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I just recently came across the Kahan (or compensated) summation algorithm for minimizing roundoff, and I'd like to know if there are equivalent algorithms for division and/or multiplication, as well as subtraction (if there happens to be one, I know about associativity). Implementation examples in any language, pseudo-code or links would be great!

Thanks

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3 Answers

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Subtraction is usually handled via the Kahan method.

For multiplication, there are algorithms to convert a product of two floating-point numbers into a sum of two floating-point numbers without rounding, at which point you can use Kahan summation or some other method, depending on what you need to do next with the product.

If you have FMA (fused multiply-add) available, this can easily be accomplished as follows:

p = a*b;
r = fma(a,b,-p);

After these two operations, if no overflow or underflow occurs, p + r is exactly equal to a * b without rounding. This can also be accomplished without FMA, but it is rather more difficult. If you're interested in these algorithms, you might start by downloading the crlibm documentation, which details several of them.

Division... well, division is best avoided. Division is slow, and compensated division is even slower. You can do it, but it's brutally hard without FMA, and non-trivial with it. Better to design your algorithms to avoid it as much as possible.

Note that all of this becomes a losing battle pretty quickly. There's a very narrow band of situations where these tricks are beneficial--for anything more complicated, it's much better to just use a wider-precision floating point library like mpfr. Unless you're an expert in the field (or want to become one), it's usually best to just learn to use such a library.

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AFAIK, using wider types is just a bad-aid and will help very little if your problem is ill-conditioned or your algorithm not stable. –  Michael Borgwardt Sep 14 '10 at 15:11
    
@Michael Borgwardt: that depends on the problem. If your problem is ill-conditioned, then either your input data is exact (in which case increasing precision will actually help once you cross some threshold), or the answer is meaningless anyway (in which case it doesn't matter). If your algorithm is unstable, it depends on the exact nature of the instability. More generally, however, any issue that can be fixed by using compensated arithmetic can also be resolved by using wider types. –  Stephen Canon Sep 14 '10 at 15:19
    
As curious as I am, as much as I'd love to know everything about everything, I know I'll have to settle on using libraries and the like for now, thanks very much for your answer, I'll take a look at it asap. :) –  Geoff Sep 14 '10 at 15:40
    
Hmm.. The fact that I don't yet know how to program in assembly (it's on my list of things to learn) rather doesn't help if I want to use FMA (I looked it up), is there an implementation somewhere that I can usee for it? (or a code snippet using the FMA instruction with explanations?) –  Geoff Sep 14 '10 at 16:11
    
@Geoff: If you're using most commodity hardware (x86, ARM), you don't have an fma instruction available anyway, so there's not too much point. If you're using PPC or Itanium or one of the other more exotic architectures that have fma, you can generally get at it directly with a compiler builtin in C, or the fma( ) function defined in <math.h>. –  Stephen Canon Sep 14 '10 at 16:36
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Designing algorithms to be numerically stable is an academic discipline and field of research in its own right. It's not something you can do (or learn) meaningfully via "cheat sheets" - it requires specific mathematical knowledge and needs to be done for each specific algorithm. If you want to learn how to do this, the reference in the Wikipedia article sounds pretty good: Nicholas J. Higham, Accuracy and Stability of Numerical Algorithms, Society of Industrial and Applied Mathematics, Philadelphia, 1996. ISBN 0-89871-355-2.

A relatively simple way to diagnose the stability of an algorithm is to use interval arithmetic.

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The goal of compensated arithmetic is not typically improving stability. More often it is to satisfy a hard accuracy bound for a stable algorithm. –  Stephen Canon Sep 14 '10 at 15:20
    
Interesting, thanks for the links I'll take a look at them when I get a chance! –  Geoff Sep 14 '10 at 15:30
    
@Stephen, Ah. I didn't know there was a difference. :S Still interesting though. :) –  Geoff Sep 14 '10 at 15:42
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You could use bignums and rational fractions rather than floating point numbers in which case you are limited only by the finite availability of memory to hold the require precision.

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performance may be an issue though –  jk. Sep 14 '10 at 15:28
    
Not an option, the solver is already memory-bound. Thanks though. –  Geoff Sep 14 '10 at 15:40
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