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Often in internet I find that LFENCE makes no sense in processors x86, ie it does nothing , so instead MFENCE we can absolutely painless to use SFENCE, because MFENCE = LFENCE + SFENCE = NOP + SFENCE = SFENCE.

But if LFENCE does not make sense, then why we have four approaches to make Sequential Consistency in x86/x86_64:

  1. LOAD (without fence) and STORE + MFENCE
  2. LOAD (without fence) and LOCK XCHG
  3. MFENCE + LOAD and STORE (without fence)
  4. LOCK XADD ( 0 ) and STORE (without fence)

Taken from here: http://www.cl.cam.ac.uk/~pes20/cpp/cpp0xmappings.html

As well as performances from Herb Sutter on page 34 at the bottom: https://skydrive.live.com/view.aspx?resid=4E86B0CF20EF15AD!24884&app=WordPdf&wdo=2&authkey=!AMtj_EflYn2507c

If LFENCE did not do anything, then the approach (3) would have the following meanings: SFENCE + LOAD and STORE (without fence), but there is no point in doing SFENCE before LOAD. Ie if LFENCE does nothing , the approach (3) does not make sense.

Does it make any sense instruction LFENCE in processors x86/x86_64?

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There are instructions with a "non-temporal hint" which aren't as strongly ordered as the usual load and store; I imagine those may benefit from fencing. (Edit: This is actually mentioned on the page you linked.) –  Kerrek SB Dec 1 '13 at 20:34

2 Answers 2

Consider the following scenario - this is the critical case where speculative load execution can theoretically harm sequential consistency

initially [x]=[y]=0

CPU0:                              CPU1: 
store [x]<--1                      store [y]<--1
load  r1<--[y]                     load r2<--[x]

Since x86 allows loads to be reordered with earlier stores to different addresses, both loads may return 0's. Adding an lfence alone after each store wouldn't prevent that, since they only prevent reordering within the same context, but since stores are dispatched after retirement you can have both lfences and both loads commit before the stores are performed and observed.

An mfence on the other hand would force the stores to perform, and only then allow the loads to be executed, so you'll see the updated data on at least one context.

As for sfences - as pointed out in the comment, in theory it's not strong enough to prevent the load from reordering above it, so it might still read stale data. While this is true as far as the memory official ordering rules apply, I believe that current implementation of x86 uarch makes it slightly stronger (while not committing to do so in the future, I guess). According to this description:

Because of the strong x86 ordering model, the load buffer is snooped by coherency traffic. A remote store must invalidate all other copies of a cache line. If a cache line is read by a load, and then invalidated by a remote store, the load must be cancelled, since it potentially read invalid data. The x86 memory model does not require snooping the store buffer.

Therefore, any load not yet committed in the machine should be snoopable by stores from other cores, thereby making the effective observation time of the load at the commit point, and not the execution point (which is indeed out of order and may have been performed much earlier). Commit is done in order, and therefore the load should be observed after previous instructions - making lfences pretty much useless as I said above in the comments, since the consistency can be maintained the same way without them. This is mostly speculation, trying to explain the common conception that lfences are meaningless in x86 - I'm not entirely sure where it originated and if there are other considerations at hand - would be happy for any expert to approve / challenge this theory.

All the above applies only for WB mem types of course

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SFENCE cannot be used to fix this example, because a load can migrate up across SFENCE. The example requires MFENCE to fix. –  Arch D. Robison Dec 2 '13 at 15:26
@ArchD.Robison, in practice, the load would have to retire after any previous instruction, and during that time a store from the other thread would be able to snoop it - I think this would cause re-execution but i'm not entirely sure, so I fixed the answer as you suggested - thanks. –  Leeor Dec 2 '13 at 16:02
Thanks for the fix. I recommend coding against the architectural guarantees since the micro-architects are always looking for clever and mysterious ways to speed things up. –  Arch D. Robison Dec 2 '13 at 17:00

Of course it make sence!

LFENCE from Intel datasheet:

Performs a serializing operation on all load-from-memory instructions that were issued prior the LFENCE instruction. This serializing operation guarantees that every load instruction that precedes in program order the LFENCE instruction is globally visible before any load instruction that follows the LFENCE instruction is globally visible.

Memory write instruction like MOV are atomic if there are properly aligned. But this instruction is normally executed in CPU cache and will not be globally visible at this moment for all other threads, because memory LFENCE/SFENCE or MFENCE must be preformed first.

Typical case:

If thread writer unlock the memory region with write instruction like memory aligned MOV, so no LOCK prefix instruction is in use, than the cache line where was peformed MOV shuld be visible in very short future to all other threads. LFENCE ensure to the thread reader that also all other cache lines from thread writer are globaly visibe!

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Thanks! Ie I must use LFENCE before MOV in thread2 to make visible changes which made by using properly aligned MOV in thread1? Or I must use only MOV in thread2 to make visible changes which made by using SFENCE after properly aligned MOV in thread1? –  Alex Dec 1 '13 at 21:28
@Alex: Only in case that first thread (writer) do not perform SFENCE what is in some cases faster. Using only a MOV instruction is very fast because it is executed in cache. –  GJ. Dec 1 '13 at 21:38
Memory operation performed in cache are globally visible. A cache may not break the consistency model. –  Leeor Dec 1 '13 at 22:05
@Leeor: "It should be noted that processors are free to speculatively fetch and cache data from system memory regions that are assigned a memory-type that permits speculative reads (that is, the WB, WC, and WT memory types)." Check: rz.uni-karlsruhe.de/rz/docs/VTune/reference/vc153.htm –  GJ. Dec 1 '13 at 22:32
@Leeor: From my privius link: "The degree to which a consumer of data recognizes or knows that the data is weakly ordered varies among applications and may be unknown to the producer of this data. The LFENCE instruction provides a performance-efficient way of ensuring ordering between routines that produce weakly-ordered results and routines that consume this data." –  GJ. Dec 1 '13 at 22:55

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