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I'm building a Java application with a GUI and a socket-based server, and I'm constantly running into problems with one part of the application getting stuck waiting for the other (mostly the GUI waiting for the server - no surprise there. The few times I manage to avoid these errors, I instead find myself reaching the end of my main method almost instantly after startup. (The app may or may not keep running, depending on if there is any GUI visible or not, but I though the main method wasn't supposed to return until the program is actually exiting...)

My requirements on the application are the following:

  • It should be able to handle an unspecified number of clients simultaneously
  • Communication between server and clients can go in either direction, and not necessarily every other turn; sometimes the server sends a bunch of messages and get replies from only some clients, other times it's the other way around.
  • It should never be "too late" for a client to connect - the serversocket needs to keep accepting connections continuously for as long as the server app is running.
  • During the whole time, the GUI should be unaffected by the server and clients waiting for eachother. Updates to the GUI happens through event listeners on other objects (mostly the model) which are changed by the background threads.

I've tried with the following, but I can't seem to get it right.

  • 1 thread for the main method and the "regular" work performed by objects it creates (Controller, Model etc). This is the thread I sometimes have problems with because it doesn't hold anywhere and returns from main prematurely.
  • Using EventQueue.invokeLater(new Runnable() { ... }); I perform all actual GUI manipulation on the UI thread, but none of these calls are "surviving" threads, so they basically just work asynchronically off the main thread.
  • 1 thread for the ServerSocket to be able to keep listening for new connections.
  • 1 thread for each client, to be able to listen to messages from clients. I'm unsure here if I need another thread here as well, to be able to send messages "out of order", i.e. without waiting to receive one first.

I have never written a (real) multithreaded application before, so this is entirely new ground to me. However, I refuse to beleive that this problem has not been solved successfully before - even so many times that some sort of best practices have evolved.

What are they? What is a good architecture for this application?

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2 Answers 2

up vote 1 down vote accepted

There are many and varied answers to this question, but the best rule I can think of is that you need one UI thread (you haven't said what you're using for GUI, but you mentioned invokeLater, so I'm thinking Swing) and then one or more threads for handling clients. A thread for each client is unnecessary; use java.nio classes for asynchronous I/O instead. You may want to make the total number of client-handling threads something you can configure at runtime; the range will be fairly small, like one to four.

The machine on which you're running your application, if it's truly a server, will probably be able to handle four (e.g., a dual dual-core machine) to sixteen (quad quad-core) actual concurrent threads of execution (there are obviously server-class machines that have even more cores than that, but you get the idea), and of course you're sharing those with all of the other services running on the architecture. So having lots and lots of threads just causes lots and lots of context switching. Context switching is cheap, but nowhere near free, and if avoidable it's time the CPU could more usefully be doing something else.

For an example of a server application coded to handle lots of clients with a minimum of threads, using NIO, you might look at the source code for Netty. In fact, you might even look at just using Netty and building your application logic around its handling of the I/O.


Side note:

The app may or may not keep running, depending on if there is any GUI visible or not, but I though the main method wasn't supposed to return until the program is actually exiting...

main will end as soon as you let it end. The JVM will keep running as long as there are outstanding running threads. If you want main to wait for other threads before exiting, use Thread#join to join them. join causes the current thread to wait until the thread you call join on terminates (some overloads of join offer a timeout so the calling thread can resume if the called thread doesn't terminate within a given period of time). Compare the output of the following when you run it with no arguments vs. running it with an argument (any argument, the content of the argument doesn't matter):

public class JoinExample implements Runnable {

    public static final void main(String[] args) {
        Thread t = new Thread(new JoinExample());

        System.out.println("Starting thread");
        t.start();

        if (args.length > 0) {
            System.out.println("Joining thread");
            while (t.isAlive()) {
                try {
                    t.join();
                }
                catch (InterruptedException ie) {
                }
            }
        }

        System.out.println("main exiting");
    }

    public void run() {
        long    stop = System.currentTimeMillis() + 2000;

        System.out.println("Thread starting");
        while (System.currentTimeMillis() < stop) {
            // Sleep a mo
            try {
                Thread.currentThread().sleep(250);
            }
            catch (InterruptedException ie) {
            }
            System.out.println("Thread still running");
        }
        System.out.println("Thread stopping");
    }
}

All of that said, you may well want to allow the main thread to die, since the UI thread will be the event dispatcher thread created by Swing. More info on threads and swing here and here.

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I had never heard about java.nio.* (after all, my only real non-cowboy Java education was a basic programming course in my first year of my bachelor's... and a class in desing patterns that was in Java out of convenience. The teacher's convenience, of course...) but after reading up a little this definitely seems like the way to go. Thanks! –  Tomas Lycken Jan 9 '12 at 22:09

Server

The main thread of the server is listening. The server may spawn a new thread per client, but it is better to just create one state-machine object for each client, so, no threads yet. If you can get your state machines to work exclusively with non-blocking calls, then you do not need any more threads on the server. But that's usually not feasible, so:

When a request comes in for a client, you need to use a "Thread Pool" to execute it in. I do not know what kind of support exists in Java for thread pools, google it.

Thread pools are extremely efficient in these scenarios because the number of threads instantiated at any given time is not equal to the total number of clients connected, but rather to the maximum number of requests that may need to be simultaneously serviced by the server at any given moment. When the requests are coming from a GUI application, they will usually be arriving at human response times, which means that your server will mostly be sitting around doing nothing waiting for a request to come, and it will rarely be found servicing multiple simultaneous requests.

With the thread pool you are also taking care of the possibility that the server may decide to send a response back to a client at any time, and not, say, as a result of a transition change of the state machine object that represents the client.

Client

On the client it is not necessarily a terrible idea to run everything from a single thread. This can be accomplished if you can have a non-blocking read always pending for out-of-time messages from the server. Then you can use either blocking or non-blocking writes to send messages to the server. True, blocking writes would mean that whenever the client tries to communicate with the server it will freeze, but then again that's not unreasonable, and if you build your server well (with thread pools etc) it will never have to wait for very long. The advantage is that the logic of the client becomes quite easy this way. If that's not good enough, then:

The main thread of the client runs the GUI, while a second thread runs the code that communicates with the server.

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But how do I listen for messages from the clients without blocking the thread? The only way I know is to have a stream reader ultimately coming from socket.getInputStream() that stands at reader.readLine() until a message is published. Is there a better way? –  Tomas Lycken Jan 8 '12 at 17:30
    
As T.J. Crowder mentioned, there is java.nio for asynchronous communications. Non-blocking is another term for asynchronous. –  Mike Nakis Jan 8 '12 at 17:56

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