Mercurial > dropbear
view common-kex.c @ 447:278805938dcf
Patch from Nicolai Ehemann to try binding before going to the background,
so that if it exits early (because something's already listening etc)
then it will return an exitcode of 1.
author | Matt Johnston <matt@ucc.asn.au> |
---|---|
date | Thu, 19 Jul 2007 15:54:18 +0000 |
parents | b895f91c2ee6 |
children | 7e43f5e473b9 |
line wrap: on
line source
/* * Dropbear SSH * * Copyright (c) 2002-2004 Matt Johnston * Portions Copyright (c) 2004 by Mihnea Stoenescu * 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 "algo.h" #include "buffer.h" #include "session.h" #include "kex.h" #include "ssh.h" #include "packet.h" #include "bignum.h" #include "random.h" /* diffie-hellman-group1-sha1 value for p */ static const unsigned char dh_p_val[] = { 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xC9, 0x0F, 0xDA, 0xA2, 0x21, 0x68, 0xC2, 0x34, 0xC4, 0xC6, 0x62, 0x8B, 0x80, 0xDC, 0x1C, 0xD1, 0x29, 0x02, 0x4E, 0x08, 0x8A, 0x67, 0xCC, 0x74, 0x02, 0x0B, 0xBE, 0xA6, 0x3B, 0x13, 0x9B, 0x22, 0x51, 0x4A, 0x08, 0x79, 0x8E, 0x34, 0x04, 0xDD, 0xEF, 0x95, 0x19, 0xB3, 0xCD, 0x3A, 0x43, 0x1B, 0x30, 0x2B, 0x0A, 0x6D, 0xF2, 0x5F, 0x14, 0x37, 0x4F, 0xE1, 0x35, 0x6D, 0x6D, 0x51, 0xC2, 0x45, 0xE4, 0x85, 0xB5, 0x76, 0x62, 0x5E, 0x7E, 0xC6, 0xF4, 0x4C, 0x42, 0xE9, 0xA6, 0x37, 0xED, 0x6B, 0x0B, 0xFF, 0x5C, 0xB6, 0xF4, 0x06, 0xB7, 0xED, 0xEE, 0x38, 0x6B, 0xFB, 0x5A, 0x89, 0x9F, 0xA5, 0xAE, 0x9F, 0x24, 0x11, 0x7C, 0x4B, 0x1F, 0xE6, 0x49, 0x28, 0x66, 0x51, 0xEC, 0xE6, 0x53, 0x81, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF}; #define DH_P_LEN sizeof(dh_p_val) static const int DH_G_VAL = 2; static void kexinitialise(); void gen_new_keys(); #ifndef DISABLE_ZLIB static void gen_new_zstreams(); #endif static void read_kex_algos(); /* helper function for gen_new_keys */ static void hashkeys(unsigned char *out, int outlen, const hash_state * hs, unsigned const char X); /* Send our list of algorithms we can use */ void send_msg_kexinit() { CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_KEXINIT); /* cookie */ genrandom(buf_getwriteptr(ses.writepayload, 16), 16); buf_incrwritepos(ses.writepayload, 16); /* kex algos */ buf_put_algolist(ses.writepayload, sshkex); /* server_host_key_algorithms */ buf_put_algolist(ses.writepayload, sshhostkey); /* encryption_algorithms_client_to_server */ buf_put_algolist(ses.writepayload, sshciphers); /* encryption_algorithms_server_to_client */ buf_put_algolist(ses.writepayload, sshciphers); /* mac_algorithms_client_to_server */ buf_put_algolist(ses.writepayload, sshhashes); /* mac_algorithms_server_to_client */ buf_put_algolist(ses.writepayload, sshhashes); /* compression_algorithms_client_to_server */ buf_put_algolist(ses.writepayload, sshcompress); /* compression_algorithms_server_to_client */ buf_put_algolist(ses.writepayload, sshcompress); /* languages_client_to_server */ buf_putstring(ses.writepayload, "", 0); /* languages_server_to_client */ buf_putstring(ses.writepayload, "", 0); /* first_kex_packet_follows - unimplemented for now */ buf_putbyte(ses.writepayload, 0x00); /* reserved unit32 */ buf_putint(ses.writepayload, 0); /* set up transmitted kex packet buffer for hashing. * This is freed after the end of the kex */ ses.transkexinit = buf_newcopy(ses.writepayload); encrypt_packet(); ses.dataallowed = 0; /* don't send other packets during kex */ TRACE(("DATAALLOWED=0")) TRACE(("-> KEXINIT")) ses.kexstate.sentkexinit = 1; } /* *** NOTE regarding (send|recv)_msg_newkeys *** * Changed by mihnea from the original kex.c to set dataallowed after a * completed key exchange, no matter the order in which it was performed. * This enables client mode without affecting server functionality. */ /* Bring new keys into use after a key exchange, and let the client know*/ void send_msg_newkeys() { TRACE(("enter send_msg_newkeys")) /* generate the kexinit request */ CHECKCLEARTOWRITE(); buf_putbyte(ses.writepayload, SSH_MSG_NEWKEYS); encrypt_packet(); /* set up our state */ if (ses.kexstate.recvnewkeys) { TRACE(("while RECVNEWKEYS=1")) gen_new_keys(); kexinitialise(); /* we've finished with this kex */ TRACE((" -> DATAALLOWED=1")) ses.dataallowed = 1; /* we can send other packets again now */ ses.kexstate.donefirstkex = 1; } else { ses.kexstate.sentnewkeys = 1; TRACE(("SENTNEWKEYS=1")) } TRACE(("-> MSG_NEWKEYS")) TRACE(("leave send_msg_newkeys")) } /* Bring the new keys into use after a key exchange */ void recv_msg_newkeys() { TRACE(("<- MSG_NEWKEYS")) TRACE(("enter recv_msg_newkeys")) /* simply check if we've sent SSH_MSG_NEWKEYS, and if so, * switch to the new keys */ if (ses.kexstate.sentnewkeys) { TRACE(("while SENTNEWKEYS=1")) gen_new_keys(); kexinitialise(); /* we've finished with this kex */ TRACE((" -> DATAALLOWED=1")) ses.dataallowed = 1; /* we can send other packets again now */ ses.kexstate.donefirstkex = 1; } else { TRACE(("RECVNEWKEYS=1")) ses.kexstate.recvnewkeys = 1; } TRACE(("leave recv_msg_newkeys")) } /* Set up the kex for the first time */ void kexfirstinitialise() { ses.kexstate.donefirstkex = 0; kexinitialise(); } /* Reset the kex state, ready for a new negotiation */ static void kexinitialise() { struct timeval tv; TRACE(("kexinitialise()")) /* sent/recv'd MSG_KEXINIT */ ses.kexstate.sentkexinit = 0; ses.kexstate.recvkexinit = 0; /* sent/recv'd MSG_NEWKEYS */ ses.kexstate.recvnewkeys = 0; ses.kexstate.sentnewkeys = 0; /* first_packet_follows */ ses.kexstate.firstfollows = 0; ses.kexstate.datatrans = 0; ses.kexstate.datarecv = 0; if (gettimeofday(&tv, 0) < 0) { dropbear_exit("Error getting time"); } ses.kexstate.lastkextime = tv.tv_sec; } /* Helper function for gen_new_keys, creates a hash. It makes a copy of the * already initialised hash_state hs, which should already have processed * the dh_K and hash, since these are common. X is the letter 'A', 'B' etc. * out must have at least min(SHA1_HASH_SIZE, outlen) bytes allocated. * The output will only be expanded once, as we are assured that * outlen <= 2*SHA1_HASH_SIZE for all known hashes. * * See Section 7.2 of rfc4253 (ssh transport) for details */ static void hashkeys(unsigned char *out, int outlen, const hash_state * hs, const unsigned char X) { hash_state hs2; unsigned char k2[SHA1_HASH_SIZE]; /* used to extending */ memcpy(&hs2, hs, sizeof(hash_state)); sha1_process(&hs2, &X, 1); sha1_process(&hs2, ses.session_id, SHA1_HASH_SIZE); sha1_done(&hs2, out); if (SHA1_HASH_SIZE < outlen) { /* need to extend */ memcpy(&hs2, hs, sizeof(hash_state)); sha1_process(&hs2, out, SHA1_HASH_SIZE); sha1_done(&hs2, k2); memcpy(&out[SHA1_HASH_SIZE], k2, outlen - SHA1_HASH_SIZE); } } /* Generate the actual encryption/integrity keys, using the results of the * key exchange, as specified in section 5.2 of the IETF secsh-transport * draft. This occurs after the DH key-exchange. * * ses.newkeys is the new set of keys which are generated, these are only * taken into use after both sides have sent a newkeys message */ /* Originally from kex.c, generalized for cli/svr mode --mihnea */ void gen_new_keys() { unsigned char C2S_IV[MAX_IV_LEN]; unsigned char C2S_key[MAX_KEY_LEN]; unsigned char S2C_IV[MAX_IV_LEN]; unsigned char S2C_key[MAX_KEY_LEN]; /* unsigned char key[MAX_KEY_LEN]; */ unsigned char *trans_IV, *trans_key, *recv_IV, *recv_key; hash_state hs; unsigned int C2S_keysize, S2C_keysize; char mactransletter, macrecvletter; /* Client or server specific */ int recv_cipher = 0, trans_cipher = 0; TRACE(("enter gen_new_keys")) /* the dh_K and hash are the start of all hashes, we make use of that */ sha1_init(&hs); sha1_process_mp(&hs, ses.dh_K); mp_clear(ses.dh_K); m_free(ses.dh_K); sha1_process(&hs, ses.hash, SHA1_HASH_SIZE); m_burn(ses.hash, SHA1_HASH_SIZE); if (IS_DROPBEAR_CLIENT) { trans_IV = C2S_IV; recv_IV = S2C_IV; trans_key = C2S_key; recv_key = S2C_key; C2S_keysize = ses.newkeys->trans_algo_crypt->keysize; S2C_keysize = ses.newkeys->recv_algo_crypt->keysize; mactransletter = 'E'; macrecvletter = 'F'; } else { trans_IV = S2C_IV; recv_IV = C2S_IV; trans_key = S2C_key; recv_key = C2S_key; C2S_keysize = ses.newkeys->recv_algo_crypt->keysize; S2C_keysize = ses.newkeys->trans_algo_crypt->keysize; mactransletter = 'F'; macrecvletter = 'E'; } hashkeys(C2S_IV, SHA1_HASH_SIZE, &hs, 'A'); hashkeys(S2C_IV, SHA1_HASH_SIZE, &hs, 'B'); hashkeys(C2S_key, C2S_keysize, &hs, 'C'); hashkeys(S2C_key, S2C_keysize, &hs, 'D'); recv_cipher = find_cipher(ses.newkeys->recv_algo_crypt->cipherdesc->name); if (recv_cipher < 0) dropbear_exit("crypto error"); if (cbc_start(recv_cipher, recv_IV, recv_key, ses.newkeys->recv_algo_crypt->keysize, 0, &ses.newkeys->recv_symmetric_struct) != CRYPT_OK) { dropbear_exit("crypto error"); } trans_cipher = find_cipher(ses.newkeys->trans_algo_crypt->cipherdesc->name); if (trans_cipher < 0) dropbear_exit("crypto error"); if (cbc_start(trans_cipher, trans_IV, trans_key, ses.newkeys->trans_algo_crypt->keysize, 0, &ses.newkeys->trans_symmetric_struct) != CRYPT_OK) { dropbear_exit("crypto error"); } /* MAC keys */ hashkeys(ses.newkeys->transmackey, ses.newkeys->trans_algo_mac->keysize, &hs, mactransletter); hashkeys(ses.newkeys->recvmackey, ses.newkeys->recv_algo_mac->keysize, &hs, macrecvletter); #ifndef DISABLE_ZLIB gen_new_zstreams(); #endif /* Switch over to the new keys */ m_burn(ses.keys, sizeof(struct key_context)); m_free(ses.keys); ses.keys = ses.newkeys; ses.newkeys = NULL; TRACE(("leave gen_new_keys")) } #ifndef DISABLE_ZLIB /* Set up new zlib compression streams, close the old ones. Only * called from gen_new_keys() */ static void gen_new_zstreams() { /* create new zstreams */ if (ses.newkeys->recv_algo_comp == DROPBEAR_COMP_ZLIB) { ses.newkeys->recv_zstream = (z_streamp)m_malloc(sizeof(z_stream)); ses.newkeys->recv_zstream->zalloc = Z_NULL; ses.newkeys->recv_zstream->zfree = Z_NULL; if (inflateInit(ses.newkeys->recv_zstream) != Z_OK) { dropbear_exit("zlib error"); } } else { ses.newkeys->recv_zstream = NULL; } if (ses.newkeys->trans_algo_comp == DROPBEAR_COMP_ZLIB) { ses.newkeys->trans_zstream = (z_streamp)m_malloc(sizeof(z_stream)); ses.newkeys->trans_zstream->zalloc = Z_NULL; ses.newkeys->trans_zstream->zfree = Z_NULL; if (deflateInit(ses.newkeys->trans_zstream, Z_DEFAULT_COMPRESSION) != Z_OK) { dropbear_exit("zlib error"); } } else { ses.newkeys->trans_zstream = NULL; } /* clean up old keys */ if (ses.keys->recv_zstream != NULL) { if (inflateEnd(ses.keys->recv_zstream) == Z_STREAM_ERROR) { /* Z_DATA_ERROR is ok, just means that stream isn't ended */ dropbear_exit("crypto error"); } m_free(ses.keys->recv_zstream); } if (ses.keys->trans_zstream != NULL) { if (deflateEnd(ses.keys->trans_zstream) == Z_STREAM_ERROR) { /* Z_DATA_ERROR is ok, just means that stream isn't ended */ dropbear_exit("crypto error"); } m_free(ses.keys->trans_zstream); } } #endif /* Executed upon receiving a kexinit message from the client to initiate * key exchange. If we haven't already done so, we send the list of our * preferred algorithms. The client's requested algorithms are processed, * and we calculate the first portion of the key-exchange-hash for used * later in the key exchange. No response is sent, as the client should * initiate the diffie-hellman key exchange */ /* Originally from kex.c, generalized for cli/svr mode --mihnea */ /* Belongs in common_kex.c where it should be moved after review */ void recv_msg_kexinit() { unsigned int kexhashbuf_len = 0; unsigned int remote_ident_len = 0; unsigned int local_ident_len = 0; TRACE(("<- KEXINIT")) TRACE(("enter recv_msg_kexinit")) if (!ses.kexstate.sentkexinit) { /* we need to send a kex packet */ send_msg_kexinit(); TRACE(("continue recv_msg_kexinit: sent kexinit")) } /* start the kex hash */ local_ident_len = strlen(LOCAL_IDENT); remote_ident_len = strlen((char*)ses.remoteident); kexhashbuf_len = local_ident_len + remote_ident_len + ses.transkexinit->len + ses.payload->len + KEXHASHBUF_MAX_INTS; ses.kexhashbuf = buf_new(kexhashbuf_len); if (IS_DROPBEAR_CLIENT) { /* read the peer's choice of algos */ read_kex_algos(); /* V_C, the client's version string (CR and NL excluded) */ buf_putstring(ses.kexhashbuf, (unsigned char*)LOCAL_IDENT, local_ident_len); /* V_S, the server's version string (CR and NL excluded) */ buf_putstring(ses.kexhashbuf, ses.remoteident, remote_ident_len); /* I_C, the payload of the client's SSH_MSG_KEXINIT */ buf_putstring(ses.kexhashbuf, ses.transkexinit->data, ses.transkexinit->len); /* I_S, the payload of the server's SSH_MSG_KEXINIT */ buf_setpos(ses.payload, 0); buf_putstring(ses.kexhashbuf, ses.payload->data, ses.payload->len); } else { /* SERVER */ /* read the peer's choice of algos */ read_kex_algos(); /* V_C, the client's version string (CR and NL excluded) */ buf_putstring(ses.kexhashbuf, ses.remoteident, remote_ident_len); /* V_S, the server's version string (CR and NL excluded) */ buf_putstring(ses.kexhashbuf, (unsigned char*)LOCAL_IDENT, local_ident_len); /* I_C, the payload of the client's SSH_MSG_KEXINIT */ buf_setpos(ses.payload, 0); buf_putstring(ses.kexhashbuf, ses.payload->data, ses.payload->len); /* I_S, the payload of the server's SSH_MSG_KEXINIT */ buf_putstring(ses.kexhashbuf, ses.transkexinit->data, ses.transkexinit->len); ses.requirenext = SSH_MSG_KEXDH_INIT; } buf_free(ses.transkexinit); ses.transkexinit = NULL; /* the rest of ses.kexhashbuf will be done after DH exchange */ ses.kexstate.recvkexinit = 1; TRACE(("leave recv_msg_kexinit")) } /* Initialises and generate one side of the diffie-hellman key exchange values. * See the ietf-secsh-transport draft, section 6, for details */ /* dh_pub and dh_priv MUST be already initialised */ void gen_kexdh_vals(mp_int *dh_pub, mp_int *dh_priv) { DEF_MP_INT(dh_p); DEF_MP_INT(dh_q); DEF_MP_INT(dh_g); TRACE(("enter send_msg_kexdh_reply")) m_mp_init_multi(&dh_g, &dh_p, &dh_q, NULL); /* read the prime and generator*/ bytes_to_mp(&dh_p, (unsigned char*)dh_p_val, DH_P_LEN); if (mp_set_int(&dh_g, DH_G_VAL) != MP_OKAY) { dropbear_exit("Diffie-Hellman error"); } /* calculate q = (p-1)/2 */ /* dh_priv is just a temp var here */ if (mp_sub_d(&dh_p, 1, dh_priv) != MP_OKAY) { dropbear_exit("Diffie-Hellman error"); } if (mp_div_2(dh_priv, &dh_q) != MP_OKAY) { dropbear_exit("Diffie-Hellman error"); } /* Generate a private portion 0 < dh_priv < dh_q */ gen_random_mpint(&dh_q, dh_priv); /* f = g^y mod p */ if (mp_exptmod(&dh_g, dh_priv, &dh_p, dh_pub) != MP_OKAY) { dropbear_exit("Diffie-Hellman error"); } mp_clear_multi(&dh_g, &dh_p, &dh_q, NULL); } /* This function is fairly common between client/server, with some substitution * of dh_e/dh_f etc. Hence these arguments: * dh_pub_us is 'e' for the client, 'f' for the server. dh_pub_them is * vice-versa. dh_priv is the x/y value corresponding to dh_pub_us */ void kexdh_comb_key(mp_int *dh_pub_us, mp_int *dh_priv, mp_int *dh_pub_them, sign_key *hostkey) { mp_int dh_p; mp_int *dh_e = NULL, *dh_f = NULL; hash_state hs; /* read the prime and generator*/ m_mp_init(&dh_p); bytes_to_mp(&dh_p, dh_p_val, DH_P_LEN); /* Check that dh_pub_them (dh_e or dh_f) is in the range [1, p-1] */ if (mp_cmp(dh_pub_them, &dh_p) != MP_LT || mp_cmp_d(dh_pub_them, 0) != MP_GT) { dropbear_exit("Diffie-Hellman error"); } /* K = e^y mod p = f^x mod p */ ses.dh_K = (mp_int*)m_malloc(sizeof(mp_int)); m_mp_init(ses.dh_K); if (mp_exptmod(dh_pub_them, dh_priv, &dh_p, ses.dh_K) != MP_OKAY) { dropbear_exit("Diffie-Hellman error"); } /* clear no longer needed vars */ mp_clear_multi(&dh_p, NULL); /* From here on, the code needs to work with the _same_ vars on each side, * not vice-versaing for client/server */ if (IS_DROPBEAR_CLIENT) { dh_e = dh_pub_us; dh_f = dh_pub_them; } else { dh_e = dh_pub_them; dh_f = dh_pub_us; } /* Create the remainder of the hash buffer, to generate the exchange hash */ /* K_S, the host key */ buf_put_pub_key(ses.kexhashbuf, hostkey, ses.newkeys->algo_hostkey); /* e, exchange value sent by the client */ buf_putmpint(ses.kexhashbuf, dh_e); /* f, exchange value sent by the server */ buf_putmpint(ses.kexhashbuf, dh_f); /* K, the shared secret */ buf_putmpint(ses.kexhashbuf, ses.dh_K); /* calculate the hash H to sign */ sha1_init(&hs); buf_setpos(ses.kexhashbuf, 0); sha1_process(&hs, buf_getptr(ses.kexhashbuf, ses.kexhashbuf->len), ses.kexhashbuf->len); sha1_done(&hs, ses.hash); buf_burn(ses.kexhashbuf); buf_free(ses.kexhashbuf); ses.kexhashbuf = NULL; /* first time around, we set the session_id to H */ if (ses.session_id == NULL) { /* create the session_id, this never needs freeing */ ses.session_id = (unsigned char*)m_malloc(SHA1_HASH_SIZE); memcpy(ses.session_id, ses.hash, SHA1_HASH_SIZE); } } /* read the other side's algo list. buf_match_algo is a callback to match * algos for the client or server. */ static void read_kex_algos() { /* for asymmetry */ algo_type * c2s_hash_algo = NULL; algo_type * s2c_hash_algo = NULL; algo_type * c2s_cipher_algo = NULL; algo_type * s2c_cipher_algo = NULL; algo_type * c2s_comp_algo = NULL; algo_type * s2c_comp_algo = NULL; /* the generic one */ algo_type * algo = NULL; /* which algo couldn't match */ char * erralgo = NULL; int goodguess = 0; int allgood = 1; /* we AND this with each goodguess and see if its still true after */ buf_incrpos(ses.payload, 16); /* start after the cookie */ ses.newkeys = (struct key_context*)m_malloc(sizeof(struct key_context)); /* kex_algorithms */ algo = ses.buf_match_algo(ses.payload, sshkex, &goodguess); allgood &= goodguess; if (algo == NULL) { erralgo = "kex"; goto error; } TRACE(("kex algo %s", algo->name)) ses.newkeys->algo_kex = algo->val; /* server_host_key_algorithms */ algo = ses.buf_match_algo(ses.payload, sshhostkey, &goodguess); allgood &= goodguess; if (algo == NULL) { erralgo = "hostkey"; goto error; } TRACE(("hostkey algo %s", algo->name)) ses.newkeys->algo_hostkey = algo->val; /* encryption_algorithms_client_to_server */ c2s_cipher_algo = ses.buf_match_algo(ses.payload, sshciphers, &goodguess); if (c2s_cipher_algo == NULL) { erralgo = "enc c->s"; goto error; } TRACE(("enc c2s is %s", c2s_cipher_algo->name)) /* encryption_algorithms_server_to_client */ s2c_cipher_algo = ses.buf_match_algo(ses.payload, sshciphers, &goodguess); if (s2c_cipher_algo == NULL) { erralgo = "enc s->c"; goto error; } TRACE(("enc s2c is %s", s2c_cipher_algo->name)) /* mac_algorithms_client_to_server */ c2s_hash_algo = ses.buf_match_algo(ses.payload, sshhashes, &goodguess); if (c2s_hash_algo == NULL) { erralgo = "mac c->s"; goto error; } TRACE(("hash c2s is %s", c2s_hash_algo->name)) /* mac_algorithms_server_to_client */ s2c_hash_algo = ses.buf_match_algo(ses.payload, sshhashes, &goodguess); if (s2c_hash_algo == NULL) { erralgo = "mac s->c"; goto error; } TRACE(("hash s2c is %s", s2c_hash_algo->name)) /* compression_algorithms_client_to_server */ c2s_comp_algo = ses.buf_match_algo(ses.payload, sshcompress, &goodguess); if (c2s_comp_algo == NULL) { erralgo = "comp c->s"; goto error; } TRACE(("hash c2s is %s", c2s_comp_algo->name)) /* compression_algorithms_server_to_client */ s2c_comp_algo = ses.buf_match_algo(ses.payload, sshcompress, &goodguess); if (s2c_comp_algo == NULL) { erralgo = "comp s->c"; goto error; } TRACE(("hash s2c is %s", s2c_comp_algo->name)) /* languages_client_to_server */ buf_eatstring(ses.payload); /* languages_server_to_client */ buf_eatstring(ses.payload); /* first_kex_packet_follows */ if (buf_getbool(ses.payload)) { ses.kexstate.firstfollows = 1; /* if the guess wasn't good, we ignore the packet sent */ if (!allgood) { ses.ignorenext = 1; } } /* Handle the asymmetry */ if (IS_DROPBEAR_CLIENT) { ses.newkeys->recv_algo_crypt = (struct dropbear_cipher*)s2c_cipher_algo->data; ses.newkeys->trans_algo_crypt = (struct dropbear_cipher*)c2s_cipher_algo->data; ses.newkeys->recv_algo_mac = (struct dropbear_hash*)s2c_hash_algo->data; ses.newkeys->trans_algo_mac = (struct dropbear_hash*)c2s_hash_algo->data; ses.newkeys->recv_algo_comp = s2c_comp_algo->val; ses.newkeys->trans_algo_comp = c2s_comp_algo->val; } else { /* SERVER */ ses.newkeys->recv_algo_crypt = (struct dropbear_cipher*)c2s_cipher_algo->data; ses.newkeys->trans_algo_crypt = (struct dropbear_cipher*)s2c_cipher_algo->data; ses.newkeys->recv_algo_mac = (struct dropbear_hash*)c2s_hash_algo->data; ses.newkeys->trans_algo_mac = (struct dropbear_hash*)s2c_hash_algo->data; ses.newkeys->recv_algo_comp = c2s_comp_algo->val; ses.newkeys->trans_algo_comp = s2c_comp_algo->val; } /* reserved for future extensions */ buf_getint(ses.payload); return; error: dropbear_exit("no matching algo %s", erralgo); }