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I wrote a multithreaded gameserver application which handles multiple simultaneous connections using NIO. Unfortunately this server generates full CPU load on one core as soon as the first user connects, even when that user is not actually sending or receiving any data.

Below is the code of my network handling thread (abbreviated to the essential parts for readability). The class ClientHandler is my own class which does the network abstraction for the game mechanics. All other classes in the example below are from java.nio.

As you can see it uses a while(true) loop. My theory about it is that when a key is writable, will return immediately and clientHandler.writeToChannel() is called. But when the handler returns without writing anything, the key will stay writable. Then select is called again immediately and returns immediately. So I got a busy spin.

Is there a way to design the network handling loop in a way that it sleeps as long as there is no data to send by the clientHandlers? Note that low latency is critical for my use-case, so I can not just let it sleep an arbitrary number of ms when no handlers have data.

ServerSocketChannel server =;
server.socket().bind(new InetSocketAddress(port));
Selector selector =;
server.register(selector, SelectionKey.OP_ACCEPT);
// wait for connections

     // Wait for next set of client connections;
    Set<SelectionKey> keys = selector.selectedKeys();
    Iterator<SelectionKey> i = keys.iterator();
    while (i.hasNext()) {
        SelectionKey key =;

        if (key.isAcceptable()) {
            SocketChannel clientChannel = server.accept();
            SelectionKey clientKey = clientChannel.register(selector, SelectionKey.OP_READ | SelectionKey.OP_WRITE);
            ClientHandler clientHanlder = new ClientHandler(clientChannel);
        if (key.isReadable()) {
            // get connection handler for this key and tell it to process data 
            ClientHandler clientHandler = (ClientHandler) key.attachment();
        if (key.isWritable()) {
            // get connection handler and tell it to send any data it has cached 
            ClientHandler clientHandler = (ClientHandler) key.attachment();
        if (!key.isValid()) {
            ClientHandler clientHandler = (ClientHandler) key.attachment();
share|improve this question
I'm not sure if select()/NIO is all that useful to wait on when channels are writable - the OS network buffer should be able to take care of that. If your bottleneck is whether data is available to be written, you should wait on that. (I.e. on your ClientHandlers I suppose.) –  millimoose Feb 14 '13 at 18:24
I would consider using a framework to support NIO like netty or mina. These have most of the bugs already solved. If you have less than 1000 connections, you could use blocking IO or NIO instead. –  Peter Lawrey Feb 14 '13 at 18:42

3 Answers 3

up vote 2 down vote accepted

I don't see any reason why the reading and writing must happen with the same selector. I would use one selector in a thread for read/accept operations and it will always be blocking until new data arrives.

Then, use a separate thread and selector for writing. You mention you are using a cache to store messages before they are sent on the writable channels. In practice the only time a channel would not be writable is if the kernel's buffer is full, so it will rarely not be writable. A good way to implement this would be to have a dedicated writer thread that is given messages, and sleeping; it can be either interrupt()ed when new messages should be sent, or using a take() on a blocking queue. Whenever a new message arrives, it will unblock, do a select() on all writable keys and send any pending messages; only in rare cases will a message have to remain in the cache since a channel is not writable.

share|improve this answer
SelectionKey clientKey = clientChannel.register(selector, SelectionKey.OP_READ | SelectionKey.OP_WRITE);

The problem is here. SocketChannels are almost always writable, unless the socket send buffer is full. Ergo they should normally not be registered for OP_WRITE: otherwise your selector loop will spin. They should only be so registered if:

  1. there is something to write, and
  2. a prior write() has returned zero.
share|improve this answer
So does this mean I can resister and unregister OP_WRITE as required? –  bot_bot Jun 11 at 10:42
@bot_bot Of course. –  EJP Aug 24 at 6:04

As EJP said, OP_WRITABLE should be set if and only if there are some bytes to send.

final ServerSocketChannel server =;

while(server.isOpen()) {;
    final Set<SelectionKey> keys = selector.selectedKeys();
    for (final SelectionKey key : keys) {
        if (key.isAcceptable()) {
            final SocketChannel client = server.accept();
            final SelectionKey registered
                = client.register(selector, SelectionKey.OP_READ);
            final ClientHandler hanlder = new ClientHandler(registered);
        if (key.isReadable()) {
            final ClientHandler handler = (ClientHandler) key.attachment();
        if (key.isWritable()) {
            ClientHandler handler = (ClientHandler) key.attachment();

I changed ClientHandler constructor as it takes the SelectionKey.

class ClientHandler {
    public ClientHandler(final SelectionKey reigstered) {
        this.registered = registered;
    public void readFromChannel() {
        final ReadableByteChannel channel =;
        // read request
        // and make it ready for writing
        registered.interestOps(OP_READABLE | OP_WRITABLE);
    public void writeToChannel() {
        final WritableByteChannel channel =;
        // write request
        // and make it unready for writing
    private final SelectionKey registered;
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