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The following excerpt from the current draft shows what I mean:

namespace std {
    typedef struct atomic_bool {
        bool is_lock_free() const volatile;
        bool is_lock_free() const;
        void store(bool, memory_order = memory_order_seq_cst) volatile;
        void store(bool, memory_order = memory_order_seq_cst);
        bool load(memory_order = memory_order_seq_cst) const volatile;
        bool load(memory_order = memory_order_seq_cst) const;
        operator bool() const volatile;
        operator bool() const;
        bool exchange(bool, memory_order = memory_order_seq_cst) volatile;
        bool exchange(bool, memory_order = memory_order_seq_cst);
        bool compare_exchange_weak(bool&, bool, memory_order, memory_order) volatile;
        bool compare_exchange_weak(bool&, bool, memory_order, memory_order);
        bool compare_exchange_strong(bool&, bool, memory_order, memory_order) volatile;
        bool compare_exchange_strong(bool&, bool, memory_order, memory_order);
        bool compare_exchange_weak(bool&, bool, memory_order = memory_order_seq_cst) volatile;
        bool compare_exchange_weak(bool&, bool, memory_order = memory_order_seq_cst);
        bool compare_exchange_strong(bool&, bool, memory_order = memory_order_seq_cst) volatile;
        bool compare_exchange_strong(bool&, bool, memory_order = memory_order_seq_cst);
        atomic_bool() = default;
        constexpr atomic_bool(bool);
        atomic_bool(const atomic_bool&) = delete;
        atomic_bool& operator=(const atomic_bool&) = delete;
        atomic_bool& operator=(const atomic_bool&) volatile = delete;
        bool operator=(bool) volatile;
    } atomic_bool;

Volatile is transitive. Thus, you cannot call a non-volatile member function from an volatile object. On the other hand, you calling a volatile member function from an non-volatile object is allowed.

So, is there any implementation difference between the volatile and non-volatile member functions in the atomic classes? In other words, is there any need for the non-volatile overload?

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@GMan: because otherwise the functions couldn't be called on volatile data. ;) –  jalf Feb 2 '11 at 9:08
@jalf: Ha, yes, but since the operations the type itself makes are atomic (and hence observable), why would we make a volatile atomic<>? I think I'm missing something major. –  GManNickG Feb 2 '11 at 9:11
@GMan: but why shouldn't it be allowed? Suppose you have an atomic<> as a member of another struct, and a volatile instance is created? Then all its members will implicitly be volatile as well, and without the volatile overloads, your shiny new atomic class would be useless. :) –  jalf Feb 2 '11 at 13:53
@GMan: exactly. If the object behaves as if it's volatile, then it should also work if I add the volatile qualifier, shouldn't it? Would you also argue that "there'd be no point in marking members of a class const if the class is semantically constant anyway"? It makes no difference, other than to allow the class to keep working in a context where the relevant qualifier is present –  jalf Feb 3 '11 at 17:21
@jalf: "If the object behaves as if it's volatile, then it should also work if I add the volatile qualifier, shouldn't it" Perhaps, but my question is why we need to even support that, if the addition of they keyword makes no difference anyway. Your const example is great for showing why we need const on a member function, but what if we had a type that was inherently const? (Like, say, std::integral_constant.) What good is it to make an instance of that const? –  GManNickG Feb 3 '11 at 22:07

2 Answers 2

I think that the volatile overloads exist for efficiency reasons. Volatile reads and writes are inherently more expensive than non-volatile reads and writes in C++0x, since the memory model puts some stringent requirements that prevent caching of values of volatile variables. If all the functions were only marked volatile, then the code couldn't necessarily make certain optimizations that would otherwise improve performance. Having the distinction allows the compiler to optimize non-volatile reads and writes when possible while degrading gracefully when volatile reads and writes are required.

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The volatile qualifier just prevents compiler optimizations. Furthermore, as far as I know, volatile qualifier applied to member functions only allows the call of this method from volatile objects and doesn't effect resulting code. –  0xbadf00d Feb 2 '11 at 5:34
@FrEEzE2046- In C++0x the definition of volatile is a lot more rigidly specified and does actually mean more than just "don't optimize." Also, the more precise meaning of the volatile modifier on a member function is that the this pointer is volatile, and so any accesses to member variables that occur in the function would implicitly become volatile –  templatetypedef Feb 2 '11 at 5:38
Okay, that means any access to the object, when calling a volatile member function, wouldn't be optimized? (Volatile description is: "Access to volatile objects are evaluated strictly according to the rules of the abstract machine.") –  0xbadf00d Feb 2 '11 at 6:52
@FrEEzE2046- Yes, that's correct. –  templatetypedef Feb 2 '11 at 7:02
+1 Whether to add the non-volatile versions was one of the open questions in earlier drafts. It was added specifically due to requests from compiler implementors. See open-std.org/jtc1/sc22/wg21/docs/papers/2009/n2925.html#LWG1147. –  stephan Mar 3 '11 at 17:28

First, it sounds redundant to make a volatile std::atomic. Actually, I can imagine an useful situation. Assuming we have an fixed device (memory-)address we want to operate on. Due to the fact that the std::atomic_xxx classes as well as the std::atomic<> template class sizes should be same size as their corresponding built-in-types, you might want to handle both: Performing atomic operations with control over memory ordering and make sure that the access to our atomic-object is never optimized. Thus, we could declare something like:

std::atomic<long> volatile* vmem_first4 = reinterpret_cast<std::atomic<long> volatile*>(0xxB8000);
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The standard explicitly says that atomic<T> may not have the same size as the equivalent T –  jalf Feb 3 '11 at 17:40
"The representation of the atomic address type need not have the same size as its corresponding regular type. It should have the same size whenever possible." So, volatile atomic<T> seems to be useless to me. –  0xbadf00d Feb 3 '11 at 20:20

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