• Java NIO——Selector机制源码分析---转


    一直不明白pipe是如何唤醒selector的,所以又去看了jdk的源码(openjdk下载),整理了如下:

    以Java nio自带demo : OperationServer.java   OperationClient.java(见附件)

    其中server端的核心代码:

    public void initSelector() {
            try {
                selector = SelectorProvider.provider().openSelector();
                this.serverChannel1 = ServerSocketChannel.open();
                serverChannel1.configureBlocking(false);
                InetSocketAddress isa = new InetSocketAddress("localhost", this.port1);
                serverChannel1.socket().bind(isa);
                serverChannel1.register(selector, SelectionKey.OP_ACCEPT);
            } catch (IOException e) {
                // TODO Auto-generated catch block
                e.printStackTrace();
            }
    }

    从头开始,

    先看看SelectorProvider.provider()做了什么:

    public static SelectorProvider provider() {
            synchronized (lock) {
                if (provider != null)
                    return provider;
                return AccessController.doPrivileged(
                    new PrivilegedAction<SelectorProvider>() {
                        public SelectorProvider run() {
                                if (loadProviderFromProperty())
                                    return provider;
                                if (loadProviderAsService())
                                    return provider;
                                provider = sun.nio.ch.DefaultSelectorProvider.create();
                                return provider;
                            }
                        });
            }
        }

    其中provider = sun.nio.ch.DefaultSelectorProvider.create();会根据操作系统来返回不同的实现类,windows平台就返回WindowsSelectorProvider;

    if (provider != nullreturn provider;

    保证了整个server程序中只有一个WindowsSelectorProvider对象;

    再看看WindowsSelectorProvider. openSelector():

    public AbstractSelector openSelector() throws IOException {
            return new WindowsSelectorImpl(this);
        }
    new WindowsSelectorImpl(SelectorProvider)代码:
    WindowsSelectorImpl(SelectorProvider sp) throws IOException {
            super(sp);
            pollWrapper = new PollArrayWrapper(INIT_CAP);
            wakeupPipe = Pipe.open();
            wakeupSourceFd = ((SelChImpl)wakeupPipe.source()).getFDVal();
    
            // Disable the Nagle algorithm so that the wakeup is more immediate
            SinkChannelImpl sink = (SinkChannelImpl)wakeupPipe.sink();
            (sink.sc).socket().setTcpNoDelay(true);
            wakeupSinkFd = ((SelChImpl)sink).getFDVal();
    
            pollWrapper.addWakeupSocket(wakeupSourceFd, 0);
        }

    其中Pipe.open()是关键,这个方法的调用过程是:

    Java代码  
    public static Pipe open() throws IOException {
            return SelectorProvider.provider().openPipe();
    }
    SelectorProvider 中:
    public Pipe openPipe() throws IOException {
            return new PipeImpl(this);
    }

    再看看怎么new PipeImpl()的:

    Java代码
    PipeImpl(SelectorProvider sp) {
            long pipeFds = IOUtil.makePipe(true);
            int readFd = (int) (pipeFds >>> 32);
            int writeFd = (int) pipeFds;
            FileDescriptor sourcefd = new FileDescriptor();
            IOUtil.setfdVal(sourcefd, readFd);
            source = new SourceChannelImpl(sp, sourcefd);
            FileDescriptor sinkfd = new FileDescriptor();
            IOUtil.setfdVal(sinkfd, writeFd);
            sink = new SinkChannelImpl(sp, sinkfd);
     }

    其中IOUtil.makePipe(true)是个native方法:

    /**

         * Returns two file descriptors for a pipe encoded in a long.

         * The read end of the pipe is returned in the high 32 bits,

         * while the write end is returned in the low 32 bits.

         */

    staticnativelong makePipe(boolean blocking);

    具体实现:

    JNIEXPORT jlong JNICALL
    Java_sun_nio_ch_IOUtil_makePipe(JNIEnv *env, jobject this, jboolean blocking)
    {
        int fd[2];
    
        if (pipe(fd) < 0) {
            JNU_ThrowIOExceptionWithLastError(env, "Pipe failed");
            return 0;
        }
        if (blocking == JNI_FALSE) {
            if ((configureBlocking(fd[0], JNI_FALSE) < 0)
                || (configureBlocking(fd[1], JNI_FALSE) < 0)) {
                JNU_ThrowIOExceptionWithLastError(env, "Configure blocking failed");
                close(fd[0]);
                close(fd[1]);
                return 0;
            }
        }
        return ((jlong) fd[0] << 32) | (jlong) fd[1];
    }
    static int
    configureBlocking(int fd, jboolean blocking)
    {
        int flags = fcntl(fd, F_GETFL);
        int newflags = blocking ? (flags & ~O_NONBLOCK) : (flags | O_NONBLOCK);
    
        return (flags == newflags) ? 0 : fcntl(fd, F_SETFL, newflags);
    }

    正如这段注释:

    /**

         * Returns two file descriptors for a pipe encoded in a long.

         * The read end of the pipe is returned in the high 32 bits,

         * while the write end is returned in the low 32 bits.

         */

    High32位存放的是通道read端的文件描述符FD(file descriptor),low 32 bits存放的是write端的文件描述符。所以取到makepipe()返回值后要做移位处理。

    pollWrapper.addWakeupSocket(wakeupSourceFd, 0);

    这行代码把返回的pipe的write端的FD放在了pollWrapper中(后面会发现,这么做是为了实现selector的wakeup())

    ServerSocketChannel.open()的实现:

    public static ServerSocketChannel open() throws IOException {
            return SelectorProvider.provider().openServerSocketChannel();
    }
    SelectorProvider:
    public ServerSocketChannel openServerSocketChannel() throws IOException {
            return new ServerSocketChannelImpl(this);
    }

    可见创建的ServerSocketChannelImpl也有WindowsSelectorImpl的引用。

    ServerSocketChannelImpl(SelectorProvider sp) throws IOException {
            super(sp);
            this.fd =  Net.serverSocket(true);    //打开一个socket,返回FD
            this.fdVal = IOUtil.fdVal(fd);
            this.state = ST_INUSE;
    }

    然后通过serverChannel1.register(selector, SelectionKey.OP_ACCEPT);把selector和channel绑定在一起,也就是把new ServerSocketChannel时创建的FD与selector绑定在了一起。

    到此,server端已启动完成了,主要创建了以下对象:

    WindowsSelectorProvider:单例

    WindowsSelectorImpl中包含:

        pollWrapper:保存selector上注册的FD,包括pipe的write端FD和ServerSocketChannel所用的FD

        wakeupPipe:通道(其实就是两个FD,一个read,一个write)

    再到Server 中的run():

    selector.select();主要调用了WindowsSelectorImpl中的这个方法:

    protected int doSelect(long timeout) throws IOException {
            if (channelArray == null)
                throw new ClosedSelectorException();
            this.timeout = timeout; // set selector timeout
            processDeregisterQueue();
            if (interruptTriggered) {
                resetWakeupSocket();
                return 0;
            }
            // Calculate number of helper threads needed for poll. If necessary
            // threads are created here and start waiting on startLock
            adjustThreadsCount();
            finishLock.reset(); // reset finishLock
            // Wakeup helper threads, waiting on startLock, so they start polling.
            // Redundant threads will exit here after wakeup.
            startLock.startThreads();
            // do polling in the main thread. Main thread is responsible for
            // first MAX_SELECTABLE_FDS entries in pollArray.
            try {
                begin();
                try {
                    subSelector.poll();
                } catch (IOException e) {
                    finishLock.setException(e); // Save this exception
                }
                // Main thread is out of poll(). Wakeup others and wait for them
                if (threads.size() > 0)
                    finishLock.waitForHelperThreads();
              } finally {
                  end();
              }
            // Done with poll(). Set wakeupSocket to nonsignaled  for the next run.
            finishLock.checkForException();
            processDeregisterQueue();
            int updated = updateSelectedKeys();
            // Done with poll(). Set wakeupSocket to nonsignaled  for the next run.
            resetWakeupSocket();
            return updated;
        }

     其中subSelector.poll()是核心,也就是轮训pollWrapper中保存的FD;具体实现是调用native方法poll0:

    private int poll() throws IOException{ // poll for the main thread
                return poll0(pollWrapper.pollArrayAddress,
                             Math.min(totalChannels, MAX_SELECTABLE_FDS),
                             readFds, writeFds, exceptFds, timeout);
            }
    private native int poll0(long pollAddress, int numfds,
                 int[] readFds, int[] writeFds, int[] exceptFds, long timeout);
    // These arrays will hold result of native select().
                // The first element of each array is the number of selected sockets.
            // Other elements are file descriptors of selected sockets.
            private final int[] readFds = new int [MAX_SELECTABLE_FDS + 1];//保存发生read的FD
            private final int[] writeFds = new int [MAX_SELECTABLE_FDS + 1]; //保存发生write的FD
            private final int[] exceptFds = new int [MAX_SELECTABLE_FDS + 1]; //保存发生except的FD

    这个poll0()会监听pollWrapper中的FD有没有数据进出,这会造成IO阻塞,直到有数据读写事件发生。比如,由于pollWrapper中保存的也有ServerSocketChannel的FD,所以只要ClientSocket发一份数据到ServerSocket,那么poll0()就会返回;又由于pollWrapper中保存的也有pipe的write端的FD,所以只要pipe的write端向FD发一份数据,也会造成poll0()返回;如果这两种情况都没有发生,那么poll0()就一直阻塞,也就是selector.select()会一直阻塞;如果有任何一种情况发生,那么selector.select()就会返回,所有在OperationServer的run()里要用while (true) {,这样就可以保证在selector接收到数据并处理完后继续监听poll();

    这时再来看看WindowsSelectorImpl. Wakeup():

    public Selector wakeup() {
            synchronized (interruptLock) {
                if (!interruptTriggered) {
                    setWakeupSocket();
                    interruptTriggered = true;
                }
            }
            return this;
        }
    // Sets Windows wakeup socket to a signaled state.
        private void setWakeupSocket() {
            setWakeupSocket0(wakeupSinkFd);
        }
    private native void setWakeupSocket0(int wakeupSinkFd);
    JNIEXPORT void JNICALL
    Java_sun_nio_ch_WindowsSelectorImpl_setWakeupSocket0(JNIEnv *env, jclass this,
                                                    jint scoutFd)
    {
        /* Write one byte into the pipe */
        const char byte = 1;
        send(scoutFd, &byte, 1, 0);
    }

    可见wakeup()是通过pipe的write 端send(scoutFd, &byte, 1, 0),发生一个字节1,来唤醒poll()。所以在需要的时候就可以调用selector.wakeup()来唤醒selector。

    原文:http://goon.iteye.com/blog/1775421

    补充linux操作系统下的DefaultSelectorProvider的实现,可以看到,如果内核版本>=2.6则,具体的SelectorProvider为EPollSelectorProvider,否则为默认的PollSelectorProvider

    //sun.nio.ch.DefaultSelectorProvider
    
    public static SelectorProvider create() {
    PrivilegedAction pa = new GetPropertyAction("os.name");
    String osname = (String) AccessController.doPrivileged(pa);
        if ("SunOS".equals(osname)) {
            return new sun.nio.ch.DevPollSelectorProvider();
        }
     
        // use EPollSelectorProvider for Linux kernels >= 2.6
        if ("Linux".equals(osname)) {
            pa = new GetPropertyAction("os.version");
            String osversion = (String) AccessController.doPrivileged(pa);
            String[] vers = osversion.split("\.", 0);
            if (vers.length >= 2) {
                try {
                    int major = Integer.parseInt(vers[0]);
                    int minor = Integer.parseInt(vers[1]);
                    if (major > 2 || (major == 2 && minor >= 6)) {
                        return new sun.nio.ch.EPollSelectorProvider();
                    }
                } catch (NumberFormatException x) {
                    // format not recognized
                }
            }
        }
     
        return new sun.nio.ch.PollSelectorProvider();
    }
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  • 原文地址:https://www.cnblogs.com/davidwang456/p/3831617.html
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