// SPDX-License-Identifier: GPL-2.0-or-later /* * * Copyright 2009-2016, LabN Consulting, L.L.C. * */ #include "lib/zebra.h" #include "lib/prefix.h" #include "lib/agg_table.h" #include "lib/vty.h" #include "lib/memory.h" #include "lib/routemap.h" #include "lib/log.h" #include "lib/linklist.h" #include "lib/command.h" #include "lib/stream.h" #include "bgpd/bgpd.h" #include "bgpd/bgp_ecommunity.h" #include "bgpd/bgp_attr.h" #include "bgpd/rfapi/bgp_rfapi_cfg.h" #include "bgpd/rfapi/rfapi.h" #include "bgpd/rfapi/rfapi_backend.h" #include "bgpd/bgp_route.h" #include "bgpd/bgp_mplsvpn.h" #include "bgpd/bgp_aspath.h" #include "bgpd/bgp_advertise.h" #include "bgpd/rfapi/rfapi_import.h" #include "bgpd/rfapi/rfapi_private.h" #include "bgpd/rfapi/rfapi_monitor.h" #include "bgpd/rfapi/rfapi_vty.h" #include "bgpd/rfapi/vnc_export_bgp.h" #include "bgpd/rfapi/vnc_export_bgp_p.h" #include "bgpd/rfapi/vnc_zebra.h" #include "bgpd/rfapi/vnc_import_bgp.h" #include "bgpd/rfapi/rfapi_rib.h" #include "bgpd/rfapi/rfapi_ap.h" #include "bgpd/rfapi/vnc_debug.h" /* * Per-NVE Advertised prefixes * * We maintain a list of prefixes advertised by each NVE. * There are two indices: by prefix and by lifetime. * * BY-PREFIX skiplist * * key: ptr to struct prefix (when storing, point to prefix that * is part of rfapi_adb). * * value: ptr to struct rfapi_adb * * BY-LIFETIME skiplist * * key: ptr to struct rfapi_adb * value: ptr to struct rfapi_adb * */ /* * Skiplist sort function that sorts first according to lifetime * and then according to adb pointer value. The adb pointer * is used to spread out the sort for adbs with the same lifetime * and thereby make the skip list operations more efficient. */ static int sl_adb_lifetime_cmp(const void *adb1, const void *adb2) { const struct rfapi_adb *a1 = adb1; const struct rfapi_adb *a2 = adb2; if (a1->lifetime < a2->lifetime) return -1; if (a1->lifetime > a2->lifetime) return 1; if (a1 < a2) return -1; if (a1 > a2) return 1; return 0; } void rfapiApInit(struct rfapi_advertised_prefixes *ap) { ap->ipN_by_prefix = skiplist_new(0, rfapi_rib_key_cmp, NULL); ap->ip0_by_ether = skiplist_new(0, rfapi_rib_key_cmp, NULL); ap->by_lifetime = skiplist_new(0, sl_adb_lifetime_cmp, NULL); } void rfapiApRelease(struct rfapi_advertised_prefixes *ap) { struct rfapi_adb *adb; /* Free ADBs and lifetime items */ while (0 == skiplist_first(ap->by_lifetime, NULL, (void **)&adb)) { rfapiAdbFree(adb); skiplist_delete_first(ap->by_lifetime); } while (0 == skiplist_delete_first(ap->ipN_by_prefix)) ; while (0 == skiplist_delete_first(ap->ip0_by_ether)) ; /* Free lists */ skiplist_free(ap->ipN_by_prefix); skiplist_free(ap->ip0_by_ether); skiplist_free(ap->by_lifetime); ap->ipN_by_prefix = NULL; ap->ip0_by_ether = NULL; ap->by_lifetime = NULL; } int rfapiApCount(struct rfapi_descriptor *rfd) { if (!rfd->advertised.by_lifetime) return 0; return skiplist_count(rfd->advertised.by_lifetime); } int rfapiApCountAll(struct bgp *bgp) { struct rfapi *h; struct listnode *node; struct rfapi_descriptor *rfd; int total = 0; h = bgp->rfapi; if (h) { for (ALL_LIST_ELEMENTS_RO(&h->descriptors, node, rfd)) { total += rfapiApCount(rfd); } } return total; } void rfapiApReadvertiseAll(struct bgp *bgp, struct rfapi_descriptor *rfd) { struct rfapi_adb *adb; void *cursor = NULL; int rc; for (rc = skiplist_next(rfd->advertised.by_lifetime, NULL, (void **)&adb, &cursor); rc == 0; rc = skiplist_next(rfd->advertised.by_lifetime, NULL, (void **)&adb, &cursor)) { struct prefix_rd prd; uint32_t local_pref = rfp_cost_to_localpref(adb->cost); prd = rfd->rd; prd.family = AF_UNSPEC; prd.prefixlen = 64; /* * TBD this is not quite right. When pfx_ip is 0/32 or 0/128, * we need to substitute the VN address as the prefix */ add_vnc_route(rfd, bgp, SAFI_MPLS_VPN, &adb->u.s.prefix_ip, &prd, /* RD to use (0 for ENCAP) */ &rfd->vn_addr, /* nexthop */ &local_pref, &adb->lifetime, NULL, NULL, /* struct rfapi_un_option */ NULL, /* struct rfapi_vn_option */ rfd->rt_export_list, NULL, /* med */ NULL, ZEBRA_ROUTE_BGP, BGP_ROUTE_RFP, 0); } } void rfapiApWithdrawAll(struct bgp *bgp, struct rfapi_descriptor *rfd) { struct rfapi_adb *adb; void *cursor; int rc; cursor = NULL; for (rc = skiplist_next(rfd->advertised.by_lifetime, NULL, (void **)&adb, &cursor); rc == 0; rc = skiplist_next(rfd->advertised.by_lifetime, NULL, (void **)&adb, &cursor)) { struct prefix pfx_vn_buf; struct prefix *pfx_ip; if (!(RFAPI_0_PREFIX(&adb->u.s.prefix_ip) && RFAPI_HOST_PREFIX(&adb->u.s.prefix_ip))) { pfx_ip = &adb->u.s.prefix_ip; } else { pfx_ip = NULL; /* * 0/32 or 0/128 => mac advertisement */ if (rfapiRaddr2Qprefix(&rfd->vn_addr, &pfx_vn_buf)) { /* * Bad: it means we can't delete the route */ vnc_zlog_debug_verbose( "%s: BAD: handle has bad vn_addr: skipping", __func__); continue; } } del_vnc_route(rfd, rfd->peer, bgp, SAFI_MPLS_VPN, pfx_ip ? pfx_ip : &pfx_vn_buf, &adb->u.s.prd, /* RD to use (0 for ENCAP) */ ZEBRA_ROUTE_BGP, BGP_ROUTE_RFP, NULL, 0); } } /* * returns nonzero if tunnel readvertisement is needed, 0 otherwise */ static int rfapiApAdjustLifetimeStats( struct rfapi_descriptor *rfd, uint32_t *old_lifetime, /* set if removing/replacing */ uint32_t *new_lifetime) /* set if replacing/adding */ { int advertise = 0; int find_max = 0; int find_min = 0; vnc_zlog_debug_verbose("%s: rfd=%p, pOldLife=%p, pNewLife=%p", __func__, rfd, old_lifetime, new_lifetime); if (old_lifetime) vnc_zlog_debug_verbose("%s: OldLife=%d", __func__, *old_lifetime); if (new_lifetime) vnc_zlog_debug_verbose("%s: NewLife=%d", __func__, *new_lifetime); if (new_lifetime) { /* * Adding new lifetime */ if (old_lifetime) { /* * replacing existing lifetime */ /* old and new are same */ if (*old_lifetime == *new_lifetime) return 0; if (*old_lifetime == rfd->min_prefix_lifetime) { find_min = 1; } if (*old_lifetime == rfd->max_prefix_lifetime) { find_max = 1; } /* no need to search if new value is at or equals * min|max */ if (*new_lifetime <= rfd->min_prefix_lifetime) { rfd->min_prefix_lifetime = *new_lifetime; find_min = 0; } if (*new_lifetime >= rfd->max_prefix_lifetime) { rfd->max_prefix_lifetime = *new_lifetime; advertise = 1; find_max = 0; } } else { /* * Just adding new lifetime */ if (*new_lifetime < rfd->min_prefix_lifetime) { rfd->min_prefix_lifetime = *new_lifetime; } if (*new_lifetime > rfd->max_prefix_lifetime) { advertise = 1; rfd->max_prefix_lifetime = *new_lifetime; } } } else { /* * Deleting */ /* * See if the max prefix lifetime for this NVE has decreased. * The easy optimization: track min & max; walk the table only * if they are different. * The general optimization: index the advertised_prefixes * table by lifetime. * * Note: for a given nve_descriptor, only one of the * advertised_prefixes[] tables will be used: viz., the * address family that matches the VN address. * */ if (rfd->max_prefix_lifetime == rfd->min_prefix_lifetime) { /* * Common case: all lifetimes are the same. Only * thing we need to do here is check if there are * no exported routes left. In that case, reinitialize * the max and min values. */ if (!rfapiApCount(rfd)) { rfd->max_prefix_lifetime = 0; rfd->min_prefix_lifetime = UINT32_MAX; } } else { if (old_lifetime) { if (*old_lifetime == rfd->min_prefix_lifetime) { find_min = 1; } if (*old_lifetime == rfd->max_prefix_lifetime) { find_max = 1; } } } } if (find_min || find_max) { uint32_t min = UINT32_MAX; uint32_t max = 0; struct rfapi_adb *adb_min; struct rfapi_adb *adb_max; if (!skiplist_first(rfd->advertised.by_lifetime, (void **)&adb_min, NULL) && !skiplist_last(rfd->advertised.by_lifetime, (void **)&adb_max, NULL)) { /* * This should always work */ min = adb_min->lifetime; max = adb_max->lifetime; } else { void *cursor; struct rfapi_rib_key rk; struct rfapi_adb *adb; int rc; vnc_zlog_debug_verbose( "%s: walking to find new min/max", __func__); cursor = NULL; for (rc = skiplist_next(rfd->advertised.ipN_by_prefix, (void **)&rk, (void **)&adb, &cursor); !rc; rc = skiplist_next(rfd->advertised.ipN_by_prefix, (void **)&rk, (void **)&adb, &cursor)) { uint32_t lt = adb->lifetime; if (lt > max) max = lt; if (lt < min) min = lt; } cursor = NULL; for (rc = skiplist_next(rfd->advertised.ip0_by_ether, (void **)&rk, (void **)&adb, &cursor); !rc; rc = skiplist_next(rfd->advertised.ip0_by_ether, (void **)&rk, (void **)&adb, &cursor)) { uint32_t lt = adb->lifetime; if (lt > max) max = lt; if (lt < min) min = lt; } } /* * trigger tunnel route update * but only if we found a VPN route and it had * a lifetime greater than 0 */ if (max && rfd->max_prefix_lifetime != max) advertise = 1; rfd->max_prefix_lifetime = max; rfd->min_prefix_lifetime = min; } vnc_zlog_debug_verbose("%s: returning advertise=%d, min=%d, max=%d", __func__, advertise, rfd->min_prefix_lifetime, rfd->max_prefix_lifetime); return (advertise != 0); } /* * Return Value * * 0 No need to advertise tunnel route * non-0 advertise tunnel route */ int rfapiApAdd(struct bgp *bgp, struct rfapi_descriptor *rfd, struct prefix *pfx_ip, struct prefix *pfx_eth, struct prefix_rd *prd, uint32_t lifetime, uint8_t cost, struct rfapi_l2address_option *l2o) /* other options TBD */ { int rc; struct rfapi_adb *adb; uint32_t old_lifetime = 0; int use_ip0 = 0; struct rfapi_rib_key rk; rfapi_rib_key_init(pfx_ip, prd, pfx_eth, &rk); if (RFAPI_0_PREFIX(pfx_ip) && RFAPI_HOST_PREFIX(pfx_ip)) { use_ip0 = 1; assert(pfx_eth); rc = skiplist_search(rfd->advertised.ip0_by_ether, &rk, (void **)&adb); } else { /* find prefix in advertised prefixes list */ rc = skiplist_search(rfd->advertised.ipN_by_prefix, &rk, (void **)&adb); } if (rc) { /* Not found */ adb = XCALLOC(MTYPE_RFAPI_ADB, sizeof(struct rfapi_adb)); adb->lifetime = lifetime; adb->u.key = rk; if (use_ip0) { assert(pfx_eth); skiplist_insert(rfd->advertised.ip0_by_ether, &adb->u.key, adb); } else { skiplist_insert(rfd->advertised.ipN_by_prefix, &adb->u.key, adb); } skiplist_insert(rfd->advertised.by_lifetime, adb, adb); } else { old_lifetime = adb->lifetime; if (old_lifetime != lifetime) { assert(!skiplist_delete(rfd->advertised.by_lifetime, adb, NULL)); adb->lifetime = lifetime; assert(!skiplist_insert(rfd->advertised.by_lifetime, adb, adb)); } } adb->cost = cost; if (l2o) adb->l2o = *l2o; else memset(&adb->l2o, 0, sizeof(struct rfapi_l2address_option)); if (rfapiApAdjustLifetimeStats(rfd, (rc ? NULL : &old_lifetime), &lifetime)) return 1; return 0; } /* * After this function returns successfully, caller should call * rfapiAdjustLifetimeStats() and possibly rfapiTunnelRouteAnnounce() */ int rfapiApDelete(struct bgp *bgp, struct rfapi_descriptor *rfd, struct prefix *pfx_ip, struct prefix *pfx_eth, struct prefix_rd *prd, int *advertise_tunnel) /* out */ { int rc; struct rfapi_adb *adb; uint32_t old_lifetime; int use_ip0 = 0; struct rfapi_rib_key rk; if (advertise_tunnel) *advertise_tunnel = 0; rfapi_rib_key_init(pfx_ip, prd, pfx_eth, &rk); /* find prefix in advertised prefixes list */ if (RFAPI_0_PREFIX(pfx_ip) && RFAPI_HOST_PREFIX(pfx_ip)) { use_ip0 = 1; assert(pfx_eth); rc = skiplist_search(rfd->advertised.ip0_by_ether, &rk, (void **)&adb); } else { /* find prefix in advertised prefixes list */ rc = skiplist_search(rfd->advertised.ipN_by_prefix, &rk, (void **)&adb); } if (rc) { return ENOENT; } old_lifetime = adb->lifetime; if (use_ip0) { rc = skiplist_delete(rfd->advertised.ip0_by_ether, &rk, NULL); } else { rc = skiplist_delete(rfd->advertised.ipN_by_prefix, &rk, NULL); } assert(!rc); rc = skiplist_delete(rfd->advertised.by_lifetime, adb, NULL); assert(!rc); rfapiAdbFree(adb); if (rfapiApAdjustLifetimeStats(rfd, &old_lifetime, NULL)) { if (advertise_tunnel) *advertise_tunnel = 1; } return 0; }