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I'm implementing a lock-free single producer single consumer queue for an intensive network application. I have a bunch of worker threads receiving work in their own separate queues, which they then dequeue and process.

Removing the locks from these queues have greatly improved the performance under high load, but they no longer block when the queues are empty, which in turn causes the CPU usage to skyrocket.

How can I efficiently cause a thread to block until it can successfully dequeue something or is killed/interrupted?

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Hi, can you share with me the rps (request per second) you achieved using the approach? I did a similar type of work (implementing a simple HTTP server) so am interested to know it. I don't know how to contact other than commenting in here. Sorry if I bothered you. –  Ayub Aug 28 '12 at 6:05
    
@Ayub Performance was alright. RPS isn't a good unit for measuring performance due to different hardware setups, etc. I redesigned the application to allow worker threads to operate in complete isolation, and the performance gain was ~10x. Sharing less data was truly the key. –  haste Aug 28 '12 at 16:27

6 Answers 6

up vote 13 down vote accepted

If you're on Linux, look into using a Futex. It provides the performance of a non-locking implementation by using atomic operations rather than kernel calls like a mutex would, but should you need to set the process to idle because of some condition not being true (i.e., lock-contention), it will then make the appropriate kernel calls to put the process to sleep and wake it back up at a future event. It's basically like a very fast semaphore.

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Helpful clarification! I upvoted both Futex-related answers for now. Thanks. –  haste May 22 '11 at 19:22
    
+1 for futex. It's performance is not as good as lock-free, but it is good enough and is the perfect choice when mutex locking is too much. pthread mutex API is using futex under the scenes. –  user405725 Jun 15 '11 at 20:26
    
Mutexes on Linux are implemented with a short cmpxchg spin for the low contention case, and falling back to a futex call. I don't really understand why you're calling it non-locking when it implements locking (fast userspace mutex - the origin of the name). –  strcat Dec 26 '13 at 21:46
    
I'm calling it non-locking because of the low-contention case which is what "typically" occurs unless you're under high load ... –  Jason Jan 1 at 17:25

On Linux, futex can be used to block a thread. But be aware that Futexes Are Tricky!

UPDATE: condition variables are much safer to use than futexes, and are more portable. However, a condition variable is used in combination with a mutex, so strictly speaking the result will not be lock-free anymore. However, if your primary goal is performance (and not the guaranty of global progress), and the locked portion (i.e. a condition to check after thread wakeup) is small, it might happen that you will get satisfactory results without the need to go into subtleties of integrating futexes into the algorithm.

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This looks very interesting. I will explore this shortly and return with my verdict. Thank you. –  haste May 22 '11 at 19:19
    
The futex call is an implementation of locking. The mutex API just spins on cmpxchg a bit and then falls back to futex (fast userspace mutex). –  strcat Dec 26 '13 at 21:49

If you're on Windows, you won't be able to use futexes, but Windows Vista has a similar mechanism called Keyed Events. Unfortunately, this isn't part of the published API (it's an NTDLL native API), but you can use it as long as you accept the caveat that it might change in future versions of Windows (and you don't need to run on pre-Vista kernels). Be sure to read the article I linked above. Here's an untested sketch of how it might work:

/* Interlocked SList queue using keyed event signaling */

struct queue {
    SLIST_HEADER slist;
    // Note: Multiple queues can (and should) share a keyed event handle
    HANDLE keyed_event;
    // Initial value: 0
    // Prior to blocking, the queue_pop function increments this to 1, then
    // rechecks the queue. If it finds an item, it attempts to compxchg back to
    // 0; if this fails, then it's racing with a push, and has to block
    LONG block_flag;
};

void init_queue(queue *qPtr) {
    NtCreateKeyedEvent(&qPtr->keyed_event, -1, NULL, 0);
    InitializeSListHead(&qPtr->slist);
    qPtr->blocking = 0;
}

void queue_push(queue *qPtr, SLIST_ENTRY *entry) {
    InterlockedPushEntrySList(&qPtr->slist, entry);

    // Transition block flag 1 -> 0. If this succeeds (block flag was 1), we
    // have committed to a keyed-event handshake
    LONG oldv = InterlockedCompareExchange(&qPtr->block_flag, 0, 1);
    if (oldv) {
        NtReleaseKeyedEvent(qPtr->keyed_event, (PVOID)qPtr, FALSE, NULL);
    }
}

SLIST_ENTRY *queue_pop(queue *qPtr) {
    SLIST_ENTRY *entry = InterlockedPopEntrySList(&qPtr->slist);
    if (entry)
        return entry; // fast path

    // Transition block flag 0 -> 1. We must recheck the queue after this point
    // in case we race with queue_push; however since ReleaseKeyedEvent
    // blocks until it is matched up with a wait, we must perform the wait if
    // queue_push sees us
    LONG oldv = InterlockedCompareExchange(&qPtr->block_flag, 1, 0);

    assert(oldv == 0);

    entry = InterlockedPopEntrySList(&qPtr->slist);
    if (entry) {
        // Try to abort
        oldv = InterlockedCompareExchange(&qPtr->block_flag, 0, 1);
        if (oldv == 1)
            return entry; // nobody saw us, we can just exit with the value
    }

    // Either we don't have an entry, or we are forced to wait because
    // queue_push saw our block flag. So do the wait
    NtWaitForKeyedEvent(qPtr->keyed_event, (PVOID)qPtr, FALSE, NULL);
    // block_flag has been reset by queue_push

    if (!entry)
        entry = InterlockedPopEntrySList(&qPtr->slist);
    assert(entry);

    return entry;
}

You could also use a similar protocol using Slim Read Write locks and Condition Variables, with a lockless fast path. These are wrappers over keyed events, so they may incur more overhead than using keyed events directly.

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the question said linux. –  J-16 SDiZ May 23 '11 at 8:06
    
Yeah, but the futex answers were already taken and I thought it might be useful for someone else searching on the subject later :) –  bdonlan May 23 '11 at 13:12
    
For completeness, this is interesting--I do occasionally develop for Windows. :-) –  haste May 23 '11 at 14:29
1  
+1, Also keyed events work fine on pre-Vista, too (they were initually implemented as a single-global-handle-for-all backoff for an out-of-handle deadlock situation with critical sections under 2k). The only difference between 2k/XP and Vista/7/8 is an implementation detail (linked list vs. hash) which makes Vista and later KEs much more efficient if you watch many memory locations with a single handle (no practial difference for 99% of all applications). –  Damon Aug 22 '13 at 15:49

You could add sleeps while it's waiting. Just pick the biggest wait you're willing to have, then do something like this (pseudocode because I don't remember pthread syntax):

WAIT_TIME = 100; // Set this to whatever you're happy with
while(loop_condition) {
   thing = get_from_queue()
   if(thing == null) {
       sleep(WAIT_TIME);
   } else {
       handle(thing);
   }
}

Even something short like a 100 ms sleep should significantly lower the CPU usage. I'm not sure at what point the context switching will make it worse than busy waiting though.

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I considered this but the sleep time would have to be ridiculously low as the application is expected to complete requests within a millisecond or two. –  haste May 22 '11 at 19:17

Have you tried conditional waiting? When the queue becomes empty, just start waiting for a new job. The thread putting jobs in the queue should fire the signal. This way you only use locks when the queue is empty.

https://computing.llnl.gov/tutorials/pthreads/#ConditionVariables

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1  
Any calls made using pthread functions will make a call into the kernel, which will be significantly slower than atomic operations. The beauty of the futex is that you're using a combination of atomics and a wait-queue at the kernel level, but if there is no lock contention, then you never touch the kernel-level wait queue. On the other-hand, using condition variables automatically places the thread in a wait-queue, so with condition variables, you're going through the kernel no matter what, which is going to be a lot slower if 90% of the time an atomic operation would be fine. –  Jason May 22 '11 at 19:28
4  
@Jason: pthread mutexes on Linux do not enter the kernel in the non-contended case; neither does a cvar signal with no waiters. Of course, a cvar wait must enter the kernel, but so must any blocking operation –  bdonlan May 22 '11 at 19:42
    
@bdonlan: Thanks for the info ... but if that's the case, then what makes a futex faster than a normal pthread mutex? According to the paper Fuss, futexes and furwocks: Fast Userlevel Locking in Linux by Franke, Russell, and Kirkwood, the reasoning behind the futex was to avoid a kernel call if there was no lock contention, i.e., when that paper was written, at least the impression I got from reading it was that mutexes and semaphores always required a kernel call. If they never accessed the kernel then what was the point of the futex? –  Jason May 23 '11 at 0:48
5  
@Jason, The futex is the underlying primitive used to create NPTL pthread mutexes. It's a bit complex and difficult to use futex() safely on its own, so the pthread library wraps up some of the more common futex protocols, and calls them mutexes and condition variables. It's also more portable this way - futex() is a Linux-only syscall. –  bdonlan May 23 '11 at 1:14
1  
@bdolan: Appreciate the clarification. Does that mean though that futexes and pthread mutexes are the same speed in Linux, and there's no benefit to using futexes since mutexes are futexes? Or is there a still a performance penalty for mutexes, and if so, from what? –  Jason May 23 '11 at 4:06

You can cause a thread to sleep by using the sigwait() function. You can wake the thread with pthread_kill. This is much faster than condition variables.

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