Mercurial > dropbear
view dss.c @ 1122:aaf576b27a10
Merge pull request #13 from gazoo74/fix-warnings
Fix warnings
author | Matt Johnston <matt@ucc.asn.au> |
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date | Thu, 04 Jun 2015 23:08:50 +0800 |
parents | c45d65392c1a |
children | 750ec4ec4cbe |
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/* * Dropbear - a SSH2 server * * Copyright (c) 2002,2003 Matt Johnston * All rights reserved. * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE * SOFTWARE. */ #include "includes.h" #include "dbutil.h" #include "bignum.h" #include "dss.h" #include "buffer.h" #include "ssh.h" #include "dbrandom.h" /* Handle DSS (Digital Signature Standard), aka DSA (D.S. Algorithm), * operations, such as key reading, signing, verification. Key generation * is in gendss.c, since it isn't required in the server itself. * * See FIPS186 or the Handbook of Applied Cryptography for details of the * algorithm */ #ifdef DROPBEAR_DSS /* Load a dss key from a buffer, initialising the values. * The key will have the same format as buf_put_dss_key. * These should be freed with dss_key_free. * Returns DROPBEAR_SUCCESS or DROPBEAR_FAILURE */ int buf_get_dss_pub_key(buffer* buf, dropbear_dss_key *key) { TRACE(("enter buf_get_dss_pub_key")) dropbear_assert(key != NULL); m_mp_alloc_init_multi(&key->p, &key->q, &key->g, &key->y, NULL); key->x = NULL; buf_incrpos(buf, 4+SSH_SIGNKEY_DSS_LEN); /* int + "ssh-dss" */ if (buf_getmpint(buf, key->p) == DROPBEAR_FAILURE || buf_getmpint(buf, key->q) == DROPBEAR_FAILURE || buf_getmpint(buf, key->g) == DROPBEAR_FAILURE || buf_getmpint(buf, key->y) == DROPBEAR_FAILURE) { TRACE(("leave buf_get_dss_pub_key: failed reading mpints")) return DROPBEAR_FAILURE; } if (mp_count_bits(key->p) < MIN_DSS_KEYLEN) { dropbear_log(LOG_WARNING, "DSS key too short"); TRACE(("leave buf_get_dss_pub_key: short key")) return DROPBEAR_FAILURE; } TRACE(("leave buf_get_dss_pub_key: success")) return DROPBEAR_SUCCESS; } /* Same as buf_get_dss_pub_key, but reads a private "x" key at the end. * Loads a private dss key from a buffer * Returns DROPBEAR_SUCCESS or DROPBEAR_FAILURE */ int buf_get_dss_priv_key(buffer* buf, dropbear_dss_key *key) { int ret = DROPBEAR_FAILURE; dropbear_assert(key != NULL); ret = buf_get_dss_pub_key(buf, key); if (ret == DROPBEAR_FAILURE) { return DROPBEAR_FAILURE; } m_mp_alloc_init_multi(&key->x, NULL); ret = buf_getmpint(buf, key->x); if (ret == DROPBEAR_FAILURE) { m_free(key->x); } return ret; } /* Clear and free the memory used by a public or private key */ void dss_key_free(dropbear_dss_key *key) { TRACE2(("enter dsa_key_free")) if (key == NULL) { TRACE2(("enter dsa_key_free: key == NULL")) return; } if (key->p) { mp_clear(key->p); m_free(key->p); } if (key->q) { mp_clear(key->q); m_free(key->q); } if (key->g) { mp_clear(key->g); m_free(key->g); } if (key->y) { mp_clear(key->y); m_free(key->y); } if (key->x) { mp_clear(key->x); m_free(key->x); } m_free(key); TRACE2(("leave dsa_key_free")) } /* put the dss public key into the buffer in the required format: * * string "ssh-dss" * mpint p * mpint q * mpint g * mpint y */ void buf_put_dss_pub_key(buffer* buf, dropbear_dss_key *key) { dropbear_assert(key != NULL); buf_putstring(buf, SSH_SIGNKEY_DSS, SSH_SIGNKEY_DSS_LEN); buf_putmpint(buf, key->p); buf_putmpint(buf, key->q); buf_putmpint(buf, key->g); buf_putmpint(buf, key->y); } /* Same as buf_put_dss_pub_key, but with the private "x" key appended */ void buf_put_dss_priv_key(buffer* buf, dropbear_dss_key *key) { dropbear_assert(key != NULL); buf_put_dss_pub_key(buf, key); buf_putmpint(buf, key->x); } #ifdef DROPBEAR_SIGNKEY_VERIFY /* Verify a DSS signature (in buf) made on data by the key given. * returns DROPBEAR_SUCCESS or DROPBEAR_FAILURE */ int buf_dss_verify(buffer* buf, dropbear_dss_key *key, buffer *data_buf) { unsigned char msghash[SHA1_HASH_SIZE]; hash_state hs; int ret = DROPBEAR_FAILURE; DEF_MP_INT(val1); DEF_MP_INT(val2); DEF_MP_INT(val3); DEF_MP_INT(val4); char * string = NULL; unsigned int stringlen; TRACE(("enter buf_dss_verify")) dropbear_assert(key != NULL); m_mp_init_multi(&val1, &val2, &val3, &val4, NULL); /* get blob, check length */ string = buf_getstring(buf, &stringlen); if (stringlen != 2*SHA1_HASH_SIZE) { goto out; } /* hash the data */ sha1_init(&hs); sha1_process(&hs, data_buf->data, data_buf->len); sha1_done(&hs, msghash); /* create the signature - s' and r' are the received signatures in buf */ /* w = (s')-1 mod q */ /* let val1 = s' */ bytes_to_mp(&val1, (const unsigned char*) &string[SHA1_HASH_SIZE], SHA1_HASH_SIZE); if (mp_cmp(&val1, key->q) != MP_LT) { TRACE(("verify failed, s' >= q")) goto out; } /* let val2 = w = (s')^-1 mod q*/ if (mp_invmod(&val1, key->q, &val2) != MP_OKAY) { goto out; } /* u1 = ((SHA(M')w) mod q */ /* let val1 = SHA(M') = msghash */ bytes_to_mp(&val1, msghash, SHA1_HASH_SIZE); /* let val3 = u1 = ((SHA(M')w) mod q */ if (mp_mulmod(&val1, &val2, key->q, &val3) != MP_OKAY) { goto out; } /* u2 = ((r')w) mod q */ /* let val1 = r' */ bytes_to_mp(&val1, (const unsigned char*) &string[0], SHA1_HASH_SIZE); if (mp_cmp(&val1, key->q) != MP_LT) { TRACE(("verify failed, r' >= q")) goto out; } /* let val4 = u2 = ((r')w) mod q */ if (mp_mulmod(&val1, &val2, key->q, &val4) != MP_OKAY) { goto out; } /* v = (((g)^u1 (y)^u2) mod p) mod q */ /* val2 = g^u1 mod p */ if (mp_exptmod(key->g, &val3, key->p, &val2) != MP_OKAY) { goto out; } /* val3 = y^u2 mod p */ if (mp_exptmod(key->y, &val4, key->p, &val3) != MP_OKAY) { goto out; } /* val4 = ((g)^u1 (y)^u2) mod p */ if (mp_mulmod(&val2, &val3, key->p, &val4) != MP_OKAY) { goto out; } /* val2 = v = (((g)^u1 (y)^u2) mod p) mod q */ if (mp_mod(&val4, key->q, &val2) != MP_OKAY) { goto out; } /* check whether signatures verify */ if (mp_cmp(&val2, &val1) == MP_EQ) { /* good sig */ ret = DROPBEAR_SUCCESS; } out: mp_clear_multi(&val1, &val2, &val3, &val4, NULL); m_free(string); return ret; } #endif /* DROPBEAR_SIGNKEY_VERIFY */ /* Sign the data presented with key, writing the signature contents * to the buffer */ void buf_put_dss_sign(buffer* buf, dropbear_dss_key *key, buffer *data_buf) { unsigned char msghash[SHA1_HASH_SIZE]; unsigned int writelen; unsigned int i; DEF_MP_INT(dss_k); DEF_MP_INT(dss_m); DEF_MP_INT(dss_temp1); DEF_MP_INT(dss_temp2); DEF_MP_INT(dss_r); DEF_MP_INT(dss_s); hash_state hs; TRACE(("enter buf_put_dss_sign")) dropbear_assert(key != NULL); /* hash the data */ sha1_init(&hs); sha1_process(&hs, data_buf->data, data_buf->len); sha1_done(&hs, msghash); m_mp_init_multi(&dss_k, &dss_temp1, &dss_temp2, &dss_r, &dss_s, &dss_m, NULL); /* the random number generator's input has included the private key which * avoids DSS's problem of private key exposure due to low entropy */ gen_random_mpint(key->q, &dss_k); /* now generate the actual signature */ bytes_to_mp(&dss_m, msghash, SHA1_HASH_SIZE); /* g^k mod p */ if (mp_exptmod(key->g, &dss_k, key->p, &dss_temp1) != MP_OKAY) { dropbear_exit("DSS error"); } /* r = (g^k mod p) mod q */ if (mp_mod(&dss_temp1, key->q, &dss_r) != MP_OKAY) { dropbear_exit("DSS error"); } /* x*r mod q */ if (mp_mulmod(&dss_r, key->x, key->q, &dss_temp1) != MP_OKAY) { dropbear_exit("DSS error"); } /* (SHA1(M) + xr) mod q) */ if (mp_addmod(&dss_m, &dss_temp1, key->q, &dss_temp2) != MP_OKAY) { dropbear_exit("DSS error"); } /* (k^-1) mod q */ if (mp_invmod(&dss_k, key->q, &dss_temp1) != MP_OKAY) { dropbear_exit("DSS error"); } /* s = (k^-1(SHA1(M) + xr)) mod q */ if (mp_mulmod(&dss_temp1, &dss_temp2, key->q, &dss_s) != MP_OKAY) { dropbear_exit("DSS error"); } buf_putstring(buf, SSH_SIGNKEY_DSS, SSH_SIGNKEY_DSS_LEN); buf_putint(buf, 2*SHA1_HASH_SIZE); writelen = mp_unsigned_bin_size(&dss_r); dropbear_assert(writelen <= SHA1_HASH_SIZE); /* need to pad to 160 bits with leading zeros */ for (i = 0; i < SHA1_HASH_SIZE - writelen; i++) { buf_putbyte(buf, 0); } if (mp_to_unsigned_bin(&dss_r, buf_getwriteptr(buf, writelen)) != MP_OKAY) { dropbear_exit("DSS error"); } mp_clear(&dss_r); buf_incrwritepos(buf, writelen); writelen = mp_unsigned_bin_size(&dss_s); dropbear_assert(writelen <= SHA1_HASH_SIZE); /* need to pad to 160 bits with leading zeros */ for (i = 0; i < SHA1_HASH_SIZE - writelen; i++) { buf_putbyte(buf, 0); } if (mp_to_unsigned_bin(&dss_s, buf_getwriteptr(buf, writelen)) != MP_OKAY) { dropbear_exit("DSS error"); } mp_clear(&dss_s); buf_incrwritepos(buf, writelen); mp_clear_multi(&dss_k, &dss_temp1, &dss_temp2, &dss_r, &dss_s, &dss_m, NULL); /* create the signature to return */ TRACE(("leave buf_put_dss_sign")) } #endif /* DROPBEAR_DSS */