Many programming languages, including the older standards of C and C++, guarantee the division rule, which is

```
a = b * (a / b) + a % b
```

even if the exact values of `a/b`

and `a%b`

are left undefined. (Nowadays they are defined in C and C++.) This can be exploited to calculate the desired result in many languages and platforms using (an equivalent of) the following code:

```
int divF(int a, int b) { return a / b - (a % b < 0); }
```

This is the version from @TomasPetricek's answer. However, this works only for `b > 0`

!

The following code will work for any `b != 0`

:^{[1]}

```
int sign(int x) { return (x > 0) - (x < 0); }
int divF2(int a, int b) { return a / b - (sign(a % b) == -sign(b)); }
```

However, the rounding-down division (aka flooring division, aka Knuth's division) is not always desirable. It is argued^{[2]} that Euclidean division is the most generally useful one. It rounds down for `b > 0`

, and up for `b < 0`

. It has the nice property that the value of the compatibly defined remainder is *always non-negative*, for all `a`

, `b`

, independently of their signs. Additionally it coincides with bit-shifts on twos complement machines for power-of-two divisors. Yes, it is also faster to calculate:

```
int divE(int a, int b) {
int c = a % b < 0;
return a / b + (b < 0 ? c : -c);
}
```

All three versions generate branchless code with clang 3.4.1 `-O2`

on amd64. However, on twos complement architectures, the following *may* be marginally faster:

```
int divE2(int a, int b) { return a / b + (-(a % b < 0) & (b < 0 ? 1 : -1)); }
```

## Generated code

divF:

```
cdq
idiv esi
shr edx, 31
sub eax, edx
```

divF2:

```
cdq
idiv esi
test edx, edx
setg cl
movzx ecx, cl
shr edx, 31
sub ecx, edx
test esi, esi
setg dl
movzx edx, dl
shr esi, 31
sub esi, edx
cmp ecx, esi
sete cl
movzx ecx, cl
sub eax, ecx
```

divE:

```
cdq
idiv esi
mov ecx, edx
shr ecx, 31
sar edx, 31
test esi, esi
cmovs edx, ecx
add eax, edx
```

divE2:

```
cdq
idiv esi
sar edx, 31
shr esi, 31
lea ecx, dword ptr [rsi + rsi - 1]
and ecx, edx
add ecx, eax
mov eax, ecx // WTF? But OK when inlined...
```

## Benchmarks

With the above mentioned compiler, on i7-3720QM CPU @ 2.60GHz, running the following code with different TESTFUNCs, gives

```
simple truncating division:
1225053229 base: 8.41 ns
round to -inf for b > 0, broken for b < 0:
975205675 divF: 8.70 ns
975205675 ben135: 8.71 ns
euclidean division:
1225082031 divE2: 9.37 ns
1225082031 divE: 9.67 ns
round to -inf, work for b < 0:
975229215 Chazz: 9.67 ns
975229215 divF2: 10.56 ns
975229215 runevision: 13.85 ns
975229215 LegsDrivenCat: 16.62 ns
975229215 Warty: 20.00 ns
likely an overflow bug trying to implement the above:
975049659 DrAltan: 11.77 ns
```

The first column is a checksum grouping algorithms producing the same result. `base`

is the simplest truncating division used to measure the testing overhead.

Code:

```
#define STRINGIZE2(a) #a
#define STRINGIZE(a) STRINGIZE2(a)
int main()
{
srandom(6283185);
static const int N = 500000000;
int ret = 0;
for(int i = 0; i < N; ++i)
{
int a = random() - 0x40000000, b;
do b = (random() >> 16) - 0x4000; while(b == 0);
ret += TESTFUNC(a,b);
}
timespec t;
clock_gettime(CLOCK_VIRTUAL, &t);
printf("%10d %20s: %5.2f ns\n", ret, STRINGIZE(TESTFUNC), (t.tv_sec*1.e9 + t.tv_nsec)/N);
}
```

## References

- Daan Leijen. Division and Modulus for Computer Scientists. December 2001.
- Raymond T. Boute. The Euclidean definition of the functions div and mod. April 1992.