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I've been led to believe that the GHC implementation of TVars is lock-free, but not wait-free. Are there any implementations that are wait-free (e.g. a package on Hackage)?

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From the Wikipedia page, it seems that wait-freedom is a property of an algorithm, not a data structure. – Daniel Wagner Apr 20 '12 at 3:23
    
@Daniel: Perhaps that's the incorrect usage of the term. What I mean is by wrapping all of your data in TVars makes any algorithm lock-free. I'd like to know if there was a datatype that makes any algoritm wait-free. – Clinton Apr 20 '12 at 3:51

Wait-freedom is a term from distributed computing. An algorithm is wait-free if a thread (or distributed node) is able to terminate correctly even if all input from other threads is delayed/lost at any time.

If you care about consistency, then you cannot guarantee wait-freedom (assuming that you always want to terminate correctly, i.e. guarantee availability). This follows from the CAP theorem [1], since wait-freedom essentially implies partition-tolerance.

[1] http://en.wikipedia.org/wiki/CAP_theorem

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Sounds like a mixup of terms to me. Typically, "wait-free" simply means that all threads make forward progress. For example (in C++, sorry), the function inc is wait-free std::atomic<int> i; void inc(){ i++; } because each thread that enters never stops progressing. Contrast that with a lock-free algorithm (like a lock-free stack), which requires no locks and is atomic, but only progresses one thread at a time (though because of its high-granularity, is quicker in high-load situations). – GManNickG Apr 20 '12 at 7:54
    
@GManNickG: If you just consider inc() as a zero-time atomic operation then I agree, inc() will be wait-free. However, if you look at how the atomicity of inc() is actually implemented it must either entail some locking or some form of "retrying" to guarantee consistency, since there's a chance that 2 threads read the same value simultaneously before one of them writes. So if you look at it at this level, inc() isn't wait-free, because one of the threads needs to reread the value before going forward. – Peter Apr 20 '12 at 8:16
    
Fair enough, I made some assumptions without specifying. But there is hardware-level atomicity, which at the program-level is lock-free and wait-free. – GManNickG Apr 20 '12 at 8:35
    
@GManNickG: Right, with hardware support it's a different story. – Peter Apr 20 '12 at 10:07

Your question "Are there any implementations that are wait-free?" is a bit incomplete. STM (and thus TVar) is rather complex and has support built into the compiler - you can't build it properly with Haskell primitives.

If you're looking for any data container that allows mutation and can be non-blocking then you want IORefs or MVars (but those can block if no value is available).

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You can implement STM yourself. It doesn't need to be hard-wired into the compiler. (Though it's probably more efficient that way.) See issue #15 of The Monad Reader for source code. – MathematicalOrchid Apr 20 '12 at 9:40
    
IORefs can't be empty and won't block, as I understand it. – Ben Millwood Apr 20 '12 at 12:47
    
@Math Haskell has no lock free / CAS primitives for a true ATM afaik, so I'll gladly see MR when I have time. – Thomas M. DuBuisson Apr 20 '12 at 14:54
    
@Ben you're right, I was just refferring to mvars. – Thomas M. DuBuisson Apr 20 '12 at 14:55
    
@MathematicalOrchid Ahh, so Andrew simulated STM behavior using a locking scheme. I would argue this is not STM any more than a well-engineered mechanical duck is a duck - they are fundamentally different in their underlying behavior in ways that matter to users. It was a fun read though, thank you for the pointer. – Thomas M. DuBuisson Apr 20 '12 at 23:29

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