[u/mdw/catacomb] / pfilt.c

/* -*-c-*-
 *
 * $Id: pfilt.c,v 1.4 2000/10/08 12:14:57 mdw Exp $
 *
 * Finding and testing prime numbers
 *
 * (c) 1999 Straylight/Edgeware
 */

/*----- Licensing notice --------------------------------------------------* 
 *
 * This file is part of Catacomb.
 *
 * Catacomb is free software; you can redistribute it and/or modify
 * it under the terms of the GNU Library General Public License as
 * published by the Free Software Foundation; either version 2 of the
 * License, or (at your option) any later version.
 * 
 * Catacomb 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 Library General Public License for more details.
 * 
 * You should have received a copy of the GNU Library General Public
 * License along with Catacomb; if not, write to the Free
 * Software Foundation, Inc., 59 Temple Place - Suite 330, Boston,
 * MA 02111-1307, USA.
 */

/*----- Revision history --------------------------------------------------* 
 *
 * $Log: pfilt.c,v $
 * Revision 1.4  2000/10/08 12:14:57  mdw
 * Remove vestiges of @primorial@.
 *
 * Revision 1.3  2000/08/15 21:44:27  mdw
 * (pfilt_smallfactor): New function for doing trial division the hard
 * way.
 *
 * (pfilt_create): Use @mpx_udivn@ for computing residues, for improved
 * performance.
 *
 * Pull the `small prime' test into a separate function, and do it
 * properly.
 *
 * Revision 1.2  2000/06/17 11:54:27  mdw
 * Use new MP memory management functions.
 *
 * Revision 1.1  1999/12/22 15:49:39  mdw
 * Renamed from `pgen'.  Reworking for new prime-search system.
 *
 * Revision 1.3  1999/12/10 23:28:35  mdw
 * Track suggested destination changes.
 *
 * Revision 1.2  1999/11/20 22:23:05  mdw
 * Add multiply-and-add function for Diffie-Hellman safe prime generation.
 *
 * Revision 1.1  1999/11/19 13:17:57  mdw
 * Prime number generator and tester.
 *
 */

/*----- Header files ------------------------------------------------------*/

#include "mp.h"
#include "mpint.h"
#include "pfilt.h"
#include "pgen.h"
#include "primetab.h"

/*----- Main code ---------------------------------------------------------*/

/* --- @smallenough@ --- *
 *
 * Arguments:	@mp *m@ = integer to test
 *
 * Returns:	One of the @PGEN@ result codes.
 *
 * Use:		Assuming that @m@ has been tested by trial division on every
 *		prime in the small-primes array, this function will return
 *		@PGEN_DONE@ if the number is less than the square of the
 *		largest small prime.
 */

static int smallenough(mp *m)
{
  static mp *max = 0;
  int rc = PGEN_TRY;

  if (!max) {
    max = mp_fromuint(MP_NEW, MAXPRIME);
    max = mp_sqr(max, max);
    max->a->n--; /* Permanent allocation */
  }
  if (MP_CMP(m, <, max))
    rc = PGEN_DONE;
  return (rc);
}

/* --- @pfilt_smallfactor@ --- *
 *
 * Arguments:	@mp *m@ = integer to test
 *
 * Returns:	One of the @PGEN@ result codes.
 *
 * Use:		Tests a number by dividing by a number of small primes.  This
 *		is a useful first step if you're testing random primes; for
 *		sequential searches, @pfilt_create@ works better.
 */

int pfilt_smallfactor(mp *m)
{
  int rc = PGEN_TRY;
  int i;
  size_t sz = MP_LEN(m);
  mpw *v = mpalloc(m->a, sz);

  /* --- Fill in the residues --- */

  for (i = 0; i < NPRIME; i++) {
    if (!mpx_udivn(v, v + sz, m->v, m->vl, primetab[i])) {
      if (MP_LEN(m) == 1 && m->v[0] == primetab[i])
	rc = PGEN_DONE;
      else
	rc = PGEN_FAIL;
    }
  }

  /* --- Check for small primes --- */

  if (rc == PGEN_TRY)
    rc = smallenough(m);

  /* --- Done --- */

  mpfree(m->a, v);
  return (rc);
}

/* --- @pfilt_create@ --- *
 *
 * Arguments:	@pfilt *p@ = pointer to prime filtering context
 *		@mp *m@ = pointer to initial number to test
 *
 * Returns:	One of the @PGEN@ result codes.
 *
 * Use:		Tests an initial number for primality by computing its
 *		residue modulo various small prime numbers.  This is fairly
 *		quick, but not particularly certain.  If a @PGEN_TRY@
 *		result is returned, perform Rabin-Miller tests to confirm.
 */

int pfilt_create(pfilt *p, mp *m)
{
  int rc = PGEN_TRY;
  int i;
  size_t sz = MP_LEN(m);
  mpw *v = mpalloc(m->a, sz);

  /* --- Take a copy of the number --- */

  mp_shrink(m);
  p->m = MP_COPY(m);

  /* --- Fill in the residues --- */

  for (i = 0; i < NPRIME; i++) {
    p->r[i] = mpx_udivn(v, v + sz, m->v, m->vl, primetab[i]);
    if (!p->r[i] && rc == PGEN_TRY) {
      if (MP_LEN(m) == 1 && m->v[0] == primetab[i])
	rc = PGEN_DONE;
      else
	rc = PGEN_FAIL;
    }
  }

  /* --- Check for small primes --- */

  if (rc == PGEN_TRY)
    rc = smallenough(m);

  /* --- Done --- */

  mpfree(m->a, v);
  return (rc);
}

/* --- @pfilt_destroy@ --- *
 *
 * Arguments:	@pfilt *p@ = pointer to prime filtering context
 *
 * Returns:	---
 *
 * Use:		Discards a context and all the resources it holds.
 */

void pfilt_destroy(pfilt *p)
{
  mp_drop(p->m);
}

/* --- @pfilt_step@ --- *
 *
 * Arguments:	@pfilt *p@ = pointer to prime filtering context
 *		@mpw step@ = how much to step the number
 *
 * Returns:	One of the @PGEN@ result codes.
 *
 * Use:		Steps a number by a small amount.  Stepping is much faster
 *		than initializing with a new number.  The test performed is
 *		the same simple one used by @primetab_create@, so @PGEN_TRY@
 *		results should be followed up by a Rabin-Miller test.
 */

int pfilt_step(pfilt *p, mpw step)
{
  int rc = PGEN_TRY;
  int i;

  /* --- Add the step on to the number --- */

  p->m = mp_split(p->m);
  mp_ensure(p->m, MP_LEN(p->m) + 1);
  mpx_uaddn(p->m->v, p->m->vl, step);
  mp_shrink(p->m);

  /* --- Update the residue table --- */

  for (i = 0; i < NPRIME; i++) {
    p->r[i] = (p->r[i] + step) % primetab[i];
    if (!p->r[i] && rc == PGEN_TRY) {
      if (MP_LEN(p->m) == 1 && p->m->v[0] == primetab[i])
	rc = PGEN_DONE;
      else
	rc = PGEN_FAIL;
    }
  }

  /* --- Check for small primes --- */

  if (rc == PGEN_TRY)
    rc = smallenough(p->m);

  /* --- Done --- */

  return (rc);
}

/* --- @pfilt_muladd@ --- *
 *
 * Arguments:	@pfilt *p@ = destination prime filtering context
 *		@const pfilt *q@ = source prime filtering context
 *		@mpw m@ = number to multiply by
 *		@mpw a@ = number to add
 *
 * Returns:	One of the @PGEN@ result codes.
 *
 * Use:		Multiplies the number in a prime filtering context by a
 *		small value and then adds a small value.  The destination
 *		should either be uninitialized or the same as the source.
 *
 *		Common things to do include multiplying by 2 and adding 0 to
 *		turn a prime into a jump for finding other primes with @q@ as
 *		a factor of @p - 1@, or multiplying by 2 and adding 1.
 */

int pfilt_muladd(pfilt *p, const pfilt *q, mpw m, mpw a)
{
  int rc = PGEN_TRY;
  int i;

  /* --- Multiply the big number --- */

  {
    mp *d = mp_new(MP_LEN(q->m) + 2, q->m->f);
    mpx_umuln(d->v, d->vl, q->m->v, q->m->vl, m);
    mpx_uaddn(d->v, d->vl, a);
    if (p == q)
      mp_drop(p->m);
    mp_shrink(d);
    p->m = d;
  }

  /* --- Gallivant through the residue table --- */
      
  for (i = 0; i < NPRIME; i++) {
    p->r[i] = (q->r[i] * m + a) % primetab[i];
    if (!p->r[i] && rc == PGEN_TRY) {
      if (MP_LEN(p->m) == 1 && p->m->v[0] == primetab[i])
	rc = PGEN_DONE;
      else
	rc = PGEN_FAIL;
    }
  }

  /* --- Check for small primes --- */

  if (rc == PGEN_TRY)
    rc = smallenough(p->m);

  /* --- Finished --- */

  return (rc);
}

/* --- @pfilt_jump@ --- *
 *
 * Arguments:	@pfilt *p@ = pointer to prime filtering context
 *		@const pfilt *j@ = pointer to another filtering context
 *
 * Returns:	One of the @PGEN@ result codes.
 *
 * Use:		Steps a number by a large amount.  Even so, jumping is much
 *		faster than initializing a new number.  The test peformed is
 *		the same simple one used by @primetab_create@, so @PGEN_TRY@
 *		results should be followed up by a Rabin-Miller test.
 *
 *		Note that the number stored in the @j@ context is probably
 *		better off being even than prime.  The important thing is
 *		that all of the residues for the number have already been
 *		computed.
 */

int pfilt_jump(pfilt *p, const pfilt *j)
{
  int rc = PGEN_TRY;
  int i;

  /* --- Add the step on --- */

  p->m = mp_add(p->m, p->m, j->m);

  /* --- Update the residue table --- */

  for (i = 0; i < NPRIME; i++) {
    p->r[i] = p->r[i] + j->r[i];
    if (p->r[i] > primetab[i])
      p->r[i] -= primetab[i];
    if (!p->r[i] && rc == PGEN_TRY) {
      if (MP_LEN(p->m) == 1 && p->m->v[0] == primetab[i])
	rc = PGEN_DONE;
      else
	rc = PGEN_FAIL;
    }
  }

  /* --- Check for small primes --- */

  if (rc == PGEN_TRY)
    rc = smallenough(p->m);

  /* --- Done --- */

  return (rc);
}

/*----- That's all, folks -------------------------------------------------*/
Commit	Line	Data
9a8b0c8d	1	/* --c--
9a8b0c8d	2	*
9312c71f	3	* $Id: pfilt.c,v 1.4 2000/10/08 12:14:57 mdw Exp $
9a8b0c8d	4	*
	5	* Finding and testing prime numbers
	6	*
	7	* (c) 1999 Straylight/Edgeware
	8	*/
	9
	10	/----- Licensing notice --------------------------------------------------
	11	*
	12	* This file is part of Catacomb.
	13	*
	14	* Catacomb is free software; you can redistribute it and/or modify
	15	* it under the terms of the GNU Library General Public License as
	16	* published by the Free Software Foundation; either version 2 of the
	17	* License, or (at your option) any later version.
	18	*
	19	* Catacomb is distributed in the hope that it will be useful,
	20	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	21	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	22	* GNU Library General Public License for more details.
	23	*
	24	* You should have received a copy of the GNU Library General Public
	25	* License along with Catacomb; if not, write to the Free
	26	* Software Foundation, Inc., 59 Temple Place - Suite 330, Boston,
	27	* MA 02111-1307, USA.
	28	*/
	29
	30	/----- Revision history --------------------------------------------------
	31	*
	32	* $Log: pfilt.c,v $
9312c71f	33	* Revision 1.4 2000/10/08 12:14:57 mdw
	34	* Remove vestiges of @primorial@.
	35	*
b8e79eeb	36	* Revision 1.3 2000/08/15 21:44:27 mdw
	37	* (pfilt_smallfactor): New function for doing trial division the hard
	38	* way.
	39	*
	40	* (pfilt_create): Use @mpx_udivn@ for computing residues, for improved
	41	* performance.
	42	*
	43	* Pull the `small prime' test into a separate function, and do it
	44	* properly.
	45	*
87b63d41	46	* Revision 1.2 2000/06/17 11:54:27 mdw
	47	* Use new MP memory management functions.
	48	*
9a8b0c8d	49	* Revision 1.1 1999/12/22 15:49:39 mdw
	50	* Renamed from `pgen'. Reworking for new prime-search system.
	51	*
	52	* Revision 1.3 1999/12/10 23:28:35 mdw
	53	* Track suggested destination changes.
	54	*
	55	* Revision 1.2 1999/11/20 22:23:05 mdw
	56	* Add multiply-and-add function for Diffie-Hellman safe prime generation.
	57	*
	58	* Revision 1.1 1999/11/19 13:17:57 mdw
	59	* Prime number generator and tester.
	60	*
	61	*/
	62
	63	/----- Header files ------------------------------------------------------/
	64
	65	#include "mp.h"
b8e79eeb	66	#include "mpint.h"
9a8b0c8d	67	#include "pfilt.h"
	68	#include "pgen.h"
	69	#include "primetab.h"
	70
	71	/----- Main code ---------------------------------------------------------/
	72
b8e79eeb	73	/* --- @smallenough@ --- *
	74	*
	75	* Arguments: @mp *m@ = integer to test
	76	*
	77	* Returns: One of the @PGEN@ result codes.
	78	*
	79	* Use: Assuming that @m@ has been tested by trial division on every
	80	* prime in the small-primes array, this function will return
	81	* @PGEN_DONE@ if the number is less than the square of the
	82	* largest small prime.
	83	*/
	84
	85	static int smallenough(mp *m)
	86	{
	87	static mp *max = 0;
	88	int rc = PGEN_TRY;
	89
	90	if (!max) {
	91	max = mp_fromuint(MP_NEW, MAXPRIME);
	92	max = mp_sqr(max, max);
	93	max->a->n--; /* Permanent allocation */
	94	}
	95	if (MP_CMP(m, <, max))
	96	rc = PGEN_DONE;
	97	return (rc);
	98	}
	99
	100	/* --- @pfilt_smallfactor@ --- *
	101	*
	102	* Arguments: @mp *m@ = integer to test
	103	*
	104	* Returns: One of the @PGEN@ result codes.
	105	*
	106	* Use: Tests a number by dividing by a number of small primes. This
	107	* is a useful first step if you're testing random primes; for
	108	* sequential searches, @pfilt_create@ works better.
	109	*/
	110
	111	int pfilt_smallfactor(mp *m)
	112	{
	113	int rc = PGEN_TRY;
	114	int i;
	115	size_t sz = MP_LEN(m);
	116	mpw *v = mpalloc(m->a, sz);
	117
	118	/* --- Fill in the residues --- */
	119
	120	for (i = 0; i < NPRIME; i++) {
	121	if (!mpx_udivn(v, v + sz, m->v, m->vl, primetab[i])) {
	122	if (MP_LEN(m) == 1 && m->v[0] == primetab[i])
	123	rc = PGEN_DONE;
	124	else
	125	rc = PGEN_FAIL;
	126	}
	127	}
	128
	129	/* --- Check for small primes --- */
	130
	131	if (rc == PGEN_TRY)
	132	rc = smallenough(m);
	133
	134	/* --- Done --- */
	135
	136	mpfree(m->a, v);
137	return (rc);
138	}
139
9a8b0c8d	140	/* --- @pfilt_create@ --- *
	141	*
	142	* Arguments: @pfilt *p@ = pointer to prime filtering context
	143	* @mp *m@ = pointer to initial number to test
	144	*
	145	* Returns: One of the @PGEN@ result codes.
	146	*
	147	* Use: Tests an initial number for primality by computing its
	148	* residue modulo various small prime numbers. This is fairly
	149	* quick, but not particularly certain. If a @PGEN_TRY@
	150	* result is returned, perform Rabin-Miller tests to confirm.
	151	*/
	152
	153	int pfilt_create(pfilt p, mp m)
	154	{
	155	int rc = PGEN_TRY;
	156	int i;
b8e79eeb	157	size_t sz = MP_LEN(m);
b8e79eeb	158	mpw *v = mpalloc(m->a, sz);
9a8b0c8d	159
	160	/* --- Take a copy of the number --- */
	161
	162	mp_shrink(m);
	163	p->m = MP_COPY(m);
	164
	165	/* --- Fill in the residues --- */
	166
9a8b0c8d	167	for (i = 0; i < NPRIME; i++) {
b8e79eeb	168	p->r[i] = mpx_udivn(v, v + sz, m->v, m->vl, primetab[i]);
9a8b0c8d	169	if (!p->r[i] && rc == PGEN_TRY) {
	170	if (MP_LEN(m) == 1 && m->v[0] == primetab[i])
	171	rc = PGEN_DONE;
	172	else
	173	rc = PGEN_FAIL;
	174	}
	175	}
	176
b8e79eeb	177	/* --- Check for small primes --- */
	178
	179	if (rc == PGEN_TRY)
	180	rc = smallenough(m);
	181
9a8b0c8d	182	/* --- Done --- */
9a8b0c8d	183
b8e79eeb	184	mpfree(m->a, v);
9a8b0c8d	185	return (rc);
	186	}
	187
	188	/* --- @pfilt_destroy@ --- *
	189	*
	190	* Arguments: @pfilt *p@ = pointer to prime filtering context
	191	*
	192	* Returns: ---
	193	*
	194	* Use: Discards a context and all the resources it holds.
	195	*/
	196
	197	void pfilt_destroy(pfilt *p)
	198	{
	199	mp_drop(p->m);
	200	}
	201
	202	/* --- @pfilt_step@ --- *
	203	*
	204	* Arguments: @pfilt *p@ = pointer to prime filtering context
	205	* @mpw step@ = how much to step the number
	206	*
	207	* Returns: One of the @PGEN@ result codes.
	208	*
	209	* Use: Steps a number by a small amount. Stepping is much faster
	210	* than initializing with a new number. The test performed is
	211	* the same simple one used by @primetab_create@, so @PGEN_TRY@
	212	* results should be followed up by a Rabin-Miller test.
	213	*/
	214
	215	int pfilt_step(pfilt *p, mpw step)
	216	{
	217	int rc = PGEN_TRY;
	218	int i;
	219
	220	/* --- Add the step on to the number --- */
	221
	222	p->m = mp_split(p->m);
	223	mp_ensure(p->m, MP_LEN(p->m) + 1);
	224	mpx_uaddn(p->m->v, p->m->vl, step);
	225	mp_shrink(p->m);
	226
	227	/* --- Update the residue table --- */
	228
	229	for (i = 0; i < NPRIME; i++) {
	230	p->r[i] = (p->r[i] + step) % primetab[i];
	231	if (!p->r[i] && rc == PGEN_TRY) {
	232	if (MP_LEN(p->m) == 1 && p->m->v[0] == primetab[i])
	233	rc = PGEN_DONE;
	234	else
	235	rc = PGEN_FAIL;
	236	}
	237	}
	238
b8e79eeb	239	/* --- Check for small primes --- */
9a8b0c8d	240
b8e79eeb	241	if (rc == PGEN_TRY)
b8e79eeb	242	rc = smallenough(p->m);
9a8b0c8d	243
	244	/* --- Done --- */
	245
	246	return (rc);
	247	}
	248
	249	/* --- @pfilt_muladd@ --- *
	250	*
	251	* Arguments: @pfilt *p@ = destination prime filtering context
	252	* @const pfilt *q@ = source prime filtering context
	253	* @mpw m@ = number to multiply by
	254	* @mpw a@ = number to add
	255	*
	256	* Returns: One of the @PGEN@ result codes.
	257	*
	258	* Use: Multiplies the number in a prime filtering context by a
	259	* small value and then adds a small value. The destination
	260	* should either be uninitialized or the same as the source.
	261	*
	262	* Common things to do include multiplying by 2 and adding 0 to
	263	* turn a prime into a jump for finding other primes with @q@ as
	264	* a factor of @p - 1@, or multiplying by 2 and adding 1.
	265	*/
	266
	267	int pfilt_muladd(pfilt p, const pfilt q, mpw m, mpw a)
	268	{
	269	int rc = PGEN_TRY;
	270	int i;
	271
	272	/* --- Multiply the big number --- */
	273
	274	{
87b63d41	275	mp *d = mp_new(MP_LEN(q->m) + 2, q->m->f);
9a8b0c8d	276	mpx_umuln(d->v, d->vl, q->m->v, q->m->vl, m);
9a8b0c8d	277	mpx_uaddn(d->v, d->vl, a);
9a8b0c8d	278	if (p == q)
	279	mp_drop(p->m);
	280	mp_shrink(d);
	281	p->m = d;
	282	}
	283
	284	/* --- Gallivant through the residue table --- */
	285
	286	for (i = 0; i < NPRIME; i++) {
	287	p->r[i] = (q->r[i] * m + a) % primetab[i];
	288	if (!p->r[i] && rc == PGEN_TRY) {
	289	if (MP_LEN(p->m) == 1 && p->m->v[0] == primetab[i])
	290	rc = PGEN_DONE;
	291	else
	292	rc = PGEN_FAIL;
	293	}
	294	}
	295
b8e79eeb	296	/* --- Check for small primes --- */
9a8b0c8d	297
b8e79eeb	298	if (rc == PGEN_TRY)
b8e79eeb	299	rc = smallenough(p->m);
9a8b0c8d	300
	301	/* --- Finished --- */
	302
	303	return (rc);
	304	}
	305
	306	/* --- @pfilt_jump@ --- *
	307	*
	308	* Arguments: @pfilt *p@ = pointer to prime filtering context
	309	* @const pfilt *j@ = pointer to another filtering context
	310	*
	311	* Returns: One of the @PGEN@ result codes.
	312	*
	313	* Use: Steps a number by a large amount. Even so, jumping is much
	314	* faster than initializing a new number. The test peformed is
	315	* the same simple one used by @primetab_create@, so @PGEN_TRY@
	316	* results should be followed up by a Rabin-Miller test.
	317	*
	318	* Note that the number stored in the @j@ context is probably
	319	* better off being even than prime. The important thing is
	320	* that all of the residues for the number have already been
	321	* computed.
	322	*/
	323
	324	int pfilt_jump(pfilt p, const pfilt j)
	325	{
	326	int rc = PGEN_TRY;
	327	int i;
	328
	329	/* --- Add the step on --- */
	330
	331	p->m = mp_add(p->m, p->m, j->m);
	332
	333	/* --- Update the residue table --- */
	334
	335	for (i = 0; i < NPRIME; i++) {
	336	p->r[i] = p->r[i] + j->r[i];
	337	if (p->r[i] > primetab[i])
	338	p->r[i] -= primetab[i];
	339	if (!p->r[i] && rc == PGEN_TRY) {
	340	if (MP_LEN(p->m) == 1 && p->m->v[0] == primetab[i])
	341	rc = PGEN_DONE;
	342	else
	343	rc = PGEN_FAIL;
	344	}
	345	}
	346
b8e79eeb	347	/* --- Check for small primes --- */
9a8b0c8d	348
b8e79eeb	349	if (rc == PGEN_TRY)
b8e79eeb	350	rc = smallenough(p->m);
9a8b0c8d	351
	352	/* --- Done --- */
	353
	354	return (rc);
	355	}
	356
	357	/----- That's all, folks -------------------------------------------------/