Now, the C(++) standard conformant answer is obviously no.
However, on Windows & Visual C++ compiler, the situation seems not so clear.
Objects declared as volatile are (...)
- A write to a volatile object (volatile write) has Release semantics; a reference to a global or static object? that occurs before a write to a volatile object in the instruction sequence will occur before that volatile write in the compiled binary.
- A read of a volatile object (volatile read) has Acquire semantics; a reference to a global or static object? that occurs after a read of volatile memory in the instruction sequence will occur after that volatile read in the compiled binary.
This allows volatile objects to be used for memory locks and releases in multithreaded applications.
Now, reading this, it would appear to me that a volatile variable will be treated by the MS compiler as
std::atomic would be in the upcoming C++11 standard.
However, in a comment to my answer, user Hans Passant wrote "That MSDN article is very unfortunate, it is dead wrong. You can't implement a lock with volatile, not even with Microsoft's version. (...)"
Please note: The example given in the MSDN seems pretty fishy, as you cannot generally implement a lock without atomic exchange. (As also pointed out by Alex.) This still leaves the question wrt. to the validity of the other infos given in this MSDN article, especially for use cases like here and here.)
Additionally, there are the docs for The Interlocked* functions, especially
InterlockedExchange with takes a volatile(!?) variable and does an atomic read+write. (Note that one question we have on SO -- When should InterlockedExchange be used? -- does not authoritatively answer whether this function is needed for a read-only or write-only atomic access.)
What's more, the
volatile docs quoted above somehow allude to "global or static object", where I would have thought that "real" acquire/release semantics should apply to all values.
Back to the question
On Windows, with Visual C++ (2005 - 2010), will declaring a (32bit? int?) variable as
volatile allow for atomic reads and writes to this variable -- or not?
What is especially important to me is that this should hold (or not) on Windows/VC++ independently of the processor or platform the program runs on. (That is, does it matter whether it's a WinXP/32bit or a Windows 2008R2/64bit running on Itanum2?)
Please back up your answer with verifiable information, links, test-cases!