Integer division / modulo is extremely slow compared to any other operation. (And is dependent on data size, unlike most operations on modern hardware, see the end of this answer)

**For repeated use of the same modulus, you will get ***much* better performance from finding the multiplicative inverse for your integer divisor. Compilers do this for you for compile-time constants, but it's moderately expensive in time and code-size to do it at run-time, so with current compilers you have to decide for yourself when it's worth doing.

It takes some CPU cycles up front, but they're amortized over 3 divisions per iteration.

The reference paper for this idea is Granlund and Montgomery's 1994 paper, back when divide was only 4x as expensive as multiply on P5 Pentium hardware. That paper talks about implementing the idea in gcc 2.6, as well as the mathematical proof that it works.

Compiler output shows the kind of code that division by a small constant turns into:

```
## clang 3.8 -O3 -mtune=haswell for x86-64 SysV ABI: first arg in rdi
int mod13 (int a) { return a%13; }
movsxd rax, edi # sign-extend 32bit a into 64bit rax
imul rcx, rax, 1321528399 # gcc uses one-operand 32bit imul (32x32 => 64b), which is faster on Atom but slower on almost everything else. I'm showing clang's output because it's simpler
mov rdx, rcx
shr rdx, 63 # 0 or 1: extract the sign bit with a logical right shift
sar rcx, 34 # only use the high half of the 32x32 => 64b multiply
add ecx, edx # ecx = a/13. # adding the sign bit accounts for the rounding semantics of C integer division with negative numbers
imul ecx, ecx, 13 # do the remainder as a - (a/13)*13
sub eax, ecx
ret
```

And yes, all this is cheaper than a `div`

instruction, for throughput and latency.

I tried to google for simpler descriptions or calculators, and found stuff like this page.

On modern Intel CPUs, 32 and 64b multiply has one per cycle throughput, and 3 cycle latency. (i.e. it's fully pipelined).

Division is only partially pipelined (the div unit can't accept one input per clock), and unlike most instructions, has data-dependent performance:

From Agner Fog's insn tables (see also the x86 tag wiki):

- Intel Core2:
`idiv r32`

: one per 12-36c throughput (18-42c latency, 4 uops).

`idiv r64`

: one per 28-40c throughput (39-72c latency, 56 uops). (unsigned `div`

is significantly faster: 32 uops, one per 18-37c throughput)
- Intel Haswell:
`div/idiv r32`

: one per 8-11c throughput (22-29c latency, 9 uops).

`idiv r64`

: one per 24-81c throughput (39-103c latency, 59 uops). (unsigned `div`

: one per 21-74c throughput, 36 uops)
- Skylake:
`div/idiv r32`

: one per 6c throughput (26c latency, 10 uops).

64b: one per 24-90c throughput (42-95c latency, 57 uops). (unsigned `div`

: one per 21-83c throughput, 36 uops)

So on Intel hardware, unsigned division is cheaper for 64bit operands, the same for 32b operands.

The throughput differences between 32b and 64b `idiv`

can easily account for 150% performance. Your code is completely throughput bound, since you have plenty of independent operations, especially between loop iterations. The loop-carried dependency is just a `cmov`

for the max operation.

`int64_t`

with`int`

. Use the same type throughout your function.`time ./120`

, right? You don't need to fork a`(subshell)`

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