xchg are both valid ways to implement a sequential-consistency store on x86. The implicit
lock prefix on an
xchg with memory makes it a full memory barrier, like all atomic RMW operations on x86. (Unfortunately for other use-cases, x86 doesn't provide a way to do a relaxed or acq_rel atomic increment, only seq_cst.)
mov is not sufficient; it only has release semantics, not sequential-release. (Unlike AArch64's
stlr instruction, which does do a sequential-release store. This choice is obviously motivated by C++11 having seq_cst as the default memory ordering. But AArch64's normal store is much weaker; relaxed not release.) See Jeff Preshing's article on acquire / release semantics, and note that regular release allows reordering with later operations. (If the release-store is releasing a lock, it's ok for later stuff to appear to happen inside the critical section.)
There are performance differences between
xchg on different CPUs, and maybe in the hot vs. cold cache and contended vs. uncontended cases. And/or for throughput of many operations back to back in the same thread vs. for one on its own, and for allowing surrounding code to overlap execution with the atomic operation.
On Intel Skylake hardware,
mfence blocks out-of-order execution of independent ALU instructions, but
xchg doesn't. (See my test asm + results in the bottom of this SO answer). Intel's manuals don't require it to be that strong; only
lfence is documented to do that. But as an implementation detail, it's very expensive for out-of-order execution of surrounding code on Skylake.
I haven't tested other CPUs, and this may be a result of a microcode fix for erratum SKL079, SKL079 MOVNTDQA From WC Memory May Pass Earlier MFENCE Instructions. The existence of the erratum basically proves that SKL used to be able to execute instructions after MFENCE. I wouldn't be surprised if they fixed it by making MFENCE stronger in microcode, kind of a blunt instrument approach that significantly increases the impact on surrounding code.
I've only tested the single-threaded case where the cache line is hot in L1d cache. (Not when it's cold in memory, or when it's in Modified state on another core.)
xchg has to load the previous value, creating a "false" dependency on the old value that was in memory. But
mfence forces the CPU to wait until previous stores commit to L1d, which also requires the cache line to arrive (and be in M state). So they're probably about equal in that respect, but Intel's
mfence forces everything to wait, not just loads.
AMD's optimization manual recommends
xchg for atomic seq-cst stores. I thought Intel recommended
mfence, which gcc uses, but Intel's compiler also uses
When I tested, I got better throughput on Skylake for
xchg than for
mfence in a single-threaded loop on the same location repeatedly. See Agner Fog's microarch guide and instruction tables for some details, but he doesn't spend much time on locked operations.
See gcc/clang/ICC/MSVC output on the Godbolt compiler explorer for a C++11 seq-cst
my_atomic = 4; gcc uses
mfence when SSE2 is available. (use
-m32 -mno-sse2 to get gcc to use
xchg too). The other 3 compilers all prefer
xchg with default tuning, or for
znver1 (Ryzen) or
The Linux kernel uses
So it appears that gcc should be using
xchg, unless they have some benchmark results that nobody else knows about.
Another interesting question is how to compile
atomic_thread_fence(mo_seq_cst);. The obvious option is
lock or dword [rsp], 0 is another valid option (and used by
gcc -m32 when MFENCE isn't available). The bottom of the stack is usually already hot in cache in M state. The downside is introducing latency if a local was stored there. (If it's just a return address, return-address prediction is usually very good so delaying
ret's ability to read it is not much of a problem.) So
lock or dword [rsp-4], 0 could be worth considering in some cases. (gcc did consider it, but reverted it because it makes valgrind unhappy. This was before it was known that it might be better than
mfence even when
mfence was available.)
All compilers currently use
mfence for a stand-alone barrier when it's available. Those are rare in C++11 code, but more research is needed on what's actually most efficient for real multi-threaded code that has real work going on inside the threads that are communicating locklessly.
But multiple source recommend using
lock add to the stack as a barrier instead of
mfence, so the Linux kernel recently switched to using it for the
smp_mb() implementation on x86, even when SSE2 is available.
See https://groups.google.com/d/msg/fa.linux.kernel/hNOoIZc6I9E/pVO3hB5ABAAJ for some discussion, including a mention of some errata for HSW/BDW about
movntdqa loads from WC memory passing earlier
locked instructions. (Opposite of Skylake, where it was
mfence instead of
locked instructions that were a problem. But unlike SKL, there's no fix in microcode. This may be why Linux still uses
mfence for its
mb() for drivers, in case anything ever uses NT loads to copy back from video RAM or something but can't let the reads happen until after an earlier store is visible.)
In Linux 4.14,
mb(). That uses mfence is used if available, otherwise
lock addl $0, 0(%esp).
__smp_store_mb (store + memory barrier) uses
xchg (and that doesn't change in later kernels).
In Linux 4.15,
lock; addl $0,-4(%esp) or
%rsp, instead of using
mb(). (The kernel doesn't use a red-zone even in 64-bit, so the
-4 may help avoid extra latency for local vars).
mb() is used by drivers to order access to MMIO regions, but
smp_mb() turns into a no-op when compiled for a uniprocessor system. Changing
mb() is riskier because it's harder to test (affects drivers), and CPUs have errata related to lock vs. mfence. But anyway,
mb() uses mfence if available, else
lock addl $0, -4(%esp). The only change is the
- In Linux 4.16, no change except removing the
#if defined(CONFIG_X86_PPRO_FENCE) which defined stuff for a more weakly-ordered memory model than the x86-TSO model that modern hardware implements.
x86 & x86_64. Where a store has an implicit acquire fence
You mean release, I hope.
my_atomic.store(1, std::memory_order_acquire); won't compile, because write-only atomic operations can't be acquire operations. See also Jeff Preshing's article on acquire/release semantics.
asm volatile("" ::: "memory");
No, that's a compiler barrier only; it prevents all compile-time reordering across it, but doesn't prevent runtime StoreLoad reordering, i.e. the store being buffered until later, and not appearing in the global order until after a later load. (StoreLoad is the only kind of runtime reordering x86 allows.)
Anyway, another way to express what you want here is:
my_atomic.store(1, std::memory_order_release); // mov
// with no operations in between, there's nothing for the release-store to be delayed past
std::atomic_thread_fence(std::memory_order_seq_cst); // mfence
Using a release fence would not be strong enough (it and the release-store could both be delayed past a later load, which is the same thing as saying that release fences don't keep later loads from happening early). A release-acquire fence would do the trick, though, keeping later loads from happening early and not itself being able to reorder with the release store.
Related: Jeff Preshing's article on fences being different from release operations.
But note that seq-cst is special according to C++11 rules: only seq-cst operations are guaranteed to have a single global / total order which all threads agree on seeing. So emulating them with weaker order + fences might not be exactly equivalent in general on the C++ abstract machine, even if it is on x86. (On x86, all store have a single total order which all cores agree on. See also Globally Invisible load instructions: Loads can take their data from the store buffer, so we can't really say that there's a total order for loads + stores.)