The definitions for std::atomic<> seem to show its obvious usefulness for primitive or perhaps POD-types.

When would you actually use it for classes?

When should you avoid using it for classes?


The operations std::atomic makes available on any trivially copyable type are pretty basic. You can construct and destroy atomic<T>, you can ask if the type is_lock_free(), you can load and store copies of T, and you can exchange values of T in various ways. If that's sufficient for your purpose then you might be better off doing that than holding an explicit lock.

If those operations aren't sufficient, if for example you need to atomically perform a sequence operations directly on the value, or if the object is large enough that copying is expensive, then instead you would probably want to hold an explicit lock which you manage to achieve your more complex goals or avoid doing all the copies that using atomic<T> would involve.

// non-POD type that maintains an invariant a==b without any care for
// thread safety.
struct T { int b; }
struct S : private T {
    S(int n) : a{n}, b{n} {}
    void increment() { a++; b++; }
    int a;

std::atomic<S> a{{5}}; // global variable

// how a thread might update the global variable without losing any
// other thread's updates.
S s = a.load();
S new_s;
do {
    new_s = s;
    new_s.increment(); // whatever modifications you want
} while (!a.compare_exchange_strong(s, new_s));

As you can see, this basically gets a copy of the value, modifies the copy, then tries to copy the modified value back, repeating as necessary. The modifications you make to the copy can be as complex as you like, not simply limited to single member functions.

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    +1 for a specific use case - so making S atomic is effectively like putting mutex locks on all methods of S? const and non-const methods? – kfmfe04 Dec 16 '12 at 18:22
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    @kfmfe04: You need to call a.load() to get your S, and after that you are unguarded and each method call is not guarded. All you're getting is load/store into 'a'. – VoidStar Dec 18 '14 at 22:38
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    @kfmfe04 It's not like a mutex on each individual method. For example you can call multiple methods and apply the results as a single atomic transaction. What's going on is that you get a local, non-shared copy, you modify the local copy however you like, and then you attempt copy the modified data back into the shared variable. – bames53 Dec 19 '14 at 6:13
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    The loop does load the value: compare_exchange_strong either succeeds in updating the atomic, or it replaces the value in the 'expected' argument with the newly observed value so that you know what to expect next time around. So if the exchange fails, the new value is loaded into s, then the loop copies the new value, makes its change again which may have a different result from the previous iteration, and attempts to store the new value. – bames53 Nov 3 '15 at 15:39
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    @pocketbroadcast Thanks for the ! correction. The memcpy requirement is already referred to (in the first sentence as 'trivially copiable'). I think it's better to leave discussion of the specifics of compare_exchange to more complete documentation, since there's more to it than just the load. For example here's some discussion of an issue with compare_exchange that even some experts took time to fully grasp. – bames53 Nov 3 '15 at 17:12

It works for primitive and POD types. The type must be memcpy-able, so more general classes are out.

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    +1 ty - I didn't know this (obviously, or I wouldn't have posted the OP)... – kfmfe04 Dec 14 '12 at 20:18
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    All that's required seems to be that the type is trivially copyable. POD types are stricter than that, so many non-POD types can be used with atomic<T>. – bames53 Dec 14 '12 at 20:41
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    The copy constructor of your type must be noexcept because the std::atomic constructor given an initial value is noexcept but is passed the initial value by-value. – Raedwald Dec 5 '17 at 23:01

The standard say that

Specializations and instantiations of the atomic template shall have a deleted copy constructor, a deleted copy assignment operator, and a constexpr value constructor.

If that is strictly the same as the answer by Pete Becker, I'm not sure. I interpret this such that you are free to specialize on your own class (not only memcpy-able classes).

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    I think you meant to quote paragraph 1 instead: "There is a generic class template atomic<T>. The type of the template argument T shall be trivially copyable (3.9)," because paragraph 3, the paragraph you quote, doesn't say the same thing or even specify any requirements on the types you may use with the generic class template atomic<T>. – bames53 Dec 14 '12 at 20:38
  • @bames53 actually, the question is unclear if it's about the generic atomic<T> class or the interface it provides. You could still re-use the interface by providing your own specialization. – KillianDS Dec 14 '12 at 20:44
  • Hm. No, I did not copy the wrong paragraph. I didn't interpret that first paragraph as clearly being demanded also for specializations. – Johan Lundberg Dec 14 '12 at 20:44
  • @JohanLundberg - no, it's not the same. That's a constraint on implementations, not on the types that the template is instantiated with. – Pete Becker Dec 14 '12 at 20:48
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    The implementation of atomic in the standard library requires that T be memcpyable; that's how std::atomic copies values. The reason for that is to avoid calling out into user code through an assignment operator, since that could lead to deadlock. – Pete Becker Dec 14 '12 at 20:54

I'd prefer std::mutex for this kind of scenarios. Nevertheless I've tried a poor mans benchmark to profile a version with std::atomics and std::mutex in a single threaded (and thus perfectly sync) environment.

#include <chrono>
#include <atomic>
#include <mutex>

std::mutex _mux;
int i = 0;
int j = 0;
void a() {
    std::lock_guard<std::mutex> lock(_mux);

struct S {
    int k = 0;
    int l = 0;

    void doSomething() {

std::atomic<S> s;
void b() {
    S tmp = s.load();
    S new_s;
    do {
        new_s = tmp;
        //new_s.doSomething(); // whatever modifications you want
    } while (!s.compare_exchange_strong(tmp, new_s));

void main(void) {

    std::chrono::high_resolution_clock clock;

    auto t1 = clock.now();
    for (int cnt = 0; cnt < 1000000; cnt++)
    auto diff1 = clock.now() - t1;

    auto t2 = clock.now();
    for (int cnt = 0; cnt < 1000000; cnt++)
    auto diff2 = clock.now() - t2;

    auto total = diff1.count() + diff2.count();
    auto frac1 = (double)diff1.count() / total;
    auto frac2 = (double)diff2.count() / total;

on my system the version using std::mutex was faster than the std::atomic approach. I think this is caused by the additional copying of the values. Further, if used in a multithreaded environment, the the busy looping can affect performance too.

Summing up, yes it is possible to use std::atomic with various pod types, but in most cases std::mutex is the weapon of choice, as it is intentionally easier to understand what is going on, and therefore is not as prone to bugs as the version presented with the std::atomic.


With Visual Studio 2017 I have experienced compiler error C2338 due to "alignment" issues when attempting to use std::atomic with a class; you're much better off using a std::mutex which I ended up doing anyway.

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