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Stores are release operations and loads are acquire operations for both. I know that memory_order_seq_cst is meant to impose an additional total ordering for all operations, but I'm failing to build an example where it isn't the case if all the memory_order_seq_cst are replaced by memory_order_acq_rel.

Do I miss something, or the difference is just a documentation effect, i.e. one should use memory_order_seq_cst if one intend not to play with a more relaxed model and use memory_order_acq_rel when constraining the relaxed model?

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http://en.cppreference.com/w/cpp/atomic/memory_order has a good example at the bottom that only works with memory_order_seq_cst. Essentially memory_order_acq_rel provides read and write orderings relative to the atomic variable, while memory_order_seq_cst provides read and write ordering globally. That is, the sequentially consistent operations are visible in the same order across all threads.

The example boils down to this:

bool x= false;
bool y= false;
int z= 0;

a() { x= true; }
b() { y= true; }
c() { while (!x); if (y) z++; }
d() { while (!y); if (x) z++; }

// kick off a, b, c, d, join all threads
assert(z!=0);

Operations on z are guarded by two atomic variables, not one, so you can't use acquire-release semantics to enforce that z is always incremented.

  • I don't understand why x=true;y=true;c();d() isn't possible? That should cause it to be 0. Also I don't know why i get 2 a lot as the results. – user34537 Sep 10 '12 at 9:49
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    @acidzombie24, even in that case, z will be 2. – MSN Sep 10 '12 at 20:40
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    @CandyChiu With ack_rel, c() can perceive that x=true; in a() happens before y=true; in b() at the same time d() can perceive that y=true; happens before x=true; (due to lack of "global ordering".) In particular c() can perceive x==true and y==false at the same time d() can perceive y==true and x==false. So z might not be incremented by either of c() or d(). With seq_cst, if c() perceives x=true; happens before y=true;, so does d(). – nodakai Jan 20 '16 at 11:03
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    @MSN You meant int z=0, not bool z=0 – nodakai Jan 20 '16 at 11:04
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    @nodakai, Your explanation is accurate but I think the phrase "happens before" can be misleading since the crux of the issue with acquire-release is that neither of the writes happens-before the other. – jhoffman0x May 1 '18 at 3:50
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On ISAs like x86 where atomics map to barriers, and the actual machine model includes a store buffer:

  • seq_cst stores require flushing the store buffer so this thread's later reads are delayed until after the store is globally visible.
  • acq_rel does not flush the store buffer. Normal x86 loads and stores have essentially acq and rel semantics. (seq_cst plus a store buffer with store forwarding.)

    But x86 atomic RMW operations always get promoted to seq_cst because the x86 asm lock prefix is a full memory barrier. Other ISAs can do relaxed or acq_rel RMWs in asm.

https://preshing.com/20120515/memory-reordering-caught-in-the-act is an instructive example of the difference between a seq_cst store and a plain release store. (It's actually mov + mfence vs. plain mov in x86 asm. In practice xchg is a more efficient way to do a seq_cst store on most x86 CPUs, but GCC does use mov+mfence)


Fun fact: AArch64's STLR release-store instruction is actually a sequential-release. In hardware it has loads/stores with relaxed or seq_cst, as well as a full-barrier instruction.

In theory, STLR only requires draining the store buffer before the next LDAR, not before other operations. i.e. before the next seq_cst load. I don't know if real AArch64 HW implements it this way or if it just drains the store buffer before committing an STLR. (In any case, all earlier stores have to commit before the STLR, but not necessarily before later plain loads.)

So strengthening rel or acq_rel to seq_cst by using LDAR / STLR doesn't need to be expensive.

Some other ISAs (like PowerPC) have more choices of barriers and can strengthen up to mo_rel or mo_acq_rel more cheaply than mo_seq_cst, but their seq_cst can't be as cheap as AArch64; seq-cst stores need a full barrier.

  • "But x86 atomic RMW operations always get promoted to seq_cst because the x86 asm lock prefix is a full memory barrier." What makes you say they are "promoted"? Also the exec could well speculatively load the value (normally) and do the computation as long as it reloads it safely (locked load) later; if the computation is fast that's probably uninteresting but still possible. (I suppose that these things are documented in a purely descriptive way by Intel for existing designs and not for future ones.) – curiousguy Nov 28 '19 at 1:01
  • @curiousguy: the full-memory-barrier nature of the x86 lock prefix is carefully documented by Intel and AMD in their x86 ISA manuals. (Does lock xchg have the same behavior as mfence?). It's definitely guaranteed for future x86 CPUs; how else could compilers make safe future-proof asm? This is what I mean by compilers having to strengthen all RMW operations to seq_cst in the asm, draining the store buffer before the RMW does its thing. – Peter Cordes Nov 28 '19 at 3:03
  • What is guaranteed exactly? That the CPU will not try to get the value already loaded and the computation ready in memory in advance, so speed up a costly RMW, says xdiv (or xcos if the FPU decides to support RMW)? – curiousguy Nov 30 '19 at 4:53
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    @curiousguy: But anyway, if a hypothetical implementation wanted to try loading early to set up for a cheaper atomic exchange to actually implement the RMW, it could only do that speculatively and roll back on mis-speculation (if the line changed before the load was architecturally allowed). Regular loads already work this way, to get performance while preserving strong load ordering. (See the machine_clears.memory_ordering performance counter: Why flush the pipeline for Memory Order Violation caused by other logical processors?) – Peter Cordes Nov 30 '19 at 5:18
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    @PeterCordes - I don't even think it's hypothetical: I think that's how atomic operations are (sometimes) implemented on current Intel x86. That is, that they load the cache line in an optimistic locked state, do the "front end" of the RMW (including the ALU op), and then in the "back end" of the RMW they verify everything was OK in the execute-at-retire op that ensures all the ordering. This works great when the location is not contended. If this fails a lot, a predictor will switch modes to doing the whole thing at retire, which causes a bigger bubble in the pipeline (hence "sometimes"). – BeeOnRope Nov 30 '19 at 18:16
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Still use the definition and example from memory_order. But replace memory_order_seq_cst with memory_order_release in store and memory_order_acquire in load.

Release-Acquire ordering guarantees everything that happened-before a store in one thread becomes a visible side effect in the thread that did a load. But in our example, nothing happens before store in both thread0 and thread1.

x.store(true, std::memory_order_release); // thread0

y.store(true, std::memory_order_release); // thread1

Further more, without memory_order_seq_cst, the sequential ordering of thread2 and thread3 are not guaranteed. You can imagine they becomes:

if (y.load(std::memory_order_acquire)) { ++z; } // thread2, load y first
while (!x.load(std::memory_order_acquire)); // and then, load x

if (x.load(std::memory_order_acquire)) { ++z; } // thread3, load x first
while (!y.load(std::memory_order_acquire)); // and then, load y

So, if thread2 and thread3 are executed before thread0 and thread1, that means both x and y stay false, thus, ++z is never touched, z stay 0 and the assert fires.

However, if memory_order_seq_cst enters the picture, it establishes a single total modification order of all atomic operations that are so tagged. Thus, in thread2, x.load then y.load; in thread3, y.load then x.load are sure things.

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