# Arbitrary precision gamma function

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
• @GeorgeSovetov: I think it's reasonably on-topic, given the practical constraints of an efficient implementation. – Mark Dickinson Nov 15 '16 at 17:35
• 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

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.