[catacomb] / math / strongprime.c

/* -*-c-*-
 *
 * Generate `strong' 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.
 */

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

#include <mLib/dstr.h>
#include <mLib/macros.h>

#include "grand.h"
#include "mp.h"
#include "mpmont.h"
#include "mprand.h"
#include "pgen.h"
#include "pfilt.h"
#include "rabin.h"

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

/* Oh, just shut up. */
CLANG_WARNING("-Wempty-body")

/* --- @strongprime_setup@ --- *
 *
 * Arguments:	@const char *name@ = pointer to name root
 *		@mp *d@ = destination for search start point
 *		@pfilt *f@ = where to store filter jump context
 *		@unsigned nbits@ = number of bits wanted
 *		@grand *r@ = random number source
 *		@unsigned n@ = number of attempts to make
 *		@pgen_proc *event@ = event handler function
 *		@void *ectx@ = argument for the event handler
 *
 * Returns:	A starting point for a `strong' prime search, or zero.
 *
 * Use:		Sets up for a strong prime search, so that primes with
 *		particular properties can be found.  It's probably important
 *		to note that the number left in the filter context @f@ is
 *		congruent to 2 (mod 4); that the jump value is twice the
 *		product of two large primes; and that the starting point is
 *		at least %$3 \cdot 2^{N-2}$%.  (Hence, if you multiply two
 *		such numbers, the product is at least
 *
 *			%$9 \cdot 2^{2N-4} > 2^{2N-1}$%
 *
 *		i.e., it will be (at least) a %$2 N$%-bit value.
 */

mp *strongprime_setup(const char *name, mp *d, pfilt *f, unsigned nbits,
		      grand *r, unsigned n, pgen_proc *event, void *ectx)
{
  mp *s, *t, *q;
  dstr dn = DSTR_INIT;
  unsigned slop, nb, u, i;

  mp *rr = d;
  pgen_filterctx c;
  pgen_jumpctx j;
  rabin rb;

  /* --- Figure out how large the smaller primes should be --- *
   *
   * We want them to be `as large as possible', subject to the constraint
   * that we produce a number of the requested size at the end.  This is
   * tricky, because the final prime search is going to involve quite large
   * jumps from its starting point; the size of the jumps are basically
   * determined by our choice here, and if they're too big then we won't find
   * a prime in time.
   *
   * Let's suppose we're trying to make an %$N$%-bit prime.  The expected
   * number of steps tends to increase linearly with size, i.e., we need to
   * take about %2^k N$% steps for some %$k$%.  If we're jumping by a
   * %$J$%-bit quantity each time, from an %$N$%-bit starting point, then we
   * will only be able to find a match if %$2^k N 2^{J-1} \le 2^{N-1}$%,
   * i.e., if %$J \le N - (k + \log_2 N)$%.
   *
   * Experimentation shows that taking %$k + \log_2 N = 12$% works well for
   * %$N = 1024$%, so %$k = 2$%.  Add a few extra bits for luck.
   */

  for (i = 1; i && nbits >> i; i <<= 1); assert(i);
  for (slop = 6, nb = nbits; nb > 1; i >>= 1) {
    u = nb >> i;
    if (u) { slop += i; nb = u; }
  }
  if (nbits/2 <= slop) return (0);

  /* --- Choose two primes %$s$% and %$t$% of half the required size --- */

  nb = nbits/2 - slop;
  c.step = 1;

  rr = mprand(rr, nb, r, 1);
  DRESET(&dn); dstr_putf(&dn, "%s [s]", name);
  if ((s = pgen(dn.buf, MP_NEWSEC, rr, event, ectx, n, pgen_filter, &c,
		rabin_iters(nb), pgen_test, &rb)) == 0)
    goto fail_s;

  rr = mprand(rr, nb, r, 1);
  DRESET(&dn); dstr_putf(&dn, "%s [t]", name);
  if ((t = pgen(dn.buf, MP_NEWSEC, rr, event, ectx, n, pgen_filter, &c,
		rabin_iters(nb), pgen_test, &rb)) == 0)
    goto fail_t;

  /* --- Choose a suitable value for %$r = 2it + 1$% for some %$i$% --- *
   *
   * Then %$r \equiv 1 \pmod{t}$%, i.e., %$r - 1$% is a multiple of %$t$%.
   */

  rr = mp_lsl(rr, t, 1);
  pfilt_create(&c.f, rr);
  rr = mp_lsl(rr, rr, slop - 1);
  rr = mp_add(rr, rr, MP_ONE);
  DRESET(&dn); dstr_putf(&dn, "%s [r]", name);
  j.j = &c.f;
  q = pgen(dn.buf, MP_NEW, rr, event, ectx, n, pgen_jump, &j,
	   rabin_iters(nb + slop), pgen_test, &rb);
  pfilt_destroy(&c.f);
  if (!q)
    goto fail_r;

  /* --- Select a suitable congruence class for %$p$% --- *
   *
   * This computes %$p_0 = 2 s (s^{-1} \bmod r) - 1$%.  Then %$p_0 + 1$% is
   * clearly a multiple of %$s$%, and
   *
   *	%$p_0 - 1 \equiv 2 s s^{-1} - 2 \equiv 0 \pmod{r}$%
   *
   * is a multiple of %$r$%.
   */

  rr = mp_modinv(rr, s, q);
  rr = mp_mul(rr, rr, s);
  rr = mp_lsl(rr, rr, 1);
  rr = mp_sub(rr, rr, MP_ONE);

  /* --- Pick a starting point for the search --- *
   *
   * Select %$3 \cdot 2^{N-2} < p_1 < 2^N$% at random, only with
   * %$p_1 \equiv p_0 \pmod{2 r s}$.
   */

  {
    mp *x, *y;
    x = mp_mul(MP_NEW, q, s);
    x = mp_lsl(x, x, 1);
    pfilt_create(f, x); /* %$2 r s$% */
    y = mprand(MP_NEW, nbits, r, 0);
    y = mp_setbit(y, y, nbits - 2);
    rr = mp_leastcongruent(rr, y, rr, x);
    mp_drop(x); mp_drop(y);
  }

  /* --- Return the result --- */

  mp_drop(q);
  mp_drop(t);
  mp_drop(s);
  dstr_destroy(&dn);
  return (rr);

  /* --- Tidy up if something failed --- */

fail_r:
  mp_drop(t);
fail_t:
  mp_drop(s);
fail_s:
  mp_drop(rr);
  dstr_destroy(&dn);
  return (0);
}

/* --- @strongprime@ --- *
 *
 * Arguments:	@const char *name@ = pointer to name root
 *		@mp *d@ = destination integer
 *		@unsigned nbits@ = number of bits wanted
 *		@grand *r@ = random number source
 *		@unsigned n@ = number of attempts to make
 *		@pgen_proc *event@ = event handler function
 *		@void *ectx@ = argument for the event handler
 *
 * Returns:	A `strong' prime, or zero.
 *
 * Use:		Finds `strong' primes.  A strong prime %$p$% is such that
 *
 *		  * %$p - 1$% has a large prime factor %$r$%,
 *		  * %$p + 1$% has a large prime factor %$s$%, and
 *		  * %$r - 1$% has a large prime factor %$t$%.
 */

mp *strongprime(const char *name, mp *d, unsigned nbits, grand *r,
		unsigned n, pgen_proc *event, void *ectx)
{
  mp *p;
  pfilt f;
  pgen_jumpctx j;
  rabin rb;

  if (d) mp_copy(d);
  p = strongprime_setup(name, d, &f, nbits, r, n, event, ectx);
  if (!p) { mp_drop(d); return (0); }
  j.j = &f;
  p = pgen(name, p, p, event, ectx, n, pgen_jump, &j,
	   rabin_iters(nbits), pgen_test, &rb);
  if (mp_bits(p) != nbits) { mp_drop(p); return (0); }
  pfilt_destroy(&f);
  mp_drop(d);
  return (p);
}

/*----- That's all, folks -------------------------------------------------*/
Commit	Line	Data
a30942cc	1	/* --c--
a30942cc	2	*
a30942cc	3	* Generate `strong' prime numbers
	4	*
	5	* (c) 1999 Straylight/Edgeware
	6	*/
	7
45c0fd36	8	/----- Licensing notice --------------------------------------------------
a30942cc	9	*
	10	* This file is part of Catacomb.
	11	*
	12	* Catacomb is free software; you can redistribute it and/or modify
	13	* it under the terms of the GNU Library General Public License as
	14	* published by the Free Software Foundation; either version 2 of the
	15	* License, or (at your option) any later version.
45c0fd36	16	*
a30942cc	17	* Catacomb is distributed in the hope that it will be useful,
	18	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	19	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	20	* GNU Library General Public License for more details.
45c0fd36	21	*
a30942cc	22	* You should have received a copy of the GNU Library General Public
	23	* License along with Catacomb; if not, write to the Free
	24	* Software Foundation, Inc., 59 Temple Place - Suite 330, Boston,
	25	* MA 02111-1307, USA.
	26	*/
	27
a30942cc	28	/----- Header files ------------------------------------------------------/
	29
	30	#include <mLib/dstr.h>
df5a67b8	31	#include <mLib/macros.h>
a30942cc	32
a30942cc	33	#include "grand.h"
a30942cc	34	#include "mp.h"
	35	#include "mpmont.h"
	36	#include "mprand.h"
	37	#include "pgen.h"
	38	#include "pfilt.h"
	39	#include "rabin.h"
	40
	41	/----- Main code ---------------------------------------------------------/
	42
df5a67b8 MW	43	/* Oh, just shut up. */
	44	CLANG_WARNING("-Wempty-body")
	45
052b36d0	46	/* --- @strongprime_setup@ --- *
a30942cc	47	*
a30942cc	48	* Arguments: @const char *name@ = pointer to name root
052b36d0	49	* @mp *d@ = destination for search start point
052b36d0	50	* @pfilt *f@ = where to store filter jump context
a30942cc	51	* @unsigned nbits@ = number of bits wanted
	52	* @grand *r@ = random number source
	53	* @unsigned n@ = number of attempts to make
	54	* @pgen_proc *event@ = event handler function
	55	* @void *ectx@ = argument for the event handler
	56	*
052b36d0	57	* Returns: A starting point for a `strong' prime search, or zero.
a30942cc	58	*
052b36d0	59	* Use: Sets up for a strong prime search, so that primes with
	60	* particular properties can be found. It's probably important
	61	* to note that the number left in the filter context @f@ is
e62e86d3 MW	62	* congruent to 2 (mod 4); that the jump value is twice the
	63	* product of two large primes; and that the starting point is
	64	* at least %$3 \cdot 2^{N-2}$%. (Hence, if you multiply two
	65	* such numbers, the product is at least
	66	*
	67	* %$9 \cdot 2^{2N-4} > 2^{2N-1}$%
	68	*
	69	* i.e., it will be (at least) a %$2 N$%-bit value.
a30942cc	70	*/
a30942cc	71
052b36d0	72	mp strongprime_setup(const char name, mp d, pfilt f, unsigned nbits,
052b36d0	73	grand r, unsigned n, pgen_proc event, void *ectx)
a30942cc	74	{
052b36d0	75	mp s, t, *q;
a30942cc	76	dstr dn = DSTR_INIT;
32bd36cf	77	unsigned slop, nb, u, i;
a30942cc	78
052b36d0	79	mp *rr = d;
a30942cc	80	pgen_filterctx c;
052b36d0	81	pgen_jumpctx j;
a30942cc	82	rabin rb;
a30942cc	83
32bd36cf	84	/* --- Figure out how large the smaller primes should be --- *
a30942cc	85	*
32bd36cf MW	86	* We want them to be `as large as possible', subject to the constraint
	87	* that we produce a number of the requested size at the end. This is
	88	* tricky, because the final prime search is going to involve quite large
	89	* jumps from its starting point; the size of the jumps are basically
	90	* determined by our choice here, and if they're too big then we won't find
	91	* a prime in time.
	92	*
	93	* Let's suppose we're trying to make an %$N$%-bit prime. The expected
	94	* number of steps tends to increase linearly with size, i.e., we need to
	95	* take about %2^k N$% steps for some %$k$%. If we're jumping by a
	96	* %$J$%-bit quantity each time, from an %$N$%-bit starting point, then we
	97	* will only be able to find a match if %$2^k N 2^{J-1} \le 2^{N-1}$%,
	98	* i.e., if %$J \le N - (k + \log_2 N)$%.
	99	*
	100	* Experimentation shows that taking %$k + \log_2 N = 12$% works well for
540ff246	101	* %$N = 1024$%, so %$k = 2$%. Add a few extra bits for luck.
a30942cc	102	*/
a30942cc	103
32bd36cf	104	for (i = 1; i && nbits >> i; i <<= 1); assert(i);
540ff246	105	for (slop = 6, nb = nbits; nb > 1; i >>= 1) {
32bd36cf MW	106	u = nb >> i;
	107	if (u) { slop += i; nb = u; }
	108	}
	109	if (nbits/2 <= slop) return (0);
a30942cc	110
	111	/* --- Choose two primes %$s$% and %$t$% of half the required size --- */
	112
32bd36cf	113	nb = nbits/2 - slop;
a30942cc	114	c.step = 1;
a30942cc	115
0b09aab8	116	rr = mprand(rr, nb, r, 1);
a30942cc	117	DRESET(&dn); dstr_putf(&dn, "%s [s]", name);
47566c4d	118	if ((s = pgen(dn.buf, MP_NEWSEC, rr, event, ectx, n, pgen_filter, &c,
0b09aab8	119	rabin_iters(nb), pgen_test, &rb)) == 0)
a30942cc	120	goto fail_s;
a30942cc	121
0b09aab8	122	rr = mprand(rr, nb, r, 1);
a30942cc	123	DRESET(&dn); dstr_putf(&dn, "%s [t]", name);
47566c4d	124	if ((t = pgen(dn.buf, MP_NEWSEC, rr, event, ectx, n, pgen_filter, &c,
0b09aab8	125	rabin_iters(nb), pgen_test, &rb)) == 0)
a30942cc	126	goto fail_t;
a30942cc	127
bd9fe975 MW	128	/* --- Choose a suitable value for %$r = 2it + 1$% for some %$i$% --- *
	129	*
	130	* Then %$r \equiv 1 \pmod{t}$%, i.e., %$r - 1$% is a multiple of %$t$%.
	131	*/
a30942cc	132
	133	rr = mp_lsl(rr, t, 1);
	134	pfilt_create(&c.f, rr);
32bd36cf	135	rr = mp_lsl(rr, rr, slop - 1);
a30942cc	136	rr = mp_add(rr, rr, MP_ONE);
a30942cc	137	DRESET(&dn); dstr_putf(&dn, "%s [r]", name);
052b36d0	138	j.j = &c.f;
052b36d0	139	q = pgen(dn.buf, MP_NEW, rr, event, ectx, n, pgen_jump, &j,
32bd36cf	140	rabin_iters(nb + slop), pgen_test, &rb);
a30942cc	141	pfilt_destroy(&c.f);
052b36d0	142	if (!q)
052b36d0	143	goto fail_r;
a30942cc	144
e62e86d3	145	/* --- Select a suitable congruence class for %$p$% --- *
a30942cc	146	*
bd9fe975 MW	147	* This computes %$p_0 = 2 s (s^{-1} \bmod r) - 1$%. Then %$p_0 + 1$% is
	148	* clearly a multiple of %$s$%, and
	149	*
	150	* %$p_0 - 1 \equiv 2 s s^{-1} - 2 \equiv 0 \pmod{r}$%
	151	*
	152	* is a multiple of %$r$%.
a30942cc	153	*/
a30942cc	154
bd490236 MW	155	rr = mp_modinv(rr, s, q);
	156	rr = mp_mul(rr, rr, s);
	157	rr = mp_lsl(rr, rr, 1);
	158	rr = mp_sub(rr, rr, MP_ONE);
a30942cc	159
e62e86d3 MW	160	/* --- Pick a starting point for the search --- *
	161	*
	162	* Select %$3 \cdot 2^{N-2} < p_1 < 2^N$% at random, only with
	163	* %$p_1 \equiv p_0 \pmod{2 r s}$.
	164	*/
a30942cc	165
a30942cc	166	{
0b09aab8	167	mp x, y;
a30942cc	168	x = mp_mul(MP_NEW, q, s);
a30942cc	169	x = mp_lsl(x, x, 1);
e62e86d3 MW	170	pfilt_create(f, x); /* %$2 r s$% */
	171	y = mprand(MP_NEW, nbits, r, 0);
	172	y = mp_setbit(y, y, nbits - 2);
0b09aab8 MW	173	rr = mp_leastcongruent(rr, y, rr, x);
0b09aab8 MW	174	mp_drop(x); mp_drop(y);
a30942cc	175	}
a30942cc	176
052b36d0	177	/* --- Return the result --- */
a30942cc	178
a30942cc	179	mp_drop(q);
052b36d0	180	mp_drop(t);
	181	mp_drop(s);
	182	dstr_destroy(&dn);
	183	return (rr);
	184
	185	/* --- Tidy up if something failed --- */
	186
a30942cc	187	fail_r:
a30942cc	188	mp_drop(t);
	189	fail_t:
	190	mp_drop(s);
	191	fail_s:
	192	mp_drop(rr);
	193	dstr_destroy(&dn);
052b36d0	194	return (0);
a30942cc	195	}
a30942cc	196
052b36d0	197	/* --- @strongprime@ --- *
	198	*
	199	* Arguments: @const char *name@ = pointer to name root
	200	* @mp *d@ = destination integer
	201	* @unsigned nbits@ = number of bits wanted
	202	* @grand *r@ = random number source
	203	* @unsigned n@ = number of attempts to make
	204	* @pgen_proc *event@ = event handler function
	205	* @void *ectx@ = argument for the event handler
	206	*
	207	* Returns: A `strong' prime, or zero.
	208	*
	209	* Use: Finds `strong' primes. A strong prime %$p$% is such that
	210	*
	211	* * %$p - 1$% has a large prime factor %$r$%,
	212	* * %$p + 1$% has a large prime factor %$s$%, and
	213	* * %$r - 1$% has a large prime factor %$t$%.
052b36d0	214	*/
	215
	216	mp strongprime(const char name, mp d, unsigned nbits, grand r,
	217	unsigned n, pgen_proc event, void ectx)
	218	{
285bf989	219	mp *p;
052b36d0	220	pfilt f;
	221	pgen_jumpctx j;
	222	rabin rb;
45c0fd36	223
285bf989 MW	224	if (d) mp_copy(d);
	225	p = strongprime_setup(name, d, &f, nbits, r, n, event, ectx);
	226	if (!p) { mp_drop(d); return (0); }
052b36d0	227	j.j = &f;
285bf989	228	p = pgen(name, p, p, event, ectx, n, pgen_jump, &j,
052b36d0	229	rabin_iters(nbits), pgen_test, &rb);
32bd36cf	230	if (mp_bits(p) != nbits) { mp_drop(p); return (0); }
052b36d0	231	pfilt_destroy(&f);
285bf989 MW	232	mp_drop(d);
285bf989 MW	233	return (p);
052b36d0	234	}
052b36d0	235
a30942cc	236	/----- That's all, folks -------------------------------------------------/