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annotate src/fftw-3.3.5/kernel/primes.c @ 169:223a55898ab9 tip default

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Add null config files
author Chris Cannam <cannam@all-day-breakfast.com>
date Mon, 02 Mar 2020 14:03:47 +0000
parents 7867fa7e1b6b
children
rev   line source
cannam@127 1 /*
cannam@127 2 * Copyright (c) 2003, 2007-14 Matteo Frigo
cannam@127 3 * Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology
cannam@127 4 *
cannam@127 5 * This program is free software; you can redistribute it and/or modify
cannam@127 6 * it under the terms of the GNU General Public License as published by
cannam@127 7 * the Free Software Foundation; either version 2 of the License, or
cannam@127 8 * (at your option) any later version.
cannam@127 9 *
cannam@127 10 * This program is distributed in the hope that it will be useful,
cannam@127 11 * but WITHOUT ANY WARRANTY; without even the implied warranty of
cannam@127 12 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
cannam@127 13 * GNU General Public License for more details.
cannam@127 14 *
cannam@127 15 * You should have received a copy of the GNU General Public License
cannam@127 16 * along with this program; if not, write to the Free Software
cannam@127 17 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
cannam@127 18 *
cannam@127 19 */
cannam@127 20
cannam@127 21
cannam@127 22 #include "ifftw.h"
cannam@127 23
cannam@127 24 /***************************************************************************/
cannam@127 25
cannam@127 26 /* Rader's algorithm requires lots of modular arithmetic, and if we
cannam@127 27 aren't careful we can have errors due to integer overflows. */
cannam@127 28
cannam@127 29 /* Compute (x * y) mod p, but watch out for integer overflows; we must
cannam@127 30 have 0 <= {x, y} < p.
cannam@127 31
cannam@127 32 If overflow is common, this routine is somewhat slower than
cannam@127 33 e.g. using 'long long' arithmetic. However, it has the advantage
cannam@127 34 of working when INT is 64 bits, and is also faster when overflow is
cannam@127 35 rare. FFTW calls this via the MULMOD macro, which further
cannam@127 36 optimizes for the case of small integers.
cannam@127 37 */
cannam@127 38
cannam@127 39 #define ADD_MOD(x, y, p) ((x) >= (p) - (y)) ? ((x) + ((y) - (p))) : ((x) + (y))
cannam@127 40
cannam@127 41 INT X(safe_mulmod)(INT x, INT y, INT p)
cannam@127 42 {
cannam@127 43 INT r;
cannam@127 44
cannam@127 45 if (y > x)
cannam@127 46 return X(safe_mulmod)(y, x, p);
cannam@127 47
cannam@127 48 A(0 <= y && x < p);
cannam@127 49
cannam@127 50 r = 0;
cannam@127 51 while (y) {
cannam@127 52 r = ADD_MOD(r, x*(y&1), p); y >>= 1;
cannam@127 53 x = ADD_MOD(x, x, p);
cannam@127 54 }
cannam@127 55
cannam@127 56 return r;
cannam@127 57 }
cannam@127 58
cannam@127 59 /***************************************************************************/
cannam@127 60
cannam@127 61 /* Compute n^m mod p, where m >= 0 and p > 0. If we really cared, we
cannam@127 62 could make this tail-recursive. */
cannam@127 63
cannam@127 64 INT X(power_mod)(INT n, INT m, INT p)
cannam@127 65 {
cannam@127 66 A(p > 0);
cannam@127 67 if (m == 0)
cannam@127 68 return 1;
cannam@127 69 else if (m % 2 == 0) {
cannam@127 70 INT x = X(power_mod)(n, m / 2, p);
cannam@127 71 return MULMOD(x, x, p);
cannam@127 72 }
cannam@127 73 else
cannam@127 74 return MULMOD(n, X(power_mod)(n, m - 1, p), p);
cannam@127 75 }
cannam@127 76
cannam@127 77 /* the following two routines were contributed by Greg Dionne. */
cannam@127 78 static INT get_prime_factors(INT n, INT *primef)
cannam@127 79 {
cannam@127 80 INT i;
cannam@127 81 INT size = 0;
cannam@127 82
cannam@127 83 A(n % 2 == 0); /* this routine is designed only for even n */
cannam@127 84 primef[size++] = (INT)2;
cannam@127 85 do {
cannam@127 86 n >>= 1;
cannam@127 87 } while ((n & 1) == 0);
cannam@127 88
cannam@127 89 if (n == 1)
cannam@127 90 return size;
cannam@127 91
cannam@127 92 for (i = 3; i * i <= n; i += 2)
cannam@127 93 if (!(n % i)) {
cannam@127 94 primef[size++] = i;
cannam@127 95 do {
cannam@127 96 n /= i;
cannam@127 97 } while (!(n % i));
cannam@127 98 }
cannam@127 99 if (n == 1)
cannam@127 100 return size;
cannam@127 101 primef[size++] = n;
cannam@127 102 return size;
cannam@127 103 }
cannam@127 104
cannam@127 105 INT X(find_generator)(INT p)
cannam@127 106 {
cannam@127 107 INT n, i, size;
cannam@127 108 INT primef[16]; /* smallest number = 32589158477190044730 > 2^64 */
cannam@127 109 INT pm1 = p - 1;
cannam@127 110
cannam@127 111 if (p == 2)
cannam@127 112 return 1;
cannam@127 113
cannam@127 114 size = get_prime_factors(pm1, primef);
cannam@127 115 n = 2;
cannam@127 116 for (i = 0; i < size; i++)
cannam@127 117 if (X(power_mod)(n, pm1 / primef[i], p) == 1) {
cannam@127 118 i = -1;
cannam@127 119 n++;
cannam@127 120 }
cannam@127 121 return n;
cannam@127 122 }
cannam@127 123
cannam@127 124 /* Return first prime divisor of n (It would be at best slightly faster to
cannam@127 125 search a static table of primes; there are 6542 primes < 2^16.) */
cannam@127 126 INT X(first_divisor)(INT n)
cannam@127 127 {
cannam@127 128 INT i;
cannam@127 129 if (n <= 1)
cannam@127 130 return n;
cannam@127 131 if (n % 2 == 0)
cannam@127 132 return 2;
cannam@127 133 for (i = 3; i*i <= n; i += 2)
cannam@127 134 if (n % i == 0)
cannam@127 135 return i;
cannam@127 136 return n;
cannam@127 137 }
cannam@127 138
cannam@127 139 int X(is_prime)(INT n)
cannam@127 140 {
cannam@127 141 return(n > 1 && X(first_divisor)(n) == n);
cannam@127 142 }
cannam@127 143
cannam@127 144 INT X(next_prime)(INT n)
cannam@127 145 {
cannam@127 146 while (!X(is_prime)(n)) ++n;
cannam@127 147 return n;
cannam@127 148 }
cannam@127 149
cannam@127 150 int X(factors_into)(INT n, const INT *primes)
cannam@127 151 {
cannam@127 152 for (; *primes != 0; ++primes)
cannam@127 153 while ((n % *primes) == 0)
cannam@127 154 n /= *primes;
cannam@127 155 return (n == 1);
cannam@127 156 }
cannam@127 157
cannam@127 158 /* integer square root. Return floor(sqrt(N)) */
cannam@127 159 INT X(isqrt)(INT n)
cannam@127 160 {
cannam@127 161 INT guess, iguess;
cannam@127 162
cannam@127 163 A(n >= 0);
cannam@127 164 if (n == 0) return 0;
cannam@127 165
cannam@127 166 guess = n; iguess = 1;
cannam@127 167
cannam@127 168 do {
cannam@127 169 guess = (guess + iguess) / 2;
cannam@127 170 iguess = n / guess;
cannam@127 171 } while (guess > iguess);
cannam@127 172
cannam@127 173 return guess;
cannam@127 174 }
cannam@127 175
cannam@127 176 static INT isqrt_maybe(INT n)
cannam@127 177 {
cannam@127 178 INT guess = X(isqrt)(n);
cannam@127 179 return guess * guess == n ? guess : 0;
cannam@127 180 }
cannam@127 181
cannam@127 182 #define divides(a, b) (((b) % (a)) == 0)
cannam@127 183 INT X(choose_radix)(INT r, INT n)
cannam@127 184 {
cannam@127 185 if (r > 0) {
cannam@127 186 if (divides(r, n)) return r;
cannam@127 187 return 0;
cannam@127 188 } else if (r == 0) {
cannam@127 189 return X(first_divisor)(n);
cannam@127 190 } else {
cannam@127 191 /* r is negative. If n = (-r) * q^2, take q as the radix */
cannam@127 192 r = 0 - r;
cannam@127 193 return (n > r && divides(r, n)) ? isqrt_maybe(n / r) : 0;
cannam@127 194 }
cannam@127 195 }
cannam@127 196
cannam@127 197 /* return A mod N, works for all A including A < 0 */
cannam@127 198 INT X(modulo)(INT a, INT n)
cannam@127 199 {
cannam@127 200 A(n > 0);
cannam@127 201 if (a >= 0)
cannam@127 202 return a % n;
cannam@127 203 else
cannam@127 204 return (n - 1) - ((-(a + (INT)1)) % n);
cannam@127 205 }
cannam@127 206
cannam@127 207 /* TRUE if N factors into small primes */
cannam@127 208 int X(factors_into_small_primes)(INT n)
cannam@127 209 {
cannam@127 210 static const INT primes[] = { 2, 3, 5, 0 };
cannam@127 211 return X(factors_into)(n, primes);
cannam@127 212 }