Consider the following sequence of writes to
volatile memory, which I've taken from David Chisnall's article at InformIT, "Understanding C11 and C++11 Atomics":
volatile int a = 1; volatile int b = 2; a = 3;
My understanding from C++98 was that these operations could not be reordered, per C++98 1.9:
conforming implementations are required to emulate (only) the observable behavior of the abstract machine as explained below ... The observable behavior of the abstract machine is its sequence of reads and writes to volatile data and calls to library I/O functions
Chisnall says that the constraint on order preservation applies only to individual variables, writing that a conforming implementation could generate code that does this:
a = 1; a = 3; b = 2;
b = 2; a = 1; a = 3;
C++11 repeats the C++98 wording that
conforming implementations are required to emulate (only) the observable behavior of the abstract machine as explained below.
but says this about
Access to volatile objects are evaluated strictly according to the rules of the abstract machine.
1.9/12 says that accessing a
volatile glvalue (which includes the variables
c above) is a side effect, and 1.9/14 says that the side effects in one full expression (e.g., a statement) must precede the side effects of a later full expression in the same thread. This leads me to conclude that the two reorderings Chisnall shows are invalid, because they do not correspond to the ordering dictated by the abstract machine.
Am I overlooking something, or is Chisnall mistaken?
(Note that this is not a threading question. The question is whether a compiler is permitted to reorder accesses to different
volatile variables in a single thread.)