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view libtomcrypt/src/pk/ecc/ltc_ecc_mul2add.c @ 1653:76189c9ffea2

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External Public-Key Authentication API (#72) * Implemented dynamic loading of an external plug-in shared library to delegate public key authentication * Moved conditional compilation of the plugin infrastructure into the configure.ac script to be able to add -ldl to dropbear build only when the flag is enabled * Added tags file to the ignore list * Updated API to have the constructor to return function pointers in the pliugin instance. Added support for passing user name to the checkpubkey function. Added options to the session returned by the plugin and have dropbear to parse and process them * Added -rdynamic to the linker flags when EPKA is enabled * Changed the API to pass a previously created session to the checkPubKey function (created during preauth) * Added documentation to the API * Added parameter addrstring to plugin creation function * Modified the API to retrieve the auth options. Instead of having them as field of the EPKASession struct, they are stored internally (plugin-dependent) in the plugin/session and retrieved through a pointer to a function (in the session) * Changed option string to be a simple char * instead of unsigned char *
author fabriziobertocci <fabriziobertocci@gmail.com>
date Wed, 15 May 2019 09:43:57 -0400
parents 6dba84798cd5
children
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/* LibTomCrypt, modular cryptographic library -- Tom St Denis
 *
 * LibTomCrypt is a library that provides various cryptographic
 * algorithms in a highly modular and flexible manner.
 *
 * The library is free for all purposes without any express
 * guarantee it works.
 */

/* Implements ECC over Z/pZ for curve y^2 = x^3 - 3x + b
 *
 * All curves taken from NIST recommendation paper of July 1999
 * Available at http://csrc.nist.gov/cryptval/dss.htm
 */
#include "tomcrypt.h"

/**
  @file ltc_ecc_mul2add.c
  ECC Crypto, Shamir's Trick, Tom St Denis
*/

#ifdef LTC_MECC

#ifdef LTC_ECC_SHAMIR

/** Computes kA*A + kB*B = C using Shamir's Trick
  @param A        First point to multiply
  @param kA       What to multiple A by
  @param B        Second point to multiply
  @param kB       What to multiple B by
  @param C        [out] Destination point (can overlap with A or B
  @param modulus  Modulus for curve
  @return CRYPT_OK on success
*/
int ltc_ecc_mul2add(ecc_point *A, void *kA,
                    ecc_point *B, void *kB,
                    ecc_point *C,
                         void *modulus)
{
  ecc_point     *precomp[16];
  unsigned       bitbufA, bitbufB, lenA, lenB, len, x, y, nA, nB, nibble;
  unsigned char *tA, *tB;
  int            err, first;
  void          *mp, *mu;

  /* argchks */
  LTC_ARGCHK(A       != NULL);
  LTC_ARGCHK(B       != NULL);
  LTC_ARGCHK(C       != NULL);
  LTC_ARGCHK(kA      != NULL);
  LTC_ARGCHK(kB      != NULL);
  LTC_ARGCHK(modulus != NULL);

  /* allocate memory */
  tA = XCALLOC(1, ECC_BUF_SIZE);
  if (tA == NULL) {
     return CRYPT_MEM;
  }
  tB = XCALLOC(1, ECC_BUF_SIZE);
  if (tB == NULL) {
     XFREE(tA);
     return CRYPT_MEM;
  }

  /* get sizes */
  lenA = mp_unsigned_bin_size(kA);
  lenB = mp_unsigned_bin_size(kB);
  len  = MAX(lenA, lenB);

  /* sanity check */
  if ((lenA > ECC_BUF_SIZE) || (lenB > ECC_BUF_SIZE)) {
     err = CRYPT_INVALID_ARG;
     goto ERR_T;
  }

  /* extract and justify kA */
  mp_to_unsigned_bin(kA, (len - lenA) + tA);

  /* extract and justify kB */
  mp_to_unsigned_bin(kB, (len - lenB) + tB);

  /* allocate the table */
  for (x = 0; x < 16; x++) {
     precomp[x] = ltc_ecc_new_point();
     if (precomp[x] == NULL) {
         for (y = 0; y < x; ++y) {
            ltc_ecc_del_point(precomp[y]);
         }
         err = CRYPT_MEM;
         goto ERR_T;
     }
  }

  /* init montgomery reduction */
  if ((err = mp_montgomery_setup(modulus, &mp)) != CRYPT_OK) {
      goto ERR_P;
  }
  if ((err = mp_init(&mu)) != CRYPT_OK) {
      goto ERR_MP;
  }
  if ((err = mp_montgomery_normalization(mu, modulus)) != CRYPT_OK) {
      goto ERR_MU;
  }

  /* copy ones ... */
  if ((err = mp_mulmod(A->x, mu, modulus, precomp[1]->x)) != CRYPT_OK)                                         { goto ERR_MU; }
  if ((err = mp_mulmod(A->y, mu, modulus, precomp[1]->y)) != CRYPT_OK)                                         { goto ERR_MU; }
  if ((err = mp_mulmod(A->z, mu, modulus, precomp[1]->z)) != CRYPT_OK)                                         { goto ERR_MU; }

  if ((err = mp_mulmod(B->x, mu, modulus, precomp[1<<2]->x)) != CRYPT_OK)                                      { goto ERR_MU; }
  if ((err = mp_mulmod(B->y, mu, modulus, precomp[1<<2]->y)) != CRYPT_OK)                                      { goto ERR_MU; }
  if ((err = mp_mulmod(B->z, mu, modulus, precomp[1<<2]->z)) != CRYPT_OK)                                      { goto ERR_MU; }

  /* precomp [i,0](A + B) table */
  if ((err = ltc_mp.ecc_ptdbl(precomp[1], precomp[2], modulus, mp)) != CRYPT_OK)                               { goto ERR_MU; }
  if ((err = ltc_mp.ecc_ptadd(precomp[1], precomp[2], precomp[3], modulus, mp)) != CRYPT_OK)                   { goto ERR_MU; }

  /* precomp [0,i](A + B) table */
  if ((err = ltc_mp.ecc_ptdbl(precomp[1<<2], precomp[2<<2], modulus, mp)) != CRYPT_OK)                         { goto ERR_MU; }
  if ((err = ltc_mp.ecc_ptadd(precomp[1<<2], precomp[2<<2], precomp[3<<2], modulus, mp)) != CRYPT_OK)          { goto ERR_MU; }

  /* precomp [i,j](A + B) table (i != 0, j != 0) */
  for (x = 1; x < 4; x++) {
     for (y = 1; y < 4; y++) {
        if ((err = ltc_mp.ecc_ptadd(precomp[x], precomp[(y<<2)], precomp[x+(y<<2)], modulus, mp)) != CRYPT_OK) { goto ERR_MU; }
     }
  }

  nibble  = 3;
  first   = 1;
  bitbufA = tA[0];
  bitbufB = tB[0];

  /* for every byte of the multiplicands */
  for (x = 0;; ) {
     /* grab a nibble */
     if (++nibble == 4) {
        if (x == len) break;
        bitbufA = tA[x];
        bitbufB = tB[x];
        nibble  = 0;
        ++x;
     }

     /* extract two bits from both, shift/update */
     nA = (bitbufA >> 6) & 0x03;
     nB = (bitbufB >> 6) & 0x03;
     bitbufA = (bitbufA << 2) & 0xFF;
     bitbufB = (bitbufB << 2) & 0xFF;

     /* if both zero, if first, continue */
     if ((nA == 0) && (nB == 0) && (first == 1)) {
        continue;
     }

     /* double twice, only if this isn't the first */
     if (first == 0) {
        /* double twice */
        if ((err = ltc_mp.ecc_ptdbl(C, C, modulus, mp)) != CRYPT_OK)                  { goto ERR_MU; }
        if ((err = ltc_mp.ecc_ptdbl(C, C, modulus, mp)) != CRYPT_OK)                  { goto ERR_MU; }
     }

     /* if not both zero */
     if ((nA != 0) || (nB != 0)) {
        if (first == 1) {
           /* if first, copy from table */
           first = 0;
           if ((err = mp_copy(precomp[nA + (nB<<2)]->x, C->x)) != CRYPT_OK)           { goto ERR_MU; }
           if ((err = mp_copy(precomp[nA + (nB<<2)]->y, C->y)) != CRYPT_OK)           { goto ERR_MU; }
           if ((err = mp_copy(precomp[nA + (nB<<2)]->z, C->z)) != CRYPT_OK)           { goto ERR_MU; }
        } else {
           /* if not first, add from table */
           if ((err = ltc_mp.ecc_ptadd(C, precomp[nA + (nB<<2)], C, modulus, mp)) != CRYPT_OK) { goto ERR_MU; }
        }
     }
  }

  /* reduce to affine */
  err = ltc_ecc_map(C, modulus, mp);

  /* clean up */
ERR_MU:
   mp_clear(mu);
ERR_MP:
   mp_montgomery_free(mp);
ERR_P:
   for (x = 0; x < 16; x++) {
       ltc_ecc_del_point(precomp[x]);
   }
ERR_T:
#ifdef LTC_CLEAN_STACK
   zeromem(tA, ECC_BUF_SIZE);
   zeromem(tB, ECC_BUF_SIZE);
#endif
   XFREE(tA);
   XFREE(tB);

   return err;
}

#endif
#endif

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