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When we talk about atomic variables, such as C++11's atomic<>, is it lock free? Or is lock-freeness something different? If I manage a queue with atomic variables, will it be slower than a lock-free queue?

share|improve this question… – user195488 Apr 11 '12 at 13:33
It's also answered here:… it seems they are lock-free. – user195488 Apr 11 '12 at 13:36
up vote 31 down vote accepted

The standard does not specify if atomic objects are lock-free. On a platform that doesn't provide lock-free atomic operations for a type T, atomic<T> objects may be implemented using a mutex, which wouldn't be lock-free. In that case, any containers using these objects in their implementation would not be lock-free either.

The standard does provide a way to check if an atomic<T> variable is lock-free: you can use var.is_lock_free() or atomic_is_lock_free(&var). These functions are guaranteed to always return the same value for the same type T on a given program execution. For basic types such as int, There are also macros provided (e.g. ATOMIC_INT_LOCK_FREE) which specify if lock-free atomic access to that type is available.

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Out of interest, are there platforms that don't provide any lockless native atomics, or do you just mean that atomic<T> may not be natively atomic for all sizes of T? I can't see how a platform with no genuine native atomics would implement mutexes in the first place ... – Useless Apr 11 '12 at 13:51
@Useless: it could be that you only have a 1-byte atomic on an embedded platform. So something like std::atomic<char> would be lock-free. However, if 32-bit integers are simulated by doing 4 byte-operations that isn't atomic. So most likely std::atomic<int> won't be lock-free. However, you can make a mutex (e.g. a spin lock) with the byte atomic. – KillianDS Apr 11 '12 at 13:54
@Useless: I meant that lock-free operations would not be supported for all object sizes - I've edited to clarify. I suppose in theory a platform could provide native lock/unlock operations without having lockless atomic operations, but I'm not aware of such platforms. – interjay Apr 11 '12 at 14:02
Some platforms only have atomic exchange instructions. You can use this for a mutex, and std::atomic_flag (which is required to be lock-free), but not for a general atomic (as it can't do a plain load). – Anthony Williams Apr 11 '12 at 16:38

Lock-free usually applies to data structures shared between multiple threads, where the synchronisation mechanism is not mutual exclusion; the intention is that all threads should keep making some kind of progress instead of sleeping on a mutex.

atomic<T> variables don't use locks (at least where T is natively atomic on your platform), but they're not lock-free in the sense above. You might use them in the implementation of a lock-free container, but they're not sufficient on their own.

Eg, atomic<queue<T>> wouldn't suddenly make a normal std::queue into a lock-free data structure. You could however implement a genuinely lock-free atomic_queue<T> whose members were atomic.

Note that even if atomic<int> is natively atomic and not emulated with a lock on your platform, that does not make it lock-free in any interesting way. Plain int is already lock-free in this sense: the atomic<> wrapper gets you explicit control of memory ordering, and access to hardware synchronisation primitives.

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So a spinlock is lock-free when I implement it using atomic operations? I guess you never yield to the scheduler, but I'm not sure that's what lock-free means in normal use. – Useless Apr 11 '12 at 14:04
I removed my downvote btw. Your edit made more clear what you meant and I think we were discussing on other levels. – KillianDS Apr 11 '12 at 14:18
Cheers - maybe I'm conflating lock-free with non-blocking, it definitely feels ambiguous when talking about the primitives themselves, rather than the algorithm using them. – Useless Apr 11 '12 at 14:23
The term "wait-free" is used to differentiate lock-free algorithms that always make forward progress on all threads (ie. don't block). Spinlocks are certainly lock-free but not wait-free - in fact, the same atomic value check (CAS) is used commonly in lock-free algorithms. – ex0du5 Apr 11 '12 at 16:11
I disagree with your last paragraph: Since plain int is not thread-safe, it is meaningless to say that it is lock-free. But atomic<int> is thread-safe, and so it is certainly meaningful whether it is lock-free or not. – interjay Apr 11 '12 at 16:24

Marketting and cool factor aside, it does not make a twopenny toss of a difference whether the magic C++ syntactic (brown) sugar ends up implementing a direct bus lock or a mutex (which might rely on bus locks but, as a commentator noted, takes advantage of OS internals to do it in a more efficient way), or nothing at all if you are unlucky enough to run on a single-procesor architecture.

Mutex are semantically lock free already. They implement all you might dream of in terms of scheduler-niceness, namely priority inversion handling and reentrancy. You cannot deadlock on a mutex (well actually you might if you tried very hard, but as far as guarding a variable is concerned, you won't), and using a mutex will not have any more noticeable side effect on the other processes or the operating system than a bus-locked variable.

The only difference is that a programmer might (by design or by mistake) hold a mutex for an unreasonable amount of time, while an equally incompetent programmer might poll on a "Wait-free" variable and achieve the same silly results, with a catastrophic bus slowdown that will put a lot more stress on the system as a whole than a faulty mutex use (OK, my previous allusion to a BSOD was just a juvenile provokation, though I still suspect some drivers might not react very kindly to heavy bus contention). Anyway, this problem is soon solved when the mutex calls are wrapped around a linear access to a reasonably small amount of memory.

"Lock free" is selling dreams to wanabee hardboiled programmers. I find it quite amusing that a mechanism that indeeds relies on locking the multiprocessor bus might be called that.

What a "Lock free" variable access does is pester the hardware by neutering the bus cache system, forbidding bus access scheduling, and generally disabling all the mechanisms that allow your average multiprocessor bus to do a decent job.
Each time you're accessing a "Lock free" magic variable, you are pelting a handful of sand into the bus controller's cogwheels.

Like any concurrent access mechanism, bus-locked variables (sorry, I meant "Lock free variables") are costly and have potential negative side effects that are extremely difficult to predict or even diagnose.

As long as you're using these new shiny toys as you would mutexes, i.e. very sparsely and only for a few good reasons (and no, acting the super cool Mr wait-free is not one of them), it's fine.

But if you start sprinkling bus locks all over the place, or (God forbids!) polling bus-locked variables as a cheap and easy replacement for proper synchronization objects (what the super cool Mr wait-free might call "brewing your own homemade spinlocks in 3 easy steps"), you will only manage to turn whatever cutting edge hardware your code runs on into a circa 1995 Pentium I emulator.

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A mutex does not rely on bus locks, god forbid that would be the case (it's way too long to be usable). Locks are maintained inside the core through snoops on most modern CPUs. – Leeor Jan 12 '14 at 12:26
I don't understand the BSOD comment. Can you give example code for how to cause a BSOD the way you mentioned? – Mehrdad Jan 12 '14 at 12:29
@Leeor You're right, I corrected it to "might rely". – kuroi neko Jan 12 '14 at 12:29
@kuroineko, that's a very rare case (like trying to lock over a line split value maybe, a page split definitely), it should hardly ever happen in any reasonable code. I do agree that the term lock free is a little bit abused, but this came out as a little too much of a rant - you should put/link some examples with profiling results for this to be more constructive – Leeor Jan 12 '14 at 12:34
@Leeor Ah well, a bit of rant is sometimes needed to offset the hype,IMHO. I've added an example benchmark discussion in an attempt at moderate informativeness/constructiveness too. The main point I was trying to make is, the complexity and potential dangers of low level mechanisms should remain clear beneath the apparent ease of use new syntactic sugar like C++11 interfaces offer. – kuroi neko Jan 12 '14 at 12:49

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