I need some division algorithm which can handle big integers (128-bit). I've already asked how to do it via bit shifting operators. However, my current implementation seems to ask for a better approach

Basically, I store numbers as two `long long unsigned int`

's in the format

`A * 2 ^ 64 + B`

with `B < 2 ^ 64`

.

This number is divisible by `24`

and I want to divide it by `24`

.

My current approach is to transform it like

```
A * 2 ^ 64 + B A B
-------------- = ---- * 2^64 + ----
24 24 24
A A mod 24 B B mod 24
= floor( ---- ) * 2^64 + ---------- * 2^64 + floor( ---- ) + ----------
24 24.0 24 24.0
```

However, this is buggy.

(Note that floor is `A / 24`

and that `mod`

is `A % 24`

. The normal divisions are stored in `long double`

, the integers are stored in `long long unsigned int`

.

Since `24`

is equal to `11000`

in binary, the second summand shouldn't change something in the range of the fourth summand since it is shifted 64 bits to the left.

So, if `A * 2 ^ 64 + B`

is divisible by 24, and B is not, it shows easily that it bugs since it returns some non-integral number.

What is the error in my implementation?