/* $OpenBSD: snmpe.c,v 1.54 2018/07/31 11:01:29 claudio Exp $ */ /* * Copyright (c) 2007, 2008, 2012 Reyk Floeter * Copyright (c) 2017 Marco Pfatschbacher * * Permission to use, copy, modify, and distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR * ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN * ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF * OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "snmpd.h" #include "mib.h" void snmpe_init(struct privsep *, struct privsep_proc *, void *); int snmpe_parse(struct snmp_message *); void snmpe_tryparse(int, struct snmp_message *); int snmpe_parsevarbinds(struct snmp_message *); void snmpe_response(struct snmp_message *); void snmpe_sig_handler(int sig, short, void *); int snmpe_dispatch_parent(int, struct privsep_proc *, struct imsg *); int snmpe_bind(struct address *); void snmpe_recvmsg(int fd, short, void *); void snmpe_readcb(int fd, short, void *); void snmpe_writecb(int fd, short, void *); void snmpe_acceptcb(int fd, short, void *); void snmpe_prepare_read(struct snmp_message *, int); int snmpe_encode(struct snmp_message *); void snmp_msgfree(struct snmp_message *); struct imsgev *iev_parent; static const struct timeval snmpe_tcp_timeout = { 10, 0 }; /* 10s */ static struct privsep_proc procs[] = { { "parent", PROC_PARENT, snmpe_dispatch_parent } }; void snmpe(struct privsep *ps, struct privsep_proc *p) { struct snmpd *env = ps->ps_env; struct address *h; struct listen_sock *so; #ifdef DEBUG char buf[BUFSIZ]; struct oid *oid; #endif #ifdef DEBUG for (oid = NULL; (oid = smi_foreach(oid, 0)) != NULL;) { smi_oid2string(&oid->o_id, buf, sizeof(buf), 0); log_debug("oid %s", buf); } #endif /* bind SNMP UDP/TCP sockets */ TAILQ_FOREACH(h, &env->sc_addresses, entry) { if ((so = calloc(1, sizeof(*so))) == NULL) fatal("snmpe: %s", __func__); if ((so->s_fd = snmpe_bind(h)) == -1) fatal("snmpe: failed to bind SNMP socket"); so->s_ipproto = h->ipproto; TAILQ_INSERT_TAIL(&env->sc_sockets, so, entry); } proc_run(ps, p, procs, nitems(procs), snmpe_init, NULL); } /* ARGSUSED */ void snmpe_init(struct privsep *ps, struct privsep_proc *p, void *arg) { struct snmpd *env = ps->ps_env; struct listen_sock *so; kr_init(); trap_init(); timer_init(); usm_generate_keys(); /* listen for incoming SNMP UDP/TCP messages */ TAILQ_FOREACH(so, &env->sc_sockets, entry) { if (so->s_ipproto == IPPROTO_TCP) { if (listen(so->s_fd, 5) < 0) fatalx("snmpe: failed to listen on socket"); event_set(&so->s_ev, so->s_fd, EV_READ, snmpe_acceptcb, so); evtimer_set(&so->s_evt, snmpe_acceptcb, so); } else { event_set(&so->s_ev, so->s_fd, EV_READ|EV_PERSIST, snmpe_recvmsg, env); } event_add(&so->s_ev, NULL); } #if 0 /* * XXX Refactoring required to move illegal ioctls and sysctls. * XXX See mps_* and if_mib in mib.c, etc. */ BROKEN if (pledge("stdio inet route recvfd vminfo", NULL) == -1) fatal("pledge"); #endif } void snmpe_shutdown(void) { struct listen_sock *so; TAILQ_FOREACH(so, &snmpd_env->sc_sockets, entry) { event_del(&so->s_ev); if (so->s_ipproto == IPPROTO_TCP) event_del(&so->s_evt); close(so->s_fd); } kr_shutdown(); } int snmpe_dispatch_parent(int fd, struct privsep_proc *p, struct imsg *imsg) { switch (imsg->hdr.type) { default: break; } return (-1); } int snmpe_bind(struct address *addr) { char buf[512]; int val, s; if ((s = snmpd_socket_af(&addr->ss, htons(addr->port), addr->ipproto)) == -1) return (-1); /* * Socket options */ if (fcntl(s, F_SETFL, O_NONBLOCK) == -1) goto bad; if (addr->ipproto == IPPROTO_TCP) { val = 1; if (setsockopt(s, SOL_SOCKET, SO_REUSEADDR, &val, sizeof(val)) == -1) fatal("setsockopt SO_REUSEADDR"); } else { /* UDP */ switch (addr->ss.ss_family) { case AF_INET: val = 1; if (setsockopt(s, IPPROTO_IP, IP_RECVDSTADDR, &val, sizeof(int)) == -1) { log_warn("%s: failed to set IPv4 packet info", __func__); goto bad; } break; case AF_INET6: val = 1; if (setsockopt(s, IPPROTO_IPV6, IPV6_RECVPKTINFO, &val, sizeof(int)) == -1) { log_warn("%s: failed to set IPv6 packet info", __func__); goto bad; } } } if (bind(s, (struct sockaddr *)&addr->ss, addr->ss.ss_len) == -1) goto bad; if (print_host(&addr->ss, buf, sizeof(buf)) == NULL) goto bad; log_info("snmpe: listening on %s %s:%d", (addr->ipproto == IPPROTO_TCP) ? "tcp" : "udp", buf, addr->port); return (s); bad: close(s); return (-1); } int snmpe_parse(struct snmp_message *msg) { struct snmpd *env = snmpd_env; struct snmp_stats *stats = &env->sc_stats; struct ber_element *a; long long ver, req; long long errval, erridx; unsigned int type; u_int class; char *comn; char *flagstr, *ctxname; size_t len; struct sockaddr_storage *ss = &msg->sm_ss; struct ber_element *root = msg->sm_req; msg->sm_errstr = "invalid message"; if (ber_scanf_elements(root, "{ie", &ver, &a) != 0) goto parsefail; /* SNMP version and community */ msg->sm_version = ver; switch (msg->sm_version) { case SNMP_V1: case SNMP_V2: if (env->sc_min_seclevel != 0) goto badversion; if (ber_scanf_elements(a, "se", &comn, &msg->sm_pdu) != 0) goto parsefail; if (strlcpy(msg->sm_community, comn, sizeof(msg->sm_community)) >= sizeof(msg->sm_community)) { stats->snmp_inbadcommunitynames++; msg->sm_errstr = "community name too long"; goto fail; } break; case SNMP_V3: if (ber_scanf_elements(a, "{iisi}e", &msg->sm_msgid, &msg->sm_max_msg_size, &flagstr, &msg->sm_secmodel, &a) != 0) goto parsefail; msg->sm_flags = *flagstr; if (MSG_SECLEVEL(msg) < env->sc_min_seclevel || msg->sm_secmodel != SNMP_SEC_USM) { /* XXX currently only USM supported */ msg->sm_errstr = "unsupported security model"; stats->snmp_usmbadseclevel++; msg->sm_usmerr = OIDVAL_usmErrSecLevel; goto parsefail; } if ((a = usm_decode(msg, a, &msg->sm_errstr)) == NULL) goto parsefail; if (ber_scanf_elements(a, "{xxe", &msg->sm_ctxengineid, &msg->sm_ctxengineid_len, &ctxname, &len, &msg->sm_pdu) != 0) goto parsefail; if (len > SNMPD_MAXCONTEXNAMELEN) goto parsefail; memcpy(msg->sm_ctxname, ctxname, len); msg->sm_ctxname[len] = '\0'; break; default: badversion: stats->snmp_inbadversions++; msg->sm_errstr = "bad snmp version"; goto fail; } if (ber_scanf_elements(msg->sm_pdu, "t{e", &class, &type, &a) != 0) goto parsefail; /* SNMP PDU context */ if (class != BER_CLASS_CONTEXT) goto parsefail; switch (type) { case SNMP_C_GETBULKREQ: if (msg->sm_version == SNMP_V1) { stats->snmp_inbadversions++; msg->sm_errstr = "invalid request for protocol version 1"; goto fail; } /* FALLTHROUGH */ case SNMP_C_GETREQ: stats->snmp_ingetrequests++; /* FALLTHROUGH */ case SNMP_C_GETNEXTREQ: if (type == SNMP_C_GETNEXTREQ) stats->snmp_ingetnexts++; if (msg->sm_version != SNMP_V3 && strcmp(env->sc_rdcommunity, msg->sm_community) != 0 && strcmp(env->sc_rwcommunity, msg->sm_community) != 0) { stats->snmp_inbadcommunitynames++; msg->sm_errstr = "wrong read community"; goto fail; } msg->sm_context = type; break; case SNMP_C_SETREQ: stats->snmp_insetrequests++; if (msg->sm_version != SNMP_V3 && strcmp(env->sc_rwcommunity, msg->sm_community) != 0) { if (strcmp(env->sc_rdcommunity, msg->sm_community) != 0) stats->snmp_inbadcommunitynames++; else stats->snmp_inbadcommunityuses++; msg->sm_errstr = "wrong write community"; goto fail; } msg->sm_context = type; break; case SNMP_C_GETRESP: stats->snmp_ingetresponses++; msg->sm_errstr = "response without request"; goto parsefail; case SNMP_C_TRAP: case SNMP_C_TRAPV2: if (msg->sm_version != SNMP_V3 && strcmp(env->sc_trcommunity, msg->sm_community) != 0) { stats->snmp_inbadcommunitynames++; msg->sm_errstr = "wrong trap community"; goto fail; } stats->snmp_intraps++; msg->sm_errstr = "received trap"; goto fail; default: msg->sm_errstr = "invalid context"; goto parsefail; } /* SNMP PDU */ if (ber_scanf_elements(a, "iiie{et", &req, &errval, &erridx, &msg->sm_pduend, &msg->sm_varbind, &class, &type) != 0) { stats->snmp_silentdrops++; msg->sm_errstr = "invalid PDU"; goto fail; } if (class != BER_CLASS_UNIVERSAL || type != BER_TYPE_SEQUENCE) { stats->snmp_silentdrops++; msg->sm_errstr = "invalid varbind"; goto fail; } msg->sm_request = req; msg->sm_error = errval; msg->sm_errorindex = erridx; print_host(ss, msg->sm_host, sizeof(msg->sm_host)); if (msg->sm_version == SNMP_V3) log_debug("%s: %s: SNMPv3 context %d, flags %#x, " "secmodel %lld, user '%s', ctx-engine %s, ctx-name '%s', " "request %lld", __func__, msg->sm_host, msg->sm_context, msg->sm_flags, msg->sm_secmodel, msg->sm_username, tohexstr(msg->sm_ctxengineid, msg->sm_ctxengineid_len), msg->sm_ctxname, msg->sm_request); else log_debug("%s: %s: SNMPv%d '%s' context %d request %lld", __func__, msg->sm_host, msg->sm_version + 1, msg->sm_community, msg->sm_context, msg->sm_request); return (0); parsefail: stats->snmp_inasnparseerrs++; fail: print_host(ss, msg->sm_host, sizeof(msg->sm_host)); log_debug("%s: %s: %s", __func__, msg->sm_host, msg->sm_errstr); return (-1); } int snmpe_parsevarbinds(struct snmp_message *msg) { struct snmp_stats *stats = &snmpd_env->sc_stats; char buf[BUFSIZ]; struct ber_oid o; int ret = 0; msg->sm_errstr = "invalid varbind element"; if (msg->sm_i == 0) { msg->sm_i = 1; msg->sm_a = msg->sm_varbind; msg->sm_last = NULL; } for (; msg->sm_a != NULL && msg->sm_i < SNMPD_MAXVARBIND; msg->sm_a = msg->sm_next, msg->sm_i++) { msg->sm_next = msg->sm_a->be_next; if (msg->sm_a->be_class != BER_CLASS_UNIVERSAL || msg->sm_a->be_type != BER_TYPE_SEQUENCE) continue; if ((msg->sm_b = msg->sm_a->be_sub) == NULL) continue; for (msg->sm_state = 0; msg->sm_state < 2 && msg->sm_b != NULL; msg->sm_b = msg->sm_b->be_next) { switch (msg->sm_state++) { case 0: if (ber_get_oid(msg->sm_b, &o) != 0) goto varfail; if (o.bo_n < BER_MIN_OID_LEN || o.bo_n > BER_MAX_OID_LEN) goto varfail; if (msg->sm_context == SNMP_C_SETREQ) stats->snmp_intotalsetvars++; else stats->snmp_intotalreqvars++; log_debug("%s: %s: oid %s", __func__, msg->sm_host, smi_oid2string(&o, buf, sizeof(buf), 0)); break; case 1: msg->sm_c = NULL; msg->sm_end = NULL; switch (msg->sm_context) { case SNMP_C_GETNEXTREQ: msg->sm_c = ber_add_sequence(NULL); ret = mps_getnextreq(msg, msg->sm_c, &o); if (ret == 0 || ret == 1) break; ber_free_elements(msg->sm_c); msg->sm_error = SNMP_ERROR_NOSUCHNAME; goto varfail; case SNMP_C_GETREQ: msg->sm_c = ber_add_sequence(NULL); ret = mps_getreq(msg, msg->sm_c, &o, msg->sm_version); if (ret == 0 || ret == 1) break; msg->sm_error = SNMP_ERROR_NOSUCHNAME; ber_free_elements(msg->sm_c); goto varfail; case SNMP_C_SETREQ: if (snmpd_env->sc_readonly == 0) { ret = mps_setreq(msg, msg->sm_b, &o); if (ret == 0) break; } msg->sm_error = SNMP_ERROR_READONLY; goto varfail; case SNMP_C_GETBULKREQ: ret = mps_getbulkreq(msg, &msg->sm_c, &msg->sm_end, &o, (msg->sm_i <= msg->sm_nonrepeaters) ? 1 : msg->sm_maxrepetitions); if (ret == 0 || ret == 1) break; msg->sm_error = SNMP_ERROR_NOSUCHNAME; goto varfail; default: goto varfail; } if (msg->sm_c == NULL) break; if (msg->sm_end == NULL) msg->sm_end = msg->sm_c; if (msg->sm_last == NULL) msg->sm_varbindresp = msg->sm_c; else ber_link_elements(msg->sm_last, msg->sm_c); msg->sm_last = msg->sm_end; break; } } if (msg->sm_state < 2) { log_debug("%s: state %d", __func__, msg->sm_state); goto varfail; } } msg->sm_errstr = "none"; msg->sm_error = 0; msg->sm_errorindex = 0; return (ret); varfail: log_debug("%s: %s: %s, error index %d", __func__, msg->sm_host, msg->sm_errstr, msg->sm_i); if (msg->sm_error == 0) msg->sm_error = SNMP_ERROR_GENERR; msg->sm_errorindex = msg->sm_i; return (-1); } void snmpe_acceptcb(int fd, short type, void *arg) { struct listen_sock *so = arg; struct sockaddr_storage ss; socklen_t len = sizeof(ss); struct snmp_message *msg; int afd; event_add(&so->s_ev, NULL); if ((type & EV_TIMEOUT)) return; if ((afd = accept4(fd, (struct sockaddr *)&ss, &len, SOCK_NONBLOCK|SOCK_CLOEXEC)) < 0) { /* Pause accept if we are out of file descriptors */ if (errno == ENFILE || errno == EMFILE) { struct timeval evtpause = { 1, 0 }; event_del(&so->s_ev); evtimer_add(&so->s_evt, &evtpause); } else if (errno != EAGAIN && errno != EINTR) log_debug("%s: accept4", __func__); return; } if ((msg = calloc(1, sizeof(*msg))) == NULL) goto fail; snmpe_prepare_read(msg, afd); return; fail: free(msg); close(afd); return; } void snmpe_prepare_read(struct snmp_message *msg, int fd) { msg->sm_sock = fd; msg->sm_sock_tcp = 1; event_del(&msg->sm_sockev); event_set(&msg->sm_sockev, fd, EV_READ, snmpe_readcb, msg); event_add(&msg->sm_sockev, &snmpe_tcp_timeout); } void snmpe_tryparse(int fd, struct snmp_message *msg) { struct snmp_stats *stats = &snmpd_env->sc_stats; ber_set_application(&msg->sm_ber, smi_application); ber_set_readbuf(&msg->sm_ber, msg->sm_data, msg->sm_datalen); msg->sm_req = ber_read_elements(&msg->sm_ber, NULL); if (msg->sm_req == NULL) { if (errno == ECANCELED) { /* short read; try again */ snmpe_prepare_read(msg, fd); return; } goto fail; } if (snmpe_parse(msg) == -1) { if (msg->sm_usmerr && MSG_REPORT(msg)) { usm_make_report(msg); snmpe_response(msg); return; } else goto fail; } stats->snmp_inpkts++; snmpe_dispatchmsg(msg); return; fail: snmp_msgfree(msg); close(fd); } void snmpe_readcb(int fd, short type, void *arg) { struct snmp_message *msg = arg; ssize_t len; if (type == EV_TIMEOUT || msg->sm_datalen >= sizeof(msg->sm_data)) goto fail; len = read(fd, msg->sm_data + msg->sm_datalen, sizeof(msg->sm_data) - msg->sm_datalen); if (len <= 0) { if (errno != EAGAIN && errno != EINTR) goto fail; snmpe_prepare_read(msg, fd); return; } msg->sm_datalen += (size_t)len; snmpe_tryparse(fd, msg); return; fail: snmp_msgfree(msg); close(fd); } void snmpe_writecb(int fd, short type, void *arg) { struct snmp_stats *stats = &snmpd_env->sc_stats; struct snmp_message *msg = arg; struct snmp_message *nmsg; ssize_t len; size_t reqlen; struct ber *ber = &msg->sm_ber; if (type == EV_TIMEOUT) goto fail; len = ber->br_wend - ber->br_wbuf; ber->br_wptr = ber->br_wbuf; log_debug("%s: write fd %d len %zd", __func__, fd, len); len = write(fd, ber->br_wptr, len); if (len == -1) { if (errno == EAGAIN || errno == EINTR) return; else goto fail; } ber->br_wptr += len; if (ber->br_wptr < ber->br_wend) { event_del(&msg->sm_sockev); event_set(&msg->sm_sockev, msg->sm_sock, EV_WRITE, snmpe_writecb, msg); event_add(&msg->sm_sockev, &snmpe_tcp_timeout); return; } stats->snmp_outpkts++; if ((nmsg = calloc(1, sizeof(*nmsg))) == NULL) goto fail; /* * Reuse the connection. * In case we already read data of the next message, copy it over. */ reqlen = ber_calc_len(msg->sm_req); if (msg->sm_datalen > reqlen) { memcpy(nmsg->sm_data, msg->sm_data + reqlen, msg->sm_datalen - reqlen); nmsg->sm_datalen = msg->sm_datalen - reqlen; snmp_msgfree(msg); snmpe_prepare_read(nmsg, fd); snmpe_tryparse(fd, nmsg); } else { snmp_msgfree(msg); snmpe_prepare_read(nmsg, fd); } return; fail: close(fd); snmp_msgfree(msg); } void snmpe_recvmsg(int fd, short sig, void *arg) { struct snmpd *env = arg; struct snmp_stats *stats = &env->sc_stats; ssize_t len; struct snmp_message *msg; if ((msg = calloc(1, sizeof(*msg))) == NULL) return; msg->sm_sock = fd; msg->sm_slen = sizeof(msg->sm_ss); if ((len = recvfromto(fd, msg->sm_data, sizeof(msg->sm_data), 0, (struct sockaddr *)&msg->sm_ss, &msg->sm_slen, (struct sockaddr *)&msg->sm_local_ss, &msg->sm_local_slen)) < 1) { free(msg); return; } stats->snmp_inpkts++; msg->sm_datalen = (size_t)len; bzero(&msg->sm_ber, sizeof(msg->sm_ber)); ber_set_application(&msg->sm_ber, smi_application); ber_set_readbuf(&msg->sm_ber, msg->sm_data, msg->sm_datalen); msg->sm_req = ber_read_elements(&msg->sm_ber, NULL); if (msg->sm_req == NULL) { stats->snmp_inasnparseerrs++; snmp_msgfree(msg); return; } #ifdef DEBUG fprintf(stderr, "recv msg:\n"); smi_debug_elements(msg->sm_req); #endif if (snmpe_parse(msg) == -1) { if (msg->sm_usmerr != 0 && MSG_REPORT(msg)) { usm_make_report(msg); snmpe_response(msg); return; } else { snmp_msgfree(msg); return; } } snmpe_dispatchmsg(msg); } void snmpe_dispatchmsg(struct snmp_message *msg) { /* dispatched to subagent */ if (snmpe_parsevarbinds(msg) == 1) return; /* respond directly */ msg->sm_context = SNMP_C_GETRESP; snmpe_response(msg); } void snmpe_response(struct snmp_message *msg) { struct snmp_stats *stats = &snmpd_env->sc_stats; u_int8_t *ptr = NULL; ssize_t len; if (msg->sm_varbindresp == NULL && msg->sm_pduend != NULL) msg->sm_varbindresp = ber_unlink_elements(msg->sm_pduend); switch (msg->sm_error) { case SNMP_ERROR_TOOBIG: stats->snmp_intoobigs++; break; case SNMP_ERROR_NOSUCHNAME: stats->snmp_innosuchnames++; break; case SNMP_ERROR_BADVALUE: stats->snmp_inbadvalues++; break; case SNMP_ERROR_READONLY: stats->snmp_inreadonlys++; break; case SNMP_ERROR_GENERR: default: stats->snmp_ingenerrs++; break; } /* Create new SNMP packet */ if (snmpe_encode(msg) < 0) goto done; len = ber_write_elements(&msg->sm_ber, msg->sm_resp); if (ber_get_writebuf(&msg->sm_ber, (void *)&ptr) == -1) goto done; usm_finalize_digest(msg, ptr, len); if (msg->sm_sock_tcp) { event_del(&msg->sm_sockev); event_set(&msg->sm_sockev, msg->sm_sock, EV_WRITE, snmpe_writecb, msg); event_add(&msg->sm_sockev, &snmpe_tcp_timeout); return; } else { len = sendtofrom(msg->sm_sock, ptr, len, 0, (struct sockaddr *)&msg->sm_ss, msg->sm_slen, (struct sockaddr *)&msg->sm_local_ss, msg->sm_local_slen); if (len != -1) stats->snmp_outpkts++; } done: snmp_msgfree(msg); } void snmp_msgfree(struct snmp_message *msg) { event_del(&msg->sm_sockev); ber_free(&msg->sm_ber); if (msg->sm_req != NULL) ber_free_elements(msg->sm_req); if (msg->sm_resp != NULL) ber_free_elements(msg->sm_resp); free(msg); } int snmpe_encode(struct snmp_message *msg) { struct ber_element *ehdr; struct ber_element *pdu, *epdu; msg->sm_resp = ber_add_sequence(NULL); if ((ehdr = ber_add_integer(msg->sm_resp, msg->sm_version)) == NULL) return -1; if (msg->sm_version == SNMP_V3) { char f = MSG_SECLEVEL(msg); if ((ehdr = ber_printf_elements(ehdr, "{iixi}", msg->sm_msgid, msg->sm_max_msg_size, &f, sizeof(f), msg->sm_secmodel)) == NULL) return -1; /* XXX currently only USM supported */ if ((ehdr = usm_encode(msg, ehdr)) == NULL) return -1; } else { if ((ehdr = ber_add_string(ehdr, msg->sm_community)) == NULL) return -1; } pdu = epdu = ber_add_sequence(NULL); if (msg->sm_version == SNMP_V3) { if ((epdu = ber_printf_elements(epdu, "xs{", snmpd_env->sc_engineid, snmpd_env->sc_engineid_len, msg->sm_ctxname)) == NULL) { ber_free_elements(pdu); return -1; } } if (!ber_printf_elements(epdu, "tiii{e}.", BER_CLASS_CONTEXT, msg->sm_context, msg->sm_request, msg->sm_error, msg->sm_errorindex, msg->sm_varbindresp)) { ber_free_elements(pdu); return -1; } if (MSG_HAS_PRIV(msg)) pdu = usm_encrypt(msg, pdu); ber_link_elements(ehdr, pdu); #ifdef DEBUG fprintf(stderr, "resp msg:\n"); smi_debug_elements(msg->sm_resp); #endif return 0; }