush();
}
/**
* @return current size in bytes of the write buffer.
*/
public long queueSize() {
return queueSize;
}
}