2 * Copyright (C) 1997, 98, 99 Kunihiro Ishiguro
4 * This file is part of GNU Zebra.
6 * GNU Zebra is free software; you can redistribute it and/or modify it
7 * under the terms of the GNU General Public License as published by the
8 * Free Software Foundation; either version 2, or (at your option) any
11 * GNU Zebra is distributed in the hope that it will be useful, but
12 * WITHOUT ANY WARRANTY; without even the implied warranty of
13 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
14 * General Public License for more details.
16 * You should have received a copy of the GNU General Public License along
17 * with this program; see the file COPYING; if not, write to the Free Software
18 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
28 #include "sockunion.h"
36 #include "lib/route_opaque.h"
42 #include "bgpd/bgpd.h"
43 #include "bgpd/bgp_route.h"
44 #include "bgpd/bgp_attr.h"
45 #include "bgpd/bgp_aspath.h"
46 #include "bgpd/bgp_nexthop.h"
47 #include "bgpd/bgp_zebra.h"
48 #include "bgpd/bgp_fsm.h"
49 #include "bgpd/bgp_debug.h"
50 #include "bgpd/bgp_errors.h"
51 #include "bgpd/bgp_mpath.h"
52 #include "bgpd/bgp_nexthop.h"
53 #include "bgpd/bgp_nht.h"
54 #include "bgpd/bgp_bfd.h"
55 #include "bgpd/bgp_label.h"
57 #include "bgpd/rfapi/rfapi_backend.h"
58 #include "bgpd/rfapi/vnc_export_bgp.h"
60 #include "bgpd/bgp_evpn.h"
61 #include "bgpd/bgp_mplsvpn.h"
62 #include "bgpd/bgp_labelpool.h"
63 #include "bgpd/bgp_pbr.h"
64 #include "bgpd/bgp_evpn_private.h"
65 #include "bgpd/bgp_evpn_mh.h"
66 #include "bgpd/bgp_mac.h"
67 #include "bgpd/bgp_trace.h"
68 #include "bgpd/bgp_community.h"
69 #include "bgpd/bgp_lcommunity.h"
71 /* All information about zebra. */
72 struct zclient
*zclient
= NULL
;
74 /* hook to indicate vrf status change for SNMP */
75 DEFINE_HOOK(bgp_vrf_status_changed
, (struct bgp
*bgp
, struct interface
*ifp
),
78 DEFINE_MTYPE_STATIC(BGPD
, BGP_IF_INFO
, "BGP interface context");
80 /* Can we install into zebra? */
81 static inline bool bgp_install_info_to_zebra(struct bgp
*bgp
)
83 if (zclient
->sock
<= 0)
86 if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp
)) {
88 "%s: No zebra instance to talk to, not installing information",
96 int zclient_num_connects
;
98 /* Router-id update message from zebra. */
99 static int bgp_router_id_update(ZAPI_CALLBACK_ARGS
)
101 struct prefix router_id
;
103 zebra_router_id_update_read(zclient
->ibuf
, &router_id
);
105 if (BGP_DEBUG(zebra
, ZEBRA
))
106 zlog_debug("Rx Router Id update VRF %u Id %pFX", vrf_id
,
109 bgp_router_id_zebra_bump(vrf_id
, &router_id
);
113 /* Nexthop update message from zebra. */
114 static int bgp_read_nexthop_update(ZAPI_CALLBACK_ARGS
)
116 bgp_parse_nexthop_update(cmd
, vrf_id
);
120 /* Set or clear interface on which unnumbered neighbor is configured. This
121 * would in turn cause BGP to initiate or turn off IPv6 RAs on this
124 static void bgp_update_interface_nbrs(struct bgp
*bgp
, struct interface
*ifp
,
125 struct interface
*upd_ifp
)
127 struct listnode
*node
, *nnode
;
130 for (ALL_LIST_ELEMENTS(bgp
->peer
, node
, nnode
, peer
)) {
131 if (peer
->conf_if
&& (strcmp(peer
->conf_if
, ifp
->name
) == 0)) {
134 bgp_zebra_initiate_radv(bgp
, peer
);
136 bgp_zebra_terminate_radv(bgp
, peer
);
143 static int bgp_read_fec_update(ZAPI_CALLBACK_ARGS
)
145 bgp_parse_fec_update();
149 static void bgp_start_interface_nbrs(struct bgp
*bgp
, struct interface
*ifp
)
151 struct listnode
*node
, *nnode
;
154 for (ALL_LIST_ELEMENTS(bgp
->peer
, node
, nnode
, peer
)) {
155 if (peer
->conf_if
&& (strcmp(peer
->conf_if
, ifp
->name
) == 0)
156 && !peer_established(peer
)) {
157 if (peer_active(peer
))
158 BGP_EVENT_ADD(peer
, BGP_Stop
);
159 BGP_EVENT_ADD(peer
, BGP_Start
);
164 static void bgp_nbr_connected_add(struct bgp
*bgp
, struct nbr_connected
*ifc
)
166 struct listnode
*node
;
167 struct connected
*connected
;
168 struct interface
*ifp
;
171 /* Kick-off the FSM for any relevant peers only if there is a
172 * valid local address on the interface.
175 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, node
, connected
)) {
176 p
= connected
->address
;
177 if (p
->family
== AF_INET6
178 && IN6_IS_ADDR_LINKLOCAL(&p
->u
.prefix6
))
184 bgp_start_interface_nbrs(bgp
, ifp
);
187 static void bgp_nbr_connected_delete(struct bgp
*bgp
, struct nbr_connected
*ifc
,
190 struct listnode
*node
, *nnode
;
192 struct interface
*ifp
;
194 for (ALL_LIST_ELEMENTS(bgp
->peer
, node
, nnode
, peer
)) {
196 && (strcmp(peer
->conf_if
, ifc
->ifp
->name
) == 0)) {
197 peer
->last_reset
= PEER_DOWN_NBR_ADDR_DEL
;
198 BGP_EVENT_ADD(peer
, BGP_Stop
);
201 /* Free neighbor also, if we're asked to. */
204 listnode_delete(ifp
->nbr_connected
, ifc
);
205 nbr_connected_free(ifc
);
209 static int bgp_ifp_destroy(struct interface
*ifp
)
213 bgp
= ifp
->vrf
->info
;
215 if (BGP_DEBUG(zebra
, ZEBRA
))
216 zlog_debug("Rx Intf del VRF %u IF %s", ifp
->vrf
->vrf_id
,
220 bgp_update_interface_nbrs(bgp
, ifp
, NULL
);
221 hook_call(bgp_vrf_status_changed
, bgp
, ifp
);
224 bgp_mac_del_mac_entry(ifp
);
229 static int bgp_ifp_up(struct interface
*ifp
)
232 struct nbr_connected
*nc
;
233 struct listnode
*node
, *nnode
;
236 bgp
= ifp
->vrf
->info
;
238 bgp_mac_add_mac_entry(ifp
);
240 if (BGP_DEBUG(zebra
, ZEBRA
))
241 zlog_debug("Rx Intf up VRF %u IF %s", ifp
->vrf
->vrf_id
,
247 for (ALL_LIST_ELEMENTS(ifp
->connected
, node
, nnode
, c
))
248 bgp_connected_add(bgp
, c
);
250 for (ALL_LIST_ELEMENTS(ifp
->nbr_connected
, node
, nnode
, nc
))
251 bgp_nbr_connected_add(bgp
, nc
);
253 hook_call(bgp_vrf_status_changed
, bgp
, ifp
);
259 static int bgp_ifp_down(struct interface
*ifp
)
262 struct nbr_connected
*nc
;
263 struct listnode
*node
, *nnode
;
267 bgp
= ifp
->vrf
->info
;
269 bgp_mac_del_mac_entry(ifp
);
271 if (BGP_DEBUG(zebra
, ZEBRA
))
272 zlog_debug("Rx Intf down VRF %u IF %s", ifp
->vrf
->vrf_id
,
278 for (ALL_LIST_ELEMENTS(ifp
->connected
, node
, nnode
, c
))
279 bgp_connected_delete(bgp
, c
);
281 for (ALL_LIST_ELEMENTS(ifp
->nbr_connected
, node
, nnode
, nc
))
282 bgp_nbr_connected_delete(bgp
, nc
, 1);
284 /* Fast external-failover */
285 if (!CHECK_FLAG(bgp
->flags
, BGP_FLAG_NO_FAST_EXT_FAILOVER
)) {
287 for (ALL_LIST_ELEMENTS(bgp
->peer
, node
, nnode
, peer
)) {
288 /* Take down directly connected peers. */
289 if ((peer
->ttl
!= BGP_DEFAULT_TTL
)
290 && (peer
->gtsm_hops
!= BGP_GTSM_HOPS_CONNECTED
))
293 if (ifp
== peer
->nexthop
.ifp
) {
294 BGP_EVENT_ADD(peer
, BGP_Stop
);
295 peer
->last_reset
= PEER_DOWN_IF_DOWN
;
300 hook_call(bgp_vrf_status_changed
, bgp
, ifp
);
301 bgp_nht_ifp_down(ifp
);
306 static int bgp_interface_address_add(ZAPI_CALLBACK_ARGS
)
308 struct connected
*ifc
;
312 struct listnode
*node
, *nnode
;
316 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
318 ifc
= zebra_interface_address_read(cmd
, zclient
->ibuf
, vrf_id
);
323 if (bgp_debug_zebra(ifc
->address
))
324 zlog_debug("Rx Intf address add VRF %u IF %s addr %pFX", vrf_id
,
325 ifc
->ifp
->name
, ifc
->address
);
330 if (if_is_operative(ifc
->ifp
)) {
331 bgp_connected_add(bgp
, ifc
);
333 /* If we have learnt of any neighbors on this interface,
334 * check to kick off any BGP interface-based neighbors,
335 * but only if this is a link-local address.
337 if (IN6_IS_ADDR_LINKLOCAL(&ifc
->address
->u
.prefix6
)
338 && !list_isempty(ifc
->ifp
->nbr_connected
))
339 bgp_start_interface_nbrs(bgp
, ifc
->ifp
);
343 for (ALL_LIST_ELEMENTS(bgp
->peer
, node
, nnode
, peer
)) {
344 if (addr
->family
== AF_INET
)
348 * If the Peer's interface name matches the
349 * interface name for which BGP received the
350 * update and if the received interface address
351 * is a globalV6 and if the peer is currently
352 * using a v4-mapped-v6 addr or a link local
353 * address, then copy the Rxed global v6 addr
354 * into peer's v6_global and send updates out
355 * with new nexthop addr.
357 if ((peer
->conf_if
&&
358 (strcmp(peer
->conf_if
, ifc
->ifp
->name
) ==
360 !IN6_IS_ADDR_LINKLOCAL(&addr
->u
.prefix6
) &&
362 &peer
->nexthop
.v6_global
)) ||
363 IN6_IS_ADDR_LINKLOCAL(
364 &peer
->nexthop
.v6_global
))) {
366 if (bgp_debug_zebra(ifc
->address
)) {
368 "Update peer %pBP's current intf addr %pI6 and send updates",
373 memcpy(&peer
->nexthop
.v6_global
,
376 FOREACH_AFI_SAFI (afi
, safi
)
377 bgp_announce_route(peer
, afi
,
387 static int bgp_interface_address_delete(ZAPI_CALLBACK_ARGS
)
389 struct listnode
*node
, *nnode
;
390 struct connected
*ifc
;
395 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
397 ifc
= zebra_interface_address_read(cmd
, zclient
->ibuf
, vrf_id
);
402 if (bgp_debug_zebra(ifc
->address
))
403 zlog_debug("Rx Intf address del VRF %u IF %s addr %pFX", vrf_id
,
404 ifc
->ifp
->name
, ifc
->address
);
406 if (bgp
&& if_is_operative(ifc
->ifp
)) {
407 bgp_connected_delete(bgp
, ifc
);
414 * When we are using the v6 global as part of the peering
415 * nexthops and we are removing it, then we need to
416 * clear the peer data saved for that nexthop and
417 * cause a re-announcement of the route. Since
418 * we do not want the peering to bounce.
420 for (ALL_LIST_ELEMENTS(bgp
->peer
, node
, nnode
, peer
)) {
424 if (addr
->family
== AF_INET
)
427 if (!IN6_IS_ADDR_LINKLOCAL(&addr
->u
.prefix6
)
428 && memcmp(&peer
->nexthop
.v6_global
,
429 &addr
->u
.prefix6
, 16)
431 memset(&peer
->nexthop
.v6_global
, 0, 16);
432 FOREACH_AFI_SAFI (afi
, safi
)
433 bgp_announce_route(peer
, afi
, safi
,
439 connected_free(&ifc
);
444 static int bgp_interface_nbr_address_add(ZAPI_CALLBACK_ARGS
)
446 struct nbr_connected
*ifc
= NULL
;
449 ifc
= zebra_interface_nbr_address_read(cmd
, zclient
->ibuf
, vrf_id
);
454 if (bgp_debug_zebra(ifc
->address
))
455 zlog_debug("Rx Intf neighbor add VRF %u IF %s addr %pFX",
456 vrf_id
, ifc
->ifp
->name
, ifc
->address
);
458 if (if_is_operative(ifc
->ifp
)) {
459 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
461 bgp_nbr_connected_add(bgp
, ifc
);
467 static int bgp_interface_nbr_address_delete(ZAPI_CALLBACK_ARGS
)
469 struct nbr_connected
*ifc
= NULL
;
472 ifc
= zebra_interface_nbr_address_read(cmd
, zclient
->ibuf
, vrf_id
);
477 if (bgp_debug_zebra(ifc
->address
))
478 zlog_debug("Rx Intf neighbor del VRF %u IF %s addr %pFX",
479 vrf_id
, ifc
->ifp
->name
, ifc
->address
);
481 if (if_is_operative(ifc
->ifp
)) {
482 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
484 bgp_nbr_connected_delete(bgp
, ifc
, 0);
487 nbr_connected_free(ifc
);
492 /* VRF update for an interface. */
493 static int bgp_interface_vrf_update(ZAPI_CALLBACK_ARGS
)
495 struct interface
*ifp
;
498 struct nbr_connected
*nc
;
499 struct listnode
*node
, *nnode
;
503 ifp
= zebra_interface_vrf_update_read(zclient
->ibuf
, vrf_id
,
508 if (BGP_DEBUG(zebra
, ZEBRA
))
509 zlog_debug("Rx Intf VRF change VRF %u IF %s NewVRF %u", vrf_id
,
510 ifp
->name
, new_vrf_id
);
512 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
515 for (ALL_LIST_ELEMENTS(ifp
->connected
, node
, nnode
, c
))
516 bgp_connected_delete(bgp
, c
);
518 for (ALL_LIST_ELEMENTS(ifp
->nbr_connected
, node
, nnode
, nc
))
519 bgp_nbr_connected_delete(bgp
, nc
, 1);
521 /* Fast external-failover */
522 if (!CHECK_FLAG(bgp
->flags
, BGP_FLAG_NO_FAST_EXT_FAILOVER
)) {
523 for (ALL_LIST_ELEMENTS(bgp
->peer
, node
, nnode
, peer
)) {
524 if ((peer
->ttl
!= BGP_DEFAULT_TTL
)
526 != BGP_GTSM_HOPS_CONNECTED
))
529 if (ifp
== peer
->nexthop
.ifp
)
530 BGP_EVENT_ADD(peer
, BGP_Stop
);
535 if_update_to_new_vrf(ifp
, new_vrf_id
);
537 bgp
= bgp_lookup_by_vrf_id(new_vrf_id
);
541 for (ALL_LIST_ELEMENTS(ifp
->connected
, node
, nnode
, c
))
542 bgp_connected_add(bgp
, c
);
544 for (ALL_LIST_ELEMENTS(ifp
->nbr_connected
, node
, nnode
, nc
))
545 bgp_nbr_connected_add(bgp
, nc
);
547 hook_call(bgp_vrf_status_changed
, bgp
, ifp
);
551 /* Zebra route add and delete treatment. */
552 static int zebra_read_route(ZAPI_CALLBACK_ARGS
)
554 enum nexthop_types_t nhtype
;
555 enum blackhole_type bhtype
= BLACKHOLE_UNSPEC
;
556 struct zapi_route api
;
557 union g_addr nexthop
= {};
562 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
566 if (zapi_route_decode(zclient
->ibuf
, &api
) < 0)
569 /* we completely ignore srcdest routes for now. */
570 if (CHECK_FLAG(api
.message
, ZAPI_MESSAGE_SRCPFX
))
573 /* ignore link-local address. */
574 if (api
.prefix
.family
== AF_INET6
575 && IN6_IS_ADDR_LINKLOCAL(&api
.prefix
.u
.prefix6
))
578 ifindex
= api
.nexthops
[0].ifindex
;
579 nhtype
= api
.nexthops
[0].type
;
581 /* api_nh structure has union of gate and bh_type */
582 if (nhtype
== NEXTHOP_TYPE_BLACKHOLE
) {
583 /* bh_type is only applicable if NEXTHOP_TYPE_BLACKHOLE*/
584 bhtype
= api
.nexthops
[0].bh_type
;
586 nexthop
= api
.nexthops
[0].gate
;
588 add
= (cmd
== ZEBRA_REDISTRIBUTE_ROUTE_ADD
);
591 * The ADD message is actually an UPDATE and there is no
593 * for a prior redistributed route, if any. So, perform an
595 * DEL processing for the same redistributed route from any
599 for (i
= 0; i
< ZEBRA_ROUTE_MAX
; i
++) {
601 bgp_redistribute_delete(bgp
, &api
.prefix
, i
,
605 /* Now perform the add/update. */
606 bgp_redistribute_add(bgp
, &api
.prefix
, &nexthop
, ifindex
,
607 nhtype
, bhtype
, api
.distance
, api
.metric
,
608 api
.type
, api
.instance
, api
.tag
);
610 bgp_redistribute_delete(bgp
, &api
.prefix
, api
.type
,
614 if (bgp_debug_zebra(&api
.prefix
)) {
615 char buf
[PREFIX_STRLEN
];
618 inet_ntop(api
.prefix
.family
, &nexthop
, buf
,
621 "Rx route ADD VRF %u %s[%d] %pFX nexthop %s (type %d if %u) metric %u distance %u tag %" ROUTE_TAG_PRI
,
622 vrf_id
, zebra_route_string(api
.type
),
623 api
.instance
, &api
.prefix
, buf
, nhtype
, ifindex
,
624 api
.metric
, api
.distance
, api
.tag
);
626 zlog_debug("Rx route DEL VRF %u %s[%d] %pFX", vrf_id
,
627 zebra_route_string(api
.type
), api
.instance
,
635 struct interface
*if_lookup_by_ipv4(struct in_addr
*addr
, vrf_id_t vrf_id
)
638 struct listnode
*cnode
;
639 struct interface
*ifp
;
640 struct connected
*connected
;
641 struct prefix_ipv4 p
;
644 vrf
= vrf_lookup_by_id(vrf_id
);
650 p
.prefixlen
= IPV4_MAX_BITLEN
;
652 FOR_ALL_INTERFACES (vrf
, ifp
) {
653 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, cnode
, connected
)) {
654 cp
= connected
->address
;
656 if (cp
->family
== AF_INET
)
657 if (prefix_match(cp
, (struct prefix
*)&p
))
664 struct interface
*if_lookup_by_ipv4_exact(struct in_addr
*addr
, vrf_id_t vrf_id
)
667 struct listnode
*cnode
;
668 struct interface
*ifp
;
669 struct connected
*connected
;
672 vrf
= vrf_lookup_by_id(vrf_id
);
676 FOR_ALL_INTERFACES (vrf
, ifp
) {
677 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, cnode
, connected
)) {
678 cp
= connected
->address
;
680 if (cp
->family
== AF_INET
)
681 if (IPV4_ADDR_SAME(&cp
->u
.prefix4
, addr
))
688 struct interface
*if_lookup_by_ipv6(struct in6_addr
*addr
, ifindex_t ifindex
,
692 struct listnode
*cnode
;
693 struct interface
*ifp
;
694 struct connected
*connected
;
695 struct prefix_ipv6 p
;
698 vrf
= vrf_lookup_by_id(vrf_id
);
704 p
.prefixlen
= IPV6_MAX_BITLEN
;
706 FOR_ALL_INTERFACES (vrf
, ifp
) {
707 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, cnode
, connected
)) {
708 cp
= connected
->address
;
710 if (cp
->family
== AF_INET6
)
711 if (prefix_match(cp
, (struct prefix
*)&p
)) {
712 if (IN6_IS_ADDR_LINKLOCAL(
714 if (ifindex
== ifp
->ifindex
)
724 struct interface
*if_lookup_by_ipv6_exact(struct in6_addr
*addr
,
725 ifindex_t ifindex
, vrf_id_t vrf_id
)
728 struct listnode
*cnode
;
729 struct interface
*ifp
;
730 struct connected
*connected
;
733 vrf
= vrf_lookup_by_id(vrf_id
);
737 FOR_ALL_INTERFACES (vrf
, ifp
) {
738 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, cnode
, connected
)) {
739 cp
= connected
->address
;
741 if (cp
->family
== AF_INET6
)
742 if (IPV6_ADDR_SAME(&cp
->u
.prefix6
, addr
)) {
743 if (IN6_IS_ADDR_LINKLOCAL(
745 if (ifindex
== ifp
->ifindex
)
755 static int if_get_ipv6_global(struct interface
*ifp
, struct in6_addr
*addr
)
757 struct listnode
*cnode
;
758 struct connected
*connected
;
761 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, cnode
, connected
)) {
762 cp
= connected
->address
;
764 if (cp
->family
== AF_INET6
)
765 if (!IN6_IS_ADDR_LINKLOCAL(&cp
->u
.prefix6
)) {
766 memcpy(addr
, &cp
->u
.prefix6
, IPV6_MAX_BYTELEN
);
773 static bool if_get_ipv6_local(struct interface
*ifp
, struct in6_addr
*addr
)
775 struct listnode
*cnode
;
776 struct connected
*connected
;
779 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, cnode
, connected
)) {
780 cp
= connected
->address
;
782 if (cp
->family
== AF_INET6
)
783 if (IN6_IS_ADDR_LINKLOCAL(&cp
->u
.prefix6
)) {
784 memcpy(addr
, &cp
->u
.prefix6
, IPV6_MAX_BYTELEN
);
791 static int if_get_ipv4_address(struct interface
*ifp
, struct in_addr
*addr
)
793 struct listnode
*cnode
;
794 struct connected
*connected
;
797 for (ALL_LIST_ELEMENTS_RO(ifp
->connected
, cnode
, connected
)) {
798 cp
= connected
->address
;
799 if ((cp
->family
== AF_INET
)
800 && !ipv4_martian(&(cp
->u
.prefix4
))) {
801 *addr
= cp
->u
.prefix4
;
809 bool bgp_zebra_nexthop_set(union sockunion
*local
, union sockunion
*remote
,
810 struct bgp_nexthop
*nexthop
, struct peer
*peer
)
813 struct interface
*ifp
= NULL
;
814 bool v6_ll_avail
= true;
816 memset(nexthop
, 0, sizeof(struct bgp_nexthop
));
823 if (local
->sa
.sa_family
== AF_INET
) {
824 nexthop
->v4
= local
->sin
.sin_addr
;
826 ifp
= if_lookup_by_name(peer
->update_if
,
829 ifp
= if_lookup_by_ipv4_exact(&local
->sin
.sin_addr
,
832 if (local
->sa
.sa_family
== AF_INET6
) {
833 memcpy(&nexthop
->v6_global
, &local
->sin6
.sin6_addr
, IPV6_MAX_BYTELEN
);
834 if (IN6_IS_ADDR_LINKLOCAL(&local
->sin6
.sin6_addr
)) {
835 if (peer
->conf_if
|| peer
->ifname
)
836 ifp
= if_lookup_by_name(peer
->conf_if
840 else if (peer
->update_if
)
841 ifp
= if_lookup_by_name(peer
->update_if
,
843 } else if (peer
->update_if
)
844 ifp
= if_lookup_by_name(peer
->update_if
,
847 ifp
= if_lookup_by_ipv6_exact(&local
->sin6
.sin6_addr
,
848 local
->sin6
.sin6_scope_id
,
854 * BGP views do not currently get proper data
855 * from zebra( when attached ) to be able to
856 * properly resolve nexthops, so give this
857 * instance type a pass.
859 if (peer
->bgp
->inst_type
== BGP_INSTANCE_TYPE_VIEW
)
862 * If we have no interface data but we have established
863 * some connection w/ zebra than something has gone
864 * terribly terribly wrong here, so say this failed
865 * If we do not any zebra connection then not
866 * having a ifp pointer is ok.
868 return zclient_num_connects
? false : true;
873 /* IPv4 connection, fetch and store IPv6 local address(es) if any. */
874 if (local
->sa
.sa_family
== AF_INET
) {
876 ret
= if_get_ipv6_global(ifp
, &nexthop
->v6_global
);
879 /* There is no global nexthop. Use link-local address as
881 * global and link-local nexthop. In this scenario, the
883 * for interop is that the network admin would use a
885 * specify the global IPv6 nexthop.
888 if_get_ipv6_local(ifp
, &nexthop
->v6_global
);
889 memcpy(&nexthop
->v6_local
, &nexthop
->v6_global
,
893 if_get_ipv6_local(ifp
, &nexthop
->v6_local
);
896 * If we are a v4 connection and we are not doing unnumbered
897 * not having a v6 LL address is ok
899 if (!v6_ll_avail
&& !peer
->conf_if
)
901 if (if_lookup_by_ipv4(&remote
->sin
.sin_addr
, peer
->bgp
->vrf_id
))
902 peer
->shared_network
= 1;
904 peer
->shared_network
= 0;
907 /* IPv6 connection, fetch and store IPv4 local address if any. */
908 if (local
->sa
.sa_family
== AF_INET6
) {
909 struct interface
*direct
= NULL
;
912 ret
= if_get_ipv4_address(ifp
, &nexthop
->v4
);
913 if (!ret
&& peer
->local_id
.s_addr
!= INADDR_ANY
)
914 nexthop
->v4
= peer
->local_id
;
917 if (!IN6_IS_ADDR_LINKLOCAL(&local
->sin6
.sin6_addr
)) {
918 memcpy(&nexthop
->v6_global
, &local
->sin6
.sin6_addr
,
921 /* If directly connected set link-local address. */
922 direct
= if_lookup_by_ipv6(&remote
->sin6
.sin6_addr
,
923 remote
->sin6
.sin6_scope_id
,
926 v6_ll_avail
= if_get_ipv6_local(
927 ifp
, &nexthop
->v6_local
);
929 * It's fine to not have a v6 LL when using
930 * update-source loopback/vrf
932 if (!v6_ll_avail
&& if_is_loopback(ifp
))
934 else if (!v6_ll_avail
) {
936 EC_BGP_NO_LL_ADDRESS_AVAILABLE
,
937 "Interface: %s does not have a v6 LL address associated with it, waiting until one is created for it",
941 /* Link-local address. */
943 ret
= if_get_ipv6_global(ifp
, &nexthop
->v6_global
);
945 /* If there is no global address. Set link-local
947 global. I know this break RFC specification... */
948 /* In this scenario, the expectation for interop is that
950 * network admin would use a route-map to specify the
955 memcpy(&nexthop
->v6_global
,
956 &local
->sin6
.sin6_addr
,
958 /* Always set the link-local address */
959 memcpy(&nexthop
->v6_local
, &local
->sin6
.sin6_addr
,
963 if (IN6_IS_ADDR_LINKLOCAL(&local
->sin6
.sin6_addr
)
964 || if_lookup_by_ipv6(&remote
->sin6
.sin6_addr
,
965 remote
->sin6
.sin6_scope_id
,
967 peer
->shared_network
= 1;
969 peer
->shared_network
= 0;
972 /* KAME stack specific treatment. */
974 if (IN6_IS_ADDR_LINKLOCAL(&nexthop
->v6_global
)
975 && IN6_LINKLOCAL_IFINDEX(nexthop
->v6_global
)) {
976 SET_IN6_LINKLOCAL_IFINDEX(nexthop
->v6_global
, 0);
978 if (IN6_IS_ADDR_LINKLOCAL(&nexthop
->v6_local
)
979 && IN6_LINKLOCAL_IFINDEX(nexthop
->v6_local
)) {
980 SET_IN6_LINKLOCAL_IFINDEX(nexthop
->v6_local
, 0);
984 /* If we have identified the local interface, there is no error for now.
989 static struct in6_addr
*
990 bgp_path_info_to_ipv6_nexthop(struct bgp_path_info
*path
, ifindex_t
*ifindex
)
992 struct in6_addr
*nexthop
= NULL
;
994 /* Only global address nexthop exists. */
995 if (path
->attr
->mp_nexthop_len
== BGP_ATTR_NHLEN_IPV6_GLOBAL
996 || path
->attr
->mp_nexthop_len
== BGP_ATTR_NHLEN_VPNV6_GLOBAL
) {
997 nexthop
= &path
->attr
->mp_nexthop_global
;
998 if (IN6_IS_ADDR_LINKLOCAL(nexthop
))
999 *ifindex
= path
->attr
->nh_ifindex
;
1002 /* If both global and link-local address present. */
1003 if (path
->attr
->mp_nexthop_len
== BGP_ATTR_NHLEN_IPV6_GLOBAL_AND_LL
1004 || path
->attr
->mp_nexthop_len
1005 == BGP_ATTR_NHLEN_VPNV6_GLOBAL_AND_LL
) {
1006 /* Check if route-map is set to prefer global over link-local */
1007 if (path
->attr
->mp_nexthop_prefer_global
) {
1008 nexthop
= &path
->attr
->mp_nexthop_global
;
1009 if (IN6_IS_ADDR_LINKLOCAL(nexthop
))
1010 *ifindex
= path
->attr
->nh_ifindex
;
1012 /* Workaround for Cisco's nexthop bug. */
1013 if (IN6_IS_ADDR_UNSPECIFIED(
1014 &path
->attr
->mp_nexthop_global
)
1015 && path
->peer
->su_remote
1016 && path
->peer
->su_remote
->sa
.sa_family
1019 &path
->peer
->su_remote
->sin6
.sin6_addr
;
1020 if (IN6_IS_ADDR_LINKLOCAL(nexthop
))
1021 *ifindex
= path
->peer
->nexthop
.ifp
1024 nexthop
= &path
->attr
->mp_nexthop_local
;
1025 if (IN6_IS_ADDR_LINKLOCAL(nexthop
))
1026 *ifindex
= path
->attr
->nh_lla_ifindex
;
1034 static bool bgp_table_map_apply(struct route_map
*map
, const struct prefix
*p
,
1035 struct bgp_path_info
*path
)
1037 route_map_result_t ret
;
1039 ret
= route_map_apply(map
, p
, path
);
1040 bgp_attr_flush(path
->attr
);
1042 if (ret
!= RMAP_DENYMATCH
)
1045 if (bgp_debug_zebra(p
)) {
1046 if (p
->family
== AF_INET
) {
1048 "Zebra rmap deny: IPv4 route %pFX nexthop %pI4",
1049 p
, &path
->attr
->nexthop
);
1051 if (p
->family
== AF_INET6
) {
1053 struct in6_addr
*nexthop
;
1055 nexthop
= bgp_path_info_to_ipv6_nexthop(path
, &ifindex
);
1057 "Zebra rmap deny: IPv6 route %pFX nexthop %pI6",
1064 static struct thread
*bgp_tm_thread_connect
;
1065 static bool bgp_tm_status_connected
;
1066 static bool bgp_tm_chunk_obtained
;
1067 #define BGP_FLOWSPEC_TABLE_CHUNK 100000
1068 static uint32_t bgp_tm_min
, bgp_tm_max
, bgp_tm_chunk_size
;
1069 struct bgp
*bgp_tm_bgp
;
1071 static void bgp_zebra_tm_connect(struct thread
*t
)
1073 struct zclient
*zclient
;
1074 int delay
= 10, ret
= 0;
1076 zclient
= THREAD_ARG(t
);
1077 if (bgp_tm_status_connected
&& zclient
->sock
> 0)
1080 bgp_tm_status_connected
= false;
1081 ret
= tm_table_manager_connect(zclient
);
1084 zlog_info("Error connecting to table manager!");
1085 bgp_tm_status_connected
= false;
1087 if (!bgp_tm_status_connected
)
1088 zlog_debug("Connecting to table manager. Success");
1089 bgp_tm_status_connected
= true;
1090 if (!bgp_tm_chunk_obtained
) {
1091 if (bgp_zebra_get_table_range(bgp_tm_chunk_size
,
1093 &bgp_tm_max
) >= 0) {
1094 bgp_tm_chunk_obtained
= true;
1095 /* parse non installed entries */
1096 bgp_zebra_announce_table(bgp_tm_bgp
, AFI_IP
, SAFI_FLOWSPEC
);
1100 thread_add_timer(bm
->master
, bgp_zebra_tm_connect
, zclient
, delay
,
1101 &bgp_tm_thread_connect
);
1104 bool bgp_zebra_tm_chunk_obtained(void)
1106 return bgp_tm_chunk_obtained
;
1109 uint32_t bgp_zebra_tm_get_id(void)
1111 static int table_id
;
1113 if (!bgp_tm_chunk_obtained
)
1115 return bgp_tm_min
++;
1118 void bgp_zebra_init_tm_connect(struct bgp
*bgp
)
1122 /* if already set, do nothing
1124 if (bgp_tm_thread_connect
!= NULL
)
1126 bgp_tm_status_connected
= false;
1127 bgp_tm_chunk_obtained
= false;
1128 bgp_tm_min
= bgp_tm_max
= 0;
1129 bgp_tm_chunk_size
= BGP_FLOWSPEC_TABLE_CHUNK
;
1131 thread_add_timer(bm
->master
, bgp_zebra_tm_connect
, zclient
, delay
,
1132 &bgp_tm_thread_connect
);
1135 int bgp_zebra_get_table_range(uint32_t chunk_size
,
1136 uint32_t *start
, uint32_t *end
)
1140 if (!bgp_tm_status_connected
)
1142 ret
= tm_get_table_chunk(zclient
, chunk_size
, start
, end
);
1144 flog_err(EC_BGP_TABLE_CHUNK
,
1145 "BGP: Error getting table chunk %u", chunk_size
);
1148 zlog_info("BGP: Table Manager returns range from chunk %u is [%u %u]",
1149 chunk_size
, *start
, *end
);
1153 static bool update_ipv4nh_for_route_install(int nh_othervrf
, struct bgp
*nh_bgp
,
1154 struct in_addr
*nexthop
,
1155 struct attr
*attr
, bool is_evpn
,
1156 struct zapi_nexthop
*api_nh
)
1158 api_nh
->gate
.ipv4
= *nexthop
;
1159 api_nh
->vrf_id
= nh_bgp
->vrf_id
;
1161 /* Need to set fields appropriately for EVPN routes imported into
1162 * a VRF (which are programmed as onlink on l3-vni SVI) as well as
1163 * connected routes leaked into a VRF.
1165 if (attr
->nh_type
== NEXTHOP_TYPE_BLACKHOLE
) {
1166 api_nh
->type
= attr
->nh_type
;
1167 api_nh
->bh_type
= attr
->bh_type
;
1168 } else if (is_evpn
) {
1170 * If the nexthop is EVPN overlay index gateway IP,
1171 * treat the nexthop as NEXTHOP_TYPE_IPV4
1172 * Else, mark the nexthop as onlink.
1174 if (attr
->evpn_overlay
.type
== OVERLAY_INDEX_GATEWAY_IP
)
1175 api_nh
->type
= NEXTHOP_TYPE_IPV4
;
1177 api_nh
->type
= NEXTHOP_TYPE_IPV4_IFINDEX
;
1178 SET_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_EVPN
);
1179 SET_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_ONLINK
);
1180 api_nh
->ifindex
= nh_bgp
->l3vni_svi_ifindex
;
1182 } else if (nh_othervrf
&& api_nh
->gate
.ipv4
.s_addr
== INADDR_ANY
) {
1183 api_nh
->type
= NEXTHOP_TYPE_IFINDEX
;
1184 api_nh
->ifindex
= attr
->nh_ifindex
;
1186 api_nh
->type
= NEXTHOP_TYPE_IPV4
;
1191 static bool update_ipv6nh_for_route_install(int nh_othervrf
, struct bgp
*nh_bgp
,
1192 struct in6_addr
*nexthop
,
1194 struct bgp_path_info
*pi
,
1195 struct bgp_path_info
*best_pi
,
1197 struct zapi_nexthop
*api_nh
)
1202 api_nh
->vrf_id
= nh_bgp
->vrf_id
;
1204 if (attr
->nh_type
== NEXTHOP_TYPE_BLACKHOLE
) {
1205 api_nh
->type
= attr
->nh_type
;
1206 api_nh
->bh_type
= attr
->bh_type
;
1207 } else if (is_evpn
) {
1209 * If the nexthop is EVPN overlay index gateway IP,
1210 * treat the nexthop as NEXTHOP_TYPE_IPV4
1211 * Else, mark the nexthop as onlink.
1213 if (attr
->evpn_overlay
.type
== OVERLAY_INDEX_GATEWAY_IP
)
1214 api_nh
->type
= NEXTHOP_TYPE_IPV6
;
1216 api_nh
->type
= NEXTHOP_TYPE_IPV6_IFINDEX
;
1217 SET_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_EVPN
);
1218 SET_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_ONLINK
);
1219 api_nh
->ifindex
= nh_bgp
->l3vni_svi_ifindex
;
1221 } else if (nh_othervrf
) {
1222 if (IN6_IS_ADDR_UNSPECIFIED(nexthop
)) {
1223 api_nh
->type
= NEXTHOP_TYPE_IFINDEX
;
1224 api_nh
->ifindex
= attr
->nh_ifindex
;
1225 } else if (IN6_IS_ADDR_LINKLOCAL(nexthop
)) {
1228 api_nh
->type
= NEXTHOP_TYPE_IPV6_IFINDEX
;
1229 api_nh
->ifindex
= ifindex
;
1231 api_nh
->type
= NEXTHOP_TYPE_IPV6
;
1232 api_nh
->ifindex
= 0;
1235 if (IN6_IS_ADDR_LINKLOCAL(nexthop
)) {
1237 && attr
->mp_nexthop_len
1238 == BGP_ATTR_NHLEN_IPV6_GLOBAL_AND_LL
)
1239 if (pi
->peer
->nexthop
.ifp
)
1241 pi
->peer
->nexthop
.ifp
->ifindex
;
1243 if (pi
->peer
->conf_if
)
1244 ifindex
= pi
->peer
->ifp
->ifindex
;
1245 else if (pi
->peer
->ifname
)
1246 ifindex
= ifname2ifindex(
1248 pi
->peer
->bgp
->vrf_id
);
1249 else if (pi
->peer
->nexthop
.ifp
)
1251 pi
->peer
->nexthop
.ifp
->ifindex
;
1256 api_nh
->type
= NEXTHOP_TYPE_IPV6_IFINDEX
;
1257 api_nh
->ifindex
= ifindex
;
1259 api_nh
->type
= NEXTHOP_TYPE_IPV6
;
1260 api_nh
->ifindex
= 0;
1263 /* api_nh structure has union of gate and bh_type */
1264 if (nexthop
&& api_nh
->type
!= NEXTHOP_TYPE_BLACKHOLE
)
1265 api_nh
->gate
.ipv6
= *nexthop
;
1270 static bool bgp_zebra_use_nhop_weighted(struct bgp
*bgp
, struct attr
*attr
,
1271 uint64_t tot_bw
, uint32_t *nh_weight
)
1277 /* zero link-bandwidth and link-bandwidth not present are treated
1278 * as the same situation.
1281 /* the only situations should be if we're either told
1282 * to skip or use default weight.
1284 if (bgp
->lb_handling
== BGP_LINK_BW_SKIP_MISSING
)
1286 *nh_weight
= BGP_ZEBRA_DEFAULT_NHOP_WEIGHT
;
1288 tmp
= (uint64_t)bw
* 100;
1289 *nh_weight
= ((uint32_t)(tmp
/ tot_bw
));
1295 void bgp_zebra_announce(struct bgp_dest
*dest
, const struct prefix
*p
,
1296 struct bgp_path_info
*info
, struct bgp
*bgp
, afi_t afi
,
1299 struct zapi_route api
= { 0 };
1300 struct zapi_nexthop
*api_nh
;
1302 unsigned int valid_nh_count
= 0;
1303 bool allow_recursion
= false;
1306 struct bgp_path_info
*mpinfo
;
1307 struct bgp
*bgp_orig
;
1309 struct attr local_attr
;
1310 struct bgp_path_info local_info
;
1311 struct bgp_path_info
*mpinfo_cp
= &local_info
;
1314 struct bgp_sid_info
*sid_info
;
1315 int nh_othervrf
= 0;
1316 bool nh_updated
= false;
1318 uint64_t cum_bw
= 0;
1319 uint32_t nhg_id
= 0;
1325 /* Don't try to install if we're not connected to Zebra or Zebra doesn't
1326 * know of this instance.
1328 if (!bgp_install_info_to_zebra(bgp
))
1331 if (bgp
->main_zebra_update_hold
)
1334 if (safi
== SAFI_FLOWSPEC
) {
1335 bgp_pbr_update_entry(bgp
, bgp_dest_get_prefix(dest
), info
, afi
,
1341 * vrf leaking support (will have only one nexthop)
1343 if (info
->extra
&& info
->extra
->bgp_orig
)
1346 /* Make Zebra API structure. */
1347 api
.vrf_id
= bgp
->vrf_id
;
1348 api
.type
= ZEBRA_ROUTE_BGP
;
1351 SET_FLAG(api
.message
, ZAPI_MESSAGE_NEXTHOP
);
1355 if (info
->type
== ZEBRA_ROUTE_BGP
1356 && info
->sub_type
== BGP_ROUTE_IMPORTED
) {
1358 /* Obtain peer from parent */
1359 if (info
->extra
&& info
->extra
->parent
)
1360 peer
= ((struct bgp_path_info
*)(info
->extra
->parent
))
1364 tag
= info
->attr
->tag
;
1366 if (peer
->sort
== BGP_PEER_IBGP
|| peer
->sort
== BGP_PEER_CONFED
1367 || info
->sub_type
== BGP_ROUTE_AGGREGATE
) {
1368 SET_FLAG(api
.flags
, ZEBRA_FLAG_IBGP
);
1369 SET_FLAG(api
.flags
, ZEBRA_FLAG_ALLOW_RECURSION
);
1372 if ((peer
->sort
== BGP_PEER_EBGP
&& peer
->ttl
!= BGP_DEFAULT_TTL
)
1373 || CHECK_FLAG(peer
->flags
, PEER_FLAG_DISABLE_CONNECTED_CHECK
)
1374 || CHECK_FLAG(bgp
->flags
, BGP_FLAG_DISABLE_NH_CONNECTED_CHK
))
1376 allow_recursion
= true;
1378 if (info
->attr
->rmap_table_id
) {
1379 SET_FLAG(api
.message
, ZAPI_MESSAGE_TABLEID
);
1380 api
.tableid
= info
->attr
->rmap_table_id
;
1383 if (CHECK_FLAG(info
->attr
->flag
, ATTR_FLAG_BIT(BGP_ATTR_SRTE_COLOR
)))
1384 SET_FLAG(api
.message
, ZAPI_MESSAGE_SRTE
);
1386 /* Metric is currently based on the best-path only */
1387 metric
= info
->attr
->med
;
1389 /* Determine if we're doing weighted ECMP or not */
1390 do_wt_ecmp
= bgp_path_info_mpath_chkwtd(bgp
, info
);
1392 cum_bw
= bgp_path_info_mpath_cumbw(info
);
1394 /* EVPN MAC-IP routes are installed with a L3 NHG id */
1395 if (bgp_evpn_path_es_use_nhg(bgp
, info
, &nhg_id
)) {
1399 SET_FLAG(api
.message
, ZAPI_MESSAGE_NHG
);
1404 for (; mpinfo
; mpinfo
= bgp_path_info_mpath_next(mpinfo
)) {
1408 if (valid_nh_count
>= multipath_num
)
1411 *mpinfo_cp
= *mpinfo
;
1414 /* Get nexthop address-family */
1415 if (p
->family
== AF_INET
&&
1416 !BGP_ATTR_MP_NEXTHOP_LEN_IP6(mpinfo_cp
->attr
))
1417 nh_family
= AF_INET
;
1418 else if (p
->family
== AF_INET6
||
1419 (p
->family
== AF_INET
&&
1420 BGP_ATTR_MP_NEXTHOP_LEN_IP6(mpinfo_cp
->attr
)))
1421 nh_family
= AF_INET6
;
1425 /* If processing for weighted ECMP, determine the next hop's
1426 * weight. Based on user setting, we may skip the next hop
1427 * in some situations.
1430 if (!bgp_zebra_use_nhop_weighted(bgp
, mpinfo
->attr
,
1431 cum_bw
, &nh_weight
))
1434 api_nh
= &api
.nexthops
[valid_nh_count
];
1436 if (CHECK_FLAG(info
->attr
->flag
,
1437 ATTR_FLAG_BIT(BGP_ATTR_SRTE_COLOR
)))
1438 api_nh
->srte_color
= info
->attr
->srte_color
;
1440 if (bgp_debug_zebra(&api
.prefix
)) {
1441 if (mpinfo
->extra
) {
1442 zlog_debug("%s: p=%pFX, bgp_is_valid_label: %d",
1445 &mpinfo
->extra
->label
[0]));
1448 "%s: p=%pFX, extra is NULL, no label",
1453 if (bgp
->table_map
[afi
][safi
].name
) {
1454 /* Copy info and attributes, so the route-map
1455 apply doesn't modify the BGP route info. */
1456 local_attr
= *mpinfo
->attr
;
1457 mpinfo_cp
->attr
= &local_attr
;
1458 if (!bgp_table_map_apply(bgp
->table_map
[afi
][safi
].map
,
1462 /* metric/tag is only allowed to be
1463 * overridden on 1st nexthop */
1464 if (mpinfo
== info
) {
1465 metric
= mpinfo_cp
->attr
->med
;
1466 tag
= mpinfo_cp
->attr
->tag
;
1470 BGP_ORIGINAL_UPDATE(bgp_orig
, mpinfo
, bgp
);
1472 if (nh_family
== AF_INET
) {
1473 is_evpn
= is_route_parent_evpn(mpinfo
);
1475 nh_updated
= update_ipv4nh_for_route_install(
1476 nh_othervrf
, bgp_orig
,
1477 &mpinfo_cp
->attr
->nexthop
, mpinfo_cp
->attr
,
1480 ifindex_t ifindex
= IFINDEX_INTERNAL
;
1481 struct in6_addr
*nexthop
;
1483 nexthop
= bgp_path_info_to_ipv6_nexthop(mpinfo_cp
,
1486 is_evpn
= is_route_parent_evpn(mpinfo
);
1489 nh_updated
= update_ipv4nh_for_route_install(
1490 nh_othervrf
, bgp_orig
,
1491 &mpinfo_cp
->attr
->nexthop
,
1492 mpinfo_cp
->attr
, is_evpn
, api_nh
);
1494 nh_updated
= update_ipv6nh_for_route_install(
1495 nh_othervrf
, bgp_orig
, nexthop
, ifindex
,
1496 mpinfo
, info
, is_evpn
, api_nh
);
1499 /* Did we get proper nexthop info to update zebra? */
1503 /* Allow recursion if it is a multipath group with both
1504 * eBGP and iBGP paths.
1506 if (!allow_recursion
1507 && CHECK_FLAG(bgp
->flags
, BGP_FLAG_PEERTYPE_MULTIPATH_RELAX
)
1508 && (mpinfo
->peer
->sort
== BGP_PEER_IBGP
1509 || mpinfo
->peer
->sort
== BGP_PEER_CONFED
))
1510 allow_recursion
= true;
1512 if (mpinfo
->extra
&&
1513 bgp_is_valid_label(&mpinfo
->extra
->label
[0]) &&
1514 !CHECK_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_EVPN
)) {
1515 mpls_lse_decode(mpinfo
->extra
->label
[0], &label
, &ttl
,
1518 SET_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_LABEL
);
1520 api_nh
->label_num
= 1;
1521 api_nh
->labels
[0] = label
;
1525 && mpinfo
->attr
->evpn_overlay
.type
1526 != OVERLAY_INDEX_GATEWAY_IP
)
1527 memcpy(&api_nh
->rmac
, &(mpinfo
->attr
->rmac
),
1528 sizeof(struct ethaddr
));
1530 api_nh
->weight
= nh_weight
;
1532 if (mpinfo
->extra
&&
1533 bgp_is_valid_label(&mpinfo
->extra
->label
[0]) &&
1534 !sid_zero(&mpinfo
->extra
->sid
[0].sid
) &&
1535 !CHECK_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_EVPN
)) {
1536 sid_info
= &mpinfo
->extra
->sid
[0];
1538 memcpy(&api_nh
->seg6_segs
, &sid_info
->sid
,
1539 sizeof(api_nh
->seg6_segs
));
1541 if (sid_info
->transposition_len
!= 0) {
1542 mpls_lse_decode(mpinfo
->extra
->label
[0], &label
,
1545 if (label
< MPLS_LABEL_UNRESERVED_MIN
) {
1546 if (bgp_debug_zebra(&api
.prefix
))
1548 "skip invalid SRv6 routes: transposition scheme is used, but label is too small");
1552 transpose_sid(&api_nh
->seg6_segs
, label
,
1553 sid_info
->transposition_offset
,
1554 sid_info
->transposition_len
);
1557 SET_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_SEG6
);
1563 is_add
= (valid_nh_count
|| nhg_id
) ? true : false;
1565 if (is_add
&& CHECK_FLAG(bm
->flags
, BM_FLAG_SEND_EXTRA_DATA_TO_ZEBRA
)) {
1566 struct bgp_zebra_opaque bzo
= {};
1567 const char *reason
=
1568 bgp_path_selection_reason2str(dest
->reason
);
1570 strlcpy(bzo
.aspath
, info
->attr
->aspath
->str
,
1571 sizeof(bzo
.aspath
));
1573 if (info
->attr
->flag
& ATTR_FLAG_BIT(BGP_ATTR_COMMUNITIES
))
1574 strlcpy(bzo
.community
,
1575 bgp_attr_get_community(info
->attr
)->str
,
1576 sizeof(bzo
.community
));
1578 if (info
->attr
->flag
1579 & ATTR_FLAG_BIT(BGP_ATTR_LARGE_COMMUNITIES
))
1580 strlcpy(bzo
.lcommunity
,
1581 bgp_attr_get_lcommunity(info
->attr
)->str
,
1582 sizeof(bzo
.lcommunity
));
1584 strlcpy(bzo
.selection_reason
, reason
,
1585 sizeof(bzo
.selection_reason
));
1587 SET_FLAG(api
.message
, ZAPI_MESSAGE_OPAQUE
);
1588 api
.opaque
.length
= MIN(sizeof(struct bgp_zebra_opaque
),
1589 ZAPI_MESSAGE_OPAQUE_LENGTH
);
1590 memcpy(api
.opaque
.data
, &bzo
, api
.opaque
.length
);
1593 if (allow_recursion
)
1594 SET_FLAG(api
.flags
, ZEBRA_FLAG_ALLOW_RECURSION
);
1597 * When we create an aggregate route we must also
1598 * install a Null0 route in the RIB, so overwrite
1599 * what was written into api with a blackhole route
1601 if (info
->sub_type
== BGP_ROUTE_AGGREGATE
)
1602 zapi_route_set_blackhole(&api
, BLACKHOLE_NULL
);
1604 api
.nexthop_num
= valid_nh_count
;
1606 SET_FLAG(api
.message
, ZAPI_MESSAGE_METRIC
);
1607 api
.metric
= metric
;
1610 SET_FLAG(api
.message
, ZAPI_MESSAGE_TAG
);
1614 distance
= bgp_distance_apply(p
, info
, afi
, safi
, bgp
);
1616 SET_FLAG(api
.message
, ZAPI_MESSAGE_DISTANCE
);
1617 api
.distance
= distance
;
1620 if (bgp_debug_zebra(p
)) {
1621 char nh_buf
[INET6_ADDRSTRLEN
];
1622 char eth_buf
[ETHER_ADDR_STRLEN
+ 7] = {'\0'};
1623 char buf1
[ETHER_ADDR_STRLEN
];
1630 "Tx route %s VRF %u %pFX metric %u tag %" ROUTE_TAG_PRI
1632 is_add
? "add" : "delete", bgp
->vrf_id
, &api
.prefix
,
1633 api
.metric
, api
.tag
, api
.nexthop_num
, nhg_id
);
1634 for (i
= 0; i
< api
.nexthop_num
; i
++) {
1635 api_nh
= &api
.nexthops
[i
];
1637 switch (api_nh
->type
) {
1638 case NEXTHOP_TYPE_IFINDEX
:
1641 case NEXTHOP_TYPE_IPV4
:
1642 case NEXTHOP_TYPE_IPV4_IFINDEX
:
1643 nh_family
= AF_INET
;
1644 inet_ntop(nh_family
, &api_nh
->gate
, nh_buf
,
1647 case NEXTHOP_TYPE_IPV6
:
1648 case NEXTHOP_TYPE_IPV6_IFINDEX
:
1649 nh_family
= AF_INET6
;
1650 inet_ntop(nh_family
, &api_nh
->gate
, nh_buf
,
1653 case NEXTHOP_TYPE_BLACKHOLE
:
1654 strlcpy(nh_buf
, "blackhole", sizeof(nh_buf
));
1657 /* Note: add new nexthop case */
1662 label_buf
[0] = '\0';
1665 if (CHECK_FLAG(api_nh
->flags
,
1666 ZAPI_NEXTHOP_FLAG_LABEL
) &&
1667 !CHECK_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_EVPN
))
1668 snprintf(label_buf
, sizeof(label_buf
),
1669 "label %u", api_nh
->labels
[0]);
1670 if (CHECK_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_SEG6
) &&
1671 !CHECK_FLAG(api_nh
->flags
,
1672 ZAPI_NEXTHOP_FLAG_EVPN
)) {
1673 inet_ntop(AF_INET6
, &api_nh
->seg6_segs
,
1674 sid_buf
, sizeof(sid_buf
));
1675 snprintf(segs_buf
, sizeof(segs_buf
), "segs %s",
1678 if (CHECK_FLAG(api_nh
->flags
, ZAPI_NEXTHOP_FLAG_EVPN
) &&
1679 !is_zero_mac(&api_nh
->rmac
))
1680 snprintf(eth_buf
, sizeof(eth_buf
), " RMAC %s",
1681 prefix_mac2str(&api_nh
->rmac
,
1682 buf1
, sizeof(buf1
)));
1683 zlog_debug(" nhop [%d]: %s if %u VRF %u wt %u %s %s %s",
1684 i
+ 1, nh_buf
, api_nh
->ifindex
,
1685 api_nh
->vrf_id
, api_nh
->weight
,
1686 label_buf
, segs_buf
, eth_buf
);
1689 int recursion_flag
= 0;
1691 if (CHECK_FLAG(api
.flags
, ZEBRA_FLAG_ALLOW_RECURSION
))
1694 zlog_debug("%s: %pFX: announcing to zebra (recursion %sset)",
1695 __func__
, p
, (recursion_flag
? "" : "NOT "));
1697 zclient_route_send(is_add
? ZEBRA_ROUTE_ADD
: ZEBRA_ROUTE_DELETE
,
1701 /* Announce all routes of a table to zebra */
1702 void bgp_zebra_announce_table(struct bgp
*bgp
, afi_t afi
, safi_t safi
)
1704 struct bgp_dest
*dest
;
1705 struct bgp_table
*table
;
1706 struct bgp_path_info
*pi
;
1708 /* Don't try to install if we're not connected to Zebra or Zebra doesn't
1709 * know of this instance.
1711 if (!bgp_install_info_to_zebra(bgp
))
1714 table
= bgp
->rib
[afi
][safi
];
1718 for (dest
= bgp_table_top(table
); dest
; dest
= bgp_route_next(dest
))
1719 for (pi
= bgp_dest_get_bgp_path_info(dest
); pi
; pi
= pi
->next
)
1720 if (CHECK_FLAG(pi
->flags
, BGP_PATH_SELECTED
) &&
1722 (pi
->type
== ZEBRA_ROUTE_BGP
1723 && (pi
->sub_type
== BGP_ROUTE_NORMAL
1724 || pi
->sub_type
== BGP_ROUTE_IMPORTED
)))
1726 bgp_zebra_announce(dest
,
1727 bgp_dest_get_prefix(dest
),
1728 pi
, bgp
, afi
, safi
);
1731 /* Announce routes of any bgp subtype of a table to zebra */
1732 void bgp_zebra_announce_table_all_subtypes(struct bgp
*bgp
, afi_t afi
,
1735 struct bgp_dest
*dest
;
1736 struct bgp_table
*table
;
1737 struct bgp_path_info
*pi
;
1739 if (!bgp_install_info_to_zebra(bgp
))
1742 table
= bgp
->rib
[afi
][safi
];
1746 for (dest
= bgp_table_top(table
); dest
; dest
= bgp_route_next(dest
))
1747 for (pi
= bgp_dest_get_bgp_path_info(dest
); pi
; pi
= pi
->next
)
1748 if (CHECK_FLAG(pi
->flags
, BGP_PATH_SELECTED
) &&
1749 pi
->type
== ZEBRA_ROUTE_BGP
)
1750 bgp_zebra_announce(dest
,
1751 bgp_dest_get_prefix(dest
),
1752 pi
, bgp
, afi
, safi
);
1755 void bgp_zebra_withdraw(const struct prefix
*p
, struct bgp_path_info
*info
,
1756 struct bgp
*bgp
, safi_t safi
)
1758 struct zapi_route api
;
1761 /* Don't try to install if we're not connected to Zebra or Zebra doesn't
1762 * know of this instance.
1764 if (!bgp_install_info_to_zebra(bgp
))
1767 if (safi
== SAFI_FLOWSPEC
) {
1769 bgp_pbr_update_entry(peer
->bgp
, p
, info
, AFI_IP
, safi
, false);
1773 memset(&api
, 0, sizeof(api
));
1774 api
.vrf_id
= bgp
->vrf_id
;
1775 api
.type
= ZEBRA_ROUTE_BGP
;
1779 if (info
->attr
->rmap_table_id
) {
1780 SET_FLAG(api
.message
, ZAPI_MESSAGE_TABLEID
);
1781 api
.tableid
= info
->attr
->rmap_table_id
;
1784 if (bgp_debug_zebra(p
))
1785 zlog_debug("Tx route delete VRF %u %pFX", bgp
->vrf_id
,
1788 zclient_route_send(ZEBRA_ROUTE_DELETE
, zclient
, &api
);
1791 /* Withdraw all entries in a BGP instances RIB table from Zebra */
1792 void bgp_zebra_withdraw_table_all_subtypes(struct bgp
*bgp
, afi_t afi
, safi_t safi
)
1794 struct bgp_dest
*dest
;
1795 struct bgp_table
*table
;
1796 struct bgp_path_info
*pi
;
1798 if (!bgp_install_info_to_zebra(bgp
))
1801 table
= bgp
->rib
[afi
][safi
];
1805 for (dest
= bgp_table_top(table
); dest
; dest
= bgp_route_next(dest
)) {
1806 for (pi
= bgp_dest_get_bgp_path_info(dest
); pi
; pi
= pi
->next
) {
1807 if (CHECK_FLAG(pi
->flags
, BGP_PATH_SELECTED
)
1808 && (pi
->type
== ZEBRA_ROUTE_BGP
))
1809 bgp_zebra_withdraw(bgp_dest_get_prefix(dest
),
1815 struct bgp_redist
*bgp_redist_lookup(struct bgp
*bgp
, afi_t afi
, uint8_t type
,
1816 unsigned short instance
)
1818 struct list
*red_list
;
1819 struct listnode
*node
;
1820 struct bgp_redist
*red
;
1822 red_list
= bgp
->redist
[afi
][type
];
1826 for (ALL_LIST_ELEMENTS_RO(red_list
, node
, red
))
1827 if (red
->instance
== instance
)
1833 struct bgp_redist
*bgp_redist_add(struct bgp
*bgp
, afi_t afi
, uint8_t type
,
1834 unsigned short instance
)
1836 struct list
*red_list
;
1837 struct bgp_redist
*red
;
1839 red
= bgp_redist_lookup(bgp
, afi
, type
, instance
);
1843 if (!bgp
->redist
[afi
][type
])
1844 bgp
->redist
[afi
][type
] = list_new();
1846 red_list
= bgp
->redist
[afi
][type
];
1847 red
= XCALLOC(MTYPE_BGP_REDIST
, sizeof(struct bgp_redist
));
1848 red
->instance
= instance
;
1850 listnode_add(red_list
, red
);
1855 static void bgp_redist_del(struct bgp
*bgp
, afi_t afi
, uint8_t type
,
1856 unsigned short instance
)
1858 struct bgp_redist
*red
;
1860 red
= bgp_redist_lookup(bgp
, afi
, type
, instance
);
1863 listnode_delete(bgp
->redist
[afi
][type
], red
);
1864 XFREE(MTYPE_BGP_REDIST
, red
);
1865 if (!bgp
->redist
[afi
][type
]->count
)
1866 list_delete(&bgp
->redist
[afi
][type
]);
1870 /* Other routes redistribution into BGP. */
1871 int bgp_redistribute_set(struct bgp
*bgp
, afi_t afi
, int type
,
1872 unsigned short instance
, bool changed
)
1874 /* If redistribute options are changed call
1875 * bgp_redistribute_unreg() to reset the option and withdraw
1879 bgp_redistribute_unreg(bgp
, afi
, type
, instance
);
1881 /* Return if already redistribute flag is set. */
1883 if (redist_check_instance(&zclient
->mi_redist
[afi
][type
],
1887 redist_add_instance(&zclient
->mi_redist
[afi
][type
], instance
);
1889 if (vrf_bitmap_check(zclient
->redist
[afi
][type
], bgp
->vrf_id
))
1892 #ifdef ENABLE_BGP_VNC
1893 if (EVPN_ENABLED(bgp
) && type
== ZEBRA_ROUTE_VNC_DIRECT
) {
1894 vnc_export_bgp_enable(
1895 bgp
, afi
); /* only enables if mode bits cfg'd */
1899 vrf_bitmap_set(zclient
->redist
[afi
][type
], bgp
->vrf_id
);
1903 * Don't try to register if we're not connected to Zebra or Zebra
1904 * doesn't know of this instance.
1906 * When we come up later well resend if needed.
1908 if (!bgp_install_info_to_zebra(bgp
))
1911 if (BGP_DEBUG(zebra
, ZEBRA
))
1912 zlog_debug("Tx redistribute add VRF %u afi %d %s %d",
1913 bgp
->vrf_id
, afi
, zebra_route_string(type
),
1916 /* Send distribute add message to zebra. */
1917 zebra_redistribute_send(ZEBRA_REDISTRIBUTE_ADD
, zclient
, afi
, type
,
1918 instance
, bgp
->vrf_id
);
1923 int bgp_redistribute_resend(struct bgp
*bgp
, afi_t afi
, int type
,
1924 unsigned short instance
)
1926 /* Don't try to send if we're not connected to Zebra or Zebra doesn't
1927 * know of this instance.
1929 if (!bgp_install_info_to_zebra(bgp
))
1932 if (BGP_DEBUG(zebra
, ZEBRA
))
1933 zlog_debug("Tx redistribute del/add VRF %u afi %d %s %d",
1934 bgp
->vrf_id
, afi
, zebra_route_string(type
),
1937 /* Send distribute add message to zebra. */
1938 zebra_redistribute_send(ZEBRA_REDISTRIBUTE_DELETE
, zclient
, afi
, type
,
1939 instance
, bgp
->vrf_id
);
1940 zebra_redistribute_send(ZEBRA_REDISTRIBUTE_ADD
, zclient
, afi
, type
,
1941 instance
, bgp
->vrf_id
);
1946 /* Redistribute with route-map specification. */
1947 bool bgp_redistribute_rmap_set(struct bgp_redist
*red
, const char *name
,
1948 struct route_map
*route_map
)
1950 if (red
->rmap
.name
&& (strcmp(red
->rmap
.name
, name
) == 0))
1953 XFREE(MTYPE_ROUTE_MAP_NAME
, red
->rmap
.name
);
1954 /* Decrement the count for existing routemap and
1955 * increment the count for new route map.
1957 route_map_counter_decrement(red
->rmap
.map
);
1958 red
->rmap
.name
= XSTRDUP(MTYPE_ROUTE_MAP_NAME
, name
);
1959 red
->rmap
.map
= route_map
;
1960 route_map_counter_increment(red
->rmap
.map
);
1965 /* Redistribute with metric specification. */
1966 bool bgp_redistribute_metric_set(struct bgp
*bgp
, struct bgp_redist
*red
,
1967 afi_t afi
, int type
, uint32_t metric
)
1969 struct bgp_dest
*dest
;
1970 struct bgp_path_info
*pi
;
1972 if (red
->redist_metric_flag
&& red
->redist_metric
== metric
)
1975 red
->redist_metric_flag
= 1;
1976 red
->redist_metric
= metric
;
1978 for (dest
= bgp_table_top(bgp
->rib
[afi
][SAFI_UNICAST
]); dest
;
1979 dest
= bgp_route_next(dest
)) {
1980 for (pi
= bgp_dest_get_bgp_path_info(dest
); pi
; pi
= pi
->next
) {
1981 if (pi
->sub_type
== BGP_ROUTE_REDISTRIBUTE
1983 && pi
->instance
== red
->instance
) {
1984 struct attr
*old_attr
;
1985 struct attr new_attr
;
1987 new_attr
= *pi
->attr
;
1988 new_attr
.med
= red
->redist_metric
;
1989 old_attr
= pi
->attr
;
1990 pi
->attr
= bgp_attr_intern(&new_attr
);
1991 bgp_attr_unintern(&old_attr
);
1993 bgp_path_info_set_flag(dest
, pi
,
1994 BGP_PATH_ATTR_CHANGED
);
1995 bgp_process(bgp
, dest
, afi
, SAFI_UNICAST
);
2003 /* Unset redistribution. */
2004 int bgp_redistribute_unreg(struct bgp
*bgp
, afi_t afi
, int type
,
2005 unsigned short instance
)
2007 struct bgp_redist
*red
;
2009 red
= bgp_redist_lookup(bgp
, afi
, type
, instance
);
2013 /* Return if zebra connection is disabled. */
2015 if (!redist_check_instance(&zclient
->mi_redist
[afi
][type
],
2018 redist_del_instance(&zclient
->mi_redist
[afi
][type
], instance
);
2020 if (!vrf_bitmap_check(zclient
->redist
[afi
][type
], bgp
->vrf_id
))
2022 vrf_bitmap_unset(zclient
->redist
[afi
][type
], bgp
->vrf_id
);
2025 if (bgp_install_info_to_zebra(bgp
)) {
2026 /* Send distribute delete message to zebra. */
2027 if (BGP_DEBUG(zebra
, ZEBRA
))
2028 zlog_debug("Tx redistribute del VRF %u afi %d %s %d",
2029 bgp
->vrf_id
, afi
, zebra_route_string(type
),
2031 zebra_redistribute_send(ZEBRA_REDISTRIBUTE_DELETE
, zclient
, afi
,
2032 type
, instance
, bgp
->vrf_id
);
2035 /* Withdraw redistributed routes from current BGP's routing table. */
2036 bgp_redistribute_withdraw(bgp
, afi
, type
, instance
);
2041 /* Unset redistribution. */
2042 int bgp_redistribute_unset(struct bgp
*bgp
, afi_t afi
, int type
,
2043 unsigned short instance
)
2045 struct bgp_redist
*red
;
2048 * vnc and vpn->vrf checks must be before red check because
2049 * they operate within bgpd irrespective of zebra connection
2050 * status. red lookup fails if there is no zebra connection.
2052 #ifdef ENABLE_BGP_VNC
2053 if (EVPN_ENABLED(bgp
) && type
== ZEBRA_ROUTE_VNC_DIRECT
) {
2054 vnc_export_bgp_disable(bgp
, afi
);
2058 red
= bgp_redist_lookup(bgp
, afi
, type
, instance
);
2062 bgp_redistribute_unreg(bgp
, afi
, type
, instance
);
2064 /* Unset route-map. */
2065 XFREE(MTYPE_ROUTE_MAP_NAME
, red
->rmap
.name
);
2066 route_map_counter_decrement(red
->rmap
.map
);
2067 red
->rmap
.map
= NULL
;
2070 red
->redist_metric_flag
= 0;
2071 red
->redist_metric
= 0;
2073 bgp_redist_del(bgp
, afi
, type
, instance
);
2078 void bgp_redistribute_redo(struct bgp
*bgp
)
2082 struct list
*red_list
;
2083 struct listnode
*node
;
2084 struct bgp_redist
*red
;
2086 for (afi
= AFI_IP
; afi
< AFI_MAX
; afi
++) {
2087 for (i
= 0; i
< ZEBRA_ROUTE_MAX
; i
++) {
2089 red_list
= bgp
->redist
[afi
][i
];
2093 for (ALL_LIST_ELEMENTS_RO(red_list
, node
, red
)) {
2094 bgp_redistribute_resend(bgp
, afi
, i
,
2101 void bgp_zclient_reset(void)
2103 zclient_reset(zclient
);
2106 /* Register this instance with Zebra. Invoked upon connect (for
2107 * default instance) and when other VRFs are learnt (or created and
2110 void bgp_zebra_instance_register(struct bgp
*bgp
)
2112 /* Don't try to register if we're not connected to Zebra */
2113 if (!zclient
|| zclient
->sock
< 0)
2116 if (BGP_DEBUG(zebra
, ZEBRA
))
2117 zlog_debug("Registering VRF %u", bgp
->vrf_id
);
2119 /* Register for router-id, interfaces, redistributed routes. */
2120 zclient_send_reg_requests(zclient
, bgp
->vrf_id
);
2122 /* For EVPN instance, register to learn about VNIs, if appropriate. */
2123 if (bgp
->advertise_all_vni
)
2124 bgp_zebra_advertise_all_vni(bgp
, 1);
2126 bgp_nht_register_nexthops(bgp
);
2129 /* Deregister this instance with Zebra. Invoked upon the instance
2130 * being deleted (default or VRF) and it is already registered.
2132 void bgp_zebra_instance_deregister(struct bgp
*bgp
)
2134 /* Don't try to deregister if we're not connected to Zebra */
2135 if (zclient
->sock
< 0)
2138 if (BGP_DEBUG(zebra
, ZEBRA
))
2139 zlog_debug("Deregistering VRF %u", bgp
->vrf_id
);
2141 /* For EVPN instance, unregister learning about VNIs, if appropriate. */
2142 if (bgp
->advertise_all_vni
)
2143 bgp_zebra_advertise_all_vni(bgp
, 0);
2145 /* Deregister for router-id, interfaces, redistributed routes. */
2146 zclient_send_dereg_requests(zclient
, bgp
->vrf_id
);
2149 void bgp_zebra_initiate_radv(struct bgp
*bgp
, struct peer
*peer
)
2151 uint32_t ra_interval
= BGP_UNNUM_DEFAULT_RA_INTERVAL
;
2153 /* Don't try to initiate if we're not connected to Zebra */
2154 if (zclient
->sock
< 0)
2157 if (BGP_DEBUG(zebra
, ZEBRA
))
2158 zlog_debug("%u: Initiating RA for peer %s", bgp
->vrf_id
,
2162 * If unnumbered peer (peer->ifp) call thru zapi to start RAs.
2163 * If we don't have an ifp pointer, call function to find the
2164 * ifps for a numbered enhe peer to turn RAs on.
2166 peer
->ifp
? zclient_send_interface_radv_req(zclient
, bgp
->vrf_id
,
2167 peer
->ifp
, 1, ra_interval
)
2168 : bgp_nht_reg_enhe_cap_intfs(peer
);
2171 void bgp_zebra_terminate_radv(struct bgp
*bgp
, struct peer
*peer
)
2173 /* Don't try to terminate if we're not connected to Zebra */
2174 if (zclient
->sock
< 0)
2177 if (BGP_DEBUG(zebra
, ZEBRA
))
2178 zlog_debug("%u: Terminating RA for peer %s", bgp
->vrf_id
,
2182 * If unnumbered peer (peer->ifp) call thru zapi to stop RAs.
2183 * If we don't have an ifp pointer, call function to find the
2184 * ifps for a numbered enhe peer to turn RAs off.
2186 peer
->ifp
? zclient_send_interface_radv_req(zclient
, bgp
->vrf_id
,
2188 : bgp_nht_dereg_enhe_cap_intfs(peer
);
2191 int bgp_zebra_advertise_subnet(struct bgp
*bgp
, int advertise
, vni_t vni
)
2193 struct stream
*s
= NULL
;
2196 if (!zclient
|| zclient
->sock
< 0)
2199 /* Don't try to register if Zebra doesn't know of this instance. */
2200 if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp
)) {
2201 if (BGP_DEBUG(zebra
, ZEBRA
))
2203 "%s: No zebra instance to talk to, cannot advertise subnet",
2211 zclient_create_header(s
, ZEBRA_ADVERTISE_SUBNET
, bgp
->vrf_id
);
2212 stream_putc(s
, advertise
);
2213 stream_put3(s
, vni
);
2214 stream_putw_at(s
, 0, stream_get_endp(s
));
2216 return zclient_send_message(zclient
);
2219 int bgp_zebra_advertise_svi_macip(struct bgp
*bgp
, int advertise
, vni_t vni
)
2221 struct stream
*s
= NULL
;
2224 if (!zclient
|| zclient
->sock
< 0)
2227 /* Don't try to register if Zebra doesn't know of this instance. */
2228 if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp
))
2234 zclient_create_header(s
, ZEBRA_ADVERTISE_SVI_MACIP
, bgp
->vrf_id
);
2235 stream_putc(s
, advertise
);
2236 stream_putl(s
, vni
);
2237 stream_putw_at(s
, 0, stream_get_endp(s
));
2239 return zclient_send_message(zclient
);
2242 int bgp_zebra_advertise_gw_macip(struct bgp
*bgp
, int advertise
, vni_t vni
)
2244 struct stream
*s
= NULL
;
2247 if (!zclient
|| zclient
->sock
< 0)
2250 /* Don't try to register if Zebra doesn't know of this instance. */
2251 if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp
)) {
2252 if (BGP_DEBUG(zebra
, ZEBRA
))
2254 "%s: No zebra instance to talk to, not installing gw_macip",
2262 zclient_create_header(s
, ZEBRA_ADVERTISE_DEFAULT_GW
, bgp
->vrf_id
);
2263 stream_putc(s
, advertise
);
2264 stream_putl(s
, vni
);
2265 stream_putw_at(s
, 0, stream_get_endp(s
));
2267 return zclient_send_message(zclient
);
2270 int bgp_zebra_vxlan_flood_control(struct bgp
*bgp
,
2271 enum vxlan_flood_control flood_ctrl
)
2276 if (!zclient
|| zclient
->sock
< 0)
2279 /* Don't try to register if Zebra doesn't know of this instance. */
2280 if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp
)) {
2281 if (BGP_DEBUG(zebra
, ZEBRA
))
2283 "%s: No zebra instance to talk to, not installing all vni",
2291 zclient_create_header(s
, ZEBRA_VXLAN_FLOOD_CONTROL
, bgp
->vrf_id
);
2292 stream_putc(s
, flood_ctrl
);
2293 stream_putw_at(s
, 0, stream_get_endp(s
));
2295 return zclient_send_message(zclient
);
2298 int bgp_zebra_advertise_all_vni(struct bgp
*bgp
, int advertise
)
2303 if (!zclient
|| zclient
->sock
< 0)
2306 /* Don't try to register if Zebra doesn't know of this instance. */
2307 if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp
))
2313 zclient_create_header(s
, ZEBRA_ADVERTISE_ALL_VNI
, bgp
->vrf_id
);
2314 stream_putc(s
, advertise
);
2315 /* Also inform current BUM handling setting. This is really
2316 * relevant only when 'advertise' is set.
2318 stream_putc(s
, bgp
->vxlan_flood_ctrl
);
2319 stream_putw_at(s
, 0, stream_get_endp(s
));
2321 return zclient_send_message(zclient
);
2324 int bgp_zebra_dup_addr_detection(struct bgp
*bgp
)
2329 if (!zclient
|| zclient
->sock
< 0)
2332 /* Don't try to register if Zebra doesn't know of this instance. */
2333 if (!IS_BGP_INST_KNOWN_TO_ZEBRA(bgp
))
2336 if (BGP_DEBUG(zebra
, ZEBRA
))
2337 zlog_debug("dup addr detect %s max_moves %u time %u freeze %s freeze_time %u",
2338 bgp
->evpn_info
->dup_addr_detect
?
2339 "enable" : "disable",
2340 bgp
->evpn_info
->dad_max_moves
,
2341 bgp
->evpn_info
->dad_time
,
2342 bgp
->evpn_info
->dad_freeze
?
2343 "enable" : "disable",
2344 bgp
->evpn_info
->dad_freeze_time
);
2348 zclient_create_header(s
, ZEBRA_DUPLICATE_ADDR_DETECTION
,
2350 stream_putl(s
, bgp
->evpn_info
->dup_addr_detect
);
2351 stream_putl(s
, bgp
->evpn_info
->dad_time
);
2352 stream_putl(s
, bgp
->evpn_info
->dad_max_moves
);
2353 stream_putl(s
, bgp
->evpn_info
->dad_freeze
);
2354 stream_putl(s
, bgp
->evpn_info
->dad_freeze_time
);
2355 stream_putw_at(s
, 0, stream_get_endp(s
));
2357 return zclient_send_message(zclient
);
2360 static int rule_notify_owner(ZAPI_CALLBACK_ARGS
)
2362 uint32_t seqno
, priority
, unique
;
2363 enum zapi_rule_notify_owner note
;
2364 struct bgp_pbr_action
*bgp_pbra
;
2365 struct bgp_pbr_rule
*bgp_pbr
= NULL
;
2366 char ifname
[INTERFACE_NAMSIZ
+ 1];
2368 if (!zapi_rule_notify_decode(zclient
->ibuf
, &seqno
, &priority
, &unique
,
2372 bgp_pbra
= bgp_pbr_action_rule_lookup(vrf_id
, unique
);
2374 /* look in bgp pbr rule */
2375 bgp_pbr
= bgp_pbr_rule_lookup(vrf_id
, unique
);
2376 if (!bgp_pbr
&& note
!= ZAPI_RULE_REMOVED
) {
2377 if (BGP_DEBUG(zebra
, ZEBRA
))
2378 zlog_debug("%s: Fail to look BGP rule (%u)",
2385 case ZAPI_RULE_FAIL_INSTALL
:
2386 if (BGP_DEBUG(zebra
, ZEBRA
))
2387 zlog_debug("%s: Received RULE_FAIL_INSTALL", __func__
);
2389 bgp_pbra
->installed
= false;
2390 bgp_pbra
->install_in_progress
= false;
2392 bgp_pbr
->installed
= false;
2393 bgp_pbr
->install_in_progress
= false;
2396 case ZAPI_RULE_INSTALLED
:
2398 bgp_pbra
->installed
= true;
2399 bgp_pbra
->install_in_progress
= false;
2401 struct bgp_path_info
*path
;
2402 struct bgp_path_info_extra
*extra
;
2404 bgp_pbr
->installed
= true;
2405 bgp_pbr
->install_in_progress
= false;
2406 bgp_pbr
->action
->refcnt
++;
2407 /* link bgp_info to bgp_pbr */
2408 path
= (struct bgp_path_info
*)bgp_pbr
->path
;
2409 extra
= bgp_path_info_extra_get(path
);
2410 listnode_add_force(&extra
->bgp_fs_iprule
,
2413 if (BGP_DEBUG(zebra
, ZEBRA
))
2414 zlog_debug("%s: Received RULE_INSTALLED", __func__
);
2416 case ZAPI_RULE_FAIL_REMOVE
:
2417 case ZAPI_RULE_REMOVED
:
2418 if (BGP_DEBUG(zebra
, ZEBRA
))
2419 zlog_debug("%s: Received RULE REMOVED", __func__
);
2426 static int ipset_notify_owner(ZAPI_CALLBACK_ARGS
)
2429 enum zapi_ipset_notify_owner note
;
2430 struct bgp_pbr_match
*bgp_pbim
;
2432 if (!zapi_ipset_notify_decode(zclient
->ibuf
,
2437 bgp_pbim
= bgp_pbr_match_ipset_lookup(vrf_id
, unique
);
2439 if (BGP_DEBUG(zebra
, ZEBRA
))
2440 zlog_debug("%s: Fail to look BGP match ( %u, ID %u)",
2441 __func__
, note
, unique
);
2446 case ZAPI_IPSET_FAIL_INSTALL
:
2447 if (BGP_DEBUG(zebra
, ZEBRA
))
2448 zlog_debug("%s: Received IPSET_FAIL_INSTALL", __func__
);
2449 bgp_pbim
->installed
= false;
2450 bgp_pbim
->install_in_progress
= false;
2452 case ZAPI_IPSET_INSTALLED
:
2453 bgp_pbim
->installed
= true;
2454 bgp_pbim
->install_in_progress
= false;
2455 if (BGP_DEBUG(zebra
, ZEBRA
))
2456 zlog_debug("%s: Received IPSET_INSTALLED", __func__
);
2458 case ZAPI_IPSET_FAIL_REMOVE
:
2459 case ZAPI_IPSET_REMOVED
:
2460 if (BGP_DEBUG(zebra
, ZEBRA
))
2461 zlog_debug("%s: Received IPSET REMOVED", __func__
);
2468 static int ipset_entry_notify_owner(ZAPI_CALLBACK_ARGS
)
2471 char ipset_name
[ZEBRA_IPSET_NAME_SIZE
];
2472 enum zapi_ipset_entry_notify_owner note
;
2473 struct bgp_pbr_match_entry
*bgp_pbime
;
2475 if (!zapi_ipset_entry_notify_decode(
2481 bgp_pbime
= bgp_pbr_match_ipset_entry_lookup(vrf_id
,
2485 if (BGP_DEBUG(zebra
, ZEBRA
))
2487 "%s: Fail to look BGP match entry (%u, ID %u)",
2488 __func__
, note
, unique
);
2493 case ZAPI_IPSET_ENTRY_FAIL_INSTALL
:
2494 if (BGP_DEBUG(zebra
, ZEBRA
))
2495 zlog_debug("%s: Received IPSET_ENTRY_FAIL_INSTALL",
2497 bgp_pbime
->installed
= false;
2498 bgp_pbime
->install_in_progress
= false;
2500 case ZAPI_IPSET_ENTRY_INSTALLED
:
2502 struct bgp_path_info
*path
;
2503 struct bgp_path_info_extra
*extra
;
2505 bgp_pbime
->installed
= true;
2506 bgp_pbime
->install_in_progress
= false;
2507 if (BGP_DEBUG(zebra
, ZEBRA
))
2508 zlog_debug("%s: Received IPSET_ENTRY_INSTALLED",
2510 /* link bgp_path_info to bpme */
2511 path
= (struct bgp_path_info
*)bgp_pbime
->path
;
2512 extra
= bgp_path_info_extra_get(path
);
2513 listnode_add_force(&extra
->bgp_fs_pbr
, bgp_pbime
);
2516 case ZAPI_IPSET_ENTRY_FAIL_REMOVE
:
2517 case ZAPI_IPSET_ENTRY_REMOVED
:
2518 if (BGP_DEBUG(zebra
, ZEBRA
))
2519 zlog_debug("%s: Received IPSET_ENTRY_REMOVED",
2526 static int iptable_notify_owner(ZAPI_CALLBACK_ARGS
)
2529 enum zapi_iptable_notify_owner note
;
2530 struct bgp_pbr_match
*bgpm
;
2532 if (!zapi_iptable_notify_decode(
2537 bgpm
= bgp_pbr_match_iptable_lookup(vrf_id
, unique
);
2539 if (BGP_DEBUG(zebra
, ZEBRA
))
2540 zlog_debug("%s: Fail to look BGP iptable (%u %u)",
2541 __func__
, note
, unique
);
2545 case ZAPI_IPTABLE_FAIL_INSTALL
:
2546 if (BGP_DEBUG(zebra
, ZEBRA
))
2547 zlog_debug("%s: Received IPTABLE_FAIL_INSTALL",
2549 bgpm
->installed_in_iptable
= false;
2550 bgpm
->install_iptable_in_progress
= false;
2552 case ZAPI_IPTABLE_INSTALLED
:
2553 bgpm
->installed_in_iptable
= true;
2554 bgpm
->install_iptable_in_progress
= false;
2555 if (BGP_DEBUG(zebra
, ZEBRA
))
2556 zlog_debug("%s: Received IPTABLE_INSTALLED", __func__
);
2557 bgpm
->action
->refcnt
++;
2559 case ZAPI_IPTABLE_FAIL_REMOVE
:
2560 case ZAPI_IPTABLE_REMOVED
:
2561 if (BGP_DEBUG(zebra
, ZEBRA
))
2562 zlog_debug("%s: Received IPTABLE REMOVED", __func__
);
2568 /* Process route notification messages from RIB */
2569 static int bgp_zebra_route_notify_owner(int command
, struct zclient
*zclient
,
2570 zebra_size_t length
, vrf_id_t vrf_id
)
2573 enum zapi_route_notify_owner note
;
2577 struct bgp_dest
*dest
;
2579 struct bgp_path_info
*pi
, *new_select
;
2581 if (!zapi_route_notify_decode(zclient
->ibuf
, &p
, &table_id
, ¬e
,
2583 zlog_err("%s : error in msg decode", __func__
);
2587 /* Get the bgp instance */
2588 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
2590 flog_err(EC_BGP_INVALID_BGP_INSTANCE
,
2591 "%s : bgp instance not found vrf %d", __func__
,
2596 /* Find the bgp route node */
2597 dest
= bgp_afi_node_lookup(bgp
->rib
[afi
][safi
], afi
, safi
, &p
,
2603 case ZAPI_ROUTE_INSTALLED
:
2605 /* Clear the flags so that route can be processed */
2606 UNSET_FLAG(dest
->flags
, BGP_NODE_FIB_INSTALL_PENDING
);
2607 SET_FLAG(dest
->flags
, BGP_NODE_FIB_INSTALLED
);
2608 if (BGP_DEBUG(zebra
, ZEBRA
))
2609 zlog_debug("route %pRN : INSTALLED", dest
);
2610 /* Find the best route */
2611 for (pi
= dest
->info
; pi
; pi
= pi
->next
) {
2612 /* Process aggregate route */
2613 bgp_aggregate_increment(bgp
, &p
, pi
, afi
, safi
);
2614 if (CHECK_FLAG(pi
->flags
, BGP_PATH_SELECTED
))
2617 /* Advertise the route */
2619 group_announce_route(bgp
, afi
, safi
, dest
, new_select
);
2621 flog_err(EC_BGP_INVALID_ROUTE
,
2622 "selected route %pRN not found", dest
);
2624 bgp_dest_unlock_node(dest
);
2628 case ZAPI_ROUTE_REMOVED
:
2629 /* Route deleted from dataplane, reset the installed flag
2630 * so that route can be reinstalled when client sends
2633 UNSET_FLAG(dest
->flags
, BGP_NODE_FIB_INSTALLED
);
2634 if (BGP_DEBUG(zebra
, ZEBRA
))
2635 zlog_debug("route %pRN: Removed from Fib", dest
);
2637 case ZAPI_ROUTE_FAIL_INSTALL
:
2639 if (BGP_DEBUG(zebra
, ZEBRA
))
2640 zlog_debug("route: %pRN Failed to Install into Fib",
2642 UNSET_FLAG(dest
->flags
, BGP_NODE_FIB_INSTALL_PENDING
);
2643 UNSET_FLAG(dest
->flags
, BGP_NODE_FIB_INSTALLED
);
2644 for (pi
= bgp_dest_get_bgp_path_info(dest
); pi
; pi
= pi
->next
) {
2645 if (CHECK_FLAG(pi
->flags
, BGP_PATH_SELECTED
))
2649 group_announce_route(bgp
, afi
, safi
, dest
, new_select
);
2650 /* Error will be logged by zebra module */
2652 case ZAPI_ROUTE_BETTER_ADMIN_WON
:
2653 if (BGP_DEBUG(zebra
, ZEBRA
))
2654 zlog_debug("route: %pRN removed due to better admin won",
2657 UNSET_FLAG(dest
->flags
, BGP_NODE_FIB_INSTALL_PENDING
);
2658 UNSET_FLAG(dest
->flags
, BGP_NODE_FIB_INSTALLED
);
2659 for (pi
= bgp_dest_get_bgp_path_info(dest
); pi
; pi
= pi
->next
) {
2660 bgp_aggregate_decrement(bgp
, &p
, pi
, afi
, safi
);
2661 if (CHECK_FLAG(pi
->flags
, BGP_PATH_SELECTED
))
2665 group_announce_route(bgp
, afi
, safi
, dest
, new_select
);
2666 /* No action required */
2668 case ZAPI_ROUTE_REMOVE_FAIL
:
2669 zlog_warn("%s: Route %pRN failure to remove",
2674 bgp_dest_unlock_node(dest
);
2678 /* this function is used to forge ip rule,
2679 * - either for iptable/ipset using fwmark id
2680 * - or for sample ip rule cmd
2682 static void bgp_encode_pbr_rule_action(struct stream
*s
,
2683 struct bgp_pbr_action
*pbra
,
2684 struct bgp_pbr_rule
*pbr
)
2687 uint8_t fam
= AF_INET
;
2688 char ifname
[INTERFACE_NAMSIZ
];
2690 if (pbra
->nh
.type
== NEXTHOP_TYPE_IPV6
)
2692 stream_putl(s
, 0); /* seqno unused */
2694 stream_putl(s
, pbr
->priority
);
2697 /* ruleno unused - priority change
2698 * ruleno permits distinguishing various FS PBR entries
2699 * - FS PBR entries based on ipset/iptables
2700 * - FS PBR entries based on iprule
2701 * the latter may contain default routing information injected by FS
2704 stream_putl(s
, pbr
->unique
);
2706 stream_putl(s
, pbra
->unique
);
2707 stream_putc(s
, 0); /* ip protocol being used */
2708 if (pbr
&& pbr
->flags
& MATCH_IP_SRC_SET
)
2709 memcpy(&pfx
, &(pbr
->src
), sizeof(struct prefix
));
2711 memset(&pfx
, 0, sizeof(pfx
));
2714 stream_putc(s
, pfx
.family
);
2715 stream_putc(s
, pfx
.prefixlen
);
2716 stream_put(s
, &pfx
.u
.prefix
, prefix_blen(&pfx
));
2718 stream_putw(s
, 0); /* src port */
2720 if (pbr
&& pbr
->flags
& MATCH_IP_DST_SET
)
2721 memcpy(&pfx
, &(pbr
->dst
), sizeof(struct prefix
));
2723 memset(&pfx
, 0, sizeof(pfx
));
2726 stream_putc(s
, pfx
.family
);
2727 stream_putc(s
, pfx
.prefixlen
);
2728 stream_put(s
, &pfx
.u
.prefix
, prefix_blen(&pfx
));
2730 stream_putw(s
, 0); /* dst port */
2731 stream_putc(s
, 0); /* dsfield */
2732 /* if pbr present, fwmark is not used */
2736 stream_putl(s
, pbra
->fwmark
); /* fwmark */
2738 stream_putl(s
, 0); /* queue id */
2739 stream_putw(s
, 0); /* vlan_id */
2740 stream_putw(s
, 0); /* vlan_flags */
2741 stream_putw(s
, 0); /* pcp */
2743 stream_putl(s
, pbra
->table_id
);
2745 memset(ifname
, 0, sizeof(ifname
));
2746 stream_put(s
, ifname
, INTERFACE_NAMSIZ
); /* ifname unused */
2749 static void bgp_encode_pbr_ipset_match(struct stream
*s
,
2750 struct bgp_pbr_match
*pbim
)
2752 stream_putl(s
, pbim
->unique
);
2753 stream_putl(s
, pbim
->type
);
2754 stream_putc(s
, pbim
->family
);
2755 stream_put(s
, pbim
->ipset_name
,
2756 ZEBRA_IPSET_NAME_SIZE
);
2759 static void bgp_encode_pbr_ipset_entry_match(struct stream
*s
,
2760 struct bgp_pbr_match_entry
*pbime
)
2762 stream_putl(s
, pbime
->unique
);
2763 /* check that back pointer is not null */
2764 stream_put(s
, pbime
->backpointer
->ipset_name
,
2765 ZEBRA_IPSET_NAME_SIZE
);
2767 stream_putc(s
, pbime
->src
.family
);
2768 stream_putc(s
, pbime
->src
.prefixlen
);
2769 stream_put(s
, &pbime
->src
.u
.prefix
, prefix_blen(&pbime
->src
));
2771 stream_putc(s
, pbime
->dst
.family
);
2772 stream_putc(s
, pbime
->dst
.prefixlen
);
2773 stream_put(s
, &pbime
->dst
.u
.prefix
, prefix_blen(&pbime
->dst
));
2775 stream_putw(s
, pbime
->src_port_min
);
2776 stream_putw(s
, pbime
->src_port_max
);
2777 stream_putw(s
, pbime
->dst_port_min
);
2778 stream_putw(s
, pbime
->dst_port_max
);
2779 stream_putc(s
, pbime
->proto
);
2782 static void bgp_encode_pbr_iptable_match(struct stream
*s
,
2783 struct bgp_pbr_action
*bpa
,
2784 struct bgp_pbr_match
*pbm
)
2786 stream_putl(s
, pbm
->unique2
);
2788 stream_putl(s
, pbm
->type
);
2790 stream_putl(s
, pbm
->flags
);
2792 /* TODO: correlate with what is contained
2793 * into bgp_pbr_action.
2794 * currently only forward supported
2796 if (bpa
->nh
.type
== NEXTHOP_TYPE_BLACKHOLE
)
2797 stream_putl(s
, ZEBRA_IPTABLES_DROP
);
2799 stream_putl(s
, ZEBRA_IPTABLES_FORWARD
);
2800 stream_putl(s
, bpa
->fwmark
);
2801 stream_put(s
, pbm
->ipset_name
,
2802 ZEBRA_IPSET_NAME_SIZE
);
2803 stream_putc(s
, pbm
->family
);
2804 stream_putw(s
, pbm
->pkt_len_min
);
2805 stream_putw(s
, pbm
->pkt_len_max
);
2806 stream_putw(s
, pbm
->tcp_flags
);
2807 stream_putw(s
, pbm
->tcp_mask_flags
);
2808 stream_putc(s
, pbm
->dscp_value
);
2809 stream_putc(s
, pbm
->fragment
);
2810 stream_putc(s
, pbm
->protocol
);
2811 stream_putw(s
, pbm
->flow_label
);
2814 /* BGP has established connection with Zebra. */
2815 static void bgp_zebra_connected(struct zclient
*zclient
)
2819 zclient_num_connects
++; /* increment even if not responding */
2821 /* Send the client registration */
2822 bfd_client_sendmsg(zclient
, ZEBRA_BFD_CLIENT_REGISTER
, VRF_DEFAULT
);
2824 /* At this point, we may or may not have BGP instances configured, but
2825 * we're only interested in the default VRF (others wouldn't have learnt
2826 * the VRF from Zebra yet.)
2828 bgp
= bgp_get_default();
2832 bgp_zebra_instance_register(bgp
);
2834 /* tell label pool that zebra is connected */
2835 bgp_lp_event_zebra_up();
2837 /* TODO - What if we have peers and networks configured, do we have to
2840 BGP_GR_ROUTER_DETECT_AND_SEND_CAPABILITY_TO_ZEBRA(bgp
, bgp
->peer
);
2843 static int bgp_zebra_process_local_es_add(ZAPI_CALLBACK_ARGS
)
2846 struct bgp
*bgp
= NULL
;
2847 struct stream
*s
= NULL
;
2848 char buf
[ESI_STR_LEN
];
2849 struct in_addr originator_ip
;
2854 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
2859 stream_get(&esi
, s
, sizeof(esi_t
));
2860 originator_ip
.s_addr
= stream_get_ipv4(s
);
2861 active
= stream_getc(s
);
2862 df_pref
= stream_getw(s
);
2863 bypass
= stream_getc(s
);
2865 if (BGP_DEBUG(zebra
, ZEBRA
))
2867 "Rx add ESI %s originator-ip %pI4 active %u df_pref %u %s",
2868 esi_to_str(&esi
, buf
, sizeof(buf
)), &originator_ip
,
2869 active
, df_pref
, bypass
? "bypass" : "");
2871 frrtrace(5, frr_bgp
, evpn_mh_local_es_add_zrecv
, &esi
, originator_ip
,
2872 active
, bypass
, df_pref
);
2874 bgp_evpn_local_es_add(bgp
, &esi
, originator_ip
, active
, df_pref
,
2880 static int bgp_zebra_process_local_es_del(ZAPI_CALLBACK_ARGS
)
2883 struct bgp
*bgp
= NULL
;
2884 struct stream
*s
= NULL
;
2885 char buf
[ESI_STR_LEN
];
2887 memset(&esi
, 0, sizeof(esi_t
));
2888 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
2893 stream_get(&esi
, s
, sizeof(esi_t
));
2895 if (BGP_DEBUG(zebra
, ZEBRA
))
2896 zlog_debug("Rx del ESI %s",
2897 esi_to_str(&esi
, buf
, sizeof(buf
)));
2899 frrtrace(1, frr_bgp
, evpn_mh_local_es_del_zrecv
, &esi
);
2901 bgp_evpn_local_es_del(bgp
, &esi
);
2906 static int bgp_zebra_process_local_es_evi(ZAPI_CALLBACK_ARGS
)
2912 char buf
[ESI_STR_LEN
];
2914 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
2919 stream_get(&esi
, s
, sizeof(esi_t
));
2920 vni
= stream_getl(s
);
2922 if (BGP_DEBUG(zebra
, ZEBRA
))
2923 zlog_debug("Rx %s ESI %s VNI %u",
2924 (cmd
== ZEBRA_VNI_ADD
) ? "add" : "del",
2925 esi_to_str(&esi
, buf
, sizeof(buf
)), vni
);
2927 if (cmd
== ZEBRA_LOCAL_ES_EVI_ADD
) {
2928 frrtrace(2, frr_bgp
, evpn_mh_local_es_evi_add_zrecv
, &esi
, vni
);
2930 bgp_evpn_local_es_evi_add(bgp
, &esi
, vni
);
2932 frrtrace(2, frr_bgp
, evpn_mh_local_es_evi_del_zrecv
, &esi
, vni
);
2934 bgp_evpn_local_es_evi_del(bgp
, &esi
, vni
);
2940 static int bgp_zebra_process_local_l3vni(ZAPI_CALLBACK_ARGS
)
2944 struct ethaddr svi_rmac
, vrr_rmac
= {.octet
= {0} };
2945 struct in_addr originator_ip
;
2947 ifindex_t svi_ifindex
;
2948 bool is_anycast_mac
= false;
2950 memset(&svi_rmac
, 0, sizeof(svi_rmac
));
2951 memset(&originator_ip
, 0, sizeof(originator_ip
));
2953 l3vni
= stream_getl(s
);
2954 if (cmd
== ZEBRA_L3VNI_ADD
) {
2955 stream_get(&svi_rmac
, s
, sizeof(struct ethaddr
));
2956 originator_ip
.s_addr
= stream_get_ipv4(s
);
2957 stream_get(&filter
, s
, sizeof(int));
2958 svi_ifindex
= stream_getl(s
);
2959 stream_get(&vrr_rmac
, s
, sizeof(struct ethaddr
));
2960 is_anycast_mac
= stream_getl(s
);
2962 if (BGP_DEBUG(zebra
, ZEBRA
))
2964 "Rx L3-VNI ADD VRF %s VNI %u RMAC svi-mac %pEA vrr-mac %pEA filter %s svi-if %u",
2965 vrf_id_to_name(vrf_id
), l3vni
, &svi_rmac
,
2967 filter
? "prefix-routes-only" : "none",
2970 frrtrace(8, frr_bgp
, evpn_local_l3vni_add_zrecv
, l3vni
, vrf_id
,
2971 &svi_rmac
, &vrr_rmac
, filter
, originator_ip
,
2972 svi_ifindex
, is_anycast_mac
);
2974 bgp_evpn_local_l3vni_add(l3vni
, vrf_id
, &svi_rmac
, &vrr_rmac
,
2975 originator_ip
, filter
, svi_ifindex
,
2978 if (BGP_DEBUG(zebra
, ZEBRA
))
2979 zlog_debug("Rx L3-VNI DEL VRF %s VNI %u",
2980 vrf_id_to_name(vrf_id
), l3vni
);
2982 frrtrace(2, frr_bgp
, evpn_local_l3vni_del_zrecv
, l3vni
, vrf_id
);
2984 bgp_evpn_local_l3vni_del(l3vni
, vrf_id
);
2990 static int bgp_zebra_process_local_vni(ZAPI_CALLBACK_ARGS
)
2995 struct in_addr vtep_ip
= {INADDR_ANY
};
2996 vrf_id_t tenant_vrf_id
= VRF_DEFAULT
;
2997 struct in_addr mcast_grp
= {INADDR_ANY
};
2998 ifindex_t svi_ifindex
= 0;
3001 vni
= stream_getl(s
);
3002 if (cmd
== ZEBRA_VNI_ADD
) {
3003 vtep_ip
.s_addr
= stream_get_ipv4(s
);
3004 stream_get(&tenant_vrf_id
, s
, sizeof(vrf_id_t
));
3005 mcast_grp
.s_addr
= stream_get_ipv4(s
);
3006 stream_get(&svi_ifindex
, s
, sizeof(ifindex_t
));
3009 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
3013 if (BGP_DEBUG(zebra
, ZEBRA
))
3015 "Rx VNI %s VRF %s VNI %u tenant-vrf %s SVI ifindex %u",
3016 (cmd
== ZEBRA_VNI_ADD
) ? "add" : "del",
3017 vrf_id_to_name(vrf_id
), vni
,
3018 vrf_id_to_name(tenant_vrf_id
), svi_ifindex
);
3020 if (cmd
== ZEBRA_VNI_ADD
) {
3021 frrtrace(4, frr_bgp
, evpn_local_vni_add_zrecv
, vni
, vtep_ip
,
3022 tenant_vrf_id
, mcast_grp
);
3024 return bgp_evpn_local_vni_add(
3026 vtep_ip
.s_addr
!= INADDR_ANY
? vtep_ip
: bgp
->router_id
,
3027 tenant_vrf_id
, mcast_grp
, svi_ifindex
);
3029 frrtrace(1, frr_bgp
, evpn_local_vni_del_zrecv
, vni
);
3031 return bgp_evpn_local_vni_del(bgp
, vni
);
3035 static int bgp_zebra_process_local_macip(ZAPI_CALLBACK_ARGS
)
3044 uint32_t seqnum
= 0;
3046 char buf2
[ESI_STR_LEN
];
3049 memset(&ip
, 0, sizeof(ip
));
3051 vni
= stream_getl(s
);
3052 stream_get(&mac
.octet
, s
, ETH_ALEN
);
3053 ipa_len
= stream_getl(s
);
3054 if (ipa_len
!= 0 && ipa_len
!= IPV4_MAX_BYTELEN
3055 && ipa_len
!= IPV6_MAX_BYTELEN
) {
3056 flog_err(EC_BGP_MACIP_LEN
,
3057 "%u:Recv MACIP %s with invalid IP addr length %d",
3058 vrf_id
, (cmd
== ZEBRA_MACIP_ADD
) ? "Add" : "Del",
3065 (ipa_len
== IPV4_MAX_BYTELEN
) ? IPADDR_V4
: IPADDR_V6
;
3066 stream_get(&ip
.ip
.addr
, s
, ipa_len
);
3068 if (cmd
== ZEBRA_MACIP_ADD
) {
3069 flags
= stream_getc(s
);
3070 seqnum
= stream_getl(s
);
3071 stream_get(&esi
, s
, sizeof(esi_t
));
3073 state
= stream_getl(s
);
3074 memset(&esi
, 0, sizeof(esi_t
));
3077 bgp
= bgp_lookup_by_vrf_id(vrf_id
);
3081 if (BGP_DEBUG(zebra
, ZEBRA
))
3083 "%u:Recv MACIP %s f 0x%x MAC %pEA IP %pIA VNI %u seq %u state %d ESI %s",
3084 vrf_id
, (cmd
== ZEBRA_MACIP_ADD
) ? "Add" : "Del", flags
,
3085 &mac
, &ip
, vni
, seqnum
, state
,
3086 esi_to_str(&esi
, buf2
, sizeof(buf2
)));
3088 if (cmd
== ZEBRA_MACIP_ADD
) {
3089 frrtrace(6, frr_bgp
, evpn_local_macip_add_zrecv
, vni
, &mac
, &ip
,
3090 flags
, seqnum
, &esi
);
3092 return bgp_evpn_local_macip_add(bgp
, vni
, &mac
, &ip
,
3093 flags
, seqnum
, &esi
);
3095 frrtrace(4, frr_bgp
, evpn_local_macip_del_zrecv
, vni
, &mac
, &ip
,
3098 return bgp_evpn_local_macip_del(bgp
, vni
, &mac
, &ip
, state
);
3102 static int bgp_zebra_process_local_ip_prefix(ZAPI_CALLBACK_ARGS
)
3104 struct stream
*s
= NULL
;
3105 struct bgp
*bgp_vrf
= NULL
;
3108 memset(&p
, 0, sizeof(p
));
3110 stream_get(&p
, s
, sizeof(struct prefix
));
3112 bgp_vrf
= bgp_lookup_by_vrf_id(vrf_id
);
3116 if (BGP_DEBUG(zebra
, ZEBRA
))
3117 zlog_debug("Recv prefix %pFX %s on vrf %s", &p
,
3118 (cmd
== ZEBRA_IP_PREFIX_ROUTE_ADD
) ? "ADD" : "DEL",
3119 vrf_id_to_name(vrf_id
));
3121 if (cmd
== ZEBRA_IP_PREFIX_ROUTE_ADD
) {
3123 if (p
.family
== AF_INET
)
3124 bgp_evpn_advertise_type5_route(bgp_vrf
, &p
, NULL
,
3125 AFI_IP
, SAFI_UNICAST
);
3127 bgp_evpn_advertise_type5_route(bgp_vrf
, &p
, NULL
,
3128 AFI_IP6
, SAFI_UNICAST
);
3131 if (p
.family
== AF_INET
)
3132 bgp_evpn_withdraw_type5_route(bgp_vrf
, &p
, AFI_IP
,
3135 bgp_evpn_withdraw_type5_route(bgp_vrf
, &p
, AFI_IP6
,
3141 static int bgp_zebra_process_label_chunk(ZAPI_CALLBACK_ARGS
)
3143 struct stream
*s
= NULL
;
3144 uint8_t response_keep
;
3148 unsigned short instance
;
3151 STREAM_GETC(s
, proto
);
3152 STREAM_GETW(s
, instance
);
3153 STREAM_GETC(s
, response_keep
);
3154 STREAM_GETL(s
, first
);
3155 STREAM_GETL(s
, last
);
3157 if (zclient
->redist_default
!= proto
) {
3158 flog_err(EC_BGP_LM_ERROR
, "Got LM msg with wrong proto %u",
3162 if (zclient
->instance
!= instance
) {
3163 flog_err(EC_BGP_LM_ERROR
, "Got LM msg with wrong instance %u",
3169 first
< MPLS_LABEL_UNRESERVED_MIN
||
3170 last
> MPLS_LABEL_UNRESERVED_MAX
) {
3172 flog_err(EC_BGP_LM_ERROR
, "%s: Invalid Label chunk: %u - %u",
3173 __func__
, first
, last
);
3176 if (BGP_DEBUG(zebra
, ZEBRA
)) {
3177 zlog_debug("Label Chunk assign: %u - %u (%u) ",
3178 first
, last
, response_keep
);
3181 bgp_lp_event_chunk(response_keep
, first
, last
);
3185 stream_failure
: /* for STREAM_GETX */
3189 extern struct zebra_privs_t bgpd_privs
;
3191 static int bgp_ifp_create(struct interface
*ifp
)
3195 if (BGP_DEBUG(zebra
, ZEBRA
))
3196 zlog_debug("Rx Intf add VRF %u IF %s", ifp
->vrf
->vrf_id
,
3199 bgp
= ifp
->vrf
->info
;
3203 bgp_mac_add_mac_entry(ifp
);
3205 bgp_update_interface_nbrs(bgp
, ifp
, ifp
);
3206 hook_call(bgp_vrf_status_changed
, bgp
, ifp
);
3210 static int bgp_zebra_process_srv6_locator_chunk(ZAPI_CALLBACK_ARGS
)
3212 struct stream
*s
= NULL
;
3213 struct bgp
*bgp
= bgp_get_default();
3214 struct listnode
*node
;
3215 struct srv6_locator_chunk
*c
;
3216 struct srv6_locator_chunk
*chunk
= srv6_locator_chunk_alloc();
3219 zapi_srv6_locator_chunk_decode(s
, chunk
);
3221 if (strcmp(bgp
->srv6_locator_name
, chunk
->locator_name
) != 0) {
3222 zlog_err("%s: Locator name unmatch %s:%s", __func__
,
3223 bgp
->srv6_locator_name
, chunk
->locator_name
);
3224 srv6_locator_chunk_free(&chunk
);
3228 for (ALL_LIST_ELEMENTS_RO(bgp
->srv6_locator_chunks
, node
, c
)) {
3229 if (!prefix_cmp(&c
->prefix
, &chunk
->prefix
)) {
3230 srv6_locator_chunk_free(&chunk
);
3235 listnode_add(bgp
->srv6_locator_chunks
, chunk
);
3236 vpn_leak_postchange_all();
3240 static int bgp_zebra_process_srv6_locator_add(ZAPI_CALLBACK_ARGS
)
3242 struct srv6_locator loc
= {};
3243 struct bgp
*bgp
= bgp_get_default();
3244 const char *loc_name
= bgp
->srv6_locator_name
;
3246 if (zapi_srv6_locator_decode(zclient
->ibuf
, &loc
) < 0)
3249 if (!bgp
|| !bgp
->srv6_enabled
)
3252 if (bgp_zebra_srv6_manager_get_locator_chunk(loc_name
) < 0)
3258 static int bgp_zebra_process_srv6_locator_delete(ZAPI_CALLBACK_ARGS
)
3260 struct srv6_locator loc
= {};
3261 struct bgp
*bgp
= bgp_get_default();
3262 struct listnode
*node
, *nnode
;
3263 struct srv6_locator_chunk
*chunk
, *tovpn_sid_locator
;
3264 struct bgp_srv6_function
*func
;
3265 struct bgp
*bgp_vrf
;
3266 struct in6_addr
*tovpn_sid
;
3267 struct prefix_ipv6 tmp_prefi
;
3269 if (zapi_srv6_locator_decode(zclient
->ibuf
, &loc
) < 0)
3273 for (ALL_LIST_ELEMENTS(bgp
->srv6_locator_chunks
, node
, nnode
, chunk
))
3274 if (prefix_match((struct prefix
*)&loc
.prefix
,
3275 (struct prefix
*)&chunk
->prefix
)) {
3276 listnode_delete(bgp
->srv6_locator_chunks
, chunk
);
3277 srv6_locator_chunk_free(&chunk
);
3280 // refresh functions
3281 for (ALL_LIST_ELEMENTS(bgp
->srv6_functions
, node
, nnode
, func
)) {
3282 tmp_prefi
.family
= AF_INET6
;
3283 tmp_prefi
.prefixlen
= 128;
3284 tmp_prefi
.prefix
= func
->sid
;
3285 if (prefix_match((struct prefix
*)&loc
.prefix
,
3286 (struct prefix
*)&tmp_prefi
)) {
3287 listnode_delete(bgp
->srv6_functions
, func
);
3288 XFREE(MTYPE_BGP_SRV6_FUNCTION
, func
);
3292 // refresh tovpn_sid
3293 for (ALL_LIST_ELEMENTS_RO(bm
->bgp
, node
, bgp_vrf
)) {
3294 if (bgp_vrf
->inst_type
!= BGP_INSTANCE_TYPE_VRF
)
3297 // refresh vpnv4 tovpn_sid
3298 tovpn_sid
= bgp_vrf
->vpn_policy
[AFI_IP
].tovpn_sid
;
3300 tmp_prefi
.family
= AF_INET6
;
3301 tmp_prefi
.prefixlen
= 128;
3302 tmp_prefi
.prefix
= *tovpn_sid
;
3303 if (prefix_match((struct prefix
*)&loc
.prefix
,
3304 (struct prefix
*)&tmp_prefi
))
3305 XFREE(MTYPE_BGP_SRV6_SID
,
3306 bgp_vrf
->vpn_policy
[AFI_IP
].tovpn_sid
);
3309 // refresh vpnv6 tovpn_sid
3310 tovpn_sid
= bgp_vrf
->vpn_policy
[AFI_IP6
].tovpn_sid
;
3312 tmp_prefi
.family
= AF_INET6
;
3313 tmp_prefi
.prefixlen
= 128;
3314 tmp_prefi
.prefix
= *tovpn_sid
;
3315 if (prefix_match((struct prefix
*)&loc
.prefix
,
3316 (struct prefix
*)&tmp_prefi
))
3317 XFREE(MTYPE_BGP_SRV6_SID
,
3318 bgp_vrf
->vpn_policy
[AFI_IP6
].tovpn_sid
);
3321 /* refresh per-vrf tovpn_sid */
3322 tovpn_sid
= bgp_vrf
->tovpn_sid
;
3324 tmp_prefi
.family
= AF_INET6
;
3325 tmp_prefi
.prefixlen
= IPV6_MAX_BITLEN
;
3326 tmp_prefi
.prefix
= *tovpn_sid
;
3327 if (prefix_match((struct prefix
*)&loc
.prefix
,
3328 (struct prefix
*)&tmp_prefi
))
3329 XFREE(MTYPE_BGP_SRV6_SID
, bgp_vrf
->tovpn_sid
);
3333 vpn_leak_postchange_all();
3335 /* refresh tovpn_sid_locator */
3336 for (ALL_LIST_ELEMENTS_RO(bm
->bgp
, node
, bgp_vrf
)) {
3337 if (bgp_vrf
->inst_type
!= BGP_INSTANCE_TYPE_VRF
)
3340 /* refresh vpnv4 tovpn_sid_locator */
3342 bgp_vrf
->vpn_policy
[AFI_IP
].tovpn_sid_locator
;
3343 if (tovpn_sid_locator
) {
3344 tmp_prefi
.family
= AF_INET6
;
3345 tmp_prefi
.prefixlen
= IPV6_MAX_BITLEN
;
3346 tmp_prefi
.prefix
= tovpn_sid_locator
->prefix
.prefix
;
3347 if (prefix_match((struct prefix
*)&loc
.prefix
,
3348 (struct prefix
*)&tmp_prefi
))
3349 srv6_locator_chunk_free(
3350 &bgp_vrf
->vpn_policy
[AFI_IP
]
3351 .tovpn_sid_locator
);
3354 /* refresh vpnv6 tovpn_sid_locator */
3356 bgp_vrf
->vpn_policy
[AFI_IP6
].tovpn_sid_locator
;
3357 if (tovpn_sid_locator
) {
3358 tmp_prefi
.family
= AF_INET6
;
3359 tmp_prefi
.prefixlen
= IPV6_MAX_BITLEN
;
3360 tmp_prefi
.prefix
= tovpn_sid_locator
->prefix
.prefix
;
3361 if (prefix_match((struct prefix
*)&loc
.prefix
,
3362 (struct prefix
*)&tmp_prefi
))
3363 srv6_locator_chunk_free(
3364 &bgp_vrf
->vpn_policy
[AFI_IP6
]
3365 .tovpn_sid_locator
);
3368 /* refresh per-vrf tovpn_sid_locator */
3369 tovpn_sid_locator
= bgp_vrf
->tovpn_sid_locator
;
3370 if (tovpn_sid_locator
) {
3371 tmp_prefi
.family
= AF_INET6
;
3372 tmp_prefi
.prefixlen
= IPV6_MAX_BITLEN
;
3373 tmp_prefi
.prefix
= tovpn_sid_locator
->prefix
.prefix
;
3374 if (prefix_match((struct prefix
*)&loc
.prefix
,
3375 (struct prefix
*)&tmp_prefi
))
3376 srv6_locator_chunk_free(
3377 &bgp_vrf
->tovpn_sid_locator
);
3384 static zclient_handler
*const bgp_handlers
[] = {
3385 [ZEBRA_ROUTER_ID_UPDATE
] = bgp_router_id_update
,
3386 [ZEBRA_INTERFACE_ADDRESS_ADD
] = bgp_interface_address_add
,
3387 [ZEBRA_INTERFACE_ADDRESS_DELETE
] = bgp_interface_address_delete
,
3388 [ZEBRA_INTERFACE_NBR_ADDRESS_ADD
] = bgp_interface_nbr_address_add
,
3389 [ZEBRA_INTERFACE_NBR_ADDRESS_DELETE
] = bgp_interface_nbr_address_delete
,
3390 [ZEBRA_INTERFACE_VRF_UPDATE
] = bgp_interface_vrf_update
,
3391 [ZEBRA_REDISTRIBUTE_ROUTE_ADD
] = zebra_read_route
,
3392 [ZEBRA_REDISTRIBUTE_ROUTE_DEL
] = zebra_read_route
,
3393 [ZEBRA_NEXTHOP_UPDATE
] = bgp_read_nexthop_update
,
3394 [ZEBRA_FEC_UPDATE
] = bgp_read_fec_update
,
3395 [ZEBRA_LOCAL_ES_ADD
] = bgp_zebra_process_local_es_add
,
3396 [ZEBRA_LOCAL_ES_DEL
] = bgp_zebra_process_local_es_del
,
3397 [ZEBRA_VNI_ADD
] = bgp_zebra_process_local_vni
,
3398 [ZEBRA_LOCAL_ES_EVI_ADD
] = bgp_zebra_process_local_es_evi
,
3399 [ZEBRA_LOCAL_ES_EVI_DEL
] = bgp_zebra_process_local_es_evi
,
3400 [ZEBRA_VNI_DEL
] = bgp_zebra_process_local_vni
,
3401 [ZEBRA_MACIP_ADD
] = bgp_zebra_process_local_macip
,
3402 [ZEBRA_MACIP_DEL
] = bgp_zebra_process_local_macip
,
3403 [ZEBRA_L3VNI_ADD
] = bgp_zebra_process_local_l3vni
,
3404 [ZEBRA_L3VNI_DEL
] = bgp_zebra_process_local_l3vni
,
3405 [ZEBRA_IP_PREFIX_ROUTE_ADD
] = bgp_zebra_process_local_ip_prefix
,
3406 [ZEBRA_IP_PREFIX_ROUTE_DEL
] = bgp_zebra_process_local_ip_prefix
,
3407 [ZEBRA_GET_LABEL_CHUNK
] = bgp_zebra_process_label_chunk
,
3408 [ZEBRA_RULE_NOTIFY_OWNER
] = rule_notify_owner
,
3409 [ZEBRA_IPSET_NOTIFY_OWNER
] = ipset_notify_owner
,
3410 [ZEBRA_IPSET_ENTRY_NOTIFY_OWNER
] = ipset_entry_notify_owner
,
3411 [ZEBRA_IPTABLE_NOTIFY_OWNER
] = iptable_notify_owner
,
3412 [ZEBRA_ROUTE_NOTIFY_OWNER
] = bgp_zebra_route_notify_owner
,
3413 [ZEBRA_SRV6_LOCATOR_ADD
] = bgp_zebra_process_srv6_locator_add
,
3414 [ZEBRA_SRV6_LOCATOR_DELETE
] = bgp_zebra_process_srv6_locator_delete
,
3415 [ZEBRA_SRV6_MANAGER_GET_LOCATOR_CHUNK
] =
3416 bgp_zebra_process_srv6_locator_chunk
,
3419 static int bgp_if_new_hook(struct interface
*ifp
)
3421 struct bgp_interface
*iifp
;
3425 iifp
= XCALLOC(MTYPE_BGP_IF_INFO
, sizeof(struct bgp_interface
));
3431 static int bgp_if_delete_hook(struct interface
*ifp
)
3433 XFREE(MTYPE_BGP_IF_INFO
, ifp
->info
);
3437 void bgp_if_init(void)
3439 /* Initialize Zebra interface data structure. */
3440 hook_register_prio(if_add
, 0, bgp_if_new_hook
);
3441 hook_register_prio(if_del
, 0, bgp_if_delete_hook
);
3444 void bgp_zebra_init(struct thread_master
*master
, unsigned short instance
)
3446 zclient_num_connects
= 0;
3448 if_zapi_callbacks(bgp_ifp_create
, bgp_ifp_up
,
3449 bgp_ifp_down
, bgp_ifp_destroy
);
3451 /* Set default values. */
3452 zclient
= zclient_new(master
, &zclient_options_default
, bgp_handlers
,
3453 array_size(bgp_handlers
));
3454 zclient_init(zclient
, ZEBRA_ROUTE_BGP
, 0, &bgpd_privs
);
3455 zclient
->zebra_connected
= bgp_zebra_connected
;
3456 zclient
->instance
= instance
;
3459 void bgp_zebra_destroy(void)
3461 if (zclient
== NULL
)
3463 zclient_stop(zclient
);
3464 zclient_free(zclient
);
3468 int bgp_zebra_num_connects(void)
3470 return zclient_num_connects
;
3473 void bgp_send_pbr_rule_action(struct bgp_pbr_action
*pbra
,
3474 struct bgp_pbr_rule
*pbr
,
3479 if (pbra
->install_in_progress
&& !pbr
)
3481 if (pbr
&& pbr
->install_in_progress
)
3483 if (BGP_DEBUG(zebra
, ZEBRA
)) {
3485 zlog_debug("%s: table %d (ip rule) %d", __func__
,
3486 pbra
->table_id
, install
);
3488 zlog_debug("%s: table %d fwmark %d %d", __func__
,
3489 pbra
->table_id
, pbra
->fwmark
, install
);
3494 zclient_create_header(s
,
3495 install
? ZEBRA_RULE_ADD
: ZEBRA_RULE_DELETE
,
3497 stream_putl(s
, 1); /* send one pbr action */
3499 bgp_encode_pbr_rule_action(s
, pbra
, pbr
);
3501 stream_putw_at(s
, 0, stream_get_endp(s
));
3502 if ((zclient_send_message(zclient
) != ZCLIENT_SEND_FAILURE
)
3505 pbra
->install_in_progress
= true;
3507 pbr
->install_in_progress
= true;
3511 void bgp_send_pbr_ipset_match(struct bgp_pbr_match
*pbrim
, bool install
)
3515 if (pbrim
->install_in_progress
)
3517 if (BGP_DEBUG(zebra
, ZEBRA
))
3518 zlog_debug("%s: name %s type %d %d, ID %u", __func__
,
3519 pbrim
->ipset_name
, pbrim
->type
, install
,
3524 zclient_create_header(s
,
3525 install
? ZEBRA_IPSET_CREATE
:
3526 ZEBRA_IPSET_DESTROY
,
3529 stream_putl(s
, 1); /* send one pbr action */
3531 bgp_encode_pbr_ipset_match(s
, pbrim
);
3533 stream_putw_at(s
, 0, stream_get_endp(s
));
3534 if ((zclient_send_message(zclient
) != ZCLIENT_SEND_FAILURE
) && install
)
3535 pbrim
->install_in_progress
= true;
3538 void bgp_send_pbr_ipset_entry_match(struct bgp_pbr_match_entry
*pbrime
,
3543 if (pbrime
->install_in_progress
)
3545 if (BGP_DEBUG(zebra
, ZEBRA
))
3546 zlog_debug("%s: name %s %d %d, ID %u", __func__
,
3547 pbrime
->backpointer
->ipset_name
, pbrime
->unique
,
3548 install
, pbrime
->unique
);
3552 zclient_create_header(s
,
3553 install
? ZEBRA_IPSET_ENTRY_ADD
:
3554 ZEBRA_IPSET_ENTRY_DELETE
,
3557 stream_putl(s
, 1); /* send one pbr action */
3559 bgp_encode_pbr_ipset_entry_match(s
, pbrime
);
3561 stream_putw_at(s
, 0, stream_get_endp(s
));
3562 if ((zclient_send_message(zclient
) != ZCLIENT_SEND_FAILURE
) && install
)
3563 pbrime
->install_in_progress
= true;
3566 static void bgp_encode_pbr_interface_list(struct bgp
*bgp
, struct stream
*s
,
3569 struct bgp_pbr_config
*bgp_pbr_cfg
= bgp
->bgp_pbr_cfg
;
3570 struct bgp_pbr_interface_head
*head
;
3571 struct bgp_pbr_interface
*pbr_if
;
3572 struct interface
*ifp
;
3576 if (family
== AF_INET
)
3577 head
= &(bgp_pbr_cfg
->ifaces_by_name_ipv4
);
3579 head
= &(bgp_pbr_cfg
->ifaces_by_name_ipv6
);
3580 RB_FOREACH (pbr_if
, bgp_pbr_interface_head
, head
) {
3581 ifp
= if_lookup_by_name(pbr_if
->name
, bgp
->vrf_id
);
3583 stream_putl(s
, ifp
->ifindex
);
3587 static int bgp_pbr_get_ifnumber(struct bgp
*bgp
, uint8_t family
)
3589 struct bgp_pbr_config
*bgp_pbr_cfg
= bgp
->bgp_pbr_cfg
;
3590 struct bgp_pbr_interface_head
*head
;
3591 struct bgp_pbr_interface
*pbr_if
;
3596 if (family
== AF_INET
)
3597 head
= &(bgp_pbr_cfg
->ifaces_by_name_ipv4
);
3599 head
= &(bgp_pbr_cfg
->ifaces_by_name_ipv6
);
3600 RB_FOREACH (pbr_if
, bgp_pbr_interface_head
, head
) {
3601 if (if_lookup_by_name(pbr_if
->name
, bgp
->vrf_id
))
3607 void bgp_send_pbr_iptable(struct bgp_pbr_action
*pba
,
3608 struct bgp_pbr_match
*pbm
,
3615 if (pbm
->install_iptable_in_progress
)
3617 if (BGP_DEBUG(zebra
, ZEBRA
))
3618 zlog_debug("%s: name %s type %d mark %d %d, ID %u", __func__
,
3619 pbm
->ipset_name
, pbm
->type
, pba
->fwmark
, install
,
3624 zclient_create_header(s
,
3625 install
? ZEBRA_IPTABLE_ADD
:
3626 ZEBRA_IPTABLE_DELETE
,
3629 bgp_encode_pbr_iptable_match(s
, pba
, pbm
);
3630 nb_interface
= bgp_pbr_get_ifnumber(pba
->bgp
, pbm
->family
);
3631 stream_putl(s
, nb_interface
);
3633 bgp_encode_pbr_interface_list(pba
->bgp
, s
, pbm
->family
);
3634 stream_putw_at(s
, 0, stream_get_endp(s
));
3635 ret
= zclient_send_message(zclient
);
3637 if (ret
!= ZCLIENT_SEND_FAILURE
)
3640 pbm
->install_iptable_in_progress
= true;
3644 /* inject in table <table_id> a default route to:
3645 * - if nexthop IP is present : to this nexthop
3646 * - if vrf is different from local : to the matching VRF
3648 void bgp_zebra_announce_default(struct bgp
*bgp
, struct nexthop
*nh
,
3649 afi_t afi
, uint32_t table_id
, bool announce
)
3651 struct zapi_nexthop
*api_nh
;
3652 struct zapi_route api
;
3655 if (!nh
|| (nh
->type
!= NEXTHOP_TYPE_IPV4
3656 && nh
->type
!= NEXTHOP_TYPE_IPV6
)
3657 || nh
->vrf_id
== VRF_UNKNOWN
)
3660 /* in vrf-lite, no default route has to be announced
3661 * the table id of vrf is directly used to divert traffic
3663 if (!vrf_is_backend_netns() && bgp
->vrf_id
!= nh
->vrf_id
)
3666 memset(&p
, 0, sizeof(p
));
3667 if (afi
!= AFI_IP
&& afi
!= AFI_IP6
)
3669 p
.family
= afi2family(afi
);
3670 memset(&api
, 0, sizeof(api
));
3671 api
.vrf_id
= bgp
->vrf_id
;
3672 api
.type
= ZEBRA_ROUTE_BGP
;
3673 api
.safi
= SAFI_UNICAST
;
3675 api
.tableid
= table_id
;
3676 api
.nexthop_num
= 1;
3677 SET_FLAG(api
.message
, ZAPI_MESSAGE_TABLEID
);
3678 SET_FLAG(api
.message
, ZAPI_MESSAGE_NEXTHOP
);
3679 api_nh
= &api
.nexthops
[0];
3681 api
.distance
= ZEBRA_EBGP_DISTANCE_DEFAULT
;
3682 SET_FLAG(api
.message
, ZAPI_MESSAGE_DISTANCE
);
3685 if (afi
== AFI_IP
&& nh
->gate
.ipv4
.s_addr
!= INADDR_ANY
) {
3686 api_nh
->vrf_id
= nh
->vrf_id
;
3687 api_nh
->gate
.ipv4
= nh
->gate
.ipv4
;
3688 api_nh
->type
= NEXTHOP_TYPE_IPV4
;
3690 if (BGP_DEBUG(zebra
, ZEBRA
))
3692 "BGP: %s default route to %pI4 table %d (redirect IP)",
3693 announce
? "adding" : "withdrawing",
3694 &nh
->gate
.ipv4
, table_id
);
3696 zclient_route_send(announce
? ZEBRA_ROUTE_ADD
3697 : ZEBRA_ROUTE_DELETE
,
3699 } else if (afi
== AFI_IP6
&&
3700 memcmp(&nh
->gate
.ipv6
,
3701 &in6addr_any
, sizeof(struct in6_addr
))) {
3702 api_nh
->vrf_id
= nh
->vrf_id
;
3703 memcpy(&api_nh
->gate
.ipv6
, &nh
->gate
.ipv6
,
3704 sizeof(struct in6_addr
));
3705 api_nh
->type
= NEXTHOP_TYPE_IPV6
;
3707 if (BGP_DEBUG(zebra
, ZEBRA
))
3709 "BGP: %s default route to %pI6 table %d (redirect IP)",
3710 announce
? "adding" : "withdrawing",
3711 &nh
->gate
.ipv6
, table_id
);
3713 zclient_route_send(announce
? ZEBRA_ROUTE_ADD
3714 : ZEBRA_ROUTE_DELETE
,
3716 } else if (nh
->vrf_id
!= bgp
->vrf_id
) {
3718 struct interface
*ifp
;
3720 vrf
= vrf_lookup_by_id(nh
->vrf_id
);
3723 /* create default route with interface <VRF>
3724 * with nexthop-vrf <VRF>
3726 ifp
= if_lookup_by_name_vrf(vrf
->name
, vrf
);
3729 api_nh
->vrf_id
= nh
->vrf_id
;
3730 api_nh
->type
= NEXTHOP_TYPE_IFINDEX
;
3731 api_nh
->ifindex
= ifp
->ifindex
;
3732 if (BGP_DEBUG(zebra
, ZEBRA
))
3733 zlog_info("BGP: %s default route to %s table %d (redirect VRF)",
3734 announce
? "adding" : "withdrawing",
3735 vrf
->name
, table_id
);
3736 zclient_route_send(announce
? ZEBRA_ROUTE_ADD
3737 : ZEBRA_ROUTE_DELETE
,
3743 /* Send capabilities to RIB */
3744 int bgp_zebra_send_capabilities(struct bgp
*bgp
, bool disable
)
3746 struct zapi_cap api
;
3747 int ret
= BGP_GR_SUCCESS
;
3749 if (zclient
== NULL
) {
3750 if (BGP_DEBUG(zebra
, ZEBRA
))
3751 zlog_debug("zclient invalid");
3752 return BGP_GR_FAILURE
;
3755 /* Check if the client is connected */
3756 if ((zclient
->sock
< 0) || (zclient
->t_connect
)) {
3757 if (BGP_DEBUG(zebra
, ZEBRA
))
3758 zlog_debug("client not connected");
3759 return BGP_GR_FAILURE
;
3762 /* Check if capability is already sent. If the flag force is set
3763 * send the capability since this can be initial bgp configuration
3765 memset(&api
, 0, sizeof(api
));
3767 api
.cap
= ZEBRA_CLIENT_GR_DISABLE
;
3768 api
.vrf_id
= bgp
->vrf_id
;
3770 api
.cap
= ZEBRA_CLIENT_GR_CAPABILITIES
;
3771 api
.stale_removal_time
= bgp
->rib_stale_time
;
3772 api
.vrf_id
= bgp
->vrf_id
;
3775 if (zclient_capabilities_send(ZEBRA_CLIENT_CAPABILITIES
, zclient
, &api
)
3776 == ZCLIENT_SEND_FAILURE
) {
3777 zlog_err("error sending capability");
3778 ret
= BGP_GR_FAILURE
;
3781 bgp
->present_zebra_gr_state
= ZEBRA_GR_DISABLE
;
3783 bgp
->present_zebra_gr_state
= ZEBRA_GR_ENABLE
;
3785 if (BGP_DEBUG(zebra
, ZEBRA
))
3786 zlog_debug("send capabilty success");
3787 ret
= BGP_GR_SUCCESS
;
3792 /* Send route update pesding or completed status to RIB for the
3793 * specific AFI, SAFI
3795 int bgp_zebra_update(afi_t afi
, safi_t safi
, vrf_id_t vrf_id
, int type
)
3797 struct zapi_cap api
= {0};
3799 if (zclient
== NULL
) {
3800 if (BGP_DEBUG(zebra
, ZEBRA
))
3801 zlog_debug("zclient == NULL, invalid");
3802 return BGP_GR_FAILURE
;
3805 /* Check if the client is connected */
3806 if ((zclient
->sock
< 0) || (zclient
->t_connect
)) {
3807 if (BGP_DEBUG(zebra
, ZEBRA
))
3808 zlog_debug("client not connected");
3809 return BGP_GR_FAILURE
;
3814 api
.vrf_id
= vrf_id
;
3817 if (zclient_capabilities_send(ZEBRA_CLIENT_CAPABILITIES
, zclient
, &api
)
3818 == ZCLIENT_SEND_FAILURE
) {
3819 if (BGP_DEBUG(zebra
, ZEBRA
))
3820 zlog_debug("error sending capability");
3821 return BGP_GR_FAILURE
;
3823 return BGP_GR_SUCCESS
;
3827 /* Send RIB stale timer update */
3828 int bgp_zebra_stale_timer_update(struct bgp
*bgp
)
3830 struct zapi_cap api
;
3832 if (zclient
== NULL
) {
3833 if (BGP_DEBUG(zebra
, ZEBRA
))
3834 zlog_debug("zclient invalid");
3835 return BGP_GR_FAILURE
;
3838 /* Check if the client is connected */
3839 if ((zclient
->sock
< 0) || (zclient
->t_connect
)) {
3840 if (BGP_DEBUG(zebra
, ZEBRA
))
3841 zlog_debug("client not connected");
3842 return BGP_GR_FAILURE
;
3845 memset(&api
, 0, sizeof(api
));
3846 api
.cap
= ZEBRA_CLIENT_RIB_STALE_TIME
;
3847 api
.stale_removal_time
= bgp
->rib_stale_time
;
3848 api
.vrf_id
= bgp
->vrf_id
;
3849 if (zclient_capabilities_send(ZEBRA_CLIENT_CAPABILITIES
, zclient
, &api
)
3850 == ZCLIENT_SEND_FAILURE
) {
3851 if (BGP_DEBUG(zebra
, ZEBRA
))
3852 zlog_debug("error sending capability");
3853 return BGP_GR_FAILURE
;
3855 if (BGP_DEBUG(zebra
, ZEBRA
))
3856 zlog_debug("send capabilty success");
3857 return BGP_GR_SUCCESS
;
3860 int bgp_zebra_srv6_manager_get_locator_chunk(const char *name
)
3862 return srv6_manager_get_locator_chunk(zclient
, name
);
3865 int bgp_zebra_srv6_manager_release_locator_chunk(const char *name
)
3867 return srv6_manager_release_locator_chunk(zclient
, name
);