Source my answer in:

Is this expression correct in c preprocessor

I'm a little bit out of my forte here, and I'm trying to understand how this particular optimization works.

As mentioned in the answer, gcc will optimize integer division by 7 to:

```
mov edx, -1840700269
mov eax, edi
imul edx
lea eax, [rdx+rdi]
sar eax, 2
sar edi, 31
sub eax, edi
```

Which translates back into C as:

```
int32_t divideBySeven(int32_t num) {
int32_t temp = ((int64_t)num * -015555555555) >> 32;
temp = (temp + num) >> 2;
return (temp - (num >> 31));
}
```

Let's take a look at the first part:

```
int32_t temp = ((int64_t)num * -015555555555) >> 32;
```

Why this number?

Well, let's take 2^64 and divide it by 7 and see what pops out.

```
2^64 / 7 = 2635249153387078802.28571428571428571429
```

That looks like a mess, what if we convert it into octal?

```
0222222222222222222222.22222222222222222222222
```

That's a very pretty repeating pattern, surely that can't be a coincidence. I mean we remember that 7 is `0b111`

and we know that when we divide by 99 we tend to get repeating patterns in base 10. So it makes sense that we'd get a repeating pattern in base 8 when we divide by 7.

So where does our number come in?

`(int32_t)-1840700269`

is the same as `(uint_32t)2454267027`

`* 7 = 17179869189`

And finally 17179869184 is `2^34`

Which means that 17179869189 is the closest multiple of 7 2^34. Or to put it another way **2454267027 is the largest number that will fit in a uint32_t which when multiplied by 7 is very close to a power of 2**

What's this number in octal?

```
0222222222223
```

Why is this important? Well, we want to divide by 7. This number is 2^34/7... approximately. So if we multiply by it, and then leftshift 34 times, we should get a number very close to the exact number.

The last two lines look like they were designed to patch up approximation errors.

Perhaps someone with a little more knowledge and/or expertise in this field can chime in on this.

```
>>> magic = 2454267027
>>> def div7(a):
... if (int(magic * a >> 34) != a // 7):
... return 0
... return 1
...
>>> for a in xrange(2**31, 2**32):
... if (not div7(a)):
... print "%s fails" % a
...
```

Failures begin at 3435973841 which is, funnily enough 0b11001100110011001100110011010001

Classifying why the approximation fails is a bit beyond me, and why the patches fix it up is as well. Does anyone know how the magic works beyond what I've put down here?

`udiv_qrnnd_preinv`

in`gmp-impl.h`

) – Brett Hale Mar 7 '13 at 8:25