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1.1.1.9 ! root 1: /* genprime.c - C source code for generation of large primes ! 2: used by public-key key generation routines. ! 3: First version 17 Mar 87 ! 4: Last revised 2 Jun 91 by PRZ ! 5: 24 Apr 93 by CP ! 6: ! 7: (c) Copyright 1990-1996 by Philip Zimmermann. All rights reserved. ! 8: The author assumes no liability for damages resulting from the use ! 9: of this software, even if the damage results from defects in this ! 10: software. No warranty is expressed or implied. ! 11: ! 12: Note that while most PGP source modules bear Philip Zimmermann's ! 13: copyright notice, many of them have been revised or entirely written ! 14: by contributors who frequently failed to put their names in their ! 15: code. Code that has been incorporated into PGP from other authors ! 16: was either originally published in the public domain or is used with ! 17: permission from the various authors. ! 18: ! 19: PGP is available for free to the public under certain restrictions. ! 20: See the PGP User's Guide (included in the release package) for ! 21: important information about licensing, patent restrictions on ! 22: certain algorithms, trademarks, copyrights, and export controls. ! 23: ! 24: These functions are for the generation of large prime integers and ! 25: for other functions related to factoring and key generation for ! 26: many number-theoretic cryptographic algorithms, such as the NIST ! 27: Digital Signature Standard. ! 28: */ ! 29: ! 30: #define SHOWPROGRESS ! 31: ! 32: /* Define some error status returns for keygen... */ ! 33: #define NOPRIMEFOUND -14 /* slowtest probably failed */ ! 34: #define NOSUSPECTS -13 /* fastsieve probably failed */ ! 35: ! 36: ! 37: #if defined(MSDOS) || defined(WIN32) ! 38: #define poll_for_break() {while (kbhit()) getch();} ! 39: #endif ! 40: ! 41: #ifndef poll_for_break ! 42: #define poll_for_break() /* stub */ ! 43: #endif ! 44: ! 45: #ifdef SHOWPROGRESS ! 46: #include <stdio.h> /* needed for putchar() */ ! 47: #endif ! 48: ! 49: #ifdef MACTC5 ! 50: extern int Putchar(int c); ! 51: #undef putchar ! 52: #define putchar Putchar ! 53: #endif ! 54: ! 55: #ifdef EMBEDDED /* compiling for embedded target */ ! 56: #define _NOMALLOC /* defined if no malloc is available. */ ! 57: #endif /* EMBEDDED */ ! 58: ! 59: /* Decide whether malloc is available. Some embedded systems lack it. */ ! 60: #ifndef _NOMALLOC /* malloc library routine available */ ! 61: #include <stdlib.h> /* ANSI C library - for malloc() and free() */ ! 62: /* #include <alloc.h> *//* Borland Turbo C has malloc in <alloc.h> */ ! 63: #endif /* malloc available */ ! 64: ! 65: #include "mpilib.h" ! 66: #include "genprime.h" ! 67: #if (defined(MSDOS) && !defined(__GO32__)) || defined(WIN32) ! 68: #include <conio.h> ! 69: #endif ! 70: ! 71: #include "random.h" ! 72: ! 73: ! 74: /* #define STRONGPRIMES *//* if defined, generate "strong" primes for key */ ! 75: /* ! 76: *"Strong" primes are no longer advantageous, due to the new ! 77: * elliptical curve method of factoring. Randomly selected primes ! 78: * are as good as any. See "Factoring", by Duncan A. Buell, Journal ! 79: * of Supercomputing 1 (1987), pages 191-216. ! 80: * This justifies disabling the lengthy search for strong primes. ! 81: * ! 82: * The advice about strong primes in the early RSA literature applies ! 83: * to 256-bit moduli where the attacks were the Pollard rho and P-1 ! 84: * factoring algorithms. Later developments in factoring have entirely ! 85: * supplanted these methods. The later algorithms are always faster ! 86: * (so we need bigger primes), and don't care about STRONGPRIMES. ! 87: * ! 88: * The early literature was saying that you can get away with small ! 89: * moduli if you choose the primes carefully. The later developments ! 90: * say you can't get away with small moduli, period. And it doesn't ! 91: * matter how you choose the primes. ! 92: * ! 93: * It's just taking a heck of a long time for the advice on "strong primes" ! 94: * to disappear from the books. Authors keep going back to the original ! 95: * documents and repeating what they read there, even though it's out ! 96: * of date. ! 97: */ ! 98: ! 99: #define BLUM ! 100: /* If BLUM is defined, this looks for prines congruent to 3 modulo 4. ! 101: The product of two of these is a Blum integer. You can uniquely define ! 102: a square root Cmodulo a Blum integer, which leads to some extra ! 103: possibilities for encryption algorithms. This shrinks the key space by ! 104: 2 bits, which is not considered significant. ! 105: */ ! 106: ! 107: #ifdef STRONGPRIMES ! 108: ! 109: static boolean primetest(unitptr p); ! 110: /* Returns TRUE iff p is a prime. */ ! 111: ! 112: static int mp_sqrt(unitptr quotient, unitptr dividend); ! 113: /* Quotient is returned as the square root of dividend. */ ! 114: ! 115: #endif ! 116: ! 117: static int nextprime(unitptr p); ! 118: /* Find next higher prime starting at p, returning result in p. */ ! 119: ! 120: static void randombits(unitptr p, short nbits); ! 121: /* Make a random unit array p with nbits of precision. */ ! 122: ! 123: #ifdef DEBUG ! 124: #define DEBUGprintf1(x) printf(x) ! 125: #define DEBUGprintf2(x,y) printf(x,y) ! 126: #define DEBUGprintf3(x,y,z) printf(x,y,z) ! 127: #else ! 128: #define DEBUGprintf1(x) ! 129: #define DEBUGprintf2(x,y) ! 130: #define DEBUGprintf3(x,y,z) ! 131: #endif ! 132: ! 133: ! 134: /* primetable is a table of 16-bit prime numbers used for sieving ! 135: and for other aspects of public-key cryptographic key generation */ ! 136: ! 137: static word16 primetable[] = ! 138: { ! 139: 2, 3, 5, 7, 11, 13, 17, 19, ! 140: 23, 29, 31, 37, 41, 43, 47, 53, ! 141: 59, 61, 67, 71, 73, 79, 83, 89, ! 142: 97, 101, 103, 107, 109, 113, 127, 131, ! 143: 137, 139, 149, 151, 157, 163, 167, 173, ! 144: 179, 181, 191, 193, 197, 199, 211, 223, ! 145: 227, 229, 233, 239, 241, 251, 257, 263, ! 146: 269, 271, 277, 281, 283, 293, 307, 311, ! 147: #ifndef EMBEDDED /* not embedded, use larger table */ ! 148: 313, 317, 331, 337, 347, 349, 353, 359, ! 149: 367, 373, 379, 383, 389, 397, 401, 409, ! 150: 419, 421, 431, 433, 439, 443, 449, 457, ! 151: 461, 463, 467, 479, 487, 491, 499, 503, ! 152: 509, 521, 523, 541, 547, 557, 563, 569, ! 153: 571, 577, 587, 593, 599, 601, 607, 613, ! 154: 617, 619, 631, 641, 643, 647, 653, 659, ! 155: 661, 673, 677, 683, 691, 701, 709, 719, ! 156: 727, 733, 739, 743, 751, 757, 761, 769, ! 157: 773, 787, 797, 809, 811, 821, 823, 827, ! 158: 829, 839, 853, 857, 859, 863, 877, 881, ! 159: 883, 887, 907, 911, 919, 929, 937, 941, ! 160: 947, 953, 967, 971, 977, 983, 991, 997, ! 161: 1009, 1013, 1019, 1021, 1031, 1033, 1039, 1049, ! 162: 1051, 1061, 1063, 1069, 1087, 1091, 1093, 1097, ! 163: 1103, 1109, 1117, 1123, 1129, 1151, 1153, 1163, ! 164: 1171, 1181, 1187, 1193, 1201, 1213, 1217, 1223, ! 165: 1229, 1231, 1237, 1249, 1259, 1277, 1279, 1283, ! 166: 1289, 1291, 1297, 1301, 1303, 1307, 1319, 1321, ! 167: 1327, 1361, 1367, 1373, 1381, 1399, 1409, 1423, ! 168: 1427, 1429, 1433, 1439, 1447, 1451, 1453, 1459, ! 169: 1471, 1481, 1483, 1487, 1489, 1493, 1499, 1511, ! 170: 1523, 1531, 1543, 1549, 1553, 1559, 1567, 1571, ! 171: 1579, 1583, 1597, 1601, 1607, 1609, 1613, 1619, ! 172: 1621, 1627, 1637, 1657, 1663, 1667, 1669, 1693, ! 173: 1697, 1699, 1709, 1721, 1723, 1733, 1741, 1747, ! 174: 1753, 1759, 1777, 1783, 1787, 1789, 1801, 1811, ! 175: 1823, 1831, 1847, 1861, 1867, 1871, 1873, 1877, ! 176: 1879, 1889, 1901, 1907, 1913, 1931, 1933, 1949, ! 177: 1951, 1973, 1979, 1987, 1993, 1997, 1999, 2003, ! 178: 2011, 2017, 2027, 2029, 2039, 2053, 2063, 2069, ! 179: 2081, 2083, 2087, 2089, 2099, 2111, 2113, 2129, ! 180: 2131, 2137, 2141, 2143, 2153, 2161, 2179, 2203, ! 181: 2207, 2213, 2221, 2237, 2239, 2243, 2251, 2267, ! 182: 2269, 2273, 2281, 2287, 2293, 2297, 2309, 2311, ! 183: 2333, 2339, 2341, 2347, 2351, 2357, 2371, 2377, ! 184: 2381, 2383, 2389, 2393, 2399, 2411, 2417, 2423, ! 185: 2437, 2441, 2447, 2459, 2467, 2473, 2477, 2503, ! 186: 2521, 2531, 2539, 2543, 2549, 2551, 2557, 2579, ! 187: 2591, 2593, 2609, 2617, 2621, 2633, 2647, 2657, ! 188: 2659, 2663, 2671, 2677, 2683, 2687, 2689, 2693, ! 189: 2699, 2707, 2711, 2713, 2719, 2729, 2731, 2741, ! 190: 2749, 2753, 2767, 2777, 2789, 2791, 2797, 2801, ! 191: 2803, 2819, 2833, 2837, 2843, 2851, 2857, 2861, ! 192: 2879, 2887, 2897, 2903, 2909, 2917, 2927, 2939, ! 193: 2953, 2957, 2963, 2969, 2971, 2999, 3001, 3011, ! 194: 3019, 3023, 3037, 3041, 3049, 3061, 3067, 3079, ! 195: 3083, 3089, 3109, 3119, 3121, 3137, 3163, 3167, ! 196: 3169, 3181, 3187, 3191, 3203, 3209, 3217, 3221, ! 197: 3229, 3251, 3253, 3257, 3259, 3271, 3299, 3301, ! 198: 3307, 3313, 3319, 3323, 3329, 3331, 3343, 3347, ! 199: 3359, 3361, 3371, 3373, 3389, 3391, 3407, 3413, ! 200: 3433, 3449, 3457, 3461, 3463, 3467, 3469, 3491, ! 201: 3499, 3511, 3517, 3527, 3529, 3533, 3539, 3541, ! 202: 3547, 3557, 3559, 3571, 3581, 3583, 3593, 3607, ! 203: 3613, 3617, 3623, 3631, 3637, 3643, 3659, 3671, ! 204: 3673, 3677, 3691, 3697, 3701, 3709, 3719, 3727, ! 205: 3733, 3739, 3761, 3767, 3769, 3779, 3793, 3797, ! 206: 3803, 3821, 3823, 3833, 3847, 3851, 3853, 3863, ! 207: 3877, 3881, 3889, 3907, 3911, 3917, 3919, 3923, ! 208: 3929, 3931, 3943, 3947, 3967, 3989, 4001, 4003, ! 209: 4007, 4013, 4019, 4021, 4027, 4049, 4051, 4057, ! 210: 4073, 4079, 4091, 4093, 4099, 4111, 4127, 4129, ! 211: 4133, 4139, 4153, 4157, 4159, 4177, 4201, 4211, ! 212: 4217, 4219, 4229, 4231, 4241, 4243, 4253, 4259, ! 213: 4261, 4271, 4273, 4283, 4289, 4297, 4327, 4337, ! 214: 4339, 4349, 4357, 4363, 4373, 4391, 4397, 4409, ! 215: 4421, 4423, 4441, 4447, 4451, 4457, 4463, 4481, ! 216: 4483, 4493, 4507, 4513, 4517, 4519, 4523, 4547, ! 217: 4549, 4561, 4567, 4583, 4591, 4597, 4603, 4621, ! 218: 4637, 4639, 4643, 4649, 4651, 4657, 4663, 4673, ! 219: 4679, 4691, 4703, 4721, 4723, 4729, 4733, 4751, ! 220: 4759, 4783, 4787, 4789, 4793, 4799, 4801, 4813, ! 221: 4817, 4831, 4861, 4871, 4877, 4889, 4903, 4909, ! 222: 4919, 4931, 4933, 4937, 4943, 4951, 4957, 4967, ! 223: 4969, 4973, 4987, 4993, 4999, 5003, 5009, 5011, ! 224: 5021, 5023, 5039, 5051, 5059, 5077, 5081, 5087, ! 225: 5099, 5101, 5107, 5113, 5119, 5147, 5153, 5167, ! 226: 5171, 5179, 5189, 5197, 5209, 5227, 5231, 5233, ! 227: 5237, 5261, 5273, 5279, 5281, 5297, 5303, 5309, ! 228: 5323, 5333, 5347, 5351, 5381, 5387, 5393, 5399, ! 229: 5407, 5413, 5417, 5419, 5431, 5437, 5441, 5443, ! 230: 5449, 5471, 5477, 5479, 5483, 5501, 5503, 5507, ! 231: 5519, 5521, 5527, 5531, 5557, 5563, 5569, 5573, ! 232: 5581, 5591, 5623, 5639, 5641, 5647, 5651, 5653, ! 233: 5657, 5659, 5669, 5683, 5689, 5693, 5701, 5711, ! 234: 5717, 5737, 5741, 5743, 5749, 5779, 5783, 5791, ! 235: 5801, 5807, 5813, 5821, 5827, 5839, 5843, 5849, ! 236: 5851, 5857, 5861, 5867, 5869, 5879, 5881, 5897, ! 237: 5903, 5923, 5927, 5939, 5953, 5981, 5987, 6007, ! 238: 6011, 6029, 6037, 6043, 6047, 6053, 6067, 6073, ! 239: 6079, 6089, 6091, 6101, 6113, 6121, 6131, 6133, ! 240: 6143, 6151, 6163, 6173, 6197, 6199, 6203, 6211, ! 241: 6217, 6221, 6229, 6247, 6257, 6263, 6269, 6271, ! 242: 6277, 6287, 6299, 6301, 6311, 6317, 6323, 6329, ! 243: 6337, 6343, 6353, 6359, 6361, 6367, 6373, 6379, ! 244: 6389, 6397, 6421, 6427, 6449, 6451, 6469, 6473, ! 245: 6481, 6491, 6521, 6529, 6547, 6551, 6553, 6563, ! 246: 6569, 6571, 6577, 6581, 6599, 6607, 6619, 6637, ! 247: 6653, 6659, 6661, 6673, 6679, 6689, 6691, 6701, ! 248: 6703, 6709, 6719, 6733, 6737, 6761, 6763, 6779, ! 249: 6781, 6791, 6793, 6803, 6823, 6827, 6829, 6833, ! 250: 6841, 6857, 6863, 6869, 6871, 6883, 6899, 6907, ! 251: 6911, 6917, 6947, 6949, 6959, 6961, 6967, 6971, ! 252: 6977, 6983, 6991, 6997, 7001, 7013, 7019, 7027, ! 253: 7039, 7043, 7057, 7069, 7079, 7103, 7109, 7121, ! 254: 7127, 7129, 7151, 7159, 7177, 7187, 7193, 7207, ! 255: 7211, 7213, 7219, 7229, 7237, 7243, 7247, 7253, ! 256: 7283, 7297, 7307, 7309, 7321, 7331, 7333, 7349, ! 257: 7351, 7369, 7393, 7411, 7417, 7433, 7451, 7457, ! 258: 7459, 7477, 7481, 7487, 7489, 7499, 7507, 7517, ! 259: 7523, 7529, 7537, 7541, 7547, 7549, 7559, 7561, ! 260: 7573, 7577, 7583, 7589, 7591, 7603, 7607, 7621, ! 261: 7639, 7643, 7649, 7669, 7673, 7681, 7687, 7691, ! 262: 7699, 7703, 7717, 7723, 7727, 7741, 7753, 7757, ! 263: 7759, 7789, 7793, 7817, 7823, 7829, 7841, 7853, ! 264: 7867, 7873, 7877, 7879, 7883, 7901, 7907, 7919, ! 265: 7927, 7933, 7937, 7949, 7951, 7963, 7993, 8009, ! 266: 8011, 8017, 8039, 8053, 8059, 8069, 8081, 8087, ! 267: 8089, 8093, 8101, 8111, 8117, 8123, 8147, 8161, ! 268: 8167, 8171, 8179, 8191, ! 269: #endif /* not EMBEDDED, use larger table */ ! 270: 0}; /* null-terminated list, with only one null at end */ ! 271: ! 272: ! 273: ! 274: #ifdef UNIT8 ! 275: static word16 bottom16(unitptr r) ! 276: /* Called from nextprime and primetest. Returns low 16 bits of r. */ ! 277: { ! 278: make_lsbptr(r, (global_precision - ((2 / BYTES_PER_UNIT) - 1))); ! 279: return *(word16 *) r; ! 280: } /* bottom16 */ ! 281: #else /* UNIT16 or UNIT32 */ ! 282: #define bottom16(r) ((word16) lsunit(r)) ! 283: /* or UNIT32 could mask off lower 16 bits, instead of typecasting it. */ ! 284: #endif /* UNIT16 or UNIT32 */ ! 285: ! 286: ! 287: /* ! 288: * This routine tests p for primality by applying Fermat's theorem: ! 289: * For any x, if ((x**(p-1)) mod p) != 1, then p is not prime. ! 290: * By trying a few values for x, we can determine if p is "probably" prime. ! 291: * ! 292: * Because this test is so slow, it is recommended that p be sieved first ! 293: * to weed out numbers that are obviously not prime. ! 294: * ! 295: * Contrary to what you may have read in the literature, empirical evidence ! 296: * shows this test weeds out a LOT more than 50% of the composite candidates ! 297: * for each trial x. Each test catches nearly all the composites. ! 298: * ! 299: * Some people have questioned whether four Fermat tests is sufficient. ! 300: * See "Finding Four Million Large Random Primes", by Ronald Rivest, ! 301: * in Advancess in Cryptology: Proceedings of Crypto '91. He used a ! 302: * small-divisor test similar to PGP's, then a Fermat test to the base 2, ! 303: * and then 8 iterarions of a Miller-Rabin test. About 718 million random ! 304: * 256-bit integers were generated, 43,741,404 passed the small divisor test, ! 305: * 4,058,000 passed the Fermat test, and all 4,058,000 passed all 8 ! 306: * iterations of the Miller-Rabin test, proving their primality beyond most ! 307: * reasonable doubts. This is strong experimental evidence that the odds ! 308: * of getting a non-prime are less than one in a million (10^-6). ! 309: * ! 310: * He also gives a theoretical argument that the chances of finding a ! 311: * 256-bit non-prime which satisfies one Fermat test to the base 2 is less ! 312: * than 10^-22. The small divisor test improves this number, and if the ! 313: * numbers are 512 bits (as needed for a 1024-bit key) the odds of failure ! 314: * shrink to about 10^-44. Thus, he concludes, for practical purposes one ! 315: * Fermat test to the base 2 is sufficient. ! 316: */ ! 317: static boolean slowtest(unitptr p) ! 318: { ! 319: unit x[MAX_UNIT_PRECISION], is_one[MAX_UNIT_PRECISION]; ! 320: unit pminus1[MAX_UNIT_PRECISION]; ! 321: short i; ! 322: ! 323: mp_move(pminus1, p); ! 324: mp_dec(pminus1); ! 325: ! 326: for (i = 0; i < 4; i++) { /* Just do a few tests. */ ! 327: poll_for_break(); /* polls keyboard, allows ctrl-C to abort program */ ! 328: mp_init(x, primetable[i]); /* Use any old random trial x */ ! 329: /* if ((x**(p-1)) mod p) != 1, then p is not prime */ ! 330: if (mp_modexp(is_one, x, pminus1, p) < 0) /* modexp error? */ ! 331: return FALSE; /* error means return not prime status */ ! 332: if (testne(is_one, 1)) /* then p is not prime */ ! 333: return FALSE; /* return not prime status */ ! 334: #ifdef SHOWPROGRESS ! 335: putchar('*'); /* let user see how we are progressing */ ! 336: fflush(stdout); ! 337: #endif /* SHOWPROGRESS */ ! 338: } ! 339: ! 340: /* If it gets to this point, it's very likely that p is prime */ ! 341: mp_burn(x); /* burn the evidence on the stack... */ ! 342: mp_burn(is_one); ! 343: mp_burn(pminus1); ! 344: return TRUE; ! 345: } /* slowtest -- fermattest */ ! 346: ! 347: ! 348: #ifdef STRONGPRIMES ! 349: ! 350: static boolean primetest(unitptr p) ! 351: /* ! 352: * Returns TRUE iff p is a prime. ! 353: * If p doesn't pass through the sieve, then p is definitely NOT a prime. ! 354: * If p is small enough for the sieve to prove primality or not, ! 355: * and p passes through the sieve, then p is definitely a prime. ! 356: * If p is large and p passes through the sieve and may be a prime, ! 357: * then p is further tested for primality with a slower test. ! 358: */ ! 359: { ! 360: short i; ! 361: static word16 lastprime = 0; /* last prime in primetable */ ! 362: word16 sqrt_p; /* to limit sieving past sqrt(p), for small p's */ ! 363: ! 364: if (!lastprime) { /* lastprime still undefined. So define it. */ ! 365: /* executes this code only once, then skips it next time */ ! 366: for (i = 0; primetable[i]; i++); /* seek end of primetable */ ! 367: lastprime = primetable[i - 1]; /* get last prime in table */ ! 368: } ! 369: if (significance(p) <= (2 / BYTES_PER_UNIT)) /* if p <= 16 bits */ ! 370: /* p may be in primetable. Search it. */ ! 371: if (bottom16(p) <= lastprime) ! 372: for (i = 0; primetable[i]; i++) { ! 373: /* scan until null-terminator */ ! 374: if (primetable[i] == bottom16(p)) ! 375: return TRUE; /* yep, definitely a prime. */ ! 376: if (primetable[i] > bottom16(p)) /* we missed. */ ! 377: return FALSE; /* definitely NOT a prime. */ ! 378: } /* We got past the whole primetable without a hit. */ ! 379: /* p is bigger than any prime in primetable, so let's sieve. */ ! 380: if (!(lsunit(p) & 1)) /* if least significant bit is 0... */ ! 381: return FALSE; /* divisible by 2, not prime */ ! 382: ! 383: if (mp_tstminus(p)) /* error if p<0 */ ! 384: return FALSE; /* not prime if p<0 */ ! 385: ! 386: /* ! 387: * Optimization for small (32 bits or less) p's. ! 388: * If p is small, compute sqrt_p = sqrt(p), or else ! 389: * if p is >32 bits then just set sqrt_p to something ! 390: * at least as big as the largest primetable entry. ! 391: */ ! 392: if (significance(p) <= (4 / BYTES_PER_UNIT)) { /* if p <= 32 bits */ ! 393: unit sqrtp[MAX_UNIT_PRECISION]; ! 394: /* Just sieve up to sqrt(p) */ ! 395: if (mp_sqrt(sqrtp, p) == 0) /* 0 means p is a perfect square */ ! 396: return FALSE; /* perfect square is not a prime */ ! 397: /* we know that sqrtp <= 16 bits because p <= 32 bits */ ! 398: sqrt_p = bottom16(sqrtp); ! 399: } else { ! 400: /* p > 32 bits, so obviate sqrt(p) test. */ ! 401: sqrt_p = lastprime; /* ensures that we do ENTIRE sieve. */ ! 402: } ! 403: ! 404: /* p is assumed odd, so begin sieve at 3 */ ! 405: for (i = 1; primetable[i]; i++) { ! 406: /* Compute p mod (primetable[i]). If it divides evenly... */ ! 407: if (mp_shortmod(p, primetable[i]) == 0) ! 408: return FALSE; /* then p is definitely NOT prime */ ! 409: if (primetable[i] > sqrt_p) /* fully sieved p? */ ! 410: return TRUE; /* yep, fully passed sieve, definitely a prime. */ ! 411: } ! 412: /* It passed the sieve, so p is a suspected prime. */ ! 413: ! 414: /* Now try slow complex primality test on suspected prime. */ ! 415: return slowtest(p); /* returns TRUE or FALSE */ ! 416: } /* primetest */ ! 417: ! 418: #endif ! 419: ! 420: /* ! 421: * Used in conjunction with fastsieve. Builds a table of remainders ! 422: * relative to the random starting point p, so that fastsieve can ! 423: * sequentially sieve for suspected primes quickly. Call buildsieve ! 424: * once, then call fastsieve for consecutive prime candidates. ! 425: * Note that p must be odd, because the sieve begins at 3. ! 426: */ ! 427: static void buildsieve(unitptr p, word16 remainders[]) ! 428: { ! 429: short i; ! 430: for (i = 1; primetable[i]; i++) { ! 431: remainders[i] = mp_shortmod(p, primetable[i]); ! 432: } ! 433: } /* buildsieve */ ! 434: ! 435: /* ! 436: Fast prime sieving algorithm by Philip Zimmermann, March 1987. ! 437: This is the fastest algorithm I know of for quickly sieving for ! 438: large (hundreds of bits in length) "random" probable primes, because ! 439: it uses only single-precision (16-bit) arithmetic. Because rigorous ! 440: prime testing algorithms are very slow, it is recommended that ! 441: potential prime candidates be quickly passed through this fast ! 442: sieving algorithm first to weed out numbers that are obviously not ! 443: prime. ! 444: ! 445: This algorithm is optimized to search sequentially for a large prime ! 446: from a random starting point. For generalized nonsequential prime ! 447: testing, the slower conventional sieve should be used, as given ! 448: in primetest(p). ! 449: ! 450: This algorithm requires a fixed table (called primetable) of the ! 451: first hundred or so small prime numbers. ! 452: First we select a random odd starting point (p) for our prime ! 453: search. Then we build a table of 16-bit remainders calculated ! 454: from that initial p. This table of 16-bit remainders is exactly ! 455: the same length as the table of small 16-bit primes. Each ! 456: remainders table entry contains the remainder of p divided by the ! 457: corresponding primetable entry. Then we begin sequentially testing ! 458: all odd integers, starting from the initial odd random p. The ! 459: distance we have searched from the huge random starting point p is ! 460: a small 16-bit number, pdelta. If pdelta plus a remainders table ! 461: entry is evenly divisible by the corresponding primetable entry, ! 462: then p+pdelta is factorable by that primetable entry, which means ! 463: p+pdelta is not prime. ! 464: */ ! 465: ! 466: /* Fastsieve is used for searching sequentially from a random starting ! 467: point for a suspected prime. Requires that buildsieve be called ! 468: first, to build a table of remainders relative to the random starting ! 469: point p. ! 470: Returns true iff pdelta passes through the sieve and thus p+pdelta ! 471: may be a prime. Note that p must be odd, because the sieve begins ! 472: at 3. ! 473: */ ! 474: static boolean fastsieve(word16 pdelta, word16 remainders[]) ! 475: { ! 476: short i; ! 477: for (i = 1; primetable[i]; i++) { ! 478: /* ! 479: * If pdelta plus a remainders table entry is evenly ! 480: * divisible by the corresponding primetable entry, ! 481: * then p+pdelta is factorable by that primetable entry, ! 482: * which means p+pdelta is not prime. ! 483: */ ! 484: if ((pdelta + remainders[i]) % primetable[i] == 0) ! 485: return FALSE; /* then p+pdelta is not prime */ ! 486: } ! 487: /* It passed the sieve. It is now a suspected prime. */ ! 488: return TRUE; ! 489: } /* fastsieve */ ! 490: ! 491: ! 492: #define numberof(x) (sizeof(x)/sizeof(x[0])) /* number of table entries */ ! 493: ! 494: ! 495: static int nextprime(unitptr p) ! 496: /* ! 497: * Find next higher prime starting at p, returning result in p. ! 498: * Uses fast prime sieving algorithm to search sequentially. ! 499: * Returns 0 for normal completion status, < 0 for failure status. ! 500: */ ! 501: { ! 502: word16 pdelta, range; ! 503: short oldprecision; ! 504: short i, suspects; ! 505: ! 506: /* start search at candidate p */ ! 507: mp_inc(p); /* remember, it's the NEXT prime from p, noninclusive. */ ! 508: if (significance(p) <= 1) { ! 509: /* ! 510: * p might be smaller than the largest prime in primetable. ! 511: * We can't sieve for primes that are already in primetable. ! 512: * We will have to directly search the table. ! 513: */ ! 514: /* scan until null-terminator */ ! 515: for (i = 0; primetable[i]; i++) { ! 516: if (primetable[i] >= lsunit(p)) { ! 517: mp_init(p, primetable[i]); ! 518: return 0; /* return next higher prime from primetable */ ! 519: } ! 520: } /* We got past the whole primetable without a hit. */ ! 521: } /* p is bigger than any prime in primetable, so let's sieve. */ ! 522: if (mp_tstminus(p)) { /* error if p<0 */ ! 523: mp_init(p, 2); /* next prime >0 is 2 */ ! 524: return 0; /* normal completion status */ ! 525: } ! 526: #ifndef BLUM ! 527: lsunit(p) |= 1; /* set candidate's lsb - make it odd */ ! 528: #else ! 529: lsunit(p) |= 3; /* Make candidate ==3 mod 4 */ ! 530: #endif ! 531: ! 532: /* Adjust the global_precision downward to the optimum size for p... */ ! 533: oldprecision = global_precision; /* save global_precision */ ! 534: /* We will need 2-3 extra bits of precision for the falsekeytest. */ ! 535: set_precision(bits2units(countbits(p) + 4 + SLOP_BITS)); ! 536: /* Rescale p to global_precision we just defined */ ! 537: rescale(p, oldprecision, global_precision); ! 538: ! 539: { ! 540: #ifdef _NOMALLOC /* No malloc and free functions available. Use stack. */ ! 541: word16 remainders[numberof(primetable)]; ! 542: #else /* malloc available, we can conserve stack space. */ ! 543: word16 *remainders; ! 544: /* Allocate some memory for the table of remainders: */ ! 545: remainders = (word16 *) malloc(sizeof(primetable)); ! 546: #endif /* malloc available */ ! 547: ! 548: /* Build remainders table relative to initial p: */ ! 549: buildsieve(p, remainders); ! 550: pdelta = 0; /* offset from initial random p */ ! 551: /* Sieve preparation complete. Now for some fast fast sieving... */ ! 552: /* slowtest will not be called unless fastsieve is true */ ! 553: ! 554: /* range is how far to search before giving up. */ ! 555: #ifndef BLUM ! 556: range = 4 * units2bits(global_precision); ! 557: #else ! 558: /* Twice as many because step size is twice as large, */ ! 559: range = 8 * units2bits(global_precision); ! 560: #endif ! 561: suspects = 0; /* number of suspected primes and slowtest trials */ ! 562: for (;;) { ! 563: /* equivalent to: if (primetest(p)) break; */ ! 564: if (fastsieve(pdelta, remainders)) { /* found suspected prime */ ! 565: suspects++; /* tally for statistical purposes */ ! 566: #ifdef SHOWPROGRESS ! 567: putchar('.'); /* let user see how we are progressing */ ! 568: fflush(stdout); ! 569: #endif /* SHOWPROGRESS */ ! 570: if (slowtest(p)) ! 571: break; /* found a prime */ ! 572: } ! 573: #ifndef BLUM ! 574: pdelta += 2; /* try next odd number */ ! 575: #else ! 576: pdelta += 4; ! 577: mp_inc(p); ! 578: mp_inc(p); ! 579: #endif ! 580: mp_inc(p); ! 581: mp_inc(p); ! 582: ! 583: if (pdelta > range) /* searched too many candidates? */ ! 584: break; /* something must be wrong--bail out of search */ ! 585: ! 586: } /* while (TRUE) */ ! 587: ! 588: #ifdef SHOWPROGRESS ! 589: putchar(' '); /* let user see how we are progressing */ ! 590: #endif /* SHOWPROGRESS */ ! 591: ! 592: for (i = 0; primetable[i]; i++) /* scan until null-terminator */ ! 593: remainders[i] = 0; /* don't leave remainders exposed in RAM */ ! 594: #ifndef _NOMALLOC ! 595: free(remainders); /* free allocated memory */ ! 596: #endif /* not _NOMALLOC */ ! 597: } ! 598: ! 599: set_precision(oldprecision); /* restore precision */ ! 600: ! 601: if (pdelta > range) { /* searched too many candidates? */ ! 602: if (suspects < 1) /* unreasonable to have found no suspects */ ! 603: return NOSUSPECTS; /* fastsieve failed, probably */ ! 604: return NOPRIMEFOUND; /* return error status */ ! 605: } ! 606: return 0; /* return normal completion status */ ! 607: ! 608: } /* nextprime */ ! 609: ! 610: ! 611: /* We will need a series of truly random bits for key generation. ! 612: In most implementations, our random number supply is derived from ! 613: random keyboard delays rather than a hardware random number ! 614: chip. So we will have to ensure we have a large enough pool of ! 615: accumulated random numbers from the keyboard. trueRandAccum() ! 616: performs this operation. ! 617: */ ! 618: ! 619: /* Fills 1 unit with random bytes, and returns unit. */ ! 620: static unit randomunit(void) ! 621: { ! 622: unit u = 0; ! 623: byte i; ! 624: i = BYTES_PER_UNIT; ! 625: do ! 626: u = (u << 8) + trueRandByte(); ! 627: while (--i != 0); ! 628: return u; ! 629: } /* randomunit */ ! 630: ! 631: /* ! 632: * Make a random unit array p with nbits of precision. Used mainly to ! 633: * generate large random numbers to search for primes. ! 634: */ ! 635: static void randombits(unitptr p, short nbits) ! 636: { ! 637: mp_init(p, 0); ! 638: make_lsbptr(p, global_precision); ! 639: ! 640: /* Add whole units of randomness */ ! 641: while (nbits >= UNITSIZE) { ! 642: *post_higherunit(p) = randomunit(); ! 643: nbits -= UNITSIZE; ! 644: } ! 645: ! 646: /* Add most-significant partial unit (if any) */ ! 647: if (nbits) ! 648: *p = randomunit() & (power_of_2(nbits) - 1); ! 649: } /* randombits */ ! 650: ! 651: /* ! 652: * Makes a "random" prime p with nbits significant bits of precision. ! 653: * Since these primes are used to compute a modulus of a guaranteed ! 654: * length, the top 2 bits of the prime are set to 1, so that the ! 655: * product of 2 primes (the modulus) is of a deterministic length. ! 656: * Returns 0 for normal completion status, < 0 for failure status. ! 657: */ ! 658: int randomprime(unitptr p, short nbits) ! 659: { ! 660: DEBUGprintf2("\nGenerating a %d-bit random prime. ", nbits); ! 661: /* Get an initial random candidate p to start search. */ ! 662: randombits(p, nbits - 2); /* 2 less random bits for nonrandom top bits */ ! 663: /* To guarantee exactly nbits of significance, set the top 2 bits to 1 */ ! 664: mp_setbit(p, nbits - 1); /* highest bit is nonrandom */ ! 665: mp_setbit(p, nbits - 2); /* next highest bit is also nonrandom */ ! 666: return nextprime(p); /* search for next higher prime ! 667: from starting point p */ ! 668: } /* randomprime */ ! 669: ! 670: ! 671: #ifdef STRONGPRIMES /* generate "strong" primes for keys */ ! 672: ! 673: #define log_1stprime 6 /* log base 2 of firstprime */ ! 674: ! 675: /* 1st primetable entry used by tryprime */ ! 676: #define firstprime (1<<log_1stprime) ! 677: ! 678: /* This routine attempts to generate a prime p such that p-1 has prime p1 ! 679: as its largest factor. Prime p will have no more than maxbits bits of ! 680: significance. Prime p1 must be less than maxbits-log_1stprime in length. ! 681: This routine is called only from goodprime. ! 682: */ ! 683: static boolean tryprime(unitptr p, unitptr p1, short maxbits) ! 684: { ! 685: int i; ! 686: unit i2[MAX_UNIT_PRECISION]; ! 687: /* Generate p such that p = (i*2*p1)+1, for i=1,2,3,5,7,11,13,17... ! 688: and test p for primality for each small prime i. ! 689: It's better to start i at firstprime rather than at 1, ! 690: because then p grows slower in significance. ! 691: Start looking for small primes that are > firstprime... ! 692: */ ! 693: if ((countbits(p1) + log_1stprime) >= maxbits) { ! 694: DEBUGprintf1("\007[Error: overconstrained prime]"); ! 695: return FALSE; /* failed to make a good prime */ ! 696: } ! 697: for (i = 0; primetable[i]; i++) { ! 698: if (primetable[i] < firstprime) ! 699: continue; ! 700: /* note that mp_init doesn't extend sign bit for >32767 */ ! 701: mp_init(i2, primetable[i] << 1); ! 702: mp_mult(p, p1, i2); ! 703: mp_inc(p); ! 704: if (countbits(p) > maxbits) ! 705: break; ! 706: DEBUGprintf1("."); ! 707: if (primetest(p)) ! 708: return TRUE; ! 709: } ! 710: return FALSE; /* failed to make a good prime */ ! 711: } /* tryprime */ ! 712: ! 713: ! 714: /* ! 715: * Make a "strong" prime p with at most maxbits and at least minbits of ! 716: * significant bits of precision. This algorithm is called to generate ! 717: * a high-quality prime p for key generation purposes. It must have ! 718: * special characteristics for making a modulus n that is hard to factor. ! 719: * Returns 0 for normal completion status, < 0 for failure status. ! 720: */ ! 721: int goodprime(unitptr p, short maxbits, short minbits) ! 722: { ! 723: unit p1[MAX_UNIT_PRECISION]; ! 724: short oldprecision, midbits; ! 725: int status; ! 726: ! 727: mp_init(p, 0); ! 728: /* Adjust the global_precision downward to the optimum size for p... */ ! 729: oldprecision = global_precision; /* save global_precision */ ! 730: /* We will need 2-3 extra bits of precision for the falsekeytest. */ ! 731: set_precision(bits2units(maxbits + 4 + SLOP_BITS)); ! 732: /* rescale p to global_precision we just defined */ ! 733: rescale(p, oldprecision, global_precision); ! 734: ! 735: minbits -= 2 * log_1stprime; /* length of p" */ ! 736: midbits = (maxbits + minbits) / 2; /* length of p' */ ! 737: DEBUGprintf3("\nGenerating a %d-%d bit refined prime. ", ! 738: minbits + 2 * log_1stprime, maxbits); ! 739: do { ! 740: do { ! 741: status = randomprime(p, minbits - 1); ! 742: if (status < 0) ! 743: return status; /* failed to find a random prime */ ! 744: DEBUGprintf2("\n(p\042=%d bits)", countbits(p)); ! 745: } while (!tryprime(p1, p, midbits)); ! 746: DEBUGprintf2("(p'=%d bits)", countbits(p1)); ! 747: } while (!tryprime(p, p1, maxbits)); ! 748: DEBUGprintf2("\n\007(p=%d bits) ", countbits(p)); ! 749: mp_burn(p1); /* burn the evidence on the stack */ ! 750: set_precision(oldprecision); /* restore precision */ ! 751: return 0; /* normal completion status */ ! 752: } /* goodprime */ ! 753: ! 754: #endif /* STRONGPRIMES */ ! 755: ! 756: ! 757: #define iplus1 ( i==2 ? 0 : i+1 ) /* used by Euclid algorithms */ ! 758: #define iminus1 ( i==0 ? 2 : i-1 ) /* used by Euclid algorithms */ ! 759: ! 760: /* Computes greatest common divisor via Euclid's algorithm. */ ! 761: void mp_gcd(unitptr result, unitptr a, unitptr n) ! 762: { ! 763: short i; ! 764: unit gcopies[3][MAX_UNIT_PRECISION]; ! 765: #define g(i) ( &(gcopies[i][0]) ) ! 766: mp_move(g(0), n); ! 767: mp_move(g(1), a); ! 768: ! 769: i = 1; ! 770: while (testne(g(i), 0)) { ! 771: mp_mod(g(iplus1), g(iminus1), g(i)); ! 772: i = iplus1; ! 773: } ! 774: mp_move(result, g(iminus1)); ! 775: mp_burn(g(iminus1)); /* burn the evidence on the stack... */ ! 776: mp_burn(g(iplus1)); ! 777: #undef g ! 778: } /* mp_gcd */ ! 779: ! 780: /* ! 781: * Euclid's algorithm extended to compute multiplicative inverse. ! 782: * Computes x such that a*x mod n = 1, where 0<a<n ! 783: * ! 784: * The variable u is unnecessary for the algorithm, but is ! 785: * included in comments for mathematical clarity. ! 786: */ ! 787: void mp_inv(unitptr x, unitptr a, unitptr n) ! 788: { ! 789: short i; ! 790: unit y[MAX_UNIT_PRECISION], temp[MAX_UNIT_PRECISION]; ! 791: unit gcopies[3][MAX_UNIT_PRECISION], vcopies[3][MAX_UNIT_PRECISION]; ! 792: #define g(i) ( &(gcopies[i][0]) ) ! 793: #define v(i) ( &(vcopies[i][0]) ) ! 794: /* unit ucopies[3][MAX_UNIT_PRECISION]; */ ! 795: /* #define u(i) ( &(ucopies[i][0]) ) */ ! 796: mp_move(g(0), n); ! 797: mp_move(g(1), a); ! 798: /* mp_init(u(0),1); mp_init(u(1),0); */ ! 799: mp_init(v(0), 0); ! 800: mp_init(v(1), 1); ! 801: i = 1; ! 802: while (testne(g(i), 0)) { ! 803: /* we know that at this point, g(i) = u(i)*n + v(i)*a */ ! 804: mp_udiv(g(iplus1), y, g(iminus1), g(i)); ! 805: mp_mult(temp, y, v(i)); ! 806: mp_move(v(iplus1), v(iminus1)); ! 807: mp_sub(v(iplus1), temp); ! 808: /* mp_mult(temp,y,u(i)); mp_move(u(iplus1),u(iminus1)); ! 809: mp_sub(u(iplus1),temp); */ ! 810: i = iplus1; ! 811: } ! 812: mp_move(x, v(iminus1)); ! 813: if (mp_tstminus(x)) ! 814: mp_add(x, n); ! 815: mp_burn(g(iminus1)); /* burn the evidence on the stack... */ ! 816: mp_burn(g(iplus1)); ! 817: mp_burn(v(0)); ! 818: mp_burn(v(1)); ! 819: mp_burn(v(2)); ! 820: mp_burn(y); ! 821: mp_burn(temp); ! 822: #undef g ! 823: #undef v ! 824: } /* mp_inv */ ! 825: ! 826: #ifdef STRONGPRIMES ! 827: ! 828: /* mp_sqrt - returns square root of a number. ! 829: returns -1 for error, 0 for perfect square, 1 for not perfect square. ! 830: Not used by any RSA-related functions. Used by factoring algorithms. ! 831: This version needs optimization. ! 832: by Charles W. Merritt July 15, 1989, refined by PRZ. ! 833: ! 834: These are notes on computing the square root the manual old-fashioned ! 835: way. This is the basis of the fast sqrt algorithm mp_sqrt below: ! 836: ! 837: 1) Separate the number into groups (periods) of two digits each, ! 838: beginning with units or at the decimal point. ! 839: 2) Find the greatest perfect square in the left hand period & write ! 840: its square root as the first figure of the required root. Subtract ! 841: the square of this number from the left hand period. Annex to the ! 842: remainder the next group so as to form a dividend. ! 843: 3) Double the root already found and write it as a partial divisor at ! 844: the left of the new dividend. Annex one zero digit, making a trial ! 845: divisor, and divide the new dividend by the trial divisor. ! 846: 4) Write the quotient in the root as the trial term and also substitute ! 847: this quotient for the annexed zero digit in the partial divisor, ! 848: making the latter complete. ! 849: 5) Multiply the complete divisor by the figure just obtained and, ! 850: if possible, subtract the product from the last remainder. ! 851: If this product is too large, the trial term of the quotient ! 852: must be replaced by the next smaller number and the operations ! 853: preformed as before. ! 854: (IN BINARY, OUR TRIAL TERM IS ALWAYS 1 AND WE USE IT OR DO NOTHING.) ! 855: 6) Proceed in this manner until all periods are used. ! 856: If there is still a remainder, it's not a perfect square. ! 857: */ ! 858: ! 859: /* Quotient is returned as the square root of dividend. */ ! 860: static int mp_sqrt(unitptr quotient, unitptr dividend) ! 861: { ! 862: register short next2bits; /* "period", or group of 2 bits of dividend */ ! 863: register unit dvdbitmask, qbitmask; ! 864: unit remainder[MAX_UNIT_PRECISION]; ! 865: unit rjq[MAX_UNIT_PRECISION], divisor[MAX_UNIT_PRECISION]; ! 866: unsigned int qbits, qprec, dvdbits, dprec, oldprecision; ! 867: int notperfect; ! 868: ! 869: mp_init(quotient, 0); ! 870: if (mp_tstminus(dividend)) { /* if dividend<0, return error */ ! 871: mp_dec(quotient); /* quotient = -1 */ ! 872: return -1; ! 873: } ! 874: /* normalize and compute number of bits in dividend first */ ! 875: init_bitsniffer(dividend, dvdbitmask, dprec, dvdbits); ! 876: /* init_bitsniffer returns a 0 if dvdbits is 0 */ ! 877: if (dvdbits == 1) { ! 878: mp_init(quotient, 1); /* square root of 1 is 1 */ ! 879: return 0; ! 880: } ! 881: /* rescale quotient to half the precision of dividend */ ! 882: qbits = (dvdbits + 1) >> 1; ! 883: qprec = bits2units(qbits); ! 884: rescale(quotient, global_precision, qprec); ! 885: make_msbptr(quotient, qprec); ! 886: qbitmask = power_of_2((qbits - 1) & (UNITSIZE - 1)); ! 887: ! 888: /* ! 889: * Set smallest optimum precision for this square root. ! 890: * The low-level primitives are affected by the call to set_precision. ! 891: * Even though the dividend precision is bigger than the precision ! 892: * we will use, no low-level primitives will be used on the dividend. ! 893: * They will be used on the quotient, remainder, and rjq, which are ! 894: * smaller precision. ! 895: */ ! 896: oldprecision = global_precision; /* save global_precision */ ! 897: set_precision(bits2units(qbits + 3)); /* 3 bits of precision slop */ ! 898: ! 899: /* special case: sqrt of 1st 2 (binary) digits of dividend ! 900: is 1st (binary) digit of quotient. This is always 1. */ ! 901: stuff_bit(quotient, qbitmask); ! 902: bump_bitsniffer(quotient, qbitmask); ! 903: mp_init(rjq, 1); /* rjq is Right Justified Quotient */ ! 904: ! 905: if (!(dvdbits & 1)) { ! 906: /* even number of bits in dividend */ ! 907: next2bits = 2; ! 908: bump_bitsniffer(dividend, dvdbitmask); ! 909: dvdbits--; ! 910: if (sniff_bit(dividend, dvdbitmask)) ! 911: next2bits++; ! 912: bump_bitsniffer(dividend, dvdbitmask); ! 913: dvdbits--; ! 914: } else { ! 915: /* odd number of bits in dividend */ ! 916: next2bits = 1; ! 917: bump_bitsniffer(dividend, dvdbitmask); ! 918: dvdbits--; ! 919: } ! 920: ! 921: mp_init(remainder, next2bits - 1); ! 922: ! 923: /* dvdbits is guaranteed to be even at this point */ ! 924: ! 925: while (dvdbits) { ! 926: next2bits = 0; ! 927: if (sniff_bit(dividend, dvdbitmask)) ! 928: next2bits = 2; ! 929: bump_bitsniffer(dividend, dvdbitmask); ! 930: dvdbits--; ! 931: if (sniff_bit(dividend, dvdbitmask)) ! 932: next2bits++; ! 933: bump_bitsniffer(dividend, dvdbitmask); ! 934: dvdbits--; ! 935: mp_rotate_left(remainder, (boolean) ((next2bits & 2) != 0)); ! 936: mp_rotate_left(remainder, (boolean) ((next2bits & 1) != 0)); ! 937: ! 938: /* ! 939: * "divisor" is trial divisor, complete divisor is 4*rjq ! 940: * or 4*rjq+1. ! 941: * Subtract divisor times its last digit from remainder. ! 942: * If divisor ends in 1, remainder -= divisor*1, ! 943: * or if divisor ends in 0, remainder -= divisor*0 (do nothing). ! 944: * Last digit of divisor inflates divisor as large as possible ! 945: * yet still subtractable from remainder. ! 946: */ ! 947: mp_move(divisor, rjq); /* divisor = 4*rjq+1 */ ! 948: mp_rotate_left(divisor, 0); ! 949: mp_rotate_left(divisor, 1); ! 950: if (mp_compare(remainder, divisor) >= 0) { ! 951: mp_sub(remainder, divisor); ! 952: stuff_bit(quotient, qbitmask); ! 953: mp_rotate_left(rjq, 1); ! 954: } else { ! 955: mp_rotate_left(rjq, 0); ! 956: } ! 957: bump_bitsniffer(quotient, qbitmask); ! 958: } ! 959: notperfect = testne(remainder, 0); /* not a perfect square? */ ! 960: set_precision(oldprecision); /* restore original precision */ ! 961: return notperfect; /* normal return */ ! 962: } /* mp_sqrt */ ! 963: #endif ! 964: ! 965: /*------------------- End of genprime.c -----------------------------*/
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