前言
每一种该语言在某些极限情况下的表现一般都不太一样,那么我常用的Java语言,在达到100万个并发连接情况下,会怎么样呢,有些好奇,更有些期盼。
这次使用经常使用的顺手的netty NIO框架(netty-3.6.5.Final),封装的很好,接口很全面,就像它现在的域名 netty.io,专注于网络IO。
整个过程没有什么技术含量,浅显分析过就更显得有些枯燥无聊,准备好,硬着头皮吧。
测试服务器配置
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运行在VMWare Workstation 9中,64位Centos 6.2系统,分配14.9G内存左右,4核。
已安装有Java7版本:
java version "1.7.0_21" Java(TM) SE Runtime Environment (build 1.7.0_21-b11) Java HotSpot(TM) 64-Bit Server VM (build 23.21-b01, mixed mode)
在/etc/sysctl.conf中添加如下配置:
fs.file-max = 1048576 net.ipv4.ip_local_port_range = 1024 65535 net.ipv4.tcp_mem = 786432 2097152 3145728 net.ipv4.tcp_rmem = 4096 4096 16777216 net.ipv4.tcp_wmem = 4096 4096 16777216 net.ipv4.tcp_tw_reuse = 1 net.ipv4.tcp_tw_recycle = 1
在/etc/security/limits.conf中添加如下配置:
* soft nofile 1048576 * hard nofile 1048576
测试端
测试端无论是配置还是程序和以前一样,翻看前几篇博客就可以看到client5.c的源码,以及相关的配置信息等。
服务器程序
这次也是很简单呐,没有业务功能,客户端HTTP请求,服务端输出chunked编码内容。
入口HttpChunkedServer.java:
package com.test.server; import static org.jboss.netty.channel.Channels.pipeline; import java.net.InetSocketAddress; import java.util.concurrent.Executors; import org.jboss.netty.bootstrap.ServerBootstrap; import org.jboss.netty.channel.ChannelPipeline; import org.jboss.netty.channel.ChannelPipelineFactory; import org.jboss.netty.channel.socket.nio.NioServerSocketChannelFactory; import org.jboss.netty.handler.codec.http.HttpChunkAggregator; import org.jboss.netty.handler.codec.http.HttpRequestDecoder; import org.jboss.netty.handler.codec.http.HttpResponseEncoder; import org.jboss.netty.handler.stream.ChunkedWriteHandler; public class HttpChunkedServer { private final int port; public HttpChunkedServer(intport) { this.port = port; } public void run() { // Configure the server. ServerBootstrap bootstrap = new ServerBootstrap( new NioServerSocketChannelFactory( Executors.newCachedThreadPool(), Executors.newCachedThreadPool())); // Set up the event pipeline factory. bootstrap.setPipelineFactory(newChannelPipelineFactory() { public ChannelPipeline getPipeline ()throws Exception { ChannelPipeline pipeline = pipeline(); pipeline.addLast("decoder", new HttpRequestDecoder()); pipeline.addLast("aggregator", new HttpChunkAggregator(65536)); pipeline.addLast("encoder", new HttpResponseEncoder()); pipeline.addLast("chunkedWriter", new ChunkedWriteHandler()); pipeline.addLast("handler", new HttpChunkedServerHandler()); return pipeline; } }); bootstrap.setOption("child.reuseAddress", true); bootstrap.setOption("child.tcpNoDelay", true); bootstrap.setOption("child.keepAlive", true); // Bind and start to accept incoming connections. bootstrap.bind(newInetSocketAddress(port)); } public static void main(String[] args) { int port; if (args.length > 0) { port = Integer.parseInt(args[0]); } else { port = 8080; } System.out.format("server start with port %d ", port); new HttpChunkedServer(port).run(); } }
唯一的自定义处理器HttpChunkedServerHandler.java:
package com.test.server; import static org.jboss.netty.handler.codec.http.HttpHeaders.Names.CONTENT_TYPE; import static org.jboss.netty.handler.codec.http.HttpMethod.GET; import static org.jboss.netty.handler.codec.http.HttpResponseStatus.BAD_REQUEST; import static org.jboss.netty.handler.codec.http.HttpResponseStatus.METHOD_NOT_ALLOWED; import static org.jboss.netty.handler.codec.http.HttpResponseStatus.OK; import static org.jboss.netty.handler.codec.http.HttpVersion.HTTP_1_1; import java.util.concurrent.atomic.AtomicInteger; import org.jboss.netty.buffer.ChannelBuffer; import org.jboss.netty.buffer.ChannelBuffers; import org.jboss.netty.channel.Channel; import org.jboss.netty.channel.ChannelFutureListener; import org.jboss.netty.channel.ChannelHandlerContext; import org.jboss.netty.channel.ChannelStateEvent; import org.jboss.netty.channel.ExceptionEvent; import org.jboss.netty.channel.MessageEvent; import org.jboss.netty.channel.SimpleChannelUpstreamHandler; import org.jboss.netty.handler.codec.frame.TooLongFrameException; import org.jboss.netty.handler.codec.http.DefaultHttpChunk; import org.jboss.netty.handler.codec.http.DefaultHttpResponse; import org.jboss.netty.handler.codec.http.HttpChunk; import org.jboss.netty.handler.codec.http.HttpHeaders; import org.jboss.netty.handler.codec.http.HttpRequest; import org.jboss.netty.handler.codec.http.HttpResponse; import org.jboss.netty.handler.codec.http.HttpResponseStatus; import org.jboss.netty.util.CharsetUtil; public class HttpChunkedServerHandlerextends SimpleChannelUpstreamHandler { private static final AtomicInteger count = new AtomicInteger(0); private void increment() { System.out.format("online user %d ", count.incrementAndGet()); } private void decrement() { if (count.get() <= 0) { System.out.format("~online user %d ", 0); } else { System.out.format("~online user %d ", count.decrementAndGet()); } } @Override public void messageReceived(ChannelHandlerContextctx, MessageEvent e) throws Exception { HttpRequest request = (HttpRequest) e.getMessage(); if (request.getMethod() != GET) { sendError(ctx, METHOD_NOT_ALLOWED); return; } sendPrepare(ctx); increment(); } @Override public void channelDisconnected(ChannelHandlerContextctx, ChannelStateEvent e) throws Exception { decrement(); super.channelDisconnected(ctx, e); } @Override public void exceptionCaught(ChannelHandlerContextctx, ExceptionEvent e) throws Exception { Throwable cause = e.getCause(); if (cause instanceof TooLongFrameException) { sendError(ctx, BAD_REQUEST); return; } } private static void sendError(ChannelHandlerContext ctx, HttpResponseStatus status) { HttpResponse response = new DefaultHttpResponse(HTTP_1_1, status); response.setHeader(CONTENT_TYPE, "text/plain; charset=UTF-8"); response.setContent(ChannelBuffers.copiedBuffer( "Failure:" + status.toString() + " ", CharsetUtil.UTF_8)); // Close the connection as soon as the error message is sent. ctx.getChannel().write(response) .addListener(ChannelFutureListener.CLOSE); } private void sendPrepare(ChannelHandlerContextctx) { HttpResponse response = new DefaultHttpResponse(HTTP_1_1, OK); response.setChunked(true); response.setHeader(HttpHeaders.Names.CONTENT_TYPE, "text/html; charset=UTF-8"); response.addHeader(HttpHeaders.Names.CONNECTION, HttpHeaders.Values.KEEP_ALIVE); response.setHeader(HttpHeaders.Names.TRANSFER_ENCODING, HttpHeaders.Values.CHUNKED); Channel chan = ctx.getChannel(); chan.write(response); // 缓冲必须凑够256字节,浏览器端才能够正常接收 ... StringBuilder builder = new StringBuilder(); builder.append(""); int leftChars = 256 - builder.length(); for (int i = 0; i < leftChars; i++) { builder.append(""); } writeStringChunk(chan, builder.toString()); } private void writeStringChunk(Channelchannel, String data) { ChannelBuffer chunkContent = ChannelBuffers.dynamicBuffer(channel .getConfig().getBufferFactory()); chunkContent.writeBytes(data.getBytes()); HttpChunk chunk = new DefaultHttpChunk(chunkContent); channel.write(chunk); } }
启动脚本start.sh
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set CLASSPATH=. nohup java -server -Xmx6G -Xms6G -Xmn600M -XX:PermSize=50M -XX:MaxPermSize=50M -Xss256K -XX:+DisableExplicitGC -XX:SurvivorRatio=1 -XX:+UseConcMarkSweepGC -XX:+UseParNewGC -XX:+CMSParallelRemarkEnabled -XX:+UseCMSCompactAtFullCollection -XX:CMSFullGCsBeforeCompaction=0 -XX:+CMSClassUnloadingEnabled -XX:LargePageSizeInBytes=128M -XX:+UseFastAccessorMethods -XX:+UseCMSInitiatingOccupancyOnly -XX:CMSInitiatingOccupancyFraction=80 -XX:SoftRefLRUPolicyMSPerMB=0 -XX:+PrintClassHistogram -XX:+PrintGCDetails -XX:+PrintGCTimeStamps -XX:+PrintHeapAtGC -Xloggc:gc.log -Djava.ext.dirs=lib com.test.server.HttpChunkedServer 8000>server.out 2>&1 &
达到100万并发连接时的一些信息
每次服务器端达到一百万个并发持久连接之后,然后关掉测试端程序,断开所有的连接,等到服务器端日志输出在线用户为0时,再次重复以上步骤。在这反反复复的情况下,观察内存等信息的一些情况。以某次断开所有测试端为例后,当前系统占用为(设置为list_free_1):
total used free shared buffers cached Mem: 15189 7736 7453 0 18 120 -/+ buffers/cache: 7597 7592 Swap: 4095 948 3147
通过top观察,其进程相关信息
PID USER PR NI VIRT RES SHR S %CPU %MEM TIME+ COMMAND 4925 root 20 0 8206m 4.3g 2776 S 0.3 28.8 50:18.66 java
在启动脚本start.sh中,我们设置堆内存为6G。
ps aux|grep java命令获得信息:
root 4925 38.0 28.8 8403444 4484764 ? Sl 15:26 50:18 java -server...HttpChunkedServer 8000
RSS占用内存为4484764K/1024K=4379M
然后再次启动测试端,在服务器接收到online user 1023749时,ps aux|grep java内容为:
root 4925 43.6 28.4 8403444 4422824 ? Sl 15:26 62:53 java -server...
查看当前网络信息统计
ss -s Total: 1024050 (kernel 1024084) TCP: 1023769 (estab 1023754, closed 2, orphaned 0, synrecv 0, timewait 0/0), ports 12 Transport Total IP IPv6 * 1024084 - - RAW 0 0 0 UDP 7 6 1 TCP 1023767 12 1023755 INET 1023774 18 1023756 FRAG 0 0 0
通过top查看一下
top -p 4925 top - 17:51:30 up 3:02, 4 users, load average: 1.03, 1.80, 1.19 Tasks: 1 total, 0 running, 1 sleeping, 0 stopped, 0 zombie Cpu0 : 0.9%us, 2.6%sy, 0.0%ni, 52.9%id, 1.0%wa, 13.6%hi, 29.0%si, 0.0%st Cpu1 : 1.4%us, 4.5%sy, 0.0%ni, 80.1%id, 1.9%wa, 0.0%hi, 12.0%si, 0.0%st Cpu2 : 1.5%us, 4.4%sy, 0.0%ni, 80.5%id, 4.3%wa, 0.0%hi, 9.3%si, 0.0%st Cpu3 : 1.9%us, 4.4%sy, 0.0%ni, 84.4%id, 3.2%wa, 0.0%hi, 6.2%si, 0.0%st Mem: 15554336k total, 15268728k used, 285608k free, 3904k buffers Swap: 4194296k total, 1082592k used, 3111704k free, 37968k cached PID USER PR NI VIRT RES SHR S %CPU %MEM TIME+ COMMAND 4925 root 20 0 8206m 4.2g 2220 S 3.3 28.4 62:53.66 java
四核都被占用了,每一个核心不太平均。这是在虚拟机中得到结果,可能真实服务器会更好一些。 因为不是CPU密集型应用,CPU不是问题,无须多加关注。
系统内存状况
free -m total used free shared buffers cached Mem: 15189 14926 263 0 5 56 -/+ buffers/cache: 14864 324 Swap: 4095 1057 3038
物理内存已经无法满足要求了,占用了1057M虚拟内存。
查看一下堆内存情况
jmap -heap 4925 Attaching to process ID 4925, please wait... Debugger attached successfully. Server compiler detected. JVM version is 23.21-b01 using parallel threads in the new generation. using thread-local object allocation. Concurrent Mark-Sweep GC Heap Configuration: MinHeapFreeRatio = 40 MaxHeapFreeRatio = 70 MaxHeapSize = 6442450944 (6144.0MB) NewSize = 629145600 (600.0MB) MaxNewSize = 629145600 (600.0MB) OldSize = 5439488 (5.1875MB) NewRatio = 2 SurvivorRatio = 1 PermSize = 52428800 (50.0MB) MaxPermSize = 52428800 (50.0MB) G1HeapRegionSize = 0 (0.0MB) Heap Usage: New Generation (Eden + 1 Survivor Space): capacity = 419430400 (400.0MB) used = 308798864 (294.49354553222656MB) free = 110631536 (105.50645446777344MB) 73.62338638305664% used Eden Space: capacity = 209715200 (200.0MB) used = 103375232 (98.5863037109375MB) free = 106339968 (101.4136962890625MB) 49.29315185546875% used From Space: capacity = 209715200 (200.0MB) used = 205423632 (195.90724182128906MB) free = 4291568 (4.0927581787109375MB) 97.95362091064453% used To Space: capacity = 209715200 (200.0MB) used = 0 (0.0MB) free = 209715200 (200.0MB) 0.0% used concurrent mark-sweep generation: capacity = 5813305344 (5544.0MB) used = 4213515472 (4018.321487426758MB) free = 1599789872 (1525.6785125732422MB) 72.48054631000646% used Perm Generation: capacity = 52428800 (50.0MB) used = 5505696 (5.250640869140625MB) free = 46923104 (44.749359130859375MB) 10.50128173828125% used 1439 interned Strings occupying 110936 bytes.
老生代占用内存为72%,较为合理,毕竟系统已经处理100万个连接。
再次断开所有测试端,看看系统内存(free -m)
total used free shared buffers cached Mem: 15189 7723 7466 0 13 120 -/+ buffers/cache: 7589 7599 Swap: 4095 950 3145
记为list_free_2。
list_free_1和list_free_2两次都释放后的内存比较结果,系统可用物理已经内存已经降到7589M,先前可是7597M物理内存。
总之,我们的JAVA测试程序在内存占用方面已经,最低需要7589 + 950 = 8.6G内存为最低需求内存吧。
GC日志
我们在启动脚本处设置的一大串参数,到底是否达到目标,还得从gc日志处获得具体效果,推荐使用GCViewer。
GC事件概览:
其它:
总之:
小结
Java与与Erlang、C相比,比较麻烦的事情,需要在程序一开始就得准备好它的堆栈到底需要多大空间,换个说法就是JVM启动参数设置堆内存大小,设置合适的垃圾回收机制,若以后程序需要更多内存,需停止程序,编辑启动参数,然后再次启动。总之一句话,就是麻烦。单单JVM的调优,就得持续不断的根据检测、信息、日志等进行适当微调。
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