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I'm working on a multithreaded project in C++ that sends data to a series of network connections. Here's some pseudocode that illustrates what's going on:

class NetworkManager
{
    Thread    writer;      // responsible for writing data in queues to the network
    Queue[]   outqueue;    // holds data until the network is ready to receive it
    Network[] nets;        // sockets or whatever
    Mutex[]   outlock;     // protects access to members of outqueue
    Mutex     managerlock; // protects access to all queues
    Condition notifier;    // blocks the write thread when there is no data
}

In reality it's a whole lot more complicated than that, but I've axed a lot of unnecessary details. One important detail is that the networking is rate-limited, and the ability of the program to queue data independently from sending it is a feature of the design (the program should not have to wait to process new data because it's blocking on a network write).

Here's a brief description of how the program is expected to interact with this class. Note that QueueWriteToNetwork and DoAdministrativeStuff are, in my implementation, managed by THE SAME external thread.

QueueWriteToNetwork(network, data) // responsibility of external thread
    Let i = the index of the network to send to
    Lock(outlock[i])
    outqueue[i].Add(data)
    Unlock(outlock[i])
    Signal(notifier)

DoAdministrativeStuff(network, more) // responsibility of external thread
    Lock(managerlock)
    more.Process() // might do any of the following:
                   // connect or disconnect networks
                   // add or remove networks from list
                   // immediate write data to network, bypassing rate limiting
                   // other things that I forgot
    Unlock(managerlock)

WriterThreadMain() // responsibility of internal write thread
    Lock(managerlock)
    Loop forever:
        Check for data in every queue (locking and unlocking each queue)
        If all queues have no data to write:
            Wait(notifier, managerlock)
            continue
        If outqueue[i] has data ready to write
            Lock(outlock[i])
            Send data from outqueue[i]
            outqueue[i].Pop()
            Unlock(outqueue[i])

As you might be able to see, there are a few issues with this approach (for example, if a write is queued to the network with QueueWriteToNetwork as WriterThreadMain is checking if the queues are empty, the call to Signal(notifier) could potentially be dropped, and the write queue could remain waiting even though there was data ready).

I need to phrase this in such a way that the following are possible:

  • Adding data to a write queue does not block, or blocks for only a reasonably short time (specifically, it does not block for the duration of a network write that's in progress)
  • The DoAdministrativeStuff function must have the ability to ensure that the writer thread is blocked in a safe state (i.e. not accessing any queue, queue lock, or network)

I've explored the possibility of using a semaphore to track the number of items in write queues. This would solve the lost-update problem I mentioned earlier.

Finally, I'm targeting Linux (using Posix libraries to provide the types pthread_t, pthread_mutex_t, pthread_cond_t, and sem_t), and I don't care about compatibility with Windows. Also, please don't recommend Boost. Pulling any Boost header into my code makes compilation take unbearably long.

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If you do not like to compile boost then do not compile boost, just take boost::asio as example of code where all that you describe here is already implemented. –  Öö Tiib Mar 17 '13 at 2:42
1  
You can use the Asio library without using boost. –  Sam Miller Mar 28 '13 at 21:04
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