/src/gmp-6.2.1/mpn/toom43_mul.c

Source
/* mpn_toom43_mul -- Multiply {ap,an} and {bp,bn} where an is nominally 4/3
   times as large as bn.  Or more accurately, bn < an < 2 bn.

   Contributed to the GNU project by Marco Bodrato.

   The idea of applying toom to unbalanced multiplication is due to Marco
   Bodrato and Alberto Zanoni.

   THE FUNCTION IN THIS FILE IS INTERNAL WITH A MUTABLE INTERFACE.  IT IS ONLY
   SAFE TO REACH IT THROUGH DOCUMENTED INTERFACES.  IN FACT, IT IS ALMOST
   GUARANTEED THAT IT WILL CHANGE OR DISAPPEAR IN A FUTURE GNU MP RELEASE.

Copyright 2009 Free Software Foundation, Inc.

This file is part of the GNU MP Library.

The GNU MP Library is free software; you can redistribute it and/or modify
it under the terms of either:

  * the GNU Lesser General Public License as published by the Free
    Software Foundation; either version 3 of the License, or (at your
    option) any later version.

or

  * the GNU General Public License as published by the Free Software
    Foundation; either version 2 of the License, or (at your option) any
    later version.

or both in parallel, as here.

The GNU MP Library is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
for more details.

You should have received copies of the GNU General Public License and the
GNU Lesser General Public License along with the GNU MP Library.  If not,
see https://www.gnu.org/licenses/.  */


#include "gmp-impl.h"

/* Evaluate in: -2, -1, 0, +1, +2, +inf

  <-s-><--n--><--n--><--n-->
   ___ ______ ______ ______
  |a3_|___a2_|___a1_|___a0_|
  |_b2_|___b1_|___b0_|
  <-t--><--n--><--n-->

  v0  =  a0             * b0          #   A(0)*B(0)
  v1  = (a0+ a1+ a2+ a3)*(b0+ b1+ b2) #   A(1)*B(1)      ah  <= 3  bh <= 2
  vm1 = (a0- a1+ a2- a3)*(b0- b1+ b2) #  A(-1)*B(-1)    |ah| <= 1 |bh|<= 1
  v2  = (a0+2a1+4a2+8a3)*(b0+2b1+4b2) #   A(2)*B(2)      ah  <= 14 bh <= 6
  vm2 = (a0-2a1+4a2-8a3)*(b0-2b1+4b2) #  A(-2)*B(-2)    |ah| <= 9 |bh|<= 4
  vinf=              a3 *         b2  # A(inf)*B(inf)
*/

void
mpn_toom43_mul (mp_ptr pp,
    mp_srcptr ap, mp_size_t an,
    mp_srcptr bp, mp_size_t bn, mp_ptr scratch)
{
  mp_size_t n, s, t;
  enum toom6_flags flags;
  mp_limb_t cy;

#define a0  ap
#define a1  (ap + n)
#define a2  (ap + 2 * n)
#define a3  (ap + 3 * n)
#define b0  bp
#define b1  (bp + n)
#define b2  (bp + 2 * n)

  n = 1 + (3 * an >= 4 * bn ? (an - 1) >> 2 : (bn - 1) / (size_t) 3);

  s = an - 3 * n;
  t = bn - 2 * n;

  ASSERT (0 < s && s <= n);
  ASSERT (0 < t && t <= n);

  /* This is true whenever an >= 25 or bn >= 19, I think. It
     guarantees that we can fit 5 values of size n+1 in the product
     area. */
  ASSERT (s+t >= 5);

#define v0    pp        /* 2n */
#define vm1   (scratch)        /* 2n+1 */
#define v1    (pp + 2*n)      /* 2n+1 */
#define vm2   (scratch + 2 * n + 1)    /* 2n+1 */
#define v2    (scratch + 4 * n + 2)    /* 2n+1 */
#define vinf  (pp + 5 * n)      /* s+t */
#define bs1    pp        /* n+1 */
#define bsm1  (scratch + 2 * n + 2)    /* n+1 */
#define asm1  (scratch + 3 * n + 3)    /* n+1 */
#define asm2  (scratch + 4 * n + 4)    /* n+1 */
#define bsm2  (pp + n + 1)      /* n+1 */
#define bs2   (pp + 2 * n + 2)      /* n+1 */
#define as2   (pp + 3 * n + 3)      /* n+1 */
#define as1   (pp + 4 * n + 4)      /* n+1 */

  /* Total sccratch need is 6 * n + 3 + 1; we allocate one extra
     limb, because products will overwrite 2n+2 limbs. */

#define a0a2  scratch
#define b0b2  scratch
#define a1a3  asm1
#define b1d   bsm1

  /* Compute as2 and asm2.  */
  flags = (enum toom6_flags) (toom6_vm2_neg & mpn_toom_eval_dgr3_pm2 (as2, asm2, ap, n, s, a1a3));

  /* Compute bs2 and bsm2.  */
  b1d[n] = mpn_lshift (b1d, b1, n, 1);      /*       2b1      */
  cy  = mpn_lshift (b0b2, b2, t, 2);      /*  4b2           */
  cy += mpn_add_n (b0b2, b0b2, b0, t);     /*  4b2      + b0 */
  if (t != n)
    cy = mpn_add_1 (b0b2 + t, b0 + t, n - t, cy);
  b0b2[n] = cy;

#if HAVE_NATIVE_mpn_add_n_sub_n
  if (mpn_cmp (b0b2, b1d, n+1) < 0)
    {
      mpn_add_n_sub_n (bs2, bsm2, b1d, b0b2, n+1);
      flags = (enum toom6_flags) (flags ^ toom6_vm2_neg);
    }
  else
    {
      mpn_add_n_sub_n (bs2, bsm2, b0b2, b1d, n+1);
    }
#else
  mpn_add_n (bs2, b0b2, b1d, n+1);
  if (mpn_cmp (b0b2, b1d, n+1) < 0)
    {
      mpn_sub_n (bsm2, b1d, b0b2, n+1);
      flags = (enum toom6_flags) (flags ^ toom6_vm2_neg);
    }
  else
    {
      mpn_sub_n (bsm2, b0b2, b1d, n+1);
    }
#endif

  /* Compute as1 and asm1.  */
  flags = (enum toom6_flags) (flags ^ (toom6_vm1_neg & mpn_toom_eval_dgr3_pm1 (as1, asm1, ap, n, s, a0a2)));

  /* Compute bs1 and bsm1.  */
  bsm1[n] = mpn_add (bsm1, b0, n, b2, t);
#if HAVE_NATIVE_mpn_add_n_sub_n
  if (bsm1[n] == 0 && mpn_cmp (bsm1, b1, n) < 0)
    {
      cy = mpn_add_n_sub_n (bs1, bsm1, b1, bsm1, n);
      bs1[n] = cy >> 1;
      flags = (enum toom6_flags) (flags ^ toom6_vm1_neg);
    }
  else
    {
      cy = mpn_add_n_sub_n (bs1, bsm1, bsm1, b1, n);
      bs1[n] = bsm1[n] + (cy >> 1);
      bsm1[n]-= cy & 1;
    }
#else
  bs1[n] = bsm1[n] + mpn_add_n (bs1, bsm1, b1, n);
  if (bsm1[n] == 0 && mpn_cmp (bsm1, b1, n) < 0)
    {
      mpn_sub_n (bsm1, b1, bsm1, n);
      flags = (enum toom6_flags) (flags ^ toom6_vm1_neg);
    }
  else
    {
      bsm1[n] -= mpn_sub_n (bsm1, bsm1, b1, n);
    }
#endif

  ASSERT (as1[n] <= 3);
  ASSERT (bs1[n] <= 2);
  ASSERT (asm1[n] <= 1);
  ASSERT (bsm1[n] <= 1);
  ASSERT (as2[n] <=14);
  ASSERT (bs2[n] <= 6);
  ASSERT (asm2[n] <= 9);
  ASSERT (bsm2[n] <= 4);

  /* vm1, 2n+1 limbs */
  mpn_mul_n (vm1, asm1, bsm1, n+1);  /* W4 */

  /* vm2, 2n+1 limbs */
  mpn_mul_n (vm2, asm2, bsm2, n+1);  /* W2 */

  /* v2, 2n+1 limbs */
  mpn_mul_n (v2, as2, bs2, n+1);  /* W1 */

  /* v1, 2n+1 limbs */
  mpn_mul_n (v1, as1, bs1, n+1);  /* W3 */

  /* vinf, s+t limbs */   /* W0 */
  if (s > t)  mpn_mul (vinf, a3, s, b2, t);
  else        mpn_mul (vinf, b2, t, a3, s);

  /* v0, 2n limbs */
  mpn_mul_n (v0, ap, bp, n);  /* W5 */

  mpn_toom_interpolate_6pts (pp, n, flags, vm1, vm2, v2, t + s);

#undef v0
#undef vm1
#undef v1
#undef vm2
#undef v2
#undef vinf
#undef bs1
#undef bs2
#undef bsm1
#undef bsm2
#undef asm1
#undef asm2
/* #undef as1 */
/* #undef as2 */
#undef a0a2
#undef b0b2
#undef a1a3
#undef b1d
#undef a0
#undef a1
#undef a2
#undef a3
#undef b0
#undef b1
#undef b2
}

Coverage Report

Created: 2024-02-25 06:16

Line	Count	Source
1		/* mpn_toom43_mul -- Multiply {ap,an} and {bp,bn} where an is nominally 4/3
2		times as large as bn. Or more accurately, bn < an < 2 bn.
3
4		Contributed to the GNU project by Marco Bodrato.
5
6		The idea of applying toom to unbalanced multiplication is due to Marco
7		Bodrato and Alberto Zanoni.
8
9		THE FUNCTION IN THIS FILE IS INTERNAL WITH A MUTABLE INTERFACE. IT IS ONLY
10		SAFE TO REACH IT THROUGH DOCUMENTED INTERFACES. IN FACT, IT IS ALMOST
11		GUARANTEED THAT IT WILL CHANGE OR DISAPPEAR IN A FUTURE GNU MP RELEASE.
12
13		Copyright 2009 Free Software Foundation, Inc.
14
15		This file is part of the GNU MP Library.
16
17		The GNU MP Library is free software; you can redistribute it and/or modify
18		it under the terms of either:
19
20		* the GNU Lesser General Public License as published by the Free
21		Software Foundation; either version 3 of the License, or (at your
22		option) any later version.
23
24		or
25
26		* the GNU General Public License as published by the Free Software
27		Foundation; either version 2 of the License, or (at your option) any
28		later version.
29
30		or both in parallel, as here.
31
32		The GNU MP Library is distributed in the hope that it will be useful, but
33		WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
34		or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
35		for more details.
36
37		You should have received copies of the GNU General Public License and the
38		GNU Lesser General Public License along with the GNU MP Library. If not,
39		see https://www.gnu.org/licenses/. */
40
41
42		#include "gmp-impl.h"
43
44		/* Evaluate in: -2, -1, 0, +1, +2, +inf
45
46		<-s-><--n--><--n--><--n-->
47		___ ______ ______ ______
48		\|a3_\|___a2_\|___a1_\|___a0_\|
49		\|_b2_\|___b1_\|___b0_\|
50		<-t--><--n--><--n-->
51
52		v0 = a0 * b0 # A(0)*B(0)
53		v1 = (a0+ a1+ a2+ a3)(b0+ b1+ b2) # A(1)B(1) ah <= 3 bh <= 2
54		vm1 = (a0- a1+ a2- a3)(b0- b1+ b2) # A(-1)B(-1) \|ah\| <= 1 \|bh\|<= 1
55		v2 = (a0+2a1+4a2+8a3)(b0+2b1+4b2) # A(2)B(2) ah <= 14 bh <= 6
56		vm2 = (a0-2a1+4a2-8a3)(b0-2b1+4b2) # A(-2)B(-2) \|ah\| <= 9 \|bh\|<= 4
57		vinf= a3 * b2 # A(inf)*B(inf)
58		*/
59
60		void
61		mpn_toom43_mul (mp_ptr pp,
62		mp_srcptr ap, mp_size_t an,
63		mp_srcptr bp, mp_size_t bn, mp_ptr scratch)
64	772	{
65	772	mp_size_t n, s, t;
66	772	enum toom6_flags flags;
67	772	mp_limb_t cy;
68
69	772	#define a0 ap
70	772	#define a1 (ap + n)
71	772	#define a2 (ap + 2 * n)
72	772	#define a3 (ap + 3 * n)
73	2.31k	#define b0 bp
74	3.08k	#define b1 (bp + n)
75	2.31k	#define b2 (bp + 2 * n)
76
77	772	n = 1 + (3 * an >= 4 * bn ? (an - 1) >> 2 : (bn - 1) / (size_t) 3);
78
79	772	s = an - 3 * n;
80	772	t = bn - 2 * n;
81
82	772	ASSERT (0 < s && s <= n);
83	772	ASSERT (0 < t && t <= n);
84
85		/* This is true whenever an >= 25 or bn >= 19, I think. It
86		guarantees that we can fit 5 values of size n+1 in the product
87		area. */
88	772	ASSERT (s+t >= 5);
89
90	772	#define v0 pp /* 2n */
91	1.54k	#define vm1 (scratch) /* 2n+1 */
92	772	#define v1 (pp + 2n) / 2n+1 */
93	1.54k	#define vm2 (scratch + 2 * n + 1) /* 2n+1 */
94	1.54k	#define v2 (scratch + 4 * n + 2) /* 2n+1 */
95	772	#define vinf (pp + 5 * n) /* s+t */
96	2.31k	#define bs1 pp /* n+1 */
97	11.1k	#define bsm1 (scratch + 2 * n + 2) /* n+1 */
98	2.31k	#define asm1 (scratch + 3 * n + 3) /* n+1 */
99	1.54k	#define asm2 (scratch + 4 * n + 4) /* n+1 */
100	1.54k	#define bsm2 (pp + n + 1) /* n+1 */
101	1.54k	#define bs2 (pp + 2 * n + 2) /* n+1 */
102	1.54k	#define as2 (pp + 3 * n + 3) /* n+1 */
103	1.54k	#define as1 (pp + 4 * n + 4) /* n+1 */
104
105		/* Total sccratch need is 6 * n + 3 + 1; we allocate one extra
106		limb, because products will overwrite 2n+2 limbs. */
107
108	772	#define a0a2 scratch
109	6.17k	#define b0b2 scratch
110	772	#define a1a3 asm1
111	3.86k	#define b1d bsm1
112
113		/* Compute as2 and asm2. */
114	772	flags = (enum toom6_flags) (toom6_vm2_neg & mpn_toom_eval_dgr3_pm2 (as2, asm2, ap, n, s, a1a3));
115
116		/* Compute bs2 and bsm2. */
117	772	b1d[n] = mpn_lshift (b1d, b1, n, 1); /* 2b1 */
118	772	cy = mpn_lshift (b0b2, b2, t, 2); /* 4b2 */
119	772	cy += mpn_add_n (b0b2, b0b2, b0, t); /* 4b2 + b0 */
120	772	if (t != n)
121	772	cy = mpn_add_1 (b0b2 + t, b0 + t, n - t, cy);
122	772	b0b2[n] = cy;
123
124		#if HAVE_NATIVE_mpn_add_n_sub_n
125		if (mpn_cmp (b0b2, b1d, n+1) < 0)
126		{
127		mpn_add_n_sub_n (bs2, bsm2, b1d, b0b2, n+1);
128		flags = (enum toom6_flags) (flags ^ toom6_vm2_neg);
129		}
130		else
131		{
132		mpn_add_n_sub_n (bs2, bsm2, b0b2, b1d, n+1);
133		}
134		#else
135	772	mpn_add_n (bs2, b0b2, b1d, n+1);
136	772	if (mpn_cmp (b0b2, b1d, n+1) < 0)
137	635	{
138	635	mpn_sub_n (bsm2, b1d, b0b2, n+1);
139	635	flags = (enum toom6_flags) (flags ^ toom6_vm2_neg);
140	635	}
141	137	else
142	137	{
143	137	mpn_sub_n (bsm2, b0b2, b1d, n+1);
144	137	}
145	772	#endif
146
147		/* Compute as1 and asm1. */
148	772	flags = (enum toom6_flags) (flags ^ (toom6_vm1_neg & mpn_toom_eval_dgr3_pm1 (as1, asm1, ap, n, s, a0a2)));
149
150		/* Compute bs1 and bsm1. */
151	772	bsm1[n] = mpn_add (bsm1, b0, n, b2, t);
152		#if HAVE_NATIVE_mpn_add_n_sub_n
153		if (bsm1[n] == 0 && mpn_cmp (bsm1, b1, n) < 0)
154		{
155		cy = mpn_add_n_sub_n (bs1, bsm1, b1, bsm1, n);
156		bs1[n] = cy >> 1;
157		flags = (enum toom6_flags) (flags ^ toom6_vm1_neg);
158		}
159		else
160		{
161		cy = mpn_add_n_sub_n (bs1, bsm1, bsm1, b1, n);
162		bs1[n] = bsm1[n] + (cy >> 1);
163		bsm1[n]-= cy & 1;
164		}
165		#else
166	772	bs1[n] = bsm1[n] + mpn_add_n (bs1, bsm1, b1, n);
167	772	if (bsm1[n] == 0 && mpn_cmp (bsm1, b1, n) < 0)
168	398	{
169	398	mpn_sub_n (bsm1, b1, bsm1, n);
170	398	flags = (enum toom6_flags) (flags ^ toom6_vm1_neg);
171	398	}
172	374	else
173	374	{
174	374	bsm1[n] -= mpn_sub_n (bsm1, bsm1, b1, n);
175	374	}
176	772	#endif
177
178	772	ASSERT (as1[n] <= 3);
179	772	ASSERT (bs1[n] <= 2);
180	772	ASSERT (asm1[n] <= 1);
181	772	ASSERT (bsm1[n] <= 1);
182	772	ASSERT (as2[n] <=14);
183	772	ASSERT (bs2[n] <= 6);
184	772	ASSERT (asm2[n] <= 9);
185	772	ASSERT (bsm2[n] <= 4);
186
187		/* vm1, 2n+1 limbs */
188	772	mpn_mul_n (vm1, asm1, bsm1, n+1); /* W4 */
189
190		/* vm2, 2n+1 limbs */
191	772	mpn_mul_n (vm2, asm2, bsm2, n+1); /* W2 */
192
193		/* v2, 2n+1 limbs */
194	772	mpn_mul_n (v2, as2, bs2, n+1); /* W1 */
195
196		/* v1, 2n+1 limbs */
197	772	mpn_mul_n (v1, as1, bs1, n+1); /* W3 */
198
199		/* vinf, s+t limbs / / W0 */
200	772	if (s > t) mpn_mul (vinf, a3, s, b2, t);
201	89	else mpn_mul (vinf, b2, t, a3, s);
202
203		/* v0, 2n limbs */
204	772	mpn_mul_n (v0, ap, bp, n); /* W5 */
205
206	772	mpn_toom_interpolate_6pts (pp, n, flags, vm1, vm2, v2, t + s);
207
208	772	#undef v0
209	772	#undef vm1
210	772	#undef v1
211	772	#undef vm2
212	772	#undef v2
213	772	#undef vinf
214	772	#undef bs1
215	772	#undef bs2
216	772	#undef bsm1
217	772	#undef bsm2
218	772	#undef asm1
219	772	#undef asm2
220		/* #undef as1 */
221		/* #undef as2 */
222	772	#undef a0a2
223	772	#undef b0b2
224	772	#undef a1a3
225	772	#undef b1d
226	772	#undef a0
227	772	#undef a1
228	772	#undef a2
229	772	#undef a3
230	772	#undef b0
231	772	#undef b1
232	772	#undef b2
233	772	}