# Obtaining remainder using single aarch64 instruction?

I am writing some assembly code for ARM8 (aarch64). I want to do a division and use the remainder obtained for further calculations. In x86 when I use 'div', and I know my remainder is kept in RDX. My question is - is there an equivalent to that in the aarch64 instruction set? I know 'udiv' and 'sdiv' do unsigned and signed divisions and gets me the quotient. Is there a single instruction which would give me remainder? (I want % modulo operator in c). I understand I can obtain it using algebra, just wanted to confirm I am not missing out on a simpler method.

Barring constant power-of-two divisors which can be optimised down to an and, there is no instruction that will calculate the remainder of a division. You can, however do it pretty neatly in two:

// input: x0=dividend, x1=divisor
udiv x2, x0, x1
msub x3, x2, x1, x0
// result: x2=quotient, x3=remainder

• This is wonderful! I used these 2 instructions to help in adding the digits of a given number for a programming assignment using a required loop. Thanks! Commented Apr 6, 2022 at 1:40

## Calculating the remainder isn't a single instruction

The Clang C compiler produced the following code for a modulo calculation:

udiv    x10, x0, x9
msub    x10, x10, x9, x0


## Good news, this isn't slow!

While the x86 does this in a single instruction, that doesn't make it faster.

On the Apple M-1, the above instruction pair is executed in about the same time as a single step. Possibly this is due to instruction macro-fusion that decodes multiple instructions into a single µ-op. It could also be due to parallelism in multiple execution units. Possibly, it is done in one EU where the remainder from the division calculation is cached and returned immediately.

Whatever the implementation, it seems to be about as fast as Intel's single instruction form.

Timing:

$time ./a.out 12345678901 Total: 301123495054 real 0m10.036s user 0m9.668s sys 0m0.031s  Instruction generated: udiv x10, x0, x9  ## Remainder-only Timing: $ time ./a.out 12345678901
Total: 8612082846779832640
real    0m10.190s
user    0m9.768s
sys 0m0.070s


Instructions generated:

udiv    x10, x0, x9
msub    x10, x10, x9, x0


## Division and remainder

Timing:

\$ time ./a.out 12345678901
Total: 8612083123211969892
real    0m10.103s
user    0m9.752s
sys 0m0.019s


Instructions generated:

udiv    x10, x0, x9
msub    x11, x10, x9, x0


## Benchmark code

The following C code can be run with either q = n / d or r = n % d commented out:

#include <stdio.h>
#include <stdlib.h>

int main(int argc, char *argv[])
{
unsigned long long n, d, q=1, r=1, total=0;

n = strtoull(argv[1], NULL, 10);
total = 0;
for (d=1 ; d<=n ; d++) {
q = n / d;
r = n % d;
total += q + r;
}
printf("Total: %llu", total);
return 0;
}

• You haven't proved it's a "single step" (fused into 1 wide instruction like mov/movk); I think you've proved that the throughput bottleneck of udiv can hide the extra work of an msub just fine, which is expected. I'd guess that a dependency chain through % would have higher latency than a dep chain through /, i.e. if the next iteration's inputs depended on a % this iteration, like x %= d if that can be arranged to not optimize away, e.g. by decrementing d instead of incrementing so it can't prove that it's a no-op. Commented Apr 5, 2021 at 23:04
• @PeterCordes Given that multiple execution units are involved, the timings don't constitute proof. That said, it is likely given that 1) macro-fusion is a well known and proven technique, 2) essentially all reasonable hardware implementations of integer division will simultaneously produce a remainder, 3) it would be wasteful to not combine the steps, and 4) Daniel Lemire also showed that the M-1 fuses mul and umulh for the same reasons. Commented Apr 5, 2021 at 23:40
• Interesting; yes it's totally possible, and reasonably likely if mul fusion . The main reason not to do it would be to avoid having one "uop" producing 2 register outputs; something AArch64 generally avoids except for ldp. (Or instruction or whatever M-1 calls an internal pipeline slot). That's why AArch64 splits up umull into umull and umulh, or vuzp into uzp1 / uzp2. But yes, high-performance implementations can fuse, if the decoders can find all the pairs they want to look for. Commented Apr 6, 2021 at 2:06
• Another test would be to try an unrelated msub, which we know can't fuse, to see if that's any slower. Commented Apr 6, 2021 at 5:03
• Per Dougall J, these are not fused: Other tested patterns are not fused, including adrp + add, mov + movk, mul + umulh, and udiv + msub. (emphasis mine) Commented Apr 11, 2021 at 5:22