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Whilst writing this answer I realised that I'm not as confident about my conclusions as I usually would ensure before hitting Post Your Answer.

I can find a couple of reasonably convincing citations for the argument that the trivial-copyability of volatile data members is either implementation-defined or flat-out disallowed:

But I haven't been able to back this up in the standard1 itself. Particularly "worrying" is that there's no sign of the proposed wording change from that n3159 issues list in the actual standard's final wording.

So, what gives? Are volatile data members trivially copyable, or not?

1   C++11

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I just spotted that the proposed wording change in issue #496 is only a month or so old and, as such, post-dates C++11. It is therefore still active. I guess then I'm only asking the same question as Maddock started back in 2004 with #496. – Lightness Races in Orbit Nov 15 '12 at 23:17

I'm seeing the following definition for "trivially copyable" (C++11 §3.9, paragraph 9):

...Scalar types, trivially copyable class types, arrays of such types, and cv-qualified versions of these types are collectively called trivially copyable types....

cv-qualified by definition includes const and/or volatile (§3.9.3). It would therefore appear that volatile values are explicitly trivially copyable, if the unqualified type would be trivially copyable (a scalar or trivially copyable class type, or array thereof).

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But look at issue #496 which suggests that this wording is inaccurate and possibly at odds with wording elsewhere. The passage you cite is singled out explicitly there. – Lightness Races in Orbit Nov 17 '12 at 17:07
@LightnessRacesinOrbit: volatile in C++ is rather different than in, say, Java. I haven't seen where it implies atomicity in C++, and would therefore assume it doesn't. That's the only interpretation i can come up with that is consistent with the rest of the standard. – cHao Nov 17 '12 at 17:17
Except committee members evidently disagree, making this inconclusive. Hence my question :( The problem is that, while the standard doesn't guarantee atomicity for volatile objects, it is arguably sufficiently vague about any property of volatile objects as to imply implementation-definedness for most of them. I think that's where Maddock was coming from. I'm actually half-anticipating a DR at this point. – Lightness Races in Orbit Nov 17 '12 at 17:40
Maddock's rationale regarding atomicity, quoted from the active issue: The problem with this is that a volatile qualified type may need to be copied in a specific way (by copying using only atomic operations on multithreaded platforms, for example) in order to avoid the “memory tearing” that may occur with a byte-by-byte copy. Sure, at present, the standard doesn't get itself involved in such things -- but some implementations may need to (see: GCC 4.7, from the original question) and, as such, 3.9/9 would appear to be a defect and thus practically non-binding. Hence #496. – Lightness Races in Orbit Nov 17 '12 at 17:44
That stuff that would have to be done in order to avoid "memory tearing"...that's the implementation's problem, if it wants to provide such a guarantee. C++ doesn't require it to. (Whether it will in some future version doesn't change the standard today.) Basically all volatile means anyway is that you want to prohibit optimizations that would cache old values. If you rely on any more than that, you'd have to ask the compiler maker what's safe and what's not, and know that you're using implementation-specific behavior. – cHao Nov 17 '12 at 19:08

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