I am working on GPU device which has very high division integer latency, several hundred cycles. I am looking to optimize divisions.

All divisions by denominator which is in a set { 1,3,6,10 }, however numerator is a runtime positive value, roughly 32000 or less. due to memory constraints, lookup table may not be a good option.

Can you think of alternatives? I have thought of computing float point inverses, and using those to multiply numerator.


PS. thank you people. bit shift hack is a really cool. to recover from roundoff, I use following C segment:

// q = m/n
q += (n*(j +1)-1) < m;

can you build a lookup table for the denominators? since you said 15 bit numerators, you could use 17 for the shifts if everything is unsigned 32 bit:


The larger the shift the less the rounding error. You can do a brute force check to see how many times, if any, this is actually wrong.

  • i do get roundoff error, but I have a way to recover correct result. Thank you – Anycorn Apr 11 '10 at 5:07
  • For roundoff error, you could try the classic add half before divide, which in this case would be a/b=(a*((1<<16)/b)+(1<<15))>>16 – drawnonward Apr 11 '10 at 6:41
  • If roundoff is a concern then you should also "add half before divide" in your constant division, i.e. ((1<<16) + (b >> 1))/b. (For my purposes this alone was sufficient, I didn't need the + (1<<15). YMMV) – yoyo Jul 10 '14 at 18:55

The standard embedded systems hack for this is to convert an integer division by N into a fixed-point multiplication by 1/N.

Assuming 16 bits, 0.33333 can be represented as 21845 (decimal). Multiply, giving a 32-bit integer product, and shift down 16 bits.

You will almost certainly encounter some roundoff (truncation) error. This may or may not be something you can live with.

It MIGHT be worthwhile to look hard at your GPU and see if you can hand-code a faster integer division routine, taking advantage of your knowledge of the restricted range of the numerator.

  • truncation would be a problem, I need actual values. However I think I can cope with it by checking for roundoff and incrementing result if found – Anycorn Apr 11 '10 at 4:56
  • One may in most cases avoid round-off error by multiplying by a value which is one larger than the rounded-down reciprocal (21846 in the case of 1/3 using 16 bits). – supercat Apr 26 '16 at 18:45
  • @supercat I'd be nervous about that approach introducing more error than it removes. Usually, I will scale the "numerator" up some number of bits, to give myself maximum precision in my "quotient", multiply by the closest value, add a rounding bit (the scaled equivalent of 0.5), and then scale the final result down. Yes, this is a headache, and it is this kind of headache that led to the invention of floating-point. – John R. Strohm Apr 26 '16 at 21:24
  • @JohnR.Strohm: Since ((uint64)0xFFFFFFFF*n)>>32 will be less than n, the approach can't introduce more effor than it removes if n isn't greater than 0xFFFFFFFF. – supercat Apr 27 '16 at 3:39

The book, "Hacker's Delight" by Henry Warren, has a whole chapter devoted to integer division by constants, including techniques that transform an integer division to a multiply/shift/add series of operations.

This page calculates the magic numbers for the multiply/shift/add operations:

  • 1
    As of 11/4/2019, this URL (hackersdelight.org/magic.htm) is 404. The domain appears to be an entirely different site that may be trying to install malware... Beware! See en.wikipedia.org/wiki/Hacker%27s_Delight for a reference to the actual author and the book. – Mac Nov 4 '19 at 20:54

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