/* $OpenBSD: bgpctl.c,v 1.238 2019/05/23 14:12:06 claudio Exp $ */ /* * Copyright (c) 2003 Henning Brauer * Copyright (c) 2016 Job Snijders * Copyright (c) 2016 Peter Hessler * * 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 "bgpd.h" #include "session.h" #include "rde.h" #include "parser.h" #include "irrfilter.h" #include "mrtparser.h" enum neighbor_views { NV_DEFAULT, NV_TIMERS }; #define EOL0(flag) ((flag & F_CTL_SSV) ? ';' : '\n') int main(int, char *[]); char *fmt_peer(const char *, const struct bgpd_addr *, int, int); void show_summary_head(void); int show_summary_msg(struct imsg *, int); int show_summary_terse_msg(struct imsg *, int); int show_neighbor_terse(struct imsg *); int show_neighbor_msg(struct imsg *, enum neighbor_views); void print_neighbor_capa_mp(struct peer *); void print_neighbor_capa_restart(struct peer *); void print_neighbor_msgstats(struct peer *); void print_timer(const char *, time_t); static char *fmt_timeframe(time_t t); static char *fmt_timeframe_core(time_t t); void show_fib_head(void); void show_fib_tables_head(void); void show_network_head(void); void show_fib_flags(u_int16_t); int show_fib_msg(struct imsg *); void show_nexthop_head(void); int show_nexthop_msg(struct imsg *); void show_interface_head(void); int show_interface_msg(struct imsg *); void show_rib_summary_head(void); void print_prefix(struct bgpd_addr *, u_int8_t, u_int8_t, u_int8_t); const char * print_origin(u_int8_t, int); const char * print_ovs(u_int8_t, int); void print_flags(u_int8_t, int); int show_rib_summary_msg(struct imsg *); int show_rib_detail_msg(struct imsg *, int, int); void show_rib_brief(struct ctl_show_rib *, u_char *); void show_rib_detail(struct ctl_show_rib *, u_char *, int, int); void show_attr(void *, u_int16_t, int); void show_community(u_char *, u_int16_t); void show_large_community(u_char *, u_int16_t); void show_ext_community(u_char *, u_int16_t); int show_rib_memory_msg(struct imsg *); void send_filterset(struct imsgbuf *, struct filter_set_head *); const char *get_errstr(u_int8_t, u_int8_t); int show_result(struct imsg *); void show_mrt_dump_neighbors(struct mrt_rib *, struct mrt_peer *, void *); void show_mrt_dump(struct mrt_rib *, struct mrt_peer *, void *); void network_mrt_dump(struct mrt_rib *, struct mrt_peer *, void *); void show_mrt_state(struct mrt_bgp_state *, void *); void show_mrt_msg(struct mrt_bgp_msg *, void *); const char *msg_type(u_int8_t); void network_bulk(struct parse_result *); const char *print_auth_method(enum auth_method); int match_aspath(void *, u_int16_t, struct filter_as *); struct imsgbuf *ibuf; struct mrt_parser show_mrt = { show_mrt_dump, show_mrt_state, show_mrt_msg }; struct mrt_parser net_mrt = { network_mrt_dump, NULL, NULL }; int tableid; __dead void usage(void) { extern char *__progname; fprintf(stderr, "usage: %s [-n] [-s socket] command [argument ...]\n", __progname); exit(1); } int main(int argc, char *argv[]) { struct sockaddr_un sun; int fd, n, done, ch, nodescr = 0, verbose = 0; struct imsg imsg; struct network_config net; struct parse_result *res; struct ctl_neighbor neighbor; struct ctl_show_rib_request ribreq; char *sockname; enum imsg_type type; if (pledge("stdio rpath wpath cpath unix inet dns", NULL) == -1) err(1, "pledge"); tableid = getrtable(); if (asprintf(&sockname, "%s.%d", SOCKET_NAME, tableid) == -1) err(1, "asprintf"); while ((ch = getopt(argc, argv, "ns:")) != -1) { switch (ch) { case 'n': if (++nodescr > 1) usage(); break; case 's': sockname = optarg; break; default: usage(); /* NOTREACHED */ } } argc -= optind; argv += optind; if ((res = parse(argc, argv)) == NULL) exit(1); memcpy(&neighbor.addr, &res->peeraddr, sizeof(neighbor.addr)); strlcpy(neighbor.descr, res->peerdesc, sizeof(neighbor.descr)); neighbor.is_group = res->is_group; strlcpy(neighbor.shutcomm, res->shutcomm, sizeof(neighbor.shutcomm)); switch (res->action) { case IRRFILTER: if (!(res->flags & (F_IPV4|F_IPV6))) res->flags |= (F_IPV4|F_IPV6); irr_main(res->as.as_min, res->flags, res->irr_outdir); break; case SHOW_MRT: if (pledge("stdio", NULL) == -1) err(1, "pledge"); bzero(&ribreq, sizeof(ribreq)); if (res->as.type != AS_UNDEF) ribreq.as = res->as; if (res->addr.aid) { ribreq.prefix = res->addr; ribreq.prefixlen = res->prefixlen; } /* XXX currently no communities support */ ribreq.neighbor = neighbor; ribreq.aid = res->aid; ribreq.flags = res->flags; ribreq.validation_state = res->validation_state; show_mrt.arg = &ribreq; if (res->flags & F_CTL_NEIGHBORS) show_mrt.dump = show_mrt_dump_neighbors; else if (!(res->flags & F_CTL_DETAIL)) show_rib_summary_head(); mrt_parse(res->mrtfd, &show_mrt, 1); exit(0); default: break; } if (pledge("stdio unix", NULL) == -1) err(1, "pledge"); if ((fd = socket(AF_UNIX, SOCK_STREAM, 0)) == -1) err(1, "control_init: socket"); bzero(&sun, sizeof(sun)); sun.sun_family = AF_UNIX; if (strlcpy(sun.sun_path, sockname, sizeof(sun.sun_path)) >= sizeof(sun.sun_path)) errx(1, "socket name too long"); if (connect(fd, (struct sockaddr *)&sun, sizeof(sun)) == -1) err(1, "connect: %s", sockname); if (pledge("stdio", NULL) == -1) err(1, "pledge"); if ((ibuf = malloc(sizeof(struct imsgbuf))) == NULL) err(1, NULL); imsg_init(ibuf, fd); done = 0; switch (res->action) { case NONE: case IRRFILTER: case SHOW_MRT: usage(); /* NOTREACHED */ case SHOW: case SHOW_SUMMARY: imsg_compose(ibuf, IMSG_CTL_SHOW_NEIGHBOR, 0, 0, -1, NULL, 0); show_summary_head(); break; case SHOW_SUMMARY_TERSE: imsg_compose(ibuf, IMSG_CTL_SHOW_TERSE, 0, 0, -1, NULL, 0); break; case SHOW_FIB: if (!res->addr.aid) { struct ibuf *msg; sa_family_t af; af = aid2af(res->aid); if ((msg = imsg_create(ibuf, IMSG_CTL_KROUTE, res->rtableid, 0, sizeof(res->flags) + sizeof(af))) == NULL) errx(1, "imsg_create failure"); if (imsg_add(msg, &res->flags, sizeof(res->flags)) == -1 || imsg_add(msg, &af, sizeof(af)) == -1) errx(1, "imsg_add failure"); imsg_close(ibuf, msg); } else imsg_compose(ibuf, IMSG_CTL_KROUTE_ADDR, res->rtableid, 0, -1, &res->addr, sizeof(res->addr)); show_fib_head(); break; case SHOW_FIB_TABLES: imsg_compose(ibuf, IMSG_CTL_SHOW_FIB_TABLES, 0, 0, -1, NULL, 0); show_fib_tables_head(); break; case SHOW_NEXTHOP: imsg_compose(ibuf, IMSG_CTL_SHOW_NEXTHOP, res->rtableid, 0, -1, NULL, 0); show_nexthop_head(); break; case SHOW_INTERFACE: imsg_compose(ibuf, IMSG_CTL_SHOW_INTERFACE, 0, 0, -1, NULL, 0); show_interface_head(); break; case SHOW_NEIGHBOR: case SHOW_NEIGHBOR_TIMERS: case SHOW_NEIGHBOR_TERSE: neighbor.show_timers = (res->action == SHOW_NEIGHBOR_TIMERS); if (res->peeraddr.aid || res->peerdesc[0]) imsg_compose(ibuf, IMSG_CTL_SHOW_NEIGHBOR, 0, 0, -1, &neighbor, sizeof(neighbor)); else imsg_compose(ibuf, IMSG_CTL_SHOW_NEIGHBOR, 0, 0, -1, NULL, 0); break; case SHOW_RIB: bzero(&ribreq, sizeof(ribreq)); type = IMSG_CTL_SHOW_RIB; if (res->addr.aid) { ribreq.prefix = res->addr; ribreq.prefixlen = res->prefixlen; type = IMSG_CTL_SHOW_RIB_PREFIX; } if (res->as.type != AS_UNDEF) ribreq.as = res->as; if (res->community.type != COMMUNITY_TYPE_NONE) ribreq.community = res->community; ribreq.neighbor = neighbor; strlcpy(ribreq.rib, res->rib, sizeof(ribreq.rib)); ribreq.aid = res->aid; ribreq.flags = res->flags; imsg_compose(ibuf, type, 0, 0, -1, &ribreq, sizeof(ribreq)); if (!(res->flags & F_CTL_DETAIL)) show_rib_summary_head(); break; case SHOW_RIB_MEM: imsg_compose(ibuf, IMSG_CTL_SHOW_RIB_MEM, 0, 0, -1, NULL, 0); break; case RELOAD: imsg_compose(ibuf, IMSG_CTL_RELOAD, 0, 0, -1, NULL, 0); printf("reload request sent.\n"); break; case FIB: errx(1, "action==FIB"); break; case FIB_COUPLE: imsg_compose(ibuf, IMSG_CTL_FIB_COUPLE, res->rtableid, 0, -1, NULL, 0); printf("couple request sent.\n"); done = 1; break; case FIB_DECOUPLE: imsg_compose(ibuf, IMSG_CTL_FIB_DECOUPLE, res->rtableid, 0, -1, NULL, 0); printf("decouple request sent.\n"); done = 1; break; case NEIGHBOR: errx(1, "action==NEIGHBOR"); break; case NEIGHBOR_UP: imsg_compose(ibuf, IMSG_CTL_NEIGHBOR_UP, 0, 0, -1, &neighbor, sizeof(neighbor)); break; case NEIGHBOR_DOWN: imsg_compose(ibuf, IMSG_CTL_NEIGHBOR_DOWN, 0, 0, -1, &neighbor, sizeof(neighbor)); break; case NEIGHBOR_CLEAR: imsg_compose(ibuf, IMSG_CTL_NEIGHBOR_CLEAR, 0, 0, -1, &neighbor, sizeof(neighbor)); break; case NEIGHBOR_RREFRESH: imsg_compose(ibuf, IMSG_CTL_NEIGHBOR_RREFRESH, 0, 0, -1, &neighbor, sizeof(neighbor)); break; case NEIGHBOR_DESTROY: imsg_compose(ibuf, IMSG_CTL_NEIGHBOR_DESTROY, 0, 0, -1, &neighbor, sizeof(neighbor)); break; case NETWORK_BULK_ADD: case NETWORK_BULK_REMOVE: network_bulk(res); printf("requests sent.\n"); done = 1; break; case NETWORK_ADD: case NETWORK_REMOVE: bzero(&net, sizeof(net)); net.prefix = res->addr; net.prefixlen = res->prefixlen; net.rd = res->rd; /* attribute sets are not supported */ if (res->action == NETWORK_ADD) { imsg_compose(ibuf, IMSG_NETWORK_ADD, 0, 0, -1, &net, sizeof(net)); send_filterset(ibuf, &res->set); imsg_compose(ibuf, IMSG_NETWORK_DONE, 0, 0, -1, NULL, 0); } else imsg_compose(ibuf, IMSG_NETWORK_REMOVE, 0, 0, -1, &net, sizeof(net)); printf("request sent.\n"); done = 1; break; case NETWORK_FLUSH: imsg_compose(ibuf, IMSG_NETWORK_FLUSH, 0, 0, -1, NULL, 0); printf("request sent.\n"); done = 1; break; case NETWORK_SHOW: bzero(&ribreq, sizeof(ribreq)); ribreq.aid = res->aid; strlcpy(ribreq.rib, res->rib, sizeof(ribreq.rib)); imsg_compose(ibuf, IMSG_CTL_SHOW_NETWORK, 0, 0, -1, &ribreq, sizeof(ribreq)); show_network_head(); break; case NETWORK_MRT: bzero(&ribreq, sizeof(ribreq)); if (res->as.type != AS_UNDEF) ribreq.as = res->as; if (res->addr.aid) { ribreq.prefix = res->addr; ribreq.prefixlen = res->prefixlen; } /* XXX currently no community support */ ribreq.neighbor = neighbor; ribreq.aid = res->aid; ribreq.flags = res->flags; net_mrt.arg = &ribreq; mrt_parse(res->mrtfd, &net_mrt, 1); done = 1; break; case LOG_VERBOSE: verbose = 1; /* FALLTHROUGH */ case LOG_BRIEF: imsg_compose(ibuf, IMSG_CTL_LOG_VERBOSE, 0, 0, -1, &verbose, sizeof(verbose)); printf("logging request sent.\n"); done = 1; break; } while (ibuf->w.queued) if (msgbuf_write(&ibuf->w) <= 0 && errno != EAGAIN) err(1, "write error"); while (!done) { if ((n = imsg_read(ibuf)) == -1 && errno != EAGAIN) err(1, "imsg_read error"); if (n == 0) errx(1, "pipe closed"); while (!done) { if ((n = imsg_get(ibuf, &imsg)) == -1) err(1, "imsg_get error"); if (n == 0) break; if (imsg.hdr.type == IMSG_CTL_RESULT) { done = show_result(&imsg); imsg_free(&imsg); continue; } switch (res->action) { case SHOW: case SHOW_SUMMARY: done = show_summary_msg(&imsg, nodescr); break; case SHOW_SUMMARY_TERSE: done = show_summary_terse_msg(&imsg, nodescr); break; case SHOW_FIB: case SHOW_FIB_TABLES: case NETWORK_SHOW: done = show_fib_msg(&imsg); break; case SHOW_NEXTHOP: done = show_nexthop_msg(&imsg); break; case SHOW_INTERFACE: done = show_interface_msg(&imsg); break; case SHOW_NEIGHBOR: done = show_neighbor_msg(&imsg, NV_DEFAULT); break; case SHOW_NEIGHBOR_TIMERS: done = show_neighbor_msg(&imsg, NV_TIMERS); break; case SHOW_NEIGHBOR_TERSE: done = show_neighbor_terse(&imsg); break; case SHOW_RIB: if (res->flags & F_CTL_DETAIL) done = show_rib_detail_msg(&imsg, nodescr, res->flags); else done = show_rib_summary_msg(&imsg); break; case SHOW_RIB_MEM: done = show_rib_memory_msg(&imsg); break; case NEIGHBOR: case NEIGHBOR_UP: case NEIGHBOR_DOWN: case NEIGHBOR_CLEAR: case NEIGHBOR_RREFRESH: case NEIGHBOR_DESTROY: case NONE: case RELOAD: case FIB: case FIB_COUPLE: case FIB_DECOUPLE: case NETWORK_ADD: case NETWORK_REMOVE: case NETWORK_FLUSH: case NETWORK_BULK_ADD: case NETWORK_BULK_REMOVE: case IRRFILTER: case LOG_VERBOSE: case LOG_BRIEF: case SHOW_MRT: case NETWORK_MRT: break; } imsg_free(&imsg); } } close(fd); free(ibuf); exit(0); } char * fmt_peer(const char *descr, const struct bgpd_addr *remote_addr, int masklen, int nodescr) { const char *ip; char *p; if (descr[0] && !nodescr) { if ((p = strdup(descr)) == NULL) err(1, NULL); return (p); } ip = log_addr(remote_addr); if (masklen != -1 && ((remote_addr->aid == AID_INET && masklen != 32) || (remote_addr->aid == AID_INET6 && masklen != 128))) { if (asprintf(&p, "%s/%u", ip, masklen) == -1) err(1, NULL); } else { if ((p = strdup(ip)) == NULL) err(1, NULL); } return (p); } void show_summary_head(void) { printf("%-20s %8s %10s %10s %5s %-8s %s\n", "Neighbor", "AS", "MsgRcvd", "MsgSent", "OutQ", "Up/Down", "State/PrfRcvd"); } int show_summary_msg(struct imsg *imsg, int nodescr) { struct peer *p; char *s; const char *a; size_t alen; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_NEIGHBOR: p = imsg->data; s = fmt_peer(p->conf.descr, &p->conf.remote_addr, p->conf.remote_masklen, nodescr); a = log_as(p->conf.remote_as); alen = strlen(a); /* max displayed length of the peers name is 28 */ if (alen < 28) { if (strlen(s) > 28 - alen) s[28 - alen] = 0; } else alen = 0; printf("%-*s %s %10llu %10llu %5u %-8s ", (28 - (int)alen), s, a, p->stats.msg_rcvd_open + p->stats.msg_rcvd_notification + p->stats.msg_rcvd_update + p->stats.msg_rcvd_keepalive + p->stats.msg_rcvd_rrefresh, p->stats.msg_sent_open + p->stats.msg_sent_notification + p->stats.msg_sent_update + p->stats.msg_sent_keepalive + p->stats.msg_sent_rrefresh, p->wbuf.queued, fmt_timeframe(p->stats.last_updown)); if (p->state == STATE_ESTABLISHED) { printf("%6u", p->stats.prefix_cnt); if (p->conf.max_prefix != 0) printf("/%u", p->conf.max_prefix); } else if (p->conf.template) printf("Template"); else printf("%s", statenames[p->state]); printf("\n"); free(s); break; case IMSG_CTL_END: return (1); default: break; } return (0); } int show_summary_terse_msg(struct imsg *imsg, int nodescr) { struct peer *p; char *s; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_NEIGHBOR: p = imsg->data; s = fmt_peer(p->conf.descr, &p->conf.remote_addr, p->conf.remote_masklen, nodescr); printf("%s %s %s\n", s, log_as(p->conf.remote_as), p->conf.template ? "Template" : statenames[p->state]); free(s); break; case IMSG_CTL_END: return (1); default: break; } return (0); } int show_neighbor_terse(struct imsg *imsg) { struct peer *p; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_NEIGHBOR: p = imsg->data; printf("%llu %llu %llu %llu %llu %llu %llu " "%llu %llu %llu %u %u %llu %llu %llu %llu\n", p->stats.msg_sent_open, p->stats.msg_rcvd_open, p->stats.msg_sent_notification, p->stats.msg_rcvd_notification, p->stats.msg_sent_update, p->stats.msg_rcvd_update, p->stats.msg_sent_keepalive, p->stats.msg_rcvd_keepalive, p->stats.msg_sent_rrefresh, p->stats.msg_rcvd_rrefresh, p->stats.prefix_cnt, p->conf.max_prefix, p->stats.prefix_sent_update, p->stats.prefix_rcvd_update, p->stats.prefix_sent_withdraw, p->stats.prefix_rcvd_withdraw); break; case IMSG_CTL_END: return (1); default: break; } return (0); } const char * print_auth_method(enum auth_method method) { switch (method) { case AUTH_MD5SIG: return ", using md5sig"; case AUTH_IPSEC_MANUAL_ESP: return ", using ipsec manual esp"; case AUTH_IPSEC_MANUAL_AH: return ", using ipsec manual ah"; case AUTH_IPSEC_IKE_ESP: return ", using ipsec ike esp"; case AUTH_IPSEC_IKE_AH: return ", using ipsec ike ah"; case AUTH_NONE: /* FALLTHROUGH */ default: return ""; } } int show_neighbor_msg(struct imsg *imsg, enum neighbor_views nv) { struct peer *p; struct ctl_timer *t; struct in_addr ina; char *s; int hascapamp = 0; u_int8_t i; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_NEIGHBOR: p = imsg->data; if ((p->conf.remote_addr.aid == AID_INET && p->conf.remote_masklen != 32) || (p->conf.remote_addr.aid == AID_INET6 && p->conf.remote_masklen != 128)) { if (asprintf(&s, "%s/%u", log_addr(&p->conf.remote_addr), p->conf.remote_masklen) == -1) err(1, NULL); } else if ((s = strdup(log_addr(&p->conf.remote_addr))) == NULL) err(1, "strdup"); ina.s_addr = p->remote_bgpid; printf("BGP neighbor is %s, ", s); free(s); if (p->conf.remote_as == 0 && p->conf.template) printf("remote AS: accept any"); else printf("remote AS %s", log_as(p->conf.remote_as)); if (p->conf.template) printf(", Template"); if (p->template) printf(", Cloned"); if (p->conf.passive) printf(", Passive"); if (p->conf.ebgp && p->conf.distance > 1) printf(", Multihop (%u)", (int)p->conf.distance); printf("\n"); if (p->conf.descr[0]) printf(" Description: %s\n", p->conf.descr); if (p->conf.max_prefix) { printf(" Max-prefix: %u", p->conf.max_prefix); if (p->conf.max_prefix_restart) printf(" (restart %u)", p->conf.max_prefix_restart); printf("\n"); } printf(" BGP version 4, remote router-id %s", inet_ntoa(ina)); printf("%s\n", print_auth_method(p->auth.method)); printf(" BGP state = %s", statenames[p->state]); if (p->conf.down) { printf(", marked down"); if (*(p->conf.shutcomm)) { printf(" with shutdown reason \"%s\"", log_shutcomm(p->conf.shutcomm)); } } if (p->stats.last_updown != 0) printf(", %s for %s", p->state == STATE_ESTABLISHED ? "up" : "down", fmt_timeframe(p->stats.last_updown)); printf("\n"); printf(" Last read %s, holdtime %us, keepalive interval %us\n", fmt_timeframe(p->stats.last_read), p->holdtime, p->holdtime/3); for (i = 0; i < AID_MAX; i++) if (p->capa.peer.mp[i]) hascapamp = 1; if (hascapamp || p->capa.peer.refresh || p->capa.peer.grestart.restart || p->capa.peer.as4byte) { printf(" Neighbor capabilities:\n"); if (hascapamp) { printf(" Multiprotocol extensions: "); print_neighbor_capa_mp(p); printf("\n"); } if (p->capa.peer.refresh) printf(" Route Refresh\n"); if (p->capa.peer.grestart.restart) { printf(" Graceful Restart"); print_neighbor_capa_restart(p); printf("\n"); } if (p->capa.peer.as4byte) printf(" 4-byte AS numbers\n"); } printf("\n"); if (nv == NV_TIMERS) break; print_neighbor_msgstats(p); printf("\n"); if (*(p->stats.last_shutcomm)) { printf(" Last received shutdown reason: \"%s\"\n", log_shutcomm(p->stats.last_shutcomm)); } if (p->state == STATE_IDLE) { static const char *errstr; errstr = get_errstr(p->stats.last_sent_errcode, p->stats.last_sent_suberr); if (errstr) printf(" Last error: %s\n\n", errstr); } else { printf(" Local host: %20s, Local port: %5u\n", log_addr(&p->local), p->local_port); printf(" Remote host: %20s, Remote port: %5u\n", log_addr(&p->remote), p->remote_port); printf("\n"); } break; case IMSG_CTL_SHOW_TIMER: t = imsg->data; if (t->type > 0 && t->type < Timer_Max) print_timer(timernames[t->type], t->val); break; case IMSG_CTL_END: return (1); break; default: break; } return (0); } void print_neighbor_capa_mp(struct peer *p) { int comma; u_int8_t i; for (i = 0, comma = 0; i < AID_MAX; i++) if (p->capa.peer.mp[i]) { printf("%s%s", comma ? ", " : "", aid2str(i)); comma = 1; } } void print_neighbor_capa_restart(struct peer *p) { int comma; u_int8_t i; if (p->capa.peer.grestart.timeout) printf(": Timeout: %d, ", p->capa.peer.grestart.timeout); for (i = 0, comma = 0; i < AID_MAX; i++) if (p->capa.peer.grestart.flags[i] & CAPA_GR_PRESENT) { if (!comma && p->capa.peer.grestart.flags[i] & CAPA_GR_RESTART) printf("restarted, "); if (comma) printf(", "); printf("%s", aid2str(i)); if (p->capa.peer.grestart.flags[i] & CAPA_GR_FORWARD) printf(" (preserved)"); comma = 1; } } void print_neighbor_msgstats(struct peer *p) { printf(" Message statistics:\n"); printf(" %-15s %-10s %-10s\n", "", "Sent", "Received"); printf(" %-15s %10llu %10llu\n", "Opens", p->stats.msg_sent_open, p->stats.msg_rcvd_open); printf(" %-15s %10llu %10llu\n", "Notifications", p->stats.msg_sent_notification, p->stats.msg_rcvd_notification); printf(" %-15s %10llu %10llu\n", "Updates", p->stats.msg_sent_update, p->stats.msg_rcvd_update); printf(" %-15s %10llu %10llu\n", "Keepalives", p->stats.msg_sent_keepalive, p->stats.msg_rcvd_keepalive); printf(" %-15s %10llu %10llu\n", "Route Refresh", p->stats.msg_sent_rrefresh, p->stats.msg_rcvd_rrefresh); printf(" %-15s %10llu %10llu\n\n", "Total", p->stats.msg_sent_open + p->stats.msg_sent_notification + p->stats.msg_sent_update + p->stats.msg_sent_keepalive + p->stats.msg_sent_rrefresh, p->stats.msg_rcvd_open + p->stats.msg_rcvd_notification + p->stats.msg_rcvd_update + p->stats.msg_rcvd_keepalive + p->stats.msg_rcvd_rrefresh); printf(" Update statistics:\n"); printf(" %-15s %-10s %-10s\n", "", "Sent", "Received"); printf(" %-15s %10llu %10llu\n", "Updates", p->stats.prefix_sent_update, p->stats.prefix_rcvd_update); printf(" %-15s %10llu %10llu\n", "Withdraws", p->stats.prefix_sent_withdraw, p->stats.prefix_rcvd_withdraw); printf(" %-15s %10llu %10llu\n", "End-of-Rib", p->stats.prefix_sent_eor, p->stats.prefix_rcvd_eor); } void print_timer(const char *name, time_t d) { printf(" %-20s ", name); if (d <= 0) printf("%-20s\n", "due"); else printf("due in %-13s\n", fmt_timeframe_core(d)); } #define TF_BUFS 8 #define TF_LEN 9 static char * fmt_timeframe(time_t t) { if (t == 0) return ("Never"); else return (fmt_timeframe_core(time(NULL) - t)); } static char * fmt_timeframe_core(time_t t) { char *buf; static char tfbuf[TF_BUFS][TF_LEN]; /* ring buffer */ static int idx = 0; unsigned int sec, min, hrs, day; unsigned long long week; buf = tfbuf[idx++]; if (idx == TF_BUFS) idx = 0; week = t; sec = week % 60; week /= 60; min = week % 60; week /= 60; hrs = week % 24; week /= 24; day = week % 7; week /= 7; if (week > 0) snprintf(buf, TF_LEN, "%02lluw%01ud%02uh", week, day, hrs); else if (day > 0) snprintf(buf, TF_LEN, "%01ud%02uh%02um", day, hrs, min); else snprintf(buf, TF_LEN, "%02u:%02u:%02u", hrs, min, sec); return (buf); } void show_fib_head(void) { printf("flags: " "* = valid, B = BGP, C = Connected, S = Static, D = Dynamic\n"); printf(" " "N = BGP Nexthop reachable via this route\n"); printf(" r = reject route, b = blackhole route\n\n"); printf("flags prio destination gateway\n"); } void show_fib_tables_head(void) { printf("%-5s %-20s %-8s\n", "Table", "Description", "State"); } void show_network_head(void) { printf("flags: S = Static\n"); printf("flags prio destination gateway\n"); } void show_fib_flags(u_int16_t flags) { if (flags & F_DOWN) printf(" "); else printf("*"); if (flags & F_BGPD_INSERTED) printf("B"); else if (flags & F_CONNECTED) printf("C"); else if (flags & F_STATIC) printf("S"); else if (flags & F_DYNAMIC) printf("D"); else printf(" "); if (flags & F_NEXTHOP) printf("N"); else printf(" "); if (flags & F_REJECT && flags & F_BLACKHOLE) printf("f"); else if (flags & F_REJECT) printf("r"); else if (flags & F_BLACKHOLE) printf("b"); else printf(" "); printf(" "); } int show_fib_msg(struct imsg *imsg) { struct kroute_full *kf; struct ktable *kt; char *p; switch (imsg->hdr.type) { case IMSG_CTL_KROUTE: case IMSG_CTL_SHOW_NETWORK: if (imsg->hdr.len < IMSG_HEADER_SIZE + sizeof(*kf)) errx(1, "wrong imsg len"); kf = imsg->data; show_fib_flags(kf->flags); if (asprintf(&p, "%s/%u", log_addr(&kf->prefix), kf->prefixlen) == -1) err(1, NULL); printf("%4i %-20s ", kf->priority, p); free(p); if (kf->flags & F_CONNECTED) printf("link#%u", kf->ifindex); else printf("%s", log_addr(&kf->nexthop)); printf("\n"); break; case IMSG_CTL_SHOW_FIB_TABLES: if (imsg->hdr.len < IMSG_HEADER_SIZE + sizeof(*kt)) errx(1, "wrong imsg len"); kt = imsg->data; printf("%5i %-20s %-8s%s\n", kt->rtableid, kt->descr, kt->fib_sync ? "coupled" : "decoupled", kt->fib_sync != kt->fib_conf ? "*" : ""); break; case IMSG_CTL_END: return (1); default: break; } return (0); } void show_nexthop_head(void) { printf("Flags: * = nexthop valid\n"); printf("\n %-15s %-19s%-4s %-15s %-20s\n", "Nexthop", "Route", "Prio", "Gateway", "Iface"); } int show_nexthop_msg(struct imsg *imsg) { struct ctl_show_nexthop *p; struct kroute *k; struct kroute6 *k6; char *s; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_NEXTHOP: p = imsg->data; printf("%s %-15s ", p->valid ? "*" : " ", log_addr(&p->addr)); if (!p->krvalid) { printf("\n"); return (0); } switch (p->addr.aid) { case AID_INET: k = &p->kr.kr4; if (asprintf(&s, "%s/%u", inet_ntoa(k->prefix), k->prefixlen) == -1) err(1, NULL); printf("%-20s", s); free(s); printf("%3i %-15s ", k->priority, k->flags & F_CONNECTED ? "connected" : inet_ntoa(k->nexthop)); break; case AID_INET6: k6 = &p->kr.kr6; if (asprintf(&s, "%s/%u", log_in6addr(&k6->prefix), k6->prefixlen) == -1) err(1, NULL); printf("%-20s", s); free(s); printf("%3i %-15s ", k6->priority, k6->flags & F_CONNECTED ? "connected" : log_in6addr(&k6->nexthop)); break; default: printf("unknown address family\n"); return (0); } if (p->iface.ifname[0]) { printf("%s (%s, %s)", p->iface.ifname, p->iface.is_up ? "UP" : "DOWN", p->iface.baudrate ? get_baudrate(p->iface.baudrate, "bps") : p->iface.linkstate); } printf("\n"); break; case IMSG_CTL_END: return (1); break; default: break; } return (0); } void show_interface_head(void) { printf("%-15s%-9s%-9s%-7s%s\n", "Interface", "rdomain", "Nexthop", "Flags", "Link state"); } int show_interface_msg(struct imsg *imsg) { struct ctl_show_interface *iface; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_INTERFACE: iface = imsg->data; printf("%-15s", iface->ifname); printf("%-9u", iface->rdomain); printf("%-9s", iface->nh_reachable ? "ok" : "invalid"); printf("%-7s", iface->is_up ? "UP" : ""); if (iface->media[0]) printf("%s, ", iface->media); printf("%s", iface->linkstate); if (iface->baudrate > 0) printf(", %s", get_baudrate(iface->baudrate, "Bit/s")); printf("\n"); break; case IMSG_CTL_END: return (1); break; default: break; } return (0); } void show_rib_summary_head(void) { printf("flags: * = Valid, > = Selected, I = via IBGP, A = Announced,\n" " S = Stale, E = Error\n"); printf("origin validation state: N = not-found, V = valid, ! = invalid\n"); printf("origin: i = IGP, e = EGP, ? = Incomplete\n\n"); printf("%-5s %3s %-20s %-15s %5s %5s %s\n", "flags", "ovs", "destination", "gateway", "lpref", "med", "aspath origin"); } void print_prefix(struct bgpd_addr *prefix, u_int8_t prefixlen, u_int8_t flags, u_int8_t ovs) { char *p; print_flags(flags, 1); printf("%3s ", print_ovs(ovs, 1)); if (asprintf(&p, "%s/%u", log_addr(prefix), prefixlen) == -1) err(1, NULL); printf("%-20s", p); free(p); } const char * print_origin(u_int8_t origin, int sum) { switch (origin) { case ORIGIN_IGP: return (sum ? "i" : "IGP"); case ORIGIN_EGP: return (sum ? "e" : "EGP"); case ORIGIN_INCOMPLETE: return (sum ? "?" : "incomplete"); default: return (sum ? "X" : "bad origin"); } } void print_flags(u_int8_t flags, int sum) { char flagstr[5]; char *p = flagstr; if (sum) { if (flags & F_PREF_INVALID) *p++ = 'E'; if (flags & F_PREF_ANNOUNCE) *p++ = 'A'; if (flags & F_PREF_INTERNAL) *p++ = 'I'; if (flags & F_PREF_STALE) *p++ = 'S'; if (flags & F_PREF_ELIGIBLE) *p++ = '*'; if (flags & F_PREF_ACTIVE) *p++ = '>'; *p = '\0'; printf("%-5s ", flagstr); } else { if (flags & F_PREF_INTERNAL) printf("internal"); else printf("external"); if (flags & F_PREF_STALE) printf(", stale"); if (flags & F_PREF_ELIGIBLE) printf(", valid"); if (flags & F_PREF_ACTIVE) printf(", best"); if (flags & F_PREF_ANNOUNCE) printf(", announced"); } } const char * print_ovs(u_int8_t validation_state, int sum) { switch (validation_state) { case ROA_INVALID: return (sum ? "!" : "invalid"); case ROA_VALID: return (sum ? "V" : "valid"); default: return (sum ? "N" : "not-found"); } } int show_rib_summary_msg(struct imsg *imsg) { struct ctl_show_rib rib; u_char *asdata; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_RIB: memcpy(&rib, imsg->data, sizeof(rib)); asdata = imsg->data; asdata += sizeof(struct ctl_show_rib); show_rib_brief(&rib, asdata); break; case IMSG_CTL_END: return (1); default: break; } return (0); } int show_rib_detail_msg(struct imsg *imsg, int nodescr, int flag0) { struct ctl_show_rib rib; u_char *asdata; u_int16_t ilen; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_RIB: memcpy(&rib, imsg->data, sizeof(rib)); asdata = imsg->data; asdata += sizeof(struct ctl_show_rib); show_rib_detail(&rib, asdata, nodescr, flag0); break; case IMSG_CTL_SHOW_RIB_ATTR: ilen = imsg->hdr.len - IMSG_HEADER_SIZE; if (ilen < 3) errx(1, "bad IMSG_CTL_SHOW_RIB_ATTR received"); show_attr(imsg->data, ilen, flag0); break; case IMSG_CTL_END: printf("\n"); return (1); default: break; } return (0); } void show_rib_brief(struct ctl_show_rib *r, u_char *asdata) { char *aspath; print_prefix(&r->prefix, r->prefixlen, r->flags, r->validation_state); printf(" %-15s ", log_addr(&r->exit_nexthop)); printf(" %5u %5u ", r->local_pref, r->med); if (aspath_asprint(&aspath, asdata, r->aspath_len) == -1) err(1, NULL); if (strlen(aspath) > 0) printf("%s ", aspath); free(aspath); printf("%s\n", print_origin(r->origin, 1)); } void show_rib_detail(struct ctl_show_rib *r, u_char *asdata, int nodescr, int flag0) { struct in_addr id; char *aspath, *s; time_t now; printf("\nBGP routing table entry for %s/%u%c", log_addr(&r->prefix), r->prefixlen, EOL0(flag0)); if (aspath_asprint(&aspath, asdata, r->aspath_len) == -1) err(1, NULL); if (strlen(aspath) > 0) printf(" %s%c", aspath, EOL0(flag0)); free(aspath); s = fmt_peer(r->descr, &r->remote_addr, -1, nodescr); printf(" Nexthop %s ", log_addr(&r->exit_nexthop)); printf("(via %s) Neighbor %s (", log_addr(&r->true_nexthop), s); free(s); id.s_addr = htonl(r->remote_id); printf("%s)%c", inet_ntoa(id), EOL0(flag0)); printf(" Origin %s, metric %u, localpref %u, weight %u, ovs %s, ", print_origin(r->origin, 0), r->med, r->local_pref, r->weight, print_ovs(r->validation_state, 0)); print_flags(r->flags, 0); now = time(NULL); if (now > r->lastchange) now -= r->lastchange; else now = 0; printf("%c Last update: %s ago%c", EOL0(flag0), fmt_timeframe_core(now), EOL0(flag0)); } static const char * print_attr(u_int8_t type, u_int8_t flags) { #define CHECK_FLAGS(s, t, m) \ if (((s) & ~(ATTR_DEFMASK | (m))) != (t)) pflags = 1 static char cstr[48]; int pflags = 0; switch (type) { case ATTR_ORIGIN: CHECK_FLAGS(flags, ATTR_WELL_KNOWN, 0); strlcpy(cstr, "Origin", sizeof(cstr)); break; case ATTR_ASPATH: CHECK_FLAGS(flags, ATTR_WELL_KNOWN, 0); strlcpy(cstr, "AS-Path", sizeof(cstr)); break; case ATTR_AS4_PATH: CHECK_FLAGS(flags, ATTR_WELL_KNOWN, 0); strlcpy(cstr, "AS4-Path", sizeof(cstr)); break; case ATTR_NEXTHOP: CHECK_FLAGS(flags, ATTR_WELL_KNOWN, 0); strlcpy(cstr, "Nexthop", sizeof(cstr)); break; case ATTR_MED: CHECK_FLAGS(flags, ATTR_OPTIONAL, 0); strlcpy(cstr, "Med", sizeof(cstr)); break; case ATTR_LOCALPREF: CHECK_FLAGS(flags, ATTR_WELL_KNOWN, 0); strlcpy(cstr, "Localpref", sizeof(cstr)); break; case ATTR_ATOMIC_AGGREGATE: CHECK_FLAGS(flags, ATTR_WELL_KNOWN, 0); strlcpy(cstr, "Atomic Aggregate", sizeof(cstr)); break; case ATTR_AGGREGATOR: CHECK_FLAGS(flags, ATTR_OPTIONAL|ATTR_TRANSITIVE, ATTR_PARTIAL); strlcpy(cstr, "Aggregator", sizeof(cstr)); break; case ATTR_AS4_AGGREGATOR: CHECK_FLAGS(flags, ATTR_OPTIONAL|ATTR_TRANSITIVE, ATTR_PARTIAL); strlcpy(cstr, "AS4-Aggregator", sizeof(cstr)); break; case ATTR_COMMUNITIES: CHECK_FLAGS(flags, ATTR_OPTIONAL|ATTR_TRANSITIVE, ATTR_PARTIAL); strlcpy(cstr, "Communities", sizeof(cstr)); break; case ATTR_ORIGINATOR_ID: CHECK_FLAGS(flags, ATTR_OPTIONAL, 0); strlcpy(cstr, "Originator Id", sizeof(cstr)); break; case ATTR_CLUSTER_LIST: CHECK_FLAGS(flags, ATTR_OPTIONAL, 0); strlcpy(cstr, "Cluster Id List", sizeof(cstr)); break; case ATTR_MP_REACH_NLRI: CHECK_FLAGS(flags, ATTR_OPTIONAL, 0); strlcpy(cstr, "MP Reach NLRI", sizeof(cstr)); break; case ATTR_MP_UNREACH_NLRI: CHECK_FLAGS(flags, ATTR_OPTIONAL, 0); strlcpy(cstr, "MP Unreach NLRI", sizeof(cstr)); break; case ATTR_EXT_COMMUNITIES: CHECK_FLAGS(flags, ATTR_OPTIONAL|ATTR_TRANSITIVE, ATTR_PARTIAL); strlcpy(cstr, "Ext. Communities", sizeof(cstr)); break; case ATTR_LARGE_COMMUNITIES: CHECK_FLAGS(flags, ATTR_OPTIONAL|ATTR_TRANSITIVE, ATTR_PARTIAL); strlcpy(cstr, "Large Communities", sizeof(cstr)); break; default: /* ignore unknown attributes */ snprintf(cstr, sizeof(cstr), "Unknown Attribute #%u", type); pflags = 1; break; } if (pflags) { strlcat(cstr, " flags [", sizeof(cstr)); if (flags & ATTR_OPTIONAL) strlcat(cstr, "O", sizeof(cstr)); if (flags & ATTR_TRANSITIVE) strlcat(cstr, "T", sizeof(cstr)); if (flags & ATTR_PARTIAL) strlcat(cstr, "P", sizeof(cstr)); strlcat(cstr, "]", sizeof(cstr)); } return (cstr); #undef CHECK_FLAGS } void show_attr(void *b, u_int16_t len, int flag0) { u_char *data = b, *path; struct in_addr id; struct bgpd_addr prefix; char *aspath; u_int32_t as; u_int16_t alen, ioff, short_as, afi; u_int8_t flags, type, safi, aid, prefixlen; int i, pos, e2, e4; if (len < 3) errx(1, "show_attr: too short bgp attr"); flags = data[0]; type = data[1]; /* get the attribute length */ if (flags & ATTR_EXTLEN) { if (len < 4) errx(1, "show_attr: too short bgp attr"); memcpy(&alen, data+2, sizeof(u_int16_t)); alen = ntohs(alen); data += 4; len -= 4; } else { alen = (u_char)data[2]; data += 3; len -= 3; } /* bad imsg len how can that happen!? */ if (alen > len) errx(1, "show_attr: bad length"); printf(" %s: ", print_attr(type, flags)); switch (type) { case ATTR_ORIGIN: if (alen == 1) printf("%u", *data); else printf("bad length"); break; case ATTR_ASPATH: case ATTR_AS4_PATH: /* prefer 4-byte AS here */ e4 = aspath_verify(data, alen, 1); e2 = aspath_verify(data, alen, 0); if (e4 == 0 || e4 == AS_ERR_SOFT) { path = data; } else if (e2 == 0 || e2 == AS_ERR_SOFT) { path = aspath_inflate(data, alen, &alen); if (path == NULL) errx(1, "aspath_inflate failed"); } else { printf("bad AS-Path"); break; } if (aspath_asprint(&aspath, path, alen) == -1) err(1, NULL); printf("%s", aspath); free(aspath); if (path != data) free(path); break; case ATTR_NEXTHOP: if (alen == 4) { memcpy(&id, data, sizeof(id)); printf("%s", inet_ntoa(id)); } else printf("bad length"); break; case ATTR_MED: case ATTR_LOCALPREF: if (alen == 4) { u_int32_t val; memcpy(&val, data, sizeof(val)); val = ntohl(val); printf("%u", val); } else printf("bad length"); break; case ATTR_AGGREGATOR: case ATTR_AS4_AGGREGATOR: if (alen == 8) { memcpy(&as, data, sizeof(as)); memcpy(&id, data + sizeof(as), sizeof(id)); as = ntohl(as); } else if (alen == 6) { memcpy(&short_as, data, sizeof(short_as)); memcpy(&id, data + sizeof(short_as), sizeof(id)); as = ntohs(short_as); } else { printf("bad length"); break; } printf("%s [%s]", log_as(as), inet_ntoa(id)); break; case ATTR_COMMUNITIES: show_community(data, alen); break; case ATTR_ORIGINATOR_ID: memcpy(&id, data, sizeof(id)); printf("%s", inet_ntoa(id)); break; case ATTR_CLUSTER_LIST: for (ioff = 0; ioff + sizeof(id) <= alen; ioff += sizeof(id)) { memcpy(&id, data + ioff, sizeof(id)); printf(" %s", inet_ntoa(id)); } break; case ATTR_MP_REACH_NLRI: case ATTR_MP_UNREACH_NLRI: if (alen < 3) { bad_len: printf("bad length"); break; } memcpy(&afi, data, 2); data += 2; alen -= 2; afi = ntohs(afi); safi = *data++; alen--; if (afi2aid(afi, safi, &aid) == -1) { printf("bad AFI/SAFI pair"); break; } printf(" %s", aid2str(aid)); if (type == ATTR_MP_REACH_NLRI) { struct bgpd_addr nexthop; u_int8_t nhlen; if (len == 0) goto bad_len; nhlen = *data++; alen--; if (nhlen > len) goto bad_len; bzero(&nexthop, sizeof(nexthop)); switch (aid) { case AID_INET6: nexthop.aid = aid; if (nhlen != 16 && nhlen != 32) goto bad_len; memcpy(&nexthop.v6.s6_addr, data, 16); break; case AID_VPN_IPv4: if (nhlen != 12) goto bad_len; nexthop.aid = AID_INET; memcpy(&nexthop.v4, data + sizeof(u_int64_t), sizeof(nexthop.v4)); break; default: printf("unhandled AID #%u", aid); goto done; } /* ignore reserved (old SNPA) field as per RFC4760 */ data += nhlen + 1; alen -= nhlen + 1; printf(" nexthop: %s", log_addr(&nexthop)); } while (alen > 0) { switch (aid) { case AID_INET6: pos = nlri_get_prefix6(data, alen, &prefix, &prefixlen); break; case AID_VPN_IPv4: pos = nlri_get_vpn4(data, alen, &prefix, &prefixlen, 1); break; default: printf("unhandled AID #%u", aid); goto done; } if (pos == -1) { printf("bad %s prefix", aid2str(aid)); break; } printf(" %s/%u", log_addr(&prefix), prefixlen); data += pos; alen -= pos; } break; case ATTR_EXT_COMMUNITIES: show_ext_community(data, alen); break; case ATTR_LARGE_COMMUNITIES: show_large_community(data, alen); break; case ATTR_ATOMIC_AGGREGATE: default: printf(" len %u", alen); if (alen) { printf(":"); for (i=0; i < alen; i++) printf(" %02x", *(data+i)); } break; } done: printf("%c", EOL0(flag0)); } void show_community(u_char *data, u_int16_t len) { u_int16_t a, v; u_int16_t i; if (len & 0x3) return; for (i = 0; i < len; i += 4) { memcpy(&a, data + i, sizeof(a)); memcpy(&v, data + i + 2, sizeof(v)); a = ntohs(a); v = ntohs(v); if (a == COMMUNITY_WELLKNOWN) switch (v) { case COMMUNITY_GRACEFUL_SHUTDOWN: printf("GRACEFUL_SHUTDOWN"); break; case COMMUNITY_NO_EXPORT: printf("NO_EXPORT"); break; case COMMUNITY_NO_ADVERTISE: printf("NO_ADVERTISE"); break; case COMMUNITY_NO_EXPSUBCONFED: printf("NO_EXPORT_SUBCONFED"); break; case COMMUNITY_NO_PEER: printf("NO_PEER"); break; case COMMUNITY_BLACKHOLE: printf("BLACKHOLE"); break; default: printf("%hu:%hu", a, v); break; } else printf("%hu:%hu", a, v); if (i + 4 < len) printf(" "); } } void show_large_community(u_char *data, u_int16_t len) { u_int32_t a, l1, l2; u_int16_t i; if (len % 12) return; for (i = 0; i < len; i += 12) { memcpy(&a, data + i, sizeof(a)); memcpy(&l1, data + i + 4, sizeof(l1)); memcpy(&l2, data + i + 8, sizeof(l2)); a = ntohl(a); l1 = ntohl(l1); l2 = ntohl(l2); printf("%u:%u:%u", a, l1, l2); if (i + 12 < len) printf(" "); } } void show_ext_community(u_char *data, u_int16_t len) { u_int64_t ext; struct in_addr ip; u_int32_t as4, u32; u_int16_t i, as2, u16; u_int8_t type, subtype; if (len & 0x7) return; for (i = 0; i < len; i += 8) { type = data[i]; subtype = data[i + 1]; printf("%s ", log_ext_subtype(type, subtype)); switch (type) { case EXT_COMMUNITY_TRANS_TWO_AS: memcpy(&as2, data + i + 2, sizeof(as2)); memcpy(&u32, data + i + 4, sizeof(u32)); printf("%s:%u", log_as(ntohs(as2)), ntohl(u32)); break; case EXT_COMMUNITY_TRANS_IPV4: memcpy(&ip, data + i + 2, sizeof(ip)); memcpy(&u16, data + i + 6, sizeof(u16)); printf("%s:%hu", inet_ntoa(ip), ntohs(u16)); break; case EXT_COMMUNITY_TRANS_FOUR_AS: memcpy(&as4, data + i + 2, sizeof(as4)); memcpy(&u16, data + i + 6, sizeof(u16)); printf("%s:%hu", log_as(ntohl(as4)), ntohs(u16)); break; case EXT_COMMUNITY_TRANS_OPAQUE: case EXT_COMMUNITY_TRANS_EVPN: memcpy(&ext, data + i, sizeof(ext)); ext = be64toh(ext) & 0xffffffffffffLL; printf("0x%llx", (unsigned long long)ext); break; case EXT_COMMUNITY_NON_TRANS_OPAQUE: memcpy(&ext, data + i, sizeof(ext)); ext = be64toh(ext) & 0xffffffffffffLL; switch (ext) { case EXT_COMMUNITY_OVS_VALID: printf("valid "); break; case EXT_COMMUNITY_OVS_NOTFOUND: printf("not-found "); break; case EXT_COMMUNITY_OVS_INVALID: printf("invalid "); break; default: printf("0x%llx ", (unsigned long long)ext); break; } break; default: memcpy(&ext, data + i, sizeof(ext)); printf("0x%llx", (unsigned long long)be64toh(ext)); } if (i + 8 < len) printf(", "); } } static char * fmt_mem(long long num) { static char buf[16]; if (fmt_scaled(num, buf) == -1) snprintf(buf, sizeof(buf), "%lldB", num); return (buf); } size_t pt_sizes[AID_MAX] = AID_PTSIZE; int show_rib_memory_msg(struct imsg *imsg) { struct rde_memstats stats; struct rde_hashstats hash; size_t pts = 0; int i; double avg, dev; switch (imsg->hdr.type) { case IMSG_CTL_SHOW_RIB_MEM: memcpy(&stats, imsg->data, sizeof(stats)); printf("RDE memory statistics\n"); for (i = 0; i < AID_MAX; i++) { if (stats.pt_cnt[i] == 0) continue; pts += stats.pt_cnt[i] * pt_sizes[i]; printf("%10lld %s network entries using %s of memory\n", stats.pt_cnt[i], aid_vals[i].name, fmt_mem(stats.pt_cnt[i] * pt_sizes[i])); } printf("%10lld rib entries using %s of memory\n", stats.rib_cnt, fmt_mem(stats.rib_cnt * sizeof(struct rib_entry))); printf("%10lld prefix entries using %s of memory\n", stats.prefix_cnt, fmt_mem(stats.prefix_cnt * sizeof(struct prefix))); printf("%10lld BGP path attribute entries using %s of memory\n", stats.path_cnt, fmt_mem(stats.path_cnt * sizeof(struct rde_aspath))); printf("\t and holding %lld references\n", stats.path_refs); printf("%10lld BGP AS-PATH attribute entries using " "%s of memory\n\t and holding %lld references\n", stats.aspath_cnt, fmt_mem(stats.aspath_size), stats.aspath_refs); printf("%10lld BGP attributes entries using %s of memory\n", stats.attr_cnt, fmt_mem(stats.attr_cnt * sizeof(struct attr))); printf("\t and holding %lld references\n", stats.attr_refs); printf("%10lld BGP attributes using %s of memory\n", stats.attr_dcnt, fmt_mem(stats.attr_data)); printf("%10lld as-set elements in %lld tables using " "%s of memory\n", stats.aset_nmemb, stats.aset_cnt, fmt_mem(stats.aset_size)); printf("%10lld prefix-set elements using %s of memory\n", stats.pset_cnt, fmt_mem(stats.pset_size)); printf("RIB using %s of memory\n", fmt_mem(pts + stats.prefix_cnt * sizeof(struct prefix) + stats.rib_cnt * sizeof(struct rib_entry) + stats.path_cnt * sizeof(struct rde_aspath) + stats.aspath_size + stats.attr_cnt * sizeof(struct attr) + stats.attr_data)); printf("Sets using %s of memory\n", fmt_mem(stats.aset_size + stats.pset_size)); printf("\nRDE hash statistics\n"); break; case IMSG_CTL_SHOW_RIB_HASH: memcpy(&hash, imsg->data, sizeof(hash)); printf("\t%s: size %lld, %lld entries\n", hash.name, hash.num, hash.sum); avg = (double)hash.sum / (double)hash.num; dev = sqrt(fmax(0, hash.sumq / hash.num - avg * avg)); printf("\t min %lld max %lld avg/std-dev = %.3f/%.3f\n", hash.min, hash.max, avg, dev); break; case IMSG_CTL_END: return (1); default: break; } return (0); } void send_filterset(struct imsgbuf *i, struct filter_set_head *set) { struct filter_set *s; while ((s = TAILQ_FIRST(set)) != NULL) { imsg_compose(i, IMSG_FILTER_SET, 0, 0, -1, s, sizeof(struct filter_set)); TAILQ_REMOVE(set, s, entry); free(s); } } const char * get_errstr(u_int8_t errcode, u_int8_t subcode) { static const char *errstr = NULL; if (errcode && errcode < sizeof(errnames)/sizeof(char *)) errstr = errnames[errcode]; switch (errcode) { case ERR_HEADER: if (subcode && subcode < sizeof(suberr_header_names)/sizeof(char *)) errstr = suberr_header_names[subcode]; break; case ERR_OPEN: if (subcode && subcode < sizeof(suberr_open_names)/sizeof(char *)) errstr = suberr_open_names[subcode]; break; case ERR_UPDATE: if (subcode && subcode < sizeof(suberr_update_names)/sizeof(char *)) errstr = suberr_update_names[subcode]; break; case ERR_HOLDTIMEREXPIRED: case ERR_FSM: case ERR_CEASE: break; default: return ("unknown error code"); } return (errstr); } int show_result(struct imsg *imsg) { u_int rescode; if (imsg->hdr.len != IMSG_HEADER_SIZE + sizeof(rescode)) errx(1, "got IMSG_CTL_RESULT with wrong len"); memcpy(&rescode, imsg->data, sizeof(rescode)); if (rescode == 0) printf("request processed\n"); else { if (rescode > sizeof(ctl_res_strerror)/sizeof(ctl_res_strerror[0])) printf("unknown result error code %u\n", rescode); else printf("%s\n", ctl_res_strerror[rescode]); } return (1); } void network_bulk(struct parse_result *res) { struct network_config net; struct filter_set *s = NULL; struct bgpd_addr h; char *line = NULL; size_t linesize = 0; ssize_t linelen; u_int8_t len; FILE *f; if ((f = fdopen(STDIN_FILENO, "r")) == NULL) err(1, "Failed to open stdin\n"); while ((linelen = getline(&line, &linesize, f)) != -1) { char *b, *buf = line; while ((b = strsep(&buf, " \t\n")) != NULL) { if (*b == '\0') /* skip empty tokens */ continue; /* Stop processing after a comment */ if (*b == '#') break; bzero(&net, sizeof(net)); if (parse_prefix(b, strlen(b), &h, &len) != 1) errx(1, "bad prefix: %s", b); net.prefix = h; net.prefixlen = len; net.rd = res->rd; if (res->action == NETWORK_BULK_ADD) { imsg_compose(ibuf, IMSG_NETWORK_ADD, 0, 0, -1, &net, sizeof(net)); TAILQ_FOREACH(s, &res->set, entry) { imsg_compose(ibuf, IMSG_FILTER_SET, 0, 0, -1, s, sizeof(*s)); } imsg_compose(ibuf, IMSG_NETWORK_DONE, 0, 0, -1, NULL, 0); } else imsg_compose(ibuf, IMSG_NETWORK_REMOVE, 0, 0, -1, &net, sizeof(net)); } } free(line); if (ferror(f)) err(1, "getline"); fclose(f); } void show_mrt_dump_neighbors(struct mrt_rib *mr, struct mrt_peer *mp, void *arg) { struct mrt_peer_entry *p; struct in_addr ina; u_int16_t i; ina.s_addr = htonl(mp->bgp_id); printf("view: %s BGP ID: %s Number of peers: %u\n\n", mp->view, inet_ntoa(ina), mp->npeers); printf("%-30s %8s %15s\n", "Neighbor", "AS", "BGP ID"); for (i = 0; i < mp->npeers; i++) { p = &mp->peers[i]; ina.s_addr = htonl(p->bgp_id); printf("%-30s %8u %15s\n", log_addr(&p->addr), p->asnum, inet_ntoa(ina)); } /* we only print the first message */ exit(0); } void show_mrt_dump(struct mrt_rib *mr, struct mrt_peer *mp, void *arg) { struct ctl_show_rib ctl; struct ctl_show_rib_request *req = arg; struct mrt_rib_entry *mre; u_int16_t i, j; for (i = 0; i < mr->nentries; i++) { mre = &mr->entries[i]; bzero(&ctl, sizeof(ctl)); ctl.prefix = mr->prefix; ctl.prefixlen = mr->prefixlen; ctl.lastchange = mre->originated; ctl.true_nexthop = mre->nexthop; ctl.exit_nexthop = mre->nexthop; ctl.origin = mre->origin; ctl.local_pref = mre->local_pref; ctl.med = mre->med; /* weight is not part of the mrt dump so it can't be set */ ctl.aspath_len = mre->aspath_len; if (mre->peer_idx < mp->npeers) { ctl.remote_addr = mp->peers[mre->peer_idx].addr; ctl.remote_id = mp->peers[mre->peer_idx].bgp_id; } /* filter by neighbor */ if (req->neighbor.addr.aid != AID_UNSPEC && memcmp(&req->neighbor.addr, &ctl.remote_addr, sizeof(ctl.remote_addr)) != 0) continue; /* filter by AF */ if (req->aid && req->aid != ctl.prefix.aid) return; /* filter by prefix */ if (req->prefix.aid != AID_UNSPEC) { if (!prefix_compare(&req->prefix, &ctl.prefix, req->prefixlen)) { if (req->flags & F_LONGER) { if (req->prefixlen > ctl.prefixlen) return; } else if (req->prefixlen != ctl.prefixlen) return; } else return; } /* filter by AS */ if (req->as.type != AS_UNDEF && !match_aspath(mre->aspath, mre->aspath_len, &req->as)) continue; if (req->flags & F_CTL_DETAIL) { show_rib_detail(&ctl, mre->aspath, 1, 0); for (j = 0; j < mre->nattrs; j++) show_attr(mre->attrs[j].attr, mre->attrs[j].attr_len, req->flags); } else show_rib_brief(&ctl, mre->aspath); } } void network_mrt_dump(struct mrt_rib *mr, struct mrt_peer *mp, void *arg) { struct ctl_show_rib ctl; struct network_config net; struct ctl_show_rib_request *req = arg; struct mrt_rib_entry *mre; struct ibuf *msg; u_int16_t i, j; for (i = 0; i < mr->nentries; i++) { mre = &mr->entries[i]; bzero(&ctl, sizeof(ctl)); ctl.prefix = mr->prefix; ctl.prefixlen = mr->prefixlen; ctl.lastchange = mre->originated; ctl.true_nexthop = mre->nexthop; ctl.exit_nexthop = mre->nexthop; ctl.origin = mre->origin; ctl.local_pref = mre->local_pref; ctl.med = mre->med; ctl.aspath_len = mre->aspath_len; if (mre->peer_idx < mp->npeers) { ctl.remote_addr = mp->peers[mre->peer_idx].addr; ctl.remote_id = mp->peers[mre->peer_idx].bgp_id; } /* filter by neighbor */ if (req->neighbor.addr.aid != AID_UNSPEC && memcmp(&req->neighbor.addr, &ctl.remote_addr, sizeof(ctl.remote_addr)) != 0) continue; /* filter by AF */ if (req->aid && req->aid != ctl.prefix.aid) return; /* filter by prefix */ if (req->prefix.aid != AID_UNSPEC) { if (!prefix_compare(&req->prefix, &ctl.prefix, req->prefixlen)) { if (req->flags & F_LONGER) { if (req->prefixlen > ctl.prefixlen) return; } else if (req->prefixlen != ctl.prefixlen) return; } else return; } /* filter by AS */ if (req->as.type != AS_UNDEF && !match_aspath(mre->aspath, mre->aspath_len, &req->as)) continue; bzero(&net, sizeof(net)); net.prefix = ctl.prefix; net.prefixlen = ctl.prefixlen; net.type = NETWORK_MRTCLONE; /* XXX rd can't be set and will be 0 */ imsg_compose(ibuf, IMSG_NETWORK_ADD, 0, 0, -1, &net, sizeof(net)); if ((msg = imsg_create(ibuf, IMSG_NETWORK_ASPATH, 0, 0, sizeof(ctl) + mre->aspath_len)) == NULL) errx(1, "imsg_create failure"); if (imsg_add(msg, &ctl, sizeof(ctl)) == -1 || imsg_add(msg, mre->aspath, mre->aspath_len) == -1) errx(1, "imsg_add failure"); imsg_close(ibuf, msg); for (j = 0; j < mre->nattrs; j++) imsg_compose(ibuf, IMSG_NETWORK_ATTR, 0, 0, -1, mre->attrs[j].attr, mre->attrs[j].attr_len); imsg_compose(ibuf, IMSG_NETWORK_DONE, 0, 0, -1, NULL, 0); while (ibuf->w.queued) { if (msgbuf_write(&ibuf->w) <= 0 && errno != EAGAIN) err(1, "write error"); } } } static const char * print_time(struct timespec *t) { static char timebuf[32]; static struct timespec prevtime; struct timespec temp; timespecsub(t, &prevtime, &temp); snprintf(timebuf, sizeof(timebuf), "%lld.%06ld", (long long)temp.tv_sec, temp.tv_nsec / 1000); prevtime = *t; return (timebuf); } void show_mrt_state(struct mrt_bgp_state *ms, void *arg) { printf("%s %s[%u] -> ", print_time(&ms->time), log_addr(&ms->src), ms->src_as); printf("%s[%u]: %s -> %s\n", log_addr(&ms->dst), ms->dst_as, statenames[ms->old_state], statenames[ms->new_state]); } static void print_afi(u_char *p, u_int8_t len) { u_int16_t afi; u_int8_t safi, aid; if (len != 4) { printf("bad length"); return; } /* afi, 2 byte */ memcpy(&afi, p, sizeof(afi)); afi = ntohs(afi); p += 2; /* reserved, 1 byte */ p += 1; /* safi, 1 byte */ memcpy(&safi, p, sizeof(safi)); if (afi2aid(afi, safi, &aid) == -1) printf("unkown afi %u safi %u", afi, safi); else printf("%s", aid2str(aid)); } static void print_capability(u_int8_t capa_code, u_char *p, u_int8_t len) { switch (capa_code) { case CAPA_MP: printf("multiprotocol capability: "); print_afi(p, len); break; case CAPA_REFRESH: printf("route refresh capability"); break; case CAPA_RESTART: printf("graceful restart capability"); /* XXX there is more needed here */ break; case CAPA_AS4BYTE: printf("4-byte AS num capability: "); if (len == 4) { u_int32_t as; memcpy(&as, p, sizeof(as)); as = ntohl(as); printf("AS %u", as); } else printf("bad length"); break; default: printf("unknown capability %u length %u", capa_code, len); break; } } static void print_notification(u_int8_t errcode, u_int8_t subcode) { const char *suberrname = NULL; int uk = 0; switch (errcode) { case ERR_HEADER: if (subcode >= sizeof(suberr_header_names)/sizeof(char *)) uk = 1; else suberrname = suberr_header_names[subcode]; break; case ERR_OPEN: if (subcode >= sizeof(suberr_open_names)/sizeof(char *)) uk = 1; else suberrname = suberr_open_names[subcode]; break; case ERR_UPDATE: if (subcode >= sizeof(suberr_update_names)/sizeof(char *)) uk = 1; else suberrname = suberr_update_names[subcode]; break; case ERR_CEASE: if (subcode >= sizeof(suberr_cease_names)/sizeof(char *)) uk = 1; else suberrname = suberr_cease_names[subcode]; break; case ERR_HOLDTIMEREXPIRED: if (subcode != 0) uk = 1; break; case ERR_FSM: if (subcode >= sizeof(suberr_fsm_names)/sizeof(char *)) uk = 1; else suberrname = suberr_fsm_names[subcode]; break; default: printf("unknown errcode %u, subcode %u", errcode, subcode); return; } if (uk) printf("%s, unknown subcode %u", errnames[errcode], subcode); else { if (suberrname == NULL) printf("%s", errnames[errcode]); else printf("%s, %s", errnames[errcode], suberrname); } } static int show_mrt_capabilities(u_char *p, u_int16_t len) { u_int16_t totlen = len; u_int8_t capa_code, capa_len; while (len > 2) { memcpy(&capa_code, p, sizeof(capa_code)); p += sizeof(capa_code); len -= sizeof(capa_code); memcpy(&capa_len, p, sizeof(capa_len)); p += sizeof(capa_len); len -= sizeof(capa_len); if (len < capa_len) { printf("capa_len %u exceeds remaining length", capa_len); return (-1); } printf("\n "); print_capability(capa_code, p, capa_len); p += capa_len; len -= capa_len; } if (len != 0) { printf("length missmatch while capability parsing"); return (-1); } return (totlen); } static void show_mrt_open(u_char *p, u_int16_t len) { u_int8_t version, optparamlen; u_int16_t short_as, holdtime; struct in_addr bgpid; /* length check up to optparamlen already happened */ memcpy(&version, p, sizeof(version)); p += sizeof(version); len -= sizeof(version); memcpy(&short_as, p, sizeof(short_as)); p += sizeof(short_as); len -= sizeof(short_as); short_as = ntohs(short_as); memcpy(&holdtime, p, sizeof(holdtime)); holdtime = ntohs(holdtime); p += sizeof(holdtime); len -= sizeof(holdtime); memcpy(&bgpid, p, sizeof(bgpid)); p += sizeof(bgpid); len -= sizeof(bgpid); memcpy(&optparamlen, p, sizeof(optparamlen)); p += sizeof(optparamlen); len -= sizeof(optparamlen); printf("\n "); printf("Version: %d AS: %u Holdtime: %u BGP Id: %s Paramlen: %u", version, short_as, holdtime, inet_ntoa(bgpid), optparamlen); if (optparamlen != len) { printf("optional parameter length mismatch"); return; } while (len > 2) { u_int8_t op_type, op_len; int r; memcpy(&op_type, p, sizeof(op_type)); p += sizeof(op_type); len -= sizeof(op_type); memcpy(&op_len, p, sizeof(op_len)); p += sizeof(op_len); len -= sizeof(op_len); printf("\n "); switch (op_type) { case OPT_PARAM_CAPABILITIES: printf("Capabilities: size %u", op_len); r = show_mrt_capabilities(p, op_len); if (r == -1) return; p += r; len -= r; break; case OPT_PARAM_AUTH: default: printf("unsupported optional parameter: type %u", op_type); return; } } if (len != 0) { printf("optional parameter encoding error"); return; } } static void show_mrt_notification(u_char *p, u_int16_t len) { u_int16_t i; u_int8_t errcode, subcode; size_t shutcomm_len; char shutcomm[SHUT_COMM_LEN]; memcpy(&errcode, p, sizeof(errcode)); p += sizeof(errcode); len -= sizeof(errcode); memcpy(&subcode, p, sizeof(subcode)); p += sizeof(subcode); len -= sizeof(subcode); printf("\n "); print_notification(errcode, subcode); if (errcode == ERR_CEASE && (subcode == ERR_CEASE_ADMIN_DOWN || subcode == ERR_CEASE_ADMIN_RESET)) { if (len > 1) { shutcomm_len = *p++; len--; if(len < shutcomm_len) { printf("truncated shutdown reason"); return; } if (shutcomm_len > SHUT_COMM_LEN - 1) { printf("overly long shutdown reason"); return; } memcpy(shutcomm, p, shutcomm_len); shutcomm[shutcomm_len] = '\0'; printf("shutdown reason: \"%s\"", log_shutcomm(shutcomm)); p += shutcomm_len; len -= shutcomm_len; } } if (errcode == ERR_OPEN && subcode == ERR_OPEN_CAPA) { int r; r = show_mrt_capabilities(p, len); if (r == -1) return; p += r; len -= r; } if (len > 0) { printf("\n additional data %u bytes", len); for (i = 0; i < len; i++) { if (i % 16 == 0) printf("\n "); if (i % 8 == 0) printf(" "); printf(" %02X", *p++); } } } static void show_mrt_update(u_char *p, u_int16_t len) { struct bgpd_addr prefix; int pos; u_int16_t wlen, alen; u_int8_t prefixlen; if (len < sizeof(wlen)) { printf("bad length"); return; } memcpy(&wlen, p, sizeof(wlen)); wlen = ntohs(wlen); p += sizeof(wlen); len -= sizeof(wlen); if (len < wlen) { printf("bad withdraw length"); return; } if (wlen > 0) { printf("\n Withdrawn prefixes:"); while (wlen > 0) { if ((pos = nlri_get_prefix(p, wlen, &prefix, &prefixlen)) == -1) { printf("bad withdraw prefix"); return; } printf(" %s/%u", log_addr(&prefix), prefixlen); p += pos; len -= pos; wlen -= pos; } } if (len < sizeof(alen)) { printf("bad length"); return; } memcpy(&alen, p, sizeof(alen)); alen = ntohs(alen); p += sizeof(alen); len -= sizeof(alen); if (len < alen) { printf("bad attribute length"); return; } printf("\n"); /* alen attributes here */ while (alen > 3) { u_int8_t flags; u_int16_t attrlen; flags = p[0]; /* type = p[1]; */ /* get the attribute length */ if (flags & ATTR_EXTLEN) { if (len < sizeof(attrlen) + 2) printf("bad attribute length"); memcpy(&attrlen, &p[2], sizeof(attrlen)); attrlen = ntohs(attrlen); attrlen += sizeof(attrlen) + 2; } else { attrlen = p[2]; attrlen += 1 + 2; } show_attr(p, attrlen, 0); p += attrlen; alen -= attrlen; len -= attrlen; } if (len > 0) { printf(" NLRI prefixes:"); while (len > 0) { if ((pos = nlri_get_prefix(p, len, &prefix, &prefixlen)) == -1) { printf("bad withdraw prefix"); return; } printf(" %s/%u", log_addr(&prefix), prefixlen); p += pos; len -= pos; } } } void show_mrt_msg(struct mrt_bgp_msg *mm, void *arg) { static const u_int8_t marker[MSGSIZE_HEADER_MARKER] = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff }; u_char *p; u_int16_t len; u_int8_t type; printf("%s %s[%u] -> ", print_time(&mm->time), log_addr(&mm->src), mm->src_as); printf("%s[%u]: size %u ", log_addr(&mm->dst), mm->dst_as, mm->msg_len); p = mm->msg; len = mm->msg_len; if (len < MSGSIZE_HEADER) { printf("illegal header length: %u byte\n", len); return; } /* parse BGP message header */ if (memcmp(p, marker, sizeof(marker))) { printf("incorrect marker in BGP message\n"); return; } p += MSGSIZE_HEADER_MARKER; memcpy(&len, p, 2); len = ntohs(len); p += 2; memcpy(&type, p, 1); p += 1; if (len < MSGSIZE_HEADER || len > MAX_PKTSIZE) { printf("illegal header length: %u byte\n", len); return; } switch (type) { case OPEN: printf("%s ", msgtypenames[type]); if (len < MSGSIZE_OPEN_MIN) { printf("illegal length: %u byte\n", len); return; } show_mrt_open(p, len - MSGSIZE_HEADER); break; case NOTIFICATION: printf("%s ", msgtypenames[type]); if (len < MSGSIZE_NOTIFICATION_MIN) { printf("illegal length: %u byte\n", len); return; } show_mrt_notification(p, len - MSGSIZE_HEADER); break; case UPDATE: printf("%s ", msgtypenames[type]); if (len < MSGSIZE_UPDATE_MIN) { printf("illegal length: %u byte\n", len); return; } show_mrt_update(p, len - MSGSIZE_HEADER); break; case KEEPALIVE: printf("%s ", msgtypenames[type]); if (len != MSGSIZE_KEEPALIVE) { printf("illegal length: %u byte\n", len); return; } /* nothing */ break; case RREFRESH: printf("%s ", msgtypenames[type]); if (len != MSGSIZE_RREFRESH) { printf("illegal length: %u byte\n", len); return; } print_afi(p, len); break; default: printf("unknown type %u\n", type); return; } printf("\n"); } const char * msg_type(u_int8_t type) { if (type >= sizeof(msgtypenames)/sizeof(msgtypenames[0])) return "BAD"; return (msgtypenames[type]); } int match_aspath(void *data, u_int16_t len, struct filter_as *f) { u_int8_t *seg; int final; u_int16_t seg_size; u_int8_t i, seg_len; u_int32_t as = 0; if (f->type == AS_EMPTY) { if (len == 0) return (1); else return (0); } seg = data; /* just check the leftmost AS */ if (f->type == AS_PEER && len >= 6) { as = aspath_extract(seg, 0); if (f->as_min == as) return (1); else return (0); } for (; len >= 6; len -= seg_size, seg += seg_size) { seg_len = seg[1]; seg_size = 2 + sizeof(u_int32_t) * seg_len; final = (len == seg_size); if (f->type == AS_SOURCE) { /* * Just extract the rightmost AS * but if that segment is an AS_SET then the rightmost * AS of a previous AS_SEQUENCE segment should be used. * Because of that just look at AS_SEQUENCE segments. */ if (seg[0] == AS_SEQUENCE) as = aspath_extract(seg, seg_len - 1); /* not yet in the final segment */ if (!final) continue; if (f->as_min == as) return (1); else return (0); } /* AS_TRANSIT or AS_ALL */ for (i = 0; i < seg_len; i++) { /* * the source (rightmost) AS is excluded from * AS_TRANSIT matches. */ if (final && i == seg_len - 1 && f->type == AS_TRANSIT) return (0); as = aspath_extract(seg, i); if (f->as_min == as) return (1); } } return (0); }