/* $OpenBSD: policy.c,v 1.50 2002/01/23 22:14:28 angelos Exp $ */ /* $EOM: policy.c,v 1.49 2000/10/24 13:33:39 niklas Exp $ */ /* * Copyright (c) 1999, 2000, 2001 Angelos D. Keromytis. All rights reserved. * Copyright (c) 1999, 2000, 2001 Niklas Hallqvist. All rights reserved. * Copyright (c) 2001 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. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by Ericsson Radio Systems. * 4. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * 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 #include #include #include #include #include #include #include "sysdep.h" #include "conf.h" #include "dyn.h" #include "exchange.h" #include "ipsec.h" #include "isakmp_doi.h" #include "sa.h" #include "transport.h" #include "log.h" #include "message.h" #include "util.h" #include "policy.h" #include "x509.h" #if defined (HAVE_DLOPEN) && !defined (USE_KEYNOTE) && 0 void *libkeynote = 0; /* * These prototypes matches OpenBSD keynote.h 1.6. If you use * a different version than that, you are on your own. */ int *lk_keynote_errno; int (*lk_kn_add_action) (int, char *, char *, int); int (*lk_kn_add_assertion) (int, char *, int, int); int (*lk_kn_add_authorizer) (int, char *); int (*lk_kn_close) (int); int (*lk_kn_do_query) (int, char **, int); char *(*lk_kn_encode_key) (struct keynote_deckey *, int, int, int); int (*lk_kn_init) (void); char **(*lk_kn_read_asserts) (char *, int, int *); int (*lk_kn_remove_authorizer) (int, char *); int (*lk_kn_get_authorizer) (int, int, int *); void (*lk_kn_free_key) (struct keynote_deckey *); struct keynote_keylist *(*lk_kn_get_licensees) (int, int); #define SYMENTRY(x) { SYM, SYM (x), (void **)&lk_ ## x } static struct dynload_script libkeynote_script[] = { { LOAD, "libc.so", &libkeynote }, { LOAD, "libcrypto.so", &libkeynote }, { LOAD, "libm.so", &libkeynote }, { LOAD, "libkeynote.so", &libkeynote }, SYMENTRY (keynote_errno), SYMENTRY (kn_add_action), SYMENTRY (kn_add_assertion), SYMENTRY (kn_add_authorizer), SYMENTRY (kn_close), SYMENTRY (kn_do_query), SYMENTRY (kn_encode_key), SYMENTRY (kn_init), SYMENTRY (kn_read_asserts), SYMENTRY (kn_remove_authorizer), SYMENTRY (kn_get_licensees), SYMENTRY (kn_get_authorizer), { EOS } }; #endif char **keynote_policy_asserts = NULL; int keynote_policy_asserts_num = 0; struct exchange *policy_exchange = 0; struct sa *policy_sa = 0; struct sa *policy_isakmp_sa = 0; static const char hextab[] = { '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', 'a', 'b', 'c', 'd', 'e', 'f' }; /* * Adaptation of Vixie's inet_ntop4 () */ static const char * my_inet_ntop4 (const in_addr_t *src, char *dst, size_t size, int normalize) { static const char fmt[] = "%03u.%03u.%03u.%03u"; char tmp[sizeof "255.255.255.255"]; in_addr_t src2; if (normalize) src2 = ntohl (*src); else src2 = *src; if (snprintf (tmp, sizeof tmp, fmt, ((u_int8_t *) &src2)[0], ((u_int8_t *) &src2)[1], ((u_int8_t *) &src2)[2], ((u_int8_t *) &src2)[3]) > size) { errno = ENOSPC; return 0; } strlcpy (dst, tmp, size); return dst; } static const char * my_inet_ntop6 (const unsigned char *src, char *dst, size_t size) { static const char fmt[] = "%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x:%02x%02x"; char tmp[sizeof "ffff:ffff:ffff:ffff:ffff:ffff:ffff:ffff"]; if (snprintf (tmp, sizeof tmp, fmt, src[0], src[1], src[2], src[3], src[4], src[5], src[6], src[7], src[8], src[9], src[10], src[11], src[12], src[13], src[14], src[15]) > size) { errno = ENOSPC; return 0; } strlcpy (dst, tmp, size); return dst; } char * policy_callback (char *name) { struct proto *proto; u_int8_t *attr, *value, *id, *idlocal, *idremote; size_t id_sz, idlocalsz, idremotesz; struct sockaddr *sin; struct ipsec_exch *ie; struct ipsec_sa *is; int fmt, i, lifetype = 0; in_addr_t net, subnet; u_int16_t len, type; time_t tt; char *addr; static char mytimeofday[15]; /* We use all these as a cache. */ #define PMAX 32 static char *esp_present, *ah_present, *comp_present; static char *ah_hash_alg, *ah_auth_alg, *esp_auth_alg, *esp_enc_alg; static char *comp_alg, ah_life_kbytes[PMAX], ah_life_seconds[PMAX]; static char esp_life_kbytes[PMAX], esp_life_seconds[PMAX]; static char comp_life_kbytes[PMAX]; static char comp_life_seconds[PMAX], *ah_encapsulation, *esp_encapsulation; static char *comp_encapsulation, ah_key_length[PMAX], esp_key_length[PMAX]; static char ah_key_rounds[PMAX], esp_key_rounds[PMAX], comp_dict_size[PMAX]; static char comp_private_alg[PMAX], *remote_filter_type, *local_filter_type; static char remote_filter_addr_upper[NI_MAXHOST]; static char remote_filter_addr_lower[NI_MAXHOST]; static char local_filter_addr_upper[NI_MAXHOST]; static char local_filter_addr_lower[NI_MAXHOST]; static char ah_group_desc[PMAX], esp_group_desc[PMAX], comp_group_desc[PMAX]; static char remote_ike_address[NI_MAXHOST]; static char local_ike_address[NI_MAXHOST]; static char *remote_id_type, remote_id_addr_upper[NI_MAXHOST], *phase_1; static char remote_id_addr_lower[NI_MAXHOST]; static char *remote_id_proto, remote_id_port[PMAX]; static char remote_filter_port[PMAX], local_filter_port[PMAX]; static char *remote_filter_proto, *local_filter_proto, *pfs, *initiator; static char remote_filter_proto_num[3], local_filter_proto_num[3]; static char remote_id_proto_num[3]; static char phase1_group[PMAX]; /* Allocated. */ static char *remote_filter = 0, *local_filter = 0, *remote_id = 0; static int dirty = 1; /* We only need to set dirty at initialization time really. */ if (strcmp (name, KEYNOTE_CALLBACK_CLEANUP) == 0 || strcmp (name, KEYNOTE_CALLBACK_INITIALIZE) == 0) { esp_present = ah_present = comp_present = pfs = "no"; ah_hash_alg = ah_auth_alg = phase_1 = ""; esp_auth_alg = esp_enc_alg = comp_alg = ah_encapsulation = ""; esp_encapsulation = comp_encapsulation = remote_filter_type = ""; local_filter_type = remote_id_type = initiator = ""; remote_filter_proto = local_filter_proto = remote_id_proto = ""; if (remote_filter != 0) { free (remote_filter); remote_filter = 0; } if (local_filter != 0) { free (local_filter); local_filter = 0; } if (remote_id != 0) { free (remote_id); remote_id = 0; } memset (remote_ike_address, 0, sizeof remote_ike_address); memset (local_ike_address, 0, sizeof local_ike_address); memset (ah_life_kbytes, 0, sizeof ah_life_kbytes); memset (ah_life_seconds, 0, sizeof ah_life_seconds); memset (esp_life_kbytes, 0, sizeof esp_life_kbytes); memset (esp_life_seconds, 0, sizeof esp_life_seconds); memset (comp_life_kbytes, 0, sizeof comp_life_kbytes); memset (comp_life_seconds, 0, sizeof comp_life_seconds); memset (ah_key_length, 0, sizeof ah_key_length); memset (ah_key_rounds, 0, sizeof ah_key_rounds); memset (esp_key_length, 0, sizeof esp_key_length); memset (esp_key_rounds, 0, sizeof esp_key_rounds); memset (comp_dict_size, 0, sizeof comp_dict_size); memset (comp_private_alg, 0, sizeof comp_private_alg); memset (remote_filter_addr_upper, 0, sizeof remote_filter_addr_upper); memset (remote_filter_addr_lower, 0, sizeof remote_filter_addr_lower); memset (local_filter_addr_upper, 0, sizeof local_filter_addr_upper); memset (local_filter_addr_lower, 0, sizeof local_filter_addr_lower); memset (remote_id_addr_upper, 0, sizeof remote_id_addr_upper); memset (remote_id_addr_lower, 0, sizeof remote_id_addr_lower); memset (ah_group_desc, 0, sizeof ah_group_desc); memset (esp_group_desc, 0, sizeof esp_group_desc); memset (remote_id_port, 0, sizeof remote_id_port); memset (remote_filter_port, 0, sizeof remote_filter_port); memset (local_filter_port, 0, sizeof local_filter_port); memset (phase1_group, 0, sizeof phase1_group); dirty = 1; return ""; } /* * If dirty is set, this is the first request for an attribute, so * populate our value cache. */ if (dirty) { ie = policy_exchange->data; if (ie->pfs) pfs = "yes"; is = policy_isakmp_sa->data; snprintf (phase1_group, PMAX, "%u", is->group_desc); for (proto = TAILQ_FIRST (&policy_sa->protos); proto; proto = TAILQ_NEXT (proto, link)) { switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: ah_present = "yes"; switch (proto->id) { case IPSEC_AH_MD5: ah_hash_alg = "md5"; break; case IPSEC_AH_SHA: ah_hash_alg = "sha"; break; case IPSEC_AH_RIPEMD: ah_hash_alg = "ripemd"; break; case IPSEC_AH_DES: ah_hash_alg = "des"; break; } break; case IPSEC_PROTO_IPSEC_ESP: esp_present = "yes"; switch (proto->id) { case IPSEC_ESP_DES_IV64: esp_enc_alg = "des-iv64"; break; case IPSEC_ESP_DES: esp_enc_alg = "des"; break; case IPSEC_ESP_3DES: esp_enc_alg = "3des"; break; case IPSEC_ESP_AES: esp_enc_alg = "aes"; break; case IPSEC_ESP_RC5: esp_enc_alg = "rc5"; break; case IPSEC_ESP_IDEA: esp_enc_alg = "idea"; break; case IPSEC_ESP_CAST: esp_enc_alg = "cast"; break; case IPSEC_ESP_BLOWFISH: esp_enc_alg = "blowfish"; break; case IPSEC_ESP_3IDEA: esp_enc_alg = "3idea"; break; case IPSEC_ESP_DES_IV32: esp_enc_alg = "des-iv32"; break; case IPSEC_ESP_RC4: esp_enc_alg = "rc4"; break; case IPSEC_ESP_NULL: esp_enc_alg = "null"; break; } break; case IPSEC_PROTO_IPCOMP: comp_present = "yes"; switch (proto->id) { case IPSEC_IPCOMP_OUI: comp_alg = "oui"; break; case IPSEC_IPCOMP_DEFLATE: comp_alg = "deflate"; break; case IPSEC_IPCOMP_LZS: comp_alg = "lzs"; break; case IPSEC_IPCOMP_V42BIS: comp_alg = "v42bis"; break; } break; } for (attr = proto->chosen->p + ISAKMP_TRANSFORM_SA_ATTRS_OFF; attr < proto->chosen->p + GET_ISAKMP_GEN_LENGTH (proto->chosen->p); attr = value + len) { if (attr + ISAKMP_ATTR_VALUE_OFF > (proto->chosen->p + GET_ISAKMP_GEN_LENGTH (proto->chosen->p))) return ""; type = GET_ISAKMP_ATTR_TYPE (attr); fmt = ISAKMP_ATTR_FORMAT (type); type = ISAKMP_ATTR_TYPE (type); value = attr + (fmt ? ISAKMP_ATTR_LENGTH_VALUE_OFF : ISAKMP_ATTR_VALUE_OFF); len = (fmt ? ISAKMP_ATTR_LENGTH_VALUE_LEN : GET_ISAKMP_ATTR_LENGTH_VALUE (attr)); if (value + len > proto->chosen->p + GET_ISAKMP_GEN_LENGTH (proto->chosen->p)) return ""; switch (type) { case IPSEC_ATTR_SA_LIFE_TYPE: lifetype = decode_16 (value); break; case IPSEC_ATTR_SA_LIFE_DURATION: switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: if (lifetype == IPSEC_DURATION_SECONDS) { if (len == 2) snprintf (ah_life_seconds, PMAX, "%u", decode_16 (value)); else snprintf (ah_life_seconds, PMAX, "%u", decode_32 (value)); } else { if (len == 2) snprintf (ah_life_kbytes, PMAX, "%u", decode_16 (value)); else snprintf (ah_life_kbytes, PMAX, "%u", decode_32 (value)); } break; case IPSEC_PROTO_IPSEC_ESP: if (lifetype == IPSEC_DURATION_SECONDS) { if (len == 2) snprintf (esp_life_seconds, PMAX, "%u", decode_16 (value)); else snprintf (esp_life_seconds, PMAX, "%u", decode_32 (value)); } else { if (len == 2) snprintf (esp_life_kbytes, PMAX, "%u", decode_16 (value)); else snprintf (esp_life_kbytes, PMAX, "%u", decode_32 (value)); } break; case IPSEC_PROTO_IPCOMP: if (lifetype == IPSEC_DURATION_SECONDS) { if (len == 2) snprintf (comp_life_seconds, PMAX, "%u", decode_16 (value)); else snprintf (comp_life_seconds, PMAX, "%u", decode_32 (value)); } else { if (len == 2) snprintf (comp_life_kbytes, PMAX, "%u", decode_16 (value)); else snprintf (comp_life_kbytes, PMAX, "%u", decode_32 (value)); } break; } break; case IPSEC_ATTR_GROUP_DESCRIPTION: switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: snprintf (ah_group_desc, PMAX, "%u", decode_16 (value)); break; case IPSEC_PROTO_IPSEC_ESP: snprintf (esp_group_desc, PMAX, "%u", decode_16 (value)); break; case IPSEC_PROTO_IPCOMP: snprintf (comp_group_desc, PMAX, "%u", decode_16 (value)); break; } break; case IPSEC_ATTR_ENCAPSULATION_MODE: if (decode_16 (value) == IPSEC_ENCAP_TUNNEL) switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: ah_encapsulation = "tunnel"; break; case IPSEC_PROTO_IPSEC_ESP: esp_encapsulation = "tunnel"; break; case IPSEC_PROTO_IPCOMP: comp_encapsulation = "tunnel"; break; } else switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: ah_encapsulation = "transport"; break; case IPSEC_PROTO_IPSEC_ESP: esp_encapsulation = "transport"; break; case IPSEC_PROTO_IPCOMP: comp_encapsulation = "transport"; break; } break; case IPSEC_ATTR_AUTHENTICATION_ALGORITHM: switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: switch (decode_16 (value)) { case IPSEC_AUTH_HMAC_MD5: ah_auth_alg = "hmac-md5"; break; case IPSEC_AUTH_HMAC_SHA: ah_auth_alg = "hmac-sha"; break; case IPSEC_AUTH_HMAC_RIPEMD: ah_auth_alg = "hmac-ripemd"; break; case IPSEC_AUTH_DES_MAC: ah_auth_alg = "des-mac"; break; case IPSEC_AUTH_KPDK: ah_auth_alg = "kpdk"; break; } break; case IPSEC_PROTO_IPSEC_ESP: switch (decode_16 (value)) { case IPSEC_AUTH_HMAC_MD5: esp_auth_alg = "hmac-md5"; break; case IPSEC_AUTH_HMAC_SHA: esp_auth_alg = "hmac-sha"; break; case IPSEC_AUTH_HMAC_RIPEMD: esp_auth_alg = "hmac-ripemd"; break; case IPSEC_AUTH_DES_MAC: esp_auth_alg = "des-mac"; break; case IPSEC_AUTH_KPDK: esp_auth_alg = "kpdk"; break; } break; } break; case IPSEC_ATTR_KEY_LENGTH: switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: snprintf (ah_key_length, PMAX, "%u", decode_16 (value)); break; case IPSEC_PROTO_IPSEC_ESP: snprintf (esp_key_length, PMAX, "%u", decode_16 (value)); break; } break; case IPSEC_ATTR_KEY_ROUNDS: switch (proto->proto) { case IPSEC_PROTO_IPSEC_AH: snprintf (ah_key_rounds, PMAX, "%u", decode_16 (value)); break; case IPSEC_PROTO_IPSEC_ESP: snprintf (esp_key_rounds, PMAX, "%u", decode_16 (value)); break; } break; case IPSEC_ATTR_COMPRESS_DICTIONARY_SIZE: snprintf (comp_dict_size, PMAX, "%u", decode_16 (value)); break; case IPSEC_ATTR_COMPRESS_PRIVATE_ALGORITHM: snprintf (comp_private_alg, PMAX, "%u", decode_16 (value)); break; } } } policy_sa->transport->vtbl->get_src (policy_sa->transport, &sin); if (sockaddr2text (sin, &addr, 1)) { log_error ("policy_callback: sockaddr2text failed"); goto bad; } strlcpy (local_ike_address, addr, sizeof local_ike_address); free (addr); policy_sa->transport->vtbl->get_dst (policy_sa->transport, &sin); if (sockaddr2text (sin, &addr, 1)) { log_error ("policy_callback: sockaddr2text failed"); goto bad; } strlcpy (remote_ike_address, addr, sizeof remote_ike_address); free (addr); switch (policy_isakmp_sa->exch_type) { case ISAKMP_EXCH_AGGRESSIVE: phase_1 = "aggressive"; break; case ISAKMP_EXCH_ID_PROT: phase_1 = "main"; break; } if (policy_isakmp_sa->initiator) { id = policy_isakmp_sa->id_r; id_sz = policy_isakmp_sa->id_r_len; } else { id = policy_isakmp_sa->id_i; id_sz = policy_isakmp_sa->id_i_len; } switch (id[0]) { case IPSEC_ID_IPV4_ADDR: remote_id_type = "IPv4 address"; net = decode_32 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ); my_inet_ntop4 (&net, remote_id_addr_upper, sizeof remote_id_addr_upper - 1, 1); my_inet_ntop4 (&net, remote_id_addr_lower, sizeof remote_id_addr_lower - 1, 1); remote_id = strdup (remote_id_addr_upper); if (!remote_id) { log_error ("policy_callback: strdup (\"%s\") failed", remote_id_addr_upper); goto bad; } break; case IPSEC_ID_IPV4_RANGE: remote_id_type = "IPv4 range"; net = decode_32 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ); my_inet_ntop4 (&net, remote_id_addr_lower, sizeof remote_id_addr_lower - 1, 1); net = decode_32 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ + 4); my_inet_ntop4 (&net, remote_id_addr_upper, sizeof remote_id_addr_upper - 1, 1); len = strlen (remote_id_addr_upper) + strlen (remote_id_addr_lower) + 2; remote_id = calloc (len, sizeof (char)); if (!remote_id) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_id, remote_id_addr_lower, len); strlcat (remote_id, "-", len); strlcat (remote_id, remote_id_addr_upper, len); break; case IPSEC_ID_IPV4_ADDR_SUBNET: remote_id_type = "IPv4 subnet"; net = decode_32 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ); subnet = decode_32 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ + 4); net &= subnet; my_inet_ntop4 (&net, remote_id_addr_lower, sizeof remote_id_addr_lower - 1, 1); net |= ~subnet; my_inet_ntop4 (&net, remote_id_addr_upper, sizeof remote_id_addr_upper - 1, 1); len = strlen (remote_id_addr_upper) + strlen (remote_id_addr_lower) + 2; remote_id = calloc (len, sizeof (char)); if (!remote_id) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_id, remote_id_addr_lower, len); strlcat (remote_id, "-", len); strlcat (remote_id, remote_id_addr_upper, len); break; case IPSEC_ID_IPV6_ADDR: remote_id_type = "IPv6 address"; my_inet_ntop6 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, remote_id_addr_upper, sizeof remote_id_addr_upper); strlcpy (remote_id_addr_lower, remote_id_addr_upper, sizeof remote_id_addr_lower); remote_id = strdup (remote_id_addr_upper); if (!remote_id) { log_error ("policy_callback: strdup (\"%s\") failed", remote_id_addr_upper); goto bad; } break; case IPSEC_ID_IPV6_RANGE: remote_id_type = "IPv6 range"; my_inet_ntop6 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, remote_id_addr_lower, sizeof remote_id_addr_lower - 1); my_inet_ntop6 (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ + 16, remote_id_addr_upper, sizeof remote_id_addr_upper - 1); len = strlen (remote_id_addr_upper) + strlen (remote_id_addr_lower) + 2; remote_id = calloc (len, sizeof (char)); if (!remote_id) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_id, remote_id_addr_lower, len); strlcat (remote_id, "-", len); strlcat (remote_id, remote_id_addr_upper, len); break; case IPSEC_ID_IPV6_ADDR_SUBNET: { struct in6_addr net, mask; remote_id_type = "IPv6 subnet"; bcopy (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, &net, sizeof (net)); bcopy (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ + 16, &mask, sizeof (mask)); for (i = 0; i < 16; i++) net.s6_addr[i] &= mask.s6_addr[i]; my_inet_ntop6 ((char *) &net, remote_id_addr_lower, sizeof remote_id_addr_lower - 1); for (i = 0; i < 16; i++) net.s6_addr[i] |= ~mask.s6_addr[i]; my_inet_ntop6 ((char *) &net, remote_id_addr_upper, sizeof remote_id_addr_upper - 1); len = strlen (remote_id_addr_upper) + strlen (remote_id_addr_lower) + 2; remote_id = calloc (len, sizeof (char)); if (!remote_id) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_id, remote_id_addr_lower, len); strlcat (remote_id, "-", len); strlcat (remote_id, remote_id_addr_upper, len); break; } case IPSEC_ID_FQDN: remote_id_type = "FQDN"; remote_id = calloc (id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1, sizeof (char)); if (!remote_id) { log_error ("policy_callback: calloc (%d, %d) failed", id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1, sizeof (char)); goto bad; } memcpy (remote_id, id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ); break; case IPSEC_ID_USER_FQDN: remote_id_type = "User FQDN"; remote_id = calloc (id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1, sizeof (char)); if (!remote_id) { log_error ("policy_callback: calloc (%d, %d) failed", id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ + 1, sizeof (char)); goto bad; } memcpy (remote_id, id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ); break; case IPSEC_ID_DER_ASN1_DN: remote_id_type = "ASN1 DN"; remote_id = x509_DN_string (id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ); if (!remote_id) { LOG_DBG ((LOG_POLICY, 50, "policy_callback: failed to decode name")); goto bad; } break; case IPSEC_ID_DER_ASN1_GN: /* XXX */ remote_id_type = "ASN1 GN"; break; case IPSEC_ID_KEY_ID: remote_id_type = "Key ID"; remote_id = calloc (2 * (id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ) + 1, sizeof (char)); if (!remote_id) { log_error ("policy_callback: calloc (%d, %d) failed", 2 * (id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ) + 1, sizeof (char)); goto bad; } /* Does it contain any non-printable characters ? */ for (i = 0; i < id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ; i++) if (!isprint (*(id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ + i))) break; if (i >= id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ) { memcpy (remote_id, id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ, id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ); break; } /* Non-printable characters, convert to hex */ for (i = 0; i < id_sz - ISAKMP_ID_DATA_OFF + ISAKMP_GEN_SZ; i++) { remote_id[2 * i] = hextab[*(id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ) >> 4]; remote_id[2 * i + 1] = hextab[*(id + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ) & 0xF]; } break; default: log_print ("policy_callback: unknown remote ID type %u", id[0]); goto bad; } switch (id[1]) { case IPPROTO_TCP: remote_id_proto = "tcp"; break; case IPPROTO_UDP: remote_id_proto = "udp"; break; #ifdef IPPROTO_ETHERIP case IPPROTO_ETHERIP: remote_id_proto = "etherip"; break; #endif default: snprintf (remote_id_proto_num, 3, "%2d", id[1]); remote_id_proto = remote_id_proto_num; break; } snprintf (remote_id_port, sizeof remote_id_port - 1, "%u", decode_16 (id + 2)); if (policy_exchange->initiator) { initiator = "yes"; idlocal = ie->id_ci; idremote = ie->id_cr; idlocalsz = ie->id_ci_sz; idremotesz = ie->id_cr_sz; } else { initiator = "no"; idlocal = ie->id_cr; idremote = ie->id_ci; idlocalsz = ie->id_cr_sz; idremotesz = ie->id_ci_sz; } /* Initialize the ID variables. */ if (idremote) { switch (GET_ISAKMP_ID_TYPE (idremote)) { case IPSEC_ID_IPV4_ADDR: remote_filter_type = "IPv4 address"; net = decode_32 (idremote + ISAKMP_ID_DATA_OFF); my_inet_ntop4 (&net, remote_filter_addr_upper, sizeof remote_filter_addr_upper - 1, 1); my_inet_ntop4 (&net, remote_filter_addr_lower, sizeof remote_filter_addr_lower - 1, 1); remote_filter = strdup (remote_filter_addr_upper); if (!remote_filter) { log_error ("policy_callback: strdup (\"%s\") failed", remote_filter_addr_upper); goto bad; } break; case IPSEC_ID_IPV4_RANGE: remote_filter_type = "IPv4 range"; net = decode_32 (idremote + ISAKMP_ID_DATA_OFF); my_inet_ntop4 (&net, remote_filter_addr_lower, sizeof remote_filter_addr_lower - 1, 1); net = decode_32 (idremote + ISAKMP_ID_DATA_OFF + 4); my_inet_ntop4 (&net, remote_filter_addr_upper, sizeof remote_filter_addr_upper - 1, 1); len = strlen (remote_filter_addr_upper) + strlen (remote_filter_addr_lower) + 2; remote_filter = calloc (len, sizeof (char)); if (!remote_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_filter, remote_filter_addr_lower, len); strlcat (remote_filter, "-", len); strlcat (remote_filter, remote_filter_addr_upper, len); break; case IPSEC_ID_IPV4_ADDR_SUBNET: remote_filter_type = "IPv4 subnet"; net = decode_32 (idremote + ISAKMP_ID_DATA_OFF); subnet = decode_32 (idremote + ISAKMP_ID_DATA_OFF + 4); net &= subnet; my_inet_ntop4 (&net, remote_filter_addr_lower, sizeof remote_filter_addr_lower - 1, 1); net |= ~subnet; my_inet_ntop4 (&net, remote_filter_addr_upper, sizeof remote_filter_addr_upper - 1, 1); len = strlen (remote_filter_addr_upper) + strlen (remote_filter_addr_lower) + 2; remote_filter = calloc (len, sizeof (char)); if (!remote_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_filter, remote_filter_addr_lower, len); strlcat (remote_filter, "-", len); strlcat (remote_filter, remote_filter_addr_upper, len); break; case IPSEC_ID_IPV6_ADDR: remote_filter_type = "IPv6 address"; my_inet_ntop6 (idremote + ISAKMP_ID_DATA_OFF, remote_filter_addr_upper, sizeof remote_filter_addr_upper - 1); strlcpy (remote_filter_addr_lower, remote_filter_addr_upper, sizeof remote_filter_addr_lower); remote_filter = strdup (remote_filter_addr_upper); if (!remote_filter) { log_error ("policy_callback: strdup (\"%s\") failed", remote_filter_addr_upper); goto bad; } break; case IPSEC_ID_IPV6_RANGE: remote_filter_type = "IPv6 range"; my_inet_ntop6 (idremote + ISAKMP_ID_DATA_OFF, remote_filter_addr_lower, sizeof remote_filter_addr_lower - 1); my_inet_ntop6 (idremote + ISAKMP_ID_DATA_OFF + 16, remote_filter_addr_upper, sizeof remote_filter_addr_upper - 1); len = strlen (remote_filter_addr_upper) + strlen (remote_filter_addr_lower) + 2; remote_filter = calloc (len, sizeof (char)); if (!remote_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_filter, remote_filter_addr_lower, len); strlcat (remote_filter, "-", len); strlcat (remote_filter, remote_filter_addr_upper, len); break; case IPSEC_ID_IPV6_ADDR_SUBNET: { struct in6_addr net, mask; remote_filter_type = "IPv6 subnet"; bcopy (idremote + ISAKMP_ID_DATA_OFF, &net, sizeof (net)); bcopy (idremote + ISAKMP_ID_DATA_OFF + 16, &mask, sizeof (mask)); for (i = 0; i < 16; i++) net.s6_addr[i] &= mask.s6_addr[i]; my_inet_ntop6 ((char *) &net, remote_filter_addr_lower, sizeof remote_filter_addr_lower - 1); for (i = 0; i < 16; i++) net.s6_addr[i] |= ~mask.s6_addr[i]; my_inet_ntop6 ((char *) &net, remote_filter_addr_upper, sizeof remote_filter_addr_upper - 1); len = strlen (remote_filter_addr_upper) + strlen (remote_filter_addr_lower) + 2; remote_filter = calloc (len, sizeof (char)); if (!remote_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (remote_filter, remote_filter_addr_lower, len); strlcat (remote_filter, "-", len); strlcat (remote_filter, remote_filter_addr_upper, len); break; } case IPSEC_ID_FQDN: remote_filter_type = "FQDN"; remote_filter = malloc (idremotesz - ISAKMP_ID_DATA_OFF + 1); if (!remote_filter) { log_error ("policy_callback: malloc (%d) failed", idremotesz - ISAKMP_ID_DATA_OFF + 1); goto bad; } memcpy (remote_filter, idremote + ISAKMP_ID_DATA_OFF, idremotesz - ISAKMP_ID_DATA_OFF); remote_filter[idremotesz - ISAKMP_ID_DATA_OFF] = '\0'; break; case IPSEC_ID_USER_FQDN: remote_filter_type = "User FQDN"; remote_filter = malloc (idremotesz - ISAKMP_ID_DATA_OFF + 1); if (!remote_filter) { log_error ("policy_callback: malloc (%d) failed", idremotesz - ISAKMP_ID_DATA_OFF + 1); goto bad; } memcpy (remote_filter, idremote + ISAKMP_ID_DATA_OFF, idremotesz - ISAKMP_ID_DATA_OFF); remote_filter[idremotesz - ISAKMP_ID_DATA_OFF] = '\0'; break; case IPSEC_ID_DER_ASN1_DN: remote_filter_type = "ASN1 DN"; remote_filter = x509_DN_string (idremote + ISAKMP_ID_DATA_OFF, idremotesz - ISAKMP_ID_DATA_OFF); if (!remote_filter) { LOG_DBG ((LOG_POLICY, 50, "policy_callback: failed to decode name")); goto bad; } break; case IPSEC_ID_DER_ASN1_GN: /* XXX -- not sure what's in this. */ remote_filter_type = "ASN1 GN"; break; case IPSEC_ID_KEY_ID: remote_filter_type = "Key ID"; remote_filter = calloc (2 * (idremotesz - ISAKMP_ID_DATA_OFF) + 1, sizeof (char)); if (!remote_filter) { log_error ("policy_callback: calloc (%d, %d) failed", 2 * (idremotesz - ISAKMP_ID_DATA_OFF) + 1, sizeof (char)); goto bad; } /* Does it contain any non-printable characters ? */ for (i = 0; i < idremotesz - ISAKMP_ID_DATA_OFF; i++) if (!isprint (*(idremote + ISAKMP_ID_DATA_OFF + i))) break; if (i >= idremotesz - ISAKMP_ID_DATA_OFF) { memcpy (remote_filter, idremote + ISAKMP_ID_DATA_OFF, idremotesz - ISAKMP_ID_DATA_OFF); break; } /* Non-printable characters, convert to hex */ for (i = 0; i < idremotesz - ISAKMP_ID_DATA_OFF; i++) { remote_filter[2 * i] = hextab[*(idremote + ISAKMP_ID_DATA_OFF) >> 4]; remote_filter[2 * i + 1] = hextab[*(idremote + ISAKMP_ID_DATA_OFF) & 0xF]; } break; default: log_print ("policy_callback: unknown Remote ID type %u", GET_ISAKMP_ID_TYPE (idremote)); goto bad; } switch (idremote[ISAKMP_GEN_SZ + 1]) { case IPPROTO_TCP: remote_filter_proto = "tcp"; break; case IPPROTO_UDP: remote_filter_proto = "udp"; break; #ifdef IPPROTO_ETHERIP case IPPROTO_ETHERIP: remote_filter_proto = "etherip"; break; #endif default: snprintf (remote_filter_proto_num, 3, "%2d", idremote[ISAKMP_GEN_SZ + 1]); remote_filter_proto = remote_filter_proto_num; break; } snprintf (remote_filter_port, sizeof remote_filter_port - 1, "%u", decode_16 (idremote + ISAKMP_GEN_SZ + 2)); } else { policy_sa->transport->vtbl->get_dst (policy_sa->transport, &sin); switch (sin->sa_family) { case AF_INET: remote_filter_type = "IPv4 address"; break; case AF_INET6: remote_filter_type = "IPv6 address"; break; default: log_print ("policy_callback: unsupported protocol family %d", sin->sa_family); goto bad; } if (sockaddr2text (sin, &addr, 1)) { log_error ("policy_callback: sockaddr2text failed"); goto bad; } memcpy (remote_filter_addr_upper, addr, sizeof remote_filter_addr_upper); memcpy (remote_filter_addr_lower, addr, sizeof remote_filter_addr_lower); free (addr); remote_filter = strdup (remote_filter_addr_upper); if (!remote_filter) { log_error ("policy_callback: strdup (\"%s\") failed", remote_filter_addr_upper); goto bad; } } if (idlocal) { switch (GET_ISAKMP_ID_TYPE (idlocal)) { case IPSEC_ID_IPV4_ADDR: local_filter_type = "IPv4 address"; net = decode_32 (idlocal + ISAKMP_ID_DATA_OFF); my_inet_ntop4 (&net, local_filter_addr_upper, sizeof local_filter_addr_upper - 1, 1); my_inet_ntop4 (&net, local_filter_addr_lower, sizeof local_filter_addr_upper - 1, 1); local_filter = strdup (local_filter_addr_upper); if (!local_filter) { log_error ("policy_callback: strdup (\"%s\") failed", local_filter_addr_upper); goto bad; } break; case IPSEC_ID_IPV4_RANGE: local_filter_type = "IPv4 range"; net = decode_32 (idlocal + ISAKMP_ID_DATA_OFF); my_inet_ntop4 (&net, local_filter_addr_lower, sizeof local_filter_addr_lower - 1, 1); net = decode_32 (idlocal + ISAKMP_ID_DATA_OFF + 4); my_inet_ntop4 (&net, local_filter_addr_upper, sizeof local_filter_addr_upper - 1, 1); len = strlen (local_filter_addr_upper) + strlen (local_filter_addr_lower) + 2; local_filter = calloc (len, sizeof (char)); if (!local_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (local_filter, local_filter_addr_lower, len); strlcat (local_filter, "-", len); strlcat (local_filter, local_filter_addr_upper, len); break; case IPSEC_ID_IPV4_ADDR_SUBNET: local_filter_type = "IPv4 subnet"; net = decode_32 (idlocal + ISAKMP_ID_DATA_OFF); subnet = decode_32 (idlocal + ISAKMP_ID_DATA_OFF + 4); net &= subnet; my_inet_ntop4 (&net, local_filter_addr_lower, sizeof local_filter_addr_lower - 1, 1); net |= ~subnet; my_inet_ntop4 (&net, local_filter_addr_upper, sizeof local_filter_addr_upper - 1, 1); len = strlen (local_filter_addr_upper) + strlen (local_filter_addr_lower) + 2; local_filter = calloc (len, sizeof (char)); if (!local_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (local_filter, local_filter_addr_lower, len); strlcat (local_filter, "-", len); strlcat (local_filter, local_filter_addr_upper, len); break; case IPSEC_ID_IPV6_ADDR: local_filter_type = "IPv6 address"; my_inet_ntop6 (idlocal + ISAKMP_ID_DATA_OFF, local_filter_addr_upper, sizeof local_filter_addr_upper - 1); strlcpy (local_filter_addr_lower, local_filter_addr_upper, sizeof local_filter_addr_lower); local_filter = strdup (local_filter_addr_upper); if (!local_filter) { log_error ("policy_callback: strdup (\"%s\") failed", local_filter_addr_upper); goto bad; } break; case IPSEC_ID_IPV6_RANGE: local_filter_type = "IPv6 range"; my_inet_ntop6 (idlocal + ISAKMP_ID_DATA_OFF, local_filter_addr_lower, sizeof local_filter_addr_lower - 1); my_inet_ntop6 (idlocal + ISAKMP_ID_DATA_OFF + 16, local_filter_addr_upper, sizeof local_filter_addr_upper - 1); len = strlen (local_filter_addr_upper) + strlen (local_filter_addr_lower) + 2; local_filter = calloc (len, sizeof (char)); if (!local_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (local_filter, local_filter_addr_lower, len); strlcat (local_filter, "-", len); strlcat (local_filter, local_filter_addr_upper, len); break; case IPSEC_ID_IPV6_ADDR_SUBNET: { struct in6_addr net, mask; local_filter_type = "IPv6 subnet"; bcopy (idlocal + ISAKMP_ID_DATA_OFF, &net, sizeof (net)); bcopy (idlocal + ISAKMP_ID_DATA_OFF + 16, &mask, sizeof (mask)); for (i = 0; i < 16; i++) net.s6_addr[i] &= mask.s6_addr[i]; my_inet_ntop6 ((char *) &net, local_filter_addr_lower, sizeof local_filter_addr_lower - 1); for (i = 0; i < 16; i++) net.s6_addr[i] |= ~mask.s6_addr[i]; my_inet_ntop6 ((char *) &net, local_filter_addr_upper, sizeof local_filter_addr_upper - 1); len = strlen (local_filter_addr_upper) + strlen (local_filter_addr_lower) + 2; local_filter = calloc (len, sizeof (char)); if (!local_filter) { log_error ("policy_callback: calloc (%d, %d) failed", len, sizeof (char)); goto bad; } strlcpy (local_filter, local_filter_addr_lower, len); strlcat (local_filter, "-", len); strlcat (local_filter, local_filter_addr_upper, len); break; } case IPSEC_ID_FQDN: local_filter_type = "FQDN"; local_filter = malloc (idlocalsz - ISAKMP_ID_DATA_OFF + 1); if (!local_filter) { log_error ("policy_callback: malloc (%d) failed", idlocalsz - ISAKMP_ID_DATA_OFF + 1); goto bad; } memcpy (local_filter, idlocal + ISAKMP_ID_DATA_OFF, idlocalsz - ISAKMP_ID_DATA_OFF); local_filter[idlocalsz - ISAKMP_ID_DATA_OFF] = '\0'; break; case IPSEC_ID_USER_FQDN: local_filter_type = "User FQDN"; local_filter = malloc (idlocalsz - ISAKMP_ID_DATA_OFF + 1); if (!local_filter) { log_error ("policy_callback: malloc (%d) failed", idlocalsz - ISAKMP_ID_DATA_OFF + 1); goto bad; } memcpy (local_filter, idlocal + ISAKMP_ID_DATA_OFF, idlocalsz - ISAKMP_ID_DATA_OFF); local_filter[idlocalsz - ISAKMP_ID_DATA_OFF] = '\0'; break; case IPSEC_ID_DER_ASN1_DN: local_filter_type = "ASN1 DN"; local_filter = x509_DN_string (idlocal + ISAKMP_ID_DATA_OFF, idlocalsz - ISAKMP_ID_DATA_OFF); if (!local_filter) { LOG_DBG ((LOG_POLICY, 50, "policy_callback: failed to decode name")); goto bad; } break; case IPSEC_ID_DER_ASN1_GN: /* XXX -- not sure what's in this. */ local_filter_type = "ASN1 GN"; break; case IPSEC_ID_KEY_ID: local_filter_type = "Key ID"; local_filter = calloc (2 * (idlocalsz - ISAKMP_ID_DATA_OFF) + 1, sizeof (char)); if (!local_filter) { log_error ("policy_callback: calloc (%d, %d) failed", 2 * (idlocalsz - ISAKMP_ID_DATA_OFF) + 1, sizeof (char)); goto bad; } /* Does it contain any non-printable characters ? */ for (i = 0; i < idlocalsz - ISAKMP_ID_DATA_OFF; i++) if (!isprint (*(idlocal + ISAKMP_ID_DATA_OFF + i))) break; if (i >= idlocalsz - ISAKMP_ID_DATA_OFF) { memcpy (local_filter, idlocal + ISAKMP_ID_DATA_OFF, idlocalsz - ISAKMP_ID_DATA_OFF); break; } /* Non-printable characters, convert to hex */ for (i = 0; i < idlocalsz - ISAKMP_ID_DATA_OFF; i++) { local_filter[2 * i] = hextab[*(idlocal + ISAKMP_ID_DATA_OFF) >> 4]; local_filter[2 * i + 1] = hextab[*(idlocal + ISAKMP_ID_DATA_OFF) & 0xF]; } break; default: log_print ("policy_callback: unknown Local ID type %u", GET_ISAKMP_ID_TYPE (idlocal)); goto bad; } switch (idlocal[ISAKMP_GEN_SZ + 1]) { case IPPROTO_TCP: local_filter_proto = "tcp"; break; case IPPROTO_UDP: local_filter_proto = "udp"; break; #ifdef IPPROTO_ETHERIP case IPPROTO_ETHERIP: local_filter_proto = "etherip"; break; #endif default: snprintf (local_filter_proto_num, 3, "%2d", idlocal[ISAKMP_GEN_SZ + 1]); local_filter_proto = local_filter_proto_num; break; } snprintf (local_filter_port, sizeof local_filter_port - 1, "%u", decode_16 (idlocal + ISAKMP_GEN_SZ + 2)); } else { policy_sa->transport->vtbl->get_src (policy_sa->transport, (struct sockaddr **)&sin); switch (sin->sa_family) { case AF_INET: local_filter_type = "IPv4 address"; break; case AF_INET6: local_filter_type = "IPv6 address"; break; default: log_print ("policy_callback: unsupported protocol family %d", sin->sa_family); goto bad; } if (sockaddr2text (sin, &addr, 1)) { log_error ("policy_callback: sockaddr2text failed"); goto bad; } memcpy (local_filter_addr_upper, addr, sizeof local_filter_addr_upper); memcpy (local_filter_addr_lower, addr, sizeof local_filter_addr_lower); free (addr); local_filter = strdup (local_filter_addr_upper); if (!local_filter) { log_error ("policy_callback: strdup (\"%s\") failed", local_filter_addr_upper); goto bad; } } LOG_DBG ((LOG_POLICY, 80, "Policy context (action attributes):")); LOG_DBG ((LOG_POLICY, 80, "esp_present == %s", esp_present)); LOG_DBG ((LOG_POLICY, 80, "ah_present == %s", ah_present)); LOG_DBG ((LOG_POLICY, 80, "comp_present == %s", comp_present)); LOG_DBG ((LOG_POLICY, 80, "ah_hash_alg == %s", ah_hash_alg)); LOG_DBG ((LOG_POLICY, 80, "esp_enc_alg == %s", esp_enc_alg)); LOG_DBG ((LOG_POLICY, 80, "comp_alg == %s", comp_alg)); LOG_DBG ((LOG_POLICY, 80, "ah_auth_alg == %s", ah_auth_alg)); LOG_DBG ((LOG_POLICY, 80, "esp_auth_alg == %s", esp_auth_alg)); LOG_DBG ((LOG_POLICY, 80, "ah_life_seconds == %s", ah_life_seconds)); LOG_DBG ((LOG_POLICY, 80, "ah_life_kbytes == %s", ah_life_kbytes)); LOG_DBG ((LOG_POLICY, 80, "esp_life_seconds == %s", esp_life_seconds)); LOG_DBG ((LOG_POLICY, 80, "esp_life_kbytes == %s", esp_life_kbytes)); LOG_DBG ((LOG_POLICY, 80, "comp_life_seconds == %s", comp_life_seconds)); LOG_DBG ((LOG_POLICY, 80, "comp_life_kbytes == %s", comp_life_kbytes)); LOG_DBG ((LOG_POLICY, 80, "ah_encapsulation == %s", ah_encapsulation)); LOG_DBG ((LOG_POLICY, 80, "esp_encapsulation == %s", esp_encapsulation)); LOG_DBG ((LOG_POLICY, 80, "comp_encapsulation == %s", comp_encapsulation)); LOG_DBG ((LOG_POLICY, 80, "comp_dict_size == %s", comp_dict_size)); LOG_DBG ((LOG_POLICY, 80, "comp_private_alg == %s", comp_private_alg)); LOG_DBG ((LOG_POLICY, 80, "ah_key_length == %s", ah_key_length)); LOG_DBG ((LOG_POLICY, 80, "ah_key_rounds == %s", ah_key_rounds)); LOG_DBG ((LOG_POLICY, 80, "esp_key_length == %s", esp_key_length)); LOG_DBG ((LOG_POLICY, 80, "esp_key_rounds == %s", esp_key_rounds)); LOG_DBG ((LOG_POLICY, 80, "ah_group_desc == %s", ah_group_desc)); LOG_DBG ((LOG_POLICY, 80, "esp_group_desc == %s", esp_group_desc)); LOG_DBG ((LOG_POLICY, 80, "comp_group_desc == %s", comp_group_desc)); LOG_DBG ((LOG_POLICY, 80, "remote_filter_type == %s", remote_filter_type)); LOG_DBG ((LOG_POLICY, 80, "remote_filter_addr_upper == %s", remote_filter_addr_upper)); LOG_DBG ((LOG_POLICY, 80, "remote_filter_addr_lower == %s", remote_filter_addr_lower)); LOG_DBG ((LOG_POLICY, 80, "remote_filter == %s", (remote_filter ? remote_filter : ""))); LOG_DBG ((LOG_POLICY, 80, "remote_filter_port == %s", remote_filter_port)); LOG_DBG ((LOG_POLICY, 80, "remote_filter_proto == %s", remote_filter_proto)); LOG_DBG ((LOG_POLICY, 80, "local_filter_type == %s", local_filter_type)); LOG_DBG ((LOG_POLICY, 80, "local_filter_addr_upper == %s", local_filter_addr_upper)); LOG_DBG ((LOG_POLICY, 80, "local_filter_addr_lower == %s", local_filter_addr_lower)); LOG_DBG ((LOG_POLICY, 80, "local_filter == %s", (local_filter ? local_filter : ""))); LOG_DBG ((LOG_POLICY, 80, "local_filter_port == %s", local_filter_port)); LOG_DBG ((LOG_POLICY, 80, "local_filter_proto == %s", local_filter_proto)); LOG_DBG ((LOG_POLICY, 80, "remote_id_type == %s", remote_id_type)); LOG_DBG ((LOG_POLICY, 80, "remote_id_addr_upper == %s", remote_id_addr_upper)); LOG_DBG ((LOG_POLICY, 80, "remote_id_addr_lower == %s", remote_id_addr_lower)); LOG_DBG ((LOG_POLICY, 80, "remote_id == %s", (remote_id ? remote_id : ""))); LOG_DBG ((LOG_POLICY, 80, "remote_id_port == %s", remote_id_port)); LOG_DBG ((LOG_POLICY, 80, "remote_id_proto == %s", remote_id_proto)); LOG_DBG ((LOG_POLICY, 80, "remote_negotiation_address == %s", remote_ike_address)); LOG_DBG ((LOG_POLICY, 80, "local_negotiation_address == %s", local_ike_address)); LOG_DBG ((LOG_POLICY, 80, "pfs == %s", pfs)); LOG_DBG ((LOG_POLICY, 80, "initiator == %s", initiator)); LOG_DBG ((LOG_POLICY, 80, "phase1_group_desc == %s", phase1_group)); /* Unset dirty now. */ dirty = 0; } if (strcmp (name, "phase_1") == 0) return phase_1; if (strcmp (name, "GMTTimeOfDay") == 0) { tt = time ((time_t) NULL); strftime (mytimeofday, 14, "%Y%m%d%H%M%S", gmtime (&tt)); return mytimeofday; } if (strcmp (name, "LocalTimeOfDay") == 0) { tt = time ((time_t) NULL); strftime (mytimeofday, 14, "%Y%m%d%H%M%S", localtime (&tt)); return mytimeofday; } if (strcmp (name, "initiator") == 0) return initiator; if (strcmp (name, "pfs") == 0) return pfs; if (strcmp (name, "app_domain") == 0) return "IPsec policy"; if (strcmp (name, "doi") == 0) return "ipsec"; if (strcmp (name, "esp_present") == 0) return esp_present; if (strcmp (name, "ah_present") == 0) return ah_present; if (strcmp (name, "comp_present") == 0) return comp_present; if (strcmp (name, "ah_hash_alg") == 0) return ah_hash_alg; if (strcmp (name, "ah_auth_alg") == 0) return ah_auth_alg; if (strcmp (name, "esp_auth_alg") == 0) return esp_auth_alg; if (strcmp (name, "esp_enc_alg") == 0) return esp_enc_alg; if (strcmp (name, "comp_alg") == 0) return comp_alg; if (strcmp (name, "ah_life_kbytes") == 0) return ah_life_kbytes; if (strcmp (name, "ah_life_seconds") == 0) return ah_life_seconds; if (strcmp (name, "esp_life_kbytes") == 0) return esp_life_kbytes; if (strcmp (name, "esp_life_seconds") == 0) return esp_life_seconds; if (strcmp (name, "comp_life_kbytes") == 0) return comp_life_kbytes; if (strcmp (name, "comp_life_seconds") == 0) return comp_life_seconds; if (strcmp (name, "ah_encapsulation") == 0) return ah_encapsulation; if (strcmp (name, "esp_encapsulation") == 0) return esp_encapsulation; if (strcmp (name, "comp_encapsulation") == 0) return comp_encapsulation; if (strcmp (name, "ah_key_length") == 0) return ah_key_length; if (strcmp (name, "ah_key_rounds") == 0) return ah_key_rounds; if (strcmp (name, "esp_key_length") == 0) return esp_key_length; if (strcmp (name, "esp_key_rounds") == 0) return esp_key_rounds; if (strcmp (name, "comp_dict_size") == 0) return comp_dict_size; if (strcmp (name, "comp_private_alg") == 0) return comp_private_alg; if (strcmp (name, "remote_filter_type") == 0) return remote_filter_type; if (strcmp (name, "remote_filter") == 0) return (remote_filter ? remote_filter : ""); if (strcmp (name, "remote_filter_addr_upper") == 0) return remote_filter_addr_upper; if (strcmp (name, "remote_filter_addr_lower") == 0) return remote_filter_addr_lower; if (strcmp (name, "remote_filter_port") == 0) return remote_filter_port; if (strcmp (name, "remote_filter_proto") == 0) return remote_filter_proto; if (strcmp (name, "local_filter_type") == 0) return local_filter_type; if (strcmp (name, "local_filter") == 0) return (local_filter ? local_filter : ""); if (strcmp (name, "local_filter_addr_upper") == 0) return local_filter_addr_upper; if (strcmp (name, "local_filter_addr_lower") == 0) return local_filter_addr_lower; if (strcmp (name, "local_filter_port") == 0) return local_filter_port; if (strcmp (name, "local_filter_proto") == 0) return local_filter_proto; if (strcmp (name, "remote_ike_address") == 0) return remote_ike_address; if (strcmp (name, "remote_negotiation_address") == 0) return remote_ike_address; if (strcmp (name, "local_ike_address") == 0) return local_ike_address; if (strcmp (name, "local_negotiation_address") == 0) return local_ike_address; if (strcmp (name, "remote_id_type") == 0) return remote_id_type; if (strcmp (name, "remote_id") == 0) return (remote_id ? remote_id : ""); if (strcmp (name, "remote_id_addr_upper") == 0) return remote_id_addr_upper; if (strcmp (name, "remote_id_addr_lower") == 0) return remote_id_addr_lower; if (strcmp (name, "remote_id_port") == 0) return remote_id_port; if (strcmp (name, "remote_id_proto") == 0) return remote_id_proto; if (strcmp (name, "phase1_group_desc") == 0) return phase1_group; if (strcmp (name, "esp_group_desc") == 0) return esp_group_desc; if (strcmp (name, "ah_group_desc") == 0) return ah_group_desc; if (strcmp (name, "comp_group_desc") == 0) return comp_group_desc; return ""; bad: policy_callback (KEYNOTE_CALLBACK_INITIALIZE); return ""; } void policy_init (void) { char *ptr, *policy_file; char **asserts; off_t sz; int fd, len, i; LOG_DBG ((LOG_POLICY, 30, "policy_init: initializing")); #if defined (HAVE_DLOPEN) && !defined (USE_KEYNOTE) if (!dyn_load (libkeynote_script)) return; #endif /* Get policy file from configuration. */ policy_file = conf_get_str ("General", "Policy-file"); if (!policy_file) policy_file = POLICY_FILE_DEFAULT; /* Check file modes and collect file size */ if (check_file_secrecy (policy_file, &sz)) log_fatal ("policy_init: cannot read %s", policy_file); /* Open policy file. */ fd = open (policy_file, O_RDONLY); if (fd == -1) log_fatal ("policy_init: open (\"%s\", O_RDONLY) failed", policy_file); /* Allocate memory to keep policies. */ ptr = calloc (sz + 1, sizeof (char)); if (!ptr) log_fatal ("policy_init: calloc (%d, %d) failed", sz + 1, sizeof (char)); /* Just in case there are short reads... */ for (len = 0; len < sz; len += i) { i = read (fd, ptr + len, sz - len); if (i == -1) log_fatal ("policy_init: read (%d, %p, %d) failed", fd, ptr + len, sz - len); } /* We're done with this. */ close (fd); /* Parse buffer, break up into individual policies. */ asserts = LK (kn_read_asserts, (ptr, sz, &i)); /* Begone! */ free (ptr); if (asserts == (char **) NULL) log_print ("policy_init: all policies flushed"); /* Cleanup */ if (keynote_policy_asserts) { for (fd = 0; fd < keynote_policy_asserts_num; fd++) if (keynote_policy_asserts && keynote_policy_asserts[fd]) free (keynote_policy_asserts[fd]); free (keynote_policy_asserts); } keynote_policy_asserts = asserts; keynote_policy_asserts_num = i; } /* Nothing needed for initialization */ int keynote_cert_init (void) { return 1; } /* Just copy and return. */ void * keynote_cert_get (u_int8_t *data, u_int32_t len) { char *foo = malloc (len + 1); if (foo == NULL) return NULL; memcpy (foo, data, len); foo[len] = '\0'; return foo; } /* * We just verify the signature on the credentials. * On signature failure, just drop the whole payload. */ int keynote_cert_validate (void *scert) { char **foo; int num, i; if (scert == NULL) return 0; foo = LK (kn_read_asserts, ((char *) scert, strlen ((char *) scert), &num)); if (foo == NULL) return 0; for (i = 0; i < num; i++) { if (LK (kn_verify_assertion, (scert, strlen ((char *) scert))) != SIGRESULT_TRUE) { for (; i < num; i++) free (foo[i]); free (foo); return 0; } free (foo[i]); } free (foo); return 1; } /* Add received credentials. */ int keynote_cert_insert (int sid, void *scert) { char **foo; int num; if (scert == NULL) return 0; foo = LK (kn_read_asserts, ((char *) scert, strlen ((char *) scert), &num)); if (foo == NULL) return 0; while (num--) LK (kn_add_assertion, (sid, foo[num], strlen (foo[num]), 0)); return 1; } /* Just regular memory free. */ void keynote_cert_free (void *cert) { free (cert); } /* Verify that the key given to us is valid. */ int keynote_certreq_validate (u_int8_t *data, u_int32_t len) { struct keynote_deckey dc; int err = 1; char *dat; dat = calloc (len + 1, sizeof (char)); if (!dat) { log_error ("keynote_certreq_validate: calloc (%d, %d) failed", len + 1, sizeof (char)); return 0; } memcpy (dat, data, len); if (LK (kn_decode_key, (&dc, dat, KEYNOTE_PUBLIC_KEY)) != 0) err = 0; else LK (kn_free_key, (&dc)); free (dat); return err; } /* Beats me what we should be doing with this. */ void * keynote_certreq_decode (u_int8_t *data, u_int32_t len) { /* XXX */ return NULL; } void keynote_free_aca (void *blob) { /* XXX */ } int keynote_cert_obtain (u_int8_t *id, size_t id_len, void *data, u_int8_t **cert, u_int32_t *certlen) { char *dirname, *file, *addr_str; struct stat sb; int idtype, fd, len; if (!id) { log_print ("keynote_cert_obtain: ID is missing"); return 0; } /* Get type of ID. */ idtype = id[0]; id += ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ; id_len -= ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ; dirname = conf_get_str ("KeyNote", "Credential-directory"); if (!dirname) { LOG_DBG ((LOG_POLICY, 30, "keynote_cert_obtain: no Credential-directory")); return 0; } len = strlen (dirname) + strlen (CREDENTIAL_FILE) + 3; switch (idtype) { case IPSEC_ID_IPV4_ADDR: case IPSEC_ID_IPV6_ADDR: util_ntoa (&addr_str, idtype == IPSEC_ID_IPV4_ADDR ? AF_INET : AF_INET6, id); if (addr_str == 0) return 0; file = calloc (len + strlen (addr_str), sizeof (char)); if (file == NULL) { log_error ("keynote_cert_obtain: failed to allocate %d bytes", len + strlen (addr_str)); free (addr_str); return 0; } snprintf (file, len + strlen (addr_str), "%s/%s/%s", dirname, addr_str, CREDENTIAL_FILE); free (addr_str); break; case IPSEC_ID_FQDN: case IPSEC_ID_USER_FQDN: { file = calloc (len + id_len, sizeof (char)); if (file == NULL) { log_error ("keynote_cert_obtain: failed to allocate %d bytes", len + id_len); return 0; } snprintf (file, len + id_len, "%s/", dirname); memcpy (file + strlen (dirname) + 1, id, id_len); snprintf (file + strlen (dirname) + 1 + id_len, len - strlen (dirname) - 1, "/%s", CREDENTIAL_FILE); break; } default: return 0; } if (stat (file, &sb) < 0) { LOG_DBG ((LOG_POLICY, 30, "keynote_cert_obtain: failed to stat \"%s\"", file)); free (file); return 0; } *cert = calloc (sb.st_size + 1, sizeof (char)); if (*cert == NULL) { log_error ("keynote_cert_obtain: failed to allocate %d bytes", sb.st_size); free (file); return 0; } fd = open (file, O_RDONLY, 0); if (fd < 0) { LOG_DBG ((LOG_POLICY, 30, "keynote_cert_obtain: failed to open \"%s\"", file)); free (file); return 0; } if (read (fd, *cert, sb.st_size) != sb.st_size) { LOG_DBG ((LOG_POLICY, 30, "keynote_cert_obtain: failed to read %d " "bytes from \"%s\"", sb.st_size, file)); free (file); close (fd); return 0; } close (fd); free (file); *certlen = sb.st_size; return 1; } /* This should never be called. */ int keynote_cert_get_subjects (void *scert, int *n, u_int8_t ***id, u_int32_t **id_len) { return 0; } /* Get the authorizer key. */ int keynote_cert_get_key (void *scert, void *keyp) { struct keynote_keylist *kl; int sid, kid, num; char **foo; foo = LK (kn_read_asserts, ((char *)scert, strlen ((char *)scert), &num)); if (foo == NULL || num == 0) { log_print ("keynote_cert_get_key: failed to decompose credentials"); return 0; } kid = LK (kn_init, ()); if (kid == -1) { log_print ("keynote_cert_get_key: failed to initialize new policy " "session"); while (num--) free (foo[num]); free (foo); return 0; } sid = LK (kn_add_assertion, (kid, foo[num - 1], strlen (foo[num - 1]), 0)); while (num--) free (foo[num]); free (foo); if (sid == -1) { log_print ("keynote_cert_get_key: failed to add assertion"); LK (kn_close, (kid)); return 0; } *(RSA **)keyp = NULL; kl = LK (kn_get_licensees, (kid, sid)); while (kl) { if (kl->key_alg == KEYNOTE_ALGORITHM_RSA) { *(RSA **)keyp = LC (RSAPublicKey_dup, (kl->key_key)); break; } kl = kl->key_next; } LK (kn_remove_assertion, (kid, sid)); LK (kn_close, (kid)); return *(RSA **)keyp == NULL ? 0 : 1; } void * keynote_cert_dup (void *cert) { return strdup((char *)cert); } void keynote_serialize (void *cert, u_int8_t **data, u_int32_t *datalen) { *datalen = strlen ((char *)cert) + 1; *data = strdup (cert); /* So we allocate an extra character at the end... */ if (*data == NULL) log_error ("keynote_serialize: malloc (%d) failed", *datalen); } /* From cert to printable */ char * keynote_printable (void *cert) { return strdup ((char *)cert); } /* From printable to cert */ void * keynote_from_printable (char *cert) { return strdup (cert); }