Could someone explain this statement:
shared variables x = 0, y = 0 Core 1 Core 2 x = 1; y = 1; r1 = y; r2 = x;
How is it possible to have
r1 == 0 and
r2 == 0 on x86 processors?
The problem can arise due to optimizations involving reordering of instructions. In other words, both processors can assign
To quote the slideshow you mentioned in your post:
Regarding the x86 architecture, the best resource to read is Intel® 64 and IA-32 Architectures Software Developer’s Manual (Chapter 8.2 Memory Ordering). Sections 8.2.1 and 8.2.2 describe the memory-ordering implemented by Intel486, Pentium, Intel Core 2 Duo, Intel Atom, Intel Core Duo, Pentium 4, Intel Xeon, and P6 family processors: a memory model called processor ordering, as opposed to program ordering (strong ordering) of the older Intel386 architecture (where read and write instructions were always issued in the order they appeared in the instruction stream).
The manual describes many ordering guarantees of the processor ordering memory model (such as Loads are not reordered with other loads, Stores are not reordered with other stores, Stores are not reordered with older loads etc.), but it also describes the allowed reordering rule which causes the race condition in the OP's post:
On the other hand, if the original order of the instructions was switched:
In this case, processor guarantees that
To compare this with different architectures, check out this article: Memory Ordering in Modern Microprocessors (this image specifically). You can see that Itanium (IA-64) does even more reordering than the IA-32 architecture.
On processors with a weaker memory consistency model (such as SPARC, PowerPC, Itanium, ARM, etc.), the above condition can take place because of a lack of enforced cache-coherency on writes without an explicit memory barrier instruction. So basically
This is why some say: Threads Considered Harmful
The problem is that neither thread enforces any ordering between its two statements, because they are not inter-dependent.
The mutual dependency looks odd but it's really no different than any other race condition. Directly writing shared-memory-threaded code is quite difficult, and that's why parallel languages and message-passing parallel frameworks have been developed, in order to isolate the parallel hazards to a small kernel and remove the hazards from the applications themselves.