I've been looking into implementations of atomic reference counting.

Most of the operations are very consistent between libraries, but I've found a surprising variety in the "decrease refcount" operation. (Note that, generally, the only difference between shared and weak decref is which on_zero() is called. Exceptions are noted below.)

If there are other implementations implemented in terms of C11/C++11 model (what does MSVC do?), other than the "we use seq_cst because we don't know any better" kind, feel free to edit them in.

Most of the examples were originally C++, but here I've rewritten them to C, inlined and normalized to the >= 1 convention:

#include <stdatomic.h>
#include <stddef.h>
typedef struct RefPtr RefPtr;
struct RefPtr {
    _Atomic(size_t) refcount;
// calls the destructor and/or calls free
// on a shared_ptr, this also calls decref on the implicit weak_ptr
void on_zero(RefPtr *);

From Boost intrusive_ptr examples and openssl:

void decref_boost_intrusive_docs(RefPtr *p) {
    if (atomic_fetch_sub_explicit(&p->refcount, 1, memory_order_release) == 1) {

It would be possible to use memory_order_acq_rel for the fetch_sub operation, but this results in unneeded "acquire" operations when the reference counter does not yet reach zero and may impose a performance penalty.

But most others ( Boost, libstdc++, libc++ shared ) do something else:

void decref_common(RefPtr *p) {
    if (atomic_fetch_sub_explicit(&p->refcount, 1, memory_order_acq_rel) == 1)

But libc++ does something different for the weak count. Curiously, this is in an external source file:

void decref_libcxx_weak(RefPtr *p) {
    if (atomic_load_explicit(&p->refcount, memory_order_acquire) == 1)

The question, then is: what are the actual differences?

Sub-questions: Are the comments wrong? What do specific platforms do (on aarch64, would ldar be cheaper than dmb ishld? also ia64?)? Under what conditions can weaker versions be used (e.g. if the dtor is a nop, if the deleter is just free, ...)?

See also Atomic Reference Counting and Why is an acquire barrier needed before deleting the data in an atomically reference counted smart pointer?

  • Only doing release unconditionally and acquire conditionally may be a performance benefit, but OTOH, I'd suspect many shared_ptrs only ever have a single reference, so a branch predictor would be trained to execute the acquire speculatively anyway. If there is an efficient instruction for the atomic_fetch_sub_explicit(acq_rel), the combined operation would then be better. – EOF May 5 at 7:41
  • @EOF So your guess is that most shared_ptr are used as heavy, relatively complex, type erased unique_ptr? – curiousguy May 8 at 4:25
  • @curiousguy I wouldn't be surprised. And why not? Most of the time the inefficiency of shared_ptr isn't going to be the bottleneck in terms of speed, so until it shows up in a profile, who cares? – EOF May 8 at 16:22
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    @curiousguy I'm not saying that you shouldn't use unique_ptr where appropriate, I'm saying that it probably isn't being used consistently, and that it probably doesn't matter most of the time. – EOF May 9 at 15:50
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    @JeremyFriesner Of course the library code that create doesn't know whether multiple owners or a single owner will be appropriate for the user, and this is exactly why it should always return a unique_ptr. – curiousguy Jun 11 at 2:40

The libc++ choice is documented in the source code:

NOTE: The acquire load here is an optimization of the very common case where a shared pointer is being destructed while having no other contended references.

libc++ coder observed that most of the time, when the last shared_ptr is destroyed there is no weak_ptr referencing the shared object. As far as I know, and at least on x86, read-modify-write instructions are much more expansive than a read instructions. So, for the most common case, they decided to avoid to perform an expansive and unusefull read-modify-write. Other implementation of the standard library does not perform this optimization.

  • Hm, but that code applies to all weak pointers, if it was inlined the extra test could be avoided. Plus, comments lie. – o11c May 5 at 23:48
  • @o11c From what I have seen, optimization are praticaly disabled when a set of expression involves atomic expressions. – Oliv May 6 at 6:53
  • @Oliv ...for absolutely no good reason. – curiousguy May 8 at 4:31
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    @curiousguy Indeed, for fun, look that horror: godbolt.org/z/yQ35Fp !!!!! Atomics are treated as volatile atomic. There is a confusion between the concept of atomic load and the concept of side effects. The standard is clear about that. There are still poeple preaching that a volatile atomic does not make sense. And those preaches last since such a long time that we can expect that this kind of code pessimization will be always there! – Oliv May 8 at 6:07
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