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  • What does rep; nop mean?
  • Is it the same as pause instruction?
  • Is it the same as rep nop (without the semi-colon)?
  • What's the difference to the simple nop instruction?
  • Does it behave differently on AMD and Intel processors?
  • (bonus) Where is the official documentation for these instructions?

Motivation for this question

After some discussion in the comments of another question, I realized that I don't know what rep; nop; means in x86 (or x86-64) assembly. And also I couldn't find a good explanation on the web.

I know that rep is a prefix that means "repeat the next instruction cx times" (or at least it was, in old 16-bit x86 assembly). According to this summary table at Wikipedia, it seems rep can only be used with movs, stos, cmps, lods, scas (but maybe this limitation was removed on newer processors). Thus, I would think rep nop (without semi-colon) would repeat a nop operation cx times.

However, after further searching, I got even more confused. It seems that rep; nop and pause map to the exactly same opcode, and pause has a bit different behavior than just nop. Some old mail from 2005 said different things:

  • "try not to burn too much power"
  • "it is equivalent to 'nop' just with 2 byte encoding."
  • "it is magic on intel. Its like 'nop but let the other HT sibling run'"
  • "it is pause on intel and fast padding on Athlon"

With these different opinions, I couldn't understand the correct meaning.

It's being used in Linux kernel (on both i386 and x86_64), together with this comment: /* REP NOP (PAUSE) is a good thing to insert into busy-wait loops. */ It is also being used in BeRTOS, with the same comment.

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rep; nop is indeed the same as the pause instruction (opcode F390). It might be used for assemblers which don't support the pause instruction yet. On previous processors, this simply did nothing, just like nop but in two bytes. On new processors which support hyperthreading, it is used as a hint to the processor that you are executing a spinloop to increase performance. From Intel's instruction reference:

Improves the performance of spin-wait loops. When executing a “spin-wait loop,” a Pentium 4 or Intel Xeon processor suffers a severe performance penalty when exiting the loop because it detects a possible memory order violation. The PAUSE instruction provides a hint to the processor that the code sequence is a spin-wait loop. The processor uses this hint to avoid the memory order violation in most situations, which greatly improves processor performance. For this reason, it is recommended that a PAUSE instruction be placed in all spin-wait loops.

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    Is spin-wait loop the same as busy-wait loop? Does this "improvement" only applies to hyperthreading processors? (and why?) – Denilson Sá Maia Aug 16 '11 at 23:38
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    Yes, spin-wait loop is the same as busy-wait loop. The benefit also applies to CPUs that don't support hyper-threading. It can be thought of as limiting the number of (unnecessary) instructions in the pipeline (rather than attempting to do many iterations of the loop in parallel) – Brendan Aug 16 '11 at 23:47
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    @Brendan, thanks! I didn't understand at all, until you said the thing about iterations of the loop in parallel. – Prof. Falken Aug 17 '11 at 11:45
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    @Brendan, Oh, now I get it! These modern processors are superscalar, and thus they will attempt to run multiple instructions at the same time. If this is a busy-wait loop, running more instructions won't make it faster, as it is just waiting for another condition. – Denilson Sá Maia Aug 17 '11 at 16:27
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    @Denilson: Yes, hyperthreading-friendliness (or just power-saving without HT) is one big benefit, but the other is avoiding a memory-ordering mis-speculation when leaving the spin-loop. Without pause, your spin-loop is effectively one pipeline-clear slower to notice the state-change of the memory location written by another core. – Peter Cordes Jun 13 '17 at 15:30
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rep nop = F3 90 = the encoding for pause, as well as how it decodes on older CPUs that don't support pause.


Prefixes (other than lock) that don't apply to an instruction are ignored in practice by existing CPUs.

The documentation says using rep with instructions it doesn't apply to is "reserved and can cause unpredictable behaviour" because future CPUs might recognize it as part of some new instruction. Once they establish any specific new instruction encoding using f3 xx, they document how it runs on older CPUs. (Yes, the x86 opcode space is so limited that they do crazy stuff like this, and yes it makes the decoders complicated.)

In this case, it means you can use pause in spinloops without breaking backwards compat. Old CPUs that don't know about pause will decode it as a NOP with no harm done, as guaranteed by Intel's ISA ref manual entry for pause. On new CPUs, you get the benefit of power-saving / HT friendliness, and avoiding memory-ordering mis-speculation when the memory you're spinning on does change and you leave the spin loop.


Links to Intel's manuals and tons of other good stuff on the x86 tag wiki info page

Another case of a meaningless rep prefix becoming a new instruction on new CPUs: lzcnt is F3 0F BD /r. On CPUs that don't support that instruction (missing the LZCNT feature flag in their CPUID), it decodes as rep bsr, which runs the same as bsr. So on old CPUs, it produces 32 - expected_result, and is undefined when the input was zero.

But tzcnt and bsf do the same thing with non-zero inputs, so compilers can and do use tzcnt even when it's not guaranteed that the target CPU will run it as tzcnt. AMD CPUs have fast tzcnt, slow bsf, and on Intel they're both fast. As long as it doesn't matter for correctness (you're not relying on flag-setting, or on leaving the destination unmodified behaviour in the input=0 case), having it decode as tzcnt on CPUs that support it is helpful.


One case of a meaningless rep prefix that will probably never decode differently: rep ret is used by default by gcc when targeting "generic" CPUs (i.e. not targetting a specific CPU with -march or -mtune, and not targetting AMD K8 or K10.) It will be decades before anyone could make a CPU that decodes rep ret as anything other than ret, because it's present in most binaries in most Linux distros. See What does `rep ret` mean?

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    The rep prefix was also used by Intel to add lock elision. – Paul A. Clayton Nov 11 '15 at 3:34
  • Prefixes that don't apply to an instruction are ignored. But it is mentioned that Repeat Prefixes (F2H and F3H) Reserved and may result in unpredictable behavior in Table 11-3. Effect of Prefixes on SSE, SSE2, and SSE3 Instructions. So the prefix application is ignored for some of the instructions, not for all. So is this feature considered undocumented? – St.Antario Oct 27 '19 at 5:25
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    @St.Antario: They phrase it that way because future CPUs might recognize it as part of some new instruction. On all real CPUs that's been the case, and once they establish an encoding using f3 xx they document how it runs on older CPUs. – Peter Cordes Oct 27 '19 at 5:29
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    Prefixes (other than lock) that don't apply to an instruction are ignored in practice by existing CPUs. It is documented that rep movbe causes #UD, so rep is not always ignored. Even if it does not apply to an instruction in the sense as it is specified in the REP/REPE/REPZ/REPNE/REPNZ manual entry. – St.Antario Oct 27 '19 at 6:21
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    @St.Antario: Interesting! In general though, for older instructions non-applicable prefixes are ignored. When introducing a new instruction it's possible to add stricter rules if they choose. IDK why they would choose that for this specific case. – Peter Cordes Oct 27 '19 at 6:29

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