/* $OpenBSD: ike_auth.c,v 1.104 2005/07/14 12:50:08 moritz Exp $ */ /* $EOM: ike_auth.c,v 1.59 2000/11/21 00:21:31 angelos Exp $ */ /* * Copyright (c) 1998, 1999, 2000, 2001 Niklas Hallqvist. All rights reserved. * Copyright (c) 1999 Niels Provos. All rights reserved. * Copyright (c) 1999 Angelos D. Keromytis. All rights reserved. * Copyright (c) 2000, 2001, 2003 Håkan Olsson. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * This code was written under funding by Ericsson Radio Systems. */ #include #include #include #include #include #include #include #include #include #include #include #include #include "cert.h" #include "conf.h" #include "constants.h" #if defined (USE_DNSSEC) #include "dnssec.h" #endif #include "exchange.h" #include "hash.h" #include "ike_auth.h" #include "ipsec.h" #include "ipsec_doi.h" #include "libcrypto.h" #include "log.h" #include "message.h" #include "monitor.h" #include "prf.h" #include "transport.h" #include "util.h" #include "key.h" #include "x509.h" #ifdef notyet static u_int8_t *enc_gen_skeyid(struct exchange *, size_t *); #endif static u_int8_t *pre_shared_gen_skeyid(struct exchange *, size_t *); static int pre_shared_decode_hash(struct message *); static int pre_shared_encode_hash(struct message *); static u_int8_t *sig_gen_skeyid(struct exchange *, size_t *); static int rsa_sig_decode_hash(struct message *); static int rsa_sig_encode_hash(struct message *); static int get_raw_key_from_file(int, u_int8_t *, size_t, RSA **); static int ike_auth_hash(struct exchange *, u_int8_t *); static struct ike_auth ike_auth[] = { { IKE_AUTH_PRE_SHARED, pre_shared_gen_skeyid, pre_shared_decode_hash, pre_shared_encode_hash }, #ifdef notdef { IKE_AUTH_DSS, sig_gen_skeyid, pre_shared_decode_hash, pre_shared_encode_hash }, #endif { IKE_AUTH_RSA_SIG, sig_gen_skeyid, rsa_sig_decode_hash, rsa_sig_encode_hash }, #ifdef notdef { IKE_AUTH_RSA_ENC, enc_gen_skeyid, pre_shared_decode_hash, pre_shared_encode_hash }, { IKE_AUTH_RSA_ENC_REV, enc_gen_skeyid, pre_shared_decode_hash, pre_shared_encode_hash }, #endif }; struct ike_auth * ike_auth_get(u_int16_t id) { size_t i; for (i = 0; i < sizeof ike_auth / sizeof ike_auth[0]; i++) if (id == ike_auth[i].id) return &ike_auth[i]; return 0; } /* * Find and decode the configured key (pre-shared or public) for the * peer denoted by ID. Stash the len in KEYLEN. */ static void * ike_auth_get_key(int type, char *id, char *local_id, size_t *keylen) { char *key, *buf; int fd; char *keyfile; FILE *keyfp; RSA *rsakey; size_t fsize; switch (type) { case IKE_AUTH_PRE_SHARED: /* Get the pre-shared key for our peer. */ key = conf_get_str(id, "Authentication"); if (!key && local_id) key = conf_get_str(local_id, "Authentication"); if (!key) { log_print("ike_auth_get_key: " "no key found for peer \"%s\" or local ID \"%s\"", id, local_id ? local_id : ""); return 0; } /* If the key starts with 0x it is in hex format. */ if (strncasecmp(key, "0x", 2) == 0) { *keylen = (strlen(key) - 1) / 2; buf = malloc(*keylen); if (!buf) { log_error("ike_auth_get_key: malloc (%lu) " "failed", (unsigned long)*keylen); return 0; } if (hex2raw(key + 2, (unsigned char *)buf, *keylen)) { free(buf); log_print("ike_auth_get_key: invalid hex key " "%s", key); return 0; } key = buf; } else { buf = key; key = strdup(buf); if (!key) { log_error("ike_auth_get_key: strdup() failed"); return 0; } *keylen = strlen(key); } break; case IKE_AUTH_RSA_SIG: if (local_id && (keyfile = conf_get_str("KeyNote", "Credential-directory")) != 0) { struct stat sb; struct keynote_deckey dc; char *privkeyfile, *buf2; int pkflen; size_t size; pkflen = strlen(keyfile) + strlen(local_id) + sizeof PRIVATE_KEY_FILE + sizeof "//" - 1; privkeyfile = calloc(pkflen, sizeof(char)); if (!privkeyfile) { log_print("ike_auth_get_key: failed to " "allocate %d bytes", pkflen); return 0; } snprintf(privkeyfile, pkflen, "%s/%s/%s", keyfile, local_id, PRIVATE_KEY_FILE); keyfile = privkeyfile; fd = monitor_open(keyfile, O_RDONLY, 0); if (fd < 0) { free(keyfile); goto ignorekeynote; } if (fstat(fd, &sb) < 0) { log_print("ike_auth_get_key: fstat failed"); free(keyfile); close(fd); return 0; } size = (size_t)sb.st_size; buf = calloc(size + 1, sizeof(char)); if (!buf) { log_print("ike_auth_get_key: failed allocating" " %lu bytes", (unsigned long)size + 1); free(keyfile); close(fd); return 0; } if (read(fd, buf, size) != (ssize_t)size) { free(buf); log_print("ike_auth_get_key: " "failed reading %lu bytes from \"%s\"", (unsigned long)size, keyfile); free(keyfile); close(fd); return 0; } close(fd); /* Parse private key string */ buf2 = kn_get_string(buf); free(buf); if (!buf2 || kn_decode_key(&dc, buf2, KEYNOTE_PRIVATE_KEY) == -1) { if (buf2) free(buf2); log_print("ike_auth_get_key: failed decoding " "key in \"%s\"", keyfile); free(keyfile); return 0; } free(buf2); if (dc.dec_algorithm != KEYNOTE_ALGORITHM_RSA) { log_print("ike_auth_get_key: wrong algorithm " "type %d in \"%s\"", dc.dec_algorithm, keyfile); free(keyfile); kn_free_key(&dc); return 0; } free(keyfile); return dc.dec_key; } ignorekeynote: /* Otherwise, try X.509 */ keyfile = conf_get_str("X509-certificates", "Private-key"); fd = monitor_open(keyfile, O_RDONLY, 0); if (fd < 0) { log_print("ike_auth_get_key: failed opening \"%s\"", keyfile); return 0; } if (check_file_secrecy_fd(fd, keyfile, &fsize) < 0) { close(fd); return 0; } if ((keyfp = fdopen(fd, "r")) == NULL) { log_print("ike_auth_get_key: fdopen failed"); close(fd); return 0; } #if SSLEAY_VERSION_NUMBER >= 0x00904100L rsakey = PEM_read_RSAPrivateKey(keyfp, NULL, NULL, NULL); #else rsakey = PEM_read_RSAPrivateKey(keyfp, NULL, NULL); #endif fclose(keyfp); if (!rsakey) { log_print("ike_auth_get_key: " "PEM_read_bio_RSAPrivateKey failed"); return 0; } return rsakey; default: log_print("ike_auth_get_key: unknown key type %d", type); return 0; } return key; } static u_int8_t * pre_shared_gen_skeyid(struct exchange *exchange, size_t *sz) { struct prf *prf; struct ipsec_exch *ie = exchange->data; u_int8_t *skeyid, *buf = 0; unsigned char *key; size_t keylen; /* * If we're the responder and have the initiator's ID (which is the * case in Aggressive mode), try to find the preshared key in the * section of the initiator's Phase 1 ID. This allows us to do * mobile user support with preshared keys. */ if (!exchange->initiator && exchange->id_i) { switch (exchange->id_i[0]) { case IPSEC_ID_IPV4_ADDR: case IPSEC_ID_IPV6_ADDR: util_ntoa((char **) &buf, exchange->id_i[0] == IPSEC_ID_IPV4_ADDR ? AF_INET : AF_INET6, exchange->id_i + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ); if (!buf) return 0; break; case IPSEC_ID_FQDN: case IPSEC_ID_USER_FQDN: buf = calloc(exchange->id_i_len - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1, sizeof(char)); if (!buf) { log_print("pre_shared_gen_skeyid: malloc (%lu" ") failed", (unsigned long)exchange->id_i_len - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1); return 0; } memcpy(buf, exchange->id_i + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, exchange->id_i_len - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ); break; /* XXX Support more ID types ? */ default: break; } } /* * Get the pre-shared key for our peer. This will work even if the key * has been passed to us through a mechanism like PFKEYv2. */ key = ike_auth_get_key(IKE_AUTH_PRE_SHARED, exchange->name, (char *)buf, &keylen); if (buf) free(buf); /* Fail if no key could be found. */ if (!key) return 0; /* Store the secret key for later policy processing. */ exchange->recv_key = calloc(keylen + 1, sizeof(char)); exchange->recv_keytype = ISAKMP_KEY_PASSPHRASE; if (!exchange->recv_key) { log_error("pre_shared_gen_skeyid: malloc (%lu) failed", (unsigned long)keylen); free(key); return 0; } memcpy(exchange->recv_key, key, keylen); exchange->recv_certtype = ISAKMP_CERTENC_NONE; free(key); prf = prf_alloc(ie->prf_type, ie->hash->type, exchange->recv_key, keylen); if (!prf) return 0; *sz = prf->blocksize; skeyid = malloc(*sz); if (!skeyid) { log_error("pre_shared_gen_skeyid: malloc (%lu) failed", (unsigned long)*sz); prf_free(prf); return 0; } prf->Init(prf->prfctx); prf->Update(prf->prfctx, exchange->nonce_i, exchange->nonce_i_len); prf->Update(prf->prfctx, exchange->nonce_r, exchange->nonce_r_len); prf->Final(skeyid, prf->prfctx); prf_free(prf); return skeyid; } /* Both DSS & RSA signature authentication use this algorithm. */ static u_int8_t * sig_gen_skeyid(struct exchange *exchange, size_t *sz) { struct prf *prf; struct ipsec_exch *ie = exchange->data; u_int8_t *skeyid; unsigned char *key; key = malloc(exchange->nonce_i_len + exchange->nonce_r_len); if (!key) return 0; memcpy(key, exchange->nonce_i, exchange->nonce_i_len); memcpy(key + exchange->nonce_i_len, exchange->nonce_r, exchange->nonce_r_len); LOG_DBG((LOG_NEGOTIATION, 80, "sig_gen_skeyid: PRF type %d, hash %d", ie->prf_type, ie->hash->type)); LOG_DBG_BUF((LOG_NEGOTIATION, 80, "sig_gen_skeyid: SKEYID initialized with", (u_int8_t *)key, exchange->nonce_i_len + exchange->nonce_r_len)); prf = prf_alloc(ie->prf_type, ie->hash->type, key, exchange->nonce_i_len + exchange->nonce_r_len); free(key); if (!prf) return 0; *sz = prf->blocksize; skeyid = malloc(*sz); if (!skeyid) { log_error("sig_gen_skeyid: malloc (%lu) failed", (unsigned long)*sz); prf_free(prf); return 0; } LOG_DBG((LOG_NEGOTIATION, 80, "sig_gen_skeyid: g^xy length %lu", (unsigned long)ie->g_x_len)); LOG_DBG_BUF((LOG_NEGOTIATION, 80, "sig_gen_skeyid: SKEYID fed with g^xy", ie->g_xy, ie->g_x_len)); prf->Init(prf->prfctx); prf->Update(prf->prfctx, ie->g_xy, ie->g_x_len); prf->Final(skeyid, prf->prfctx); prf_free(prf); return skeyid; } #ifdef notdef /* * Both standard and revised RSA encryption authentication use this SKEYID * computation. */ static u_int8_t * enc_gen_skeyid(struct exchange *exchange, size_t *sz) { struct prf *prf; struct ipsec_exch *ie = exchange->data; struct hash *hash = ie->hash; u_int8_t *skeyid; hash->Init(hash->ctx); hash->Update(hash->ctx, exchange->nonce_i, exchange->nonce_i_len); hash->Update(hash->ctx, exchange->nonce_r, exchange->nonce_r_len); hash->Final(hash->digest, hash->ctx); prf = prf_alloc(ie->prf_type, hash->type, hash->digest, *sz); if (!prf) return 0; *sz = prf->blocksize; skeyid = malloc(*sz); if (!skeyid) { log_error("enc_gen_skeyid: malloc (%d) failed", *sz); prf_free(prf); return 0; } prf->Init(prf->prfctx); prf->Update(prf->prfctx, exchange->cookies, ISAKMP_HDR_COOKIES_LEN); prf->Final(skeyid, prf->prfctx); prf_free(prf); return skeyid; } #endif /* notdef */ static int pre_shared_decode_hash(struct message *msg) { struct exchange *exchange = msg->exchange; struct ipsec_exch *ie = exchange->data; struct payload *payload; size_t hashsize = ie->hash->hashsize; char header[80]; int initiator = exchange->initiator; u_int8_t **hash_p; /* Choose the right fields to fill-in. */ hash_p = initiator ? &ie->hash_r : &ie->hash_i; payload = payload_first(msg, ISAKMP_PAYLOAD_HASH); if (!payload) { log_print("pre_shared_decode_hash: no HASH payload found"); return -1; } /* Check that the hash is of the correct size. */ if (GET_ISAKMP_GEN_LENGTH(payload->p) - ISAKMP_GEN_SZ != hashsize) return -1; /* XXX Need this hash be in the SA? */ *hash_p = malloc(hashsize); if (!*hash_p) { log_error("pre_shared_decode_hash: malloc (%lu) failed", (unsigned long)hashsize); return -1; } memcpy(*hash_p, payload->p + ISAKMP_HASH_DATA_OFF, hashsize); snprintf(header, sizeof header, "pre_shared_decode_hash: HASH_%c", initiator ? 'R' : 'I'); LOG_DBG_BUF((LOG_MISC, 80, header, *hash_p, hashsize)); payload->flags |= PL_MARK; return 0; } /* Decrypt the HASH in SIG, we already need a parsed ID payload. */ static int rsa_sig_decode_hash(struct message *msg) { struct cert_handler *handler; struct exchange *exchange = msg->exchange; struct ipsec_exch *ie = exchange->data; struct payload *p; void *cert = 0; u_int8_t *rawcert = 0, **hash_p, **id_cert, *id; u_int32_t rawcertlen, *id_cert_len; RSA *key = 0; size_t hashsize = ie->hash->hashsize, id_len; char header[80]; int len, initiator = exchange->initiator; int found = 0, n, i, id_found; #if defined (USE_DNSSEC) u_int8_t *rawkey = 0; u_int32_t rawkeylen; #endif /* Choose the right fields to fill-in. */ hash_p = initiator ? &ie->hash_r : &ie->hash_i; id = initiator ? exchange->id_r : exchange->id_i; id_len = initiator ? exchange->id_r_len : exchange->id_i_len; if (!id || id_len == 0) { log_print("rsa_sig_decode_hash: ID is missing"); return -1; } /* * XXX Assume we should use the same kind of certification as the * remote... moreover, just use the first CERT payload to decide what * to use. */ p = payload_first(msg, ISAKMP_PAYLOAD_CERT); if (!p) handler = cert_get(ISAKMP_CERTENC_KEYNOTE); else handler = cert_get(GET_ISAKMP_CERT_ENCODING(p->p)); if (!handler) { log_print("rsa_sig_decode_hash: cert_get (%d) failed", p ? GET_ISAKMP_CERT_ENCODING(p->p) : -1); return -1; } /* * We need the policy session initialized now, so we can add * credentials etc. */ exchange->policy_id = kn_init(); if (exchange->policy_id == -1) { log_print("rsa_sig_decode_hash: failed to initialize policy " "session"); return -1; } /* Obtain a certificate from our certificate storage. */ if (handler->cert_obtain(id, id_len, 0, &rawcert, &rawcertlen)) { if (handler->id == ISAKMP_CERTENC_X509_SIG) { cert = handler->cert_get(rawcert, rawcertlen); if (!cert) LOG_DBG((LOG_CRYPTO, 50, "rsa_sig_decode_hash:" " certificate malformed")); else { if (!handler->cert_get_key(cert, &key)) { log_print("rsa_sig_decode_hash: " "decoding certificate failed"); handler->cert_free(cert); } else { found++; LOG_DBG((LOG_CRYPTO, 40, "rsa_sig_decode_hash: using cert " "of type %d", handler->id)); exchange->recv_cert = cert; exchange->recv_certtype = handler->id; x509_generate_kn(exchange->policy_id, cert); } } } else if (handler->id == ISAKMP_CERTENC_KEYNOTE) handler->cert_insert(exchange->policy_id, rawcert); free(rawcert); } /* * Walk over potential CERT payloads in this message. * XXX I believe this is the wrong spot for this. CERTs can appear * anytime. */ TAILQ_FOREACH(p, &msg->payload[ISAKMP_PAYLOAD_CERT], link) { p->flags |= PL_MARK; /* * When we have found a key, just walk over the rest, marking * them. */ if (found) continue; handler = cert_get(GET_ISAKMP_CERT_ENCODING(p->p)); if (!handler) { LOG_DBG((LOG_MISC, 30, "rsa_sig_decode_hash: " "no handler for %s CERT encoding", constant_name(isakmp_certenc_cst, GET_ISAKMP_CERT_ENCODING(p->p)))); continue; } cert = handler->cert_get(p->p + ISAKMP_CERT_DATA_OFF, GET_ISAKMP_GEN_LENGTH(p->p) - ISAKMP_CERT_DATA_OFF); if (!cert) { log_print("rsa_sig_decode_hash: " "can not get data from CERT"); continue; } if (!handler->cert_validate(cert)) { handler->cert_free(cert); log_print("rsa_sig_decode_hash: received CERT can't " "be validated"); continue; } if (GET_ISAKMP_CERT_ENCODING(p->p) == ISAKMP_CERTENC_X509_SIG) { if (!handler->cert_get_subjects(cert, &n, &id_cert, &id_cert_len)) { handler->cert_free(cert); log_print("rsa_sig_decode_hash: can not get " "subject from CERT"); continue; } id_found = 0; for (i = 0; i < n; i++) if (id_cert_len[i] == id_len && id[0] == id_cert[i][0] && memcmp(id + 4, id_cert[i] + 4, id_len - 4) == 0) { id_found++; break; } if (!id_found) { handler->cert_free(cert); log_print("rsa_sig_decode_hash: no CERT " "subject match the ID"); free(id_cert); continue; } cert_free_subjects(n, id_cert, id_cert_len); } if (!handler->cert_get_key(cert, &key)) { handler->cert_free(cert); log_print("rsa_sig_decode_hash: decoding payload CERT " "failed"); continue; } /* We validated the cert, cache it for later use. */ handler->cert_insert(exchange->policy_id, cert); exchange->recv_cert = cert; exchange->recv_certtype = GET_ISAKMP_CERT_ENCODING(p->p); if (exchange->recv_certtype == ISAKMP_CERTENC_KEYNOTE) { struct keynote_deckey dc; char *pp; int dclen; dc.dec_algorithm = KEYNOTE_ALGORITHM_RSA; dc.dec_key = key; pp = kn_encode_key(&dc, INTERNAL_ENC_PKCS1, ENCODING_HEX, KEYNOTE_PUBLIC_KEY); if (pp == NULL) { kn_free_key(&dc); log_print("rsa_sig_decode_hash: failed to " "ASCII-encode key"); return -1; } dclen = strlen(pp) + sizeof "rsa-hex:"; exchange->keynote_key = calloc(dclen, sizeof(char)); if (!exchange->keynote_key) { free(pp); kn_free_key(&dc); log_print("rsa_sig_decode_hash: failed to " "allocate %d bytes", dclen); return -1; } snprintf(exchange->keynote_key, dclen, "rsa-hex:%s", pp); free(pp); } found++; } #if defined (USE_DNSSEC) /* * If no certificate provided a key, try to find a validated DNSSEC * KEY. */ if (!found) { rawkey = dns_get_key(IKE_AUTH_RSA_SIG, msg, &rawkeylen); /* We need to convert 'void *rawkey' into 'RSA *key'. */ if (dns_RSA_dns_to_x509(rawkey, rawkeylen, &key) == 0) found++; else log_print("rsa_sig_decode_hash: KEY to RSA key " "conversion failed"); if (rawkey) free(rawkey); } #endif /* USE_DNSSEC */ /* If we still have not found a key, try to read it from a file. */ if (!found) if (get_raw_key_from_file(IKE_AUTH_RSA_SIG, id, id_len, &key) != -1) found++; if (!found) { log_print("rsa_sig_decode_hash: no public key found"); return -1; } p = payload_first(msg, ISAKMP_PAYLOAD_SIG); if (!p) { log_print("rsa_sig_decode_hash: missing signature payload"); RSA_free(key); return -1; } /* Check that the sig is of the correct size. */ len = GET_ISAKMP_GEN_LENGTH(p->p) - ISAKMP_SIG_SZ; if (len != RSA_size(key)) { RSA_free(key); log_print("rsa_sig_decode_hash: " "SIG payload length does not match public key"); return -1; } *hash_p = malloc(len); if (!*hash_p) { RSA_free(key); log_error("rsa_sig_decode_hash: malloc (%d) failed", len); return -1; } len = RSA_public_decrypt(len, p->p + ISAKMP_SIG_DATA_OFF, *hash_p, key, RSA_PKCS1_PADDING); if (len == -1) { RSA_free(key); log_print("rsa_sig_decode_hash: RSA_public_decrypt () failed"); return -1; } /* Store key for later use */ exchange->recv_key = key; exchange->recv_keytype = ISAKMP_KEY_RSA; if (len != (int)hashsize) { free(*hash_p); *hash_p = 0; log_print("rsa_sig_decode_hash: len %lu != hashsize %lu", (unsigned long)len, (unsigned long)hashsize); return -1; } snprintf(header, sizeof header, "rsa_sig_decode_hash: HASH_%c", initiator ? 'R' : 'I'); LOG_DBG_BUF((LOG_MISC, 80, header, *hash_p, hashsize)); p->flags |= PL_MARK; return 0; } static int pre_shared_encode_hash(struct message *msg) { struct exchange *exchange = msg->exchange; struct ipsec_exch *ie = exchange->data; size_t hashsize = ie->hash->hashsize; char header[80]; int initiator = exchange->initiator; u_int8_t *buf; buf = ipsec_add_hash_payload(msg, hashsize); if (!buf) return -1; if (ike_auth_hash(exchange, buf + ISAKMP_HASH_DATA_OFF) == -1) return -1; snprintf(header, sizeof header, "pre_shared_encode_hash: HASH_%c", initiator ? 'I' : 'R'); LOG_DBG_BUF((LOG_MISC, 80, header, buf + ISAKMP_HASH_DATA_OFF, hashsize)); return 0; } /* Encrypt the HASH into a SIG type. */ static int rsa_sig_encode_hash(struct message *msg) { struct exchange *exchange = msg->exchange; struct ipsec_exch *ie = exchange->data; size_t hashsize = ie->hash->hashsize, id_len; struct cert_handler *handler; char header[80]; int initiator = exchange->initiator, idtype; u_int8_t *buf, *data, *buf2, *id; u_int32_t datalen; int32_t sigsize; void *sent_key; id = initiator ? exchange->id_i : exchange->id_r; id_len = initiator ? exchange->id_i_len : exchange->id_r_len; /* We may have been provided these by the kernel */ buf = (u_int8_t *)conf_get_str(exchange->name, "Credentials"); if (buf && (idtype = conf_get_num(exchange->name, "Credential_Type", -1)) != -1) { exchange->sent_certtype = idtype; handler = cert_get(idtype); if (!handler) { log_print("rsa_sig_encode_hash: cert_get (%d) failed", idtype); return -1; } exchange->sent_cert = handler->cert_from_printable((char *)buf); if (!exchange->sent_cert) { log_print("rsa_sig_encode_hash: failed to retrieve " "certificate"); return -1; } handler->cert_serialize(exchange->sent_cert, &data, &datalen); if (!data) { log_print("rsa_sig_encode_hash: cert serialization " "failed"); return -1; } goto aftercert; /* Skip all the certificate discovery */ } /* XXX This needs to be configurable. */ idtype = ISAKMP_CERTENC_KEYNOTE; /* Find a certificate with subjectAltName = id. */ handler = cert_get(idtype); if (!handler) { idtype = ISAKMP_CERTENC_X509_SIG; handler = cert_get(idtype); if (!handler) { log_print("rsa_sig_encode_hash: cert_get(%d) failed", idtype); return -1; } } if (handler->cert_obtain(id, id_len, 0, &data, &datalen) == 0) { if (idtype == ISAKMP_CERTENC_KEYNOTE) { idtype = ISAKMP_CERTENC_X509_SIG; handler = cert_get(idtype); if (!handler) { log_print("rsa_sig_encode_hash: cert_get(%d) " "failed", idtype); return -1; } if (handler->cert_obtain(id, id_len, 0, &data, &datalen) == 0) { LOG_DBG((LOG_MISC, 10, "rsa_sig_encode_hash: " "no certificate to send")); goto skipcert; } } else { LOG_DBG((LOG_MISC, 10, "rsa_sig_encode_hash: no certificate to send")); goto skipcert; } } /* Let's store the certificate we are going to use */ exchange->sent_certtype = idtype; exchange->sent_cert = handler->cert_get(data, datalen); if (!exchange->sent_cert) { free(data); log_print("rsa_sig_encode_hash: failed to get certificate " "from wire encoding"); return -1; } aftercert: buf = realloc(data, ISAKMP_CERT_SZ + datalen); if (!buf) { log_error("rsa_sig_encode_hash: realloc (%p, %d) failed", data, ISAKMP_CERT_SZ + datalen); free(data); return -1; } memmove(buf + ISAKMP_CERT_SZ, buf, datalen); SET_ISAKMP_CERT_ENCODING(buf, idtype); if (message_add_payload(msg, ISAKMP_PAYLOAD_CERT, buf, ISAKMP_CERT_SZ + datalen, 1)) { free(buf); return -1; } skipcert: /* Again, we may have these from the kernel */ buf = (u_int8_t *)conf_get_str(exchange->name, "PKAuthentication"); if (buf) { key_from_printable(ISAKMP_KEY_RSA, ISAKMP_KEYTYPE_PRIVATE, (char *)buf, &data, &datalen); if (!data) { log_print("rsa_sig_encode_hash: badly formatted RSA " "private key"); return 0; } sent_key = key_internalize(ISAKMP_KEY_RSA, ISAKMP_KEYTYPE_PRIVATE, data, datalen); if (!sent_key) { log_print("rsa_sig_encode_hash: bad RSA private key " "from dynamic SA acquisition subsystem"); return 0; } } else { /* Try through the regular means. */ switch (id[ISAKMP_ID_TYPE_OFF - ISAKMP_GEN_SZ]) { case IPSEC_ID_IPV4_ADDR: case IPSEC_ID_IPV6_ADDR: util_ntoa((char **)&buf2, id[ISAKMP_ID_TYPE_OFF - ISAKMP_GEN_SZ] == IPSEC_ID_IPV4_ADDR ? AF_INET : AF_INET6, id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ); if (!buf2) return 0; break; case IPSEC_ID_FQDN: case IPSEC_ID_USER_FQDN: buf2 = calloc(id_len - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1, sizeof(char)); if (!buf2) { log_print("rsa_sig_encode_hash: malloc (%lu) " "failed", (unsigned long)id_len - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1); return 0; } memcpy(buf2, id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, id_len - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ); break; /* XXX Support more ID types? */ default: buf2 = 0; return 0; } sent_key = ike_auth_get_key(IKE_AUTH_RSA_SIG, exchange->name, (char *)buf2, 0); free(buf2); /* Did we find a key? */ if (!sent_key) { log_print("rsa_sig_encode_hash: " "could not get private key"); return -1; } } /* Enable RSA blinding. */ if (RSA_blinding_on(sent_key, NULL) != 1) { log_error("rsa_sig_encode_hash: RSA_blinding_on () failed."); RSA_free(sent_key); return -1; } /* XXX hashsize is not necessarily prf->blocksize. */ buf = malloc(hashsize); if (!buf) { log_error("rsa_sig_encode_hash: malloc (%lu) failed", (unsigned long)hashsize); RSA_free(sent_key); return -1; } if (ike_auth_hash(exchange, buf) == -1) { free(buf); RSA_free(sent_key); return -1; } snprintf(header, sizeof header, "rsa_sig_encode_hash: HASH_%c", initiator ? 'I' : 'R'); LOG_DBG_BUF((LOG_MISC, 80, header, buf, hashsize)); data = malloc(RSA_size(sent_key)); if (!data) { log_error("rsa_sig_encode_hash: malloc (%d) failed", RSA_size(sent_key)); free(buf); RSA_free(sent_key); return -1; } sigsize = RSA_private_encrypt(hashsize, buf, data, sent_key, RSA_PKCS1_PADDING); if (sigsize == -1) { log_print("rsa_sig_encode_hash: " "RSA_private_encrypt () failed"); if (data) free(data); free(buf); RSA_free(sent_key); return -1; } datalen = (u_int32_t) sigsize; free(buf); RSA_free(sent_key); buf = realloc(data, ISAKMP_SIG_SZ + datalen); if (!buf) { log_error("rsa_sig_encode_hash: realloc (%p, %d) failed", data, ISAKMP_SIG_SZ + datalen); free(data); return -1; } memmove(buf + ISAKMP_SIG_SZ, buf, datalen); snprintf(header, sizeof header, "rsa_sig_encode_hash: SIG_%c", initiator ? 'I' : 'R'); LOG_DBG_BUF((LOG_MISC, 80, header, buf + ISAKMP_SIG_DATA_OFF, datalen)); if (message_add_payload(msg, ISAKMP_PAYLOAD_SIG, buf, ISAKMP_SIG_SZ + datalen, 1)) { free(buf); return -1; } return 0; } int ike_auth_hash(struct exchange *exchange, u_int8_t *buf) { struct ipsec_exch *ie = exchange->data; struct prf *prf; struct hash *hash = ie->hash; int initiator = exchange->initiator; u_int8_t *id; size_t id_len; /* Choose the right fields to fill-in. */ id = initiator ? exchange->id_i : exchange->id_r; id_len = initiator ? exchange->id_i_len : exchange->id_r_len; /* Allocate the prf and start calculating our HASH. */ prf = prf_alloc(ie->prf_type, hash->type, ie->skeyid, ie->skeyid_len); if (!prf) return -1; prf->Init(prf->prfctx); prf->Update(prf->prfctx, initiator ? ie->g_xi : ie->g_xr, ie->g_x_len); prf->Update(prf->prfctx, initiator ? ie->g_xr : ie->g_xi, ie->g_x_len); prf->Update(prf->prfctx, exchange->cookies + (initiator ? ISAKMP_HDR_ICOOKIE_OFF : ISAKMP_HDR_RCOOKIE_OFF), ISAKMP_HDR_ICOOKIE_LEN); prf->Update(prf->prfctx, exchange->cookies + (initiator ? ISAKMP_HDR_RCOOKIE_OFF : ISAKMP_HDR_ICOOKIE_OFF), ISAKMP_HDR_ICOOKIE_LEN); prf->Update(prf->prfctx, ie->sa_i_b, ie->sa_i_b_len); prf->Update(prf->prfctx, id, id_len); prf->Final(buf, prf->prfctx); prf_free(prf); return 0; } static int get_raw_key_from_file(int type, u_int8_t *id, size_t id_len, RSA **rsa) { char filename[FILENAME_MAX]; char *fstr; FILE *keyfp; if (type != IKE_AUTH_RSA_SIG) { /* XXX More types? */ LOG_DBG((LOG_NEGOTIATION, 20, "get_raw_key_from_file: " "invalid auth type %d\n", type)); return -1; } *rsa = 0; fstr = conf_get_str("General", "Pubkey-directory"); if (!fstr) fstr = CONF_DFLT_PUBKEY_DIR; if (snprintf(filename, sizeof filename, "%s/", fstr) > (int)sizeof filename - 1) return -1; fstr = ipsec_id_string(id, id_len); if (!fstr) { LOG_DBG((LOG_NEGOTIATION, 50, "get_raw_key_from_file: " "ipsec_id_string failed")); return -1; } strlcat(filename, fstr, sizeof filename - strlen(filename)); free(fstr); /* If the file does not exist, fail silently. */ keyfp = monitor_fopen(filename, "r"); if (keyfp) { *rsa = PEM_read_RSA_PUBKEY(keyfp, NULL, NULL, NULL); if (!*rsa) log_print("get_raw_key_from_file: failed to get " "public key %s", filename); fclose(keyfp); } else if (errno != ENOENT) { log_error("get_raw_key_from_file: monitor_fopen " "(\"%s\", \"r\") failed", filename); return -1; } else LOG_DBG((LOG_NEGOTIATION, 50, "get_raw_key_from_file: file %s not found", filename)); return (*rsa ? 0 : -1); }