Mercurial > dropbear
view pkcs_1_pss_encode.c @ 143:5d99163f7e32 libtomcrypt-orig
import of libtomcrypt 0.99
| author | Matt Johnston <matt@ucc.asn.au> |
|---|---|
| date | Sun, 19 Dec 2004 11:34:45 +0000 |
| parents | 6362d3854bb4 |
| 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. * * Tom St Denis, [email protected], http://libtomcrypt.org */ #include "mycrypt.h" /* PKCS #1 PSS Signature Padding -- Tom St Denis */ #ifdef PKCS_1 int pkcs_1_pss_encode(const unsigned char *msghash, unsigned long msghashlen, unsigned long saltlen, prng_state *prng, int prng_idx, int hash_idx, unsigned long modulus_bitlen, unsigned char *out, unsigned long *outlen) { unsigned char *DB, *mask, *salt, *hash; unsigned long x, y, hLen, modulus_len; int err; hash_state md; _ARGCHK(msghash != NULL); _ARGCHK(out != NULL); _ARGCHK(outlen != NULL); /* ensure hash and PRNG are valid */ if ((err = hash_is_valid(hash_idx)) != CRYPT_OK) { return err; } if ((err = prng_is_valid(prng_idx)) != CRYPT_OK) { return err; } hLen = hash_descriptor[hash_idx].hashsize; modulus_len = (modulus_bitlen>>3) + (modulus_bitlen & 7 ? 1 : 0); /* allocate ram for DB/mask/salt/hash of size modulus_len */ DB = XMALLOC(modulus_len); mask = XMALLOC(modulus_len); salt = XMALLOC(modulus_len); hash = XMALLOC(modulus_len); if (DB == NULL || mask == NULL || salt == NULL || hash == NULL) { if (DB != NULL) { XFREE(DB); } if (mask != NULL) { XFREE(mask); } if (salt != NULL) { XFREE(salt); } if (hash != NULL) { XFREE(hash); } return CRYPT_MEM; } /* check sizes */ if ((saltlen > modulus_len) || (modulus_len < hLen + saltlen + 2)) { err = CRYPT_INVALID_ARG; goto __ERR; } /* generate random salt */ if (saltlen > 0) { if (prng_descriptor[prng_idx].read(salt, saltlen, prng) != saltlen) { err = CRYPT_ERROR_READPRNG; goto __ERR; } } /* M = (eight) 0x00 || msghash || salt, hash = H(M) */ if ((err = hash_descriptor[hash_idx].init(&md)) != CRYPT_OK) { goto __ERR; } zeromem(DB, 8); if ((err = hash_descriptor[hash_idx].process(&md, DB, 8)) != CRYPT_OK) { goto __ERR; } if ((err = hash_descriptor[hash_idx].process(&md, msghash, msghashlen)) != CRYPT_OK) { goto __ERR; } if ((err = hash_descriptor[hash_idx].process(&md, salt, saltlen)) != CRYPT_OK) { goto __ERR; } if ((err = hash_descriptor[hash_idx].done(&md, hash)) != CRYPT_OK) { goto __ERR; } /* generate DB = PS || 0x01 || salt, PS == modulus_len - saltlen - hLen - 2 zero bytes */ for (x = 0; x < (modulus_len - saltlen - hLen - 2); x++) { DB[x] = 0x00; } DB[x++] = 0x01; for (y = 0; y < saltlen; y++) { DB[x++] = salt[y]; } /* generate mask of length modulus_len - hLen - 1 from hash */ if ((err = pkcs_1_mgf1(hash, hLen, hash_idx, mask, modulus_len - hLen - 1)) != CRYPT_OK) { goto __ERR; } /* xor against DB */ for (y = 0; y < (modulus_len - hLen - 1); y++) { DB[y] ^= mask[y]; } /* output is DB || hash || 0xBC */ if (*outlen < modulus_len) { err = CRYPT_BUFFER_OVERFLOW; goto __ERR; } /* DB */ for (y = x = 0; x < modulus_len - hLen - 1; x++) { out[y++] = DB[x]; } /* hash */ for (x = 0; x < hLen; x++) { out[y++] = hash[x]; } /* 0xBC */ out[y] = 0xBC; /* now clear the 8*modulus_len - modulus_bitlen most significant bits */ out[0] &= 0xFF >> ((modulus_len<<3) - (modulus_bitlen-1)); /* store output size */ *outlen = modulus_len; err = CRYPT_OK; __ERR: #ifdef CLEAN_STACK zeromem(DB, modulus_len); zeromem(mask, modulus_len); zeromem(salt, modulus_len); zeromem(hash, modulus_len); #endif XFREE(hash); XFREE(salt); XFREE(mask); XFREE(DB); return err; } #endif /* PKCS_1 */