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I am trying to write a C function that performs the following calculation at runtime:

Numerator/Denominator

where:

Numerator is a prior calculation result, is always positive, and is greater than the Denominator

and,

Denominator is such that (1 <= Denominator <= 64).

The runtime calculation must be fast, i.e. fewest cycles, so the division operator is out of the question. I have looked at recursive subtraction and bitwise long division, but I am trying to find another solution.

Any Help?

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Where is the code you hahve trid? –  ErrorNotFoundException Jun 12 '13 at 14:06
    
How much greater is Numerator - i.e. is the expected quotient capped at some value? Perhaps a binary search using multiplication (which still isn't extremely fast, but is faster than division) - try 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
    
The numerator is 48,000,000 to 768,000,000 –  user2478619 Jun 12 '13 at 15:00
    
What kind of CPU are we talking about here? If it has a clz instruction, things can get faster. –  Michael Dorgan Jun 12 '13 at 16:01

2 Answers 2

up vote 1 down vote accepted

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).

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Since shifting always truncates the result and truncating always generates a negative error, you should always round the multiplier up so the errors cancel. I.e. k = (2^30 + y-1) / y. –  Mark Ransom Jun 12 '13 at 16:20
    
@MarkRansom Hmm.... good point. And probably a better way to improve accuracy than just adding another bit or two. –  twalberg Jun 12 '13 at 16:24
    
Awesome. My problem has been solved. The Table lookup for k values did it nicely. Thanks! –  user2478619 Jun 12 '13 at 17:21

Big @ss table would work for small numbers:

unsigned int divTable[kMaxNumerator][64] = {...}

Where you put the values of each possible divide in there. Not very practical above a certain sizes, but it does work for contained cases and was a common solution for texture mapping way back in the day :) Then I read your comments and see that you are in the 768,000,000 range and this because completely impractical unless you can handle quite a bit of precision loss.

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