lgamma_neg.c source code [glibc/sysdeps/ieee754/dbl-64/lgamma_neg.c]

1	/ lgamma expanding around zeros.*
2	Copyright (C) 2015-2022 Free Software Foundation, Inc.
3	This file is part of the GNU C Library.
4
5	The GNU C Library is free software; you can redistribute it and/or
6	modify it under the terms of the GNU Lesser General Public
7	License as published by the Free Software Foundation; either
8	version 2.1 of the License, or (at your option) any later version.
9
10	The GNU C Library is distributed in the hope that it will be useful,
11	but WITHOUT ANY WARRANTY; without even the implied warranty of
12	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
13	Lesser General Public License for more details.
14
15	You should have received a copy of the GNU Lesser General Public
16	License along with the GNU C Library; if not, see
17	<https://www.gnu.org/licenses/>. /*
18
19	#include <float.h>
20	#include <math.h>
21	#include <math-narrow-eval.h>
22	#include <math_private.h>
23	#include <fenv_private.h>
24
25	static const double lgamma_zeros[][`2`] =
26	{
27	{ -`0x2.74ff92c01f0d8p+0`, -`0x2.abec9f315f1ap-56` },
28	{ -`0x2.bf6821437b202p+0`, `0x6.866a5b4b9be14p-56` },
29	{ -`0x3.24c1b793cb35ep+0`, -`0xf.b8be699ad3d98p-56` },
30	{ -`0x3.f48e2a8f85fcap+0`, -`0x1.70d4561291237p-56` },
31	{ -`0x4.0a139e1665604p+0`, `0xf.3c60f4f21e7fp-56` },
32	{ -`0x4.fdd5de9bbabf4p+0`, `0xa.ef2f55bf89678p-56` },
33	{ -`0x5.021a95fc2db64p+0`, -`0x3.2a4c56e595394p-56` },
34	{ -`0x5.ffa4bd647d034p+0`, -`0x1.7dd4ed62cbd32p-52` },
35	{ -`0x6.005ac9625f234p+0`, `0x4.9f83d2692e9c8p-56` },
36	{ -`0x6.fff2fddae1bcp+0`, `0xc.29d949a3dc03p-60` },
37	{ -`0x7.000cff7b7f87cp+0`, `0x1.20bb7d2324678p-52` },
38	{ -`0x7.fffe5fe05673cp+0`, -`0x3.ca9e82b522b0cp-56` },
39	{ -`0x8.0001a01459fc8p+0`, -`0x1.f60cb3cec1cedp-52` },
40	{ -`0x8.ffffd1c425e8p+0`, -`0xf.fc864e9574928p-56` },
41	{ -`0x9.00002e3bb47d8p+0`, -`0x6.d6d843fedc35p-56` },
42	{ -`0x9.fffffb606bep+0`, `0x2.32f9d51885afap-52` },
43	{ -`0xa.0000049f93bb8p+0`, -`0x1.927b45d95e154p-52` },
44	{ -`0xa.ffffff9466eap+0`, `0xe.4c92532d5243p-56` },
45	{ -`0xb.0000006b9915p+0`, -`0x3.15d965a6ffea4p-52` },
46	{ -`0xb.fffffff708938p+0`, -`0x7.387de41acc3d4p-56` },
47	{ -`0xc.00000008f76c8p+0`, `0x8.cea983f0fdafp-56` },
48	{ -`0xc.ffffffff4f6ep+0`, `0x3.09e80685a0038p-52` },
49	{ -`0xd.00000000b092p+0`, -`0x3.09c06683dd1bap-52` },
50	{ -`0xd.fffffffff3638p+0`, `0x3.a5461e7b5c1f6p-52` },
51	{ -`0xe.000000000c9c8p+0`, -`0x3.a545e94e75ec6p-52` },
52	{ -`0xe.ffffffffff29p+0`, `0x3.f9f399fb10cfcp-52` },
53	{ -`0xf.0000000000d7p+0`, -`0x3.f9f399bd0e42p-52` },
54	{ -`0xf.fffffffffff28p+0`, -`0xc.060c6621f513p-56` },
55	{ -`0x1.000000000000dp+4`, -`0x7.3f9f399da1424p-52` },
56	{ -`0x1.0ffffffffffffp+4`, -`0x3.569c47e7a93e2p-52` },
57	{ -`0x1.1000000000001p+4`, `0x3.569c47e7a9778p-52` },
58	{ -`0x1.2p+4`, `0xb.413c31dcbecdp-56` },
59	{ -`0x1.2p+4`, -`0xb.413c31dcbeca8p-56` },
60	{ -`0x1.3p+4`, `0x9.7a4da340a0ab8p-60` },
61	{ -`0x1.3p+4`, -`0x9.7a4da340a0ab8p-60` },
62	{ -`0x1.4p+4`, `0x7.950ae90080894p-64` },
63	{ -`0x1.4p+4`, -`0x7.950ae90080894p-64` },
64	{ -`0x1.5p+4`, `0x5.c6e3bdb73d5c8p-68` },
65	{ -`0x1.5p+4`, -`0x5.c6e3bdb73d5c8p-68` },
66	{ -`0x1.6p+4`, `0x4.338e5b6dfe14cp-72` },
67	{ -`0x1.6p+4`, -`0x4.338e5b6dfe14cp-72` },
68	{ -`0x1.7p+4`, `0x2.ec368262c7034p-76` },
69	{ -`0x1.7p+4`, -`0x2.ec368262c7034p-76` },
70	{ -`0x1.8p+4`, `0x1.f2cf01972f578p-80` },
71	{ -`0x1.8p+4`, -`0x1.f2cf01972f578p-80` },
72	{ -`0x1.9p+4`, `0x1.3f3ccdd165fa9p-84` },
73	{ -`0x1.9p+4`, -`0x1.3f3ccdd165fa9p-84` },
74	{ -`0x1.ap+4`, `0xc.4742fe35272dp-92` },
75	{ -`0x1.ap+4`, -`0xc.4742fe35272dp-92` },
76	{ -`0x1.bp+4`, `0x7.46ac70b733a8cp-96` },
77	{ -`0x1.bp+4`, -`0x7.46ac70b733a8cp-96` },
78	{ -`0x1.cp+4`, `0x4.2862898d42174p-100` },
79	};
80
81	static const double e_hi = `0x2.b7e151628aed2p+0`, e_lo = `0xa.6abf7158809dp-56`;
82
83	/ Coefficients B_2k / 2k(2k-1) of x^-(2k-1) in Stirling's*
84	approximation to lgamma function. /*
85
86	static const double lgamma_coeff[] =
87	{
88	`0x1.5555555555555p-4`,
89	-`0xb.60b60b60b60b8p-12`,
90	`0x3.4034034034034p-12`,
91	-`0x2.7027027027028p-12`,
92	`0x3.72a3c5631fe46p-12`,
93	-`0x7.daac36664f1f4p-12`,
94	`0x1.a41a41a41a41ap-8`,
95	-`0x7.90a1b2c3d4e6p-8`,
96	`0x2.dfd2c703c0dp-4`,
97	-`0x1.6476701181f3ap+0`,
98	`0xd.672219167003p+0`,
99	-`0x9.cd9292e6660d8p+4`,
100	};
101
102	#define NCOEFF (sizeof (lgamma_coeff) / sizeof (lgamma_coeff[0]))
103
104	/ Polynomial approximations to (\|gamma(x)\|-1)(x-n)/(x-x0), where n is*
105	the integer end-point of the half-integer interval containing x and
106	x0 is the zero of lgamma in that half-integer interval. Each
107	polynomial is expressed in terms of x-xm, where xm is the midpoint
108	of the interval for which the polynomial applies. /*
109
110	static const double poly_coeff[] =
111	{
112	/ Interval [-2.125, -2] (polynomial degree 10). /
113	-`0x1.0b71c5c54d42fp+0`,
114	-`0xc.73a1dc05f3758p-4`,
115	-`0x1.ec84140851911p-4`,
116	-`0xe.37c9da23847e8p-4`,
117	-`0x1.03cd87cdc0ac6p-4`,
118	-`0xe.ae9aedce12eep-4`,
119	`0x9.b11a1780cfd48p-8`,
120	-`0xe.f25fc460bdebp-4`,
121	`0x2.6e984c61ca912p-4`,
122	-`0xf.83fea1c6d35p-4`,
123	`0x4.760c8c8909758p-4`,
124	/ Interval [-2.25, -2.125] (polynomial degree 11). /
125	-`0xf.2930890d7d678p-4`,
126	-`0xc.a5cfde054eaa8p-4`,
127	`0x3.9c9e0fdebd99cp-4`,
128	-`0x1.02a5ad35619d9p+0`,
129	`0x9.6e9b1167c164p-4`,
130	-`0x1.4d8332eba090ap+0`,
131	`0x1.1c0c94b1b2b6p+0`,
132	-`0x1.c9a70d138c74ep+0`,
133	`0x1.d7d9cf1d4c196p+0`,
134	-`0x2.91fbf4cd6abacp+0`,
135	`0x2.f6751f74b8ff8p+0`,
136	-`0x3.e1bb7b09e3e76p+0`,
137	/ Interval [-2.375, -2.25] (polynomial degree 12). /
138	-`0xd.7d28d505d618p-4`,
139	-`0xe.69649a3040958p-4`,
140	`0xb.0d74a2827cd6p-4`,
141	-`0x1.924b09228a86ep+0`,
142	`0x1.d49b12bcf6175p+0`,
143	-`0x3.0898bb530d314p+0`,
144	`0x4.207a6be8fda4cp+0`,
145	-`0x6.39eef56d4e9p+0`,
146	`0x8.e2e42acbccec8p+0`,
147	-`0xd.0d91c1e596a68p+0`,
148	`0x1.2e20d7099c585p+4`,
149	-`0x1.c4eb6691b4ca9p+4`,
150	`0x2.96a1a11fd85fep+4`,
151	/ Interval [-2.5, -2.375] (polynomial degree 13). /
152	-`0xb.74ea1bcfff948p-4`,
153	-`0x1.2a82bd590c376p+0`,
154	`0x1.88020f828b81p+0`,
155	-`0x3.32279f040d7aep+0`,
156	`0x5.57ac8252ce868p+0`,
157	-`0x9.c2aedd093125p+0`,
158	`0x1.12c132716e94cp+4`,
159	-`0x1.ea94dfa5c0a6dp+4`,
160	`0x3.66b61abfe858cp+4`,
161	-`0x6.0cfceb62a26e4p+4`,
162	`0xa.beeba09403bd8p+4`,
163	-`0x1.3188d9b1b288cp+8`,
164	`0x2.37f774dd14c44p+8`,
165	-`0x3.fdf0a64cd7136p+8`,
166	/ Interval [-2.625, -2.5] (polynomial degree 13). /
167	-`0x3.d10108c27ebbp-4`,
168	`0x1.cd557caff7d2fp+0`,
169	`0x3.819b4856d36cep+0`,
170	`0x6.8505cbacfc42p+0`,
171	`0xb.c1b2e6567a4dp+0`,
172	`0x1.50a53a3ce6c73p+4`,
173	`0x2.57adffbb1ec0cp+4`,
174	`0x4.2b15549cf400cp+4`,
175	`0x7.698cfd82b3e18p+4`,
176	`0xd.2decde217755p+4`,
177	`0x1.7699a624d07b9p+8`,
178	`0x2.98ecf617abbfcp+8`,
179	`0x4.d5244d44d60b4p+8`,
180	`0x8.e962bf7395988p+8`,
181	/ Interval [-2.75, -2.625] (polynomial degree 12). /
182	-`0x6.b5d252a56e8a8p-4`,
183	`0x1.28d60383da3a6p+0`,
184	`0x1.db6513ada89bep+0`,
185	`0x2.e217118fa8c02p+0`,
186	`0x4.450112c651348p+0`,
187	`0x6.4af990f589b8cp+0`,
188	`0x9.2db5963d7a238p+0`,
189	`0xd.62c03647da19p+0`,
190	`0x1.379f81f6416afp+4`,
191	`0x1.c5618b4fdb96p+4`,
192	`0x2.9342d0af2ac4ep+4`,
193	`0x3.d9cdf56d2b186p+4`,
194	`0x5.ab9f91d5a27a4p+4`,
195	/ Interval [-2.875, -2.75] (polynomial degree 11). /
196	-`0x8.a41b1e4f36ff8p-4`,
197	`0xc.da87d3b69dbe8p-4`,
198	`0x1.1474ad5c36709p+0`,
199	`0x1.761ecb90c8c5cp+0`,
200	`0x1.d279bff588826p+0`,
201	`0x2.4e5d003fb36a8p+0`,
202	`0x2.d575575566842p+0`,
203	`0x3.85152b0d17756p+0`,
204	`0x4.5213d921ca13p+0`,
205	`0x5.55da7dfcf69c4p+0`,
206	`0x6.acef729b9404p+0`,
207	`0x8.483cc21dd0668p+0`,
208	/ Interval [-3, -2.875] (polynomial degree 11). /
209	-`0xa.046d667e468f8p-4`,
210	`0x9.70b88dcc006cp-4`,
211	`0xa.a8a39421c94dp-4`,
212	`0xd.2f4d1363f98ep-4`,
213	`0xd.ca9aa19975b7p-4`,
214	`0xf.cf09c2f54404p-4`,
215	`0x1.04b1365a9adfcp+0`,
216	`0x1.22b54ef213798p+0`,
217	`0x1.2c52c25206bf5p+0`,
218	`0x1.4aa3d798aace4p+0`,
219	`0x1.5c3f278b504e3p+0`,
220	`0x1.7e08292cc347bp+0`,
221	};
222
223	static const size_t poly_deg[] =
224	{
225	`10`,
226	`11`,
227	`12`,
228	`13`,
229	`13`,
230	`12`,
231	`11`,
232	`11`,
233	};
234
235	static const size_t poly_end[] =
236	{
237	`10`,
238	`22`,
239	`35`,
240	`49`,
241	`63`,
242	`76`,
243	`88`,
244	`100`,
245	};
246
247	/ Compute sin (pi * X) for -0.25 <= X <= 0.5. /
248
249	static double
250	lg_sinpi (double x)
251	{
252	if (x <= `0.25`)
253	return __sin (M_PI * x);
254	else
255	return __cos (M_PI * (`0.5` - x));
256	}
257
258	/ Compute cos (pi * X) for -0.25 <= X <= 0.5. /
259
260	static double
261	lg_cospi (double x)
262	{
263	if (x <= `0.25`)
264	return __cos (M_PI * x);
265	else
266	return __sin (M_PI * (`0.5` - x));
267	}
268
269	/ Compute cot (pi * X) for -0.25 <= X <= 0.5. /
270
271	static double
272	lg_cotpi (double x)
273	{
274	return lg_cospi (x) / lg_sinpi (x);
275	}
276
277	/ Compute lgamma of a negative argument -28 < X < -2, setting*
278	SIGNGAMP accordingly. /
279
280	double
281	__lgamma_neg (double x, int *signgamp)
282	{
283	/ Determine the half-integer region X lies in, handle exact*
284	integers and determine the sign of the result. /*
285	int i = floor (-`2` * x);
286	if ((i & `1`) == `0` && i == -`2` * x)
287	return `1.0` / `0.0`;
288	double xn = ((i & `1`) == `0` ? -i / `2` : (-i - `1`) / `2`);
289	i -= `4`;
290	*signgamp = ((i & `2`) == `0` ? -`1` : `1`);
291
292	SET_RESTORE_ROUND (FE_TONEAREST);
293
294	/ Expand around the zero X0 = X0_HI + X0_LO. /
295	double x0_hi = lgamma_zeros[i][`0`], x0_lo = lgamma_zeros[i][`1`];
296	double xdiff = x - x0_hi - x0_lo;
297
298	/ For arguments in the range -3 to -2, use polynomial*
299	approximations to an adjusted version of the gamma function. /*
300	if (i < `2`)
301	{
302	int j = floor (-`8` * x) - `16`;
303	double xm = (-`33` - `2` * j) * `0.0625`;
304	double x_adj = x - xm;
305	size_t deg = poly_deg[j];
306	size_t end = poly_end[j];
307	double g = poly_coeff[end];
308	for (size_t j = `1`; j <= deg; j++)
309	g = g * x_adj + poly_coeff[end - j];
310	return __log1p (x: g * xdiff / (x - xn));
311	}
312
313	/ The result we want is log (sinpi (X0) / sinpi (X))*
314	+ log (gamma (1 - X0) / gamma (1 - X)). /*
315	double x_idiff = fabs (x: xn - x), x0_idiff = fabs (x: xn - x0_hi - x0_lo);
316	double log_sinpi_ratio;
317	if (x0_idiff < x_idiff * `0.5`)
318	/ Use log not log1p to avoid inaccuracy from log1p of arguments*
319	close to -1. /*
320	log_sinpi_ratio = __ieee754_log (lg_sinpi (x: x0_idiff)
321	/ lg_sinpi (x: x_idiff));
322	else
323	{
324	/ Use log1p not log to avoid inaccuracy from log of arguments*
325	close to 1. X0DIFF2 has positive sign if X0 is further from
326	XN than X is from XN, negative sign otherwise. /*
327	double x0diff2 = ((i & `1`) == `0` ? xdiff : -xdiff) * `0.5`;
328	double sx0d2 = lg_sinpi (x: x0diff2);
329	double cx0d2 = lg_cospi (x: x0diff2);
330	log_sinpi_ratio = __log1p (x: `2` * sx0d2
331	* (-sx0d2 + cx0d2 * lg_cotpi (x: x_idiff)));
332	}
333
334	double log_gamma_ratio;
335	double y0 = math_narrow_eval (`1` - x0_hi);
336	double y0_eps = -x0_hi + (`1` - y0) - x0_lo;
337	double y = math_narrow_eval (`1` - x);
338	double y_eps = -x + (`1` - y);
339	/ We now wish to compute LOG_GAMMA_RATIO*
340	= log (gamma (Y0 + Y0_EPS) / gamma (Y + Y_EPS)). XDIFF
341	accurately approximates the difference Y0 + Y0_EPS - Y -
342	Y_EPS. Use Stirling's approximation. First, we may need to
343	adjust into the range where Stirling's approximation is
344	sufficiently accurate. /*
345	double log_gamma_adj = `0`;
346	if (i < `6`)
347	{
348	int n_up = (`7` - i) / `2`;
349	double ny0, ny0_eps, ny, ny_eps;
350	ny0 = math_narrow_eval (y0 + n_up);
351	ny0_eps = y0 - (ny0 - n_up) + y0_eps;
352	y0 = ny0;
353	y0_eps = ny0_eps;
354	ny = math_narrow_eval (y + n_up);
355	ny_eps = y - (ny - n_up) + y_eps;
356	y = ny;
357	y_eps = ny_eps;
358	double prodm1 = __lgamma_product (t: xdiff, x: y - n_up, x_eps: y_eps, n: n_up);
359	log_gamma_adj = -__log1p (x: prodm1);
360	}
361	double log_gamma_high
362	= (xdiff * __log1p (x: (y0 - e_hi - e_lo + y0_eps) / e_hi)
363	+ (y - `0.5` + y_eps) * __log1p (x: xdiff / y) + log_gamma_adj);
364	/ Compute the sum of (B_2k / 2k(2k-1))(Y0^-(2k-1) - Y^-(2k-1)). /
365	double y0r = `1` / y0, yr = `1` / y;
366	double y0r2 = y0r * y0r, yr2 = yr * yr;
367	double rdiff = -xdiff / (y * y0);
368	double bterm[NCOEFF];
369	double dlast = rdiff, elast = rdiff * yr * (yr + y0r);
370	bterm[`0`] = dlast * lgamma_coeff[`0`];
371	for (size_t j = `1`; j < NCOEFF; j++)
372	{
373	double dnext = dlast * y0r2 + elast;
374	double enext = elast * yr2;
375	bterm[j] = dnext * lgamma_coeff[j];
376	dlast = dnext;
377	elast = enext;
378	}
379	double log_gamma_low = `0`;
380	for (size_t j = `0`; j < NCOEFF; j++)
381	log_gamma_low += bterm[NCOEFF - `1` - j];
382	log_gamma_ratio = log_gamma_high + log_gamma_low;
383
384	return log_sinpi_ratio + log_gamma_ratio;
385	}
386

source code of glibc/sysdeps/ieee754/dbl-64/lgamma_neg.c