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new to WCF.

I have a client which is deadlocking when calling a WCF service.

The service will invoke a callback to the client at the time of the call which is marked as IsOneWay. I have confirmed that the service is not blocking on the callback.

The client then immediately calls the same service again (in a tight loop), without having yet serviced the callback. The client then deadlocks (and a breakpoint on the service side never gets triggered).

So to recap:

CLIENT                                SERVICE
Call service -----------------------> (service breakpoint triggers)
(waiting for dispatch thread) <------ Invoke callback (IsOneWay - doesn't block)
                                      Service returns

Call service again immediately -----? (service breakpoint doesn't trigger)
(deadlock)

I am assuming that the callback has grabbed some WCF lock at the client end, and then the second service call from the client also wants that lock, so deadlock results. But this is just assumption.

I have read about ConcurrencyMode but I can't decide which mode to use, or where to put it because I'm not 100% clear on what is going on, and what is being blocked exactly.

I would also prefer to keep all callbacks being serviced by the dispatch thread if possible as it keeps the code simpler.

Can any WCF experts shed light on exactly what is going on here?

Many thanks

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Can you show us the code? –  KMån Jun 8 '11 at 10:10
    
Hardly worth it, there's nothing to it. It's more a problem of me understanding how WCF deals with and syncs callbacks. –  GazTheDestroyer Jun 8 '11 at 10:29
    
What type of client application do you have? Are both client call and callback one ways or is any of them with response? –  Ladislav Mrnka Jun 8 '11 at 10:40

2 Answers 2

up vote 15 down vote accepted

OK, think I've sussed it.

WCF services default to single threaded. All calls and callbacks get marshalled to a single thread (or SynchronizationContext to be more accurate).

My app is a single threaded WPF app, so the SynchronizationContext gets set to the dispatch thread.

When the callback comes in it tries to marshal the call to the dispatch thread, which of course is sat blocking on the original service call. I'm not clear it locks exactly, but there's obviously some global lock that it tries to get before waiting for the dispatch thread.

When the dispatch thread then calls the service again, it deadlocks on this global lock.

Two ways around it:

1) Create the service proxy on a different thread in the first place. All calls will get marshalled through this thread instead and it won't matter that the dispatch thread is blocked.

2) Apply [CallbackBehavior(UseSynchronizationContext = false)] attribute to the client class that implements the callback. This means WCF will ignore the synchronisation context when the callback comes in, and it will service it on any available thread.

I went with 2. Obviously this means I need to marshal callbacks that could update the GUI to the dispatch thread myself, but luckily my callback implementation is a small wrapper anyway, so I just do a _dispatcher.BeginInvoke() in each callback method to marshal ASYNCHRONOUSLY. The dispatch thread will then service when it gets a chance which is what I wanted in the first place.

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1  
[CallbackBehavior(UseSynchronizationContext = false)] was the answer in my case. I've been looking for a solution entire day, and finally I found this. Thank you. –  alexandrudicu Jun 21 '12 at 13:25
    
Glad it helped someone, cheers. –  GazTheDestroyer Jun 21 '12 at 15:16
    
A third way: You can set the SynchronizationContext on the InstanceContext used to create the DuplexChannelFactory. Setting it to a plain new SynchronizationContext() works fine. –  Dietrich Epp Jan 29 '14 at 23:03
    
This applies to WinForms too. Also, be careful to specify **CallbackBehavior**(UseSynchronizationContext:=False), setting **ServiceBehavior**(UseSynchronizationContext:=False) is allowed, but has no effect –  smirkingman Apr 29 at 15:04

The sequence that you have depicted resembles a synchronous call. While in an async call, the sequence would be:

Client                            Server
Call service    --------------->ProcessRequest(1) //Your for loop for instance.
Call service    --------------->ProcessRequest(2)
Call service    --------------->ProcessRequest(3)
Call service    --------------->ProcessRequest(4)
Call service    --------------->ProcessRequest(5)

Callback awake  <---------------Response1 //Responses tends to pour in...
Callback awake  <---------------Response2
Callback awake  <---------------Response3
Callback awake  <---------------Response4...

In each case of each async web service call, the system creates a separate IO thread(IOCP thread), and processes the request. In this, seldom you will find a deadlock.

I have found this way, even when called within a loop, to be working very well.

You can, for instance, register for the event .OnProcessComplete, and then call the ProcessCompleteAsync method.

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I don't want async calls though. I was hoping the callbacks would just queue up in a similar fashion to your diagram, and I could service them in the dispatch thread when I got a chance. Am getting the feeling this isn't possible though. :/ –  GazTheDestroyer Jun 8 '11 at 10:26
    
Callbacks are async calls. A callback is, when you request for notification(events, for instance); then you are notified, in the form that your method/function is called back. –  KMån Jun 8 '11 at 10:47
    
Sorry yes, the callbacks are obviously async. You seemed to be inferring above that I convert the original service calls to async so that the dispatch thread is free. –  GazTheDestroyer Jun 8 '11 at 10:51
    
You talked about callback, so is the reason of inferring async calls. If you want synchronous calls, you can look into implementing the producer/consumer pattern. For instance, your ProcessRequest(1) will push an operation on a queue, and a thread will Dequeue an item, process and respond. Or enqueue calls on to a threadpool worker threads directly from the WCF operation using async delegate; and set threadpool based timers from your WCF operation. –  KMån Jun 9 '11 at 5:00

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