I read the "Intel Optimization guide Guide For Intel Architecture".

However, I still have no idea about when should I use


Could anyone explain when these should be used when writing multi-threaded code?

  • @BeeOnRope: I updated / retagged this question to ask what I think the real question was: about these intrinsics in multi-threaded code (the original tags included parallel-processing.) There are lots of Q&As about the machine instructions, but this one is different because C++'s mem model is weak. You want a way to do an acquire-load or release-store without making the compiler emit a useless lfence or sfence, just stopping compile-time reordering. (preshing.com/20120625/memory-ordering-at-compile-time). Of course in 2018, just use C11 stdatomic / C++11 std::atomic. Commented Jun 9, 2018 at 16:02
  • @PeterCordes So you think this question is about compiler barriers in a way? That is, a good answer might be along the lines of lfence and sfence instructions are generally useless at the x86 assembly level, but you might want to insert a compiler barrier to prevent compiler reorderings? BTW, I don't know of finer-grained-than-full compiler-barriers for most compilers, but MSVC does have _[Read|Write]Barrier. I guess you could invent some types of barriers with inline asm and clever use of constraints.
    – BeeOnRope
    Commented Jun 9, 2018 at 16:46
  • std::atomic_signal_fence(std::memory_order_release) with gcc does seem to order even non-atomic variables, but that may be an implementation detail. I haven't looked under the hood. Commented Jun 9, 2018 at 16:49
  • @PeterCordes - it is supposed to order non-atomic variables, isn't it? Just like most of the mo_ orders on atomic variables also order somehow the surrounding non-atomic accesses. For fences, ordering of non-atomic variables is the main purpose, I think. Maybe I didn't understand what you meant...
    – BeeOnRope
    Commented Jun 9, 2018 at 16:56

4 Answers 4


If you're using NT stores, you might want _mm_sfence or maybe even _mm_mfence. The use-cases for _mm_lfence are much more obscure.

If not, just use C++11 std::atomic and let the compiler worry about the asm details of controlling memory ordering.

x86 has a strongly-ordered memory model, but C++ has a very weak memory model (same for C). For acquire/release semantics, you only need to prevent compile-time reordering. See Jeff Preshing's Memory Ordering At Compile Time article.

_mm_lfence and _mm_sfence do have the necessary compiler-barrier effect, but they will also cause the compiler to emit a useless lfence or sfence asm instruction that makes your code run slower.

There are better options for controlling compile-time reordering when you aren't doing any of the obscure stuff that would make you want sfence.

For example, GNU C/C++ asm("" ::: "memory") is a compiler barrier (all values have to be in memory matching the abstract machine because of the "memory" clobber), but no asm instructions are emitted.

If you're using C++11 std::atomic, you can simply do shared_var.store(tmp, std::memory_order_release). That's guaranteed to become globally visible after any earlier C assignments, even to non-atomic variables.

_mm_mfence is potentially useful if you're rolling your own version of C11 / C++11 std::atomic, because an actual mfence instruction is one way to get sequential consistency, i.e. to stop later loads from reading a value until after preceding stores become globally visible. See Jeff Preshing's Memory Reordering Caught in the Act.

But note that mfence seems to be slower on current hardware than using a locked atomic-RMW operation. e.g. xchg [mem], eax is also a full barrier, but runs faster, and does a store. On Skylake, the way mfence is implemented prevents out-of-order execution of even non-memory instruction following it. See the bottom of this answer.

In C++ without inline asm, though, your options for memory barriers are more limited (How many memory barriers instructions does an x86 CPU have?). mfence isn't terrible, and it is what gcc and clang currently use to do sequential-consistency stores.

Seriously just use C++11 std::atomic or C11 stdatomic if possible, though; It's easier to use and you get quite good code-gen for a lot of things. Or in the Linux kernel, there are already wrapper functions for inline asm for the necessary barriers. Sometimes that's just a compiler barrier, sometimes it's also an asm instruction to get stronger run-time ordering than the default. (e.g. for a full barrier).

No barriers will make your stores appear to other threads any faster. All they can do is delay later operations in the current thread until earlier things happen. The CPU already tries to commit pending non-speculative stores to L1d cache as quickly as possible.

_mm_sfence is by far the most likely barrier to actually use manually in C++

The main use-case for _mm_sfence() is after some _mm_stream stores, before setting a flag that other threads will check.

See Enhanced REP MOVSB for memcpy for more about NT stores vs. regular stores, and x86 memory bandwidth. For writing very large buffers (larger than L3 cache size) that definitely won't be re-read any time soon, it can be a good idea to use NT stores.

NT stores are weakly-ordered, unlike normal stores, so you need sfence if you care about publishing the data to another thread. If not (you'll eventually read them from this thread), then you don't. Or if you make a system call before telling another thread the data is ready, that's also serializing.

sfence (or some other barrier) is necessary to give you release/acquire synchronization when using NT stores. C++11 std::atomic implementations leave it up to you to fence your NT stores, so that atomic release-stores can be efficient.

#include <atomic>
#include <immintrin.h>

struct bigbuf {
    int buf[100000];
    std::atomic<unsigned> buf_ready;

void producer(bigbuf *p) {
  __m128i *buf = (__m128i*) (p->buf);

  for(...) {
     _mm_stream_si128(buf,   vec1);
     _mm_stream_si128(buf+1, vec2);
     _mm_stream_si128(buf+2, vec3);

  _mm_sfence();    // All weakly-ordered memory shenanigans stay above this line
  // So we can safely use normal std::atomic release/acquire sync for buf
  p->buf_ready.store(1, std::memory_order_release);

Then a consumer can safely do if(p->buf_ready.load(std::memory_order_acquire)) { foo = p->buf[0]; ... } without any data-race Undefined Behaviour. The reader side does not need _mm_lfence; the weakly-ordered nature of NT stores is confined entirely to the core doing the writing. Once it becomes globally visible, it's fully coherent and ordered according to the normal rules.

Other use-cases include ordering clflushopt to control the order of data being stored to memory-mapped non-volatile storage. (e.g. an NVDIMM using Optane memory, or DIMMs with battery-backed DRAM exist now.)

_mm_lfence is almost never useful as an actual load fence. Loads can only be weakly ordered when loading from WC (Write-Combining) memory regions, like video ram. Even movntdqa (_mm_stream_load_si128) is still strongly ordered on normal (WB = write-back) memory, and doesn't do anything to reduce cache pollution. (prefetchnta might, but it's hard to tune and can make things worse.)

TL:DR: if you aren't writing graphics drivers or something else that maps video RAM directly, you don't need _mm_lfence to order your loads.

lfence does have the interesting microarchitectural effect of preventing execution of later instructions until it retires. e.g. to stop _rdtsc() from reading the cycle-counter while earlier work is still pending in a microbenchmark. (Applies always on Intel CPUs, but on AMD only with an MSR setting: Is LFENCE serializing on AMD processors?. Otherwise lfence runs 4 per clock on Bulldozer family, so clearly not serializing.)

Since you're using intrinsics from C/C++, the compiler is generating code for you. You don't have direct control over the asm, but you might possibly use _mm_lfence for things like Spectre mitigation if you can get the compiler to put it in the right place in the asm output: right after a conditional branch, before a double array access. (like foo[bar[i]]). If you're using kernel patches for Spectre, I think the kernel will defend your process from other processes, so you'd only have to worry about this in a program that uses a JIT sandbox and is worried about being attacked from within its own sandbox.

  • 1
    It is possible that sfence; lfence, if sfence flushes the store buffer, could make stores appear faster to other threads, by effectively pausing other subsequent load activity that might compete for L1 bandwidth and other resources like LFBs. Even subsequent store activity could compete in this way, although that seems less likely (it depends on the details of RFO prefetching). This is fairly obscure though and seems unlikely to matter much in practice. You could also use pause, although it's a lot slower on Skylake+.
    – BeeOnRope
    Commented Jun 10, 2018 at 21:22

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). It only guarantees the order that writes become visible to other processors is in program order. It does not guarantee that other processors will immediately see any update, no matter what you do.

Locked read/modify/write instructions are fully sequentially consistent. 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, you will acquire the relevant cache line for ownership immediately and will update it atomically. If another CPU is racing with your locked operation, either you will win the race and the other CPU will miss the cache and get it back after your locked operation, or they will win the race, and you will miss the cache and get the updated value from them.

lfence stalls instruction issue until all instructions before the lfence are completed. mfence specifically waits for all preceding memory reads to be brought fully into the destination register, and waits for all preceding writes to become globally visible, but does not stall all further instructions as lfence would. sfence does the same for only stores, flushes write combiner, and ensures that all stores preceding the sfence are globally visible before allowing any stores following the sfence to begin execution.

Fences of any kind are rarely needed on x86, they are not necessary unless you are using write-combining memory or non-temporal instructions, something you rarely do if you are not a kernel mode (driver) developer. Normally, x86 guarantees that all stores are visible in program order, but it does not make that guarantee for WC (write combining) memory or for "non-temporal" instructions that do explicit weakly ordered stores, such as movnti.

So, to summarize, stores are always visible in program order unless you have used special weakly ordered stores or are accessing WC memory type. Algorithms using locked instructions like xchg, or xadd, or cmpxchg, etc, will work without fences because locked instructions are sequentially consistent.

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    You normally don't need lfence ever. You only need sfence after weakly-ordered movnt streaming stores. You need mfence (or a locked operation) to get sequential consistency instead of just release/acquire. (See Memory Reordering Caught in the Act for an example.) Commented Jul 2, 2017 at 1:39
  • You normally need lfence because C++ compiler. Commented Jul 9, 2017 at 20:59
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    lfence doesn't discard speculatively executed stores. lfence is just an instruction stream serializer: it waits until all previous instructions (of any type, not just memory access) have retired before proceeding, and no later instructions will execute while it is waiting. It is not useful for ordering memory accesses in normal user-mode programs. It's main use there is as an OoO barrier for profiling small regions of code more consistently. sfence is similarly not useful except in conjunction with so-called "non-temporal" stores, like movntq.
    – BeeOnRope
    Commented Jun 8, 2018 at 22:33
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    @PeterCordes I think lfence also does stop issue (Intel terms: i.e., sending ops to the scheduler). Once the uops are in the scheduler, it's too hard to separate them before/after, so it seem (from patents, etc) that lfence just stops issue until it retires. So I think renaming stops, but everything before that can keep running and queuing in the IDQ.
    – BeeOnRope
    Commented Jun 9, 2018 at 17:10
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    @BeeOnRope: That would make sense. I was thinking about whether it's testable. Maybe with a latency bottleneck after a bunch of NOPs, and see if more NOPs reduce throughput. If uops from after an lfence are all sitting in the scheduler waiting to be allowed to start, then more uops won't matter unless we create a front-end bottleneck bigger than the dep chain. Commented Jun 9, 2018 at 17:20

The intrinsic calls you mention all simply insert an sfence, lfence or mfence instruction when they are called. So the question then becomes "What are the purposes of those fence instructions"?

The short answer is that lfence is completely useless* and sfence almost completely useless for memory ordering purposes for user-mode programs in x86. On the other hand, mfence serves as a full memory barrier, so you might use it in places where you need a barrier if there isn't already some nearby lock-prefixed instruction providing what you need.

The longer-but-still short answer is...


lfence is documented to order loads prior to the lfence with respect to loads after, but this guarantee is already provided for normal loads without any fence at all: that is, Intel already guarantees that "loads aren't reordered with other loads". As a practical matter, this leaves the purpose of lfence in user-mode code as an out-of-order execution barrier, useful perhaps for carefully timing certain operations.


sfence is documented to order stores before and after in the same way that lfence does for loads, but just like loads the store order is already guaranteed in most cases by Intel. The primary interesting case where it doesn't is the so-called non-temporal stores such as movntdq, movnti, maskmovq and a few other instructions. These instructions don't play by the normal memory ordering rules, so you can put an sfence between these stores and any other stores where you want to enforce the relative order. mfence works for this purpose too, but sfence is faster.


Unlike the other two, mfence actually does something: it serves as a full memory barrier, ensuring that all of the previous loads and stores will have completed1 before any of the subsequent loads or stores begin execution. This answer is too short to explain the concept of a memory barrier fully, but an example would be Dekker's algorithm, where each thread wanting to enter a critical section stores to a location and then checks to see if the other thread has stored something to its location. For example, on thread 1:

mov   DWORD [thread_1_wants_to_enter], 1  # store our flag
mov   eax,  [thread_2_wants_to_enter]     # check the other thread's flag
test  eax, eax
jnz   retry
; critical section

Here, on x86, you need a memory barrier in between the store (the first mov), and the load (the second mov), otherwise each thread could see zero when they read the other's flag because the x86 memory model allows loads to be re-ordered with earlier stores. So you could insert an mfence barrier as follows to restore sequential consistency and the correct behavior of the algorithm:

mov   DWORD [thread_1_wants_to_enter], 1  # store our flag
mov   eax,  [thread_2_wants_to_enter]     # check the other thread's flag
test  eax, eax
jnz   retry
; critical section

In practice, you don't see mfence as much as you might expect, because x86 lock-prefixed instructions have the same full-barrier effect, and these are often/always (?) cheaper than an mfence.

1 E.g., loads will have been satisfied and stores will have become globally visible (although it would be implemented differently as long as the visible effect wrt ordering is "as if" that occurred).

  • Maybe worth mentioning that the memory-ordering use-case for lfence is after loads from video memory, especially with movntdqa, or anything else that's mapped WC. So you could say "if you haven't mapped video RAM into your user-space program, you don't need lfence". I'm sure people will wonder when it ever is useful; I know I would, so a tiny hint / summary is useful. User-space can map video RAM with the kernel's help... Commented Jun 9, 2018 at 8:12
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    I'm deliberately trying to keep this a fairly short and direct answer, even if it is perhaps at the cost of not being exhaustively accurate when it comes to every possible lfence use. That is, I don't want to make a @PeterCordes-style answer which necessarily covers every possibility and often spends more prose on that than the 99% case (not that this is a problem, I also write such answers - but I don't want it here). Are there user-mode applications that map WC video ram into their address space? Probably, but a very tiny fraction. Are there some of those who need ...
    – BeeOnRope
    Commented Jun 9, 2018 at 16:36
  • 1
    ... load-load ordering (but not other types of ordering) with respect to loads from video RAM and who aren't already using some type of synchronization which provides it? This seems like a small slice of the earlier small slice. Out of that minuscule group, for how many is lfence interesting in the sense that it provides any type of improvement over mfence? I don't know, but I think it's very small. Out of curiosity have you ever seen lfence in a real program dealing with WC reads from video RAM? BTW, if I was going to add another lfence use it would be meltdown/spectre mitigation.
    – BeeOnRope
    Commented Jun 9, 2018 at 16:38
  • 1
    @PeterCordes - looks good. I have also wondered about the purpose of lfence. I don't think it is actually explained by "mapping WC memory into user space". It seems to me that these instructions were introduced at a time of "great hope" for non-temporal instructions on WB memory, and perhaps when the memory model wasn't really nailed down and Intel architects still possibly wanted to allow load-load reordering in some circumstances (even outside of NT loads) in WB mode, or perhaps were considering another higher-performance weaker mode, like WB+ that allowed more reorderings.
    – BeeOnRope
    Commented Jun 10, 2018 at 20:20
  • 1
    That kind of didn't pan out: they stuck with a strong model, perhaps just by default since by not defining it very well in the first MP systems, people were probably already relying on existing behaviors (although it took them several iterations to really settle on a model and even today it's hard to read the document). So then I think lfence was just kind of orphaned - the WC video RAM case seems unlikely to me since mfence serves the same purpose, and such scenarios existed long before lfence (indeed, were more common back in DOS and non-protected OSes). This is pure speculation...
    – BeeOnRope
    Commented Jun 10, 2018 at 20:23

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

array[idx+1] = something

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

newestthing = array[idx]

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.

This article or this article may give better info

  • 2
    No, x86 stores are strongly-ordered by default. Compile-time reordering could produce the reordering you describe (if you fail to use std::atomic with memory_order_release or stronger), but the stores from the x86 instructions mov [array + rcx], eax / mov [idx], rcx would become globally visible to other threads in that order. Only MOVNT streaming stores are weakly-ordered (so you need sfence after them before storing to a buffer_ready flag). You normally never need lfence, unless you're using weakly-ordered loads from video memory or something. Commented Jul 2, 2017 at 1:33
  • 2
    See also my answer on a more recent sfence question. Also, Jeff Preshing's excellent articles, like this weak vs. strong memory model post. (It was written 2 years after you posted this. I'm not intending to be rude about an old answer, but it is almost totally wrong, xD) Commented Jul 2, 2017 at 1:36
  • 1
    All of this is because x86 has a strong memory model, but C++ has a weak memory model. Preventing compile-time reordering is all you need to do. Inserting lfence or sfence may not hurt performance much, but they're not necessary if you haven't used weakly-ordered MOVNT loads or stores. Commented Jul 9, 2017 at 22:06
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    @MarekVitek: SFENCE and LFENCE don't help you avoid those kinds of reordering, only MFENCE does that. See Does SFENCE prevent the Store Buffer hiding changes from MESI?, and Why is (or isn't?) SFENCE + LFENCE equivalent to MFENCE?. To get a release-store in C++, you only need to tell your compiler that's what you want. _mm_sfence() has that effect, but it also forces it to also emit a useless sfence asm instruction. There are other options that don't have that side effect, like asm("" ::: "memory");. Commented Jun 8, 2018 at 13:22
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    @MarekVitek - you are wrong and Peter is right here. Intel has a relatively strong model, and stores aren't re-ordered with other stores and loads aren't re-ordered with other loads (except perhaps in the SLF scenario which doesn't apply here). So if you write the array element, and then update the index, any other CPU that sees the index update is guaranteed to see the write to the array element also. Of course, you need to prevent compiler re-ordering, still! lfence and sfence are largely useless as fences in x86 - they have only very obscure uses not related to above.
    – BeeOnRope
    Commented Jun 8, 2018 at 22:31

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