I'm a bit confused about both instructions. First let's discard the special case when the scanned value is 0 and the undefined/bsr or bitsize/lzcnt result - this difference is clear and not part of my question.

Let's take the binary value 0001 1111 1111 1111 1111 1111 1111 1111

According to Intel's spec the result for lzcnt is 3

According to Intel's spec the result for bsr is 28

lzcnt counts, bsr returns the index or distance from bit 0 (which is the lsb).

How can both instructions be the same and how can lzcnt be emulated as bsr in case there's no BMI on the CPU available? Or is bit 0 in case of bsr the msb? Both "code operations" in Intel's spec are different too, one counts or indexes from the left, the other from the right.

Maybe someone can shed some light on this, I have no CPU without BMI/lzcnt instruction to test if the fallback to bsr works with the same result (as the special case of value 0 to scan never happens).

2 Answers 2


LZCNT gives the number of leading zero bits. BSR gives the bit index of the most significant 1 bit. So they do effectively the same thing for the non-zero case, except the result is interpreted differently. Therefore you can just subtract the BSR result from 31 to get the same behaviour as with LZCNT, i.e. LZCNT == (31 - BSR).

  • Now you confuse me even more. Sorry. If the result is different, then they do effectively not the same thing. They look for the same bit, but in a program I rely on the result. And if the result is different for lzcnt and lzcnt-as-bsr-emulation-on-non-bmi-cpu then I can't use it and must test for BMI. (special doesn't matter, scanned value is never 0). So why does lzcnt fallback to bsr at all?
    – hopperpl
    Commented Sep 5, 2014 at 10:42
  • There is no "fallback" - they are two different instructions - you would need to either use conditional assembly, or do a run-time check and maybe implement some kind of dispatcher, so that you either use LZCNT or BSR + SUB.
    – Paul R
    Commented Sep 5, 2014 at 10:59
  • 7
    Now I got it. On CPUs without BMI the lzcnt instruction does not #ud but executes bsr instead. With a different result than lzcnt. I misinterpreted the spec here. Disregarding the special case when the scanned value is zero, tzcnt and bsf behave the same, but lzcnt and bsr do not. And a lot of webpages say that both are. Which is obviously incorrect and the reason for my confusion. Thanks for clearing that up.
    – hopperpl
    Commented Sep 5, 2014 at 19:24
  • 7
    By the way (and late), you can also implement it as LZCNT = BSR ^ 31, which saves an instruction
    – user555045
    Commented Jul 1, 2015 at 10:55
  • 1
    @harold This is actually how GCC's __builtin_clz is implemented. If you do __builtin_clz(x) ^ 31, it yields a single BSR since the XORs cancel out.
    – minmaxavg
    Commented Oct 3, 2018 at 21:17

To be clear, there is no working fallback from lzcnt to bsr. What happened is that Intel used the previously redundant sequence rep bsr to encode the new lzcnt instruction. Using a redudant rep prefix for bsr was generally defined to be ignored, but with the caveat that it may decode differently on future CPUs1.

So if you happen to execute lzcnt on a CPU that doesn't support it, it will execute as bsr. Of course, this fallback is not exactly intentional, and it gives the wrong result (as Paul R points out they look at the same bit but report it differently): it is just a consequence of the way the new instruction was encoded and how pointless rep prefixes were treated by prior CPUs. So the world fallback is pretty much entirely inappropriate for lzcnt and bsr.

The situation is more subtle for the case of tzcnt and bsf. It uses the same encoding trick: tzcnt has the same encoding as rep bsf, but here the "fallback" mostly works since tzcnt returns the same value as bsf for all inputs except zero. For zero inputs tzcnt returns 32, but bsf leaves the destination undefined.

You can't really use even this fallback though: if you never have zero inputs you might as well just use bsf, saving a byte and being compatible with a couple decades of CPUs, and if you do have zero inputs the behavior differs.

So the behavior is perhaps better classified as trivia than a fallback...

1 Normally this would more or less be esoterica, but you could for example use rep prefixes are where they have no functional effect to lengthen instructions to help align subsequent code without inserting explicit nop instructions. Given the "may decode differently in the future" this would be dangerous when compiling code which may run on any future CPU.

  • I believe the usual "undefined" behaviour of BSF and BSR is to leave the destination unmodified when the source operand is 0. In that case, even when the source operand is guaranteed not be 0, it would be better to use TZCNT or LZCNT ^ 31 over BSF or BSR respectively because the newer instruction wouldn't have a dependency on the old value of the source register. Or at least in theory, apparently this doesn't work in practice: stackoverflow.com/questions/21390165/…
    – Ross Ridge
    Commented Apr 17, 2017 at 1:44
  • Indeed, several of the two operand instructions that actually overwrite their first operand (rather than also using it as an input) have this false dependency (see also popcnt). Perhaps it will be fixed in a future architecture. AFAIK not all chips implemented the behavior as "source unchanged" - apparently some AMD chips set it to zero or something. @RossRidge
    – BeeOnRope
    Commented Apr 17, 2017 at 1:47
  • AMD's AMD64 manual (March 2017 version) explicitly documents the dest-unchanged behaviour.: If the second operand contains 0, the instruction sets ZF to 1 and does not change the contents of the destination register. Fun fact: @RossRidge: Skylake fixes the false-dep for tz/lzcnt, but not popcnt. (IIRC, there's a SKL erratum for popcnt having a false dep, so maybe they meant to. :P) Commented Sep 9, 2017 at 1:37
  • rep nop is pause. The padding prefixes usually used with NOP are 66 operand-size. I think Intel says something about CPUs ignoring prefixes that don't apply to an instruction. They point out that future CPUs could decode it differently, which is exactly what happens here, but the "compatibility" with old CPUs is fairly well defined. For this reason, some compilers (with -mtune=generic) will use tzcnt instead of bsf when the input is known non-zero, because tzcnt is much faster on AMD. I suspect that setting flags from the input operand instead of output is what hurts them. Commented Sep 9, 2017 at 1:41
  • @PeterCordes - good point. I updated the answer to indicate that Intel and AMD apparently allowed the redundant rep prefixes, but kept open the option of decoding them differently in the future - which made them effectively useless for compile-to-native code that might even run on another CPU (but perhaps still useful for JIT or AOT compiler code), since you could never be sure your binary wouldn't break. Lately it seems they are being stricter with their prefix behavior, usually defining exact semantics and #GPing if not followed...
    – BeeOnRope
    Commented Sep 9, 2017 at 2:02

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