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142 lines
4.7 KiB
Plaintext
142 lines
4.7 KiB
Plaintext
[section:tgamma Gamma]
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[h4 Synopsis]
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``
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#include <boost/math/special_functions/gamma.hpp>
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``
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namespace boost{ namespace math{
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template <class T>
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``__sf_result`` tgamma(T z);
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template <class T, class ``__Policy``>
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``__sf_result`` tgamma(T z, const ``__Policy``&);
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template <class T>
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``__sf_result`` tgamma1pm1(T dz);
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template <class T, class ``__Policy``>
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``__sf_result`` tgamma1pm1(T dz, const ``__Policy``&);
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}} // namespaces
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[h4 Description]
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template <class T>
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``__sf_result`` tgamma(T z);
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template <class T, class ``__Policy``>
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``__sf_result`` tgamma(T z, const ``__Policy``&);
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Returns the "true gamma" (hence name tgamma) of value z:
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[equation gamm1]
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[graph tgamma]
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[optional_policy]
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There are effectively two versions of the [@http://en.wikipedia.org/wiki/Gamma_function tgamma]
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function internally: a fully
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generic version that is slow, but reasonably accurate, and a much more
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efficient approximation that is used where the number of digits in the significand
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of T correspond to a certain __lanczos. In practice any built in
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floating point type you will encounter has an appropriate __lanczos
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defined for it. It is also possible, given enough machine time, to generate
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further __lanczos's using the program libs/math/tools/lanczos_generator.cpp.
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The return type of this function is computed using the __arg_promotion_rules:
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the result is `double` when T is an integer type, and T otherwise.
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template <class T>
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``__sf_result`` tgamma1pm1(T dz);
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template <class T, class ``__Policy``>
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``__sf_result`` tgamma1pm1(T dz, const ``__Policy``&);
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Returns `tgamma(dz + 1) - 1`. Internally the implementation does not make
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use of the addition and subtraction implied by the definition, leading to
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accurate results even for very small `dz`. However, the implementation is
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capped to either 35 digit accuracy, or to the precision of the __lanczos
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associated with type T, whichever is more accurate.
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The return type of this function is computed using the __arg_promotion_rules:
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the result is `double` when T is an integer type, and T otherwise.
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[optional_policy]
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[h4 Accuracy]
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The following table shows the peak errors (in units of epsilon)
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found on various platforms with various floating point types,
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along with comparisons to other common libraries.
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Unless otherwise specified any floating point type that is narrower
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than the one shown will have __zero_error.
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[table_tgamma]
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[table_tgamma1pm1]
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[h4 Testing]
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The gamma is relatively easy to test: factorials and half-integer factorials
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can be calculated exactly by other means and compared with the gamma function.
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In addition, some accuracy tests in known tricky areas were computed at high precision
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using the generic version of this function.
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The function `tgamma1pm1` is tested against values calculated very naively
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using the formula `tgamma(1+dz)-1` with a lanczos approximation accurate
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to around 100 decimal digits.
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[h4 Implementation]
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The generic version of the `tgamma` function is implemented Sterling's approximation
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for lgamma for large z:
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[equation gamma6]
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Following exponentiation, downward recursion is then used for small values of z.
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For types of known precision the __lanczos is used, a traits class
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`boost::math::lanczos::lanczos_traits` maps type T to an appropriate
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approximation.
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For z in the range -20 < z < 1 then recursion is used to shift to z > 1 via:
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[equation gamm3]
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For very small z, this helps to preserve the identity:
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[equation gamm4]
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For z < -20 the reflection formula:
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[equation gamm5]
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is used. Particular care has to be taken to evaluate the [^ z * sin([pi][space] * z)] part:
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a special routine is used to reduce z prior to multiplying by [pi][space] to ensure that the
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result in is the range [0, [pi]/2]. Without this an excessive amount of error occurs
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in this region (which is hard enough already, as the rate of change near a negative pole
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is /exceptionally/ high).
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Finally if the argument is a small integer then table lookup of the factorial
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is used.
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The function `tgamma1pm1` is implemented using rational approximations [jm_rationals] in the
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region `-0.5 < dz < 2`. These are the same approximations (and internal routines)
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that are used for __lgamma, and so aren't detailed further here. The result of
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the approximation is `log(tgamma(dz+1))` which can fed into __expm1 to give
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the desired result. Outside the range `-0.5 < dz < 2` then the naive formula
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`tgamma1pm1(dz) = tgamma(dz+1)-1` can be used directly.
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[endsect][/section:tgamma The Gamma Function]
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[/
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Copyright 2006 John Maddock and Paul A. Bristow.
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Distributed under the Boost Software License, Version 1.0.
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(See accompanying file LICENSE_1_0.txt or copy at
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http://www.boost.org/LICENSE_1_0.txt).
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]
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