libgcrypt-1.4.6/mpi/mpi-pow.c - nest-learning-thermostat/5.1/libgcrypt - Git at Google

 /* mpi-pow.c  -  MPI functions for exponentiation
  * Copyright (C) 1994, 1996, 1998, 2000, 2002
  *               2003  Free Software Foundation, Inc.
  *
  * This file is part of Libgcrypt.
  *
  * Libgcrypt is free software; you can redistribute it and/or modify
  * it under the terms of the GNU Lesser General Public License as
  * published by the Free Software Foundation; either version 2.1 of
  * the License, or (at your option) any later version.
  *
  * Libgcrypt 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 Lesser General Public License for more details.
  *
  * You should have received a copy of the GNU Lesser General Public
  * License along with this program; if not, see <http://www.gnu.org/licenses/>.
  *
  * Note: This code is heavily based on the GNU MP Library.
  *	 Actually it's the same code with only minor changes in the
  *	 way the data is stored; this is to support the abstraction
  *	 of an optional secure memory allocation which may be used
  *	 to avoid revealing of sensitive data due to paging etc.
  */

 #include <config.h>
 #include <stdio.h>
 #include <stdlib.h>
 #include <string.h>

 #include "mpi-internal.h"
 #include "longlong.h"


 /****************
  * RES = BASE ^ EXPO mod MOD
  */
 void
 gcry_mpi_powm (gcry_mpi_t res,
                gcry_mpi_t base, gcry_mpi_t expo, gcry_mpi_t mod)
 {
   /* Pointer to the limbs of the arguments, their size and signs. */
   mpi_ptr_t  rp, ep, mp, bp;
   mpi_size_t esize, msize, bsize, rsize;
   int               msign, bsign, rsign;
   /* Flags telling the secure allocation status of the arguments.  */
   int        esec,  msec,  bsec,  rsec;
   /* Size of the result including space for temporary values.  */
   mpi_size_t size;
   /* Helper.  */
   int mod_shift_cnt;
   int negative_result;
   mpi_ptr_t mp_marker = NULL;
   mpi_ptr_t bp_marker = NULL;
   mpi_ptr_t ep_marker = NULL;
   mpi_ptr_t xp_marker = NULL;
   unsigned int mp_nlimbs = 0;
   unsigned int bp_nlimbs = 0;
   unsigned int ep_nlimbs = 0;
   unsigned int xp_nlimbs = 0;
   mpi_ptr_t tspace = NULL;
   mpi_size_t tsize = 0;


   esize = expo->nlimbs;
   msize = mod->nlimbs;
   size = 2 * msize;
   msign = mod->sign;

   esec = mpi_is_secure(expo);
   msec = mpi_is_secure(mod);
   bsec = mpi_is_secure(base);
   rsec = mpi_is_secure(res);

   rp = res->d;
   ep = expo->d;

   if (!msize)
     msize = 1 / msize;	    /* Provoke a signal.  */

   if (!esize)
     {
       /* Exponent is zero, result is 1 mod MOD, i.e., 1 or 0 depending
         on if MOD equals 1.  */
       rp[0] = 1;
       res->nlimbs = (msize == 1 && mod->d[0] == 1) ? 0 : 1;
       res->sign = 0;
       goto leave;
     }

   /* Normalize MOD (i.e. make its most significant bit set) as
      required by mpn_divrem.  This will make the intermediate values
      in the calculation slightly larger, but the correct result is
      obtained after a final reduction using the original MOD value. */
   mp_nlimbs = msec? msize:0;
   mp = mp_marker = mpi_alloc_limb_space(msize, msec);
   count_leading_zeros (mod_shift_cnt, mod->d[msize-1]);
   if (mod_shift_cnt)
     _gcry_mpih_lshift (mp, mod->d, msize, mod_shift_cnt);
   else
     MPN_COPY( mp, mod->d, msize );

   bsize = base->nlimbs;
   bsign = base->sign;
   if (bsize > msize)
     {
       /* The base is larger than the module.  Reduce it.

          Allocate (BSIZE + 1) with space for remainder and quotient.
          (The quotient is (bsize - msize + 1) limbs.)  */
       bp_nlimbs = bsec ? (bsize + 1):0;
       bp = bp_marker = mpi_alloc_limb_space( bsize + 1, bsec );
       MPN_COPY ( bp, base->d, bsize );
       /* We don't care about the quotient, store it above the
        * remainder, at BP + MSIZE.  */
       _gcry_mpih_divrem( bp + msize, 0, bp, bsize, mp, msize );
       bsize = msize;
       /* Canonicalize the base, since we are going to multiply with it
 	 quite a few times.  */
       MPN_NORMALIZE( bp, bsize );
     }
   else
     bp = base->d;

   if (!bsize)
     {
       res->nlimbs = 0;
       res->sign = 0;
       goto leave;
     }


   /* Make BASE, EXPO and MOD not overlap with RES.  */
   if ( rp == bp )
     {
       /* RES and BASE are identical.  Allocate temp. space for BASE.  */
       gcry_assert (!bp_marker);
       bp_nlimbs = bsec? bsize:0;
       bp = bp_marker = mpi_alloc_limb_space( bsize, bsec );
       MPN_COPY(bp, rp, bsize);
     }
   if ( rp == ep )
     {
       /* RES and EXPO are identical.  Allocate temp. space for EXPO.  */
       ep_nlimbs = esec? esize:0;
       ep = ep_marker = mpi_alloc_limb_space( esize, esec );
       MPN_COPY(ep, rp, esize);
     }
   if ( rp == mp )
     {
       /* RES and MOD are identical.  Allocate temporary space for MOD.*/
       gcry_assert (!mp_marker);
       mp_nlimbs = msec?msize:0;
       mp = mp_marker = mpi_alloc_limb_space( msize, msec );
       MPN_COPY(mp, rp, msize);
     }

   /* Copy base to the result.  */
   if (res->alloced < size)
     {
       mpi_resize (res, size);
       rp = res->d;
     }
   MPN_COPY ( rp, bp, bsize );
   rsize = bsize;
   rsign = bsign;

   /* Main processing.  */
   {
     mpi_size_t i;
     mpi_ptr_t xp;
     int c;
     mpi_limb_t e;
     mpi_limb_t carry_limb;
     struct karatsuba_ctx karactx;

     xp_nlimbs = msec? (2 * (msize + 1)):0;
     xp = xp_marker = mpi_alloc_limb_space( 2 * (msize + 1), msec );

     memset( &karactx, 0, sizeof karactx );
     negative_result = (ep[0] & 1) && base->sign;

     i = esize - 1;
     e = ep[i];
     count_leading_zeros (c, e);
     e = (e << c) << 1;     /* Shift the expo bits to the left, lose msb.  */
     c = BITS_PER_MPI_LIMB - 1 - c;

     /* Main loop.

        Make the result be pointed to alternately by XP and RP.  This
        helps us avoid block copying, which would otherwise be
        necessary with the overlap restrictions of
        _gcry_mpih_divmod. With 50% probability the result after this
        loop will be in the area originally pointed by RP (==RES->d),
        and with 50% probability in the area originally pointed to by XP. */
     for (;;)
       {
         while (c)
           {
             mpi_ptr_t tp;
             mpi_size_t xsize;

             /*mpih_mul_n(xp, rp, rp, rsize);*/
             if ( rsize < KARATSUBA_THRESHOLD )
               _gcry_mpih_sqr_n_basecase( xp, rp, rsize );
             else
               {
                 if ( !tspace )
                   {
                     tsize = 2 * rsize;
                     tspace = mpi_alloc_limb_space( tsize, 0 );
                   }
                 else if ( tsize < (2*rsize) )
                   {
                     _gcry_mpi_free_limb_space (tspace, 0);
                     tsize = 2 * rsize;
                     tspace = mpi_alloc_limb_space (tsize, 0 );
                   }
                 _gcry_mpih_sqr_n (xp, rp, rsize, tspace);
               }

             xsize = 2 * rsize;
             if ( xsize > msize )
               {
                 _gcry_mpih_divrem(xp + msize, 0, xp, xsize, mp, msize);
                 xsize = msize;
               }

             tp = rp; rp = xp; xp = tp;
             rsize = xsize;

             if ( (mpi_limb_signed_t)e < 0 )
               {
                 /*mpih_mul( xp, rp, rsize, bp, bsize );*/
                 if( bsize < KARATSUBA_THRESHOLD )
                   _gcry_mpih_mul ( xp, rp, rsize, bp, bsize );
                 else
                   _gcry_mpih_mul_karatsuba_case (xp, rp, rsize, bp, bsize,
                                                  &karactx);

                 xsize = rsize + bsize;
                 if ( xsize > msize )
                   {
                     _gcry_mpih_divrem(xp + msize, 0, xp, xsize, mp, msize);
                     xsize = msize;
                   }

                 tp = rp; rp = xp; xp = tp;
                 rsize = xsize;
               }
             e <<= 1;
             c--;
           }

         i--;
         if ( i < 0 )
           break;
         e = ep[i];
         c = BITS_PER_MPI_LIMB;
       }

     /* We shifted MOD, the modulo reduction argument, left
        MOD_SHIFT_CNT steps.  Adjust the result by reducing it with the
        original MOD.

        Also make sure the result is put in RES->d (where it already
        might be, see above).  */
     if ( mod_shift_cnt )
       {
         carry_limb = _gcry_mpih_lshift( res->d, rp, rsize, mod_shift_cnt);
         rp = res->d;
         if ( carry_limb )
           {
             rp[rsize] = carry_limb;
             rsize++;
           }
       }
     else if (res->d != rp)
       {
         MPN_COPY (res->d, rp, rsize);
         rp = res->d;
       }

     if ( rsize >= msize )
       {
         _gcry_mpih_divrem(rp + msize, 0, rp, rsize, mp, msize);
         rsize = msize;
       }

     /* Remove any leading zero words from the result.  */
     if ( mod_shift_cnt )
       _gcry_mpih_rshift( rp, rp, rsize, mod_shift_cnt);
     MPN_NORMALIZE (rp, rsize);

     _gcry_mpih_release_karatsuba_ctx (&karactx );
   }

   /* Fixup for negative results.  */
   if ( negative_result && rsize )
     {
       if ( mod_shift_cnt )
         _gcry_mpih_rshift( mp, mp, msize, mod_shift_cnt);
       _gcry_mpih_sub( rp, mp, msize, rp, rsize);
       rsize = msize;
       rsign = msign;
       MPN_NORMALIZE(rp, rsize);
     }
   gcry_assert (res->d == rp);
   res->nlimbs = rsize;
   res->sign = rsign;

  leave:
   if (mp_marker)
     _gcry_mpi_free_limb_space( mp_marker, mp_nlimbs );
   if (bp_marker)
     _gcry_mpi_free_limb_space( bp_marker, bp_nlimbs );
   if (ep_marker)
     _gcry_mpi_free_limb_space( ep_marker, ep_nlimbs );
   if (xp_marker)
     _gcry_mpi_free_limb_space( xp_marker, xp_nlimbs );
   if (tspace)
     _gcry_mpi_free_limb_space( tspace, 0 );
 }
	/* mpi-pow.c - MPI functions for exponentiation
	* Copyright (C) 1994, 1996, 1998, 2000, 2002
	* 2003 Free Software Foundation, Inc.
	*
	* This file is part of Libgcrypt.
	*
	* Libgcrypt is free software; you can redistribute it and/or modify
	* it under the terms of the GNU Lesser General Public License as
	* published by the Free Software Foundation; either version 2.1 of
	* the License, or (at your option) any later version.
	*
	* Libgcrypt 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 Lesser General Public License for more details.
	*
	* You should have received a copy of the GNU Lesser General Public
	* License along with this program; if not, see <http://www.gnu.org/licenses/>.
	*
	* Note: This code is heavily based on the GNU MP Library.
	* Actually it's the same code with only minor changes in the
	* way the data is stored; this is to support the abstraction
	* of an optional secure memory allocation which may be used
	* to avoid revealing of sensitive data due to paging etc.
	*/

	#include <config.h>
	#include <stdio.h>
	#include <stdlib.h>
	#include <string.h>

	#include "mpi-internal.h"
	#include "longlong.h"


	/****************
	* RES = BASE ^ EXPO mod MOD
	*/
	void
	gcry_mpi_powm (gcry_mpi_t res,
	gcry_mpi_t base, gcry_mpi_t expo, gcry_mpi_t mod)
	{
	/* Pointer to the limbs of the arguments, their size and signs. */
	mpi_ptr_t rp, ep, mp, bp;
	mpi_size_t esize, msize, bsize, rsize;
	int msign, bsign, rsign;
	/* Flags telling the secure allocation status of the arguments. */
	int esec, msec, bsec, rsec;
	/* Size of the result including space for temporary values. */
	mpi_size_t size;
	/* Helper. */
	int mod_shift_cnt;
	int negative_result;
	mpi_ptr_t mp_marker = NULL;
	mpi_ptr_t bp_marker = NULL;
	mpi_ptr_t ep_marker = NULL;
	mpi_ptr_t xp_marker = NULL;
	unsigned int mp_nlimbs = 0;
	unsigned int bp_nlimbs = 0;
	unsigned int ep_nlimbs = 0;
	unsigned int xp_nlimbs = 0;
	mpi_ptr_t tspace = NULL;
	mpi_size_t tsize = 0;


	esize = expo->nlimbs;
	msize = mod->nlimbs;
	size = 2 * msize;
	msign = mod->sign;

	esec = mpi_is_secure(expo);
	msec = mpi_is_secure(mod);
	bsec = mpi_is_secure(base);
	rsec = mpi_is_secure(res);

	rp = res->d;
	ep = expo->d;

	if (!msize)
	msize = 1 / msize; /* Provoke a signal. */

	if (!esize)
	{
	/* Exponent is zero, result is 1 mod MOD, i.e., 1 or 0 depending
	on if MOD equals 1. */
	rp[0] = 1;
	res->nlimbs = (msize == 1 && mod->d[0] == 1) ? 0 : 1;
	res->sign = 0;
	goto leave;
	}

	/* Normalize MOD (i.e. make its most significant bit set) as
	required by mpn_divrem. This will make the intermediate values
	in the calculation slightly larger, but the correct result is
	obtained after a final reduction using the original MOD value. */
	mp_nlimbs = msec? msize:0;
	mp = mp_marker = mpi_alloc_limb_space(msize, msec);
	count_leading_zeros (mod_shift_cnt, mod->d[msize-1]);
	if (mod_shift_cnt)
	_gcry_mpih_lshift (mp, mod->d, msize, mod_shift_cnt);
	else
	MPN_COPY( mp, mod->d, msize );

	bsize = base->nlimbs;
	bsign = base->sign;
	if (bsize > msize)
	{
	/* The base is larger than the module. Reduce it.

	Allocate (BSIZE + 1) with space for remainder and quotient.
	(The quotient is (bsize - msize + 1) limbs.) */
	bp_nlimbs = bsec ? (bsize + 1):0;
	bp = bp_marker = mpi_alloc_limb_space( bsize + 1, bsec );
	MPN_COPY ( bp, base->d, bsize );
	/* We don't care about the quotient, store it above the
	* remainder, at BP + MSIZE. */
	_gcry_mpih_divrem( bp + msize, 0, bp, bsize, mp, msize );
	bsize = msize;
	/* Canonicalize the base, since we are going to multiply with it
	quite a few times. */
	MPN_NORMALIZE( bp, bsize );
	}
	else
	bp = base->d;

	if (!bsize)
	{
	res->nlimbs = 0;
	res->sign = 0;
	goto leave;
	}


	/* Make BASE, EXPO and MOD not overlap with RES. */
	if ( rp == bp )
	{
	/* RES and BASE are identical. Allocate temp. space for BASE. */
	gcry_assert (!bp_marker);
	bp_nlimbs = bsec? bsize:0;
	bp = bp_marker = mpi_alloc_limb_space( bsize, bsec );
	MPN_COPY(bp, rp, bsize);
	}
	if ( rp == ep )
	{
	/* RES and EXPO are identical. Allocate temp. space for EXPO. */
	ep_nlimbs = esec? esize:0;
	ep = ep_marker = mpi_alloc_limb_space( esize, esec );
	MPN_COPY(ep, rp, esize);
	}
	if ( rp == mp )
	{
	/* RES and MOD are identical. Allocate temporary space for MOD.*/
	gcry_assert (!mp_marker);
	mp_nlimbs = msec?msize:0;
	mp = mp_marker = mpi_alloc_limb_space( msize, msec );
	MPN_COPY(mp, rp, msize);
	}

	/* Copy base to the result. */
	if (res->alloced < size)
	{
	mpi_resize (res, size);
	rp = res->d;
	}
	MPN_COPY ( rp, bp, bsize );
	rsize = bsize;
	rsign = bsign;

	/* Main processing. */
	{
	mpi_size_t i;
	mpi_ptr_t xp;
	int c;
	mpi_limb_t e;
	mpi_limb_t carry_limb;
	struct karatsuba_ctx karactx;

	xp_nlimbs = msec? (2 * (msize + 1)):0;
	xp = xp_marker = mpi_alloc_limb_space( 2 * (msize + 1), msec );

	memset( &karactx, 0, sizeof karactx );
	negative_result = (ep[0] & 1) && base->sign;

	i = esize - 1;
	e = ep[i];
	count_leading_zeros (c, e);
	e = (e << c) << 1; /* Shift the expo bits to the left, lose msb. */
	c = BITS_PER_MPI_LIMB - 1 - c;

	/* Main loop.

	Make the result be pointed to alternately by XP and RP. This
	helps us avoid block copying, which would otherwise be
	necessary with the overlap restrictions of
	_gcry_mpih_divmod. With 50% probability the result after this
	loop will be in the area originally pointed by RP (==RES->d),
	and with 50% probability in the area originally pointed to by XP. */
	for (;;)
	{
	while (c)
	{
	mpi_ptr_t tp;
	mpi_size_t xsize;

	/mpih_mul_n(xp, rp, rp, rsize);/
	if ( rsize < KARATSUBA_THRESHOLD )
	_gcry_mpih_sqr_n_basecase( xp, rp, rsize );
	else
	{
	if ( !tspace )
	{
	tsize = 2 * rsize;
	tspace = mpi_alloc_limb_space( tsize, 0 );
	}
	else if ( tsize < (2*rsize) )
	{
	_gcry_mpi_free_limb_space (tspace, 0);
	tsize = 2 * rsize;
	tspace = mpi_alloc_limb_space (tsize, 0 );
	}
	_gcry_mpih_sqr_n (xp, rp, rsize, tspace);
	}

	xsize = 2 * rsize;
	if ( xsize > msize )
	{
	_gcry_mpih_divrem(xp + msize, 0, xp, xsize, mp, msize);
	xsize = msize;
	}

	tp = rp; rp = xp; xp = tp;
	rsize = xsize;

	if ( (mpi_limb_signed_t)e < 0 )
	{
	/mpih_mul( xp, rp, rsize, bp, bsize );/
	if( bsize < KARATSUBA_THRESHOLD )
	_gcry_mpih_mul ( xp, rp, rsize, bp, bsize );
	else
	_gcry_mpih_mul_karatsuba_case (xp, rp, rsize, bp, bsize,
	&karactx);

	xsize = rsize + bsize;
	if ( xsize > msize )
	{
	_gcry_mpih_divrem(xp + msize, 0, xp, xsize, mp, msize);
	xsize = msize;
	}

	tp = rp; rp = xp; xp = tp;
	rsize = xsize;
	}
	e <<= 1;
	c--;
	}

	i--;
	if ( i < 0 )
	break;
	e = ep[i];
	c = BITS_PER_MPI_LIMB;
	}

	/* We shifted MOD, the modulo reduction argument, left
	MOD_SHIFT_CNT steps. Adjust the result by reducing it with the
	original MOD.

	Also make sure the result is put in RES->d (where it already
	might be, see above). */
	if ( mod_shift_cnt )
	{
	carry_limb = _gcry_mpih_lshift( res->d, rp, rsize, mod_shift_cnt);
	rp = res->d;
	if ( carry_limb )
	{
	rp[rsize] = carry_limb;
	rsize++;
	}
	}
	else if (res->d != rp)
	{
	MPN_COPY (res->d, rp, rsize);
	rp = res->d;
	}

	if ( rsize >= msize )
	{
	_gcry_mpih_divrem(rp + msize, 0, rp, rsize, mp, msize);
	rsize = msize;
	}

	/* Remove any leading zero words from the result. */
	if ( mod_shift_cnt )
	_gcry_mpih_rshift( rp, rp, rsize, mod_shift_cnt);
	MPN_NORMALIZE (rp, rsize);

	_gcry_mpih_release_karatsuba_ctx (&karactx );
	}

	/* Fixup for negative results. */
	if ( negative_result && rsize )
	{
	if ( mod_shift_cnt )
	_gcry_mpih_rshift( mp, mp, msize, mod_shift_cnt);
	_gcry_mpih_sub( rp, mp, msize, rp, rsize);
	rsize = msize;
	rsign = msign;
	MPN_NORMALIZE(rp, rsize);
	}
	gcry_assert (res->d == rp);
	res->nlimbs = rsize;
	res->sign = rsign;

	leave:
	if (mp_marker)
	_gcry_mpi_free_limb_space( mp_marker, mp_nlimbs );
	if (bp_marker)
	_gcry_mpi_free_limb_space( bp_marker, bp_nlimbs );
	if (ep_marker)
	_gcry_mpi_free_limb_space( ep_marker, ep_nlimbs );
	if (xp_marker)
	_gcry_mpi_free_limb_space( xp_marker, xp_nlimbs );
	if (tspace)
	_gcry_mpi_free_limb_space( tspace, 0 );
	}