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I have read the doc of std::memory_order_relaxed.

One part of explanation of Relaxed ordering is ....

// Thread 1:
r1 = y.load(memory_order_relaxed); // A
x.store(r1, memory_order_relaxed); // B
// Thread 2:
r2 = x.load(memory_order_relaxed); // C 
y.store(42, memory_order_relaxed); // D

and the explanation of this is said ...

[It] is allowed to produce r1 == r2 == 42. In particular, this may occur if D is completed before C in thread 2, either due to compiler reordering or at runtime.

I have understood the explanation, and try to test on my computer as following code:

std::atomic<int> x = {0};
std::atomic<int> y = {0};

int r1, r2;

void task1() {
    // Thread 1:
    r1 = y.load(memory_order_relaxed); // A
    x.store(r1, memory_order_relaxed); // B
}

void task2() {
   // Thread 2:
    r2 = x.load(memory_order_relaxed); // C 
    y.store(42, memory_order_relaxed); // D
}


int main()
{
    std::thread t2 (task2);
    std::thread t1 (task1);

    t1.join();
    t2.join();

    cout << "r1: " << r1
        << "\nr2: " << r2 << endl;

    return 0;
}

The results of this code is never r1 == r2 == 42, which is said that it's a possible behavior in that doc.

Is there any wrong in this code? Or, is there any misunderstanding?

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  • 1
    It is possible that I will win 1000000 in the lottery tomorrow. But it is not likely. I can try all my life and never hit the jackpot. Someone however will win it. – n. 'pronouns' m. Sep 6 '18 at 10:08
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    The memory ordering on x86 is at minimum acquire-release. So you will not see r1==r2==42 on a classical computer. Maybe if you target an ARM CPU you could see it. – Oliv Sep 6 '18 at 11:03
  • @Olive That's not precisely true. The hardware will never reorder these operations, but the compiler is allowed to reorder them (on different atomics), according to the language specification. The observed behavior depends on whether the compiler actually does that. – Arne Vogel Sep 6 '18 at 11:11
  • @Oliv: Also on multi-socket setups? You typically have limited non-uniform memory access; each memory module connects directly to only a single CPU. – MSalters Sep 6 '18 at 12:25
  • @ArneVogel In theory yes. But until nowaday, all compilers treats atomics as if they were also declared volatile. For exemple, compilers do not even optimize away two successives stored on a single atomic performed inside the same function, even if the standard alowes that. – Oliv Sep 6 '18 at 12:45
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Or, is there any misunderstanding?

Yes there is one. What std::memory_order_relaxed allows in your program is for an implementation (a compiler) targeting an architecture, to produce a program which may observe the side effect r1 == r2 == 42.

An implementation does not have to produce such a program, and such a program does not have to produce that side effect; it is a possible outcome anyway.

How to test the behavior of std::memory_order_relaxed?

I cannot see a general solution to this question. You can only check that the side effect you observes matches with the specs of std::memory_order_relaxed.

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3
  • It seems the same results of using memory_order_relaxed and memory_order_seq_cst in high level implementation instead of low level (like compiler). So, when should memory_order_relaxed be actually used ? Or, generally, is it just okay to use default memory_order (seq_cst) in high level ? – sheucm Sep 6 '18 at 9:44
  • @eric_hsu it's well explained in the page you linked: The default behavior of all atomic operations in the library provides for sequentially consistent ordering (see discussion below). That default can hurt performance, but the library's atomic operations can be given an additional std::memory_order argument to specify the exact constraints, beyond atomicity, that the compiler and processor must enforce for that operation. – YSC Sep 6 '18 at 9:46
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    @eric_hsu you may be operating on an architecture which always guarantees sequential consistency for atomic operations. Or the relative timings of your various threads have not yet occurred just so in a manner that causes the behaviour you are looking for. – Caleth Sep 6 '18 at 9:51
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Your code is a bit naive because by the time the 2nd thread starts the 1st one may have completed. The threads need to run these pieces of code truly concurrently.

For r1 == r2 == 42 to be true it requires load C to be reordered past store D, x86 does not do loads reordered after stores currently, so that you may never observe this kind of reordering on this platform (unless the compiler reorders C with D).

ARM and PowerPC, on the other hand, have weaker memory models. See Runtime memory ordering table.

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5
  • This is imprecise for the same reason as Oliv's previous comment is. See my reply in the question's comment thread. – Arne Vogel Sep 6 '18 at 11:24
  • @ArneVogel I do not think your comment is accurate. In particular, the hardware will never reorder these operations is false on PowerPC and ARM. – Maxim Egorushkin Sep 6 '18 at 11:27
  • Context matters… I responded to Oliv's statement about x86. The point however is that the C++ implementation (i.e. in this case, usually, the compiler) may also reorder relaxed operations on different atomic variables, even if the hardware guarantees acquire-loads and release-stores, unless other synchronization mechanisms are used. IOW, r1 == r2 == 42 is actually possible on x86. – Arne Vogel Sep 6 '18 at 11:37
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    @ArneVogel The compiler can reorder C and D, true. But I fail to see a reason why it would do so here. There must be a reason for the compiler to do this reordering (e.g. faster code, register pressure). – Maxim Egorushkin Sep 6 '18 at 11:41
  • Indeed, there's no reason here to do or not to do it. The standard simply allows it, but generally it allows several kinds of behavior of atomics that don't actually happen in practice. An extreme example are the infamous "out-of-thin-air" loads, which are discouraged ("should" vs. "shall"/"must") but not forbidden. – Arne Vogel Sep 6 '18 at 11:52

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