Consider the following code:

#include <limits>
#include <cstdint>

using T = uint32_t; // or uint64_t

T shift(T x, T y, T n)
    return (x >> n) | (y << (std::numeric_limits<T>::digits - n));

According to godbolt, clang 3.8.1 generates the following assembly code for -O1, -O2, -O3:

shift(unsigned int, unsigned int, unsigned int):
        movb    %dl, %cl
        shrdl   %cl, %esi, %edi
        movl    %edi, %eax

While gcc 6.2 (even with -mtune=haswell) generates:

shift(unsigned int, unsigned int, unsigned int):
    movl    $32, %ecx
    subl    %edx, %ecx
    sall    %cl, %esi
    movl    %edx, %ecx
    shrl    %cl, %edi
    movl    %esi, %eax
    orl     %edi, %eax

This seems far less optimized, since SHRD is very fast on Intel Sandybridge and later. Is there anyway to rewrite the function to facilitate optimization by compilers (and in particular gcc) and to favor the use of SHLD/SHRD assembly instructions?

Or are there any gcc -mtune or other options that would encourage gcc to tune better for modern Intel CPUs?

With -march=haswell, it emits BMI2 shlx / shrx, but still not shrd.

  • The difference is in fact tiny. shrd takes 4 cycles to resolve. sal takes 2. My guess is that gcc takes 7 cycles and clang takes 5. (Skylake) On e.g. Bulldozer gcc is faster because sal/shr is a single cycle and shrd is 8.
    – Johan
    Sep 1, 2016 at 23:25
  • @Johan: Haswell: SHRD is 1uop, 3c latency, one per 1c throughput. SHL/SHR r,cl is 3 uops, 2c latency, one per 2c throughput. I forget if clang's silly 8bit mov can be eliminated at register-rename time, so clang's code is either 4c or 3c latency on SKL, with much better throughput. Sep 1, 2016 at 23:34
  • 1
    @Johan: oops, I was looking at shrd r,r,i, not shrd r,r,cl. The variable-count version is still 4 uops, with 4c latency, and not the best option when BMI2 is available. Sep 2, 2016 at 0:06
  • 1
    @Johan: I always look at the spreadsheet version, which already exists (in .ods format, OpenOffice, but you could easily convert it to Excel if you want). My mistake was that I remembered testing SHRD specifically on my own SnB hardware, and that it was efficient on SnB (and that IACA was wrong for SHRD/SHLD on SnB). But what I was remembering was the immediate-count version, so I only saw what I was expecting to see in Agner's spreadsheet. :/ Sep 2, 2016 at 0:15
  • 2
    I think it's worth pointing out that n being 0 is undefined behavior.
    – tbodt
    Jun 29, 2017 at 23:41

1 Answer 1


No, I can see no way to get gcc to use the SHRD instruction.
You can manipulate the output that gcc generates by changing the -mtune and -march options.

Or are there any gcc -mtune or other options that would encourage gcc to tune better for modern Intel CPUs?

Yes you can get gcc to generate BMI2 code:

E.g: X86-64 GCC6.2 -O3 -march=znver1 //AMD Zen
Generates: (Haswell timings).

    code            critical path latency     reciprocal throughput
    mov     eax, 32          *                     0.25
    sub     eax, edx         1                     0.25        
    shlx    eax, esi, eax    1                     0.5
    shrx    esi, edi, edx    *                     0.5
    or      eax, esi         1                     0.25
    TOTAL:                   3                     1.75

Compared with clang 3.8.1:

    mov    cl, dl            1                     0.25
    shrd   edi, esi, cl      4                     2
    mov    eax, edi          *                     0.25 
    TOTAL                    5                     2.25

Given the dependency chain here: SHRD is slower on Haswell, tied on Sandybridge, slower on Skylake.
The reciprocal throughput is faster for the shrx sequence.

So it depends, on post BMI processors gcc produces better code, pre-BMI clang wins.
SHRD has wildly varying timings on different processors, I can see why gcc is not overly fond of it.
Even with -Os (optimize for size) gcc still does not select SHRD.

*) Not part of the timing because either not on the critical path, or turns into a zero latency register rename.

  • 1
    The mov eax,edi (which goes away when inlining) is actually zero latency on Haswell. And mov eax, 32 isn't on the critical path, so the BMI2 version is actually 4c latency from the count being ready, and 3c latency from x being ready. Sep 2, 2016 at 0:11
  • 1
    shlx / shrx have a write-only destination (using VEX encoding), so they're 1c latency, but can run in parallel with each other (without a resource conflict, because they can run on p0/p6). It's bogus to have a single "latency" column when there isn't one single dependency chain. So the actual latency of the BMI2 version is 2c from x and y being ready, and 3c from count being ready. (i.e. if count isn't on the critical path, the latency is only 2c). With constant (immediate) shift-counts, SHRD would be potentially useful. Sep 2, 2016 at 2:26
  • Missed that because I was blinded by the use of ESI in both. Good catch.
    – Johan
    Sep 2, 2016 at 13:06
  • Yeah same here, at first. Then I thought "wait a minute, aren't they supposed to be shifting both operands separately?". BTW, "critical path latency" might be a good column header. Those are still latency numbers. Sep 2, 2016 at 13:08

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.