Referring to a (slightly dated) paper by Hans Boehm, under "Atomic Operations". It mentions that the memory model (proposed at the time) would not prevent an optimizing compiler from combining a sequence of loads, or stores, on the same variable from being combined into a single load. His example is as follows (updated to hopefully correct current syntax):


atomic<int> v;

The code

while( v.load( memory_order_acquire ) ) { ... }

Could be optimized to:

int a = v.load(memory_order_acquire);
while(a) { ... }

Obviously this would be bad, as he states. Now my question is, as the paper is a bit old, does the current C++0x memory model prevent this type of optimization, or is it still technically allowed?

My reading of the standard would seem to lean towards it being disallowed, but the use "acquire" semantics makes it less clear. For example if it were "seq_cst" the model seems to guarantee that the load must partake in a total ordering on the access and loading the value only once would thus seem to violate ordering (as it breaks the sequence happens before relationship).

For acquire I interpret 29.3.2 to mean that this optimization can not occur, since any "release" operation must be observed by the "acquire" operation. Doing only one acquire would seem not valid.

So my question is whether the current model (in the pending standard) would disallow this type of optimization? And if yes, then which part specifically forbids it? If no, does using a volatile atomic solve the problem?

And for bonus, if the load operation has a "relaxed" ordering is the optimization then allowed?


The C++0x standard attempts to outlaw this optimization.

The relevant words are from 29.3p13:

Implementations should make atomic stores visible to atomic loads within a reasonable amount of time.

If the thread that is doing the load only ever issues one load instruction then this is violated, as if it misses the write the first time, it will never see it. It doesn't matter which memory ordering is used for the load, it is the same for both memory_order_seq_cst and memory_order_relaxed.

However, the following optimization is allowed, unless there is something in the loop that forces an ordering:

while( v.load( memory_order_acquire ) ) {
    for(unsigned __temp=0;__temp<100;++__temp) {
        // original loop body goes here

i.e. the compiler can generate code that executes the actual loads arbitrarily infrequently, provided it still executes them. This is even permitted for memory_order_seq_cst unless there are other memory_order_seq_cst operations in the loop, since this is equivalent to running 100 iterations between any memory accesses by other threads.

As an aside, the use of memory_order_acquire doesn't have the effect you describe --- it is not required to see release operations (other than by 29.3p13 quoted above), just that if it does see the release operation then it imposes visibility constraints on other accesses.

  • About the acquire semantics: Yes, I mis-worded that bit -- the release being visible establishes the sequenced relationship, but there is technically no guarantee I ever see it at all (except that such a compiler/cpu would quickly lose all market share). – edA-qa mort-ora-y Jul 13 '11 at 16:25
  • About 29.3p13, I also read this bit and was tempted to think it makes this guarantee. But because it uses the term reasonable time it has no value and could just be taken out of the standard. It's a meaningless term which means it can't be relied upon in low-latency situations. For example, in my current project, if this time is any more than 10s of nanoseconds there is no value whatsoever in the atomic operation (say compared to a lock). – edA-qa mort-ora-y Jul 13 '11 at 16:27
  • Do you agree then, as I think n.m would, that making this atomic a volatile prevents the compiler from doing the optimization you have shown? – edA-qa mort-ora-y Jul 13 '11 at 16:30
  • @edA: while reasonable amount of time is not strongly defined, it pretty clearly cannot be infinite. When talking about real-time constraints, the standard makes no claim at all about how fast things must run, but leaves things entirely up to the implementation. – Chris Dodd Jul 13 '11 at 17:56
  • Chris is right: the details of the timings are entirely a matter for Quality of Implementation. For one thing, the reading thread might not even be scheduled by the OS for several milliseconds. In a real-time system, I would expect that latencies would be short, and well-documented. – Anthony Williams Jul 13 '11 at 20:50

Right from the very paper you're linking:

Volatiles guarantee that the right number of memory operations are performed.

The standard says essentially the same:

Access to volatile objects are evaluated strictly according to the rules of the abstract machine.

This has always been the case, since the very first C compiler by Dennis Ritchie I think. It has to be this way because memory mapped I/O registers won't work otherwise. To read two characters from your keyboard, you need to read the corresponding memory mapped register twice. If the compiler had a different idea about the number of reads it has to perform, that would be too bad!

  • 1
    Correct, but the question is must we put volatile on our atomic data to ensure it is read correctly? The inter-thread synchronization requirements seem to imply we might not. Yet on the same hand the atomics do have volatile qualified forms of their functions. – edA-qa mort-ora-y Jul 13 '11 at 11:27
  • I think if you want the code while(v.load(memory_order_acquire)){} to most portably work with an absolute guarantee, then you have to use volatile. You need not use volatile in other cases, such as implementing the double-lock pattern, because there's a total order in the check-lock-check sequence and the compiler cannot reorder it to check-check-lock or whatever, even without volatile. Or so is my understanding anyway. – n.m. Jul 13 '11 at 12:42

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