Suppose we have two register-length2 signed1 integers, say a and b. We want to compute the value (a + b) / 2, either rounded up, down, towards zero, or away from zero, whichever way is easier (i.e. we do not care about the rounding direction).

The result is another register-length signed integer (it is clear that the average must be within the range of a register-length signed integer).

What is the fastest way to perform this computation?

You may choose which registers the two integers will initially be in, and which register the average ends up being in.

Footnote 1: For unsigned integers, we can do it in two instructions. This is perhaps the fastest way, although rotate-through-carry is more than 1 uop on Intel CPUs. But only a couple when the count is only 1. An answer on a Q&A about unsigned mean discusses the efficiency.

add rdi, rsi
rcr rdi, 1

The two numbers start in rdi and rsi, and the average ends up in rdi. But for signed numbers, -1 + 3 would set CF, and rotate a 1 into the sign bit. Not giving the correct answer of +1.

Footnote 2: I specified register-length signed integers so that we can't simply sign extend the integers with a movsxd or cdqe instruction.

The closest I've got towards a solution uses four instructions, one of them an rcr that's 3 uops on Intel, 1 on AMD Zen (https://uops.info/):

add rdi, rsi
setge al
sub al, 1          # CF = !(ge) = !(SF==OF)
rcr rdi, 1         # shift CF into the top of (a+b)>>1

I think a shorter solution probably lies in combining the middle two instructions in some way, i.e. performing CF ← SF ≠ OF.

I've seen this question, but that's not x86-specific and none of the answers seem to compile to something as good as my solution.

  • 4
    Try starting with rdi = -1 and rsi = 3. add rdi, rsi will set CF, and it will be rotated in to the sign bit of rdi by the rcr rdi, 1 instruction, resulting in some negative number. But the correct answer is 1.
    – Bernard
    Jul 25, 2022 at 17:25
  • 1
    @Brendan Nope, try starting with both integers bigger than 2^30. Adding the two integers will set the sign bit, and so your sar instruction will keep the sign bit set, resulting in a negative integer. But the correct answer is positive.
    – Bernard
    Jul 25, 2022 at 17:42
  • 3
    Hrm (using RAX instead of RDI): cqo; add rax,rsi; adc rdx,0; shrd rax,rdx,1.
    – Brendan
    Jul 25, 2022 at 17:49
  • 1
    @Brendan Also possible with any pair of registers if you replace cqo with mov hi, reg; sar hi, 63. The mov is a rename and thus essentially free.
    – fuz
    Jul 25, 2022 at 17:55
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    If my math is right, sar rdi, 1 ; sar rsi, 1 ; add rdi, rsi works unless both operands are odd, in which case we need to add 1 to the result. Maybe there is some way to use this? Jul 25, 2022 at 18:03

2 Answers 2


Depending on how we interpret your lax rounding requirements, the following may be acceptable:

sar rdi, 1
sar rsi, 1
adc rdi, rsi

Try on godbolt

This effectively divides both inputs by 2, adds the results, and adds 1 more if rsi was odd. (Remember that sar sets the carry flag according to the last bit shifted out.)

Since sar rounds to minus infinity, the result of this algorithm is:

  • exactly correct if rdi, rsi are both even or both odd

  • rounded down (toward minus infinity) if rdi is odd and rsi is even

  • rounded up (toward plus infinity) if rdi is even and rsi is odd

As a bonus, for random inputs, the average rounding error is zero.

It should be 3 uops on a typical CPU, with a latency of 2 cycles since the two sar are independent.

  • 3
    "up" here is always towards +Inf, not symmetric around 0. But yeah, for avg(-3,-3), we get -2 + -2 + CF(1), so we get the correct -3. For avg(3,3), we get 1 + 1 + CF(1) which is also 3. So the always-upward of adding CF counteracts the towards -Inf rounding of arithmetic right shift. Jul 25, 2022 at 20:06
  • @PeterCordes Would something like this be useful? lea eax,[edi+esi] shr eax,1
    – vengy
    Jul 26, 2022 at 12:50
  • @vengy: For unsigned inputs that are known to not overflow, yes. i.e. that are already zero-extended from 31 bits or narrower. (Except you'd never use 32-bit address-size with LEA, you'd use lea eax, [rdi+rsi] to avoid an address-size prefix). But this Q&A is about full-range signed inputs that may be negative. So even sar eax, 1 wouldn't be sufficient. Jul 26, 2022 at 12:55
  • Seems like this is the only faster solution so far, but with the drawback that the operation is not commutative.
    – Bernard
    Aug 2, 2022 at 17:04

As an outside answer, consider the pavg family of instructions.

I say "outside", since this is likely not acceptable to you. It assumes the value is unsigned 8-bit or 16-bit and in an SSE register, which of course also requires SSE. I mention it mainly since it is x86's anointed equivalent to averaging instructions in other ISAs.

In its defense, SSE is ubiquitous by now, even guaranteed on x86-64. Also, this instruction is 1 cycle, and actually can do 4 at once if you like. Best of all, unlike your original solutions, it also correctly handles overflow issues.

Note that it's possible to use an unsigned routine to implement a signed routine, though in general correctly accounting for overflow issues is a nightmare. Your current solution appears to already be broken in that regard, though.

  • Can you maybe range-shift signed to unsigned by adding 128 (i.e. flipping the high bit)? So pxor both inputs with set1_epi8(0x80), pavgb, then pxor back to the signed range? I'd expect that to work even near overflow boundaries, since pavgb/pavgw does. And you can use other unsigned-rounding bithacks that don't rely on carry-out, if you want a vectorized version of this trick for 32-bit operand-size. (But yeah, not generally worth transferring data from GP integer regs to XMM and back for a single scalar average, especially of signed numbers.) Jul 26, 2022 at 4:02
  • @PeterCordes I can't comment on algorithms for using this for signed; that sort of thing is obnoxiously difficult to get right and it's 2am right now. And yeah, the assumption is you're already in an XMM register. Actually, what inspired this answer was a recent image processing paper where this was used for a win; you get back a lot in parallelism doing this over a whole image, and images are often 8-bit unsigned so it's essentially a perfect use-case.
    – geometrian
    Jul 26, 2022 at 9:06
  • "Your current solution appears to already be broken in that regard, though." Do you mean the fact that setge can only assign to an 8-bit register? Or is it something else I'm not aware of?
    – Bernard
    Jul 26, 2022 at 15:43
  • I suppose this solution works, but if my integer was only 16 bits long then I could just perform addition without overflow in regular registers. Unless I'm using some ancient 16-bit x86 hardware.
    – Bernard
    Jul 26, 2022 at 15:45
  • 1
    @Bernard but if you have lots of 8/16-bit integers then this will be much faster because it can do multiple additions at the same time
    – phuclv
    Jul 26, 2022 at 15:56

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