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spoiler note: the question is the last phrase.

In C#, the classical pattern to use a condition variable is like this:

lock (answersQueue)
{
    answersQueue.Enqueue(c);
    Monitor.Pulse(answersQueue); // condition variable "notify one".
}

and some other thread:

lock (answersQueue)
{
    while (answersQueue.Count == 0)
    {
        // unlock answer queue and sleeps here until notified.
        Monitor.Wait(answersQueue);
    }
    ...
}

that's an example taken from my code. if I place the Pulse outside of the lock scope, it doesn't compile. however, it is the correct way: c.f:

http://msdn.microsoft.com/en-us/library/windows/desktop/ms686903(v=vs.85).aspx and: http://www.installsetupconfig.com/win32programming/threadprocesssynchronizationapis11_7.html (search for "inside")

And indeed it is idiotic to signal the sleeping thread when you still are in your critical section. Because the sleeping thread CAN'T wake up (not immediately), BECAUSE it is INSIDE a criticial section as well !

Therefore, I hope that .NET or C# Pulse call is actually just flagging the lock object, so that when it goes out of scope it actually "pulses" the condition variable at this moment. Because otherwise, it would have an optimality issue.

So how come the design of the Monitor object was chosen to be that way ?

Edit:

I found the answer in this paper: http://research.microsoft.com/pubs/64242/implementingcvs.pdf section "Optimising Signal and Broadcast" and the previous section about NT kernel and how to make Condition Variable on top of Semaphores, which is the reason for introducing the "darned queues". NOW that makes me a better engineer.

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1  
"if I place the Pulse outside of the lock scope, it doesn't compile. however" : oh, it'll compile - it just won't run; but it is not the correct way when using Monitor; the pulse must be inside –  Marc Gravell Feb 1 '13 at 9:59
    
Ok, it is not the correct way. but it is the correct way of using condition variables. So need I take it a monitor is just another managed object waaay up in the toposphere of .NET and nowhere near the system ? –  v.oddou Feb 1 '13 at 10:06
    
Monitor is implemented inside the CLI, yes; as part of the object-header. So unlike things like AutoResetEvent, it doesn't involve going outside the VM to the OS. –  Marc Gravell Feb 1 '13 at 10:08
2  
I find that this question : stackoverflow.com/questions/1958294/… is totally similar and has a very interesting answer from Hans Passant. But it also leads to more questionning about what is that darned ready queue ? –  v.oddou Feb 1 '13 at 10:08
1  
I'm not confused:) I tried to tell that the lock is there by design. I tried to show you some cases where you'd see/feel the difference between the monitor and other synchronization mechanisms. They all are similar to some extent. However, each one gives you something different, some tiny feature you may exploit to boost performance in your case. Semaphore seems idiotic when you need only a mutex. But once yo uhit that specific semaphorly case, it shines as a diamond. Monitors simply give you that next locking bit, as a feature. In some cases you critically need that. In others, it's useless. –  quetzalcoatl Feb 1 '13 at 10:53

2 Answers 2

up vote 1 down vote accepted

And indeed it is idiotic to signal the sleeping thread when you still are in your critical section. Because the sleeping thread CAN'T wake up

Pulse doesn't expect to get a thread running; it only expects to move a thread between the 2 queues (waiting and ready). The "not go do something" is part of releasing the lock via Exit (or the end of a lock). In reality, it isn't an issue because Monitor.Pulse typically happens right before a Wait or an Exit.

Therefore, I hope that .NET or C# Pulse call is actually just flagging the lock object, so that when it goes out of scope it actually "pulses" the condition variable at this moment. Because otherwise, it would have an optimality issue.

Again; these are different issues: moving between waiting and ready is one thing; exiting a lock already has all the code to actually activate the next ready thread.

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Should I take it that .NET uses user-space threads ? (i.e. they over-manage threads on the VM to abstract the system ?) How efficient is that ? (it is not rhetoric, I probably just need a link :) ) –  v.oddou Feb 1 '13 at 10:18
    
@v.oddou that depends on the host; it can do, hence the distinction of ManagedThreadId; IIRC SQL Server does that aggressively via the fibre model. –  Marc Gravell Feb 1 '13 at 10:27
    
I remembered what I read in: en.wikipedia.org/wiki/Green_threads about the Java section. And got scared. Because of that paragraph, I would have thought that C# being modern, would have left out from the spec the constraints that you mention, to let VMs implementors free to map them to kernel threads. But since the article also mention good perf on linux experiments, I suppose Java experience is just an example of how bad Sun people were, and should not scare me into thinking "damn, .NET is repeating history, in a bad way...". –  v.oddou Feb 1 '13 at 10:43
    
@v.oddou it isn't a c# concern; it is a runtime/CLI/host issue; but yes, a sophisticated host can do thread mapping itself –  Marc Gravell Feb 1 '13 at 10:47
1  
@v.oddou C# is a language, and does not define or control the behavior Monitor, which is part of the BCL. The language does have some special treatment of Monitor, but only as far as Enter / TryEnter / Exit, for the lock keyword –  Marc Gravell Feb 1 '13 at 11:01

You did not understood the basic problem of synchronization. What is a 'monitor', what does it mean that a thread sleeps and what does it mean that it is about to be woken up?

A monitor is a mid-level synchronization structure. This is not a low-level petty volatile boolean flag with bus-halting XCHG operation, and this is not high-level thread pool handler that requires dozens of other special mechanisms..

On a monitor, MANY threads may sleep. There are logical queues out there that i.e. preserver order of being put to sleep/woken up, or mechanisms that guarantee proper time scheduling and fairnees. I will not get into details, all of it is out there on the web, even on wiki.

Add to that that the operation is PULSE. Pulse is instantenous. It does not "stick". Pulse will wake those now sleeping. If after the pulse another one check the monitor, it will go to sleep.

Now imagine: you have a queue of 5 sleeping threads. One thread (6th) wants now to pulse them, and yet another (7th) wants to check the monitor.

6th and 7th are running in parallel, truly simultaneously, since you have quad-core CPU.

So, tell me, what would happen to the queue's implementtion if the 6th starts pulsing andwaking and removing woken threads from the queue, and in the same time the 7th one starts adding itself there?

To solve that, the internal queues would have to be internally synchronized and locked, so only one thread at time modifies them.

Um wait. We just stumbled upon a case where we wanted to SYNCHRONIZE something, and to do it properly we need to SYNCHRONIZE on another thing? Not good.

Therefore, the actual LOCK is done EXTERNALLY before you talk to the monitor itself. This is to achieve SINGLE LOCKING, instead of introduce several layers of hierarchical locks.

That way it is simplier, faster, and more resource-friendly.

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I think I get synchronization good enough, I was using boost mutex and condition_variable a lot in the past with, I think, correct understanding. I also used the Win32 equivalent primitives. And now in C# the same "concept" is turned upside-down. So you must understand my puzzling. And all of your explanation only makes it more tangled. You want to say that Monitors are between XCHG and poor handler, but now you just made it look exaclty like a poor handler. Thanks though :) –  v.oddou Feb 1 '13 at 10:16
    
IIRC, when using condition variables, to raise/change them you also had to lock them first. Even if it was done completely out of your sight, it was still performed within the API call. Here it is just on the eyes so that you remember about the fact that the API call may instantly put you to sleep, just because the sync is temporarily blocked. –  quetzalcoatl Feb 1 '13 at 10:20
    
Well, that is covered by the two links I put in the question. The first is explaining clearly why notification has to be made after the lock : "prevent useless context switches". Which is also mentioned in the "Linked Question". The MSDN sample also clearly notifies (Wake..) after the lock. –  v.oddou Feb 1 '13 at 10:24
    
Hmm.. after thinking about it a little more, I think I know what bothers you - aren't you too focused on (autoreset)events ? For simple cases, they are in fact very similar to Monitors. However, the main difference is that autoresetevent is notification-only. With autoresetevent, you cannot thread-safely do operations like a "notification-and-statusupdate" because after the notifications the threads might already be running and don't see the status update. You could do a "statusupdate-and-then-notification" of course, but that means that YOU have to control and keep the order manually. –  quetzalcoatl Feb 1 '13 at 10:32
1  
I understand that the source of my bothering can seem like a nitpicking. It is purely coming from my past with POSIX/Win32 implementations of the same concept. Like seen with Marc Gravell, the thing is that C# is acutally pretty far from those system libraries. And that is the reason why it is designed that way. We are abstracted from the concept that I was thinking it was mapping in a direct-to-kernel fashion. Though the thing is that it does not. And that is the answer. It is just a high-level manager of all sync primitives in one big terminology. –  v.oddou Feb 1 '13 at 10:52

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