I've been using ZMQ in some Python applications for a while, but only very recently I decided to reimplement one of them in Go and I realized that ZMQ sockets are not thread-safe.

The original Python implementation uses an event loop that looks like this:

while running:
    socks = dict(poller.poll(TIMEOUT))
    if socks.get(router) == zmq.POLLIN:
        client_id = router.recv()
        _ = router.recv()
        data = router.recv()
        requests.append((client_id, data))

    for req in requests:
        rep = handle_request(req)
        if rep:

    for client_id, data in replies:
        router.send(client_id, zmq.SNDMORE)
        router.send(b'', zmq.SNDMORE)
        del replies[:]

The problem is that the reply might not be ready on the first pass, so whenever I have pending requests, I have to poll with a very short timeout or the clients will wait for more than they should, and the application ends up using a lot of CPU for polling.

When I decided to reimplement it in Go, I thought it would be as simple as this, avoiding the problem by using infinite timeout on polling:

for {
    sockets, _ := poller.Poll(-1) 
    for _, socket := range sockets {
        switch s := socket.Socket; s {
        case router:
            msg, _ := s.RecvMessage(0)
            client_id := msg[0]
            data := msg[2]
            go handleRequest(router, client_id, data)                

But that ideal implementation only works when I have a single client connected, or a light load. Under heavy load I get random assertion errors inside libzmq. I tried the following:

  1. Following the zmq4 docs I tried adding a sync.Mutex and lock/unlock on all socket operations. It fails. I assume it's because ZMQ uses its own threads for flushing.

  2. Creating one goroutine for polling/receiving and one for sending, and use channels in the same way I used the req/rep queues in the Python version. It fails, as I'm still sharing the socket.

  3. Same as 2, but setting GOMAXPROCS=1. It fails, and throughput was very limited because replies were being held back until the Poll() call returned.

  4. Use the req/rep channels as in 2, but use runtime.LockOSThread to keep all socket operations in the same thread as the socket. Has the same problem as above. It doesn't fail, but throughput was very limited.

  5. Same as 4, but using the poll timeout strategy from the Python version. It works, but has the same problem the Python version does.

  6. Share the context instead of the socket and create one socket for sending and one for receiving in separate goroutines, communicating with channels. It works, but I'll have to rewrite the client libs to use two sockets instead of one.

  7. Get rid of zmq and use raw TCP sockets, which are thread-safe. It works perfectly, but I'll also have to rewrite the client libs.

So, it looks like 6 is how ZMQ was really intended to be used, as that's the only way I got it to work seamlessly with goroutines, but I wonder if there's any other way I haven't tried. Any ideas?


With the answers here I realized I can just add an inproc PULL socket to the poller and have a goroutine connect and push a byte to break out of the infinite wait. It's not as versatile as the solutions suggested here, but it works and I can even backport it to the Python version.

  • What ZMQ library are you using on the Go side? – sberry Apr 5 '16 at 22:22
  • @sberry github.com/pebbe/zmq4, the one linked on #1 – Pedro Werneck Apr 5 '16 at 22:30
  • I'm new to the Go world - is there a reason other than consistency that you would use inproc sockets rather than a hybrid system that uses ZMQ for external communication and Go channels for internal communication? – Jason Apr 6 '16 at 13:01
  • @Jason Because I can't use a channel with ZMQ poller. It would be great if I could use ZMQ sockets with Go's select or channels with the ZMQ poller. – Pedro Werneck Apr 6 '16 at 15:42

I opened an issue a 1.5 years ago to introduce a port of https://github.com/vaughan0/go-zmq/blob/master/channels.go to pebbe/zmq4. Ultimately the author decided against it, but we have used this in production (under VERY heavy workloads) for a long time now.

This is a gist of the file that had to be added to the pebbe/zmq4 package (since it adds methods to the Socket). This could be re-written in such a way that the methods on the Socket receiver instead took a Socket as an argument, but since we vendor our code anyway, this was an easy way forward.

The basic usage is to create your Socket like normal (call it s for example) then you can:

channels := s.Channels()
outBound := channels.Out()
inBound := channels.In()

Now you have two channels of type [][]byte that you can use between goroutines, but a single goroutine - managed within the channels abstraction, is responsible for managing the Poller and communicating with the socket.

  • Forget my previous comment. I got it now. In essence what it does is to use an inproc socket to break out of the infinite timeout and wrap everything in channels to make it more seamless. Nice one. Thanks. – Pedro Werneck Apr 6 '16 at 2:46

The blessed way to do this with pebbe/zmq4 is with a Reactor. Reactors have the ability to listen on Go channels, but you don't want to do that because they do so by polling the channel periodically using a poll timeout, which reintroduces the same exact problem you have in your Python version. Instead you can use zmq inproc sockets, with one end held by the reactor and the other end held by a goroutine that passes data in from a channel. It's complicated, verbose, and unpleasant, but I have used it successfully.

  • I got it, but I just realized I can simply use an inproc socket to break out of the poller.Poll(-1) call, I don't even have to use a reactor. Thanks. – Pedro Werneck Apr 6 '16 at 2:50
  • @PedroWerneck clever. Glad I could help somehow. – hobbs Apr 6 '16 at 3:43

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