This is a somewhat low-level question. In x86 assembly there are two SSE instructions:

MOVDQA xmmi, m128


MOVNTDQA xmmi, m128

The IA-32 Software Developer's Manual says that the NT in MOVNTDQA stands for Non-Temporal, and that otherwise it's the same as MOVDQA.

My question is, what does Non-Temporal mean?

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    Note that SSE4.1 MOVNTDQA xmmi, m128 is an NT load, while all the other NT instructions are stores, except for prefetchnta. The accepted answer here only seems to be talking about stores. This is what I've been able to turn up about NT loads. TL:DR: hopefully the CPU does something useful with the NT hint to minimize cache pollution, but they don't override the strongly-ordered semantics of "normal" WB memory, so they do have to use the cache. – Peter Cordes Nov 23 '16 at 7:25
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    Update: NT loads may not do anything useful except on UCSW memory regions on most CPUs (e.g. Intel SnB family). NT/streaming stores definitely work on normal memory, though. – Peter Cordes Jul 8 '17 at 1:18
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    @Peter: You mean USWC memory right? I've never heard of UCSW or USWC memory before. Googling the wrong acronym wasn't helpful :-) – Andrew Bainbridge Aug 15 '17 at 11:29
up vote 115 down vote accepted

Non-Temporal SSE instructions (MOVNTI, MOVNTQ, etc.), don't follow the normal cache-coherency rules. Therefore non-temporal stores must be followed by an SFENCE instruction in order for their results to be seen by other processors in a timely fashion.

When data is produced and not (immediately) consumed again, the fact that memory store operations read a full cache line first and then modify the cached data is detrimental to performance. This operation pushes data out of the caches which might be needed again in favor of data which will not be used soon. This is especially true for large data structures, like matrices, which are filled and then used later. Before the last element of the matrix is filled the sheer size evicts the first elements, making caching of the writes ineffective.

For this and similar situations, processors provide support for non-temporal write operations. Non-temporal in this context means the data will not be reused soon, so there is no reason to cache it. These non-temporal write operations do not read a cache line and then modify it; instead, the new content is directly written to memory.


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    Nice answer, I would just like to point out that on the kind of processor with NT instructions, even with a non-non-temporal instruction (i.e. a normal instruction), the line cache is not "read and then modified". For a normal instruction writing to a line that is not in the cache, a line is reserved in the cache and a mask indicates what parts of the line are up-to-date. This webpage calls it "no stall on store": . I couldn't find more precise references, I only heard about this from guys whose job is to implement processor simulators. – Pascal Cuoq May 4 '10 at 20:03
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    Actually is a web site about a cycle-accurate processor simulator, exactly the same kind of thing the guys who told me about "no stall on store" are doing. I'd better mention them too in case they ever see this comment: – Pascal Cuoq May 4 '10 at 20:06
  • From the answers and comments here… it seems SFENCE may be not needed. At least in the same thread. Could you also look? – Serge Rogatch Jul 2 '17 at 10:32

Espo is pretty much bang on target. Just wanted to add my two cents:

The "non temporal" phrase means lacking temporal locality. Caches exploit two kinds of locality - spatial and temporal, and by using a non-temporal instruction you're signaling to the processor that you don't expect the data item be used in the near future.

I am a little skeptical about the hand-coded assembly that uses the cache control instructions. In my experience these things lead to more evil bugs than any effective performance increases.

  • question about "hand-coded assembly that uses the cache control instructions." I know you explicitly said "hand-coded" what about something like a JavaVM. Is this a better use case? The JavaVM/Compiler has analyzed the static and dynamic behavior of the program and uses these non-temporal instructions. – Pat Dec 1 '15 at 18:21
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    Exploiting known locality properties (or lack thereof) of your problem domain, algorithm or application shouldn't be shunned. Avoiding cache pollution is indeed a very attractive and effective optimisation task. Also, why the aversion toward assembly? There are vast amounts of opportunities for gains available which a compiler cannot possibly capitalise on – Martin Källman Dec 21 '15 at 23:44
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    It's definitely true that a knowledgeable low-level programmer can outperform a compiler for small kernels. This is great for publishing papers and blogposts and I've done both. They're also good didactic tools, and help understand what "really" going on. In my experience though, in practice, where you have a real system with many programmers working on it and correctness and maintainability are important, the benefit of low-level coding is almost always outweighed by the risks. – Pramod Dec 22 '15 at 22:23
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    @Pramod that same argument easily generalises to optimisation in general and is not really in scope of the discussion -- clearly that trade-off has already been considered or otherwise been deemed irrelevant given the fact that we are already talking about non-temporal instructions – Martin Källman Oct 31 '16 at 13:59

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