Here's one idea, which uses one multiplication and one shift, so it'll be faster than a division on most systems. Since your numerators top out at 768,000,000 ~= 30 bits, we don't have much room left in a 32-bit word, so we'll have to use 64-bit multiplication.

The main idea is to take advantage of the fact that:

```
x / y == (x * k) / (y * k)
```

and that dividing by a power of 2 is a simple, fast bit shift.

So to pick a particular example, assume `x = 700,000,000`

and `y = 47`

(so the correct quotient is 14,893,617). To avoid rounding errors, our shift needs to be approximately the size of our largest possible numerator - 30 bits. Find the value of `k`

that gives the closest approximation to `y * k = 2^30`

, which is `k = 22845571`

in this case. Then `x * k = 0x38D08C4CE6F500`

. Shifting this by 30 bits gives `0xE34231 = 14,893,617`

, our expected quotient. It's possible you may need to add 1-2 more bits for some combinations of numerator/denominator for rounding purposes, unless being off by 1 in your quotient is acceptable.

The exercise then becomes creating a lookup table with the right multipliers for each of the possible denominators.

EDIT: as pointed out in a comment below, choosing `k = (2^30 + y - 1) / y`

should give better and more consistent results than simply `k = round(2^30 / y)`

.

`10 * Denominator`

, if that's too small try`100 * Denominator`

, if that's too big, try`55 * Denominator`

, etc... It will take O(log2(Quotient)) steps... – twalberg Jun 12 '13 at 14:40