71

From what I've read from Herb Sutter and others you would think that volatile and concurrent programming were completely orthogonal concepts, at least as far as C/C++ are concerned.

However, in GCC implementation all of std::atomic's member functions have the volatile qualifier. The same is true in Anthony Williams's implementation of std::atomic.

So what's deal, do my atomic<> variables need be volatile or not?

  • +1 Mr. Williams is here on SO, maybe he can show up and give an answer :) – AraK Mar 19 '10 at 16:55
  • 1
    I've seen a question on comp.std.c++ about that. Remember that volatile guarants that reads and writes in a single thread are done in order and that a volatile object cannot have any non-volatile member functions being called on it (just like const). But further than that, i have no clue about threads in C++. Everytime i try to read about it in the Standard, i'm starting to give up, not being able to grasp the sheer amount of indirections and logics in the text xD – Johannes Schaub - litb Mar 19 '10 at 17:08
56

Why is the volatile qualifier used throughout std::atomic?

So that volatile objects can also be atomic. See here:

The relevant quote is

The functions and operations are defined to work with volatile objects, so that variables that should be volatile can also be atomic. The volatile qualifier, however, is not required for atomicity.

Do my atomic<> variables need to be volatile or not?

No, atomic objects don't have to be volatile.

  • Note: This is technically same as platform specific stackoverflow.com/questions/3708160/… – Suma Nov 22 '10 at 10:54
  • The volatile qualifier is used to prevent reordering. That's what it does. – Michaël Roy Aug 31 '17 at 4:25
  • 2
    @MichaëlRoy: volatile operations are only ordered wrt. other volatile accesses. atomic<T> release, acquire, and seq_cst ops are ordered wrt. plain non-atomic variables, so rolling your own atomics with just volatile can't give you the same acq/rel semantics without barriers. volatile atomic<T> may / will be useful in the future when compilers take advantage of the as-if rule to optimize atomics, e.g. to prevent merging "redundant" writes to a progress-counter. – Peter Cordes Jul 18 '18 at 6:49
  • @PeterCordes I agree. Using the bare volatile keyword is only safe in a single threaded environment, with interrupts. It does prevent reordering of operations for optimization by the compiler, not by the CPU. I should have specified. edit: the bare volatile keyword can be used safely on single core CPUs in a multithreaded environment. But we're seeing fewer and fewer of this kind of setup. – Michaël Roy Jul 27 '18 at 15:27
  • @MichaëlRoy: it's technically still UB except for volatile sig_atomic_t, but most real implementations have int that's naturally atomic for loads/stores (defining the behaviour). (I recently wrote a big answer about this: MCU programming - C++ O2 optimization breaks while loop) Still, if you want any ordering wrt. non-atomic variables (e.g. interrupt handler writes a normal buffer then sets an atomic flag), you can use a relaxed atomic load and atomic_signal_fence(memory_order_acquire) in the main code to prevent compile-time reordering. – Peter Cordes Jul 27 '18 at 15:51
77

To summarize what others have correctly written:

C/C++ volatile is for hardware access and interrupts. C++11 atomic<> is for inter-thread communication (e.g., in lock-free code). Those two concepts/uses are orthogonal, but they have overlapping requirements and that is why people have often confused the two.

The reason that atomic<> has volatile-qualified functions is the same reason it has const-qualified functions, because it's possible in principle for an object be both atomic<> and also const and/or volatile.

Of course, as my article pointed out, a further source of confusion is that C/C++ volatile isn't the same as C#/Java volatile (the latter is basically equivalent to C++11 atomic<>).

  • 2
    I am going to abuse the fact that you are here to ask your opinion about an article by Alexandrescu on using the volatile flag to produce compile-time errors on thread-unsafe code (using volatile instances to lock the use of the interface and const_cast to remove the volatile when a mutex is acquire). Could it make sense adding a type qualifier 'threadsafe' or the like for this purpose in the language (I am just thinking out loud) The article is here: drdobbs.com/cpp/… – David Rodríguez - dribeas Mar 22 '10 at 10:27
  • I have added it as a question here: stackoverflow.com/questions/2491495 – David Rodríguez - dribeas Mar 22 '10 at 10:55
  • 10
    In some of Andrei's articles, what he was really doing was to hijack (er, I mean, "reuse") the volatile keyword as a handy mostly-unused tag in the type system he could use as a hook to overload and get other effects, which was a little confusing because it wasn't stated quite that way. – Herb Sutter Mar 23 '10 at 14:10
  • 1
    See also Dr. Alexandrescu's (I'm not on a first name basis) follow-up comments and not-quite-retractions on that volatile article (as it were): drdobbs.com/generic-min-and-max-redivivus/184403774 – metal Jan 14 '13 at 14:33
15

As const, volatile is transitive. If you declare a method as volatile then you cannot call any non-volatile method on it or any of its member attributes. By having std::atomic methods volatile you allow calls from volatile member methods in classes that contain the std::atomic variables.

I am not having a good day... so confusing... maybe a little example helps:

struct element {
   void op1() volatile;
   void op2();
};
struct container {
   void foo() volatile {
      e.op1();  // correct
      //e.op2();  // compile time error
   }
   element e;
};

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