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// This file is part of Eigen, a lightweight C++ template library
// for linear algebra.
//
// Copyright (C) 2015 Eugene Brevdo <ebrevdo@gmail.com>
//
// This Source Code Form is subject to the terms of the Mozilla
// Public License v. 2.0. If a copy of the MPL was not distributed
// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
#ifndef EIGEN_BESSEL_FUNCTIONS_H
#define EIGEN_BESSEL_FUNCTIONS_H
#include "./InternalHeaderCheck.h"
namespace Eigen {
namespace internal {
// Parts of this code are based on the Cephes Math Library.
//
// Cephes Math Library Release 2.8: June, 2000
// Copyright 1984, 1987, 1992, 2000 by Stephen L. Moshier
//
// Permission has been kindly provided by the original author
// to incorporate the Cephes software into the Eigen codebase:
//
// From: Stephen Moshier
// To: Eugene Brevdo
// Subject: Re: Permission to wrap several cephes functions in Eigen
//
// Hello Eugene,
//
// Thank you for writing.
//
// If your licensing is similar to BSD, the formal way that has been
// handled is simply to add a statement to the effect that you are incorporating
// the Cephes software by permission of the author.
//
// Good luck with your project,
// Steve
/****************************************************************************
* Implementation of Bessel function, based on Cephes *
****************************************************************************/
template <typename Scalar>
struct bessel_i0e_retval {
typedef Scalar type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_i0e {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_i0e<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* i0ef.c
*
* Modified Bessel function of order zero,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* float x, y, i0ef();
*
* y = i0ef( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of order zero of the argument.
*
* The function is defined as i0e(x) = exp(-|x|) j0( ix ).
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0,30 100000 3.7e-7 7.0e-8
* See i0f().
*
*/
const float A[] = {-1.30002500998624804212E-8f, 6.04699502254191894932E-8f,
-2.67079385394061173391E-7f, 1.11738753912010371815E-6f,
-4.41673835845875056359E-6f, 1.64484480707288970893E-5f,
-5.75419501008210370398E-5f, 1.88502885095841655729E-4f,
-5.76375574538582365885E-4f, 1.63947561694133579842E-3f,
-4.32430999505057594430E-3f, 1.05464603945949983183E-2f,
-2.37374148058994688156E-2f, 4.93052842396707084878E-2f,
-9.49010970480476444210E-2f, 1.71620901522208775349E-1f,
-3.04682672343198398683E-1f, 6.76795274409476084995E-1f};
const float B[] = {3.39623202570838634515E-9f, 2.26666899049817806459E-8f,
2.04891858946906374183E-7f, 2.89137052083475648297E-6f,
6.88975834691682398426E-5f, 3.36911647825569408990E-3f,
8.04490411014108831608E-1f};
T y = pabs(x);
T y_le_eight = internal::pchebevl<T, 18>::run(
pmadd(pset1<T>(0.5f), y, pset1<T>(-2.0f)), A);
T y_gt_eight = pmul(
internal::pchebevl<T, 7>::run(
psub(pdiv(pset1<T>(32.0f), y), pset1<T>(2.0f)), B),
prsqrt(y));
// TODO: Perhaps instead check whether all packet elements are in
// [-8, 8] and evaluate a branch based off of that. It's possible
// in practice most elements are in this region.
return pselect(pcmp_le(y, pset1<T>(8.0f)), y_le_eight, y_gt_eight);
}
};
template <typename T>
struct generic_i0e<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* i0e.c
*
* Modified Bessel function of order zero,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* double x, y, i0e();
*
* y = i0e( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of order zero of the argument.
*
* The function is defined as i0e(x) = exp(-|x|) j0( ix ).
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0,30 30000 5.4e-16 1.2e-16
* See i0().
*
*/
const double A[] = {-4.41534164647933937950E-18, 3.33079451882223809783E-17,
-2.43127984654795469359E-16, 1.71539128555513303061E-15,
-1.16853328779934516808E-14, 7.67618549860493561688E-14,
-4.85644678311192946090E-13, 2.95505266312963983461E-12,
-1.72682629144155570723E-11, 9.67580903537323691224E-11,
-5.18979560163526290666E-10, 2.65982372468238665035E-9,
-1.30002500998624804212E-8, 6.04699502254191894932E-8,
-2.67079385394061173391E-7, 1.11738753912010371815E-6,
-4.41673835845875056359E-6, 1.64484480707288970893E-5,
-5.75419501008210370398E-5, 1.88502885095841655729E-4,
-5.76375574538582365885E-4, 1.63947561694133579842E-3,
-4.32430999505057594430E-3, 1.05464603945949983183E-2,
-2.37374148058994688156E-2, 4.93052842396707084878E-2,
-9.49010970480476444210E-2, 1.71620901522208775349E-1,
-3.04682672343198398683E-1, 6.76795274409476084995E-1};
const double B[] = {
-7.23318048787475395456E-18, -4.83050448594418207126E-18,
4.46562142029675999901E-17, 3.46122286769746109310E-17,
-2.82762398051658348494E-16, -3.42548561967721913462E-16,
1.77256013305652638360E-15, 3.81168066935262242075E-15,
-9.55484669882830764870E-15, -4.15056934728722208663E-14,
1.54008621752140982691E-14, 3.85277838274214270114E-13,
7.18012445138366623367E-13, -1.79417853150680611778E-12,
-1.32158118404477131188E-11, -3.14991652796324136454E-11,
1.18891471078464383424E-11, 4.94060238822496958910E-10,
3.39623202570838634515E-9, 2.26666899049817806459E-8,
2.04891858946906374183E-7, 2.89137052083475648297E-6,
6.88975834691682398426E-5, 3.36911647825569408990E-3,
8.04490411014108831608E-1};
T y = pabs(x);
T y_le_eight = internal::pchebevl<T, 30>::run(
pmadd(pset1<T>(0.5), y, pset1<T>(-2.0)), A);
T y_gt_eight = pmul(
internal::pchebevl<T, 25>::run(
psub(pdiv(pset1<T>(32.0), y), pset1<T>(2.0)), B),
prsqrt(y));
// TODO: Perhaps instead check whether all packet elements are in
// [-8, 8] and evaluate a branch based off of that. It's possible
// in practice most elements are in this region.
return pselect(pcmp_le(y, pset1<T>(8.0)), y_le_eight, y_gt_eight);
}
};
template <typename T>
struct bessel_i0e_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_i0e<T>::run(x);
}
};
template <typename Scalar>
struct bessel_i0_retval {
typedef Scalar type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_i0 {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
return pmul(
pexp(pabs(x)),
generic_i0e<T, ScalarType>::run(x));
}
};
template <typename T>
struct bessel_i0_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_i0<T>::run(x);
}
};
template <typename Scalar>
struct bessel_i1e_retval {
typedef Scalar type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type >
struct generic_i1e {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_i1e<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* i1ef.c
*
* Modified Bessel function of order one,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* float x, y, i1ef();
*
* y = i1ef( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of order one of the argument.
*
* The function is defined as i1(x) = -i exp(-|x|) j1( ix ).
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 1.5e-6 1.5e-7
* See i1().
*
*/
const float A[] = {9.38153738649577178388E-9f, -4.44505912879632808065E-8f,
2.00329475355213526229E-7f, -8.56872026469545474066E-7f,
3.47025130813767847674E-6f, -1.32731636560394358279E-5f,
4.78156510755005422638E-5f, -1.61760815825896745588E-4f,
5.12285956168575772895E-4f, -1.51357245063125314899E-3f,
4.15642294431288815669E-3f, -1.05640848946261981558E-2f,
2.47264490306265168283E-2f, -5.29459812080949914269E-2f,
1.02643658689847095384E-1f, -1.76416518357834055153E-1f,
2.52587186443633654823E-1f};
const float B[] = {-3.83538038596423702205E-9f, -2.63146884688951950684E-8f,
-2.51223623787020892529E-7f, -3.88256480887769039346E-6f,
-1.10588938762623716291E-4f, -9.76109749136146840777E-3f,
7.78576235018280120474E-1f};
T y = pabs(x);
T y_le_eight = pmul(y, internal::pchebevl<T, 17>::run(
pmadd(pset1<T>(0.5f), y, pset1<T>(-2.0f)), A));
T y_gt_eight = pmul(
internal::pchebevl<T, 7>::run(
psub(pdiv(pset1<T>(32.0f), y),
pset1<T>(2.0f)), B),
prsqrt(y));
// TODO: Perhaps instead check whether all packet elements are in
// [-8, 8] and evaluate a branch based off of that. It's possible
// in practice most elements are in this region.
y = pselect(pcmp_le(y, pset1<T>(8.0f)), y_le_eight, y_gt_eight);
return pselect(pcmp_lt(x, pset1<T>(0.0f)), pnegate(y), y);
}
};
template <typename T>
struct generic_i1e<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* i1e.c
*
* Modified Bessel function of order one,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* double x, y, i1e();
*
* y = i1e( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of order one of the argument.
*
* The function is defined as i1(x) = -i exp(-|x|) j1( ix ).
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 2.0e-15 2.0e-16
* See i1().
*
*/
const double A[] = {2.77791411276104639959E-18, -2.11142121435816608115E-17,
1.55363195773620046921E-16, -1.10559694773538630805E-15,
7.60068429473540693410E-15, -5.04218550472791168711E-14,
3.22379336594557470981E-13, -1.98397439776494371520E-12,
1.17361862988909016308E-11, -6.66348972350202774223E-11,
3.62559028155211703701E-10, -1.88724975172282928790E-9,
9.38153738649577178388E-9, -4.44505912879632808065E-8,
2.00329475355213526229E-7, -8.56872026469545474066E-7,
3.47025130813767847674E-6, -1.32731636560394358279E-5,
4.78156510755005422638E-5, -1.61760815825896745588E-4,
5.12285956168575772895E-4, -1.51357245063125314899E-3,
4.15642294431288815669E-3, -1.05640848946261981558E-2,
2.47264490306265168283E-2, -5.29459812080949914269E-2,
1.02643658689847095384E-1, -1.76416518357834055153E-1,
2.52587186443633654823E-1};
const double B[] = {
7.51729631084210481353E-18, 4.41434832307170791151E-18,
-4.65030536848935832153E-17, -3.20952592199342395980E-17,
2.96262899764595013876E-16, 3.30820231092092828324E-16,
-1.88035477551078244854E-15, -3.81440307243700780478E-15,
1.04202769841288027642E-14, 4.27244001671195135429E-14,
-2.10154184277266431302E-14, -4.08355111109219731823E-13,
-7.19855177624590851209E-13, 2.03562854414708950722E-12,
1.41258074366137813316E-11, 3.25260358301548823856E-11,
-1.89749581235054123450E-11, -5.58974346219658380687E-10,
-3.83538038596423702205E-9, -2.63146884688951950684E-8,
-2.51223623787020892529E-7, -3.88256480887769039346E-6,
-1.10588938762623716291E-4, -9.76109749136146840777E-3,
7.78576235018280120474E-1};
T y = pabs(x);
T y_le_eight = pmul(y, internal::pchebevl<T, 29>::run(
pmadd(pset1<T>(0.5), y, pset1<T>(-2.0)), A));
T y_gt_eight = pmul(
internal::pchebevl<T, 25>::run(
psub(pdiv(pset1<T>(32.0), y),
pset1<T>(2.0)), B),
prsqrt(y));
// TODO: Perhaps instead check whether all packet elements are in
// [-8, 8] and evaluate a branch based off of that. It's possible
// in practice most elements are in this region.
y = pselect(pcmp_le(y, pset1<T>(8.0)), y_le_eight, y_gt_eight);
return pselect(pcmp_lt(x, pset1<T>(0.0)), pnegate(y), y);
}
};
template <typename T>
struct bessel_i1e_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_i1e<T>::run(x);
}
};
template <typename T>
struct bessel_i1_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_i1 {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
return pmul(
pexp(pabs(x)),
generic_i1e<T, ScalarType>::run(x));
}
};
template <typename T>
struct bessel_i1_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_i1<T>::run(x);
}
};
template <typename T>
struct bessel_k0e_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_k0e {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_k0e<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* k0ef.c
* Modified Bessel function, third kind, order zero,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* float x, y, k0ef();
*
* y = k0ef( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of the third kind of order zero of the argument.
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 8.1e-7 7.8e-8
* See k0().
*
*/
const float A[] = {1.90451637722020886025E-9f, 2.53479107902614945675E-7f,
2.28621210311945178607E-5f, 1.26461541144692592338E-3f,
3.59799365153615016266E-2f, 3.44289899924628486886E-1f,
-5.35327393233902768720E-1f};
const float B[] = {-1.69753450938905987466E-9f, 8.57403401741422608519E-9f,
-4.66048989768794782956E-8f, 2.76681363944501510342E-7f,
-1.83175552271911948767E-6f, 1.39498137188764993662E-5f,
-1.28495495816278026384E-4f, 1.56988388573005337491E-3f,
-3.14481013119645005427E-2f, 2.44030308206595545468E0f};
const T MAXNUM = pset1<T>(NumTraits<float>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = internal::pchebevl<T, 7>::run(
pmadd(x, x, pset1<T>(-2.0)), A);
x_le_two = pmadd(
generic_i0<T, float>::run(x), pnegate(
plog(pmul(pset1<T>(0.5), x))), x_le_two);
x_le_two = pmul(pexp(x), x_le_two);
T x_gt_two = pmul(
internal::pchebevl<T, 10>::run(
psub(pdiv(pset1<T>(8.0), x), two), B),
prsqrt(x));
return pselect(
pcmp_le(x, pset1<T>(0.0)),
MAXNUM,
pselect(pcmp_le(x, two), x_le_two, x_gt_two));
}
};
template <typename T>
struct generic_k0e<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* k0e.c
* Modified Bessel function, third kind, order zero,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* double x, y, k0e();
*
* y = k0e( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of the third kind of order zero of the argument.
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 1.4e-15 1.4e-16
* See k0().
*
*/
const double A[] = {
1.37446543561352307156E-16,
4.25981614279661018399E-14,
1.03496952576338420167E-11,
1.90451637722020886025E-9,
2.53479107902614945675E-7,
2.28621210311945178607E-5,
1.26461541144692592338E-3,
3.59799365153615016266E-2,
3.44289899924628486886E-1,
-5.35327393233902768720E-1};
const double B[] = {
5.30043377268626276149E-18, -1.64758043015242134646E-17,
5.21039150503902756861E-17, -1.67823109680541210385E-16,
5.51205597852431940784E-16, -1.84859337734377901440E-15,
6.34007647740507060557E-15, -2.22751332699166985548E-14,
8.03289077536357521100E-14, -2.98009692317273043925E-13,
1.14034058820847496303E-12, -4.51459788337394416547E-12,
1.85594911495471785253E-11, -7.95748924447710747776E-11,
3.57739728140030116597E-10, -1.69753450938905987466E-9,
8.57403401741422608519E-9, -4.66048989768794782956E-8,
2.76681363944501510342E-7, -1.83175552271911948767E-6,
1.39498137188764993662E-5, -1.28495495816278026384E-4,
1.56988388573005337491E-3, -3.14481013119645005427E-2,
2.44030308206595545468E0
};
const T MAXNUM = pset1<T>(NumTraits<double>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = internal::pchebevl<T, 10>::run(
pmadd(x, x, pset1<T>(-2.0)), A);
x_le_two = pmadd(
generic_i0<T, double>::run(x), pmul(
pset1<T>(-1.0), plog(pmul(pset1<T>(0.5), x))), x_le_two);
x_le_two = pmul(pexp(x), x_le_two);
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), MAXNUM, x_le_two);
T x_gt_two = pmul(
internal::pchebevl<T, 25>::run(
psub(pdiv(pset1<T>(8.0), x), two), B),
prsqrt(x));
return pselect(pcmp_le(x, two), x_le_two, x_gt_two);
}
};
template <typename T>
struct bessel_k0e_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_k0e<T>::run(x);
}
};
template <typename T>
struct bessel_k0_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_k0 {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_k0<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* k0f.c
* Modified Bessel function, third kind, order zero
*
*
*
* SYNOPSIS:
*
* float x, y, k0f();
*
* y = k0f( x );
*
*
*
* DESCRIPTION:
*
* Returns modified Bessel function of the third kind
* of order zero of the argument.
*
* The range is partitioned into the two intervals [0,8] and
* (8, infinity). Chebyshev polynomial expansions are employed
* in each interval.
*
*
*
* ACCURACY:
*
* Tested at 2000 random points between 0 and 8. Peak absolute
* error (relative when K0 > 1) was 1.46e-14; rms, 4.26e-15.
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 7.8e-7 8.5e-8
*
* ERROR MESSAGES:
*
* message condition value returned
* K0 domain x <= 0 MAXNUM
*
*/
const float A[] = {1.90451637722020886025E-9f, 2.53479107902614945675E-7f,
2.28621210311945178607E-5f, 1.26461541144692592338E-3f,
3.59799365153615016266E-2f, 3.44289899924628486886E-1f,
-5.35327393233902768720E-1f};
const float B[] = {-1.69753450938905987466E-9f, 8.57403401741422608519E-9f,
-4.66048989768794782956E-8f, 2.76681363944501510342E-7f,
-1.83175552271911948767E-6f, 1.39498137188764993662E-5f,
-1.28495495816278026384E-4f, 1.56988388573005337491E-3f,
-3.14481013119645005427E-2f, 2.44030308206595545468E0f};
const T MAXNUM = pset1<T>(NumTraits<float>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = internal::pchebevl<T, 7>::run(
pmadd(x, x, pset1<T>(-2.0)), A);
x_le_two = pmadd(
generic_i0<T, float>::run(x), pnegate(
plog(pmul(pset1<T>(0.5), x))), x_le_two);
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), MAXNUM, x_le_two);
T x_gt_two = pmul(
pmul(
pexp(pnegate(x)),
internal::pchebevl<T, 10>::run(
psub(pdiv(pset1<T>(8.0), x), two), B)),
prsqrt(x));
return pselect(pcmp_le(x, two), x_le_two, x_gt_two);
}
};
template <typename T>
struct generic_k0<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/*
*
* Modified Bessel function, third kind, order zero,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* double x, y, k0();
*
* y = k0( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of the third kind of order zero of the argument.
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 1.4e-15 1.4e-16
* See k0().
*
*/
const double A[] = {
1.37446543561352307156E-16,
4.25981614279661018399E-14,
1.03496952576338420167E-11,
1.90451637722020886025E-9,
2.53479107902614945675E-7,
2.28621210311945178607E-5,
1.26461541144692592338E-3,
3.59799365153615016266E-2,
3.44289899924628486886E-1,
-5.35327393233902768720E-1};
const double B[] = {
5.30043377268626276149E-18, -1.64758043015242134646E-17,
5.21039150503902756861E-17, -1.67823109680541210385E-16,
5.51205597852431940784E-16, -1.84859337734377901440E-15,
6.34007647740507060557E-15, -2.22751332699166985548E-14,
8.03289077536357521100E-14, -2.98009692317273043925E-13,
1.14034058820847496303E-12, -4.51459788337394416547E-12,
1.85594911495471785253E-11, -7.95748924447710747776E-11,
3.57739728140030116597E-10, -1.69753450938905987466E-9,
8.57403401741422608519E-9, -4.66048989768794782956E-8,
2.76681363944501510342E-7, -1.83175552271911948767E-6,
1.39498137188764993662E-5, -1.28495495816278026384E-4,
1.56988388573005337491E-3, -3.14481013119645005427E-2,
2.44030308206595545468E0
};
const T MAXNUM = pset1<T>(NumTraits<double>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = internal::pchebevl<T, 10>::run(
pmadd(x, x, pset1<T>(-2.0)), A);
x_le_two = pmadd(
generic_i0<T, double>::run(x), pnegate(
plog(pmul(pset1<T>(0.5), x))), x_le_two);
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), MAXNUM, x_le_two);
T x_gt_two = pmul(
pmul(
pexp(-x),
internal::pchebevl<T, 25>::run(
psub(pdiv(pset1<T>(8.0), x), two), B)),
prsqrt(x));
return pselect(pcmp_le(x, two), x_le_two, x_gt_two);
}
};
template <typename T>
struct bessel_k0_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_k0<T>::run(x);
}
};
template <typename T>
struct bessel_k1e_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_k1e {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_k1e<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* k1ef.c
*
* Modified Bessel function, third kind, order one,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* float x, y, k1ef();
*
* y = k1ef( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of the third kind of order one of the argument:
*
* k1e(x) = exp(x) * k1(x).
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 4.9e-7 6.7e-8
* See k1().
*
*/
const float A[] = {-2.21338763073472585583E-8f, -2.43340614156596823496E-6f,
-1.73028895751305206302E-4f, -6.97572385963986435018E-3f,
-1.22611180822657148235E-1f, -3.53155960776544875667E-1f,
1.52530022733894777053E0f};
const float B[] = {2.01504975519703286596E-9f, -1.03457624656780970260E-8f,
5.74108412545004946722E-8f, -3.50196060308781257119E-7f,
2.40648494783721712015E-6f, -1.93619797416608296024E-5f,
1.95215518471351631108E-4f, -2.85781685962277938680E-3f,
1.03923736576817238437E-1f, 2.72062619048444266945E0f};
const T MAXNUM = pset1<T>(NumTraits<float>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = pdiv(internal::pchebevl<T, 7>::run(
pmadd(x, x, pset1<T>(-2.0)), A), x);
x_le_two = pmadd(
generic_i1<T, float>::run(x), plog(pmul(pset1<T>(0.5), x)), x_le_two);
x_le_two = pmul(x_le_two, pexp(x));
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), MAXNUM, x_le_two);
T x_gt_two = pmul(
internal::pchebevl<T, 10>::run(
psub(pdiv(pset1<T>(8.0), x), two), B),
prsqrt(x));
return pselect(pcmp_le(x, two), x_le_two, x_gt_two);
}
};
template <typename T>
struct generic_k1e<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* k1e.c
*
* Modified Bessel function, third kind, order one,
* exponentially scaled
*
*
*
* SYNOPSIS:
*
* double x, y, k1e();
*
* y = k1e( x );
*
*
*
* DESCRIPTION:
*
* Returns exponentially scaled modified Bessel function
* of the third kind of order one of the argument:
*
* k1e(x) = exp(x) * k1(x).
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 7.8e-16 1.2e-16
* See k1().
*
*/
const double A[] = {-7.02386347938628759343E-18, -2.42744985051936593393E-15,
-6.66690169419932900609E-13, -1.41148839263352776110E-10,
-2.21338763073472585583E-8, -2.43340614156596823496E-6,
-1.73028895751305206302E-4, -6.97572385963986435018E-3,
-1.22611180822657148235E-1, -3.53155960776544875667E-1,
1.52530022733894777053E0};
const double B[] = {-5.75674448366501715755E-18, 1.79405087314755922667E-17,
-5.68946255844285935196E-17, 1.83809354436663880070E-16,
-6.05704724837331885336E-16, 2.03870316562433424052E-15,
-7.01983709041831346144E-15, 2.47715442448130437068E-14,
-8.97670518232499435011E-14, 3.34841966607842919884E-13,
-1.28917396095102890680E-12, 5.13963967348173025100E-12,
-2.12996783842756842877E-11, 9.21831518760500529508E-11,
-4.19035475934189648750E-10, 2.01504975519703286596E-9,
-1.03457624656780970260E-8, 5.74108412545004946722E-8,
-3.50196060308781257119E-7, 2.40648494783721712015E-6,
-1.93619797416608296024E-5, 1.95215518471351631108E-4,
-2.85781685962277938680E-3, 1.03923736576817238437E-1,
2.72062619048444266945E0};
const T MAXNUM = pset1<T>(NumTraits<double>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = pdiv(internal::pchebevl<T, 11>::run(
pmadd(x, x, pset1<T>(-2.0)), A), x);
x_le_two = pmadd(
generic_i1<T, double>::run(x), plog(pmul(pset1<T>(0.5), x)), x_le_two);
x_le_two = pmul(x_le_two, pexp(x));
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), MAXNUM, x_le_two);
T x_gt_two = pmul(
internal::pchebevl<T, 25>::run(
psub(pdiv(pset1<T>(8.0), x), two), B),
prsqrt(x));
return pselect(pcmp_le(x, two), x_le_two, x_gt_two);
}
};
template <typename T>
struct bessel_k1e_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_k1e<T>::run(x);
}
};
template <typename T>
struct bessel_k1_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_k1 {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_k1<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* k1f.c
* Modified Bessel function, third kind, order one
*
*
*
* SYNOPSIS:
*
* float x, y, k1f();
*
* y = k1f( x );
*
*
*
* DESCRIPTION:
*
* Computes the modified Bessel function of the third kind
* of order one of the argument.
*
* The range is partitioned into the two intervals [0,2] and
* (2, infinity). Chebyshev polynomial expansions are employed
* in each interval.
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 4.6e-7 7.6e-8
*
* ERROR MESSAGES:
*
* message condition value returned
* k1 domain x <= 0 MAXNUM
*
*/
const float A[] = {-2.21338763073472585583E-8f, -2.43340614156596823496E-6f,
-1.73028895751305206302E-4f, -6.97572385963986435018E-3f,
-1.22611180822657148235E-1f, -3.53155960776544875667E-1f,
1.52530022733894777053E0f};
const float B[] = {2.01504975519703286596E-9f, -1.03457624656780970260E-8f,
5.74108412545004946722E-8f, -3.50196060308781257119E-7f,
2.40648494783721712015E-6f, -1.93619797416608296024E-5f,
1.95215518471351631108E-4f, -2.85781685962277938680E-3f,
1.03923736576817238437E-1f, 2.72062619048444266945E0f};
const T MAXNUM = pset1<T>(NumTraits<float>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = pdiv(internal::pchebevl<T, 7>::run(
pmadd(x, x, pset1<T>(-2.0)), A), x);
x_le_two = pmadd(
generic_i1<T, float>::run(x), plog(pmul(pset1<T>(0.5), x)), x_le_two);
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), MAXNUM, x_le_two);
T x_gt_two = pmul(
pexp(pnegate(x)),
pmul(
internal::pchebevl<T, 10>::run(
psub(pdiv(pset1<T>(8.0), x), two), B),
prsqrt(x)));
return pselect(pcmp_le(x, two), x_le_two, x_gt_two);
}
};
template <typename T>
struct generic_k1<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* k1.c
* Modified Bessel function, third kind, order one
*
*
*
* SYNOPSIS:
*
* float x, y, k1f();
*
* y = k1f( x );
*
*
*
* DESCRIPTION:
*
* Computes the modified Bessel function of the third kind
* of order one of the argument.
*
* The range is partitioned into the two intervals [0,2] and
* (2, infinity). Chebyshev polynomial expansions are employed
* in each interval.
*
*
*
* ACCURACY:
*
* Relative error:
* arithmetic domain # trials peak rms
* IEEE 0, 30 30000 4.6e-7 7.6e-8
*
* ERROR MESSAGES:
*
* message condition value returned
* k1 domain x <= 0 MAXNUM
*
*/
const double A[] = {-7.02386347938628759343E-18, -2.42744985051936593393E-15,
-6.66690169419932900609E-13, -1.41148839263352776110E-10,
-2.21338763073472585583E-8, -2.43340614156596823496E-6,
-1.73028895751305206302E-4, -6.97572385963986435018E-3,
-1.22611180822657148235E-1, -3.53155960776544875667E-1,
1.52530022733894777053E0};
const double B[] = {-5.75674448366501715755E-18, 1.79405087314755922667E-17,
-5.68946255844285935196E-17, 1.83809354436663880070E-16,
-6.05704724837331885336E-16, 2.03870316562433424052E-15,
-7.01983709041831346144E-15, 2.47715442448130437068E-14,
-8.97670518232499435011E-14, 3.34841966607842919884E-13,
-1.28917396095102890680E-12, 5.13963967348173025100E-12,
-2.12996783842756842877E-11, 9.21831518760500529508E-11,
-4.19035475934189648750E-10, 2.01504975519703286596E-9,
-1.03457624656780970260E-8, 5.74108412545004946722E-8,
-3.50196060308781257119E-7, 2.40648494783721712015E-6,
-1.93619797416608296024E-5, 1.95215518471351631108E-4,
-2.85781685962277938680E-3, 1.03923736576817238437E-1,
2.72062619048444266945E0};
const T MAXNUM = pset1<T>(NumTraits<double>::infinity());
const T two = pset1<T>(2.0);
T x_le_two = pdiv(internal::pchebevl<T, 11>::run(
pmadd(x, x, pset1<T>(-2.0)), A), x);
x_le_two = pmadd(
generic_i1<T, double>::run(x), plog(pmul(pset1<T>(0.5), x)), x_le_two);
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), MAXNUM, x_le_two);
T x_gt_two = pmul(
pexp(-x),
pmul(
internal::pchebevl<T, 25>::run(
psub(pdiv(pset1<T>(8.0), x), two), B),
prsqrt(x)));
return pselect(pcmp_le(x, two), x_le_two, x_gt_two);
}
};
template <typename T>
struct bessel_k1_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_k1<T>::run(x);
}
};
template <typename T>
struct bessel_j0_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_j0 {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_j0<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j0f.c
* Bessel function of order zero
*
*
*
* SYNOPSIS:
*
* float x, y, j0f();
*
* y = j0f( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of order zero of the argument.
*
* The domain is divided into the intervals [0, 2] and
* (2, infinity). In the first interval the following polynomial
* approximation is used:
*
*
* 2 2 2
* (w - r ) (w - r ) (w - r ) P(w)
* 1 2 3
*
* 2
* where w = x and the three r's are zeros of the function.
*
* In the second interval, the modulus and phase are approximated
* by polynomials of the form Modulus(x) = sqrt(1/x) Q(1/x)
* and Phase(x) = x + 1/x R(1/x^2) - pi/4. The function is
*
* j0(x) = Modulus(x) cos( Phase(x) ).
*
*
*
* ACCURACY:
*
* Absolute error:
* arithmetic domain # trials peak rms
* IEEE 0, 2 100000 1.3e-7 3.6e-8
* IEEE 2, 32 100000 1.9e-7 5.4e-8
*
*/
const float JP[] = {-6.068350350393235E-008f, 6.388945720783375E-006f,
-3.969646342510940E-004f, 1.332913422519003E-002f,
-1.729150680240724E-001f};
const float MO[] = {-6.838999669318810E-002f, 1.864949361379502E-001f,
-2.145007480346739E-001f, 1.197549369473540E-001f,
-3.560281861530129E-003f, -4.969382655296620E-002f,
-3.355424622293709E-006f, 7.978845717621440E-001f};
const float PH[] = {3.242077816988247E+001f, -3.630592630518434E+001f,
1.756221482109099E+001f, -4.974978466280903E+000f,
1.001973420681837E+000f, -1.939906941791308E-001f,
6.490598792654666E-002f, -1.249992184872738E-001f};
const T DR1 = pset1<T>(5.78318596294678452118f);
const T NEG_PIO4F = pset1<T>(-0.7853981633974483096f); /* -pi / 4 */
T y = pabs(x);
T z = pmul(y, y);
T y_le_two = pselect(
pcmp_lt(y, pset1<T>(1.0e-3f)),
pmadd(z, pset1<T>(-0.25f), pset1<T>(1.0f)),
pmul(psub(z, DR1), internal::ppolevl<T, 4>::run(z, JP)));
T q = pdiv(pset1<T>(1.0f), y);
T w = prsqrt(y);
T p = pmul(w, internal::ppolevl<T, 7>::run(q, MO));
w = pmul(q, q);
T yn = pmadd(q, internal::ppolevl<T, 7>::run(w, PH), NEG_PIO4F);
T y_gt_two = pmul(p, pcos(padd(yn, y)));
return pselect(pcmp_le(y, pset1<T>(2.0)), y_le_two, y_gt_two);
}
};
template <typename T>
struct generic_j0<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j0.c
* Bessel function of order zero
*
*
*
* SYNOPSIS:
*
* double x, y, j0();
*
* y = j0( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of order zero of the argument.
*
* The domain is divided into the intervals [0, 5] and
* (5, infinity). In the first interval the following rational
* approximation is used:
*
*
* 2 2
* (w - r ) (w - r ) P (w) / Q (w)
* 1 2 3 8
*
* 2
* where w = x and the two r's are zeros of the function.
*
* In the second interval, the Hankel asymptotic expansion
* is employed with two rational functions of degree 6/6
* and 7/7.
*
*
*
* ACCURACY:
*
* Absolute error:
* arithmetic domain # trials peak rms
* DEC 0, 30 10000 4.4e-17 6.3e-18
* IEEE 0, 30 60000 4.2e-16 1.1e-16
*
*/
const double PP[] = {7.96936729297347051624E-4, 8.28352392107440799803E-2,
1.23953371646414299388E0, 5.44725003058768775090E0,
8.74716500199817011941E0, 5.30324038235394892183E0,
9.99999999999999997821E-1};
const double PQ[] = {9.24408810558863637013E-4, 8.56288474354474431428E-2,
1.25352743901058953537E0, 5.47097740330417105182E0,
8.76190883237069594232E0, 5.30605288235394617618E0,
1.00000000000000000218E0};
const double QP[] = {-1.13663838898469149931E-2, -1.28252718670509318512E0,
-1.95539544257735972385E1, -9.32060152123768231369E1,
-1.77681167980488050595E2, -1.47077505154951170175E2,
-5.14105326766599330220E1, -6.05014350600728481186E0};
const double QQ[] = {1.00000000000000000000E0, 6.43178256118178023184E1,
8.56430025976980587198E2, 3.88240183605401609683E3,
7.24046774195652478189E3, 5.93072701187316984827E3,
2.06209331660327847417E3, 2.42005740240291393179E2};
const double RP[] = {-4.79443220978201773821E9, 1.95617491946556577543E12,
-2.49248344360967716204E14, 9.70862251047306323952E15};
const double RQ[] = {1.00000000000000000000E0, 4.99563147152651017219E2,
1.73785401676374683123E5, 4.84409658339962045305E7,
1.11855537045356834862E10, 2.11277520115489217587E12,
3.10518229857422583814E14, 3.18121955943204943306E16,
1.71086294081043136091E18};
const T DR1 = pset1<T>(5.78318596294678452118E0);
const T DR2 = pset1<T>(3.04712623436620863991E1);
const T SQ2OPI = pset1<T>(7.9788456080286535587989E-1); /* sqrt(2 / pi) */
const T NEG_PIO4 = pset1<T>(-0.7853981633974483096); /* pi / 4 */
T y = pabs(x);
T z = pmul(y, y);
T y_le_five = pselect(
pcmp_lt(y, pset1<T>(1.0e-5)),
pmadd(z, pset1<T>(-0.25), pset1<T>(1.0)),
pmul(pmul(psub(z, DR1), psub(z, DR2)),
pdiv(internal::ppolevl<T, 3>::run(z, RP),
internal::ppolevl<T, 8>::run(z, RQ))));
T s = pdiv(pset1<T>(25.0), z);
T p = pdiv(
internal::ppolevl<T, 6>::run(s, PP),
internal::ppolevl<T, 6>::run(s, PQ));
T q = pdiv(
internal::ppolevl<T, 7>::run(s, QP),
internal::ppolevl<T, 7>::run(s, QQ));
T yn = padd(y, NEG_PIO4);
T w = pdiv(pset1<T>(-5.0), y);
p = pmadd(p, pcos(yn), pmul(w, pmul(q, psin(yn))));
T y_gt_five = pmul(p, pmul(SQ2OPI, prsqrt(y)));
return pselect(pcmp_le(y, pset1<T>(5.0)), y_le_five, y_gt_five);
}
};
template <typename T>
struct bessel_j0_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_j0<T>::run(x);
}
};
template <typename T>
struct bessel_y0_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_y0 {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_y0<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j0f.c
* Bessel function of the second kind, order zero
*
*
*
* SYNOPSIS:
*
* float x, y, y0f();
*
* y = y0f( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of the second kind, of order
* zero, of the argument.
*
* The domain is divided into the intervals [0, 2] and
* (2, infinity). In the first interval a rational approximation
* R(x) is employed to compute
*
* 2 2 2
* y0(x) = (w - r ) (w - r ) (w - r ) R(x) + 2/pi ln(x) j0(x).
* 1 2 3
*
* Thus a call to j0() is required. The three zeros are removed
* from R(x) to improve its numerical stability.
*
* In the second interval, the modulus and phase are approximated
* by polynomials of the form Modulus(x) = sqrt(1/x) Q(1/x)
* and Phase(x) = x + 1/x S(1/x^2) - pi/4. Then the function is
*
* y0(x) = Modulus(x) sin( Phase(x) ).
*
*
*
*
* ACCURACY:
*
* Absolute error, when y0(x) < 1; else relative error:
*
* arithmetic domain # trials peak rms
* IEEE 0, 2 100000 2.4e-7 3.4e-8
* IEEE 2, 32 100000 1.8e-7 5.3e-8
*
*/
const float YP[] = {9.454583683980369E-008f, -9.413212653797057E-006f,
5.344486707214273E-004f, -1.584289289821316E-002f,
1.707584643733568E-001f};
const float MO[] = {-6.838999669318810E-002f, 1.864949361379502E-001f,
-2.145007480346739E-001f, 1.197549369473540E-001f,
-3.560281861530129E-003f, -4.969382655296620E-002f,
-3.355424622293709E-006f, 7.978845717621440E-001f};
const float PH[] = {3.242077816988247E+001f, -3.630592630518434E+001f,
1.756221482109099E+001f, -4.974978466280903E+000f,
1.001973420681837E+000f, -1.939906941791308E-001f,
6.490598792654666E-002f, -1.249992184872738E-001f};
const T YZ1 = pset1<T>(0.43221455686510834878f);
const T TWOOPI = pset1<T>(0.636619772367581343075535f); /* 2 / pi */
const T NEG_PIO4F = pset1<T>(-0.7853981633974483096f); /* -pi / 4 */
const T NEG_MAXNUM = pset1<T>(-NumTraits<float>::infinity());
T z = pmul(x, x);
T x_le_two = pmul(TWOOPI, pmul(plog(x), generic_j0<T, float>::run(x)));
x_le_two = pmadd(
psub(z, YZ1), internal::ppolevl<T, 4>::run(z, YP), x_le_two);
x_le_two = pselect(pcmp_le(x, pset1<T>(0.0)), NEG_MAXNUM, x_le_two);
T q = pdiv(pset1<T>(1.0), x);
T w = prsqrt(x);
T p = pmul(w, internal::ppolevl<T, 7>::run(q, MO));
T u = pmul(q, q);
T xn = pmadd(q, internal::ppolevl<T, 7>::run(u, PH), NEG_PIO4F);
T x_gt_two = pmul(p, psin(padd(xn, x)));
return pselect(pcmp_le(x, pset1<T>(2.0)), x_le_two, x_gt_two);
}
};
template <typename T>
struct generic_y0<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j0.c
* Bessel function of the second kind, order zero
*
*
*
* SYNOPSIS:
*
* double x, y, y0();
*
* y = y0( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of the second kind, of order
* zero, of the argument.
*
* The domain is divided into the intervals [0, 5] and
* (5, infinity). In the first interval a rational approximation
* R(x) is employed to compute
* y0(x) = R(x) + 2 * log(x) * j0(x) / PI.
* Thus a call to j0() is required.
*
* In the second interval, the Hankel asymptotic expansion
* is employed with two rational functions of degree 6/6
* and 7/7.
*
*
*
* ACCURACY:
*
* Absolute error, when y0(x) < 1; else relative error:
*
* arithmetic domain # trials peak rms
* DEC 0, 30 9400 7.0e-17 7.9e-18
* IEEE 0, 30 30000 1.3e-15 1.6e-16
*
*/
const double PP[] = {7.96936729297347051624E-4, 8.28352392107440799803E-2,
1.23953371646414299388E0, 5.44725003058768775090E0,
8.74716500199817011941E0, 5.30324038235394892183E0,
9.99999999999999997821E-1};
const double PQ[] = {9.24408810558863637013E-4, 8.56288474354474431428E-2,
1.25352743901058953537E0, 5.47097740330417105182E0,
8.76190883237069594232E0, 5.30605288235394617618E0,
1.00000000000000000218E0};
const double QP[] = {-1.13663838898469149931E-2, -1.28252718670509318512E0,
-1.95539544257735972385E1, -9.32060152123768231369E1,
-1.77681167980488050595E2, -1.47077505154951170175E2,
-5.14105326766599330220E1, -6.05014350600728481186E0};
const double QQ[] = {1.00000000000000000000E0, 6.43178256118178023184E1,
8.56430025976980587198E2, 3.88240183605401609683E3,
7.24046774195652478189E3, 5.93072701187316984827E3,
2.06209331660327847417E3, 2.42005740240291393179E2};
const double YP[] = {1.55924367855235737965E4, -1.46639295903971606143E7,
5.43526477051876500413E9, -9.82136065717911466409E11,
8.75906394395366999549E13, -3.46628303384729719441E15,
4.42733268572569800351E16, -1.84950800436986690637E16};
const double YQ[] = {1.00000000000000000000E0, 1.04128353664259848412E3,
6.26107330137134956842E5, 2.68919633393814121987E8,
8.64002487103935000337E10, 2.02979612750105546709E13,
3.17157752842975028269E15, 2.50596256172653059228E17};
const T SQ2OPI = pset1<T>(7.9788456080286535587989E-1); /* sqrt(2 / pi) */
const T TWOOPI = pset1<T>(0.636619772367581343075535); /* 2 / pi */
const T NEG_PIO4 = pset1<T>(-0.7853981633974483096); /* -pi / 4 */
const T NEG_MAXNUM = pset1<T>(-NumTraits<double>::infinity());
T z = pmul(x, x);
T x_le_five = pdiv(internal::ppolevl<T, 7>::run(z, YP),
internal::ppolevl<T, 7>::run(z, YQ));
x_le_five = pmadd(
pmul(TWOOPI, plog(x)), generic_j0<T, double>::run(x), x_le_five);
x_le_five = pselect(pcmp_le(x, pset1<T>(0.0)), NEG_MAXNUM, x_le_five);
T s = pdiv(pset1<T>(25.0), z);
T p = pdiv(
internal::ppolevl<T, 6>::run(s, PP),
internal::ppolevl<T, 6>::run(s, PQ));
T q = pdiv(
internal::ppolevl<T, 7>::run(s, QP),
internal::ppolevl<T, 7>::run(s, QQ));
T xn = padd(x, NEG_PIO4);
T w = pdiv(pset1<T>(5.0), x);
p = pmadd(p, psin(xn), pmul(w, pmul(q, pcos(xn))));
T x_gt_five = pmul(p, pmul(SQ2OPI, prsqrt(x)));
return pselect(pcmp_le(x, pset1<T>(5.0)), x_le_five, x_gt_five);
}
};
template <typename T>
struct bessel_y0_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_y0<T>::run(x);
}
};
template <typename T>
struct bessel_j1_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_j1 {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_j1<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j1f.c
* Bessel function of order one
*
*
*
* SYNOPSIS:
*
* float x, y, j1f();
*
* y = j1f( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of order one of the argument.
*
* The domain is divided into the intervals [0, 2] and
* (2, infinity). In the first interval a polynomial approximation
* 2
* (w - r ) x P(w)
* 1
* 2
* is used, where w = x and r is the first zero of the function.
*
* In the second interval, the modulus and phase are approximated
* by polynomials of the form Modulus(x) = sqrt(1/x) Q(1/x)
* and Phase(x) = x + 1/x R(1/x^2) - 3pi/4. The function is
*
* j0(x) = Modulus(x) cos( Phase(x) ).
*
*
*
* ACCURACY:
*
* Absolute error:
* arithmetic domain # trials peak rms
* IEEE 0, 2 100000 1.2e-7 2.5e-8
* IEEE 2, 32 100000 2.0e-7 5.3e-8
*
*
*/
const float JP[] = {-4.878788132172128E-009f, 6.009061827883699E-007f,
-4.541343896997497E-005f, 1.937383947804541E-003f,
-3.405537384615824E-002f};
const float MO1[] = {6.913942741265801E-002f, -2.284801500053359E-001f,
3.138238455499697E-001f, -2.102302420403875E-001f,
5.435364690523026E-003f, 1.493389585089498E-001f,
4.976029650847191E-006f, 7.978845453073848E-001f};
const float PH1[] = {-4.497014141919556E+001f, 5.073465654089319E+001f,
-2.485774108720340E+001f, 7.222973196770240E+000f,
-1.544842782180211E+000f, 3.503787691653334E-001f,
-1.637986776941202E-001f, 3.749989509080821E-001f};
const T Z1 = pset1<T>(1.46819706421238932572E1f);
const T NEG_THPIO4F = pset1<T>(-2.35619449019234492885f); /* -3*pi/4 */
T y = pabs(x);
T z = pmul(y, y);
T y_le_two = pmul(
psub(z, Z1),
pmul(x, internal::ppolevl<T, 4>::run(z, JP)));
T q = pdiv(pset1<T>(1.0f), y);
T w = prsqrt(y);
T p = pmul(w, internal::ppolevl<T, 7>::run(q, MO1));
w = pmul(q, q);
T yn = pmadd(q, internal::ppolevl<T, 7>::run(w, PH1), NEG_THPIO4F);
T y_gt_two = pmul(p, pcos(padd(yn, y)));
// j1 is an odd function. This implementation differs from cephes to
// take this fact in to account. Cephes returns -j1(x) for y > 2 range.
y_gt_two = pselect(
pcmp_lt(x, pset1<T>(0.0f)), pnegate(y_gt_two), y_gt_two);
return pselect(pcmp_le(y, pset1<T>(2.0f)), y_le_two, y_gt_two);
}
};
template <typename T>
struct generic_j1<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j1.c
* Bessel function of order one
*
*
*
* SYNOPSIS:
*
* double x, y, j1();
*
* y = j1( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of order one of the argument.
*
* The domain is divided into the intervals [0, 8] and
* (8, infinity). In the first interval a 24 term Chebyshev
* expansion is used. In the second, the asymptotic
* trigonometric representation is employed using two
* rational functions of degree 5/5.
*
*
*
* ACCURACY:
*
* Absolute error:
* arithmetic domain # trials peak rms
* DEC 0, 30 10000 4.0e-17 1.1e-17
* IEEE 0, 30 30000 2.6e-16 1.1e-16
*
*/
const double PP[] = {7.62125616208173112003E-4, 7.31397056940917570436E-2,
1.12719608129684925192E0, 5.11207951146807644818E0,
8.42404590141772420927E0, 5.21451598682361504063E0,
1.00000000000000000254E0};
const double PQ[] = {5.71323128072548699714E-4, 6.88455908754495404082E-2,
1.10514232634061696926E0, 5.07386386128601488557E0,
8.39985554327604159757E0, 5.20982848682361821619E0,
9.99999999999999997461E-1};
const double QP[] = {5.10862594750176621635E-2, 4.98213872951233449420E0,
7.58238284132545283818E1, 3.66779609360150777800E2,
7.10856304998926107277E2, 5.97489612400613639965E2,
2.11688757100572135698E2, 2.52070205858023719784E1};
const double QQ[] = {1.00000000000000000000E0, 7.42373277035675149943E1,
1.05644886038262816351E3, 4.98641058337653607651E3,
9.56231892404756170795E3, 7.99704160447350683650E3,
2.82619278517639096600E3, 3.36093607810698293419E2};
const double RP[] = {-8.99971225705559398224E8, 4.52228297998194034323E11,
-7.27494245221818276015E13, 3.68295732863852883286E15};
const double RQ[] = {1.00000000000000000000E0, 6.20836478118054335476E2,
2.56987256757748830383E5, 8.35146791431949253037E7,
2.21511595479792499675E10, 4.74914122079991414898E12,
7.84369607876235854894E14, 8.95222336184627338078E16,
5.32278620332680085395E18};
const T Z1 = pset1<T>(1.46819706421238932572E1);
const T Z2 = pset1<T>(4.92184563216946036703E1);
const T NEG_THPIO4 = pset1<T>(-2.35619449019234492885); /* -3*pi/4 */
const T SQ2OPI = pset1<T>(7.9788456080286535587989E-1); /* sqrt(2 / pi) */
T y = pabs(x);
T z = pmul(y, y);
T y_le_five = pdiv(internal::ppolevl<T, 3>::run(z, RP),
internal::ppolevl<T, 8>::run(z, RQ));
y_le_five = pmul(pmul(pmul(y_le_five, x), psub(z, Z1)), psub(z, Z2));
T s = pdiv(pset1<T>(25.0), z);
T p = pdiv(
internal::ppolevl<T, 6>::run(s, PP),
internal::ppolevl<T, 6>::run(s, PQ));
T q = pdiv(
internal::ppolevl<T, 7>::run(s, QP),
internal::ppolevl<T, 7>::run(s, QQ));
T yn = padd(y, NEG_THPIO4);
T w = pdiv(pset1<T>(-5.0), y);
p = pmadd(p, pcos(yn), pmul(w, pmul(q, psin(yn))));
T y_gt_five = pmul(p, pmul(SQ2OPI, prsqrt(y)));
// j1 is an odd function. This implementation differs from cephes to
// take this fact in to account. Cephes returns -j1(x) for y > 5 range.
y_gt_five = pselect(
pcmp_lt(x, pset1<T>(0.0)), pnegate(y_gt_five), y_gt_five);
return pselect(pcmp_le(y, pset1<T>(5.0)), y_le_five, y_gt_five);
}
};
template <typename T>
struct bessel_j1_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_j1<T>::run(x);
}
};
template <typename T>
struct bessel_y1_retval {
typedef T type;
};
template <typename T, typename ScalarType = typename unpacket_traits<T>::type>
struct generic_y1 {
EIGEN_STATIC_ASSERT((internal::is_same<T, T>::value == false),
THIS_TYPE_IS_NOT_SUPPORTED)
EIGEN_DEVICE_FUNC static EIGEN_STRONG_INLINE T run(const T&) {
return ScalarType(0);
}
};
template <typename T>
struct generic_y1<T, float> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j1f.c
* Bessel function of second kind of order one
*
*
*
* SYNOPSIS:
*
* double x, y, y1();
*
* y = y1( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of the second kind of order one
* of the argument.
*
* The domain is divided into the intervals [0, 2] and
* (2, infinity). In the first interval a rational approximation
* R(x) is employed to compute
*
* 2
* y0(x) = (w - r ) x R(x^2) + 2/pi (ln(x) j1(x) - 1/x) .
* 1
*
* Thus a call to j1() is required.
*
* In the second interval, the modulus and phase are approximated
* by polynomials of the form Modulus(x) = sqrt(1/x) Q(1/x)
* and Phase(x) = x + 1/x S(1/x^2) - 3pi/4. Then the function is
*
* y0(x) = Modulus(x) sin( Phase(x) ).
*
*
*
*
* ACCURACY:
*
* Absolute error:
* arithmetic domain # trials peak rms
* IEEE 0, 2 100000 2.2e-7 4.6e-8
* IEEE 2, 32 100000 1.9e-7 5.3e-8
*
* (error criterion relative when |y1| > 1).
*
*/
const float YP[] = {8.061978323326852E-009f, -9.496460629917016E-007f,
6.719543806674249E-005f, -2.641785726447862E-003f,
4.202369946500099E-002f};
const float MO1[] = {6.913942741265801E-002f, -2.284801500053359E-001f,
3.138238455499697E-001f, -2.102302420403875E-001f,
5.435364690523026E-003f, 1.493389585089498E-001f,
4.976029650847191E-006f, 7.978845453073848E-001f};
const float PH1[] = {-4.497014141919556E+001f, 5.073465654089319E+001f,
-2.485774108720340E+001f, 7.222973196770240E+000f,
-1.544842782180211E+000f, 3.503787691653334E-001f,
-1.637986776941202E-001f, 3.749989509080821E-001f};
const T YO1 = pset1<T>(4.66539330185668857532f);
const T NEG_THPIO4F = pset1<T>(-2.35619449019234492885f); /* -3*pi/4 */
const T TWOOPI = pset1<T>(0.636619772367581343075535f); /* 2/pi */
const T NEG_MAXNUM = pset1<T>(-NumTraits<float>::infinity());
T z = pmul(x, x);
T x_le_two = pmul(psub(z, YO1), internal::ppolevl<T, 4>::run(z, YP));
x_le_two = pmadd(
x_le_two, x,
pmul(TWOOPI, pmadd(
generic_j1<T, float>::run(x), plog(x),
pdiv(pset1<T>(-1.0f), x))));
x_le_two = pselect(pcmp_lt(x, pset1<T>(0.0f)), NEG_MAXNUM, x_le_two);
T q = pdiv(pset1<T>(1.0), x);
T w = prsqrt(x);
T p = pmul(w, internal::ppolevl<T, 7>::run(q, MO1));
w = pmul(q, q);
T xn = pmadd(q, internal::ppolevl<T, 7>::run(w, PH1), NEG_THPIO4F);
T x_gt_two = pmul(p, psin(padd(xn, x)));
return pselect(pcmp_le(x, pset1<T>(2.0)), x_le_two, x_gt_two);
}
};
template <typename T>
struct generic_y1<T, double> {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T& x) {
/* j1.c
* Bessel function of second kind of order one
*
*
*
* SYNOPSIS:
*
* double x, y, y1();
*
* y = y1( x );
*
*
*
* DESCRIPTION:
*
* Returns Bessel function of the second kind of order one
* of the argument.
*
* The domain is divided into the intervals [0, 8] and
* (8, infinity). In the first interval a 25 term Chebyshev
* expansion is used, and a call to j1() is required.
* In the second, the asymptotic trigonometric representation
* is employed using two rational functions of degree 5/5.
*
*
*
* ACCURACY:
*
* Absolute error:
* arithmetic domain # trials peak rms
* DEC 0, 30 10000 8.6e-17 1.3e-17
* IEEE 0, 30 30000 1.0e-15 1.3e-16
*
* (error criterion relative when |y1| > 1).
*
*/
const double PP[] = {7.62125616208173112003E-4, 7.31397056940917570436E-2,
1.12719608129684925192E0, 5.11207951146807644818E0,
8.42404590141772420927E0, 5.21451598682361504063E0,
1.00000000000000000254E0};
const double PQ[] = {5.71323128072548699714E-4, 6.88455908754495404082E-2,
1.10514232634061696926E0, 5.07386386128601488557E0,
8.39985554327604159757E0, 5.20982848682361821619E0,
9.99999999999999997461E-1};
const double QP[] = {5.10862594750176621635E-2, 4.98213872951233449420E0,
7.58238284132545283818E1, 3.66779609360150777800E2,
7.10856304998926107277E2, 5.97489612400613639965E2,
2.11688757100572135698E2, 2.52070205858023719784E1};
const double QQ[] = {1.00000000000000000000E0, 7.42373277035675149943E1,
1.05644886038262816351E3, 4.98641058337653607651E3,
9.56231892404756170795E3, 7.99704160447350683650E3,
2.82619278517639096600E3, 3.36093607810698293419E2};
const double YP[] = {1.26320474790178026440E9, -6.47355876379160291031E11,
1.14509511541823727583E14, -8.12770255501325109621E15,
2.02439475713594898196E17, -7.78877196265950026825E17};
const double YQ[] = {1.00000000000000000000E0, 5.94301592346128195359E2,
2.35564092943068577943E5, 7.34811944459721705660E7,
1.87601316108706159478E10, 3.88231277496238566008E12,
6.20557727146953693363E14, 6.87141087355300489866E16,
3.97270608116560655612E18};
const T SQ2OPI = pset1<T>(.79788456080286535588);
const T NEG_THPIO4 = pset1<T>(-2.35619449019234492885); /* -3*pi/4 */
const T TWOOPI = pset1<T>(0.636619772367581343075535); /* 2/pi */
const T NEG_MAXNUM = pset1<T>(-NumTraits<double>::infinity());
T z = pmul(x, x);
T x_le_five = pdiv(internal::ppolevl<T, 5>::run(z, YP),
internal::ppolevl<T, 8>::run(z, YQ));
x_le_five = pmadd(
x_le_five, x, pmul(
TWOOPI, pmadd(generic_j1<T, double>::run(x), plog(x),
pdiv(pset1<T>(-1.0), x))));
x_le_five = pselect(pcmp_le(x, pset1<T>(0.0)), NEG_MAXNUM, x_le_five);
T s = pdiv(pset1<T>(25.0), z);
T p = pdiv(
internal::ppolevl<T, 6>::run(s, PP),
internal::ppolevl<T, 6>::run(s, PQ));
T q = pdiv(
internal::ppolevl<T, 7>::run(s, QP),
internal::ppolevl<T, 7>::run(s, QQ));
T xn = padd(x, NEG_THPIO4);
T w = pdiv(pset1<T>(5.0), x);
p = pmadd(p, psin(xn), pmul(w, pmul(q, pcos(xn))));
T x_gt_five = pmul(p, pmul(SQ2OPI, prsqrt(x)));
return pselect(pcmp_le(x, pset1<T>(5.0)), x_le_five, x_gt_five);
}
};
template <typename T>
struct bessel_y1_impl {
EIGEN_DEVICE_FUNC
static EIGEN_STRONG_INLINE T run(const T x) {
return generic_y1<T>::run(x);
}
};
} // end namespace internal
namespace numext {
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_i0, Scalar)
bessel_i0(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_i0, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_i0e, Scalar)
bessel_i0e(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_i0e, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_i1, Scalar)
bessel_i1(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_i1, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_i1e, Scalar)
bessel_i1e(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_i1e, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_k0, Scalar)
bessel_k0(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_k0, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_k0e, Scalar)
bessel_k0e(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_k0e, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_k1, Scalar)
bessel_k1(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_k1, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_k1e, Scalar)
bessel_k1e(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_k1e, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_j0, Scalar)
bessel_j0(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_j0, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_y0, Scalar)
bessel_y0(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_y0, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_j1, Scalar)
bessel_j1(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_j1, Scalar)::run(x);
}
template <typename Scalar>
EIGEN_DEVICE_FUNC inline EIGEN_MATHFUNC_RETVAL(bessel_y1, Scalar)
bessel_y1(const Scalar& x) {
return EIGEN_MATHFUNC_IMPL(bessel_y1, Scalar)::run(x);
}
} // end namespace numext
} // end namespace Eigen
#endif // EIGEN_BESSEL_FUNCTIONS_H