When I experimented with different variants of mutexes, finally I came to 2 fastest primitives.
One is InterlockedExchange-based (well-known method)
Access: while InterlockedExchange(AccessFlag, 1) <> 0 do Release: InterlockedExchange(AccessFlag, 0)
Another one is event-based.
Init: Event = CreateEvent(Null, false, true, Null); Access: WaitForSingleObject(Event, INFINITE) Release: SetEvent(Event)
InterlockedExchanged-based was fastest always, but it suffered from not-sleeping in case of failure. On the other side it worked greatly either on single physical processor (core) or on multiple cores. Although small benefit of single core test was that there were no failures if I added Sleep(0) inside the loop.
Event-based is great in waiting while sleeping, but when I measured the performance, I noticed that several threads working with this type of mutex perform faster if they reside on the single physical processor (SetThreadAffinityMask called with identical values or testing on a single-core computer) than on different processors. Depending on the type of processor, this varied from x4 (iCore 5) to x8 (Xeon).
Some statistics from Xeon
3 threads, each increases a variable by 10 (10,000,000 steps) accessing it with a mutex at each increase.
344 msec / Per Ms: 87,209 / Failures in while loop: 2,487,376 (8% of total steps from 3 threads, Sleep(0) exists but probably useless with multi-processor threads)
6187 msec / Per Ms: 4,848
Single processor, InterlockedExcchange-based
281 msec / Per Ms: 106,761 / Failures in while loop: 0 (Sleep(0) inside the loop);
Single processor, Event-based
765 msec / Per Ms: 39,215
I assume that real inter-core synchronization has some penalty. But I would like to "marry" the perfect performance of the InterlockedExchange method with the correctness ("sleep if you don't work") of the event-based approach. Is this possible?