I read the "Intel Optimization guide Guide For Intel Architecture".
However, I still have no idea about when should I use _mm_sfence() _mm_lfence() _mm_mfence()
could somebody give me the explanation ?
Caveat: I'm no expert in this. I'm still trying to learn this myself. But since no one has replied in the past two days, it seems experts on memory fence instructions are not plentiful. So here's my understanding ...
Intel is a weakly-ordered memory system. That means your program may execute
but the change to idx may be globally visible (e.g. to threads/processes running on other processors) before the change to array. Placing sfence between the two statements will ensure the order the writes are sent to the FSB.
Meanwhile, another processor runs
may have cached the memory for array and has a stale copy, but gets the updated idx due to a cache miss. The solution is to use lfence just beforehand to ensure the loads are synchronized.
Here is my understanding, hopefully accurate and simple enough to make sense:
(Itanium) IA64 architecture allows memory reads and writes to be executed in any order, so the order of memory changes from the point of view of another processor is not predictable unless you use fences to enforce that writes complete in a reasonable order.
From here on, I am talking about x86, x86 is strongly ordered.
On x86, Intel does not guarantee that a store done on another processor will always be immediately visible on this processor. It is possible that this processor speculatively executed the load (read) just early enough to miss the other processor's store (write).
Locked read/modify/write instructions are fully sequentially consistent, so you rarely actually have to use fences on x86. Because of this, in general you already handle missing the other processor's memory operations because a locked xchg or cmpxchg will sync it all up.
As far as I understand it, lfence drains the memory load queue and waits for the load unit's pipeline to finish whatever ops are in progress. mfence goes further and waits for all memory reads and writes, sfence does the same for only stores (and flushes write combiner).
In essence, lfence discards any speculatively executed loads. Loads that may have been previously speculatively executed will be re-issued. sfence is the least necessary in practice, usually it is not necessary unless using write-combining memory, something you rarely do if you are not a kernel mode (driver) developer.
So, to summarize, algorithms using locked instructions like xchg, or xadd, or cmpxchg, etc, will work without fences because the locked instruction (in most cases) does everything to synchronize. Any tricky lock-free code that (for example) has early-out code paths that don't use those lock instructions might need lfence somewhere to avoid missing a store done by another processor. Code that touchy is rare and is not a good practice but might be necessary in extremely hot code paths.