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I am looking for a library of C mathematical functions (trigonometric functions, exponential, logarithm, ...) that would take and return single-precision floats. The library would have to be available in source form, and it would be a plus if it was already known/believed optimal considering the IEEE 754 single-precision constraint.

Something like fdlibm, but less precise/expensive, would be perfect. There are other implementations all over the place, but most of them are double-precision, since that is what is standardized. While searching, I also found these integer trigonometric functions, that do not quite fit my purpose either.


I tinker with a static analyzer for C that I recently started applying to numerical functions (low-precision polynomial or interpolation implementations). One thing that I am interested in is taking into account the floating-point aspects of the computations (and the errors these can introduce), which are usually left out of the analyses of these implementations.

I know little about this kind of program. The two naive examples I linked use double in order to be compatible with older versions of the analyzer, and in retrospect, the Taylor development should probably be a Remez approximation instead. It would all look more serious (and useful) if I verified available, established implementations; and I would have more interesting things to say if these implementations were single-precision, considering the brute-force approach that I want to try. On the other hand of the complexity spectrum, the 16-bit integer library has so few possible inputs that it does not need static analysis at all: it can be exhaustively tested. Something in the middle would be ideal.

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Couldn't you just start with fdlibm and chop off the last couple terms of the approximation? :-) –  R.. Feb 24 '11 at 23:46
@R.. Good one. You are exactly the kind of person I expected would have something constructive to say, so I hope you will not limit yourself to sophisticated numerical humor :) –  Pascal Cuoq Feb 24 '11 at 23:59
Well I'm not quite sure what you wanted, but that's the general approach I would use for implementing lower-precision versions of the standard library functions. Of course I'd also throw in some rigorous numerical analysis to make sure the number of terms kept is right. –  R.. Feb 25 '11 at 1:02
@R.. Oh, I see. I thought you were making a joke because chopping off terms doesn't work for Remez polynomials, which are the popular way to implement uniform precision over an input range. Take openbsd.org/cgi-bin/cvsweb/src/lib/libm/src/… for instance: if the Taylor development was used, the hexadecimal representation for S1 would be ..55..56. This slight difference has to be recomputed if you change the degree of the approximation. Compare with openbsd.org/cgi-bin/cvsweb/src/lib/libm/src/… –  Pascal Cuoq Feb 25 '11 at 3:01

3 Answers 3

up vote 2 down vote accepted

Aren't these already part of the math standard library? e.g. logf(), expf(), sinf() and so forth? (These are guaranteed by both C99, and POSIX.1-2001).

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Right you are. With the right keywords, Google dug up koders.com/c/… . And now I know I will always have glibc to fall back on if I can't find anything lighter on the #defines. –  Pascal Cuoq Feb 25 '11 at 0:31
The various BSDs' libm implementations might also prove fruitful. –  wnoise Feb 25 '11 at 0:34
Yes, openbsd.org/cgi-bin/cvsweb/src/lib/libm/src/… is exactly what I was looking for. –  Pascal Cuoq Feb 25 '11 at 0:49

The book "The standard C library" by Plauger isbn 0131315099 contains well worked-out and commented floating point C library source.

You could try to convert that to single precision.

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The comments are only part of the problem (actually, squinting at fdlibm long enough I manage to make sense of it a bit). The problem is that when you compute single-precision results, you do not use the same operations—you plan to do less of them, for starters. And if the implementation is based on Remez's algorithm, you cannot just remove some coefficients from the polynomial either. You have to recompute them all. I will look for this book, but I'm afraid I will look amateurish even with its help if I attempt to write the functions myself. –  Pascal Cuoq Feb 24 '11 at 23:57

See the Cephes Mathematical Library.

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