Mercurial > dropbear
view libtomcrypt/src/pk/ecc/ltc_ecc_mulmod.c @ 1861:2b3a8026a6ce
Add re-exec for server
This allows ASLR to re-randomize the address
space for every connection, preventing some
vulnerabilities from being exploitable by
repeated probing.
Overhead (memory and time) is yet to be confirmed.
At present this is only enabled on Linux. Other BSD platforms
with fexecve() would probably also work though have not been tested.
| author | Matt Johnston <matt@ucc.asn.au> |
|---|---|
| date | Sun, 30 Jan 2022 10:14:56 +0800 |
| 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_mulmod.c ECC Crypto, Tom St Denis */ #ifdef LTC_MECC #ifndef LTC_ECC_TIMING_RESISTANT /* size of sliding window, don't change this! */ #define WINSIZE 4 /** Perform a point multiplication @param k The scalar to multiply by @param G The base point @param R [out] Destination for kG @param modulus The modulus of the field the ECC curve is in @param map Boolean whether to map back to affine or not (1==map, 0 == leave in projective) @return CRYPT_OK on success */ int ltc_ecc_mulmod(void *k, ecc_point *G, ecc_point *R, void *modulus, int map) { ecc_point *tG, *M[8]; int i, j, err; void *mu, *mp; ltc_mp_digit buf; int first, bitbuf, bitcpy, bitcnt, mode, digidx; LTC_ARGCHK(k != NULL); LTC_ARGCHK(G != NULL); LTC_ARGCHK(R != NULL); LTC_ARGCHK(modulus != NULL); /* init montgomery reduction */ if ((err = mp_montgomery_setup(modulus, &mp)) != CRYPT_OK) { return err; } if ((err = mp_init(&mu)) != CRYPT_OK) { mp_montgomery_free(mp); return err; } if ((err = mp_montgomery_normalization(mu, modulus)) != CRYPT_OK) { mp_montgomery_free(mp); mp_clear(mu); return err; } /* alloc ram for window temps */ for (i = 0; i < 8; i++) { M[i] = ltc_ecc_new_point(); if (M[i] == NULL) { for (j = 0; j < i; j++) { ltc_ecc_del_point(M[j]); } mp_montgomery_free(mp); mp_clear(mu); return CRYPT_MEM; } } /* make a copy of G incase R==G */ tG = ltc_ecc_new_point(); if (tG == NULL) { err = CRYPT_MEM; goto done; } /* tG = G and convert to montgomery */ if (mp_cmp_d(mu, 1) == LTC_MP_EQ) { if ((err = mp_copy(G->x, tG->x)) != CRYPT_OK) { goto done; } if ((err = mp_copy(G->y, tG->y)) != CRYPT_OK) { goto done; } if ((err = mp_copy(G->z, tG->z)) != CRYPT_OK) { goto done; } } else { if ((err = mp_mulmod(G->x, mu, modulus, tG->x)) != CRYPT_OK) { goto done; } if ((err = mp_mulmod(G->y, mu, modulus, tG->y)) != CRYPT_OK) { goto done; } if ((err = mp_mulmod(G->z, mu, modulus, tG->z)) != CRYPT_OK) { goto done; } } mp_clear(mu); mu = NULL; /* calc the M tab, which holds kG for k==8..15 */ /* M[0] == 8G */ if ((err = ltc_mp.ecc_ptdbl(tG, M[0], modulus, mp)) != CRYPT_OK) { goto done; } if ((err = ltc_mp.ecc_ptdbl(M[0], M[0], modulus, mp)) != CRYPT_OK) { goto done; } if ((err = ltc_mp.ecc_ptdbl(M[0], M[0], modulus, mp)) != CRYPT_OK) { goto done; } /* now find (8+k)G for k=1..7 */ for (j = 9; j < 16; j++) { if ((err = ltc_mp.ecc_ptadd(M[j-9], tG, M[j-8], modulus, mp)) != CRYPT_OK) { goto done; } } /* setup sliding window */ mode = 0; bitcnt = 1; buf = 0; digidx = mp_get_digit_count(k) - 1; bitcpy = bitbuf = 0; first = 1; /* perform ops */ for (;;) { /* grab next digit as required */ if (--bitcnt == 0) { if (digidx == -1) { break; } buf = mp_get_digit(k, digidx); bitcnt = (int) ltc_mp.bits_per_digit; --digidx; } /* grab the next msb from the ltiplicand */ i = (buf >> (ltc_mp.bits_per_digit - 1)) & 1; buf <<= 1; /* skip leading zero bits */ if (mode == 0 && i == 0) { continue; } /* if the bit is zero and mode == 1 then we double */ if (mode == 1 && i == 0) { if ((err = ltc_mp.ecc_ptdbl(R, R, modulus, mp)) != CRYPT_OK) { goto done; } continue; } /* else we add it to the window */ bitbuf |= (i << (WINSIZE - ++bitcpy)); mode = 2; if (bitcpy == WINSIZE) { /* if this is the first window we do a simple copy */ if (first == 1) { /* R = kG [k = first window] */ if ((err = mp_copy(M[bitbuf-8]->x, R->x)) != CRYPT_OK) { goto done; } if ((err = mp_copy(M[bitbuf-8]->y, R->y)) != CRYPT_OK) { goto done; } if ((err = mp_copy(M[bitbuf-8]->z, R->z)) != CRYPT_OK) { goto done; } first = 0; } else { /* normal window */ /* ok window is filled so double as required and add */ /* double first */ for (j = 0; j < WINSIZE; j++) { if ((err = ltc_mp.ecc_ptdbl(R, R, modulus, mp)) != CRYPT_OK) { goto done; } } /* then add, bitbuf will be 8..15 [8..2^WINSIZE] guaranteed */ if ((err = ltc_mp.ecc_ptadd(R, M[bitbuf-8], R, modulus, mp)) != CRYPT_OK) { goto done; } } /* empty window and reset */ bitcpy = bitbuf = 0; mode = 1; } } /* if bits remain then double/add */ if (mode == 2 && bitcpy > 0) { /* double then add */ for (j = 0; j < bitcpy; j++) { /* only double if we have had at least one add first */ if (first == 0) { if ((err = ltc_mp.ecc_ptdbl(R, R, modulus, mp)) != CRYPT_OK) { goto done; } } bitbuf <<= 1; if ((bitbuf & (1 << WINSIZE)) != 0) { if (first == 1){ /* first add, so copy */ if ((err = mp_copy(tG->x, R->x)) != CRYPT_OK) { goto done; } if ((err = mp_copy(tG->y, R->y)) != CRYPT_OK) { goto done; } if ((err = mp_copy(tG->z, R->z)) != CRYPT_OK) { goto done; } first = 0; } else { /* then add */ if ((err = ltc_mp.ecc_ptadd(R, tG, R, modulus, mp)) != CRYPT_OK) { goto done; } } } } } /* map R back from projective space */ if (map) { err = ltc_ecc_map(R, modulus, mp); } else { err = CRYPT_OK; } done: if (mu != NULL) { mp_clear(mu); } mp_montgomery_free(mp); ltc_ecc_del_point(tG); for (i = 0; i < 8; i++) { ltc_ecc_del_point(M[i]); } return err; } #endif #undef WINSIZE #endif /* ref: $Format:%D$ */ /* git commit: $Format:%H$ */ /* commit time: $Format:%ai$ */