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I have two 8-bit registers and have to check, if one of them is 0.

My solution by now is:

cmp $0, %r10b
je end
cmp $0, %r11b
je end

Is there any other way to do it?


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Yes, but it is unlikely to be more efficient, due to speculative execution on any x86-64 implementation. cmp updates all the flags, so there are no partial flags register stalls either. –  Brett Hale Mar 26 '14 at 13:10

1 Answer 1

Performance discussions in this answer are for recent Intel CPUs (Sandybridge, Haswell). Mostly applicable to at least as far back as Pentium M, or even earlier P6 (Pentium Pro / Pentium II). See http://agner.org/optimize/ for microarch docs. Performance considerations should be similar on AMD, except they don't macro-fuse test&branch instructions into a single macro-op the way Intel macro-fuses them into a single uop.

Branch predictors exist on every pipelined design, but are more important on something like Haswell than old pre-Silvermont Atom. Still, that part is pretty universal.

Small tweak to your version:

test %r10b, %r10b   ; test is shorter than cmp with an immediate, but no faster
je   end
test %r11b, %r11b
je   end

Probably only one of the test/je pairs will macro-fuse in the 2nd, because they'll probably both hit the decoders in the same cycle. Also, if either value was the output of an ALU op, it probably already set the zero-flag. So arrange your code so one of the branches doesn't need to separately test.

You can save a branch (at the expense of an extra uop). Throughput of even non-taken branches could be a bottleneck in a really tight loop. Sandybridge can only sustain 1 branch per 2 cycles. So this idea might possibly help for:

test  %r10b, %r10b
setnz %r15b   ; 1 if %r10b == 0, else 0
dec   %r15b   ; 0 if %r10b == 0, else 0xFF
test  %r11b, %r15b
je    end

This is one more instruction (all single-uop instructions with 1 cycle latency, though.) It adds more latency before the branch instruction can be retired (increasing the mispredict penalty by 3 cycles), but it could increase performance:

If a && b is predictable, but it's unpredictable which of a or b will actually be zero, this can reduce the amount of branch mispredicts. Benchmark / perf-counter test it, though: programmers are said to be notoriously bad at guessing which branches will be predictable in their code. CPUs have a limited size branch-history-buffer, so using one fewer entry can help a tiny bit.

If latency really doesn't matter, just throughput (i.e. mispredicts are very infrequent):

; mov     %r10b, %al  ; have the byte you want already stored in %r10b
imul    %r11b        ; Intel: 3 cycle latency, 1/cycle throughput.
test    %ax, %ax
je      end
   ; or    movzx   %ax, %eax  ; to avoid the Intel decode penalty for 16b
   ;       test   %eax, %eax

Total of 2 uops, if you don't need to save the old value of %al, and you can manage to have one of the values in %al. If the upper bits in %eax were zero before this, test %eax, %eax wouldn't suffer the 16bit-insn decode penalty on Intel designs, but might generate a partial-reg-merging uop (or a stall), which would (partially) defeat the purpose.

Actually, this isn't bad as far as latency, compared to the test/setcc version. And it's fewer uops. The big problem is the huge decode penalty on the 16b test insn. This is ok in a long-running loop on SnB and later, or if the loop is small enough for the loop buffer, Nehalem. Otherwise, stay away from 16bit ops. movzxwl %ax, %eax would be an extra uop, but would allow test %eax, %eax without a partial-register stall.

@Brett Hale's comment on the OP: You only get partial flag stalls (or on later CPUs, an extra uop added to merge the flags (much more efficient)) if your branch instruction depends on flag bits that weren't modified by the last instruction to set the flags.

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hmm, IDK what I was thinking with my first attempt at an answer. Thanks for catching my silly mistake. Fixed now. –  Peter Cordes Jul 20 at 17:06
Yeah. @10K, I get to see 2 deleted answers that made the same initial error - and it's real easy to make trying to keep test/cmp/sub/jcc, etc., straight. I'm always sceptical of micro-optimizations, since they're a sliding target with each architecture. I tend to go with the most straightforward case being the best candidate for future optimizations. But this +1 answer is full of interesting details. Maybe you could further qualify them with processor architectures? –  Brett Hale Jul 20 at 17:42
Good point, I sometimes forget to mention that I'm mostly looking at timings and throughput on recent Intel (SnB and onwards). I added that and some other thoughts. And yeah, it's too much work to write much code in asm. I'd only use tricks like this if I was already optimizing a hot loop, and it needed this operation. It's fun to play around with performance ideas, though. –  Peter Cordes Jul 20 at 18:19
Don't get me wrong. I think there's plenty of room for this sort of expertise. The GMP project is one example that could always use your talents. Not to mention compiler technology. Beyond that, I love the idea that people still care about an extra cycle or two:) –  Brett Hale Jul 20 at 18:36

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