/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* * This module implements a STREAMS driver that provides layer-two (Ethernet) * bridging functionality. The STREAMS interface is used to provide * observability (snoop/wireshark) and control, but not for interface plumbing. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Locks and reference counts: object lifetime and design. * * bridge_mac_t * Bridge mac (snoop) instances are in bmac_list, which is protected by * bmac_rwlock. They're allocated by bmac_alloc and freed by bridge_timer(). * Every bridge_inst_t has a single bridge_mac_t, but when bridge_inst_t goes * away, the bridge_mac_t remains until either all of the users go away * (detected by a timer) or until the instance is picked up again by the same * bridge starting back up. * * bridge_inst_t * Bridge instances are in inst_list, which is protected by inst_lock. * They're allocated by inst_alloc() and freed by inst_free(). After * allocation, an instance is placed in inst_list, and the reference count is * incremented to represent this. That reference is decremented when the * BIF_SHUTDOWN flag is set, and no new increments may occur. When the last * reference is freed, the instance is removed from the list. * * Bridge instances have lists of links and an AVL tree of forwarding * entries. Each of these structures holds one reference on the bridge * instance. These lists and tree are protected by bi_rwlock. * * bridge_stream_t * Bridge streams are allocated by stream_alloc() and freed by stream_free(). * These streams are created when "bridged" opens /dev/bridgectl, and are * used to create new bridge instances (via BRIOC_NEWBRIDGE) and control the * links on the bridge. When a stream closes, the bridge instance created is * destroyed. There's at most one bridge instance for a given control * stream. * * bridge_link_t * Links are allocated by bridge_add_link() and freed by link_free(). The * bi_links list holds a reference to the link. When the BLF_DELETED flag is * set, that reference is dropped. The link isn't removed from the list * until the last reference drops. Each forwarding entry that uses a given * link holds a reference, as does each thread transmitting a packet via the * link. The MAC layer calls in via bridge_ref_cb() to hold a reference on * a link when transmitting. * * It's important that once BLF_DELETED is set, there's no way for the * reference count to increase again. If it can, then the link may be * double-freed. The BLF_FREED flag is intended for use with assertions to * guard against this in testing. * * bridge_fwd_t * Bridge forwarding entries are allocated by bridge_recv_cb() and freed by * fwd_free(). The bi_fwd AVL tree holds one reference to the entry. Unlike * other data structures, the reference is dropped when the entry is removed * from the tree by fwd_delete(), and the BFF_INTREE flag is removed. Each * thread that's forwarding a packet to a known destination holds a reference * to a forwarding entry. * * TRILL notes: * * The TRILL module does all of its I/O through bridging. It uses references * on the bridge_inst_t and bridge_link_t structures, and has seven entry * points and four callbacks. One entry point is for setting the callbacks * (bridge_trill_register_cb). There are four entry points for taking bridge * and link references (bridge_trill_{br,ln}{ref,unref}). The final two * entry points are for decapsulated packets from TRILL (bridge_trill_decaps) * that need to be bridged locally, and for TRILL-encapsulated output packets * (bridge_trill_output). * * The four callbacks comprise two notification functions for bridges and * links being deleted, one function for raw received TRILL packets, and one * for bridge output to non-local TRILL destinations (tunnel entry). */ /* * Ethernet reserved multicast addresses for TRILL; used also in TRILL module. */ const uint8_t all_isis_rbridges[] = ALL_ISIS_RBRIDGES; static const uint8_t all_esadi_rbridges[] = ALL_ESADI_RBRIDGES; const uint8_t bridge_group_address[] = BRIDGE_GROUP_ADDRESS; static const char *inst_kstats_list[] = { KSINST_NAMES }; static const char *link_kstats_list[] = { KSLINK_NAMES }; #define KREF(p, m, vn) p->m.vn.value.ui64 #define KINCR(p, m, vn) ++KREF(p, m, vn) #define KDECR(p, m, vn) --KREF(p, m, vn) #define KIPINCR(p, vn) KINCR(p, bi_kstats, vn) #define KIPDECR(p, vn) KDECR(p, bi_kstats, vn) #define KLPINCR(p, vn) KINCR(p, bl_kstats, vn) #define KIINCR(vn) KIPINCR(bip, vn) #define KIDECR(vn) KIPDECR(bip, vn) #define KLINCR(vn) KLPINCR(blp, vn) #define Dim(x) (sizeof (x) / sizeof (*(x))) /* Amount of overhead added when encapsulating with VLAN headers */ #define VLAN_INCR (sizeof (struct ether_vlan_header) - \ sizeof (struct ether_header)) static dev_info_t *bridge_dev_info; static major_t bridge_major; static ddi_taskq_t *bridge_taskq; /* * These are the bridge instance management data structures. The mutex lock * protects the list of bridge instances. A reference count is then used on * each instance to determine when to free it. We use mac_minor_hold() to * allocate minor_t values, which are used both for self-cloning /dev/net/ * device nodes as well as client streams. Minor node 0 is reserved for the * allocation control node. */ static list_t inst_list; static kcondvar_t inst_cv; /* Allows us to wait for shutdown */ static kmutex_t inst_lock; static krwlock_t bmac_rwlock; static list_t bmac_list; /* Wait for taskq entries that use STREAMS */ static kcondvar_t stream_ref_cv; static kmutex_t stream_ref_lock; static timeout_id_t bridge_timerid; static clock_t bridge_scan_interval; static clock_t bridge_fwd_age; static bridge_inst_t *bridge_find_name(const char *); static void bridge_timer(void *); static void bridge_unref(bridge_inst_t *); static const uint8_t zero_addr[ETHERADDRL] = { 0 }; /* Global TRILL linkage */ static trill_recv_pkt_t trill_recv_fn; static trill_encap_pkt_t trill_encap_fn; static trill_br_dstr_t trill_brdstr_fn; static trill_ln_dstr_t trill_lndstr_fn; /* special settings to accommodate DLD flow control; see dld_str.c */ static struct module_info bridge_dld_modinfo = { 0, /* mi_idnum */ "bridge", /* mi_idname */ 0, /* mi_minpsz */ INFPSZ, /* mi_maxpsz */ 1, /* mi_hiwat */ 0 /* mi_lowat */ }; static struct qinit bridge_dld_rinit = { NULL, /* qi_putp */ NULL, /* qi_srvp */ dld_open, /* qi_qopen */ dld_close, /* qi_qclose */ NULL, /* qi_qadmin */ &bridge_dld_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; static struct qinit bridge_dld_winit = { (int (*)())dld_wput, /* qi_putp */ (int (*)())dld_wsrv, /* qi_srvp */ NULL, /* qi_qopen */ NULL, /* qi_qclose */ NULL, /* qi_qadmin */ &bridge_dld_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; static int bridge_ioc_listfwd(void *, intptr_t, int, cred_t *, int *); /* GLDv3 control ioctls used by Bridging */ static dld_ioc_info_t bridge_ioc_list[] = { {BRIDGE_IOC_LISTFWD, DLDCOPYINOUT, sizeof (bridge_listfwd_t), bridge_ioc_listfwd, NULL}, }; /* * Given a bridge mac pointer, get a ref-held pointer to the corresponding * bridge instance, if any. We must hold the global bmac_rwlock so that * bm_inst doesn't slide out from under us. */ static bridge_inst_t * mac_to_inst(const bridge_mac_t *bmp) { bridge_inst_t *bip; rw_enter(&bmac_rwlock, RW_READER); if ((bip = bmp->bm_inst) != NULL) atomic_inc_uint(&bip->bi_refs); rw_exit(&bmac_rwlock); return (bip); } static void link_sdu_fail(bridge_link_t *blp, boolean_t failed, mblk_t **mlist) { mblk_t *mp; bridge_ctl_t *bcp; bridge_link_t *blcmp; bridge_inst_t *bip; bridge_mac_t *bmp; if (failed) { if (blp->bl_flags & BLF_SDUFAIL) return; blp->bl_flags |= BLF_SDUFAIL; } else { if (!(blp->bl_flags & BLF_SDUFAIL)) return; blp->bl_flags &= ~BLF_SDUFAIL; } /* * If this link is otherwise up, then check if there are any other * non-failed non-down links. If not, then we control the state of the * whole bridge. */ bip = blp->bl_inst; bmp = bip->bi_mac; if (blp->bl_linkstate != LINK_STATE_DOWN) { for (blcmp = list_head(&bip->bi_links); blcmp != NULL; blcmp = list_next(&bip->bi_links, blcmp)) { if (blp != blcmp && !(blcmp->bl_flags & (BLF_DELETED|BLF_SDUFAIL)) && blcmp->bl_linkstate != LINK_STATE_DOWN) break; } if (blcmp == NULL) { bmp->bm_linkstate = failed ? LINK_STATE_DOWN : LINK_STATE_UP; mac_link_redo(bmp->bm_mh, bmp->bm_linkstate); } } /* * If we're becoming failed, then the link's current true state needs * to be reflected upwards to this link's clients. If we're becoming * unfailed, then we get the state of the bridge instead on all * clients. */ if (failed) { if (bmp->bm_linkstate != blp->bl_linkstate) mac_link_redo(blp->bl_mh, blp->bl_linkstate); } else { mac_link_redo(blp->bl_mh, bmp->bm_linkstate); } /* get the current mblk we're going to send up */ if ((mp = blp->bl_lfailmp) == NULL && (mp = allocb(sizeof (bridge_ctl_t), BPRI_MED)) == NULL) return; /* get a new one for next time */ blp->bl_lfailmp = allocb(sizeof (bridge_ctl_t), BPRI_MED); /* if none for next time, then report only failures */ if (blp->bl_lfailmp == NULL && !failed) { blp->bl_lfailmp = mp; return; } /* LINTED: alignment */ bcp = (bridge_ctl_t *)mp->b_rptr; bcp->bc_linkid = blp->bl_linkid; bcp->bc_failed = failed; mp->b_wptr = (uchar_t *)(bcp + 1); mp->b_next = *mlist; *mlist = mp; } /* * Send control messages (link SDU changes) using the stream to the * bridge instance daemon. */ static void send_up_messages(bridge_inst_t *bip, mblk_t *mp) { mblk_t *mnext; queue_t *rq; rq = bip->bi_control->bs_wq; rq = OTHERQ(rq); while (mp != NULL) { mnext = mp->b_next; mp->b_next = NULL; putnext(rq, mp); mp = mnext; } } /* ARGSUSED */ static int bridge_m_getstat(void *arg, uint_t stat, uint64_t *val) { return (ENOTSUP); } static int bridge_m_start(void *arg) { bridge_mac_t *bmp = arg; bmp->bm_flags |= BMF_STARTED; return (0); } static void bridge_m_stop(void *arg) { bridge_mac_t *bmp = arg; bmp->bm_flags &= ~BMF_STARTED; } /* ARGSUSED */ static int bridge_m_setpromisc(void *arg, boolean_t on) { return (0); } /* ARGSUSED */ static int bridge_m_multicst(void *arg, boolean_t add, const uint8_t *mca) { return (0); } /* ARGSUSED */ static int bridge_m_unicst(void *arg, const uint8_t *macaddr) { return (ENOTSUP); } static mblk_t * bridge_m_tx(void *arg, mblk_t *mp) { _NOTE(ARGUNUSED(arg)); freemsgchain(mp); return (NULL); } /* ARGSUSED */ static int bridge_ioc_listfwd(void *karg, intptr_t arg, int mode, cred_t *cred, int *rvalp) { bridge_listfwd_t *blf = karg; bridge_inst_t *bip; bridge_fwd_t *bfp, match; avl_index_t where; bip = bridge_find_name(blf->blf_name); if (bip == NULL) return (ENOENT); bcopy(blf->blf_dest, match.bf_dest, ETHERADDRL); match.bf_flags |= BFF_VLANLOCAL; rw_enter(&bip->bi_rwlock, RW_READER); if ((bfp = avl_find(&bip->bi_fwd, &match, &where)) == NULL) bfp = avl_nearest(&bip->bi_fwd, where, AVL_AFTER); else bfp = AVL_NEXT(&bip->bi_fwd, bfp); if (bfp == NULL) { bzero(blf, sizeof (*blf)); } else { bcopy(bfp->bf_dest, blf->blf_dest, ETHERADDRL); blf->blf_trill_nick = bfp->bf_trill_nick; blf->blf_ms_age = drv_hztousec(lbolt - bfp->bf_lastheard) / 1000; blf->blf_is_local = (bfp->bf_flags & BFF_LOCALADDR) != 0; blf->blf_linkid = bfp->bf_links[0]->bl_linkid; } rw_exit(&bip->bi_rwlock); bridge_unref(bip); return (0); } static int bridge_m_setprop(void *arg, const char *pr_name, mac_prop_id_t pr_num, uint_t pr_valsize, const void *pr_val) { bridge_mac_t *bmp = arg; bridge_inst_t *bip; bridge_link_t *blp; int err; uint_t maxsdu; mblk_t *mlist; _NOTE(ARGUNUSED(pr_name)); switch (pr_num) { case MAC_PROP_MTU: if (pr_valsize < sizeof (bmp->bm_maxsdu)) { err = EINVAL; break; } (void) bcopy(pr_val, &maxsdu, sizeof (maxsdu)); if (maxsdu == bmp->bm_maxsdu) { err = 0; } else if ((bip = mac_to_inst(bmp)) == NULL) { err = ENXIO; } else { rw_enter(&bip->bi_rwlock, RW_WRITER); mlist = NULL; for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (blp->bl_flags & BLF_DELETED) continue; if (blp->bl_maxsdu == maxsdu) link_sdu_fail(blp, B_FALSE, &mlist); else if (blp->bl_maxsdu == bmp->bm_maxsdu) link_sdu_fail(blp, B_TRUE, &mlist); } rw_exit(&bip->bi_rwlock); bmp->bm_maxsdu = maxsdu; (void) mac_maxsdu_update(bmp->bm_mh, maxsdu); send_up_messages(bip, mlist); bridge_unref(bip); err = 0; } break; default: err = ENOTSUP; break; } return (err); } static int bridge_m_getprop(void *arg, const char *pr_name, mac_prop_id_t pr_num, uint_t pr_flags, uint_t pr_valsize, void *pr_val, uint_t *perm) { bridge_mac_t *bmp = arg; int err = 0; _NOTE(ARGUNUSED(pr_name)); switch (pr_num) { case MAC_PROP_MTU: { mac_propval_range_t range; if (!(pr_flags & MAC_PROP_POSSIBLE)) return (ENOTSUP); if (pr_valsize < sizeof (mac_propval_range_t)) return (EINVAL); range.mpr_count = 1; range.mpr_type = MAC_PROPVAL_UINT32; range.range_uint32[0].mpur_min = range.range_uint32[0].mpur_max = bmp->bm_maxsdu; bcopy(&range, pr_val, sizeof (range)); *perm = MAC_PROP_PERM_RW; break; } case MAC_PROP_STATUS: if (pr_valsize < sizeof (bmp->bm_linkstate)) { err = EINVAL; } else { bcopy(&bmp->bm_linkstate, pr_val, sizeof (&bmp->bm_linkstate)); *perm = MAC_PROP_PERM_READ; } break; default: err = ENOTSUP; break; } return (err); } static mac_callbacks_t bridge_m_callbacks = { MC_SETPROP | MC_GETPROP, bridge_m_getstat, bridge_m_start, bridge_m_stop, bridge_m_setpromisc, bridge_m_multicst, bridge_m_unicst, bridge_m_tx, NULL, /* ioctl */ NULL, /* getcapab */ NULL, /* open */ NULL, /* close */ bridge_m_setprop, bridge_m_getprop }; /* * Create kstats from a list. */ static kstat_t * kstat_setup(kstat_named_t *knt, const char **names, int nstat, const char *unitname) { kstat_t *ksp; int i; for (i = 0; i < nstat; i++) kstat_named_init(&knt[i], names[i], KSTAT_DATA_UINT64); ksp = kstat_create_zone("bridge", 0, unitname, "net", KSTAT_TYPE_NAMED, nstat, KSTAT_FLAG_VIRTUAL, GLOBAL_ZONEID); if (ksp != NULL) { ksp->ks_data = knt; kstat_install(ksp); } return (ksp); } /* * Find an existing bridge_mac_t structure or allocate a new one for the given * bridge instance. This creates the mac driver instance that snoop can use. */ static int bmac_alloc(bridge_inst_t *bip, bridge_mac_t **bmacp) { bridge_mac_t *bmp, *bnew; mac_register_t *mac; int err; *bmacp = NULL; if ((mac = mac_alloc(MAC_VERSION)) == NULL) return (EINVAL); bnew = kmem_zalloc(sizeof (*bnew), KM_SLEEP); rw_enter(&bmac_rwlock, RW_WRITER); for (bmp = list_head(&bmac_list); bmp != NULL; bmp = list_next(&bmac_list, bmp)) { if (strcmp(bip->bi_name, bmp->bm_name) == 0) { ASSERT(bmp->bm_inst == NULL); bmp->bm_inst = bip; rw_exit(&bmac_rwlock); kmem_free(bnew, sizeof (*bnew)); mac_free(mac); *bmacp = bmp; return (0); } } mac->m_type_ident = MAC_PLUGIN_IDENT_ETHER; mac->m_driver = bnew; mac->m_dip = bridge_dev_info; mac->m_instance = (uint_t)-1; mac->m_src_addr = (uint8_t *)zero_addr; mac->m_callbacks = &bridge_m_callbacks; /* * Note that the SDU limits are irrelevant, as nobody transmits on the * bridge node itself. It's mainly for monitoring but we allow * setting the bridge MTU for quick transition of all links part of the * bridge to a new MTU. */ mac->m_min_sdu = 1; mac->m_max_sdu = 1500; err = mac_register(mac, &bnew->bm_mh); mac_free(mac); if (err != 0) { rw_exit(&bmac_rwlock); kmem_free(bnew, sizeof (*bnew)); return (err); } bnew->bm_inst = bip; (void) strcpy(bnew->bm_name, bip->bi_name); if (list_is_empty(&bmac_list)) { bridge_timerid = timeout(bridge_timer, NULL, bridge_scan_interval); } list_insert_tail(&bmac_list, bnew); rw_exit(&bmac_rwlock); /* * Mark the MAC as unable to go "active" so that only passive clients * (such as snoop) can bind to it. */ mac_no_active(bnew->bm_mh); *bmacp = bnew; return (0); } /* * Disconnect the given bridge_mac_t from its bridge instance. The bridge * instance is going away. The mac instance can't go away until the clients * are gone (see bridge_timer). */ static void bmac_disconnect(bridge_mac_t *bmp) { bridge_inst_t *bip; bmp->bm_linkstate = LINK_STATE_DOWN; mac_link_redo(bmp->bm_mh, LINK_STATE_DOWN); rw_enter(&bmac_rwlock, RW_READER); bip = bmp->bm_inst; bip->bi_mac = NULL; bmp->bm_inst = NULL; rw_exit(&bmac_rwlock); } /* This is used by the avl trees to sort forwarding table entries */ static int fwd_compare(const void *addr1, const void *addr2) { const bridge_fwd_t *fwd1 = addr1; const bridge_fwd_t *fwd2 = addr2; int diff = memcmp(fwd1->bf_dest, fwd2->bf_dest, ETHERADDRL); if (diff != 0) return (diff > 0 ? 1 : -1); if ((fwd1->bf_flags ^ fwd2->bf_flags) & BFF_VLANLOCAL) { if (fwd1->bf_vlanid > fwd2->bf_vlanid) return (1); else if (fwd1->bf_vlanid < fwd2->bf_vlanid) return (-1); } return (0); } static void inst_free(bridge_inst_t *bip) { ASSERT(bip->bi_mac == NULL); rw_destroy(&bip->bi_rwlock); list_destroy(&bip->bi_links); cv_destroy(&bip->bi_linkwait); avl_destroy(&bip->bi_fwd); if (bip->bi_ksp != NULL) kstat_delete(bip->bi_ksp); kmem_free(bip, sizeof (*bip)); } static bridge_inst_t * inst_alloc(const char *bridge) { bridge_inst_t *bip; bip = kmem_zalloc(sizeof (*bip), KM_SLEEP); bip->bi_refs = 1; (void) strcpy(bip->bi_name, bridge); rw_init(&bip->bi_rwlock, NULL, RW_DRIVER, NULL); list_create(&bip->bi_links, sizeof (bridge_link_t), offsetof(bridge_link_t, bl_node)); cv_init(&bip->bi_linkwait, NULL, CV_DRIVER, NULL); avl_create(&bip->bi_fwd, fwd_compare, sizeof (bridge_fwd_t), offsetof(bridge_fwd_t, bf_node)); return (bip); } static bridge_inst_t * bridge_find_name(const char *bridge) { bridge_inst_t *bip; mutex_enter(&inst_lock); for (bip = list_head(&inst_list); bip != NULL; bip = list_next(&inst_list, bip)) { if (!(bip->bi_flags & BIF_SHUTDOWN) && strcmp(bridge, bip->bi_name) == 0) { atomic_inc_uint(&bip->bi_refs); break; } } mutex_exit(&inst_lock); return (bip); } static int bridge_create(datalink_id_t linkid, const char *bridge, bridge_inst_t **bipc) { bridge_inst_t *bip, *bipnew; bridge_mac_t *bmp = NULL; int err; *bipc = NULL; bipnew = inst_alloc(bridge); mutex_enter(&inst_lock); lookup_retry: for (bip = list_head(&inst_list); bip != NULL; bip = list_next(&inst_list, bip)) { if (strcmp(bridge, bip->bi_name) == 0) break; } /* This should not take long; if it does, we've got a design problem */ if (bip != NULL && (bip->bi_flags & BIF_SHUTDOWN)) { cv_wait(&inst_cv, &inst_lock); goto lookup_retry; } if (bip != NULL) { /* We weren't expecting to find anything */ bip = NULL; err = EEXIST; } else { bip = bipnew; bipnew = NULL; list_insert_tail(&inst_list, bip); } mutex_exit(&inst_lock); if (bip == NULL) goto fail; bip->bi_ksp = kstat_setup((kstat_named_t *)&bip->bi_kstats, inst_kstats_list, Dim(inst_kstats_list), bip->bi_name); err = bmac_alloc(bip, &bmp); if ((bip->bi_mac = bmp) == NULL) goto fail_create; /* * bm_inst is set, so the timer cannot yank the DLS rug from under us. * No extra locking is needed here. */ if (!(bmp->bm_flags & BMF_DLS)) { if ((err = dls_devnet_create(bmp->bm_mh, linkid)) != 0) goto fail_create; bmp->bm_flags |= BMF_DLS; } bip->bi_dev = makedevice(bridge_major, mac_minor(bmp->bm_mh)); *bipc = bip; return (0); fail_create: if (bmp != NULL) bmac_disconnect(bip->bi_mac); bipnew = bip; fail: ASSERT(bipnew->bi_trilldata == NULL); bipnew->bi_flags |= BIF_SHUTDOWN; inst_free(bipnew); return (err); } static void bridge_unref(bridge_inst_t *bip) { if (atomic_dec_uint_nv(&bip->bi_refs) == 0) { ASSERT(bip->bi_flags & BIF_SHUTDOWN); /* free up mac for reuse before leaving global list */ if (bip->bi_mac != NULL) bmac_disconnect(bip->bi_mac); mutex_enter(&inst_lock); list_remove(&inst_list, bip); cv_broadcast(&inst_cv); mutex_exit(&inst_lock); inst_free(bip); } } /* * Stream instances are used only for allocating bridges and serving as a * control node. They serve no data-handling function. */ static bridge_stream_t * stream_alloc(void) { bridge_stream_t *bsp; minor_t mn; if ((mn = mac_minor_hold(B_FALSE)) == 0) return (NULL); bsp = kmem_zalloc(sizeof (*bsp), KM_SLEEP); bsp->bs_minor = mn; return (bsp); } static void stream_free(bridge_stream_t *bsp) { mac_minor_rele(bsp->bs_minor); kmem_free(bsp, sizeof (*bsp)); } /* Reference hold/release functions for STREAMS-related taskq */ static void stream_ref(bridge_stream_t *bsp) { mutex_enter(&stream_ref_lock); bsp->bs_taskq_cnt++; mutex_exit(&stream_ref_lock); } static void stream_unref(bridge_stream_t *bsp) { mutex_enter(&stream_ref_lock); if (--bsp->bs_taskq_cnt == 0) cv_broadcast(&stream_ref_cv); mutex_exit(&stream_ref_lock); } static void link_free(bridge_link_t *blp) { bridge_inst_t *bip = blp->bl_inst; ASSERT(!(blp->bl_flags & BLF_FREED)); blp->bl_flags |= BLF_FREED; if (blp->bl_ksp != NULL) kstat_delete(blp->bl_ksp); if (blp->bl_lfailmp != NULL) freeb(blp->bl_lfailmp); cv_destroy(&blp->bl_trillwait); mutex_destroy(&blp->bl_trilllock); kmem_free(blp, sizeof (*blp)); /* Don't unreference the bridge until the MAC is closed */ bridge_unref(bip); } static void link_unref(bridge_link_t *blp) { if (atomic_dec_uint_nv(&blp->bl_refs) == 0) { bridge_inst_t *bip = blp->bl_inst; ASSERT(blp->bl_flags & BLF_DELETED); rw_enter(&bip->bi_rwlock, RW_WRITER); list_remove(&bip->bi_links, blp); rw_exit(&bip->bi_rwlock); if (bip->bi_trilldata != NULL && list_is_empty(&bip->bi_links)) cv_broadcast(&bip->bi_linkwait); link_free(blp); } } static bridge_fwd_t * fwd_alloc(const uint8_t *addr, uint_t nlinks, uint16_t nick) { bridge_fwd_t *bfp; bfp = kmem_zalloc(sizeof (*bfp) + (nlinks * sizeof (bridge_link_t *)), KM_NOSLEEP); if (bfp != NULL) { bcopy(addr, bfp->bf_dest, ETHERADDRL); bfp->bf_lastheard = lbolt; bfp->bf_maxlinks = nlinks; bfp->bf_links = (bridge_link_t **)(bfp + 1); bfp->bf_trill_nick = nick; } return (bfp); } static bridge_fwd_t * fwd_find(bridge_inst_t *bip, const uint8_t *addr, uint16_t vlanid) { bridge_fwd_t *bfp, *vbfp; bridge_fwd_t match; bcopy(addr, match.bf_dest, ETHERADDRL); match.bf_flags = 0; rw_enter(&bip->bi_rwlock, RW_READER); if ((bfp = avl_find(&bip->bi_fwd, &match, NULL)) != NULL) { if (bfp->bf_vlanid != vlanid && bfp->bf_vcnt > 0) { match.bf_vlanid = vlanid; match.bf_flags = BFF_VLANLOCAL; vbfp = avl_find(&bip->bi_fwd, &match, NULL); if (vbfp != NULL) bfp = vbfp; } atomic_inc_uint(&bfp->bf_refs); } rw_exit(&bip->bi_rwlock); return (bfp); } static void fwd_free(bridge_fwd_t *bfp) { uint_t i; bridge_inst_t *bip = bfp->bf_links[0]->bl_inst; KIDECR(bki_count); for (i = 0; i < bfp->bf_nlinks; i++) link_unref(bfp->bf_links[i]); kmem_free(bfp, sizeof (*bfp) + bfp->bf_maxlinks * sizeof (bridge_link_t *)); } static void fwd_unref(bridge_fwd_t *bfp) { if (atomic_dec_uint_nv(&bfp->bf_refs) == 0) { ASSERT(!(bfp->bf_flags & BFF_INTREE)); fwd_free(bfp); } } static void fwd_delete(bridge_fwd_t *bfp) { bridge_inst_t *bip; bridge_fwd_t *bfpzero; if (bfp->bf_flags & BFF_INTREE) { ASSERT(bfp->bf_nlinks > 0); bip = bfp->bf_links[0]->bl_inst; rw_enter(&bip->bi_rwlock, RW_WRITER); /* Another thread could beat us to this */ if (bfp->bf_flags & BFF_INTREE) { avl_remove(&bip->bi_fwd, bfp); bfp->bf_flags &= ~BFF_INTREE; if (bfp->bf_flags & BFF_VLANLOCAL) { bfp->bf_flags &= ~BFF_VLANLOCAL; bfpzero = avl_find(&bip->bi_fwd, bfp, NULL); if (bfpzero != NULL && bfpzero->bf_vcnt > 0) bfpzero->bf_vcnt--; } rw_exit(&bip->bi_rwlock); fwd_unref(bfp); /* no longer in avl tree */ } else { rw_exit(&bip->bi_rwlock); } } } static boolean_t fwd_insert(bridge_inst_t *bip, bridge_fwd_t *bfp) { avl_index_t idx; boolean_t retv; rw_enter(&bip->bi_rwlock, RW_WRITER); if (!(bip->bi_flags & BIF_SHUTDOWN) && avl_numnodes(&bip->bi_fwd) < bip->bi_tablemax && avl_find(&bip->bi_fwd, bfp, &idx) == NULL) { avl_insert(&bip->bi_fwd, bfp, idx); bfp->bf_flags |= BFF_INTREE; atomic_inc_uint(&bfp->bf_refs); /* avl entry */ retv = B_TRUE; } else { retv = B_FALSE; } rw_exit(&bip->bi_rwlock); return (retv); } static void fwd_update_local(bridge_link_t *blp, const uint8_t *oldaddr, const uint8_t *newaddr) { bridge_inst_t *bip = blp->bl_inst; bridge_fwd_t *bfp, *bfnew; bridge_fwd_t match; avl_index_t idx; boolean_t drop_ref = B_FALSE; if (bcmp(oldaddr, newaddr, ETHERADDRL) == 0) return; if (bcmp(oldaddr, zero_addr, ETHERADDRL) == 0) goto no_old_addr; /* * Find the previous entry, and remove our link from it. */ bcopy(oldaddr, match.bf_dest, ETHERADDRL); rw_enter(&bip->bi_rwlock, RW_WRITER); if ((bfp = avl_find(&bip->bi_fwd, &match, NULL)) != NULL) { int i; /* * See if we're in the list, and remove if so. */ for (i = 0; i < bfp->bf_nlinks; i++) { if (bfp->bf_links[i] == blp) { /* * We assume writes are atomic, so no special * MT handling is needed. The list length is * decremented first, and then we remove * entries. */ bfp->bf_nlinks--; for (; i < bfp->bf_nlinks; i++) bfp->bf_links[i] = bfp->bf_links[i + 1]; drop_ref = B_TRUE; break; } } /* If no more links, then remove and free up */ if (bfp->bf_nlinks == 0) { avl_remove(&bip->bi_fwd, bfp); bfp->bf_flags &= ~BFF_INTREE; } else { bfp = NULL; } } rw_exit(&bip->bi_rwlock); if (bfp != NULL) fwd_unref(bfp); /* no longer in avl tree */ /* * Now get the new link address and add this link to the list. The * list should be of length 1 unless the user has configured multiple * NICs with the same address. (That's an incorrect configuration, but * we support it anyway.) */ no_old_addr: bfp = NULL; if ((bip->bi_flags & BIF_SHUTDOWN) || bcmp(newaddr, zero_addr, ETHERADDRL) == 0) goto no_new_addr; bcopy(newaddr, match.bf_dest, ETHERADDRL); rw_enter(&bip->bi_rwlock, RW_WRITER); if ((bfp = avl_find(&bip->bi_fwd, &match, &idx)) == NULL) { bfnew = fwd_alloc(newaddr, 1, RBRIDGE_NICKNAME_NONE); if (bfnew != NULL) KIINCR(bki_count); } else if (bfp->bf_nlinks < bfp->bf_maxlinks) { /* special case: link fits in existing entry */ bfnew = bfp; } else { bfnew = fwd_alloc(newaddr, bfp->bf_nlinks + 1, RBRIDGE_NICKNAME_NONE); if (bfnew != NULL) { KIINCR(bki_count); avl_remove(&bip->bi_fwd, bfp); bfp->bf_flags &= ~BFF_INTREE; bfnew->bf_nlinks = bfp->bf_nlinks; bcopy(bfp->bf_links, bfnew->bf_links, bfp->bf_nlinks * sizeof (bfp)); /* reset the idx value due to removal above */ (void) avl_find(&bip->bi_fwd, &match, &idx); } } if (bfnew != NULL) { bfnew->bf_links[bfnew->bf_nlinks++] = blp; if (drop_ref) drop_ref = B_FALSE; else atomic_inc_uint(&blp->bl_refs); /* bf_links entry */ if (bfnew != bfp) { /* local addresses are not subject to table limits */ avl_insert(&bip->bi_fwd, bfnew, idx); bfnew->bf_flags |= (BFF_INTREE | BFF_LOCALADDR); atomic_inc_uint(&bfnew->bf_refs); /* avl entry */ } } rw_exit(&bip->bi_rwlock); no_new_addr: /* * If we found an existing entry and we replaced it with a new one, * then drop the table reference from the old one. We removed it from * the AVL tree above. */ if (bfnew != NULL && bfp != NULL && bfnew != bfp) fwd_unref(bfp); /* Account for removed entry. */ if (drop_ref) link_unref(blp); } static void bridge_new_unicst(bridge_link_t *blp) { uint8_t new_mac[ETHERADDRL]; mac_unicast_primary_get(blp->bl_mh, new_mac); fwd_update_local(blp, blp->bl_local_mac, new_mac); bcopy(new_mac, blp->bl_local_mac, ETHERADDRL); } /* * We must shut down a link prior to freeing it, and doing that requires * blocking to wait for running MAC threads while holding a reference. This is * run from a taskq to accomplish proper link shutdown followed by reference * drop. */ static void link_shutdown(void *arg) { bridge_link_t *blp = arg; mac_handle_t mh = blp->bl_mh; bridge_inst_t *bip; bridge_fwd_t *bfp, *bfnext; avl_tree_t fwd_scavenge; int i; /* * This link is being destroyed. Notify TRILL now that it's no longer * possible to send packets. Data packets may still arrive until TRILL * calls bridge_trill_lnunref. */ if (blp->bl_trilldata != NULL) trill_lndstr_fn(blp->bl_trilldata, blp); if (blp->bl_flags & BLF_PROM_ADDED) (void) mac_promisc_remove(blp->bl_mphp); if (blp->bl_flags & BLF_SET_BRIDGE) mac_bridge_clear(mh, (mac_handle_t)blp); if (blp->bl_flags & BLF_MARGIN_ADDED) { (void) mac_notify_remove(blp->bl_mnh, B_TRUE); (void) mac_margin_remove(mh, blp->bl_margin); } /* Tell the clients the real link state when we leave */ mac_link_redo(blp->bl_mh, mac_stat_get(blp->bl_mh, MAC_STAT_LOWLINK_STATE)); /* Destroy all of the forwarding entries related to this link */ avl_create(&fwd_scavenge, fwd_compare, sizeof (bridge_fwd_t), offsetof(bridge_fwd_t, bf_node)); bip = blp->bl_inst; rw_enter(&bip->bi_rwlock, RW_WRITER); bfnext = avl_first(&bip->bi_fwd); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&bip->bi_fwd, bfp); for (i = 0; i < bfp->bf_nlinks; i++) { if (bfp->bf_links[i] == blp) break; } if (i >= bfp->bf_nlinks) continue; if (bfp->bf_nlinks > 1) { /* note that this can't be the last reference */ link_unref(blp); bfp->bf_nlinks--; for (; i < bfp->bf_nlinks; i++) bfp->bf_links[i] = bfp->bf_links[i + 1]; } else { ASSERT(bfp->bf_flags & BFF_INTREE); avl_remove(&bip->bi_fwd, bfp); bfp->bf_flags &= ~BFF_INTREE; avl_add(&fwd_scavenge, bfp); } } rw_exit(&bip->bi_rwlock); bfnext = avl_first(&fwd_scavenge); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&fwd_scavenge, bfp); avl_remove(&fwd_scavenge, bfp); fwd_unref(bfp); } avl_destroy(&fwd_scavenge); if (blp->bl_flags & BLF_CLIENT_OPEN) mac_client_close(blp->bl_mch, 0); mac_close(mh); /* * We are now completely removed from the active list, so drop the * reference (see bridge_add_link). */ link_unref(blp); } static void shutdown_inst(bridge_inst_t *bip) { bridge_link_t *blp, *blnext; bridge_fwd_t *bfp; mutex_enter(&inst_lock); if (bip->bi_flags & BIF_SHUTDOWN) { mutex_exit(&inst_lock); return; } /* * Once on the inst_list, the bridge instance must not leave that list * without having the shutdown flag set first. When the shutdown flag * is set, we own the list reference, so we must drop it before * returning. */ bip->bi_flags |= BIF_SHUTDOWN; mutex_exit(&inst_lock); bip->bi_control = NULL; rw_enter(&bip->bi_rwlock, RW_READER); blnext = list_head(&bip->bi_links); while ((blp = blnext) != NULL) { blnext = list_next(&bip->bi_links, blp); if (!(blp->bl_flags & BLF_DELETED)) { blp->bl_flags |= BLF_DELETED; (void) ddi_taskq_dispatch(bridge_taskq, link_shutdown, blp, DDI_SLEEP); } } while ((bfp = avl_first(&bip->bi_fwd)) != NULL) { atomic_inc_uint(&bfp->bf_refs); rw_exit(&bip->bi_rwlock); fwd_delete(bfp); fwd_unref(bfp); rw_enter(&bip->bi_rwlock, RW_READER); } rw_exit(&bip->bi_rwlock); /* * This bridge is being destroyed. Notify TRILL once all of the * links are all gone. */ mutex_enter(&inst_lock); while (bip->bi_trilldata != NULL && !list_is_empty(&bip->bi_links)) cv_wait(&bip->bi_linkwait, &inst_lock); mutex_exit(&inst_lock); if (bip->bi_trilldata != NULL) trill_brdstr_fn(bip->bi_trilldata, bip); bridge_unref(bip); } /* * This is called once by the TRILL module when it starts up. It just sets the * global TRILL callback function pointers -- data transmit/receive and bridge * and link destroy notification. There's only one TRILL module, so only one * registration is needed. * * TRILL should call this function with NULL pointers before unloading. It * must not do so before dropping all references to bridges and links. We * assert that this is true on debug builds. */ void bridge_trill_register_cb(trill_recv_pkt_t recv_fn, trill_encap_pkt_t encap_fn, trill_br_dstr_t brdstr_fn, trill_ln_dstr_t lndstr_fn) { #ifdef DEBUG if (recv_fn == NULL && trill_recv_fn != NULL) { bridge_inst_t *bip; bridge_link_t *blp; mutex_enter(&inst_lock); for (bip = list_head(&inst_list); bip != NULL; bip = list_next(&inst_list, bip)) { ASSERT(bip->bi_trilldata == NULL); rw_enter(&bip->bi_rwlock, RW_READER); for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { ASSERT(blp->bl_trilldata == NULL); } rw_exit(&bip->bi_rwlock); } mutex_exit(&inst_lock); } #endif trill_recv_fn = recv_fn; trill_encap_fn = encap_fn; trill_brdstr_fn = brdstr_fn; trill_lndstr_fn = lndstr_fn; } /* * This registers the TRILL instance pointer with a bridge. Before this * pointer is set, the forwarding, TRILL receive, and bridge destructor * functions won't be called. * * TRILL holds a reference on a bridge with this call. It must free the * reference by calling the unregister function below. */ bridge_inst_t * bridge_trill_brref(const char *bname, void *ptr) { char bridge[MAXLINKNAMELEN]; bridge_inst_t *bip; (void) snprintf(bridge, MAXLINKNAMELEN, "%s0", bname); bip = bridge_find_name(bridge); if (bip != NULL) { ASSERT(bip->bi_trilldata == NULL && ptr != NULL); bip->bi_trilldata = ptr; } return (bip); } void bridge_trill_brunref(bridge_inst_t *bip) { ASSERT(bip->bi_trilldata != NULL); bip->bi_trilldata = NULL; bridge_unref(bip); } /* * TRILL calls this function when referencing a particular link on a bridge. * * It holds a reference on the link, so TRILL must clear out the reference when * it's done with the link (on unbinding). */ bridge_link_t * bridge_trill_lnref(bridge_inst_t *bip, datalink_id_t linkid, void *ptr) { bridge_link_t *blp; ASSERT(ptr != NULL); rw_enter(&bip->bi_rwlock, RW_READER); for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (!(blp->bl_flags & BLF_DELETED) && blp->bl_linkid == linkid && blp->bl_trilldata == NULL) { blp->bl_trilldata = ptr; blp->bl_flags &= ~BLF_TRILLACTIVE; (void) memset(blp->bl_afs, 0, sizeof (blp->bl_afs)); atomic_inc_uint(&blp->bl_refs); break; } } rw_exit(&bip->bi_rwlock); return (blp); } void bridge_trill_lnunref(bridge_link_t *blp) { mutex_enter(&blp->bl_trilllock); ASSERT(blp->bl_trilldata != NULL); blp->bl_trilldata = NULL; blp->bl_flags &= ~BLF_TRILLACTIVE; while (blp->bl_trillthreads > 0) cv_wait(&blp->bl_trillwait, &blp->bl_trilllock); mutex_exit(&blp->bl_trilllock); (void) memset(blp->bl_afs, 0xff, sizeof (blp->bl_afs)); link_unref(blp); } /* * This periodic timer performs three functions: * 1. It scans the list of learned forwarding entries, and removes ones that * haven't been heard from in a while. The time limit is backed down if * we're above the configured table limit. * 2. It walks the links and decays away the bl_learns counter. * 3. It scans the observability node entries looking for ones that can be * freed up. */ /* ARGSUSED */ static void bridge_timer(void *arg) { bridge_inst_t *bip; bridge_fwd_t *bfp, *bfnext; bridge_mac_t *bmp, *bmnext; bridge_link_t *blp; int err; datalink_id_t tmpid; avl_tree_t fwd_scavenge; clock_t age_limit; uint32_t ldecay; avl_create(&fwd_scavenge, fwd_compare, sizeof (bridge_fwd_t), offsetof(bridge_fwd_t, bf_node)); mutex_enter(&inst_lock); for (bip = list_head(&inst_list); bip != NULL; bip = list_next(&inst_list, bip)) { if (bip->bi_flags & BIF_SHUTDOWN) continue; rw_enter(&bip->bi_rwlock, RW_WRITER); /* compute scaled maximum age based on table limit */ if (avl_numnodes(&bip->bi_fwd) > bip->bi_tablemax) bip->bi_tshift++; else bip->bi_tshift = 0; if ((age_limit = bridge_fwd_age >> bip->bi_tshift) == 0) { if (bip->bi_tshift != 0) bip->bi_tshift--; age_limit = 1; } bfnext = avl_first(&bip->bi_fwd); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&bip->bi_fwd, bfp); if (!(bfp->bf_flags & BFF_LOCALADDR) && (lbolt - bfp->bf_lastheard) > age_limit) { ASSERT(bfp->bf_flags & BFF_INTREE); avl_remove(&bip->bi_fwd, bfp); bfp->bf_flags &= ~BFF_INTREE; avl_add(&fwd_scavenge, bfp); } } for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { ldecay = mac_get_ldecay(blp->bl_mh); if (ldecay >= blp->bl_learns) blp->bl_learns = 0; else atomic_add_int(&blp->bl_learns, -(int)ldecay); } rw_exit(&bip->bi_rwlock); bfnext = avl_first(&fwd_scavenge); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&fwd_scavenge, bfp); avl_remove(&fwd_scavenge, bfp); KIINCR(bki_expire); fwd_unref(bfp); /* drop tree reference */ } } mutex_exit(&inst_lock); avl_destroy(&fwd_scavenge); /* * Scan the bridge_mac_t entries and try to free up the ones that are * no longer active. This must be done by polling, as neither DLS nor * MAC provides a driver any sort of positive control over clients. */ rw_enter(&bmac_rwlock, RW_WRITER); bmnext = list_head(&bmac_list); while ((bmp = bmnext) != NULL) { bmnext = list_next(&bmac_list, bmp); /* ignore active bridges */ if (bmp->bm_inst != NULL) continue; if (bmp->bm_flags & BMF_DLS) { err = dls_devnet_destroy(bmp->bm_mh, &tmpid, B_FALSE); ASSERT(err == 0 || err == EBUSY); if (err == 0) bmp->bm_flags &= ~BMF_DLS; } if (!(bmp->bm_flags & BMF_DLS)) { err = mac_unregister(bmp->bm_mh); ASSERT(err == 0 || err == EBUSY); if (err == 0) { list_remove(&bmac_list, bmp); kmem_free(bmp, sizeof (*bmp)); } } } if (list_is_empty(&bmac_list)) { bridge_timerid = 0; } else { bridge_timerid = timeout(bridge_timer, NULL, bridge_scan_interval); } rw_exit(&bmac_rwlock); } static int bridge_open(queue_t *rq, dev_t *devp, int oflag, int sflag, cred_t *credp) { bridge_stream_t *bsp; if (rq->q_ptr != NULL) return (0); if (sflag & MODOPEN) return (EINVAL); /* * Check the minor node number being opened. This tells us which * bridge instance the user wants. */ if (getminor(*devp) != 0) { /* * This is a regular DLPI stream for snoop or the like. * Redirect it through DLD. */ rq->q_qinfo = &bridge_dld_rinit; OTHERQ(rq)->q_qinfo = &bridge_dld_winit; return (dld_open(rq, devp, oflag, sflag, credp)); } else { /* * Allocate the bridge control stream structure. */ if ((bsp = stream_alloc()) == NULL) return (ENOSR); rq->q_ptr = WR(rq)->q_ptr = (caddr_t)bsp; bsp->bs_wq = WR(rq); *devp = makedevice(getmajor(*devp), bsp->bs_minor); qprocson(rq); return (0); } } /* * This is used only for bridge control streams. DLPI goes through dld * instead. */ static int bridge_close(queue_t *rq) { bridge_stream_t *bsp = rq->q_ptr; bridge_inst_t *bip; /* * Wait for any stray taskq (add/delete link) entries related to this * stream to leave the system. */ mutex_enter(&stream_ref_lock); while (bsp->bs_taskq_cnt != 0) cv_wait(&stream_ref_cv, &stream_ref_lock); mutex_exit(&stream_ref_lock); qprocsoff(rq); if ((bip = bsp->bs_inst) != NULL) shutdown_inst(bip); rq->q_ptr = WR(rq)->q_ptr = NULL; stream_free(bsp); if (bip != NULL) bridge_unref(bip); return (0); } static void bridge_learn(bridge_link_t *blp, const uint8_t *saddr, uint16_t ingress_nick, uint16_t vlanid) { bridge_inst_t *bip = blp->bl_inst; bridge_fwd_t *bfp, *bfpnew; int i; boolean_t replaced = B_FALSE; /* Ignore multi-destination address used as source; it's nonsense. */ if (*saddr & 1) return; /* * If the source is known, then check whether it belongs on this link. * If not, and this isn't a fixed local address, then we've detected a * move. If it's not known, learn it. */ if ((bfp = fwd_find(bip, saddr, vlanid)) != NULL) { /* * If the packet has a fixed local source address, then there's * nothing we can learn. We must quit. If this was a received * packet, then the sender has stolen our address, but there's * nothing we can do. If it's a transmitted packet, then * that's the normal case. */ if (bfp->bf_flags & BFF_LOCALADDR) { fwd_unref(bfp); return; } /* * Check if the link (and TRILL sender, if any) being used is * among the ones registered for this address. If so, then * this is information that we already know. */ if (bfp->bf_trill_nick == ingress_nick) { for (i = 0; i < bfp->bf_nlinks; i++) { if (bfp->bf_links[i] == blp) { bfp->bf_lastheard = lbolt; fwd_unref(bfp); return; } } } } /* * Note that we intentionally "unlearn" things that appear to be under * attack on this link. The forwarding cache is a negative thing for * security -- it disables reachability as a performance optimization * -- so leaving out entries optimizes for success and defends against * the attack. Thus, the bare increment without a check in the delete * code above is right. (And it's ok if we skid over the limit a * little, so there's no syncronization needed on the test.) */ if (blp->bl_learns >= mac_get_llimit(blp->bl_mh)) { if (bfp != NULL) { if (bfp->bf_vcnt == 0) fwd_delete(bfp); fwd_unref(bfp); } return; } atomic_inc_uint(&blp->bl_learns); if ((bfpnew = fwd_alloc(saddr, 1, ingress_nick)) == NULL) { if (bfp != NULL) fwd_unref(bfp); return; } KIINCR(bki_count); if (bfp != NULL) { /* * If this is a new destination for the same VLAN, then delete * so that we can update. If it's a different VLAN, then we're * not going to delete the original. Split off instead into an * IVL entry. */ if (bfp->bf_vlanid == vlanid) { /* save the count of IVL duplicates */ bfpnew->bf_vcnt = bfp->bf_vcnt; /* entry deletes count as learning events */ atomic_inc_uint(&blp->bl_learns); /* destroy and create anew; node moved */ fwd_delete(bfp); replaced = B_TRUE; KIINCR(bki_moved); } else { bfp->bf_vcnt++; bfpnew->bf_flags |= BFF_VLANLOCAL; } fwd_unref(bfp); } bfpnew->bf_links[0] = blp; bfpnew->bf_nlinks = 1; atomic_inc_uint(&blp->bl_refs); /* bf_links entry */ if (!fwd_insert(bip, bfpnew)) fwd_free(bfpnew); else if (!replaced) KIINCR(bki_source); } /* * Process the VLAN headers for output on a given link. There are several * cases (noting that we don't map VLANs): * 1. The input packet is good as it is; either * a. It has no tag, and output has same PVID * b. It has a non-zero priority-only tag for PVID, and b_band is same * c. It has a tag with VLAN different from PVID, and b_band is same * 2. The tag must change: non-zero b_band is different from tag priority * 3. The packet has a tag and should not (VLAN same as PVID, b_band zero) * 4. The packet has no tag and needs one: * a. VLAN ID same as PVID, but b_band is non-zero * b. VLAN ID different from PVID * We exclude case 1 first, then modify the packet. Note that output packets * get a priority set by the mblk, not by the header, because QoS in bridging * requires priority recalculation at each node. * * The passed-in tci is the "impossible" value 0xFFFF when no tag is present. */ static mblk_t * reform_vlan_header(mblk_t *mp, uint16_t vlanid, uint16_t tci, uint16_t pvid) { boolean_t source_has_tag = (tci != 0xFFFF); mblk_t *mpcopy; size_t mlen, minlen; struct ether_vlan_header *evh; int pri; /* This helps centralize error handling in the caller. */ if (mp == NULL) return (mp); /* No forwarded packet can have hardware checksum enabled */ DB_CKSUMFLAGS(mp) = 0; /* Get the no-modification cases out of the way first */ if (!source_has_tag && vlanid == pvid) /* 1a */ return (mp); pri = VLAN_PRI(tci); if (source_has_tag && mp->b_band == pri) { if (vlanid != pvid) /* 1c */ return (mp); if (pri != 0 && VLAN_ID(tci) == 0) /* 1b */ return (mp); } /* * We now know that we must modify the packet. Prepare for that. Note * that if a tag is present, the caller has already done a pullup for * the VLAN header, so we're good to go. */ if (MBLKL(mp) < sizeof (struct ether_header)) { mpcopy = msgpullup(mp, sizeof (struct ether_header)); if (mpcopy == NULL) { freemsg(mp); return (NULL); } mp = mpcopy; } if (DB_REF(mp) > 1 || !IS_P2ALIGNED(mp->b_rptr, sizeof (uint16_t)) || (!source_has_tag && MBLKTAIL(mp) < VLAN_INCR)) { minlen = mlen = MBLKL(mp); if (!source_has_tag) minlen += VLAN_INCR; ASSERT(minlen >= sizeof (struct ether_vlan_header)); /* * We're willing to copy some data to avoid fragmentation, but * not a lot. */ if (minlen > 256) minlen = sizeof (struct ether_vlan_header); mpcopy = allocb(minlen, BPRI_MED); if (mpcopy == NULL) { freemsg(mp); return (NULL); } if (mlen <= minlen) { /* We toss the first mblk when we can. */ bcopy(mp->b_rptr, mpcopy->b_rptr, mlen); mpcopy->b_wptr += mlen; mpcopy->b_cont = mp->b_cont; freeb(mp); } else { /* If not, then just copy what we need */ if (!source_has_tag) minlen = sizeof (struct ether_header); bcopy(mp->b_rptr, mpcopy->b_rptr, minlen); mpcopy->b_wptr += minlen; mpcopy->b_cont = mp; mp->b_rptr += minlen; } mp = mpcopy; } /* LINTED: pointer alignment */ evh = (struct ether_vlan_header *)mp->b_rptr; if (source_has_tag) { if (mp->b_band == 0 && vlanid == pvid) { /* 3 */ evh->ether_tpid = evh->ether_type; mlen = MBLKL(mp); if (mlen > sizeof (struct ether_vlan_header)) ovbcopy(mp->b_rptr + sizeof (struct ether_vlan_header), mp->b_rptr + sizeof (struct ether_header), mlen - sizeof (struct ether_vlan_header)); mp->b_wptr -= VLAN_INCR; } else { /* 2 */ if (vlanid == pvid) vlanid = VLAN_ID_NONE; tci = VLAN_TCI(mp->b_band, ETHER_CFI, vlanid); evh->ether_tci = htons(tci); } } else { /* case 4: no header present, but one is needed */ mlen = MBLKL(mp); if (mlen > sizeof (struct ether_header)) ovbcopy(mp->b_rptr + sizeof (struct ether_header), mp->b_rptr + sizeof (struct ether_vlan_header), mlen - sizeof (struct ether_header)); mp->b_wptr += VLAN_INCR; ASSERT(mp->b_wptr <= DB_LIM(mp)); if (vlanid == pvid) vlanid = VLAN_ID_NONE; tci = VLAN_TCI(mp->b_band, ETHER_CFI, vlanid); evh->ether_type = evh->ether_tpid; evh->ether_tpid = htons(ETHERTYPE_VLAN); evh->ether_tci = htons(tci); } return (mp); } /* Record VLAN information and strip header if requested . */ static void update_header(mblk_t *mp, mac_header_info_t *hdr_info, boolean_t striphdr) { if (hdr_info->mhi_bindsap == ETHERTYPE_VLAN) { struct ether_vlan_header *evhp; uint16_t ether_type; /* LINTED: alignment */ evhp = (struct ether_vlan_header *)mp->b_rptr; hdr_info->mhi_istagged = B_TRUE; hdr_info->mhi_tci = ntohs(evhp->ether_tci); if (striphdr) { /* * For VLAN tagged frames update the ether_type * in hdr_info before stripping the header. */ ether_type = ntohs(evhp->ether_type); hdr_info->mhi_origsap = ether_type; hdr_info->mhi_bindsap = (ether_type > ETHERMTU) ? ether_type : DLS_SAP_LLC; mp->b_rptr = (uchar_t *)(evhp + 1); } } else { hdr_info->mhi_istagged = B_FALSE; hdr_info->mhi_tci = VLAN_ID_NONE; if (striphdr) mp->b_rptr += sizeof (struct ether_header); } } /* * Return B_TRUE if we're allowed to send on this link with the given VLAN ID. */ static boolean_t bridge_can_send(bridge_link_t *blp, uint16_t vlanid) { ASSERT(vlanid != VLAN_ID_NONE); if (blp->bl_flags & BLF_DELETED) return (B_FALSE); if (blp->bl_trilldata == NULL && blp->bl_state != BLS_FORWARDING) return (B_FALSE); return (BRIDGE_VLAN_ISSET(blp, vlanid) && BRIDGE_AF_ISSET(blp, vlanid)); } /* * This function scans the bridge forwarding tables in order to forward a given * packet. If the packet either doesn't need forwarding (the current link is * correct) or the current link needs a copy as well, then the packet is * returned to the caller. * * If a packet has been decapsulated from TRILL, then it must *NOT* reenter a * TRILL tunnel. If the destination points there, then drop instead. */ static mblk_t * bridge_forward(bridge_link_t *blp, mac_header_info_t *hdr_info, mblk_t *mp, uint16_t vlanid, uint16_t tci, boolean_t from_trill, boolean_t is_xmit) { mblk_t *mpsend, *mpcopy; bridge_inst_t *bip = blp->bl_inst; bridge_link_t *blpsend, *blpnext; bridge_fwd_t *bfp; uint_t i; boolean_t selfseen = B_FALSE; void *tdp; const uint8_t *daddr = hdr_info->mhi_daddr; /* * Check for the IEEE "reserved" multicast addresses. Messages sent to * these addresses are used for link-local control (STP and pause), and * are never forwarded or redirected. */ if (daddr[0] == 1 && daddr[1] == 0x80 && daddr[2] == 0xc2 && daddr[3] == 0 && daddr[4] == 0 && (daddr[5] & 0xf0) == 0) { if (from_trill) { freemsg(mp); mp = NULL; } return (mp); } if ((bfp = fwd_find(bip, daddr, vlanid)) != NULL) { /* * If trill indicates a destination for this node, then it's * clearly not intended for local delivery. We must tell TRILL * to encapsulate, as long as we didn't just decapsulate it. */ if (bfp->bf_trill_nick != RBRIDGE_NICKNAME_NONE) { /* * Error case: can't reencapsulate if the protocols are * working correctly. */ if (from_trill) { freemsg(mp); return (NULL); } mutex_enter(&blp->bl_trilllock); if ((tdp = blp->bl_trilldata) != NULL) { blp->bl_trillthreads++; mutex_exit(&blp->bl_trilllock); update_header(mp, hdr_info, B_FALSE); if (is_xmit) mp = mac_fix_cksum(mp); /* all trill data frames have Inner.VLAN */ mp = reform_vlan_header(mp, vlanid, tci, 0); if (mp == NULL) { KIINCR(bki_drops); fwd_unref(bfp); return (NULL); } trill_encap_fn(tdp, blp, hdr_info, mp, bfp->bf_trill_nick); mutex_enter(&blp->bl_trilllock); if (--blp->bl_trillthreads == 0 && blp->bl_trilldata == NULL) cv_broadcast(&blp->bl_trillwait); } mutex_exit(&blp->bl_trilllock); /* if TRILL has been disabled, then kill this stray */ if (tdp == NULL) { freemsg(mp); fwd_delete(bfp); } fwd_unref(bfp); return (NULL); } /* find first link we can send on */ for (i = 0; i < bfp->bf_nlinks; i++) { blpsend = bfp->bf_links[i]; if (blpsend == blp) selfseen = B_TRUE; else if (bridge_can_send(blpsend, vlanid)) break; } while (i < bfp->bf_nlinks) { blpsend = bfp->bf_links[i]; for (i++; i < bfp->bf_nlinks; i++) { blpnext = bfp->bf_links[i]; if (blpnext == blp) selfseen = B_TRUE; else if (bridge_can_send(blpnext, vlanid)) break; } if (i == bfp->bf_nlinks && !selfseen) { mpsend = mp; mp = NULL; } else { mpsend = copymsg(mp); } if (!from_trill && is_xmit) mpsend = mac_fix_cksum(mpsend); mpsend = reform_vlan_header(mpsend, vlanid, tci, blpsend->bl_pvid); if (mpsend == NULL) { KIINCR(bki_drops); continue; } KIINCR(bki_forwards); /* * No need to bump up the link reference count, as * the forwarding entry itself holds a reference to * the link. */ if (bfp->bf_flags & BFF_LOCALADDR) { mac_rx_common(blpsend->bl_mh, NULL, mpsend); } else { KLPINCR(blpsend, bkl_xmit); MAC_RING_TX(blpsend->bl_mh, NULL, mpsend, mpsend); freemsg(mpsend); } } /* * Handle a special case: if we're transmitting to the original * link, then check whether the localaddr flag is set. If it * is, then receive instead. This doesn't happen with ordinary * bridging, but does happen often with TRILL decapsulation. */ if (mp != NULL && is_xmit && (bfp->bf_flags & BFF_LOCALADDR)) { mac_rx_common(blp->bl_mh, NULL, mp); mp = NULL; } fwd_unref(bfp); } else { /* * TRILL has two cases to handle. If the packet is off the * wire (not from TRILL), then we need to send up into the * TRILL module to have the distribution tree computed. If the * packet is from TRILL (decapsulated), then we're part of the * distribution tree, and we need to copy the packet on member * interfaces. * * Thus, the from TRILL case is identical to the STP case. */ if (!from_trill && blp->bl_trilldata != NULL) { mutex_enter(&blp->bl_trilllock); if ((tdp = blp->bl_trilldata) != NULL) { blp->bl_trillthreads++; mutex_exit(&blp->bl_trilllock); if ((mpsend = copymsg(mp)) != NULL) { update_header(mpsend, hdr_info, B_FALSE); /* * all trill data frames have * Inner.VLAN */ mpsend = reform_vlan_header(mpsend, vlanid, tci, 0); if (mpsend == NULL) { KIINCR(bki_drops); } else { trill_encap_fn(tdp, blp, hdr_info, mpsend, RBRIDGE_NICKNAME_NONE); } } mutex_enter(&blp->bl_trilllock); if (--blp->bl_trillthreads == 0 && blp->bl_trilldata == NULL) cv_broadcast(&blp->bl_trillwait); } mutex_exit(&blp->bl_trilllock); } /* * This is an unknown destination, so flood. */ rw_enter(&bip->bi_rwlock, RW_READER); for (blpnext = list_head(&bip->bi_links); blpnext != NULL; blpnext = list_next(&bip->bi_links, blpnext)) { if (blpnext == blp) selfseen = B_TRUE; else if (bridge_can_send(blpnext, vlanid)) break; } if (blpnext != NULL) atomic_inc_uint(&blpnext->bl_refs); rw_exit(&bip->bi_rwlock); while ((blpsend = blpnext) != NULL) { rw_enter(&bip->bi_rwlock, RW_READER); for (blpnext = list_next(&bip->bi_links, blpsend); blpnext != NULL; blpnext = list_next(&bip->bi_links, blpnext)) { if (blpnext == blp) selfseen = B_TRUE; else if (bridge_can_send(blpnext, vlanid)) break; } if (blpnext != NULL) atomic_inc_uint(&blpnext->bl_refs); rw_exit(&bip->bi_rwlock); if (blpnext == NULL && !selfseen) { mpsend = mp; mp = NULL; } else { mpsend = copymsg(mp); } if (!from_trill && is_xmit) mpsend = mac_fix_cksum(mpsend); mpsend = reform_vlan_header(mpsend, vlanid, tci, blpsend->bl_pvid); if (mpsend == NULL) { KIINCR(bki_drops); continue; } if (hdr_info->mhi_dsttype == MAC_ADDRTYPE_UNICAST) KIINCR(bki_unknown); else KIINCR(bki_mbcast); KLPINCR(blpsend, bkl_xmit); if ((mpcopy = copymsg(mpsend)) != NULL) mac_rx_common(blpsend->bl_mh, NULL, mpcopy); MAC_RING_TX(blpsend->bl_mh, NULL, mpsend, mpsend); freemsg(mpsend); link_unref(blpsend); } } /* * At this point, if np is non-NULL, it means that the caller needs to * continue on the selected link. */ return (mp); } /* * Extract and validate the VLAN information for a given packet. This checks * conformance with the rules for use of the PVID on the link, and for the * allowed (configured) VLAN set. * * Returns B_TRUE if the packet passes, B_FALSE if it fails. */ static boolean_t bridge_get_vlan(bridge_link_t *blp, mac_header_info_t *hdr_info, mblk_t *mp, uint16_t *vlanidp, uint16_t *tcip) { uint16_t tci, vlanid; if (hdr_info->mhi_bindsap == ETHERTYPE_VLAN) { ptrdiff_t tpos = offsetof(struct ether_vlan_header, ether_tci); ptrdiff_t mlen; /* * Extract the VLAN ID information, regardless of alignment, * and without a pullup. This isn't attractive, but we do this * to avoid having to deal with the pointers stashed in * hdr_info moving around or having the caller deal with a new * mblk_t pointer. */ while (mp != NULL) { mlen = MBLKL(mp); if (mlen > tpos && mlen > 0) break; tpos -= mlen; mp = mp->b_cont; } if (mp == NULL) return (B_FALSE); tci = mp->b_rptr[tpos] << 8; if (++tpos >= mlen) { do { mp = mp->b_cont; } while (mp != NULL && MBLKL(mp) == 0); if (mp == NULL) return (B_FALSE); tpos = 0; } tci |= mp->b_rptr[tpos]; vlanid = VLAN_ID(tci); if (VLAN_CFI(tci) != ETHER_CFI || vlanid > VLAN_ID_MAX) return (B_FALSE); if (vlanid == VLAN_ID_NONE || vlanid == blp->bl_pvid) goto input_no_vlan; if (!BRIDGE_VLAN_ISSET(blp, vlanid)) return (B_FALSE); } else { tci = 0xFFFF; input_no_vlan: /* * If PVID is set to zero, then untagged traffic is not * supported here. Do not learn or forward. */ if ((vlanid = blp->bl_pvid) == VLAN_ID_NONE) return (B_FALSE); } *tcip = tci; *vlanidp = vlanid; return (B_TRUE); } /* * Handle MAC notifications. */ static void bridge_notify_cb(void *arg, mac_notify_type_t note_type) { bridge_link_t *blp = arg; switch (note_type) { case MAC_NOTE_UNICST: bridge_new_unicst(blp); break; case MAC_NOTE_SDU_SIZE: { uint_t maxsdu; bridge_inst_t *bip = blp->bl_inst; bridge_mac_t *bmp = bip->bi_mac; boolean_t notify = B_FALSE; mblk_t *mlist = NULL; mac_sdu_get(blp->bl_mh, NULL, &maxsdu); rw_enter(&bip->bi_rwlock, RW_READER); if (list_prev(&bip->bi_links, blp) == NULL && list_next(&bip->bi_links, blp) == NULL) { notify = (maxsdu != bmp->bm_maxsdu); bmp->bm_maxsdu = maxsdu; } blp->bl_maxsdu = maxsdu; if (maxsdu != bmp->bm_maxsdu) link_sdu_fail(blp, B_TRUE, &mlist); else if (notify) (void) mac_maxsdu_update(bmp->bm_mh, maxsdu); rw_exit(&bip->bi_rwlock); send_up_messages(bip, mlist); break; } } } /* * This is called by the MAC layer. As with the transmit side, we're right in * the data path for all I/O on this port, so if we don't need to forward this * packet anywhere, we have to send it upwards via mac_rx_common. */ static void bridge_recv_cb(mac_handle_t mh, mac_resource_handle_t rsrc, mblk_t *mpnext) { mblk_t *mp, *mpcopy; bridge_link_t *blp = (bridge_link_t *)mh; bridge_inst_t *bip = blp->bl_inst; bridge_mac_t *bmp = bip->bi_mac; mac_header_info_t hdr_info; uint16_t vlanid, tci; boolean_t trillmode = B_FALSE; KIINCR(bki_recv); KLINCR(bkl_recv); /* * Regardless of state, check for inbound TRILL packets when TRILL is * active. These are pulled out of band and sent for TRILL handling. */ if (blp->bl_trilldata != NULL) { void *tdp; mblk_t *newhead; mblk_t *tail = NULL; mutex_enter(&blp->bl_trilllock); if ((tdp = blp->bl_trilldata) != NULL) { blp->bl_trillthreads++; mutex_exit(&blp->bl_trilllock); trillmode = B_TRUE; newhead = mpnext; while ((mp = mpnext) != NULL) { boolean_t raw_isis, bridge_group; mpnext = mp->b_next; /* * If the header isn't readable, then leave on * the list and continue. */ if (mac_header_info(blp->bl_mh, mp, &hdr_info) != 0) { tail = mp; continue; } /* * The TRILL document specifies that, on * Ethernet alone, IS-IS packets arrive with * LLC rather than Ethertype, and using a * specific destination address. We must check * for that here. Also, we need to give BPDUs * to TRILL for processing. */ raw_isis = bridge_group = B_FALSE; if (hdr_info.mhi_dsttype == MAC_ADDRTYPE_MULTICAST) { if (memcmp(hdr_info.mhi_daddr, all_isis_rbridges, ETHERADDRL) == 0) raw_isis = B_TRUE; else if (memcmp(hdr_info.mhi_daddr, bridge_group_address, ETHERADDRL) == 0) bridge_group = B_TRUE; } if (!raw_isis && !bridge_group && hdr_info.mhi_bindsap != ETHERTYPE_TRILL && (hdr_info.mhi_bindsap != ETHERTYPE_VLAN || /* LINTED: alignment */ ((struct ether_vlan_header *)mp->b_rptr)-> ether_type != htons(ETHERTYPE_TRILL))) { tail = mp; continue; } /* * We've got TRILL input. Remove from the list * and send up through the TRILL module. (Send * a copy through promiscuous receive just to * support snooping on TRILL. Order isn't * preserved strictly, but that doesn't matter * here.) */ if (tail != NULL) tail->b_next = mpnext; mp->b_next = NULL; if (mp == newhead) newhead = mpnext; mac_trill_snoop(blp->bl_mh, mp); update_header(mp, &hdr_info, B_TRUE); /* * On raw IS-IS and BPDU frames, we have to * make sure that the length is trimmed * properly. We use origsap in order to cope * with jumbograms for IS-IS. (Regular mac * can't.) */ if (raw_isis || bridge_group) { size_t msglen = msgdsize(mp); if (msglen > hdr_info.mhi_origsap) { (void) adjmsg(mp, hdr_info.mhi_origsap - msglen); } else if (msglen < hdr_info.mhi_origsap) { freemsg(mp); continue; } } trill_recv_fn(tdp, blp, rsrc, mp, &hdr_info); } mpnext = newhead; mutex_enter(&blp->bl_trilllock); if (--blp->bl_trillthreads == 0 && blp->bl_trilldata == NULL) cv_broadcast(&blp->bl_trillwait); } mutex_exit(&blp->bl_trilllock); if (mpnext == NULL) return; } /* * If this is a TRILL RBridge, then just check whether this link is * used at all for forwarding. If not, then we're done. */ if (trillmode) { if (!(blp->bl_flags & BLF_TRILLACTIVE) || (blp->bl_flags & BLF_SDUFAIL)) { mac_rx_common(blp->bl_mh, rsrc, mpnext); return; } } else { /* * For regular (STP) bridges, if we're in blocking or listening * state, then do nothing. We don't learn or forward until * told to do so. */ if (blp->bl_state == BLS_BLOCKLISTEN) { mac_rx_common(blp->bl_mh, rsrc, mpnext); return; } } /* * Send a copy of the message chain up to the observability node users. * For TRILL, we must obey the VLAN AF rules, so we go packet-by- * packet. */ if (!trillmode && blp->bl_state == BLS_FORWARDING && (bmp->bm_flags & BMF_STARTED) && (mp = copymsgchain(mpnext)) != NULL) { mac_rx(bmp->bm_mh, NULL, mp); } /* * We must be in learning or forwarding state, or using TRILL on a link * with one or more VLANs active. For each packet in the list, process * the source address, and then attempt to forward. */ while ((mp = mpnext) != NULL) { mpnext = mp->b_next; mp->b_next = NULL; /* * If we can't decode the header or if the header specifies a * multicast source address (impossible!), then don't bother * learning or forwarding, but go ahead and forward up the * stack for subsequent processing. */ if (mac_header_info(blp->bl_mh, mp, &hdr_info) != 0 || (hdr_info.mhi_saddr[0] & 1) != 0) { KIINCR(bki_drops); KLINCR(bkl_drops); mac_rx_common(blp->bl_mh, rsrc, mp); continue; } /* * Extract and validate the VLAN ID for this packet. */ if (!bridge_get_vlan(blp, &hdr_info, mp, &vlanid, &tci) || !BRIDGE_AF_ISSET(blp, vlanid)) { mac_rx_common(blp->bl_mh, rsrc, mp); continue; } if (trillmode) { /* * Special test required by TRILL document: must * discard frames with outer address set to ESADI. */ if (memcmp(hdr_info.mhi_daddr, all_esadi_rbridges, ETHERADDRL) == 0) { mac_rx_common(blp->bl_mh, rsrc, mp); continue; } /* * If we're in TRILL mode, then the call above to get * the VLAN ID has also checked that we're the * appointed forwarder, so report that we're handling * this packet to any observability node users. */ if ((bmp->bm_flags & BMF_STARTED) && (mpcopy = copymsg(mp)) != NULL) mac_rx(bmp->bm_mh, NULL, mpcopy); } /* * First process the source address and learn from it. For * TRILL, we learn only if we're the appointed forwarder. */ bridge_learn(blp, hdr_info.mhi_saddr, RBRIDGE_NICKNAME_NONE, vlanid); /* * Now check whether we're forwarding and look up the * destination. If we can forward, do so. */ if (trillmode || blp->bl_state == BLS_FORWARDING) { mp = bridge_forward(blp, &hdr_info, mp, vlanid, tci, B_FALSE, B_FALSE); } if (mp != NULL) mac_rx_common(blp->bl_mh, rsrc, mp); } } /* ARGSUSED */ static mblk_t * bridge_xmit_cb(mac_handle_t mh, mac_ring_handle_t rh, mblk_t *mpnext) { bridge_link_t *blp = (bridge_link_t *)mh; bridge_inst_t *bip = blp->bl_inst; bridge_mac_t *bmp = bip->bi_mac; mac_header_info_t hdr_info; uint16_t vlanid, tci; mblk_t *mp, *mpcopy; boolean_t trillmode; trillmode = blp->bl_trilldata != NULL; /* * If we're using STP and we're in blocking or listening state, or if * we're using TRILL and no VLANs are active, then behave as though the * bridge isn't here at all, and send on the local link alone. */ if ((!trillmode && blp->bl_state == BLS_BLOCKLISTEN) || (trillmode && (!(blp->bl_flags & BLF_TRILLACTIVE) || (blp->bl_flags & BLF_SDUFAIL)))) { KIINCR(bki_sent); KLINCR(bkl_xmit); MAC_RING_TX(blp->bl_mh, rh, mpnext, mp); return (mp); } /* * Send a copy of the message up to the observability node users. * TRILL needs to check on a packet-by-packet basis. */ if (!trillmode && blp->bl_state == BLS_FORWARDING && (bmp->bm_flags & BMF_STARTED) && (mp = copymsgchain(mpnext)) != NULL) { mac_rx(bmp->bm_mh, NULL, mp); } while ((mp = mpnext) != NULL) { mpnext = mp->b_next; mp->b_next = NULL; if (mac_header_info(blp->bl_mh, mp, &hdr_info) != 0) { freemsg(mp); continue; } /* * Extract and validate the VLAN ID for this packet. */ if (!bridge_get_vlan(blp, &hdr_info, mp, &vlanid, &tci) || !BRIDGE_AF_ISSET(blp, vlanid)) { freemsg(mp); continue; } /* * If we're using TRILL, then we've now validated that we're * the forwarder for this VLAN, so go ahead and let * observability node users know about the packet. */ if (trillmode && (bmp->bm_flags & BMF_STARTED) && (mpcopy = copymsg(mp)) != NULL) { mac_rx(bmp->bm_mh, NULL, mpcopy); } /* * We have to learn from our own transmitted packets, because * there may be a Solaris DLPI raw sender (who can specify his * own source address) using promiscuous mode for receive. The * mac layer information won't (and can't) tell us everything * we need to know. */ bridge_learn(blp, hdr_info.mhi_saddr, RBRIDGE_NICKNAME_NONE, vlanid); /* attempt forwarding */ if (trillmode || blp->bl_state == BLS_FORWARDING) { mp = bridge_forward(blp, &hdr_info, mp, vlanid, tci, B_FALSE, B_TRUE); } if (mp != NULL) { MAC_RING_TX(blp->bl_mh, rh, mp, mp); if (mp == NULL) { KIINCR(bki_sent); KLINCR(bkl_xmit); } } /* * If we get stuck, then stop. Don't let the user's output * packets get out of order. (More importantly: don't try to * bridge the same packet multiple times if flow control is * asserted.) */ if (mp != NULL) { mp->b_next = mpnext; break; } } return (mp); } /* * This is called by TRILL when it decapsulates an packet, and we must forward * locally. On failure, we just drop. * * Note that the ingress_nick reported by TRILL must not represent this local * node. */ void bridge_trill_decaps(bridge_link_t *blp, mblk_t *mp, uint16_t ingress_nick) { mac_header_info_t hdr_info; uint16_t vlanid, tci; bridge_inst_t *bip = blp->bl_inst; /* used by macros */ mblk_t *mpcopy; if (mac_header_info(blp->bl_mh, mp, &hdr_info) != 0) { freemsg(mp); return; } /* Extract VLAN ID for this packet. */ if (hdr_info.mhi_bindsap == ETHERTYPE_VLAN) { struct ether_vlan_header *evhp; /* LINTED: alignment */ evhp = (struct ether_vlan_header *)mp->b_rptr; tci = ntohs(evhp->ether_tci); vlanid = VLAN_ID(tci); } else { /* Inner VLAN headers are required in TRILL data packets */ DTRACE_PROBE3(bridge__trill__decaps__novlan, bridge_link_t *, blp, mblk_t *, mp, uint16_t, ingress_nick); freemsg(mp); return; } /* Learn the location of this sender in the RBridge network */ bridge_learn(blp, hdr_info.mhi_saddr, ingress_nick, vlanid); /* attempt forwarding */ mp = bridge_forward(blp, &hdr_info, mp, vlanid, tci, B_TRUE, B_TRUE); if (mp != NULL) { if (bridge_can_send(blp, vlanid)) { /* Deliver a copy locally as well */ if ((mpcopy = copymsg(mp)) != NULL) mac_rx_common(blp->bl_mh, NULL, mpcopy); MAC_RING_TX(blp->bl_mh, NULL, mp, mp); } if (mp == NULL) { KIINCR(bki_sent); KLINCR(bkl_xmit); } else { freemsg(mp); } } } /* * This function is used by TRILL _only_ to transmit TRILL-encapsulated * packets. It sends on a single underlying link and does not bridge. */ mblk_t * bridge_trill_output(bridge_link_t *blp, mblk_t *mp) { bridge_inst_t *bip = blp->bl_inst; /* used by macros */ mac_trill_snoop(blp->bl_mh, mp); MAC_RING_TX(blp->bl_mh, NULL, mp, mp); if (mp == NULL) { KIINCR(bki_sent); KLINCR(bkl_xmit); } return (mp); } /* * Set the "appointed forwarder" flag array for this link. TRILL controls * forwarding on a VLAN basis. The "trillactive" flag is an optimization for * the forwarder. */ void bridge_trill_setvlans(bridge_link_t *blp, const uint8_t *arr) { int i; uint_t newflags = 0; for (i = 0; i < BRIDGE_VLAN_ARR_SIZE; i++) { if ((blp->bl_afs[i] = arr[i]) != 0) newflags = BLF_TRILLACTIVE; } blp->bl_flags = (blp->bl_flags & ~BLF_TRILLACTIVE) | newflags; } void bridge_trill_flush(bridge_link_t *blp, uint16_t vlan, boolean_t dotrill) { bridge_inst_t *bip = blp->bl_inst; bridge_fwd_t *bfp, *bfnext; avl_tree_t fwd_scavenge; int i; _NOTE(ARGUNUSED(vlan)); avl_create(&fwd_scavenge, fwd_compare, sizeof (bridge_fwd_t), offsetof(bridge_fwd_t, bf_node)); rw_enter(&bip->bi_rwlock, RW_WRITER); bfnext = avl_first(&bip->bi_fwd); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&bip->bi_fwd, bfp); if (bfp->bf_flags & BFF_LOCALADDR) continue; if (dotrill) { /* port doesn't matter if we're flushing TRILL */ if (bfp->bf_trill_nick == RBRIDGE_NICKNAME_NONE) continue; } else { if (bfp->bf_trill_nick != RBRIDGE_NICKNAME_NONE) continue; for (i = 0; i < bfp->bf_nlinks; i++) { if (bfp->bf_links[i] == blp) break; } if (i >= bfp->bf_nlinks) continue; } ASSERT(bfp->bf_flags & BFF_INTREE); avl_remove(&bip->bi_fwd, bfp); bfp->bf_flags &= ~BFF_INTREE; avl_add(&fwd_scavenge, bfp); } rw_exit(&bip->bi_rwlock); bfnext = avl_first(&fwd_scavenge); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&fwd_scavenge, bfp); avl_remove(&fwd_scavenge, bfp); fwd_unref(bfp); } avl_destroy(&fwd_scavenge); } /* * Let the mac module take or drop a reference to a bridge link. When this is * called, the mac module is holding the mi_bridge_lock, so the link cannot be * in the process of entering or leaving a bridge. */ static void bridge_ref_cb(mac_handle_t mh, boolean_t hold) { bridge_link_t *blp = (bridge_link_t *)mh; if (hold) atomic_inc_uint(&blp->bl_refs); else link_unref(blp); } /* * Handle link state changes reported by the mac layer. This acts as a filter * for link state changes: if a link is reporting down, but there are other * links still up on the bridge, then the state is changed to "up." When the * last link goes down, all are marked down, and when the first link goes up, * all are marked up. (Recursion is avoided by the use of the "redo" function.) * * We treat unknown as equivalent to "up." */ static link_state_t bridge_ls_cb(mac_handle_t mh, link_state_t newls) { bridge_link_t *blp = (bridge_link_t *)mh; bridge_link_t *blcmp; bridge_inst_t *bip; bridge_mac_t *bmp; if (newls != LINK_STATE_DOWN && blp->bl_linkstate != LINK_STATE_DOWN || (blp->bl_flags & (BLF_DELETED|BLF_SDUFAIL))) { blp->bl_linkstate = newls; return (newls); } /* * Scan first to see if there are any other non-down links. If there * are, then we're done. Otherwise, if all others are down, then the * state of this link is the state of the bridge. */ bip = blp->bl_inst; rw_enter(&bip->bi_rwlock, RW_WRITER); for (blcmp = list_head(&bip->bi_links); blcmp != NULL; blcmp = list_next(&bip->bi_links, blcmp)) { if (blcmp != blp && !(blcmp->bl_flags & (BLF_DELETED|BLF_SDUFAIL)) && blcmp->bl_linkstate != LINK_STATE_DOWN) break; } if (blcmp != NULL) { /* * If there are other links that are considered up, then tell * the caller that the link is actually still up, regardless of * this link's underlying state. */ blp->bl_linkstate = newls; newls = LINK_STATE_UP; } else if (blp->bl_linkstate != newls) { /* * If we've found no other 'up' links, and this link has * changed state, then report the new state of the bridge to * all other clients. */ blp->bl_linkstate = newls; for (blcmp = list_head(&bip->bi_links); blcmp != NULL; blcmp = list_next(&bip->bi_links, blcmp)) { if (blcmp != blp && !(blcmp->bl_flags & BLF_DELETED)) mac_link_redo(blcmp->bl_mh, newls); } bmp = bip->bi_mac; if ((bmp->bm_linkstate = newls) != LINK_STATE_DOWN) bmp->bm_linkstate = LINK_STATE_UP; mac_link_redo(bmp->bm_mh, bmp->bm_linkstate); } rw_exit(&bip->bi_rwlock); return (newls); } static void bridge_add_link(void *arg) { mblk_t *mp = arg; bridge_stream_t *bsp; bridge_inst_t *bip, *bipt; bridge_mac_t *bmp; datalink_id_t linkid; int err; mac_handle_t mh; uint_t maxsdu; bridge_link_t *blp = NULL, *blpt; const mac_info_t *mip; boolean_t macopen = B_FALSE; char linkname[MAXLINKNAMELEN]; char kstatname[KSTAT_STRLEN]; int i; link_state_t linkstate; mblk_t *mlist; bsp = (bridge_stream_t *)mp->b_next; mp->b_next = NULL; bip = bsp->bs_inst; /* LINTED: alignment */ linkid = *(datalink_id_t *)mp->b_cont->b_rptr; /* * First make sure that there is no other bridge that has this link. * We don't want to overlap operations from two bridges; the MAC layer * supports only one bridge on a given MAC at a time. * * We rely on the fact that there's just one taskq thread for the * bridging module: once we've checked for a duplicate, we can drop the * lock, because no other thread could possibly be adding another link * until we're done. */ mutex_enter(&inst_lock); for (bipt = list_head(&inst_list); bipt != NULL; bipt = list_next(&inst_list, bipt)) { rw_enter(&bipt->bi_rwlock, RW_READER); for (blpt = list_head(&bipt->bi_links); blpt != NULL; blpt = list_next(&bipt->bi_links, blpt)) { if (linkid == blpt->bl_linkid) break; } rw_exit(&bipt->bi_rwlock); if (blpt != NULL) break; } mutex_exit(&inst_lock); if (bipt != NULL) { err = EBUSY; goto fail; } if ((err = mac_open_by_linkid(linkid, &mh)) != 0) goto fail; macopen = B_TRUE; /* we bridge only Ethernet */ mip = mac_info(mh); if (mip->mi_media != DL_ETHER) { err = ENOTSUP; goto fail; } /* * Get the current maximum SDU on this interface. If there are other * links on the bridge, then this one must match, or it errors out. * Otherwise, the first link becomes the standard for the new bridge. */ mac_sdu_get(mh, NULL, &maxsdu); bmp = bip->bi_mac; if (list_is_empty(&bip->bi_links)) { bmp->bm_maxsdu = maxsdu; (void) mac_maxsdu_update(bmp->bm_mh, maxsdu); } /* figure the kstat name; also used as the mac client name */ i = MBLKL(mp->b_cont) - sizeof (datalink_id_t); if (i < 0 || i >= MAXLINKNAMELEN) i = MAXLINKNAMELEN - 1; bcopy(mp->b_cont->b_rptr + sizeof (datalink_id_t), linkname, i); linkname[i] = '\0'; (void) snprintf(kstatname, sizeof (kstatname), "%s-%s", bip->bi_name, linkname); if ((blp = kmem_zalloc(sizeof (*blp), KM_NOSLEEP)) == NULL) { err = ENOMEM; goto fail; } blp->bl_lfailmp = allocb(sizeof (bridge_ctl_t), BPRI_MED); if (blp->bl_lfailmp == NULL) { kmem_free(blp, sizeof (*blp)); err = ENOMEM; goto fail; } atomic_inc_uint(&bip->bi_refs); blp->bl_inst = bip; blp->bl_mh = mh; blp->bl_linkid = linkid; blp->bl_maxsdu = maxsdu; cv_init(&blp->bl_trillwait, NULL, CV_DRIVER, NULL); mutex_init(&blp->bl_trilllock, NULL, MUTEX_DRIVER, NULL); (void) memset(blp->bl_afs, 0xff, sizeof (blp->bl_afs)); err = mac_client_open(mh, &blp->bl_mch, kstatname, 0); if (err != 0) goto fail; blp->bl_flags |= BLF_CLIENT_OPEN; err = mac_margin_add(mh, &blp->bl_margin, B_TRUE); if (err != 0) goto fail; blp->bl_flags |= BLF_MARGIN_ADDED; blp->bl_mnh = mac_notify_add(mh, bridge_notify_cb, blp); err = mac_bridge_set(mh, (mac_handle_t)blp); if (err != 0) goto fail; blp->bl_flags |= BLF_SET_BRIDGE; err = mac_promisc_add(blp->bl_mch, MAC_CLIENT_PROMISC_ALL, NULL, blp, &blp->bl_mphp, MAC_PROMISC_FLAGS_NO_TX_LOOP); if (err != 0) goto fail; blp->bl_flags |= BLF_PROM_ADDED; bridge_new_unicst(blp); blp->bl_ksp = kstat_setup((kstat_named_t *)&blp->bl_kstats, link_kstats_list, Dim(link_kstats_list), kstatname); /* * The link holds a reference to the bridge instance, so that the * instance can't go away before the link is freed. The insertion into * bi_links holds a reference on the link. When marking as removed * from bi_links (BLF_DELETED), drop the reference on the link. When * freeing the link, drop the reference on the instance. */ rw_enter(&bip->bi_rwlock, RW_WRITER); list_insert_tail(&bip->bi_links, blp); atomic_inc_uint(&blp->bl_refs); /* * If the new link is no good on this bridge, then let the daemon know * about the problem. */ mlist = NULL; if (maxsdu != bmp->bm_maxsdu) link_sdu_fail(blp, B_TRUE, &mlist); rw_exit(&bip->bi_rwlock); send_up_messages(bip, mlist); /* * Trigger a link state update so that if this link is the first one * "up" in the bridge, then we notify everyone. This triggers a trip * through bridge_ls_cb. */ linkstate = mac_stat_get(mh, MAC_STAT_LOWLINK_STATE); blp->bl_linkstate = LINK_STATE_DOWN; mac_link_update(mh, linkstate); /* * We now need to report back to the stream that invoked us, and then * drop the reference on the stream that we're holding. */ miocack(bsp->bs_wq, mp, 0, 0); stream_unref(bsp); return; fail: if (blp == NULL) { if (macopen) mac_close(mh); } else { link_shutdown(blp); link_free(blp); } miocnak(bsp->bs_wq, mp, 0, err); stream_unref(bsp); } static void bridge_rem_link(void *arg) { mblk_t *mp = arg; bridge_stream_t *bsp; bridge_inst_t *bip; bridge_mac_t *bmp; datalink_id_t linkid; bridge_link_t *blp, *blsave; boolean_t found; mblk_t *mlist; bsp = (bridge_stream_t *)mp->b_next; mp->b_next = NULL; bip = bsp->bs_inst; /* LINTED: alignment */ linkid = *(datalink_id_t *)mp->b_cont->b_rptr; /* * We become reader here so that we can loop over the other links and * deliver link up/down notification. */ rw_enter(&bip->bi_rwlock, RW_READER); found = B_FALSE; for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (blp->bl_linkid == linkid && !(blp->bl_flags & BLF_DELETED)) { blp->bl_flags |= BLF_DELETED; (void) ddi_taskq_dispatch(bridge_taskq, link_shutdown, blp, DDI_SLEEP); found = B_TRUE; break; } } /* * Check if this link is up and the remainder of the links are all * down. */ if (blp != NULL && blp->bl_linkstate != LINK_STATE_DOWN) { for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (blp->bl_linkstate != LINK_STATE_DOWN && !(blp->bl_flags & (BLF_DELETED|BLF_SDUFAIL))) break; } if (blp == NULL) { for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (!(blp->bl_flags & BLF_DELETED)) mac_link_redo(blp->bl_mh, LINK_STATE_DOWN); } bmp = bip->bi_mac; bmp->bm_linkstate = LINK_STATE_DOWN; mac_link_redo(bmp->bm_mh, LINK_STATE_DOWN); } } /* * Check if there's just one working link left on the bridge. If so, * then that link is now authoritative for bridge MTU. */ blsave = NULL; for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (!(blp->bl_flags & BLF_DELETED)) { if (blsave == NULL) blsave = blp; else break; } } mlist = NULL; bmp = bip->bi_mac; if (blsave != NULL && blp == NULL && blsave->bl_maxsdu != bmp->bm_maxsdu) { bmp->bm_maxsdu = blsave->bl_maxsdu; (void) mac_maxsdu_update(bmp->bm_mh, blsave->bl_maxsdu); link_sdu_fail(blsave, B_FALSE, &mlist); } rw_exit(&bip->bi_rwlock); send_up_messages(bip, mlist); if (found) miocack(bsp->bs_wq, mp, 0, 0); else miocnak(bsp->bs_wq, mp, 0, ENOENT); stream_unref(bsp); } /* * This function intentionally returns with bi_rwlock held; it is intended for * quick checks and updates. */ static bridge_link_t * enter_link(bridge_inst_t *bip, datalink_id_t linkid) { bridge_link_t *blp; rw_enter(&bip->bi_rwlock, RW_READER); for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (blp->bl_linkid == linkid && !(blp->bl_flags & BLF_DELETED)) break; } return (blp); } static void bridge_ioctl(queue_t *wq, mblk_t *mp) { bridge_stream_t *bsp = wq->q_ptr; bridge_inst_t *bip; struct iocblk *iop; int rc = EINVAL; int len = 0; bridge_link_t *blp; cred_t *cr; /* LINTED: alignment */ iop = (struct iocblk *)mp->b_rptr; /* * For now, all of the bridge ioctls are privileged. */ if ((cr = msg_getcred(mp, NULL)) == NULL) cr = iop->ioc_cr; if (cr != NULL && secpolicy_net_config(cr, B_FALSE) != 0) { miocnak(wq, mp, 0, EPERM); return; } switch (iop->ioc_cmd) { case BRIOC_NEWBRIDGE: { bridge_newbridge_t *bnb; if (bsp->bs_inst != NULL || (rc = miocpullup(mp, sizeof (bridge_newbridge_t))) != 0) break; /* LINTED: alignment */ bnb = (bridge_newbridge_t *)mp->b_cont->b_rptr; bnb->bnb_name[MAXNAMELEN-1] = '\0'; if ((rc = bridge_create(bnb->bnb_linkid, bnb->bnb_name, &bip)) != 0) break; rw_enter(&bip->bi_rwlock, RW_WRITER); if (bip->bi_control != NULL) { rw_exit(&bip->bi_rwlock); bridge_unref(bip); rc = EBUSY; } else { atomic_inc_uint(&bip->bi_refs); bsp->bs_inst = bip; /* stream holds reference */ bip->bi_control = bsp; rw_exit(&bip->bi_rwlock); rc = 0; } break; } case BRIOC_ADDLINK: if ((bip = bsp->bs_inst) == NULL || (rc = miocpullup(mp, sizeof (datalink_id_t))) != 0) break; /* * We cannot perform the action in this thread, because we're * not in process context, and we may already be holding * MAC-related locks. Place the request on taskq. */ mp->b_next = (mblk_t *)bsp; stream_ref(bsp); (void) ddi_taskq_dispatch(bridge_taskq, bridge_add_link, mp, DDI_SLEEP); return; case BRIOC_REMLINK: if ((bip = bsp->bs_inst) == NULL || (rc = miocpullup(mp, sizeof (datalink_id_t))) != 0) break; /* * We cannot perform the action in this thread, because we're * not in process context, and we may already be holding * MAC-related locks. Place the request on taskq. */ mp->b_next = (mblk_t *)bsp; stream_ref(bsp); (void) ddi_taskq_dispatch(bridge_taskq, bridge_rem_link, mp, DDI_SLEEP); return; case BRIOC_SETSTATE: { bridge_setstate_t *bss; if ((bip = bsp->bs_inst) == NULL || (rc = miocpullup(mp, sizeof (*bss))) != 0) break; /* LINTED: alignment */ bss = (bridge_setstate_t *)mp->b_cont->b_rptr; if ((blp = enter_link(bip, bss->bss_linkid)) == NULL) { rc = ENOENT; } else { rc = 0; blp->bl_state = bss->bss_state; } rw_exit(&bip->bi_rwlock); break; } case BRIOC_SETPVID: { bridge_setpvid_t *bsv; if ((bip = bsp->bs_inst) == NULL || (rc = miocpullup(mp, sizeof (*bsv))) != 0) break; /* LINTED: alignment */ bsv = (bridge_setpvid_t *)mp->b_cont->b_rptr; if (bsv->bsv_vlan > VLAN_ID_MAX) break; if ((blp = enter_link(bip, bsv->bsv_linkid)) == NULL) { rc = ENOENT; } else if (blp->bl_pvid == bsv->bsv_vlan) { rc = 0; } else { rc = 0; BRIDGE_VLAN_CLR(blp, blp->bl_pvid); blp->bl_pvid = bsv->bsv_vlan; if (blp->bl_pvid != 0) BRIDGE_VLAN_SET(blp, blp->bl_pvid); } rw_exit(&bip->bi_rwlock); break; } case BRIOC_VLANENAB: { bridge_vlanenab_t *bve; if ((bip = bsp->bs_inst) == NULL || (rc = miocpullup(mp, sizeof (*bve))) != 0) break; /* LINTED: alignment */ bve = (bridge_vlanenab_t *)mp->b_cont->b_rptr; if (bve->bve_vlan > VLAN_ID_MAX) break; if ((blp = enter_link(bip, bve->bve_linkid)) == NULL) { rc = ENOENT; } else { rc = 0; /* special case: vlan 0 means "all" */ if (bve->bve_vlan == 0) { (void) memset(blp->bl_vlans, bve->bve_onoff ? ~0 : 0, sizeof (blp->bl_vlans)); BRIDGE_VLAN_CLR(blp, 0); if (blp->bl_pvid != 0) BRIDGE_VLAN_SET(blp, blp->bl_pvid); } else if (bve->bve_vlan == blp->bl_pvid) { rc = EINVAL; } else if (bve->bve_onoff) { BRIDGE_VLAN_SET(blp, bve->bve_vlan); } else { BRIDGE_VLAN_CLR(blp, bve->bve_vlan); } } rw_exit(&bip->bi_rwlock); break; } case BRIOC_FLUSHFWD: { bridge_flushfwd_t *bff; bridge_fwd_t *bfp, *bfnext; avl_tree_t fwd_scavenge; int i; if ((bip = bsp->bs_inst) == NULL || (rc = miocpullup(mp, sizeof (*bff))) != 0) break; /* LINTED: alignment */ bff = (bridge_flushfwd_t *)mp->b_cont->b_rptr; rw_enter(&bip->bi_rwlock, RW_WRITER); /* This case means "all" */ if (bff->bff_linkid == DATALINK_INVALID_LINKID) { blp = NULL; } else { for (blp = list_head(&bip->bi_links); blp != NULL; blp = list_next(&bip->bi_links, blp)) { if (blp->bl_linkid == bff->bff_linkid && !(blp->bl_flags & BLF_DELETED)) break; } if (blp == NULL) { rc = ENOENT; rw_exit(&bip->bi_rwlock); break; } } avl_create(&fwd_scavenge, fwd_compare, sizeof (bridge_fwd_t), offsetof(bridge_fwd_t, bf_node)); bfnext = avl_first(&bip->bi_fwd); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&bip->bi_fwd, bfp); if (bfp->bf_flags & BFF_LOCALADDR) continue; if (blp != NULL) { for (i = 0; i < bfp->bf_maxlinks; i++) { if (bfp->bf_links[i] == blp) break; } /* * If the link is there and we're excluding, * then skip. If the link is not there and * we're doing only that link, then skip. */ if ((i < bfp->bf_maxlinks) == bff->bff_exclude) continue; } ASSERT(bfp->bf_flags & BFF_INTREE); avl_remove(&bip->bi_fwd, bfp); bfp->bf_flags &= ~BFF_INTREE; avl_add(&fwd_scavenge, bfp); } rw_exit(&bip->bi_rwlock); bfnext = avl_first(&fwd_scavenge); while ((bfp = bfnext) != NULL) { bfnext = AVL_NEXT(&fwd_scavenge, bfp); avl_remove(&fwd_scavenge, bfp); fwd_unref(bfp); /* drop tree reference */ } avl_destroy(&fwd_scavenge); break; } case BRIOC_TABLEMAX: if ((bip = bsp->bs_inst) == NULL || (rc = miocpullup(mp, sizeof (uint32_t))) != 0) break; /* LINTED: alignment */ bip->bi_tablemax = *(uint32_t *)mp->b_cont->b_rptr; break; } if (rc == 0) miocack(wq, mp, len, 0); else miocnak(wq, mp, 0, rc); } static void bridge_wput(queue_t *wq, mblk_t *mp) { switch (DB_TYPE(mp)) { case M_IOCTL: bridge_ioctl(wq, mp); break; case M_FLUSH: if (*mp->b_rptr & FLUSHW) *mp->b_rptr &= ~FLUSHW; if (*mp->b_rptr & FLUSHR) qreply(wq, mp); else freemsg(mp); break; default: freemsg(mp); break; } } /* * This function allocates the main data structures for the bridge driver and * connects us into devfs. */ static void bridge_inst_init(void) { bridge_scan_interval = 5 * drv_usectohz(1000000); bridge_fwd_age = 25 * drv_usectohz(1000000); rw_init(&bmac_rwlock, NULL, RW_DRIVER, NULL); list_create(&bmac_list, sizeof (bridge_mac_t), offsetof(bridge_mac_t, bm_node)); list_create(&inst_list, sizeof (bridge_inst_t), offsetof(bridge_inst_t, bi_node)); cv_init(&inst_cv, NULL, CV_DRIVER, NULL); mutex_init(&inst_lock, NULL, MUTEX_DRIVER, NULL); cv_init(&stream_ref_cv, NULL, CV_DRIVER, NULL); mutex_init(&stream_ref_lock, NULL, MUTEX_DRIVER, NULL); mac_bridge_vectors(bridge_xmit_cb, bridge_recv_cb, bridge_ref_cb, bridge_ls_cb); } /* * This function disconnects from devfs and destroys all data structures in * preparation for unload. It's assumed that there are no active bridge * references left at this point. */ static void bridge_inst_fini(void) { mac_bridge_vectors(NULL, NULL, NULL, NULL); if (bridge_timerid != 0) (void) untimeout(bridge_timerid); rw_destroy(&bmac_rwlock); list_destroy(&bmac_list); list_destroy(&inst_list); cv_destroy(&inst_cv); mutex_destroy(&inst_lock); cv_destroy(&stream_ref_cv); mutex_destroy(&stream_ref_lock); } /* * bridge_attach() * * Description: * Attach bridge driver to the system. */ static int bridge_attach(dev_info_t *dip, ddi_attach_cmd_t cmd) { if (cmd != DDI_ATTACH) return (DDI_FAILURE); if (ddi_create_minor_node(dip, BRIDGE_CTL, S_IFCHR, 0, DDI_PSEUDO, CLONE_DEV) == DDI_FAILURE) { return (DDI_FAILURE); } if (dld_ioc_register(BRIDGE_IOC, bridge_ioc_list, DLDIOCCNT(bridge_ioc_list)) != 0) { ddi_remove_minor_node(dip, BRIDGE_CTL); return (DDI_FAILURE); } bridge_dev_info = dip; bridge_major = ddi_driver_major(dip); bridge_taskq = ddi_taskq_create(dip, "bridge", 1, TASKQ_DEFAULTPRI, 0); return (DDI_SUCCESS); } /* * bridge_detach() * * Description: * Detach an interface to the system. */ static int bridge_detach(dev_info_t *dip, ddi_detach_cmd_t cmd) { if (cmd != DDI_DETACH) return (DDI_FAILURE); ddi_remove_minor_node(dip, NULL); ddi_taskq_destroy(bridge_taskq); bridge_dev_info = NULL; return (DDI_SUCCESS); } /* * bridge_info() * * Description: * Translate "dev_t" to a pointer to the associated "dev_info_t". */ /* ARGSUSED */ static int bridge_info(dev_info_t *dip, ddi_info_cmd_t infocmd, void *arg, void **result) { int rc; switch (infocmd) { case DDI_INFO_DEVT2DEVINFO: if (bridge_dev_info == NULL) { rc = DDI_FAILURE; } else { *result = (void *)bridge_dev_info; rc = DDI_SUCCESS; } break; case DDI_INFO_DEVT2INSTANCE: *result = NULL; rc = DDI_SUCCESS; break; default: rc = DDI_FAILURE; break; } return (rc); } static struct module_info bridge_modinfo = { 2105, /* mi_idnum */ "bridge", /* mi_idname */ 0, /* mi_minpsz */ 16384, /* mi_maxpsz */ 65536, /* mi_hiwat */ 128 /* mi_lowat */ }; static struct qinit bridge_rinit = { NULL, /* qi_putp */ NULL, /* qi_srvp */ bridge_open, /* qi_qopen */ bridge_close, /* qi_qclose */ NULL, /* qi_qadmin */ &bridge_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; static struct qinit bridge_winit = { (int (*)())bridge_wput, /* qi_putp */ NULL, /* qi_srvp */ NULL, /* qi_qopen */ NULL, /* qi_qclose */ NULL, /* qi_qadmin */ &bridge_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; static struct streamtab bridge_tab = { &bridge_rinit, /* st_rdinit */ &bridge_winit /* st_wrinit */ }; /* No STREAMS perimeters; we do all our own locking */ DDI_DEFINE_STREAM_OPS(bridge_ops, nulldev, nulldev, bridge_attach, bridge_detach, nodev, bridge_info, D_NEW | D_MP, &bridge_tab, ddi_quiesce_not_supported); static struct modldrv modldrv = { &mod_driverops, "bridging driver", &bridge_ops }; static struct modlinkage modlinkage = { MODREV_1, (void *)&modldrv, NULL }; int _init(void) { int retv; bridge_inst_init(); if ((retv = mod_install(&modlinkage)) != 0) bridge_inst_fini(); return (retv); } int _fini(void) { int retv; rw_enter(&bmac_rwlock, RW_READER); retv = list_is_empty(&bmac_list) ? 0 : EBUSY; rw_exit(&bmac_rwlock); if (retv == 0 && (retv = mod_remove(&modlinkage)) == 0) bridge_inst_fini(); return (retv); } int _info(struct modinfo *modinfop) { return (mod_info(&modlinkage, modinfop)); }