[u/mdw/catacomb] / math / mpcrt.c

/* -*-c-*-
 *
 * Chinese Remainder Theorem computations (Gauss's algorithm)
 *
 * (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 "mp.h"
#include "mpcrt.h"
#include "mpmul.h"
#include "mpbarrett.h"

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

/* --- @mpcrt_create@ --- *
 *
 * Arguments:	@mpcrt *c@ = pointer to CRT context
 *		@mpcrt_mod *v@ = pointer to vector of moduli
 *		@size_t k@ = number of moduli
 *		@mp *n@ = product of all moduli (@MP_NEW@ if unknown)
 *
 * Returns:	---
 *
 * Use:		Initializes a context for solving Chinese Remainder Theorem
 *		problems.  The vector of moduli can be incomplete.  Omitted
 *		items must be left as null pointers.  Not all combinations of
 *		missing things can be coped with, even if there is
 *		technically enough information to cope.  For example, if @n@
 *		is unspecified, all the @m@ values must be present, even if
 *		there is one modulus with both @m@ and @n@ (from which the
 *		product of all moduli could clearly be calculated).
 */

void mpcrt_create(mpcrt *c, mpcrt_mod *v, size_t k, mp *n)
{
  size_t i;

  /* --- Simple initialization things --- */

  c->k = k;
  c->v = v;

  /* --- Work out @n@ if I don't have it already --- */

  if (n != MP_NEW)
    n = MP_COPY(n);
  else {
    mpmul mm;
    mpmul_init(&mm);
    for (i = 0; i < k; i++)
      mpmul_add(&mm, v[i].m);
    n = mpmul_done(&mm);
  }

  /* --- A quick hack if %$k = 2$% --- */

  if (k == 2) {

    /* --- The %$n / n_i$% values are trivial in this case --- */

    if (!v[0].n)
      v[0].n = MP_COPY(v[1].m);
    if (!v[1].n)
      v[1].n = MP_COPY(v[0].m);

    /* --- Now sort out the inverses --- *
     *
     * @mp_gcd@ will ensure that the first argument is negative.
     */

    if (!v[0].ni && !v[1].ni) {
      mp *g = MP_NEW;
      mp_gcd(&g, &v[0].ni, &v[1].ni, v[0].n, v[1].n);
      assert(MP_EQ(g, MP_ONE));
      mp_drop(g);
      v[0].ni = mp_add(v[0].ni, v[0].ni, v[1].n);
    } else {
      int i, j;
      mp *x;

      if (!v[0].ni)
	i = 0, j = 1;
      else
	i = 1, j = 0;

      x = mp_mul(MP_NEW, v[j].n, v[j].ni);
      x = mp_sub(x, x, MP_ONE);
      mp_div(&x, 0, x, v[i].n);
      v[i].ni = x;
    }
  }

  /* --- Set up the Barrett context --- */

  mpbarrett_create(&c->mb, n);

  /* --- Walk through filling in @n@, @ni@ and @nnir@ --- */

  for (i = 0; i < k; i++) {
    if (!v[i].n)
      mp_div(&v[i].n, 0, n, v[i].m);
    if (!v[i].ni)
      v[i].ni = mp_modinv(MP_NEW, v[i].n, v[i].m);
    if (!v[i].nni)
      v[i].nni = mp_mul(MP_NEW, v[i].n, v[i].ni);
  }

  /* --- Done --- */

  mp_drop(n);
}

/* --- @mpcrt_destroy@ --- *
 *
 * Arguments:	@mpcrt *c@ - pointer to CRT context
 *
 * Returns:	---
 *
 * Use:		Destroys a CRT context, releasing all the resources it holds.
 */

void mpcrt_destroy(mpcrt *c)
{
  size_t i;

  for (i = 0; i < c->k; i++) {
    if (c->v[i].m) mp_drop(c->v[i].m);
    if (c->v[i].n) mp_drop(c->v[i].n);
    if (c->v[i].ni) mp_drop(c->v[i].ni);
    if (c->v[i].nni) mp_drop(c->v[i].nni);
  }
  mpbarrett_destroy(&c->mb);
}

/* --- @mpcrt_solve@ --- *
 *
 * Arguments:	@mpcrt *c@ = pointer to CRT context
 *		@mp *d@ = fake destination
 *		@mp **v@ = array of residues
 *
 * Returns:	The unique solution modulo the product of the individual
 *		moduli, which leaves the given residues.
 *
 * Use:		Constructs a result given its residue modulo an array of
 *		coprime integers.  This can be used to improve performance of
 *		RSA encryption or Blum-Blum-Shub generation if the factors
 *		of the modulus are known, since results can be computed mod
 *		each of the individual factors and then combined at the end.
 *		This is rather faster than doing the full-scale modular
 *		exponentiation.
 */

mp *mpcrt_solve(mpcrt *c, mp *d, mp **v)
{
  mp *a = MP_ZERO;
  mp *x = MP_NEW;
  size_t i;

  for (i = 0; i < c->k; i++) {
    x = mp_mul(x, c->v[i].nni, v[i]);
    x = mpbarrett_reduce(&c->mb, x, x);
    a = mp_add(a, a, x);
  }
  if (x)
    MP_DROP(x);
  a = mpbarrett_reduce(&c->mb, a, a);
  if (d != MP_NEW)
    MP_DROP(d);
  return (a);
}

/*----- Test rig ----------------------------------------------------------*/

#ifdef TEST_RIG

static int verify(size_t n, dstr *v)
{
  mpcrt_mod *m = xmalloc(n * sizeof(mpcrt_mod));
  mp **r = xmalloc(n * sizeof(mp *));
  mpcrt c;
  mp *a, *b;
  size_t i;
  int ok = 1;

  for (i = 0; i < n; i++) {
    r[i] = *(mp **)v[2 * i].buf;
    m[i].m = *(mp **)v[2 * i + 1].buf;
    m[i].n = 0;
    m[i].ni = 0;
    m[i].nni = 0;
  }
  a = *(mp **)v[2 * n].buf;

  mpcrt_create(&c, m, n, 0);
  b = mpcrt_solve(&c, MP_NEW, r);

  if (!MP_EQ(a, b)) {
    fputs("\n*** failed\n", stderr);
    fputs("n = ", stderr);
    mp_writefile(c.mb.m, stderr, 10);
    for (i = 0; i < n; i++) {
      fprintf(stderr, "\nr[%lu] = ", (unsigned long)i);
      mp_writefile(r[i], stderr, 10);
      fprintf(stderr, "\nm[%lu] = ", (unsigned long)i);
      mp_writefile(m[i].m, stderr, 10);
      fprintf(stderr, "\nN[%lu] = ", (unsigned long)i);
      mp_writefile(m[i].n, stderr, 10);
      fprintf(stderr, "\nM[%lu] = ", (unsigned long)i);
      mp_writefile(m[i].ni, stderr, 10);
    }
    fputs("\nresult = ", stderr);
    mp_writefile(b, stderr, 10);
    fputs("\nexpect = ", stderr);
    mp_writefile(a, stderr, 10);
    fputc('\n', stderr);
    ok = 0;
  }

  for (i = 0; i < n; i++)
    mp_drop(r[i]);
  mp_drop(a);
  mp_drop(b);
  mpcrt_destroy(&c);
  xfree(m);
  xfree(r);
  assert(mparena_count(MPARENA_GLOBAL) == 0);
  return (ok);
}

static int crt1(dstr *v) { return verify(1, v); }
static int crt2(dstr *v) { return verify(2, v); }
static int crt3(dstr *v) { return verify(3, v); }
static int crt4(dstr *v) { return verify(4, v); }
static int crt5(dstr *v) { return verify(5, v); }

static test_chunk tests[] = {
  { "crt-1", crt1, { &type_mp, &type_mp,
		    &type_mp, 0 } },
  { "crt-2", crt2, { &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, 0 } },
  { "crt-3", crt3, { &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, 0 } },
  { "crt-4", crt4, { &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, 0 } },
  { "crt-5", crt5, { &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, &type_mp,
		    &type_mp, 0 } },
  { 0, 0, { 0 } }
};

int main(int argc, char *argv[])
{
  sub_init();
  test_run(argc, argv, tests, SRCDIR "/t/mpcrt");
  return (0);
}

#endif

/*----- That's all, folks -------------------------------------------------*/
Commit	Line	Data
5ee4c893	1	/* --c--
5ee4c893	2	*
5ee4c893	3	* Chinese Remainder Theorem computations (Gauss's algorithm)
	4	*
	5	* (c) 1999 Straylight/Edgeware
	6	*/
	7
45c0fd36	8	/----- Licensing notice --------------------------------------------------
5ee4c893	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	*
5ee4c893	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	*
5ee4c893	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
5ee4c893	28	/----- Header files ------------------------------------------------------/
	29
	30	#include "mp.h"
	31	#include "mpcrt.h"
5e1601ef	32	#include "mpmul.h"
5bda60bd	33	#include "mpbarrett.h"
5ee4c893	34
	35	/----- Main code ---------------------------------------------------------/
	36
	37	/* --- @mpcrt_create@ --- *
	38	*
	39	* Arguments: @mpcrt *c@ = pointer to CRT context
	40	* @mpcrt_mod *v@ = pointer to vector of moduli
	41	* @size_t k@ = number of moduli
	42	* @mp *n@ = product of all moduli (@MP_NEW@ if unknown)
	43	*
	44	* Returns: ---
	45	*
	46	* Use: Initializes a context for solving Chinese Remainder Theorem
	47	* problems. The vector of moduli can be incomplete. Omitted
	48	* items must be left as null pointers. Not all combinations of
	49	* missing things can be coped with, even if there is
	50	* technically enough information to cope. For example, if @n@
	51	* is unspecified, all the @m@ values must be present, even if
	52	* there is one modulus with both @m@ and @n@ (from which the
	53	* product of all moduli could clearly be calculated).
	54	*/
	55
	56	void mpcrt_create(mpcrt c, mpcrt_mod v, size_t k, mp *n)
	57	{
5ee4c893	58	size_t i;
	59
	60	/* --- Simple initialization things --- */
	61
	62	c->k = k;
	63	c->v = v;
	64
	65	/* --- Work out @n@ if I don't have it already --- */
	66
5bda60bd	67	if (n != MP_NEW)
	68	n = MP_COPY(n);
	69	else {
5e1601ef	70	mpmul mm;
5e1601ef	71	mpmul_init(&mm);
5e1601ef	72	for (i = 0; i < k; i++)
	73	mpmul_add(&mm, v[i].m);
	74	n = mpmul_done(&mm);
5bda60bd	75	}
	76
	77	/* --- A quick hack if %$k = 2$% --- */
	78
	79	if (k == 2) {
	80
	81	/* --- The %$n / n_i$% values are trivial in this case --- */
	82
	83	if (!v[0].n)
	84	v[0].n = MP_COPY(v[1].m);
	85	if (!v[1].n)
	86	v[1].n = MP_COPY(v[0].m);
	87
	88	/* --- Now sort out the inverses --- *
	89	*
	90	* @mp_gcd@ will ensure that the first argument is negative.
	91	*/
	92
	93	if (!v[0].ni && !v[1].ni) {
b817bfc6	94	mp *g = MP_NEW;
	95	mp_gcd(&g, &v[0].ni, &v[1].ni, v[0].n, v[1].n);
	96	assert(MP_EQ(g, MP_ONE));
	97	mp_drop(g);
5bda60bd	98	v[0].ni = mp_add(v[0].ni, v[0].ni, v[1].n);
	99	} else {
	100	int i, j;
	101	mp *x;
	102
	103	if (!v[0].ni)
	104	i = 0, j = 1;
	105	else
	106	i = 1, j = 0;
45c0fd36	107
5bda60bd	108	x = mp_mul(MP_NEW, v[j].n, v[j].ni);
	109	x = mp_sub(x, x, MP_ONE);
	110	mp_div(&x, 0, x, v[i].n);
	111	v[i].ni = x;
5ee4c893	112	}
	113	}
	114
5bda60bd	115	/* --- Set up the Barrett context --- */
5ee4c893	116
5bda60bd	117	mpbarrett_create(&c->mb, n);
5ee4c893	118
	119	/* --- Walk through filling in @n@, @ni@ and @nnir@ --- */
	120
	121	for (i = 0; i < k; i++) {
	122	if (!v[i].n)
	123	mp_div(&v[i].n, 0, n, v[i].m);
	124	if (!v[i].ni)
b817bfc6	125	v[i].ni = mp_modinv(MP_NEW, v[i].n, v[i].m);
5bda60bd	126	if (!v[i].nni)
5bda60bd	127	v[i].nni = mp_mul(MP_NEW, v[i].n, v[i].ni);
5ee4c893	128	}
	129
	130	/* --- Done --- */
	131
5bda60bd	132	mp_drop(n);
5ee4c893	133	}
	134
	135	/* --- @mpcrt_destroy@ --- *
	136	*
	137	* Arguments: @mpcrt *c@ - pointer to CRT context
	138	*
	139	* Returns: ---
	140	*
	141	* Use: Destroys a CRT context, releasing all the resources it holds.
	142	*/
	143
	144	void mpcrt_destroy(mpcrt *c)
	145	{
	146	size_t i;
	147
	148	for (i = 0; i < c->k; i++) {
	149	if (c->v[i].m) mp_drop(c->v[i].m);
	150	if (c->v[i].n) mp_drop(c->v[i].n);
	151	if (c->v[i].ni) mp_drop(c->v[i].ni);
5bda60bd	152	if (c->v[i].nni) mp_drop(c->v[i].nni);
5ee4c893	153	}
5bda60bd	154	mpbarrett_destroy(&c->mb);
5ee4c893	155	}
	156
	157	/* --- @mpcrt_solve@ --- *
	158	*
	159	* Arguments: @mpcrt *c@ = pointer to CRT context
5bda60bd	160	* @mp *d@ = fake destination
5ee4c893	161	* @mp **v@ = array of residues
	162	*
	163	* Returns: The unique solution modulo the product of the individual
	164	* moduli, which leaves the given residues.
	165	*
	166	* Use: Constructs a result given its residue modulo an array of
	167	* coprime integers. This can be used to improve performance of
	168	* RSA encryption or Blum-Blum-Shub generation if the factors
	169	* of the modulus are known, since results can be computed mod
	170	* each of the individual factors and then combined at the end.
	171	* This is rather faster than doing the full-scale modular
	172	* exponentiation.
	173	*/
	174
5bda60bd	175	mp mpcrt_solve(mpcrt c, mp d, mp *v)
5ee4c893	176	{
	177	mp *a = MP_ZERO;
	178	mp *x = MP_NEW;
	179	size_t i;
	180
	181	for (i = 0; i < c->k; i++) {
5bda60bd	182	x = mp_mul(x, c->v[i].nni, v[i]);
5bda60bd	183	x = mpbarrett_reduce(&c->mb, x, x);
5ee4c893	184	a = mp_add(a, a, x);
	185	}
	186	if (x)
5bda60bd	187	MP_DROP(x);
	188	a = mpbarrett_reduce(&c->mb, a, a);
	189	if (d != MP_NEW)
	190	MP_DROP(d);
5ee4c893	191	return (a);
	192	}
	193
	194	/----- Test rig ----------------------------------------------------------/
	195
	196	#ifdef TEST_RIG
	197
	198	static int verify(size_t n, dstr *v)
	199	{
	200	mpcrt_mod m = xmalloc(n sizeof(mpcrt_mod));
	201	mp *r = xmalloc(n sizeof(mp *));
	202	mpcrt c;
	203	mp a, b;
	204	size_t i;
	205	int ok = 1;
	206
	207	for (i = 0; i < n; i++) {
	208	r[i] = (mp )v[2 i].buf;
	209	m[i].m = (mp )v[2 i + 1].buf;
	210	m[i].n = 0;
	211	m[i].ni = 0;
5bda60bd	212	m[i].nni = 0;
5ee4c893	213	}
	214	a = (mp )v[2 n].buf;
	215
	216	mpcrt_create(&c, m, n, 0);
5bda60bd	217	b = mpcrt_solve(&c, MP_NEW, r);
5ee4c893	218
22bab86c	219	if (!MP_EQ(a, b)) {
5ee4c893	220	fputs("\n*** failed\n", stderr);
5ee4c893	221	fputs("n = ", stderr);
5bda60bd	222	mp_writefile(c.mb.m, stderr, 10);
5ee4c893	223	for (i = 0; i < n; i++) {
bb77b1d1	224	fprintf(stderr, "\nr[%lu] = ", (unsigned long)i);
5ee4c893	225	mp_writefile(r[i], stderr, 10);
bb77b1d1	226	fprintf(stderr, "\nm[%lu] = ", (unsigned long)i);
5ee4c893	227	mp_writefile(m[i].m, stderr, 10);
bb77b1d1	228	fprintf(stderr, "\nN[%lu] = ", (unsigned long)i);
5ee4c893	229	mp_writefile(m[i].n, stderr, 10);
bb77b1d1	230	fprintf(stderr, "\nM[%lu] = ", (unsigned long)i);
5ee4c893	231	mp_writefile(m[i].ni, stderr, 10);
	232	}
	233	fputs("\nresult = ", stderr);
	234	mp_writefile(b, stderr, 10);
	235	fputs("\nexpect = ", stderr);
	236	mp_writefile(a, stderr, 10);
	237	fputc('\n', stderr);
	238	ok = 0;
	239	}
	240
5bda60bd	241	for (i = 0; i < n; i++)
5bda60bd	242	mp_drop(r[i]);
5ee4c893	243	mp_drop(a);
	244	mp_drop(b);
	245	mpcrt_destroy(&c);
12ed8a1f	246	xfree(m);
12ed8a1f	247	xfree(r);
5bda60bd	248	assert(mparena_count(MPARENA_GLOBAL) == 0);
5ee4c893	249	return (ok);
	250	}
	251
	252	static int crt1(dstr *v) { return verify(1, v); }
	253	static int crt2(dstr *v) { return verify(2, v); }
	254	static int crt3(dstr *v) { return verify(3, v); }
	255	static int crt4(dstr *v) { return verify(4, v); }
	256	static int crt5(dstr *v) { return verify(5, v); }
	257
	258	static test_chunk tests[] = {
	259	{ "crt-1", crt1, { &type_mp, &type_mp,
	260	&type_mp, 0 } },
	261	{ "crt-2", crt2, { &type_mp, &type_mp,
	262	&type_mp, &type_mp,
	263	&type_mp, 0 } },
	264	{ "crt-3", crt3, { &type_mp, &type_mp,
	265	&type_mp, &type_mp,
	266	&type_mp, &type_mp,
	267	&type_mp, 0 } },
	268	{ "crt-4", crt4, { &type_mp, &type_mp,
	269	&type_mp, &type_mp,
	270	&type_mp, &type_mp,
	271	&type_mp, &type_mp,
	272	&type_mp, 0 } },
	273	{ "crt-5", crt5, { &type_mp, &type_mp,
	274	&type_mp, &type_mp,
	275	&type_mp, &type_mp,
	276	&type_mp, &type_mp,
	277	&type_mp, &type_mp,
	278	&type_mp, 0 } },
	279	{ 0, 0, { 0 } }
	280	};
	281
	282	int main(int argc, char *argv[])
	283	{
	284	sub_init();
0f00dc4c	285	test_run(argc, argv, tests, SRCDIR "/t/mpcrt");
5ee4c893	286	return (0);
	287	}
	288
	289	#endif
	290
	291	/----- That's all, folks -------------------------------------------------/