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I'm implementing an arbitrary precision arithmetic library in C++ and I'm pretty much stuck when implementing the gamma function.

By using the equivalences gamma(n) = gamma(n - 1) * n and gamma(n) = gamma(n + 1) / n, respectively, I can obtain a rational number r in the range (1; 2] for all real values x.

However, I don't know how to evaluate gamma(r). For the Lanczos approximation (https://en.wikipedia.org/wiki/Lanczos_approximation), I need precomputed values p which happen to calculate a factorial of a non-integer value (?!) and can't be calculated dynamically with my current knowledge... Precomputing values for p wouldn't make much sense when implementing an arbitrary precision library.

Are there any algorithms that compute gamma(r) in a reasonable amount of time with arbitrary precision? Thanks for your help.

  • I presume you have studied functions.wolfram.com/GammaBetaErf/Gamma/introductions/Gamma/05 and failed to find what you need. – High Performance Mark Nov 15 '16 at 17:27
  • Looks like it's more related to math than to programming... Maybe, it's better to post question there. – George Sovetov Nov 15 '16 at 17:33
  • I'd also look into MPFR's source to see what they use. – Mark Dickinson Nov 15 '16 at 17:34
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    @GeorgeSovetov: I think it's reasonably on-topic, given the practical constraints of an efficient implementation. – Mark Dickinson Nov 15 '16 at 17:35
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    Second 4.5 of Modern Computer Arithmetic (official PDF here) gives one approach, which is to use Stirling's asymptotic expansion for large x, and the functional equation to transfer this to smaller x. (The reflection formula lets you extend this to negative x efficiently.) – Mark Dickinson Nov 15 '16 at 17:39
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Spouge's approximation is similar to Lanczos's approximation, but probably easier to use for arbitrary precision, as you can set the desired error.

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Lanczos approximation doesn't seem too bad. What exactly do you suspect?

Parts of code which calculate p, C (Chebyshev polynomials) and (a + 1/2)! can be implemented as stateful objects so that, for example, you can calculate p(i) from p(i-1) and Chebyshev coefficients and be computed once, maintaining their matrix.

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