[u/mdw/catacomb] / mpmont.c

/* -*-c-*-
 *
 * $Id: mpmont.c,v 1.14 2001/02/22 09:04:26 mdw Exp $
 *
 * Montgomery reduction
 *
 * (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: mpmont.c,v $
 * Revision 1.14  2001/02/22 09:04:26  mdw
 * Cosmetic fix.
 *
 * Revision 1.13  2001/02/03 12:00:29  mdw
 * Now @mp_drop@ checks its argument is non-NULL before attempting to free
 * it.  Note that the macro version @MP_DROP@ doesn't do this.
 *
 * Revision 1.12  2000/10/08 15:48:35  mdw
 * Rename Karatsuba constants now that we have @gfx_kmul@ too.
 *
 * Revision 1.11  2000/10/08 12:04:27  mdw
 * (mpmont_reduce, mpmont_mul): Cope with negative numbers.
 *
 * Revision 1.10  2000/07/29 17:05:43  mdw
 * (mpmont_expr): Use sliding window exponentiation, with a drop-through
 * for small exponents to use a simple left-to-right bitwise routine.  This
 * can reduce modexp times by up to a quarter.
 *
 * Revision 1.9  2000/06/17 11:45:09  mdw
 * Major memory management overhaul.  Added arena support.  Use the secure
 * arena for secret integers.  Replace and improve the MP management macros
 * (e.g., replace MP_MODIFY by MP_DEST).
 *
 * Revision 1.8  1999/12/22 15:55:00  mdw
 * Adjust Karatsuba parameters.
 *
 * Revision 1.7  1999/12/11 01:51:14  mdw
 * Use a Karatsuba-based reduction for large moduli.
 *
 * Revision 1.6  1999/12/10 23:18:39  mdw
 * Change interface for suggested destinations.
 *
 * Revision 1.5  1999/11/22 13:58:40  mdw
 * Add an option to disable Montgomery reduction, so that performance
 * comparisons can be done.
 *
 * Revision 1.4  1999/11/21 12:27:06  mdw
 * Remove a division from the Montgomery setup by calculating
 * %$R^2 \bmod m$% first and then %$R \bmod m$% by Montgomery reduction of
 * %$R^2$%.
 *
 * Revision 1.3  1999/11/21 11:35:10  mdw
 * Performance improvement: use @mp_sqr@ and @mpmont_reduce@ instead of
 * @mpmont_mul@ for squaring in exponentiation.
 *
 * Revision 1.2  1999/11/19 13:17:26  mdw
 * Add extra interface to exponentiation which returns a Montgomerized
 * result.
 *
 * Revision 1.1  1999/11/17 18:02:16  mdw
 * New multiprecision integer arithmetic suite.
 *
 */

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

#include "mp.h"
#include "mpmont.h"

/*----- Tweakables --------------------------------------------------------*/

/* --- @MPMONT_DISABLE@ --- *
 *
 * Replace all the clever Montgomery reduction with good old-fashioned long
 * division.
 */

/* #define MPMONT_DISABLE */

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

/* --- @mpmont_create@ --- *
 *
 * Arguments:	@mpmont *mm@ = pointer to Montgomery reduction context
 *		@mp *m@ = modulus to use
 *
 * Returns:	---
 *
 * Use:		Initializes a Montgomery reduction context ready for use.
 *		The argument @m@ must be a positive odd integer.
 */

#ifdef MPMONT_DISABLE

void mpmont_create(mpmont *mm, mp *m)
{
  mp_shrink(m);
  mm->m = MP_COPY(m);
  mm->r = MP_ONE;
  mm->r2 = MP_ONE;
  mm->mi = MP_ONE;
}

#else

void mpmont_create(mpmont *mm, mp *m)
{
  size_t n = MP_LEN(m);
  mp *r2 = mp_new(2 * n + 1, 0);
  mp r;

  /* --- Validate the arguments --- */

  assert(((void)"Montgomery modulus must be positive",
	  (m->f & MP_NEG) == 0));
  assert(((void)"Montgomery modulus must be odd", m->v[0] & 1));

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

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

  /* --- Determine %$R^2$% --- */

  mm->n = n;
  MPX_ZERO(r2->v, r2->vl - 1);
  r2->vl[-1] = 1;

  /* --- Find the magic value @mi@ --- */

  mp_build(&r, r2->v + n, r2->vl);
  mm->mi = MP_NEW;
  mp_gcd(0, 0, &mm->mi, &r, m);
  mm->mi = mp_sub(mm->mi, &r, mm->mi);

  /* --- Discover the values %$R \bmod m$% and %$R^2 \bmod m$% --- */

  mm->r2 = MP_NEW;
  mp_div(0, &mm->r2, r2, m);
  mm->r = mpmont_reduce(mm, MP_NEW, mm->r2);
  MP_DROP(r2);
}

#endif

/* --- @mpmont_destroy@ --- *
 *
 * Arguments:	@mpmont *mm@ = pointer to a Montgomery reduction context
 *
 * Returns:	---
 *
 * Use:		Disposes of a context when it's no longer of any use to
 *		anyone.
 */

void mpmont_destroy(mpmont *mm)
{
  MP_DROP(mm->m);
  MP_DROP(mm->r);
  MP_DROP(mm->r2);
  MP_DROP(mm->mi);
}

/* --- @mpmont_reduce@ --- *
 *
 * Arguments:	@mpmont *mm@ = pointer to Montgomery reduction context
 *		@mp *d@ = destination
 *		@mp *a@ = source, assumed positive
 *
 * Returns:	Result, %$a R^{-1} \bmod m$%.
 */

#ifdef MPMONT_DISABLE

mp *mpmont_reduce(mpmont *mm, mp *d, mp *a)
{
  mp_div(0, &d, a, mm->m);
  return (d);
}

#else

mp *mpmont_reduce(mpmont *mm, mp *d, mp *a)
{
  size_t n = mm->n;

  /* --- Check for serious Karatsuba reduction --- */

  if (n > MPK_THRESH * 3) {
    mp al;
    mpw *vl;
    mp *u;

    if (MP_LEN(a) >= n)
      vl = a->v + n;
    else
      vl = a->vl;
    mp_build(&al, a->v, vl);
    u = mp_mul(MP_NEW, &al, mm->mi);
    if (MP_LEN(u) > n)
      u->vl = u->v + n;
    u = mp_mul(u, u, mm->m);
    d = mp_add(d, a, u);
    mp_drop(u);
  }

  /* --- Otherwise do it the hard way --- */

  else {
    mpw *dv, *dvl;
    mpw *mv, *mvl;
    mpw mi;
    size_t k = n;

    /* --- Initial conditioning of the arguments --- */

    a = MP_COPY(a);
    if (d)
      MP_DROP(d);
    d = a;
    MP_DEST(d, 2 * n + 1, a->f);

    dv = d->v; dvl = d->vl;
    mv = mm->m->v; mvl = mm->m->vl;

    /* --- Let's go to work --- */

    mi = mm->mi->v[0];
    while (k--) {
      mpw u = MPW(*dv * mi);
      MPX_UMLAN(dv, dvl, mv, mvl, u);
      dv++;
    }
  }

  /* --- Wrap everything up --- */

  memmove(d->v, d->v + n, MPWS(MP_LEN(d) - n));
  d->vl -= n;
  if (MPX_UCMP(d->v, d->vl, >=, mm->m->v, mm->m->vl))
    mpx_usub(d->v, d->vl, d->v, d->vl, mm->m->v, mm->m->vl);
  if (d->f & MP_NEG) {
    mpx_usub(d->v, d->vl, mm->m->v, mm->m->vl, d->v, d->vl);
    d->f &= ~MP_NEG;
  }
  MP_SHRINK(d);
  return (d);
}

#endif

/* --- @mpmont_mul@ --- *
 *
 * Arguments:	@mpmont *mm@ = pointer to Montgomery reduction context
 *		@mp *d@ = destination
 *		@mp *a, *b@ = sources, assumed positive
 *
 * Returns:	Result, %$a b R^{-1} \bmod m$%.
 */

#ifdef MPMONT_DISABLE

mp *mpmont_mul(mpmont *mm, mp *d, mp *a, mp *b)
{
  d = mp_mul(d, a, b);
  mp_div(0, &d, d, mm->m);
  return (d);
}

#else

mp *mpmont_mul(mpmont *mm, mp *d, mp *a, mp *b)
{
  if (mm->n > MPK_THRESH * 3) {
    d = mp_mul(d, a, b);
    d = mpmont_reduce(mm, d, d);
  } else {
    mpw *dv, *dvl;
    mpw *av, *avl;
    mpw *bv, *bvl;
    mpw *mv, *mvl;
    mpw y;
    size_t n, i;
    mpw mi;

    /* --- Initial conditioning of the arguments --- */

    if (MP_LEN(a) > MP_LEN(b)) {
      mp *t = a; a = b; b = t;
    }
    n = MP_LEN(mm->m);

    a = MP_COPY(a);
    b = MP_COPY(b);
    MP_DEST(d, 2 * n + 1, a->f | b->f | MP_UNDEF);
    dv = d->v; dvl = d->vl;
    MPX_ZERO(dv, dvl);
    av = a->v; avl = a->vl;
    bv = b->v; bvl = b->vl;
    mv = mm->m->v; mvl = mm->m->vl;
    y = *bv;

    /* --- Montgomery multiplication phase --- */

    i = 0;
    mi = mm->mi->v[0];
    while (i < n && av < avl) {
      mpw x = *av++;
      mpw u = MPW((*dv + x * y) * mi);
      MPX_UMLAN(dv, dvl, bv, bvl, x);
      MPX_UMLAN(dv, dvl, mv, mvl, u);
      dv++;
      i++;
    }

    /* --- Simpler Montgomery reduction phase --- */

    while (i < n) {
      mpw u = MPW(*dv * mi);
      MPX_UMLAN(dv, dvl, mv, mvl, u);
      dv++;
      i++;
    }

    /* --- Done --- */

    memmove(d->v, dv, MPWS(dvl - dv));
    d->vl -= dv - d->v;
    if (MPX_UCMP(d->v, d->vl, >=, mm->m->v, mm->m->vl))
      mpx_usub(d->v, d->vl, d->v, d->vl, mm->m->v, mm->m->vl);
    if ((a->f ^ b->f) & MP_NEG)
      mpx_usub(d->v, d->vl, mm->m->v, mm->m->vl, d->v, d->vl);
    MP_SHRINK(d);
    d->f = (a->f | b->f) & MP_BURN;
    MP_DROP(a);
    MP_DROP(b);
  }

  return (d);
}

#endif

/* --- @mpmont_expr@ --- *
 *
 * Arguments:	@mpmont *mm@ = pointer to Montgomery reduction context
 *		@mp *d@ = fake destination
 *		@mp *a@ = base
 *		@mp *e@ = exponent
 *
 * Returns:	Result, %$a^e R \bmod m$%.
 */

#define WINSZ 5
#define TABSZ (1 << (WINSZ - 1))

#define THRESH (((MPW_BITS / WINSZ) << 2) + 1)

static mp *exp_simple(mpmont *mm, mp *d, mp *a, mp *e)
{
  mpscan sc;
  mp *ar;
  mp *x = MP_COPY(mm->r);
  mp *spare = (e->f & MP_BURN) ? MP_NEWSEC : MP_NEW;
  unsigned sq = 0;

  mp_rscan(&sc, e);
  if (!MP_RSTEP(&sc))
    goto exit;
  while (!MP_RBIT(&sc))
    MP_RSTEP(&sc);

  /* --- Do the main body of the work --- */
  
  ar = mpmont_mul(mm, MP_NEW, a, mm->r2);
  for (;;) {
    sq++;
    while (sq) {
      mp *y;
      y = mp_sqr(spare, x);
      y = mpmont_reduce(mm, y, y);
      spare = x; x = y;
      sq--;
    }
    { mp *y = mpmont_mul(mm, spare, x, ar); spare = x; x = y; }
    sq = 0;
    for (;;) {
      if (!MP_RSTEP(&sc))
	goto done;
      if (MP_RBIT(&sc))
	break;
      sq++;
    }
  }

  /* --- Do a final round of squaring --- */

done:
  while (sq) {
    mp *y;
    y = mp_sqr(spare, x);
    y = mpmont_reduce(mm, y, y);
    spare = x; x = y;
    sq--;
  }

  /* --- Done --- */

  MP_DROP(ar);
exit:
  if (spare != MP_NEW)
    MP_DROP(spare);
  if (d != MP_NEW)
    MP_DROP(d);
  return (x);
}

mp *mpmont_expr(mpmont *mm, mp *d, mp *a, mp *e)
{
  mp **tab;
  mp *ar, *a2;
  mp *spare = (e->f & MP_BURN) ? MP_NEWSEC : MP_NEW;
  mp *x = MP_COPY(mm->r);
  unsigned i, sq = 0;
  mpscan sc;

  /* --- Do we bother? --- */

  MP_SHRINK(e);
  if (MP_LEN(e) == 0)
    goto exit;
  if (MP_LEN(e) < THRESH) {
    x->ref--;
    return (exp_simple(mm, d, a, e));
  }

  /* --- Do the precomputation --- */

  ar = mpmont_mul(mm, MP_NEW, a, mm->r2);
  a2 = mp_sqr(MP_NEW, ar);
  a2 = mpmont_reduce(mm, a2, a2);
  tab = xmalloc(TABSZ * sizeof(mp *));
  tab[0] = ar;
  for (i = 1; i < TABSZ; i++)
    tab[i] = mpmont_mul(mm, MP_NEW, tab[i - 1], a2);
  mp_drop(a2);
  mp_rscan(&sc, e);

  /* --- Skip top-end zero bits --- *
   *
   * If the initial step worked, there must be a set bit somewhere, so keep
   * stepping until I find it.
   */

  MP_RSTEP(&sc);
  while (!MP_RBIT(&sc))
    MP_RSTEP(&sc);

  /* --- Now for the main work --- */

  for (;;) {
    unsigned l = 0;
    unsigned z = 0;

    /* --- The next bit is set, so read a window index --- *
     *
     * Reset @i@ to zero and increment @sq@.  Then, until either I read
     * @WINSZ@ bits or I run out of bits, scan in a bit: if it's clear, bump
     * the @z@ counter; if it's set, push a set bit into @i@, shift it over
     * by @z@ bits, bump @sq@ by @z + 1@ and clear @z@.  By the end of this
     * palaver, @i@ is an index to the precomputed value in @tab@.
     */

    i = 0;
    sq++;
    for (;;) {
      l++;
      if (l >= WINSZ || !MP_RSTEP(&sc))
	break;
      if (!MP_RBIT(&sc))
	z++;
      else {
	i = ((i << 1) | 1) << z;
	sq += z + 1;
	z = 0;
      }
    }

    /* --- Do the squaring --- *
     *
     * Remember that @sq@ carries over from the zero-skipping stuff below.
     */

    while (sq) {
      mp *y;
      y = mp_sqr(spare, x);
      y = mpmont_reduce(mm, y, y);
      spare = x; x = y;
      sq--;
    }

    /* --- Do the multiply --- */

    { mp *y = mpmont_mul(mm, spare, x, tab[i]); spare = x; x = y; }

    /* --- Now grind along through the rest of the bits --- */

    sq = z;
    for (;;) {
      if (!MP_RSTEP(&sc))
	goto done;
      if (MP_RBIT(&sc))
	break;
      sq++;
    }
  }

  /* --- Do a final round of squaring --- */

done:
  while (sq) {
    mp *y;
    y = mp_sqr(spare, x);
    y = mpmont_reduce(mm, y, y);
    spare = x; x = y;
    sq--;
  }

  /* --- Done --- */

  for (i = 0; i < TABSZ; i++)
    mp_drop(tab[i]);
  xfree(tab);
exit:
  mp_drop(d);
  mp_drop(spare);
  return (x);
}

/* --- @mpmont_exp@ --- *
 *
 * Arguments:	@mpmont *mm@ = pointer to Montgomery reduction context
 *		@mp *d@ = fake destination
 *		@mp *a@ = base
 *		@mp *e@ = exponent
 *
 * Returns:	Result, %$a^e \bmod m$%.
 */

mp *mpmont_exp(mpmont *mm, mp *d, mp *a, mp *e)
{
  d = mpmont_expr(mm, d, a, e);
  d = mpmont_reduce(mm, d, d);
  return (d);
}

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

#ifdef TEST_RIG

static int tcreate(dstr *v)
{
  mp *m = *(mp **)v[0].buf;
  mp *mi = *(mp **)v[1].buf;
  mp *r = *(mp **)v[2].buf;
  mp *r2 = *(mp **)v[3].buf;

  mpmont mm;
  int ok = 1;

  mpmont_create(&mm, m);

  if (mm.mi->v[0] != mi->v[0]) {
    fprintf(stderr, "\n*** bad mi: found %lu, expected %lu",
	    (unsigned long)mm.mi->v[0], (unsigned long)mi->v[0]);
    fputs("\nm = ", stderr); mp_writefile(m, stderr, 10);
    fputc('\n', stderr);
    ok = 0;
  }

  if (!MP_EQ(mm.r, r)) {
    fputs("\n*** bad r", stderr);
    fputs("\nm = ", stderr); mp_writefile(m, stderr, 10);
    fputs("\nexpected ", stderr); mp_writefile(r, stderr, 10);
    fputs("\n   found ", stderr); mp_writefile(mm.r, stderr, 10);
    fputc('\n', stderr);
    ok = 0;
  }

  if (!MP_EQ(mm.r2, r2)) {
    fputs("\n*** bad r2", stderr);
    fputs("\nm = ", stderr); mp_writefile(m, stderr, 10);
    fputs("\nexpected ", stderr); mp_writefile(r2, stderr, 10);
    fputs("\n   found ", stderr); mp_writefile(mm.r2, stderr, 10);
    fputc('\n', stderr);
    ok = 0;
  }

  MP_DROP(m);
  MP_DROP(mi);
  MP_DROP(r);
  MP_DROP(r2);
  mpmont_destroy(&mm);
  assert(mparena_count(MPARENA_GLOBAL) == 0);
  return (ok);
}

static int tmul(dstr *v)
{
  mp *m = *(mp **)v[0].buf;
  mp *a = *(mp **)v[1].buf;
  mp *b = *(mp **)v[2].buf;
  mp *r = *(mp **)v[3].buf;
  int ok = 1;

  mpmont mm;
  mpmont_create(&mm, m);

  {
    mp *qr = mp_mul(MP_NEW, a, b);
    mp_div(0, &qr, qr, m);

    if (!MP_EQ(qr, r)) {
      fputs("\n*** classical modmul failed", stderr);
      fputs("\n m = ", stderr); mp_writefile(m, stderr, 10);
      fputs("\n a = ", stderr); mp_writefile(a, stderr, 10);
      fputs("\n b = ", stderr); mp_writefile(b, stderr, 10);
      fputs("\n r = ", stderr); mp_writefile(r, stderr, 10);
      fputs("\nqr = ", stderr); mp_writefile(qr, stderr, 10);
      fputc('\n', stderr);
      ok = 0;
    }

    mp_drop(qr);
  }

  {
    mp *ar = mpmont_mul(&mm, MP_NEW, a, mm.r2);
    mp *br = mpmont_mul(&mm, MP_NEW, b, mm.r2);
    mp *mr = mpmont_mul(&mm, MP_NEW, ar, br);
    mr = mpmont_reduce(&mm, mr, mr);
    if (!MP_EQ(mr, r)) {
      fputs("\n*** montgomery modmul failed", stderr);
      fputs("\n m = ", stderr); mp_writefile(m, stderr, 10);
      fputs("\n a = ", stderr); mp_writefile(a, stderr, 10);
      fputs("\n b = ", stderr); mp_writefile(b, stderr, 10);
      fputs("\n r = ", stderr); mp_writefile(r, stderr, 10);
      fputs("\nmr = ", stderr); mp_writefile(mr, stderr, 10);
      fputc('\n', stderr);
      ok = 0;
    }
    MP_DROP(ar); MP_DROP(br);
    mp_drop(mr);
  }


  MP_DROP(m);
  MP_DROP(a);
  MP_DROP(b);
  MP_DROP(r);
  mpmont_destroy(&mm);
  assert(mparena_count(MPARENA_GLOBAL) == 0);
  return ok;
}

static int texp(dstr *v)
{
  mp *m = *(mp **)v[0].buf;
  mp *a = *(mp **)v[1].buf;
  mp *b = *(mp **)v[2].buf;
  mp *r = *(mp **)v[3].buf;
  mp *mr;
  int ok = 1;

  mpmont mm;
  mpmont_create(&mm, m);

  mr = mpmont_exp(&mm, MP_NEW, a, b);

  if (!MP_EQ(mr, r)) {
    fputs("\n*** montgomery modexp failed", stderr);
    fputs("\n m = ", stderr); mp_writefile(m, stderr, 10);
    fputs("\n a = ", stderr); mp_writefile(a, stderr, 10);
    fputs("\n e = ", stderr); mp_writefile(b, stderr, 10);
    fputs("\n r = ", stderr); mp_writefile(r, stderr, 10);
    fputs("\nmr = ", stderr); mp_writefile(mr, stderr, 10);
    fputc('\n', stderr);
    ok = 0;
  }

  MP_DROP(m);
  MP_DROP(a);
  MP_DROP(b);
  MP_DROP(r);
  MP_DROP(mr);
  mpmont_destroy(&mm);
  assert(mparena_count(MPARENA_GLOBAL) == 0);
  return ok;
}


static test_chunk tests[] = {
  { "create", tcreate, { &type_mp, &type_mp, &type_mp, &type_mp, 0 } },
  { "mul", tmul, { &type_mp, &type_mp, &type_mp, &type_mp, 0 } },
  { "exp", texp, { &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 "/tests/mpmont");
  return (0);
}

#endif

/*----- That's all, folks -------------------------------------------------*/
Commit	Line	Data
d3409d5e	1	/* --c--
d3409d5e	2	*
b096ec7f	3	* $Id: mpmont.c,v 1.14 2001/02/22 09:04:26 mdw Exp $
d3409d5e	4	*
	5	* Montgomery reduction
	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: mpmont.c,v $
b096ec7f	33	* Revision 1.14 2001/02/22 09:04:26 mdw
	34	* Cosmetic fix.
	35	*
f1140c41	36	* Revision 1.13 2001/02/03 12:00:29 mdw
	37	* Now @mp_drop@ checks its argument is non-NULL before attempting to free
	38	* it. Note that the macro version @MP_DROP@ doesn't do this.
	39	*
52cdaca9	40	* Revision 1.12 2000/10/08 15:48:35 mdw
	41	* Rename Karatsuba constants now that we have @gfx_kmul@ too.
	42	*
032099d1	43	* Revision 1.11 2000/10/08 12:04:27 mdw
	44	* (mpmont_reduce, mpmont_mul): Cope with negative numbers.
	45	*
c9d4c30b	46	* Revision 1.10 2000/07/29 17:05:43 mdw
	47	* (mpmont_expr): Use sliding window exponentiation, with a drop-through
	48	* for small exponents to use a simple left-to-right bitwise routine. This
	49	* can reduce modexp times by up to a quarter.
	50	*
d34decd2	51	* Revision 1.9 2000/06/17 11:45:09 mdw
	52	* Major memory management overhaul. Added arena support. Use the secure
	53	* arena for secret integers. Replace and improve the MP management macros
	54	* (e.g., replace MP_MODIFY by MP_DEST).
	55	*
01f6ed1a	56	* Revision 1.8 1999/12/22 15:55:00 mdw
	57	* Adjust Karatsuba parameters.
	58	*
f5f35081	59	* Revision 1.7 1999/12/11 01:51:14 mdw
	60	* Use a Karatsuba-based reduction for large moduli.
	61	*
ef5f4810	62	* Revision 1.6 1999/12/10 23:18:39 mdw
	63	* Change interface for suggested destinations.
	64	*
52e4b041	65	* Revision 1.5 1999/11/22 13:58:40 mdw
	66	* Add an option to disable Montgomery reduction, so that performance
	67	* comparisons can be done.
	68	*
93feaa6e	69	* Revision 1.4 1999/11/21 12:27:06 mdw
	70	* Remove a division from the Montgomery setup by calculating
	71	* %$R^2 \bmod m$% first and then %$R \bmod m$% by Montgomery reduction of
	72	* %$R^2$%.
	73	*
79a34029	74	* Revision 1.3 1999/11/21 11:35:10 mdw
	75	* Performance improvement: use @mp_sqr@ and @mpmont_reduce@ instead of
	76	* @mpmont_mul@ for squaring in exponentiation.
	77	*
17ad212e	78	* Revision 1.2 1999/11/19 13:17:26 mdw
	79	* Add extra interface to exponentiation which returns a Montgomerized
	80	* result.
	81	*
d3409d5e	82	* Revision 1.1 1999/11/17 18:02:16 mdw
	83	* New multiprecision integer arithmetic suite.
	84	*
	85	*/
	86
	87	/----- Header files ------------------------------------------------------/
	88
	89	#include "mp.h"
	90	#include "mpmont.h"
	91
52e4b041	92	/----- Tweakables --------------------------------------------------------/
	93
	94	/* --- @MPMONT_DISABLE@ --- *
	95	*
	96	* Replace all the clever Montgomery reduction with good old-fashioned long
	97	* division.
	98	*/
	99
	100	/* #define MPMONT_DISABLE */
	101
d3409d5e	102	/----- Main code ---------------------------------------------------------/
	103
	104	/* --- @mpmont_create@ --- *
	105	*
	106	* Arguments: @mpmont *mm@ = pointer to Montgomery reduction context
	107	* @mp *m@ = modulus to use
	108	*
	109	* Returns: ---
	110	*
	111	* Use: Initializes a Montgomery reduction context ready for use.
ef5f4810	112	* The argument @m@ must be a positive odd integer.
d3409d5e	113	*/
d3409d5e	114
52e4b041	115	#ifdef MPMONT_DISABLE
	116
	117	void mpmont_create(mpmont mm, mp m)
	118	{
	119	mp_shrink(m);
	120	mm->m = MP_COPY(m);
	121	mm->r = MP_ONE;
	122	mm->r2 = MP_ONE;
f5f35081	123	mm->mi = MP_ONE;
52e4b041	124	}
	125
	126	#else
	127
d3409d5e	128	void mpmont_create(mpmont mm, mp m)
d3409d5e	129	{
f5f35081	130	size_t n = MP_LEN(m);
d34decd2	131	mp r2 = mp_new(2 n + 1, 0);
f5f35081	132	mp r;
f5f35081	133
ef5f4810	134	/* --- Validate the arguments --- */
	135
	136	assert(((void)"Montgomery modulus must be positive",
	137	(m->f & MP_NEG) == 0));
	138	assert(((void)"Montgomery modulus must be odd", m->v[0] & 1));
	139
d3409d5e	140	/* --- Take a copy of the modulus --- */
	141
	142	mp_shrink(m);
	143	mm->m = MP_COPY(m);
	144
f5f35081	145	/* --- Determine %$R^2$% --- */
d3409d5e	146
f5f35081	147	mm->n = n;
	148	MPX_ZERO(r2->v, r2->vl - 1);
	149	r2->vl[-1] = 1;
d3409d5e	150
f5f35081	151	/* --- Find the magic value @mi@ --- */
	152
	153	mp_build(&r, r2->v + n, r2->vl);
	154	mm->mi = MP_NEW;
	155	mp_gcd(0, 0, &mm->mi, &r, m);
	156	mm->mi = mp_sub(mm->mi, &r, mm->mi);
d3409d5e	157
	158	/* --- Discover the values %$R \bmod m$% and %$R^2 \bmod m$% --- */
	159
f5f35081	160	mm->r2 = MP_NEW;
	161	mp_div(0, &mm->r2, r2, m);
	162	mm->r = mpmont_reduce(mm, MP_NEW, mm->r2);
	163	MP_DROP(r2);
d3409d5e	164	}
d3409d5e	165
52e4b041	166	#endif
52e4b041	167
d3409d5e	168	/* --- @mpmont_destroy@ --- *
	169	*
	170	* Arguments: @mpmont *mm@ = pointer to a Montgomery reduction context
	171	*
	172	* Returns: ---
	173	*
	174	* Use: Disposes of a context when it's no longer of any use to
	175	* anyone.
	176	*/
	177
	178	void mpmont_destroy(mpmont *mm)
	179	{
	180	MP_DROP(mm->m);
	181	MP_DROP(mm->r);
	182	MP_DROP(mm->r2);
f5f35081	183	MP_DROP(mm->mi);
d3409d5e	184	}
	185
	186	/* --- @mpmont_reduce@ --- *
	187	*
	188	* Arguments: @mpmont *mm@ = pointer to Montgomery reduction context
	189	* @mp *d@ = destination
ef5f4810	190	* @mp *a@ = source, assumed positive
d3409d5e	191	*
	192	* Returns: Result, %$a R^{-1} \bmod m$%.
	193	*/
	194
52e4b041	195	#ifdef MPMONT_DISABLE
52e4b041	196
ef5f4810	197	mp mpmont_reduce(mpmont mm, mp d, mp a)
52e4b041	198	{
	199	mp_div(0, &d, a, mm->m);
	200	return (d);
	201	}
	202
	203	#else
	204
ef5f4810	205	mp mpmont_reduce(mpmont mm, mp d, mp a)
d3409d5e	206	{
f5f35081	207	size_t n = mm->n;
	208
	209	/* --- Check for serious Karatsuba reduction --- */
	210
52cdaca9	211	if (n > MPK_THRESH * 3) {
f5f35081	212	mp al;
	213	mpw *vl;
	214	mp *u;
	215
	216	if (MP_LEN(a) >= n)
	217	vl = a->v + n;
	218	else
	219	vl = a->vl;
	220	mp_build(&al, a->v, vl);
	221	u = mp_mul(MP_NEW, &al, mm->mi);
	222	if (MP_LEN(u) > n)
	223	u->vl = u->v + n;
	224	u = mp_mul(u, u, mm->m);
	225	d = mp_add(d, a, u);
	226	mp_drop(u);
	227	}
d3409d5e	228
f5f35081	229	/* --- Otherwise do it the hard way --- */
d3409d5e	230
d3409d5e	231	else {
f5f35081	232	mpw dv, dvl;
	233	mpw mv, mvl;
	234	mpw mi;
	235	size_t k = n;
	236
	237	/* --- Initial conditioning of the arguments --- */
	238
d34decd2	239	a = MP_COPY(a);
	240	if (d)
	241	MP_DROP(d);
	242	d = a;
	243	MP_DEST(d, 2 * n + 1, a->f);
	244
f5f35081	245	dv = d->v; dvl = d->vl;
f5f35081	246	mv = mm->m->v; mvl = mm->m->vl;
d3409d5e	247
f5f35081	248	/* --- Let's go to work --- */
d3409d5e	249
f5f35081	250	mi = mm->mi->v[0];
	251	while (k--) {
	252	mpw u = MPW(dv mi);
	253	MPX_UMLAN(dv, dvl, mv, mvl, u);
	254	dv++;
	255	}
d3409d5e	256	}
d3409d5e	257
f5f35081	258	/* --- Wrap everything up --- */
d3409d5e	259
f5f35081	260	memmove(d->v, d->v + n, MPWS(MP_LEN(d) - n));
f5f35081	261	d->vl -= n;
032099d1	262	if (MPX_UCMP(d->v, d->vl, >=, mm->m->v, mm->m->vl))
	263	mpx_usub(d->v, d->vl, d->v, d->vl, mm->m->v, mm->m->vl);
	264	if (d->f & MP_NEG) {
	265	mpx_usub(d->v, d->vl, mm->m->v, mm->m->vl, d->v, d->vl);
	266	d->f &= ~MP_NEG;
	267	}
f5f35081	268	MP_SHRINK(d);
d3409d5e	269	return (d);
	270	}
	271
52e4b041	272	#endif
52e4b041	273
d3409d5e	274	/* --- @mpmont_mul@ --- *
	275	*
	276	* Arguments: @mpmont *mm@ = pointer to Montgomery reduction context
	277	* @mp *d@ = destination
ef5f4810	278	* @mp a, b@ = sources, assumed positive
d3409d5e	279	*
	280	* Returns: Result, %$a b R^{-1} \bmod m$%.
	281	*/
	282
52e4b041	283	#ifdef MPMONT_DISABLE
52e4b041	284
ef5f4810	285	mp mpmont_mul(mpmont mm, mp d, mp a, mp *b)
52e4b041	286	{
	287	d = mp_mul(d, a, b);
	288	mp_div(0, &d, d, mm->m);
	289	return (d);
	290	}
	291
	292	#else
	293
ef5f4810	294	mp mpmont_mul(mpmont mm, mp d, mp a, mp *b)
d3409d5e	295	{
52cdaca9	296	if (mm->n > MPK_THRESH * 3) {
ef5f4810	297	d = mp_mul(d, a, b);
	298	d = mpmont_reduce(mm, d, d);
	299	} else {
	300	mpw dv, dvl;
	301	mpw av, avl;
	302	mpw bv, bvl;
	303	mpw mv, mvl;
	304	mpw y;
	305	size_t n, i;
f5f35081	306	mpw mi;
ef5f4810	307
	308	/* --- Initial conditioning of the arguments --- */
	309
	310	if (MP_LEN(a) > MP_LEN(b)) {
	311	mp *t = a; a = b; b = t;
	312	}
	313	n = MP_LEN(mm->m);
d3409d5e	314
ef5f4810	315	a = MP_COPY(a);
ef5f4810	316	b = MP_COPY(b);
d34decd2	317	MP_DEST(d, 2 * n + 1, a->f \| b->f \| MP_UNDEF);
ef5f4810	318	dv = d->v; dvl = d->vl;
	319	MPX_ZERO(dv, dvl);
	320	av = a->v; avl = a->vl;
	321	bv = b->v; bvl = b->vl;
	322	mv = mm->m->v; mvl = mm->m->vl;
	323	y = *bv;
	324
	325	/* --- Montgomery multiplication phase --- */
	326
	327	i = 0;
f5f35081	328	mi = mm->mi->v[0];
ef5f4810	329	while (i < n && av < avl) {
ef5f4810	330	mpw x = *av++;
f5f35081	331	mpw u = MPW((dv + x y) * mi);
ef5f4810	332	MPX_UMLAN(dv, dvl, bv, bvl, x);
	333	MPX_UMLAN(dv, dvl, mv, mvl, u);
	334	dv++;
	335	i++;
	336	}
d3409d5e	337
ef5f4810	338	/* --- Simpler Montgomery reduction phase --- */
d3409d5e	339
ef5f4810	340	while (i < n) {
f5f35081	341	mpw u = MPW(dv mi);
ef5f4810	342	MPX_UMLAN(dv, dvl, mv, mvl, u);
	343	dv++;
	344	i++;
	345	}
d3409d5e	346
ef5f4810	347	/* --- Done --- */
d3409d5e	348
ef5f4810	349	memmove(d->v, dv, MPWS(dvl - dv));
ef5f4810	350	d->vl -= dv - d->v;
032099d1	351	if (MPX_UCMP(d->v, d->vl, >=, mm->m->v, mm->m->vl))
	352	mpx_usub(d->v, d->vl, d->v, d->vl, mm->m->v, mm->m->vl);
	353	if ((a->f ^ b->f) & MP_NEG)
	354	mpx_usub(d->v, d->vl, mm->m->v, mm->m->vl, d->v, d->vl);
ef5f4810	355	MP_SHRINK(d);
ef5f4810	356	d->f = (a->f \| b->f) & MP_BURN;
ef5f4810	357	MP_DROP(a);
ef5f4810	358	MP_DROP(b);
d3409d5e	359	}
d3409d5e	360
d3409d5e	361	return (d);
	362	}
	363
52e4b041	364	#endif
52e4b041	365
17ad212e	366	/* --- @mpmont_expr@ --- *
d3409d5e	367	*
d3409d5e	368	* Arguments: @mpmont *mm@ = pointer to Montgomery reduction context
ef5f4810	369	* @mp *d@ = fake destination
	370	* @mp *a@ = base
	371	* @mp *e@ = exponent
d3409d5e	372	*
17ad212e	373	* Returns: Result, %$a^e R \bmod m$%.
d3409d5e	374	*/
d3409d5e	375
c9d4c30b	376	#define WINSZ 5
	377	#define TABSZ (1 << (WINSZ - 1))
	378
	379	#define THRESH (((MPW_BITS / WINSZ) << 2) + 1)
	380
	381	static mp exp_simple(mpmont mm, mp d, mp a, mp *e)
d3409d5e	382	{
d3409d5e	383	mpscan sc;
c9d4c30b	384	mp *ar;
ef5f4810	385	mp *x = MP_COPY(mm->r);
d34decd2	386	mp *spare = (e->f & MP_BURN) ? MP_NEWSEC : MP_NEW;
c9d4c30b	387	unsigned sq = 0;
	388
	389	mp_rscan(&sc, e);
	390	if (!MP_RSTEP(&sc))
	391	goto exit;
	392	while (!MP_RBIT(&sc))
	393	MP_RSTEP(&sc);
	394
	395	/* --- Do the main body of the work --- */
	396
	397	ar = mpmont_mul(mm, MP_NEW, a, mm->r2);
	398	for (;;) {
	399	sq++;
	400	while (sq) {
	401	mp *y;
	402	y = mp_sqr(spare, x);
	403	y = mpmont_reduce(mm, y, y);
	404	spare = x; x = y;
	405	sq--;
	406	}
	407	{ mp *y = mpmont_mul(mm, spare, x, ar); spare = x; x = y; }
	408	sq = 0;
d3409d5e	409	for (;;) {
c9d4c30b	410	if (!MP_RSTEP(&sc))
	411	goto done;
	412	if (MP_RBIT(&sc))
d3409d5e	413	break;
c9d4c30b	414	sq++;
d3409d5e	415	}
d3409d5e	416	}
c9d4c30b	417
	418	/* --- Do a final round of squaring --- */
	419
	420	done:
	421	while (sq) {
	422	mp *y;
	423	y = mp_sqr(spare, x);
	424	y = mpmont_reduce(mm, y, y);
	425	spare = x; x = y;
	426	sq--;
	427	}
	428
	429	/* --- Done --- */
	430
d3409d5e	431	MP_DROP(ar);
c9d4c30b	432	exit:
17ad212e	433	if (spare != MP_NEW)
17ad212e	434	MP_DROP(spare);
ef5f4810	435	if (d != MP_NEW)
	436	MP_DROP(d);
	437	return (x);
17ad212e	438	}
17ad212e	439
c9d4c30b	440	mp mpmont_expr(mpmont mm, mp d, mp a, mp *e)
	441	{
	442	mp **tab;
	443	mp ar, a2;
	444	mp *spare = (e->f & MP_BURN) ? MP_NEWSEC : MP_NEW;
	445	mp *x = MP_COPY(mm->r);
	446	unsigned i, sq = 0;
	447	mpscan sc;
	448
	449	/* --- Do we bother? --- */
	450
	451	MP_SHRINK(e);
	452	if (MP_LEN(e) == 0)
	453	goto exit;
	454	if (MP_LEN(e) < THRESH) {
	455	x->ref--;
	456	return (exp_simple(mm, d, a, e));
	457	}
	458
	459	/* --- Do the precomputation --- */
	460
	461	ar = mpmont_mul(mm, MP_NEW, a, mm->r2);
	462	a2 = mp_sqr(MP_NEW, ar);
	463	a2 = mpmont_reduce(mm, a2, a2);
	464	tab = xmalloc(TABSZ * sizeof(mp *));
	465	tab[0] = ar;
	466	for (i = 1; i < TABSZ; i++)
	467	tab[i] = mpmont_mul(mm, MP_NEW, tab[i - 1], a2);
	468	mp_drop(a2);
	469	mp_rscan(&sc, e);
	470
	471	/* --- Skip top-end zero bits --- *
	472	*
	473	* If the initial step worked, there must be a set bit somewhere, so keep
	474	* stepping until I find it.
	475	*/
	476
	477	MP_RSTEP(&sc);
b096ec7f	478	while (!MP_RBIT(&sc))
c9d4c30b	479	MP_RSTEP(&sc);
c9d4c30b	480
	481	/* --- Now for the main work --- */
	482
	483	for (;;) {
	484	unsigned l = 0;
	485	unsigned z = 0;
	486
	487	/* --- The next bit is set, so read a window index --- *
	488	*
	489	* Reset @i@ to zero and increment @sq@. Then, until either I read
	490	* @WINSZ@ bits or I run out of bits, scan in a bit: if it's clear, bump
	491	* the @z@ counter; if it's set, push a set bit into @i@, shift it over
	492	* by @z@ bits, bump @sq@ by @z + 1@ and clear @z@. By the end of this
	493	* palaver, @i@ is an index to the precomputed value in @tab@.
	494	*/
	495
	496	i = 0;
	497	sq++;
	498	for (;;) {
	499	l++;
	500	if (l >= WINSZ \|\| !MP_RSTEP(&sc))
	501	break;
	502	if (!MP_RBIT(&sc))
	503	z++;
	504	else {
	505	i = ((i << 1) \| 1) << z;
	506	sq += z + 1;
	507	z = 0;
	508	}
	509	}
	510
	511	/* --- Do the squaring --- *
	512	*
	513	* Remember that @sq@ carries over from the zero-skipping stuff below.
	514	*/
	515
	516	while (sq) {
	517	mp *y;
	518	y = mp_sqr(spare, x);
	519	y = mpmont_reduce(mm, y, y);
	520	spare = x; x = y;
	521	sq--;
	522	}
	523
	524	/* --- Do the multiply --- */
	525
	526	{ mp *y = mpmont_mul(mm, spare, x, tab[i]); spare = x; x = y; }
	527
	528	/* --- Now grind along through the rest of the bits --- */
	529
	530	sq = z;
	531	for (;;) {
	532	if (!MP_RSTEP(&sc))
	533	goto done;
	534	if (MP_RBIT(&sc))
	535	break;
	536	sq++;
	537	}
	538	}
	539
	540	/* --- Do a final round of squaring --- */
	541
	542	done:
	543	while (sq) {
544	mp *y;
545	y = mp_sqr(spare, x);
546	y = mpmont_reduce(mm, y, y);
547	spare = x; x = y;
548	sq--;
549	}
550
551	/* --- Done --- */
552
553	for (i = 0; i < TABSZ; i++)
554	mp_drop(tab[i]);
555	xfree(tab);
556	exit:
f1140c41	557	mp_drop(d);
f1140c41	558	mp_drop(spare);
c9d4c30b	559	return (x);
	560	}
	561
17ad212e	562	/* --- @mpmont_exp@ --- *
	563	*
	564	* Arguments: @mpmont *mm@ = pointer to Montgomery reduction context
ef5f4810	565	* @mp *d@ = fake destination
	566	* @mp *a@ = base
	567	* @mp *e@ = exponent
17ad212e	568	*
	569	* Returns: Result, %$a^e \bmod m$%.
	570	*/
	571
ef5f4810	572	mp mpmont_exp(mpmont mm, mp d, mp a, mp *e)
17ad212e	573	{
ef5f4810	574	d = mpmont_expr(mm, d, a, e);
17ad212e	575	d = mpmont_reduce(mm, d, d);
17ad212e	576	return (d);
d3409d5e	577	}
	578
	579	/----- Test rig ----------------------------------------------------------/
	580
	581	#ifdef TEST_RIG
	582
	583	static int tcreate(dstr *v)
	584	{
	585	mp m = (mp **)v[0].buf;
	586	mp mi = (mp **)v[1].buf;
	587	mp r = (mp **)v[2].buf;
	588	mp r2 = (mp **)v[3].buf;
	589
	590	mpmont mm;
	591	int ok = 1;
	592
	593	mpmont_create(&mm, m);
	594
f5f35081	595	if (mm.mi->v[0] != mi->v[0]) {
d3409d5e	596	fprintf(stderr, "\n*** bad mi: found %lu, expected %lu",
f5f35081	597	(unsigned long)mm.mi->v[0], (unsigned long)mi->v[0]);
d3409d5e	598	fputs("\nm = ", stderr); mp_writefile(m, stderr, 10);
	599	fputc('\n', stderr);
	600	ok = 0;
	601	}
	602
032099d1	603	if (!MP_EQ(mm.r, r)) {
d3409d5e	604	fputs("\n*** bad r", stderr);
	605	fputs("\nm = ", stderr); mp_writefile(m, stderr, 10);
	606	fputs("\nexpected ", stderr); mp_writefile(r, stderr, 10);
17ad212e	607	fputs("\n found ", stderr); mp_writefile(mm.r, stderr, 10);
d3409d5e	608	fputc('\n', stderr);
	609	ok = 0;
	610	}
	611
032099d1	612	if (!MP_EQ(mm.r2, r2)) {
d3409d5e	613	fputs("\n*** bad r2", stderr);
	614	fputs("\nm = ", stderr); mp_writefile(m, stderr, 10);
	615	fputs("\nexpected ", stderr); mp_writefile(r2, stderr, 10);
17ad212e	616	fputs("\n found ", stderr); mp_writefile(mm.r2, stderr, 10);
d3409d5e	617	fputc('\n', stderr);
	618	ok = 0;
	619	}
	620
	621	MP_DROP(m);
	622	MP_DROP(mi);
	623	MP_DROP(r);
	624	MP_DROP(r2);
	625	mpmont_destroy(&mm);
ef5f4810	626	assert(mparena_count(MPARENA_GLOBAL) == 0);
d3409d5e	627	return (ok);
	628	}
	629
	630	static int tmul(dstr *v)
	631	{
	632	mp m = (mp **)v[0].buf;
	633	mp a = (mp **)v[1].buf;
	634	mp b = (mp **)v[2].buf;
	635	mp r = (mp **)v[3].buf;
d3409d5e	636	int ok = 1;
	637
	638	mpmont mm;
	639	mpmont_create(&mm, m);
	640
	641	{
79a34029	642	mp *qr = mp_mul(MP_NEW, a, b);
	643	mp_div(0, &qr, qr, m);
	644
032099d1	645	if (!MP_EQ(qr, r)) {
79a34029	646	fputs("\n*** classical modmul failed", stderr);
	647	fputs("\n m = ", stderr); mp_writefile(m, stderr, 10);
	648	fputs("\n a = ", stderr); mp_writefile(a, stderr, 10);
	649	fputs("\n b = ", stderr); mp_writefile(b, stderr, 10);
	650	fputs("\n r = ", stderr); mp_writefile(r, stderr, 10);
	651	fputs("\nqr = ", stderr); mp_writefile(qr, stderr, 10);
	652	fputc('\n', stderr);
	653	ok = 0;
	654	}
	655
	656	mp_drop(qr);
	657	}
	658
	659	{
d3409d5e	660	mp *ar = mpmont_mul(&mm, MP_NEW, a, mm.r2);
d3409d5e	661	mp *br = mpmont_mul(&mm, MP_NEW, b, mm.r2);
79a34029	662	mp *mr = mpmont_mul(&mm, MP_NEW, ar, br);
d3409d5e	663	mr = mpmont_reduce(&mm, mr, mr);
032099d1	664	if (!MP_EQ(mr, r)) {
79a34029	665	fputs("\n*** montgomery modmul failed", stderr);
	666	fputs("\n m = ", stderr); mp_writefile(m, stderr, 10);
	667	fputs("\n a = ", stderr); mp_writefile(a, stderr, 10);
	668	fputs("\n b = ", stderr); mp_writefile(b, stderr, 10);
	669	fputs("\n r = ", stderr); mp_writefile(r, stderr, 10);
	670	fputs("\nmr = ", stderr); mp_writefile(mr, stderr, 10);
	671	fputc('\n', stderr);
	672	ok = 0;
	673	}
d3409d5e	674	MP_DROP(ar); MP_DROP(br);
79a34029	675	mp_drop(mr);
d3409d5e	676	}
d3409d5e	677
d3409d5e	678
	679	MP_DROP(m);
	680	MP_DROP(a);
	681	MP_DROP(b);
	682	MP_DROP(r);
d3409d5e	683	mpmont_destroy(&mm);
ef5f4810	684	assert(mparena_count(MPARENA_GLOBAL) == 0);
d3409d5e	685	return ok;
	686	}
	687
	688	static int texp(dstr *v)
	689	{
	690	mp m = (mp **)v[0].buf;
	691	mp a = (mp **)v[1].buf;
	692	mp b = (mp **)v[2].buf;
	693	mp r = (mp **)v[3].buf;
	694	mp *mr;
	695	int ok = 1;
	696
	697	mpmont mm;
	698	mpmont_create(&mm, m);
	699
ef5f4810	700	mr = mpmont_exp(&mm, MP_NEW, a, b);
d3409d5e	701
032099d1	702	if (!MP_EQ(mr, r)) {
d3409d5e	703	fputs("\n*** montgomery modexp failed", stderr);
	704	fputs("\n m = ", stderr); mp_writefile(m, stderr, 10);
	705	fputs("\n a = ", stderr); mp_writefile(a, stderr, 10);
	706	fputs("\n e = ", stderr); mp_writefile(b, stderr, 10);
	707	fputs("\n r = ", stderr); mp_writefile(r, stderr, 10);
	708	fputs("\nmr = ", stderr); mp_writefile(mr, stderr, 10);
	709	fputc('\n', stderr);
	710	ok = 0;
	711	}
	712
	713	MP_DROP(m);
	714	MP_DROP(a);
	715	MP_DROP(b);
	716	MP_DROP(r);
	717	MP_DROP(mr);
	718	mpmont_destroy(&mm);
ef5f4810	719	assert(mparena_count(MPARENA_GLOBAL) == 0);
d3409d5e	720	return ok;
	721	}
	722
	723
	724	static test_chunk tests[] = {
ef5f4810	725	{ "create", tcreate, { &type_mp, &type_mp, &type_mp, &type_mp, 0 } },
	726	{ "mul", tmul, { &type_mp, &type_mp, &type_mp, &type_mp, 0 } },
	727	{ "exp", texp, { &type_mp, &type_mp, &type_mp, &type_mp, 0 } },
d3409d5e	728	{ 0, 0, { 0 } },
	729	};
	730
	731	int main(int argc, char *argv[])
	732	{
	733	sub_init();
	734	test_run(argc, argv, tests, SRCDIR "/tests/mpmont");
	735	return (0);
	736	}
	737
	738	#endif
	739
	740	/----- That's all, folks -------------------------------------------------/