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/* --------------------------------------------------------------  */
/* (C)Copyright 2007,2008,                                         */
/* International Business Machines Corporation                     */
/* All Rights Reserved.                                            */
/*                                                                 */
/* Redistribution and use in source and binary forms, with or      */
/* without modification, are permitted provided that the           */
/* following conditions are met:                                   */
/*                                                                 */
/* - Redistributions of source code must retain the above copyright*/
/*   notice, this list of conditions and the following disclaimer. */
/*                                                                 */
/* - Redistributions in binary form must reproduce the above       */
/*   copyright notice, this list of conditions and the following   */
/*   disclaimer in the documentation and/or other materials        */
/*   provided with the distribution.                               */
/*                                                                 */
/* - Neither the name of IBM Corporation nor the names of its      */
/*   contributors may be used to endorse or promote products       */
/*   derived from this software without specific prior written     */
/*   permission.                                                   */
/*                                                                 */
/* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND          */
/* CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES,     */
/* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF        */
/* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE        */
/* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR            */
/* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,    */
/* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT    */
/* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;    */
/* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)        */
/* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN       */
/* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR    */
/* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE,  */
/* EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.              */
/* --------------------------------------------------------------  */
/* PROLOG END TAG zYx                                              */
#ifdef __SPU__
 
#ifndef _TGAMMAD2_H_
#define _TGAMMAD2_H_    1
 
#include <spu_intrinsics.h>
#include "simdmath.h"
 
#include "recipd2.h"
#include "truncd2.h"
#include "expd2.h"
#include "logd2.h"
#include "divd2.h"
#include "sind2.h"
#include "powd2.h"
 
 
/*
 * FUNCTION
 *      vector double _tgammad2(vector double x)
 *
 * DESCRIPTION
 *      _tgammad2
 *
 *      This is an interesting function to approximate fast
 *      and accurately. We take a fairly standard approach - break
 *      the domain into 5 separate regions:
 *
 *      1. [-infinity, 0)  - use
 *      2. [0, 1)          - push x into [1,2), then adjust the
 *                           result.
 *      3. [1, 2)          - use a rational approximation.
 *      4. [2, 10)         - pull back into [1, 2), then adjust
 *                           the result.
 *      5. [10, +infinity] - use Stirling's Approximation.
 *
 *
 * Special Cases:
 *      - tgamma(+/- 0) returns +/- infinity
 *      - tgamma(negative integer) returns NaN
 *      - tgamma(-infinity) returns NaN
 *      - tgamma(infinity) returns infinity
 *
 */
 
 
/*
 * Coefficients for Stirling's Series for Gamma()
 */
/* 1/ 1 */
#define STIRLING_00   1.000000000000000000000000000000000000E0
/* 1/ 12 */
#define STIRLING_01   8.333333333333333333333333333333333333E-2
/* 1/ 288 */
#define STIRLING_02   3.472222222222222222222222222222222222E-3
/* -139/ 51840 */
#define STIRLING_03  -2.681327160493827160493827160493827160E-3
/* -571/ 2488320 */
#define STIRLING_04  -2.294720936213991769547325102880658436E-4
/* 163879/ 209018880 */
#define STIRLING_05   7.840392217200666274740348814422888497E-4
/* 5246819/ 75246796800 */
#define STIRLING_06   6.972813758365857774293988285757833083E-5
/* -534703531/ 902961561600 */
#define STIRLING_07  -5.921664373536938828648362256044011874E-4
/* -4483131259/ 86684309913600 */
#define STIRLING_08  -5.171790908260592193370578430020588228E-5
/* 432261921612371/ 514904800886784000 */
#define STIRLING_09   8.394987206720872799933575167649834452E-4
/* 6232523202521089/ 86504006548979712000 */
#define STIRLING_10   7.204895416020010559085719302250150521E-5
/* -25834629665134204969/ 13494625021640835072000 */
#define STIRLING_11  -1.914438498565477526500898858328522545E-3
/* -1579029138854919086429/ 9716130015581401251840000 */
#define STIRLING_12  -1.625162627839158168986351239802709981E-4
/* 746590869962651602203151/ 116593560186976815022080000 */
#define STIRLING_13   6.403362833808069794823638090265795830E-3
/* 1511513601028097903631961/ 2798245444487443560529920000 */
#define STIRLING_14   5.401647678926045151804675085702417355E-4
/* -8849272268392873147705987190261/ 299692087104605205332754432000000 */
#define STIRLING_15  -2.952788094569912050544065105469382445E-2
/* -142801712490607530608130701097701/ 57540880724084199423888850944000000 */
#define STIRLING_16  -2.481743600264997730915658368743464324E-3
 
 
/*
 * Rational Approximation Coefficients for the
 * domain [1, 2).
 */
#define TGD2_P00     -1.8211798563156931777484715e+05
#define TGD2_P01     -8.7136501560410004458390176e+04
#define TGD2_P02     -3.9304030489789496641606092e+04
#define TGD2_P03     -1.2078833505605729442322627e+04
#define TGD2_P04     -2.2149136023607729839568492e+03
#define TGD2_P05     -7.2672456596961114883015398e+02
#define TGD2_P06     -2.2126466212611862971471055e+01
#define TGD2_P07     -2.0162424149396112937893122e+01
 
#define TGD2_Q00     1.0000000000000000000000000
#define TGD2_Q01     -1.8212849094205905566923320e+05
#define TGD2_Q02     -1.9220660507239613798446953e+05
#define TGD2_Q03     2.9692670736656051303725690e+04
#define TGD2_Q04     3.0352658363629092491464689e+04
#define TGD2_Q05     -1.0555895821041505769244395e+04
#define TGD2_Q06     1.2786642579487202056043316e+03
#define TGD2_Q07     -5.5279768804094054246434098e+01
 
static __inline vector double _tgammad2(vector double x)
{
    vector double signbit = spu_splats(-0.0);
    vector double zerod   = spu_splats(0.0);
    vector double halfd   = spu_splats(0.5);
    vector double oned    = spu_splats(1.0);
    vector double ninep9d = (vec_double2)spu_splats(0x4023FFFFFFFFFFFFull);
    vector double twohd   = spu_splats(200.0);
    vector double pi      = spu_splats(SM_PI);
    vector double sqrt2pi = spu_splats(2.50662827463100050241576528481);
    vector double inf     = (vector double)spu_splats(0x7FF0000000000000ull);
    vector double nan     = (vector double)spu_splats(0x7FF8000000000000ull);
 
 
    vector double xabs;
    vector double xscaled;
    vector double xtrunc;
    vector double xinv;
    vector double nresult;
    vector double rresult; /* Rational Approx result */
    vector double sresult; /* Stirling's result */
    vector double result;
    vector double pr,qr;
 
    vector unsigned long long gt0   = spu_cmpgt(x, zerod);
    vector unsigned long long gt1   = spu_cmpgt(x, oned);
    vector unsigned long long gt9p9 = spu_cmpgt(x, ninep9d);
    vector unsigned long long gt200 = spu_cmpgt(x, twohd);
 
 
    xabs    = spu_andc(x, signbit);
 
    /*
     * For x in [0, 1], add 1 to x, use rational
     * approximation, then use:
     *
     * gamma(x) = gamma(x+1)/x
     *
     */
    xabs = spu_sel(spu_add(xabs, oned), xabs, gt1);
    xtrunc = _truncd2(xabs);
 
 
    /*
     * For x in [2, 10):
     */
    xscaled = spu_add(oned, spu_sub(xabs, xtrunc));
 
    /*
     * For x in [1,2), use a rational approximation.
     */
    pr = spu_madd(xscaled, spu_splats(TGD2_P07), spu_splats(TGD2_P06));
    pr = spu_madd(pr, xscaled, spu_splats(TGD2_P05));
    pr = spu_madd(pr, xscaled, spu_splats(TGD2_P04));
    pr = spu_madd(pr, xscaled, spu_splats(TGD2_P03));
    pr = spu_madd(pr, xscaled, spu_splats(TGD2_P02));
    pr = spu_madd(pr, xscaled, spu_splats(TGD2_P01));
    pr = spu_madd(pr, xscaled, spu_splats(TGD2_P00));
 
    qr = spu_madd(xscaled, spu_splats(TGD2_Q07), spu_splats(TGD2_Q06));
    qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q05));
    qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q04));
    qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q03));
    qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q02));
    qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q01));
    qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q00));
 
    rresult = _divd2(pr, qr);
    rresult = spu_sel(_divd2(rresult, x), rresult, gt1);
 
    /*
     * If x was in [2,10) and we pulled it into [1,2), we need to push
     * it back out again.
     */
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [2,3) */
    xscaled = spu_add(xscaled, oned);
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [3,4) */
    xscaled = spu_add(xscaled, oned);
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [4,5) */
    xscaled = spu_add(xscaled, oned);
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [5,6) */
    xscaled = spu_add(xscaled, oned);
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [6,7) */
    xscaled = spu_add(xscaled, oned);
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [7,8) */
    xscaled = spu_add(xscaled, oned);
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [8,9) */
    xscaled = spu_add(xscaled, oned);
    rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [9,10) */
 
 
    /*
     * For x >= 10, we use Stirling's Approximation
     */
    vector double sum;
    xinv    = _recipd2(xabs);
    sum = spu_madd(xinv, spu_splats(STIRLING_16), spu_splats(STIRLING_15));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_14));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_13));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_12));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_11));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_10));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_09));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_08));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_07));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_06));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_05));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_04));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_03));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_02));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_01));
    sum = spu_madd(sum, xinv, spu_splats(STIRLING_00));
 
    sum = spu_mul(sum, sqrt2pi);
    sum = spu_mul(sum, _powd2(x, spu_sub(x, halfd)));
    sresult = spu_mul(sum, _expd2(spu_or(x, signbit)));
 
    /*
     * Choose rational approximation or Stirling's result.
     */
    result = spu_sel(rresult, sresult, gt9p9);
 
 
    result = spu_sel(result, inf, gt200);
 
    /* For x < 0, use:
     *
     * gamma(x) = pi/(x*gamma(-x)*sin(x*pi))
     * or
     * gamma(x) = pi/(gamma(1 - x)*sin(x*pi))
     */
    nresult = _divd2(pi, spu_mul(x, spu_mul(result, _sind2(spu_mul(x, pi)))));
    result = spu_sel(nresult, result, gt0);
 
    /*
     * x = non-positive integer, return NaN.
     */
    result = spu_sel(result, nan, spu_andc(spu_cmpeq(x, xtrunc), gt0));
 
 
    return result;
}
 
#endif /* _TGAMMAD2_H_ */
#endif /* __SPU__ */

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[/] [openrisc/] [trunk/] [gnu-src/] [newlib-1.17.0/] [newlib/] [libm/] [machine/] [spu/] [headers/] [tgammad2.h] - Blame information for rev 148

Line No.	Rev	Author	Line
1	148	jeremybenn	`/* -------------------------------------------------------------- */`
2			`/* (C)Copyright 2007,2008, */`
3			`/* International Business Machines Corporation */`
4			`/* All Rights Reserved. */`
5			`/* */`
6			`/* Redistribution and use in source and binary forms, with or */`
7			`/* without modification, are permitted provided that the */`
8			`/* following conditions are met: */`
9			`/* */`
10			`/* - Redistributions of source code must retain the above copyright*/`
11			`/* notice, this list of conditions and the following disclaimer. */`
12			`/* */`
13			`/* - Redistributions in binary form must reproduce the above */`
14			`/* copyright notice, this list of conditions and the following */`
15			`/* disclaimer in the documentation and/or other materials */`
16			`/* provided with the distribution. */`
17			`/* */`
18			`/* - Neither the name of IBM Corporation nor the names of its */`
19			`/* contributors may be used to endorse or promote products */`
20			`/* derived from this software without specific prior written */`
21			`/* permission. */`
22			`/* */`
23			`/* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND */`
24			`/* CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, */`
25			`/* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF */`
26			`/* MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE */`
27			`/* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR */`
28			`/* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, */`
29			`/* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT */`
30			`/* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; */`
31			`/* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) */`
32			`/* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN */`
33			`/* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR */`
34			`/* OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, */`
35			`/* EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */`
36			`/* -------------------------------------------------------------- */`
37			`/* PROLOG END TAG zYx */`
38			`#ifdef __SPU__`
39
40			`#ifndef _TGAMMAD2_H_`
41			`#define _TGAMMAD2_H_ 1`
42
43			`#include <spu_intrinsics.h>`
44			`#include "simdmath.h"`
45
46			`#include "recipd2.h"`
47			`#include "truncd2.h"`
48			`#include "expd2.h"`
49			`#include "logd2.h"`
50			`#include "divd2.h"`
51			`#include "sind2.h"`
52			`#include "powd2.h"`
53
54
55			`/*`
56			`* FUNCTION`
57			`* vector double _tgammad2(vector double x)`
58			`*`
59			`* DESCRIPTION`
60			`* _tgammad2`
61			`*`
62			`* This is an interesting function to approximate fast`
63			`* and accurately. We take a fairly standard approach - break`
64			`* the domain into 5 separate regions:`
65			`*`
66			`* 1. [-infinity, 0) - use`
67			`* 2. [0, 1) - push x into [1,2), then adjust the`
68			`* result.`
69			`* 3. [1, 2) - use a rational approximation.`
70			`* 4. [2, 10) - pull back into [1, 2), then adjust`
71			`* the result.`
72			`* 5. [10, +infinity] - use Stirling's Approximation.`
73			`*`
74			`*`
75			`* Special Cases:`
76			`* - tgamma(+/- 0) returns +/- infinity`
77			`* - tgamma(negative integer) returns NaN`
78			`* - tgamma(-infinity) returns NaN`
79			`* - tgamma(infinity) returns infinity`
80			`*`
81			`*/`
82
83
84			`/*`
85			`* Coefficients for Stirling's Series for Gamma()`
86			`*/`
87			`/* 1/ 1 */`
88			`#define STIRLING_00 1.000000000000000000000000000000000000E0`
89			`/* 1/ 12 */`
90			`#define STIRLING_01 8.333333333333333333333333333333333333E-2`
91			`/* 1/ 288 */`
92			`#define STIRLING_02 3.472222222222222222222222222222222222E-3`
93			`/* -139/ 51840 */`
94			`#define STIRLING_03 -2.681327160493827160493827160493827160E-3`
95			`/* -571/ 2488320 */`
96			`#define STIRLING_04 -2.294720936213991769547325102880658436E-4`
97			`/* 163879/ 209018880 */`
98			`#define STIRLING_05 7.840392217200666274740348814422888497E-4`
99			`/* 5246819/ 75246796800 */`
100			`#define STIRLING_06 6.972813758365857774293988285757833083E-5`
101			`/* -534703531/ 902961561600 */`
102			`#define STIRLING_07 -5.921664373536938828648362256044011874E-4`
103			`/* -4483131259/ 86684309913600 */`
104			`#define STIRLING_08 -5.171790908260592193370578430020588228E-5`
105			`/* 432261921612371/ 514904800886784000 */`
106			`#define STIRLING_09 8.394987206720872799933575167649834452E-4`
107			`/* 6232523202521089/ 86504006548979712000 */`
108			`#define STIRLING_10 7.204895416020010559085719302250150521E-5`
109			`/* -25834629665134204969/ 13494625021640835072000 */`
110			`#define STIRLING_11 -1.914438498565477526500898858328522545E-3`
111			`/* -1579029138854919086429/ 9716130015581401251840000 */`
112			`#define STIRLING_12 -1.625162627839158168986351239802709981E-4`
113			`/* 746590869962651602203151/ 116593560186976815022080000 */`
114			`#define STIRLING_13 6.403362833808069794823638090265795830E-3`
115			`/* 1511513601028097903631961/ 2798245444487443560529920000 */`
116			`#define STIRLING_14 5.401647678926045151804675085702417355E-4`
117			`/* -8849272268392873147705987190261/ 299692087104605205332754432000000 */`
118			`#define STIRLING_15 -2.952788094569912050544065105469382445E-2`
119			`/* -142801712490607530608130701097701/ 57540880724084199423888850944000000 */`
120			`#define STIRLING_16 -2.481743600264997730915658368743464324E-3`
121
122
123			`/*`
124			`* Rational Approximation Coefficients for the`
125			`* domain [1, 2).`
126			`*/`
127			`#define TGD2_P00 -1.8211798563156931777484715e+05`
128			`#define TGD2_P01 -8.7136501560410004458390176e+04`
129			`#define TGD2_P02 -3.9304030489789496641606092e+04`
130			`#define TGD2_P03 -1.2078833505605729442322627e+04`
131			`#define TGD2_P04 -2.2149136023607729839568492e+03`
132			`#define TGD2_P05 -7.2672456596961114883015398e+02`
133			`#define TGD2_P06 -2.2126466212611862971471055e+01`
134			`#define TGD2_P07 -2.0162424149396112937893122e+01`
135
136			`#define TGD2_Q00 1.0000000000000000000000000`
137			`#define TGD2_Q01 -1.8212849094205905566923320e+05`
138			`#define TGD2_Q02 -1.9220660507239613798446953e+05`
139			`#define TGD2_Q03 2.9692670736656051303725690e+04`
140			`#define TGD2_Q04 3.0352658363629092491464689e+04`
141			`#define TGD2_Q05 -1.0555895821041505769244395e+04`
142			`#define TGD2_Q06 1.2786642579487202056043316e+03`
143			`#define TGD2_Q07 -5.5279768804094054246434098e+01`
144
145			`static __inline vector double _tgammad2(vector double x)`
146			`{`
147			`vector double signbit = spu_splats(-0.0);`
148			`vector double zerod = spu_splats(0.0);`
149			`vector double halfd = spu_splats(0.5);`
150			`vector double oned = spu_splats(1.0);`
151			`vector double ninep9d = (vec_double2)spu_splats(0x4023FFFFFFFFFFFFull);`
152			`vector double twohd = spu_splats(200.0);`
153			`vector double pi = spu_splats(SM_PI);`
154			`vector double sqrt2pi = spu_splats(2.50662827463100050241576528481);`
155			`vector double inf = (vector double)spu_splats(0x7FF0000000000000ull);`
156			`vector double nan = (vector double)spu_splats(0x7FF8000000000000ull);`
157
158
159			`vector double xabs;`
160			`vector double xscaled;`
161			`vector double xtrunc;`
162			`vector double xinv;`
163			`vector double nresult;`
164			`vector double rresult; /* Rational Approx result */`
165			`vector double sresult; /* Stirling's result */`
166			`vector double result;`
167			`vector double pr,qr;`
168
169			`vector unsigned long long gt0 = spu_cmpgt(x, zerod);`
170			`vector unsigned long long gt1 = spu_cmpgt(x, oned);`
171			`vector unsigned long long gt9p9 = spu_cmpgt(x, ninep9d);`
172			`vector unsigned long long gt200 = spu_cmpgt(x, twohd);`
173
174
175			`xabs = spu_andc(x, signbit);`
176
177			`/*`
178			`* For x in [0, 1], add 1 to x, use rational`
179			`* approximation, then use:`
180			`*`
181			`* gamma(x) = gamma(x+1)/x`
182			`*`
183			`*/`
184			`xabs = spu_sel(spu_add(xabs, oned), xabs, gt1);`
185			`xtrunc = _truncd2(xabs);`
186
187
188			`/*`
189			`* For x in [2, 10):`
190			`*/`
191			`xscaled = spu_add(oned, spu_sub(xabs, xtrunc));`
192
193			`/*`
194			`* For x in [1,2), use a rational approximation.`
195			`*/`
196			`pr = spu_madd(xscaled, spu_splats(TGD2_P07), spu_splats(TGD2_P06));`
197			`pr = spu_madd(pr, xscaled, spu_splats(TGD2_P05));`
198			`pr = spu_madd(pr, xscaled, spu_splats(TGD2_P04));`
199			`pr = spu_madd(pr, xscaled, spu_splats(TGD2_P03));`
200			`pr = spu_madd(pr, xscaled, spu_splats(TGD2_P02));`
201			`pr = spu_madd(pr, xscaled, spu_splats(TGD2_P01));`
202			`pr = spu_madd(pr, xscaled, spu_splats(TGD2_P00));`
203
204			`qr = spu_madd(xscaled, spu_splats(TGD2_Q07), spu_splats(TGD2_Q06));`
205			`qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q05));`
206			`qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q04));`
207			`qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q03));`
208			`qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q02));`
209			`qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q01));`
210			`qr = spu_madd(qr, xscaled, spu_splats(TGD2_Q00));`
211
212			`rresult = _divd2(pr, qr);`
213			`rresult = spu_sel(_divd2(rresult, x), rresult, gt1);`
214
215			`/*`
216			`* If x was in [2,10) and we pulled it into [1,2), we need to push`
217			`* it back out again.`
218			`*/`
219			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [2,3) */`
220			`xscaled = spu_add(xscaled, oned);`
221			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [3,4) */`
222			`xscaled = spu_add(xscaled, oned);`
223			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [4,5) */`
224			`xscaled = spu_add(xscaled, oned);`
225			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [5,6) */`
226			`xscaled = spu_add(xscaled, oned);`
227			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [6,7) */`
228			`xscaled = spu_add(xscaled, oned);`
229			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [7,8) */`
230			`xscaled = spu_add(xscaled, oned);`
231			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [8,9) */`
232			`xscaled = spu_add(xscaled, oned);`
233			`rresult = spu_sel(rresult, spu_mul(rresult, xscaled), spu_cmpgt(x, xscaled)); /* [9,10) */`
234
235
236			`/*`
237			`* For x >= 10, we use Stirling's Approximation`
238			`*/`
239			`vector double sum;`
240			`xinv = _recipd2(xabs);`
241			`sum = spu_madd(xinv, spu_splats(STIRLING_16), spu_splats(STIRLING_15));`
242			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_14));`
243			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_13));`
244			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_12));`
245			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_11));`
246			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_10));`
247			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_09));`
248			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_08));`
249			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_07));`
250			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_06));`
251			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_05));`
252			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_04));`
253			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_03));`
254			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_02));`
255			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_01));`
256			`sum = spu_madd(sum, xinv, spu_splats(STIRLING_00));`
257
258			`sum = spu_mul(sum, sqrt2pi);`
259			`sum = spu_mul(sum, _powd2(x, spu_sub(x, halfd)));`
260			`sresult = spu_mul(sum, _expd2(spu_or(x, signbit)));`
261
262			`/*`
263			`* Choose rational approximation or Stirling's result.`
264			`*/`
265			`result = spu_sel(rresult, sresult, gt9p9);`
266
267
268			`result = spu_sel(result, inf, gt200);`
269
270			`/* For x < 0, use:`
271			`*`
272			`* gamma(x) = pi/(xgamma(-x)sin(x*pi))`
273			`* or`
274			`* gamma(x) = pi/(gamma(1 - x)sin(xpi))`
275			`*/`
276			`nresult = _divd2(pi, spu_mul(x, spu_mul(result, _sind2(spu_mul(x, pi)))));`
277			`result = spu_sel(nresult, result, gt0);`
278
279			`/*`
280			`* x = non-positive integer, return NaN.`
281			`*/`
282			`result = spu_sel(result, nan, spu_andc(spu_cmpeq(x, xtrunc), gt0));`
283
284
285			`return result;`
286			`}`
287
288			`#endif /* _TGAMMAD2_H_ */`
289			`#endif /* __SPU__ */`