You are correct that finding the multiplicative inverse may be worth it if integer division inside a loop is unavoidable. gcc and clang won't do this for you with run-time constants, though; only compile-time constants. It's too expensive (in code-size) for the compiler to do without being sure it's needed, and the perf gains aren't as big with non compile-time constants. (I'm not confident a speedup will always be possible, depending on how good integer division is on the target microarchitecture.)

### Using a multiplicative inverse

*If* you can't transform things to pull the divide out of the loop, and it runs many iterations, and a significant increase in code-size is with the performance gain (e.g. you aren't bottlenecked on cache misses that hide the div latency), then you might get a speedup from doing for run-time constants what the compiler does for compile-time constants.

Note that different constants need different shifts of the high half of the full-multiply, and some constants need more different shifts than others. (Another way of saying that some of the shift-counts are zero for some constants). So non-compile-time-constant divide-by-multiplying code needs all the shifts, and the shift counts have to be variable-count. (On x86, this is more expensive than immediate-count shifts).

`libdivide`

has an implementation of the necessary math. You can use it to do SIMD-vectorized division, or for scalar, I think. This will definitely provide a big speedup over unpacking to scalar and doing integer division there. I haven't used it myself.

(Intel SSE/AVX doesn't do integer-division in hardware, but provides a variety of multiplies, and fairly efficient variable-count shift instructions. For 16bit elements, there's an instruction that produces only the high half of the multiply. For 32bit elements, there's a widening multiply, so you'd need a shuffle with that.)

Anyway, you could use libdivide to vectorize that add loop, with a horizontal sum at the end.

### Other ways to get the div out of the loop

```
for (i=0; i<1000000000; i++)
s += i/a;
```

In your example, you might get better results from using a `uint128_t s`

accumulator and dividing by `a`

outside the loop. A 64bit add/adc pair is pretty cheap. (It wouldn't give identical results, though, because integer division truncates instead of rounding to nearest.)

I think you can account for that by looping with `i += a; tmp++`

, and doing `s += tmp*a`

, to combine all the adds from iterations where `i/a`

is the same. So `s += 1 * a`

accounts for all the iterations from `i = [a .. a*2-1]`

. Obviously that was just a trivial example, and looping more efficiently is usually not actually possible. It's off-topic for this question, but worth saying anyway: Look for big optimizations by re-structuring code or taking advantage of some math before trying to speed up doing the exact same thing faster. Speaking of math, you can use the `sum(0..n) = n * (n+1) / 2`

formula here, because we can factor `a`

out of `a*1 + a*2 + a*3 ... a*max`

. I may have an off-by-one here, but I'm confident a closed-form simple constant time calculation will give the same answer as the loop for any `a`

:

```
uint32_t n = 1000000000 / a;
uint32_t s = a * n*(n+1)/2 + 1000000000 % a;
```

If you just needed `i/a`

in a loop, it might be worth it to do something like:

```
// another optimization for an unlikely case
for (uint32_t i=0, remainder=0, i_over_a=0 ; i < n ; i++) {
// use i_over_a
++remainder;
if (remainder == a) { // if you don't need the remainder in the loop, it could save an insn or two to count down from a to 0 instead of up from 0 to a, e.g. on x86. But then you need a clever variable name other than remainder.
remainder = 0;
++i_over_a;
}
}
```

Again, this is unlikely: it only works if you're dividing the loop counter by a constant. However, it should work well. Either `a`

is large so branch mispredicts will be infrequent, or `a`

is (hopefully) small enough for a good branch predictor to recognize the repeating pattern of `a-1`

branches one way, then 1 branch the other way. The worst-case `a`

value might be 33 or 65 or something, depending on microarchitecture. Branchless asm is probably possible but not worth it. e.g. handle `++i_over_a`

with an add-with-carry and a conditional move for zeroing. (e.g. x86 pseudo-code `cmp a-1, remainder`

/ `cmovc remainder, 0`

/ `adc i_over_a, 0`

. The `b`

(below) condition is just `CF==1`

, same as the `c`

(carry) condition. The branchless asm would be simplified by decrementing from a to 0. (don't need a zeroed reg for cmov, and could have `a`

in a reg instead of `a-1`

))