/* * 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 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #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 "s_common.h" #include "sppptun_mod.h" #include "sppptun_impl.h" #define NTUN_INITIAL 16 /* Initial number of sppptun slots */ #define NTUN_PERCENT 5 /* Percent of memory to use */ /* * This is used to tag official Solaris sources. Please do not define * "INTERNAL_BUILD" when building this software outside of Sun * Microsystems. */ #ifdef INTERNAL_BUILD /* MODINFO is limited to 32 characters. */ const char sppptun_driver_description[] = "PPP 4.0 tunnel driver"; const char sppptun_module_description[] = "PPP 4.0 tunnel module"; #else const char sppptun_driver_description[] = "ANU PPP tundrv"; const char sppptun_module_description[] = "ANU PPP tunmod"; /* LINTED */ static const char buildtime[] = "Built " __DATE__ " at " __TIME__ #ifdef DEBUG " DEBUG" #endif "\n"; #endif /* * Tunable values; these are similar to the values used in ptms_conf.c. * Override these settings via /etc/system. */ uint_t sppptun_cnt = 0; /* Minimum number of tunnels */ size_t sppptun_max_pty = 0; /* Maximum number of tunnels */ uint_t sppptun_init_cnt = NTUN_INITIAL; /* Initial number of tunnel slots */ uint_t sppptun_pctofmem = NTUN_PERCENT; /* Percent of memory to use */ typedef struct ether_dest_s { ether_addr_t addr; ushort_t type; } ether_dest_t; /* Allows unaligned access. */ #define GETLONG(x) (((x)[0]<<24)|((x)[1]<<16)|((x)[2]<<8)|(x)[3]) static const char *tll_kstats_list[] = { TLL_KSTATS_NAMES }; static const char *tcl_kstats_list[] = { TCL_KSTATS_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 KLINCR(vn) KINCR(tll, tll_kstats, vn) #define KLDECR(vn) KDECR(tll, tll_kstats, vn) #define KCINCR(vn) KINCR(tcl, tcl_kstats, vn) #define KCDECR(vn) KDECR(tcl, tcl_kstats, vn) static int sppptun_open(queue_t *, dev_t *, int, int, cred_t *); static int sppptun_close(queue_t *); static void sppptun_urput(queue_t *, mblk_t *); static void sppptun_uwput(queue_t *, mblk_t *); static int sppptun_ursrv(queue_t *); static int sppptun_uwsrv(queue_t *); static void sppptun_lrput(queue_t *, mblk_t *); static void sppptun_lwput(queue_t *, mblk_t *); /* * This is the hash table of clients. Clients are the programs that * open /dev/sppptun as a device. There may be a large number of * these; one per tunneled PPP session. * * Note: slots are offset from minor node value by 1 because * vmem_alloc returns 0 for failure. * * The tcl_slots array entries are modified only when exclusive on * both inner and outer perimeters. This ensures that threads on * shared perimeters always view this as unchanging memory with no * need to lock around accesses. (Specifically, the tcl_slots array * is modified by entry to sppptun_open, sppptun_close, and _fini.) */ static tuncl_t **tcl_slots = NULL; /* Slots for tuncl_t */ static size_t tcl_nslots = 0; /* Size of slot array */ static size_t tcl_minormax = 0; /* Maximum number of tunnels */ static size_t tcl_inuse = 0; /* # of tunnels currently allocated */ static krwlock_t tcl_rwlock; static struct kmem_cache *tcl_cache = NULL; /* tunnel cache */ static vmem_t *tcl_minor_arena = NULL; /* Arena for device minors */ /* * This is the simple list of lower layers. For PPPoE, there is one * of these per Ethernet interface. Lower layers are established by * "plumbing" -- using I_PLINK to connect the tunnel multiplexor to * the physical interface. */ static struct qelem tunll_list; static int tunll_index; /* Test value; if all zeroes, then address hasn't been set yet. */ static const ether_addr_t zero_mac_addr = { 0, 0, 0, 0, 0, 0 }; #define MIN_SET_FASTPATH_UNITDATAREQ_SIZE \ (sizeof (dl_unitdata_req_t) + 4) #define TUN_MI_ID 2104 /* officially allocated module ID */ #define TUN_MI_MINPSZ (0) #define TUN_MI_MAXPSZ (PPP_MAXMTU) #define TUN_MI_HIWAT (PPP_MTU * 8) #define TUN_MI_LOWAT (128) static struct module_info sppptun_modinfo = { TUN_MI_ID, /* mi_idnum */ PPP_TUN_NAME, /* mi_idname */ TUN_MI_MINPSZ, /* mi_minpsz */ TUN_MI_MAXPSZ, /* mi_maxpsz */ TUN_MI_HIWAT, /* mi_hiwat */ TUN_MI_LOWAT /* mi_lowat */ }; static struct qinit sppptun_urinit = { (int (*)())sppptun_urput, /* qi_putp */ sppptun_ursrv, /* qi_srvp */ sppptun_open, /* qi_qopen */ sppptun_close, /* qi_qclose */ NULL, /* qi_qadmin */ &sppptun_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; static struct qinit sppptun_uwinit = { (int (*)())sppptun_uwput, /* qi_putp */ sppptun_uwsrv, /* qi_srvp */ NULL, /* qi_qopen */ NULL, /* qi_qclose */ NULL, /* qi_qadmin */ &sppptun_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; static struct qinit sppptun_lrinit = { (int (*)())sppptun_lrput, /* qi_putp */ NULL, /* qi_srvp */ NULL, /* qi_qopen */ NULL, /* qi_qclose */ NULL, /* qi_qadmin */ &sppptun_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; static struct qinit sppptun_lwinit = { (int (*)())sppptun_lwput, /* qi_putp */ NULL, /* qi_srvp */ NULL, /* qi_qopen */ NULL, /* qi_qclose */ NULL, /* qi_qadmin */ &sppptun_modinfo, /* qi_minfo */ NULL /* qi_mstat */ }; /* * This is referenced in sppptun_mod.c. */ struct streamtab sppptun_tab = { &sppptun_urinit, /* st_rdinit */ &sppptun_uwinit, /* st_wrinit */ &sppptun_lrinit, /* st_muxrinit */ &sppptun_lwinit /* st_muxwrinit */ }; /* * Allocate another slot table twice as large as the original one * (limited to global maximum). Migrate all tunnels to the new slot * table and free the original one. Assumes we're exclusive on both * inner and outer perimeters, and thus there are no other users of * the tcl_slots array. */ static minor_t tcl_grow(void) { minor_t old_size = tcl_nslots; minor_t new_size = 2 * old_size; tuncl_t **tcl_old = tcl_slots; tuncl_t **tcl_new; void *vaddr; /* vmem_add return value */ ASSERT(RW_LOCK_HELD(&tcl_rwlock)); /* Allocate new ptms array */ tcl_new = kmem_zalloc(new_size * sizeof (tuncl_t *), KM_NOSLEEP); if (tcl_new == NULL) return ((minor_t)0); /* Increase clone index space */ vaddr = vmem_add(tcl_minor_arena, (void*)((uintptr_t)old_size + 1), new_size - old_size, VM_NOSLEEP); if (vaddr == NULL) { kmem_free(tcl_new, new_size * sizeof (tuncl_t *)); return ((minor_t)0); } /* Migrate tuncl_t entries to a new location */ tcl_nslots = new_size; bcopy(tcl_old, tcl_new, old_size * sizeof (tuncl_t *)); tcl_slots = tcl_new; kmem_free(tcl_old, old_size * sizeof (tuncl_t *)); /* Allocate minor number and return it */ return ((minor_t)(uintptr_t)vmem_alloc(tcl_minor_arena, 1, VM_NOSLEEP)); } /* * Allocate new minor number and tunnel client entry. Returns the new * entry or NULL if no memory or maximum number of entries reached. * Assumes we're exclusive on both inner and outer perimeters, and * thus there are no other users of the tcl_slots array. */ static tuncl_t * tuncl_alloc(int wantminor) { minor_t dminor; tuncl_t *tcl = NULL; rw_enter(&tcl_rwlock, RW_WRITER); ASSERT(tcl_slots != NULL); /* * Always try to allocate new pty when sppptun_cnt minimum * limit is not achieved. If it is achieved, the maximum is * determined by either user-specified value (if it is * non-zero) or our memory estimations - whatever is less. */ if (tcl_inuse >= sppptun_cnt) { /* * When system achieved required minimum of tunnels, * check for the denial of service limits. * * Get user-imposed maximum, if configured, or * calculated memory constraint. */ size_t user_max = (sppptun_max_pty == 0 ? tcl_minormax : min(sppptun_max_pty, tcl_minormax)); /* Do not try to allocate more than allowed */ if (tcl_inuse >= user_max) { rw_exit(&tcl_rwlock); return (NULL); } } tcl_inuse++; /* * Allocate new minor number. If this fails, all slots are * busy and we need to grow the hash. */ if (wantminor <= 0) { dminor = (minor_t)(uintptr_t)vmem_alloc(tcl_minor_arena, 1, VM_NOSLEEP); if (dminor == 0) { /* Grow the cache and retry allocation */ dminor = tcl_grow(); } } else { dminor = (minor_t)(uintptr_t)vmem_xalloc(tcl_minor_arena, 1, 0, 0, 0, (void *)(uintptr_t)wantminor, (void *)((uintptr_t)wantminor+1), VM_NOSLEEP); if (dminor != 0 && dminor != wantminor) { vmem_free(tcl_minor_arena, (void *)(uintptr_t)dminor, 1); dminor = 0; } } if (dminor == 0) { /* Not enough memory now */ tcl_inuse--; rw_exit(&tcl_rwlock); return (NULL); } tcl = kmem_cache_alloc(tcl_cache, KM_NOSLEEP); if (tcl == NULL) { /* Not enough memory - this entry can't be used now. */ vmem_free(tcl_minor_arena, (void *)(uintptr_t)dminor, 1); tcl_inuse--; } else { bzero(tcl, sizeof (*tcl)); tcl->tcl_lsessid = dminor; ASSERT(tcl_slots[dminor - 1] == NULL); tcl_slots[dminor - 1] = tcl; } rw_exit(&tcl_rwlock); return (tcl); } /* * This routine frees an upper level (client) stream by removing it * from the minor number pool and freeing the state structure storage. * Assumes we're exclusive on both inner and outer perimeters, and * thus there are no other concurrent users of the tcl_slots array or * of any entry in that array. */ static void tuncl_free(tuncl_t *tcl) { rw_enter(&tcl_rwlock, RW_WRITER); ASSERT(tcl->tcl_lsessid <= tcl_nslots); ASSERT(tcl_slots[tcl->tcl_lsessid - 1] == tcl); ASSERT(tcl_inuse > 0); tcl_inuse--; tcl_slots[tcl->tcl_lsessid - 1] = NULL; if (tcl->tcl_ksp != NULL) { kstat_delete(tcl->tcl_ksp); tcl->tcl_ksp = NULL; } /* Return minor number to the pool of minors */ vmem_free(tcl_minor_arena, (void *)(uintptr_t)tcl->tcl_lsessid, 1); /* Return tuncl_t to the cache */ kmem_cache_free(tcl_cache, tcl); rw_exit(&tcl_rwlock); } /* * Get tuncl_t structure by minor number. Returns NULL when minor is * out of range. Note that lookup of tcl pointers (and use of those * pointers) is safe because modification is done only when exclusive * on both inner and outer perimeters. */ static tuncl_t * tcl_by_minor(minor_t dminor) { tuncl_t *tcl = NULL; if ((dminor >= 1) && (dminor <= tcl_nslots) && tcl_slots != NULL) { tcl = tcl_slots[dminor - 1]; } return (tcl); } /* * Set up kstats for upper or lower stream. */ static kstat_t * kstat_setup(kstat_named_t *knt, const char **names, int nstat, const char *modname, int unitnum) { kstat_t *ksp; char unitname[KSTAT_STRLEN]; int i; for (i = 0; i < nstat; i++) { kstat_set_string(knt[i].name, names[i]); knt[i].data_type = KSTAT_DATA_UINT64; } (void) sprintf(unitname, "%s" "%d", modname, unitnum); ksp = kstat_create(modname, unitnum, unitname, "net", KSTAT_TYPE_NAMED, nstat, KSTAT_FLAG_VIRTUAL); if (ksp != NULL) { ksp->ks_data = (void *)knt; kstat_install(ksp); } return (ksp); } /* * sppptun_open() * * MT-Perimeters: * exclusive inner, exclusive outer. * * Description: * Common open procedure for module and driver. */ static int sppptun_open(queue_t *q, dev_t *devp, int oflag, int sflag, cred_t *credp) { _NOTE(ARGUNUSED(oflag)) /* Allow a re-open */ if (q->q_ptr != NULL) return (0); /* In the off chance that we're on our way out, just return error */ if (tcl_slots == NULL) return (EINVAL); if (sflag & MODOPEN) { tunll_t *tll; char *cp; /* ordinary users have no need to push this module */ if (secpolicy_net_config(credp, B_FALSE) != 0) return (EPERM); tll = kmem_zalloc(sizeof (tunll_t), KM_SLEEP); tll->tll_index = tunll_index++; tll->tll_wq = WR(q); /* Insert at end of list */ insque(&tll->tll_next, tunll_list.q_back); q->q_ptr = WR(q)->q_ptr = tll; tll->tll_style = PTS_PPPOE; tll->tll_alen = sizeof (tll->tll_lcladdr.pta_pppoe); tll->tll_ksp = kstat_setup((kstat_named_t *)&tll->tll_kstats, tll_kstats_list, Dim(tll_kstats_list), "tll", tll->tll_index); /* * Find the name of the driver somewhere beneath us. * Note that we have no driver under us until after * qprocson(). */ qprocson(q); for (q = WR(q); q->q_next != NULL; q = q->q_next) ; cp = NULL; if (q->q_qinfo != NULL && q->q_qinfo->qi_minfo != NULL) cp = q->q_qinfo->qi_minfo->mi_idname; if (cp != NULL && *cp == '\0') cp = NULL; /* Set initial name; user should overwrite. */ if (cp == NULL) (void) snprintf(tll->tll_name, sizeof (tll->tll_name), PPP_TUN_NAME "%d", tll->tll_index); else (void) snprintf(tll->tll_name, sizeof (tll->tll_name), "%s:tun%d", cp, tll->tll_index); } else { tuncl_t *tcl; ASSERT(devp != NULL); if (sflag & CLONEOPEN) { tcl = tuncl_alloc(-1); } else { minor_t mn; /* * Support of non-clone open (ie, mknod with * defined minor number) is supported for * testing purposes so that 'arbitrary' minor * numbers can be used. */ mn = getminor(*devp); if (mn == 0 || (tcl = tcl_by_minor(mn)) != NULL) { return (EPERM); } tcl = tuncl_alloc(mn); } if (tcl == NULL) return (ENOSR); tcl->tcl_rq = q; /* save read queue pointer */ tcl->tcl_flags |= TCLF_ISCLIENT; /* sanity check */ q->q_ptr = WR(q)->q_ptr = (caddr_t)tcl; *devp = makedevice(getmajor(*devp), tcl->tcl_lsessid); tcl->tcl_ksp = kstat_setup((kstat_named_t *)&tcl->tcl_kstats, tcl_kstats_list, Dim(tcl_kstats_list), "tcl", tcl->tcl_lsessid); qprocson(q); } return (0); } /* * Create an appropriate control message for this client event. */ static mblk_t * make_control(tuncl_t *tclabout, tunll_t *tllabout, int action, tuncl_t *tclto) { struct ppptun_control *ptc; mblk_t *mp = allocb(sizeof (*ptc), BPRI_HI); if (mp != NULL) { MTYPE(mp) = M_PROTO; ptc = (struct ppptun_control *)mp->b_wptr; mp->b_wptr += sizeof (*ptc); if (tclabout != NULL) { ptc->ptc_rsessid = tclabout->tcl_rsessid; ptc->ptc_address = tclabout->tcl_address; } else { bzero(ptc, sizeof (*ptc)); } ptc->ptc_discrim = tclto->tcl_ctlval; ptc->ptc_action = action; (void) strncpy(ptc->ptc_name, tllabout->tll_name, sizeof (ptc->ptc_name)); } return (mp); } /* * Send an appropriate control message up this client session. */ static void send_control(tuncl_t *tclabout, tunll_t *tllabout, int action, tuncl_t *tcl) { mblk_t *mp; if (tcl->tcl_rq != NULL) { mp = make_control(tclabout, tllabout, action, tcl); if (mp != NULL) { KCINCR(cks_octrl_spec); putnext(tcl->tcl_rq, mp); } } } /* * If a lower stream is being unplumbed, then the upper streams * connected to this lower stream must be disconnected. This routine * accomplishes this by sending M_HANGUP to data streams and M_PROTO * messages to control streams. This is called by vmem_walk, and * handles a span of minor node numbers. * * No need to update lks_clients here; the lower stream is on its way * out. */ static void tclvm_remove_tll(void *arg, void *firstv, size_t numv) { tunll_t *tll = (tunll_t *)arg; int minorn = (int)(uintptr_t)firstv; int minormax = minorn + numv; tuncl_t *tcl; mblk_t *mp; while (minorn < minormax) { tcl = tcl_slots[minorn - 1]; ASSERT(tcl != NULL); if (tcl->tcl_data_tll == tll && tcl->tcl_rq != NULL) { tcl->tcl_data_tll = NULL; mp = allocb(0, BPRI_HI); if (mp != NULL) { MTYPE(mp) = M_HANGUP; putnext(tcl->tcl_rq, mp); if (tcl->tcl_ctrl_tll == tll) tcl->tcl_ctrl_tll = NULL; } } if (tcl->tcl_ctrl_tll == tll) { send_control(tcl, tll, PTCA_UNPLUMB, tcl); tcl->tcl_ctrl_tll = NULL; } minorn++; } } /* * sppptun_close() * * MT-Perimeters: * exclusive inner, exclusive outer. * * Description: * Common close procedure for module and driver. */ static int sppptun_close(queue_t *q) { int err; void *qptr; tunll_t *tll; tuncl_t *tcl; qptr = q->q_ptr; err = 0; tll = qptr; if (!(tll->tll_flags & TLLF_NOTLOWER)) { /* q_next is set on modules */ ASSERT(WR(q)->q_next != NULL); /* unlink any clients using this lower layer. */ vmem_walk(tcl_minor_arena, VMEM_ALLOC, tclvm_remove_tll, tll); /* tell daemon that this has been removed. */ if ((tcl = tll->tll_defcl) != NULL) send_control(NULL, tll, PTCA_UNPLUMB, tcl); tll->tll_flags |= TLLF_CLOSING; while (!(tll->tll_flags & TLLF_CLOSE_DONE)) { qenable(tll->tll_wq); qwait(tll->tll_wq); } tll->tll_error = 0; while (!(tll->tll_flags & TLLF_SHUTDOWN_DONE)) { if (!qwait_sig(tll->tll_wq)) break; } qprocsoff(q); q->q_ptr = WR(q)->q_ptr = NULL; tll->tll_wq = NULL; remque(&tll->tll_next); err = tll->tll_error; if (tll->tll_ksp != NULL) kstat_delete(tll->tll_ksp); kmem_free(tll, sizeof (*tll)); } else { tcl = qptr; /* devices are end of line; no q_next. */ ASSERT(WR(q)->q_next == NULL); qprocsoff(q); DTRACE_PROBE1(sppptun__client__close, tuncl_t *, tcl); tcl->tcl_rq = NULL; q->q_ptr = WR(q)->q_ptr = NULL; tll = TO_TLL(tunll_list.q_forw); while (tll != TO_TLL(&tunll_list)) { if (tll->tll_defcl == tcl) tll->tll_defcl = NULL; if (tll->tll_lastcl == tcl) tll->tll_lastcl = NULL; tll = TO_TLL(tll->tll_next); } /* * If this was a normal session, then tell the daemon. */ if (!(tcl->tcl_flags & TCLF_DAEMON) && (tll = tcl->tcl_ctrl_tll) != NULL && tll->tll_defcl != NULL) { send_control(tcl, tll, PTCA_DISCONNECT, tll->tll_defcl); } /* Update statistics for references being dropped. */ if ((tll = tcl->tcl_data_tll) != NULL) { KLDECR(lks_clients); } if ((tll = tcl->tcl_ctrl_tll) != NULL) { KLDECR(lks_clients); } tuncl_free(tcl); } return (err); } /* * Allocate and initialize a DLPI or TPI template of the specified * length. */ static mblk_t * pi_alloc(size_t len, int prim) { mblk_t *mp; mp = allocb(len, BPRI_MED); if (mp != NULL) { MTYPE(mp) = M_PROTO; mp->b_wptr = mp->b_rptr + len; bzero(mp->b_rptr, len); *(int *)mp->b_rptr = prim; } return (mp); } #define dlpi_alloc(l, p) pi_alloc((l), (p)) /* * Prepend some room to an mblk. Try to reuse the existing buffer, if * at all possible, rather than allocating a new one. (Fast-path * output should be able to use this.) * * (XXX why isn't this a library function ...?) */ static mblk_t * prependb(mblk_t *mp, size_t len, size_t align) { mblk_t *newmp; if (align == 0) align = 8; if (DB_REF(mp) > 1 || mp->b_datap->db_base+len > mp->b_rptr || ((uint_t)((uintptr_t)mp->b_rptr - len) % align) != 0) { if ((newmp = allocb(len, BPRI_LO)) == NULL) { freemsg(mp); return (NULL); } newmp->b_wptr = newmp->b_rptr + len; newmp->b_cont = mp; return (newmp); } mp->b_rptr -= len; return (mp); } /* * sppptun_outpkt() * * MT-Perimeters: * shared inner, shared outer (if called from sppptun_uwput), * exclusive inner, shared outer (if called from sppptun_uwsrv). * * Description: * Called from sppptun_uwput or sppptun_uwsrv when processing a * M_DATA, M_PROTO, or M_PCPROTO message. For all cases, it tries * to prepare the data to be sent to the module below this driver * if there is a lower stream linked underneath. If no lower * stream exists, then the data will be discarded and an ENXIO * error returned. * * Returns: * pointer to queue if caller should do putnext, otherwise * *mpp != NULL if message should be enqueued, otherwise * *mpp == NULL if message is gone. */ static queue_t * sppptun_outpkt(queue_t *q, mblk_t **mpp) { mblk_t *mp; tuncl_t *tcl; tunll_t *tll; mblk_t *encmb; mblk_t *datamb; dl_unitdata_req_t *dur; queue_t *lowerq; poep_t *poep; int len; ether_dest_t *edestp; enum { luNone, luCopy, luSend } loopup; boolean_t isdata; struct ppptun_control *ptc; mp = *mpp; tcl = q->q_ptr; *mpp = NULL; if (!(tcl->tcl_flags & TCLF_ISCLIENT)) { merror(q, mp, EINVAL); return (NULL); } isdata = (MTYPE(mp) == M_DATA); if (isdata) { tll = tcl->tcl_data_tll; ptc = NULL; } else { /* * If data are unaligned or otherwise unsuitable, then * discard. */ if (MBLKL(mp) != sizeof (*ptc) || DB_REF(mp) > 1 || !IS_P2ALIGNED(mp->b_rptr, sizeof (ptc))) { KCINCR(cks_octrl_drop); DTRACE_PROBE2(sppptun__bad__control, tuncl_t *, tcl, mblk_t *, mp); merror(q, mp, EINVAL); return (NULL); } ptc = (struct ppptun_control *)mp->b_rptr; /* Set stream discriminator value if not yet set. */ if (tcl->tcl_ctlval == 0) tcl->tcl_ctlval = ptc->ptc_discrim; /* If this is a test message, then reply to caller. */ if (ptc->ptc_action == PTCA_TEST) { DTRACE_PROBE2(sppptun__test, tuncl_t *, tcl, struct ppptun_control *, ptc); if (mp->b_cont != NULL) { freemsg(mp->b_cont); mp->b_cont = NULL; } ptc->ptc_discrim = tcl->tcl_ctlval; putnext(RD(q), mp); return (NULL); } /* If this one isn't for us, then discard it */ if (tcl->tcl_ctlval != ptc->ptc_discrim) { DTRACE_PROBE2(sppptun__bad__discrim, tuncl_t *, tcl, struct ppptun_control *, ptc); freemsg(mp); return (NULL); } /* Don't allow empty control packets. */ if (mp->b_cont == NULL) { KCINCR(cks_octrl_drop); merror(q, mp, EINVAL); return (NULL); } tll = tcl->tcl_ctrl_tll; } if (tll == NULL || (lowerq = tll->tll_wq) == NULL) { DTRACE_PROBE3(sppptun__cannot__send, tuncl_t *, tcl, tunll_t *, tll, mblk_t *, mp); merror(q, mp, ENXIO); if (isdata) { tcl->tcl_stats.ppp_oerrors++; } else { KCINCR(cks_octrl_drop); } return (NULL); } /* * If so, then try to send it down. The lower queue is only * ever detached while holding an exclusive lock on the whole * driver, so we can be confident that the lower queue is * still there. */ if (!bcanputnext(lowerq, mp->b_band)) { DTRACE_PROBE3(sppptun__flow__control, tuncl_t *, tcl, tunll_t *, tll, mblk_t *, mp); *mpp = mp; return (NULL); } /* * Note: DLPI and TPI expect that the first buffer contains * the control (unitdata-req) header, destination address, and * nothing else. Any protocol headers must go in the next * buffer. */ loopup = luNone; encmb = NULL; if (isdata) { if (tll->tll_alen != 0 && bcmp(&tcl->tcl_address, &tll->tll_lcladdr, tll->tll_alen) == 0) loopup = luSend; switch (tll->tll_style) { case PTS_PPPOE: /* Strip address and control fields if present. */ if (mp->b_rptr[0] == 0xFF) { if (MBLKL(mp) < 3) { encmb = msgpullup(mp, 3); freemsg(mp); if ((mp = encmb) == NULL) break; } mp->b_rptr += 2; } /* Broadcasting data is probably not a good idea. */ if (tcl->tcl_address.pta_pppoe.ptma_mac[0] & 1) break; encmb = dlpi_alloc(sizeof (*dur) + sizeof (*edestp), DL_UNITDATA_REQ); if (encmb == NULL) break; dur = (dl_unitdata_req_t *)encmb->b_rptr; dur->dl_dest_addr_length = sizeof (*edestp); dur->dl_dest_addr_offset = sizeof (*dur); edestp = (ether_dest_t *)(dur + 1); ether_copy(tcl->tcl_address.pta_pppoe.ptma_mac, edestp->addr); /* DLPI SAPs are in host byte order! */ edestp->type = ETHERTYPE_PPPOES; /* Make sure the protocol field isn't compressed. */ len = (*mp->b_rptr & 1); mp = prependb(mp, sizeof (*poep) + len, POE_HDR_ALIGN); if (mp == NULL) break; poep = (poep_t *)mp->b_rptr; poep->poep_version_type = POE_VERSION; poep->poep_code = POECODE_DATA; poep->poep_session_id = htons(tcl->tcl_rsessid); poep->poep_length = htons(msgsize(mp) - sizeof (*poep)); if (len > 0) *(char *)(poep + 1) = '\0'; break; default: ASSERT(0); } } else { /* * Control side encapsulation. */ if (bcmp(&ptc->ptc_address, &tll->tll_lcladdr, tll->tll_alen) == 0) loopup = luSend; datamb = mp->b_cont; switch (tll->tll_style) { case PTS_PPPOE: /* * Don't allow a loopback session to establish * itself. PPPoE is broken; it uses only one * session ID for both data directions, so the * loopback data path can simply never work. */ if (loopup == luSend && ((poep_t *)datamb->b_rptr)->poep_code == POECODE_PADR) break; encmb = dlpi_alloc(sizeof (*dur) + sizeof (*edestp), DL_UNITDATA_REQ); if (encmb == NULL) break; dur = (dl_unitdata_req_t *)encmb->b_rptr; dur->dl_dest_addr_length = sizeof (*edestp); dur->dl_dest_addr_offset = sizeof (*dur); edestp = (ether_dest_t *)(dur + 1); /* DLPI SAPs are in host byte order! */ edestp->type = ETHERTYPE_PPPOED; /* * If destination isn't set yet, then we have to * allow anything at all. Otherwise, force use * of configured peer address. */ if (bcmp(tcl->tcl_address.pta_pppoe.ptma_mac, zero_mac_addr, sizeof (zero_mac_addr)) == 0 || (tcl->tcl_flags & TCLF_DAEMON)) { ether_copy(ptc->ptc_address.pta_pppoe.ptma_mac, edestp->addr); } else { ether_copy(tcl->tcl_address.pta_pppoe.ptma_mac, edestp->addr); } /* Reflect multicast/broadcast back up. */ if (edestp->addr[0] & 1) loopup = luCopy; break; case PTS_PPTP: /* * PPTP's control side is actually done over * separate TCP connections. */ default: ASSERT(0); } freeb(mp); mp = datamb; } if (mp == NULL || encmb == NULL) { DTRACE_PROBE1(sppptun__output__failure, tuncl_t *, tcl); freemsg(mp); freemsg(encmb); if (isdata) { tcl->tcl_stats.ppp_oerrors++; } else { KCINCR(cks_octrl_drop); KLINCR(lks_octrl_drop); } lowerq = NULL; } else { if (isdata) { tcl->tcl_stats.ppp_obytes += msgsize(mp); tcl->tcl_stats.ppp_opackets++; } else { KCINCR(cks_octrls); KLINCR(lks_octrls); } if (encmb != mp) encmb->b_cont = mp; switch (loopup) { case luNone: *mpp = encmb; break; case luCopy: mp = copymsg(encmb); if (mp != NULL) sppptun_urput(RD(lowerq), mp); *mpp = encmb; break; case luSend: sppptun_urput(RD(lowerq), encmb); lowerq = NULL; break; } } return (lowerq); } /* * Enqueue a message to be sent when the lower stream is closed. This * is done so that we're guaranteed that we always have the necessary * resources to properly detach ourselves from the system. (If we * waited until the close was done to allocate these messages, then * the message allocation could fail, and we'd be unable to properly * detach.) */ static void save_for_close(tunll_t *tll, mblk_t *mp) { mblk_t *onc; if ((onc = tll->tll_onclose) == NULL) tll->tll_onclose = mp; else { while (onc->b_next != NULL) onc = onc->b_next; onc->b_next = mp; } } /* * Given the lower stream name, locate the state structure. Note that * lookup of tcl pointers (and use of those pointers) is safe because * modification is done only when exclusive on both inner and outer * perimeters. */ static tunll_t * tll_lookup_on_name(char *dname) { tunll_t *tll; tll = TO_TLL(tunll_list.q_forw); for (; tll != TO_TLL(&tunll_list); tll = TO_TLL(tll->tll_next)) if (strcmp(dname, tll->tll_name) == 0) return (tll); return (NULL); } /* * sppptun_inner_ioctl() * * MT-Perimeters: * exclusive inner, shared outer. * * Description: * Called by qwriter from sppptun_ioctl as the result of receiving * a handled ioctl. */ static void sppptun_inner_ioctl(queue_t *q, mblk_t *mp) { struct iocblk *iop; int rc = 0; int len = 0; int i; tuncl_t *tcl; tunll_t *tll; union ppptun_name *ptn; struct ppptun_info *pti; struct ppptun_peer *ptp; mblk_t *mptmp; ppptun_atype *pap; struct ppp_stats64 *psp; iop = (struct iocblk *)mp->b_rptr; tcl = NULL; tll = q->q_ptr; if (tll->tll_flags & TLLF_NOTLOWER) { tcl = (tuncl_t *)tll; tll = NULL; } DTRACE_PROBE3(sppptun__ioctl, tuncl_t *, tcl, tunll_t *, tll, struct iocblk *, iop); switch (iop->ioc_cmd) { case PPPIO_DEBUG: /* * Debug requests are now ignored; use dtrace or wireshark * instead. */ break; case PPPIO_GETSTAT: rc = EINVAL; break; case PPPIO_GETSTAT64: /* Client (device) side only */ if (tcl == NULL) { rc = EINVAL; break; } mptmp = allocb(sizeof (*psp), BPRI_HI); if (mptmp == NULL) { rc = ENOSR; break; } freemsg(mp->b_cont); mp->b_cont = mptmp; psp = (struct ppp_stats64 *)mptmp->b_wptr; bzero((caddr_t)psp, sizeof (*psp)); psp->p = tcl->tcl_stats; len = sizeof (*psp); break; case PPPTUN_SNAME: /* This is done on the *module* (lower level) side. */ if (tll == NULL || mp->b_cont == NULL || iop->ioc_count != sizeof (*ptn) || *mp->b_cont->b_rptr == '\0') { rc = EINVAL; break; } ptn = (union ppptun_name *)mp->b_cont->b_rptr; ptn->ptn_name[sizeof (ptn->ptn_name) - 1] = '\0'; if ((tll = tll_lookup_on_name(ptn->ptn_name)) != NULL) { rc = EEXIST; break; } tll = (tunll_t *)q->q_ptr; (void) strcpy(tll->tll_name, ptn->ptn_name); break; case PPPTUN_GNAME: /* This is done on the *module* (lower level) side. */ if (tll == NULL) { rc = EINVAL; break; } if (mp->b_cont != NULL) freemsg(mp->b_cont); if ((mp->b_cont = allocb(sizeof (*ptn), BPRI_HI)) == NULL) { rc = ENOSR; break; } ptn = (union ppptun_name *)mp->b_cont->b_rptr; bcopy(tll->tll_name, ptn->ptn_name, sizeof (ptn->ptn_name)); len = sizeof (*ptn); break; case PPPTUN_SINFO: case PPPTUN_GINFO: /* Either side */ if (mp->b_cont == NULL || iop->ioc_count != sizeof (*pti)) { rc = EINVAL; break; } pti = (struct ppptun_info *)mp->b_cont->b_rptr; if (pti->pti_name[0] != '\0') tll = tll_lookup_on_name(pti->pti_name); if (tll == NULL) { /* Driver (client) side must have name */ if (tcl != NULL && pti->pti_name[0] == '\0') rc = EINVAL; else rc = ESRCH; break; } if (iop->ioc_cmd == PPPTUN_GINFO) { pti->pti_muxid = tll->tll_muxid; pti->pti_style = tll->tll_style; len = sizeof (*pti); break; } tll->tll_muxid = pti->pti_muxid; tll->tll_style = pti->pti_style; switch (tll->tll_style) { case PTS_PPPOE: /* DLPI type */ tll->tll_alen = sizeof (tll->tll_lcladdr.pta_pppoe); mptmp = dlpi_alloc(sizeof (dl_unbind_req_t), DL_UNBIND_REQ); if (mptmp == NULL) { rc = ENOSR; break; } save_for_close(tll, mptmp); mptmp = dlpi_alloc(sizeof (dl_detach_req_t), DL_DETACH_REQ); if (mptmp == NULL) { rc = ENOSR; break; } save_for_close(tll, mptmp); break; default: tll->tll_style = PTS_NONE; tll->tll_alen = 0; rc = EINVAL; break; } break; case PPPTUN_GNNAME: /* This can be done on either side. */ if (mp->b_cont == NULL || iop->ioc_count < sizeof (uint32_t)) { rc = EINVAL; break; } ptn = (union ppptun_name *)mp->b_cont->b_rptr; i = ptn->ptn_index; tll = TO_TLL(tunll_list.q_forw); while (--i >= 0 && tll != TO_TLL(&tunll_list)) tll = TO_TLL(tll->tll_next); if (tll != TO_TLL(&tunll_list)) { bcopy(tll->tll_name, ptn->ptn_name, sizeof (ptn->ptn_name)); } else { bzero(ptn, sizeof (*ptn)); } len = sizeof (*ptn); break; case PPPTUN_LCLADDR: /* This is done on the *module* (lower level) side. */ if (tll == NULL || mp->b_cont == NULL) { rc = EINVAL; break; } pap = &tll->tll_lcladdr; len = tll->tll_alen; if (len == 0 || len > iop->ioc_count) { rc = EINVAL; break; } bcopy(mp->b_cont->b_rptr, pap, len); len = 0; break; case PPPTUN_SPEER: /* Client (device) side only; before SDATA */ if (tcl == NULL || mp->b_cont == NULL || iop->ioc_count != sizeof (*ptp)) { rc = EINVAL; break; } if (tcl->tcl_data_tll != NULL) { rc = EINVAL; break; } ptp = (struct ppptun_peer *)mp->b_cont->b_rptr; DTRACE_PROBE2(sppptun__speer, tuncl_t *, tcl, struct ppptun_peer *, ptp); /* Once set, the style cannot change. */ if (tcl->tcl_style != PTS_NONE && tcl->tcl_style != ptp->ptp_style) { rc = EINVAL; break; } if (ptp->ptp_flags & PTPF_DAEMON) { /* User requests registration for tunnel 0 */ if ((tcl->tcl_flags & TCLF_SPEER_DONE) || ptp->ptp_ltunid != 0 || ptp->ptp_rtunid != 0 || ptp->ptp_lsessid != 0 || ptp->ptp_rsessid != 0) { rc = EINVAL; break; } tcl->tcl_flags |= TCLF_DAEMON; } else { /* Normal client connection */ if (tcl->tcl_flags & TCLF_DAEMON) { rc = EINVAL; break; } if (ptp->ptp_lsessid != 0 && ptp->ptp_lsessid != tcl->tcl_lsessid) { rc = EINVAL; break; } /* * If we're reassigning the peer data, then * the previous assignment must have been for * a client control connection. Check that. */ if ((tcl->tcl_flags & TCLF_SPEER_DONE) && ((tcl->tcl_ltunid != 0 && tcl->tcl_ltunid != ptp->ptp_ltunid) || (tcl->tcl_rtunid != 0 && tcl->tcl_rtunid != ptp->ptp_rtunid) || (tcl->tcl_rsessid != 0 && tcl->tcl_rsessid != ptp->ptp_rsessid))) { rc = EINVAL; break; } if ((tcl->tcl_ltunid = ptp->ptp_ltunid) == 0 && tcl->tcl_style == PTS_L2FTP) tcl->tcl_ltunid = ptp->ptp_lsessid; tcl->tcl_rtunid = ptp->ptp_rtunid; tcl->tcl_rsessid = ptp->ptp_rsessid; } tcl->tcl_flags |= TCLF_SPEER_DONE; tcl->tcl_style = ptp->ptp_style; tcl->tcl_address = ptp->ptp_address; goto fill_in_peer; case PPPTUN_GPEER: /* Client (device) side only */ if (tcl == NULL) { rc = EINVAL; break; } if (mp->b_cont != NULL) freemsg(mp->b_cont); mp->b_cont = allocb(sizeof (*ptp), BPRI_HI); if (mp->b_cont == NULL) { rc = ENOSR; break; } ptp = (struct ppptun_peer *)mp->b_cont->b_rptr; fill_in_peer: ptp->ptp_style = tcl->tcl_style; ptp->ptp_flags = (tcl->tcl_flags & TCLF_DAEMON) ? PTPF_DAEMON : 0; ptp->ptp_ltunid = tcl->tcl_ltunid; ptp->ptp_rtunid = tcl->tcl_rtunid; ptp->ptp_lsessid = tcl->tcl_lsessid; ptp->ptp_rsessid = tcl->tcl_rsessid; ptp->ptp_address = tcl->tcl_address; len = sizeof (*ptp); break; case PPPTUN_SDATA: case PPPTUN_SCTL: /* Client (device) side only; must do SPEER first */ if (tcl == NULL || mp->b_cont == NULL || iop->ioc_count != sizeof (*ptn) || *mp->b_cont->b_rptr == '\0') { rc = EINVAL; break; } if (!(tcl->tcl_flags & TCLF_SPEER_DONE)) { rc = EINVAL; break; } ptn = (union ppptun_name *)mp->b_cont->b_rptr; ptn->ptn_name[sizeof (ptn->ptn_name) - 1] = '\0'; tll = tll_lookup_on_name(ptn->ptn_name); if (tll == NULL) { rc = ESRCH; break; } if (tll->tll_style != tcl->tcl_style) { rc = ENXIO; break; } if (iop->ioc_cmd == PPPTUN_SDATA) { if (tcl->tcl_data_tll != NULL) { rc = EEXIST; break; } /* server daemons cannot use regular data */ if (tcl->tcl_flags & TCLF_DAEMON) { rc = EINVAL; break; } tcl->tcl_data_tll = tll; } else if (tcl->tcl_flags & TCLF_DAEMON) { if (tll->tll_defcl != NULL && tll->tll_defcl != tcl) { rc = EEXIST; break; } tll->tll_defcl = tcl; if (tcl->tcl_ctrl_tll != NULL) { KDECR(tcl->tcl_ctrl_tll, tll_kstats, lks_clients); } tcl->tcl_ctrl_tll = tll; } else { if (tcl->tcl_ctrl_tll != NULL) { rc = EEXIST; break; } tcl->tcl_ctrl_tll = tll; } KLINCR(lks_clients); break; case PPPTUN_GDATA: case PPPTUN_GCTL: /* Client (device) side only */ if (tcl == NULL) { rc = EINVAL; break; } if (mp->b_cont != NULL) freemsg(mp->b_cont); mp->b_cont = allocb(sizeof (*ptn), BPRI_HI); if (mp->b_cont == NULL) { rc = ENOSR; break; } ptn = (union ppptun_name *)mp->b_cont->b_rptr; if (iop->ioc_cmd == PPPTUN_GDATA) tll = tcl->tcl_data_tll; else tll = tcl->tcl_ctrl_tll; if (tll == NULL) bzero(ptn, sizeof (*ptn)); else bcopy(tll->tll_name, ptn->ptn_name, sizeof (ptn->ptn_name)); len = sizeof (*ptn); break; case PPPTUN_DCTL: /* Client (device) side daemon mode only */ if (tcl == NULL || mp->b_cont == NULL || iop->ioc_count != sizeof (*ptn) || !(tcl->tcl_flags & TCLF_DAEMON)) { rc = EINVAL; break; } ptn = (union ppptun_name *)mp->b_cont->b_rptr; ptn->ptn_name[sizeof (ptn->ptn_name) - 1] = '\0'; tll = tll_lookup_on_name(ptn->ptn_name); if (tll == NULL || tll->tll_defcl != tcl) { rc = ESRCH; break; } tll->tll_defcl = NULL; break; default: /* Caller should already have checked command value */ ASSERT(0); } if (rc != 0) { miocnak(q, mp, 0, rc); } else { if (len > 0) mp->b_cont->b_wptr = mp->b_cont->b_rptr + len; miocack(q, mp, len, 0); } } /* * sppptun_ioctl() * * MT-Perimeters: * shared inner, shared outer. * * Description: * Called by sppptun_uwput as the result of receiving a M_IOCTL command. */ static void sppptun_ioctl(queue_t *q, mblk_t *mp) { struct iocblk *iop; int rc = 0; int len = 0; uint32_t val = 0; tunll_t *tll; iop = (struct iocblk *)mp->b_rptr; switch (iop->ioc_cmd) { case PPPIO_DEBUG: case PPPIO_GETSTAT: case PPPIO_GETSTAT64: case PPPTUN_SNAME: case PPPTUN_GNAME: case PPPTUN_SINFO: case PPPTUN_GINFO: case PPPTUN_GNNAME: case PPPTUN_LCLADDR: case PPPTUN_SPEER: case PPPTUN_GPEER: case PPPTUN_SDATA: case PPPTUN_GDATA: case PPPTUN_SCTL: case PPPTUN_GCTL: case PPPTUN_DCTL: qwriter(q, mp, sppptun_inner_ioctl, PERIM_INNER); return; case PPPIO_GCLEAN: /* always clean */ val = RCV_B7_1 | RCV_B7_0 | RCV_ODDP | RCV_EVNP; len = sizeof (uint32_t); break; case PPPIO_GTYPE: /* we look like an async driver. */ val = PPPTYP_AHDLC; len = sizeof (uint32_t); break; case PPPIO_CFLAGS: /* never compress headers */ val = 0; len = sizeof (uint32_t); break; /* quietly ack PPP things we don't need to do. */ case PPPIO_XFCS: case PPPIO_RFCS: case PPPIO_XACCM: case PPPIO_RACCM: case PPPIO_LASTMOD: case PPPIO_MUX: case I_PLINK: case I_PUNLINK: case I_LINK: case I_UNLINK: break; default: tll = (tunll_t *)q->q_ptr; if (!(tll->tll_flags & TLLF_NOTLOWER)) { /* module side; pass this through. */ putnext(q, mp); return; } rc = EINVAL; break; } if (rc == 0 && len == sizeof (uint32_t)) { if (mp->b_cont != NULL) freemsg(mp->b_cont); mp->b_cont = allocb(sizeof (uint32_t), BPRI_HI); if (mp->b_cont == NULL) { rc = ENOSR; } else { *(uint32_t *)mp->b_cont->b_wptr = val; mp->b_cont->b_wptr += sizeof (uint32_t); } } if (rc == 0) { miocack(q, mp, len, 0); } else { miocnak(q, mp, 0, rc); } } /* * sppptun_inner_mctl() * * MT-Perimeters: * exclusive inner, shared outer. * * Description: * Called by qwriter (via sppptun_uwput) as the result of receiving * an M_CTL. Called only on the client (driver) side. */ static void sppptun_inner_mctl(queue_t *q, mblk_t *mp) { int msglen; tuncl_t *tcl; tcl = q->q_ptr; if (!(tcl->tcl_flags & TCLF_ISCLIENT)) { freemsg(mp); return; } msglen = MBLKL(mp); switch (*mp->b_rptr) { case PPPCTL_UNIT: if (msglen == 2) tcl->tcl_unit = mp->b_rptr[1]; else if (msglen == 8) tcl->tcl_unit = ((uint32_t *)mp->b_rptr)[1]; break; } freemsg(mp); } /* * sppptun_uwput() * * MT-Perimeters: * shared inner, shared outer. * * Description: * Regular output data and controls pass through here. */ static void sppptun_uwput(queue_t *q, mblk_t *mp) { queue_t *nextq; tuncl_t *tcl; ASSERT(q->q_ptr != NULL); switch (MTYPE(mp)) { case M_DATA: case M_PROTO: case M_PCPROTO: if (q->q_first == NULL && (nextq = sppptun_outpkt(q, &mp)) != NULL) { putnext(nextq, mp); } else if (mp != NULL && !putq(q, mp)) { freemsg(mp); } break; case M_IOCTL: sppptun_ioctl(q, mp); break; case M_CTL: qwriter(q, mp, sppptun_inner_mctl, PERIM_INNER); break; default: tcl = (tuncl_t *)q->q_ptr; /* * If we're the driver, then discard unknown junk. * Otherwise, if we're the module, then forward along. */ if (tcl->tcl_flags & TCLF_ISCLIENT) freemsg(mp); else putnext(q, mp); break; } } /* * Send a DLPI/TPI control message to the driver but make sure there * is only one outstanding message. Uses tll_msg_pending to tell when * it must queue. sppptun_urput calls message_done() when an ACK or a * NAK is received to process the next queued message. */ static void message_send(tunll_t *tll, mblk_t *mp) { mblk_t **mpp; if (tll->tll_msg_pending) { /* Must queue message. Tail insertion */ mpp = &tll->tll_msg_deferred; while (*mpp != NULL) mpp = &((*mpp)->b_next); *mpp = mp; return; } tll->tll_msg_pending = 1; putnext(tll->tll_wq, mp); } /* * Called when an DLPI/TPI control message has been acked or nacked to * send down the next queued message (if any). */ static void message_done(tunll_t *tll) { mblk_t *mp; ASSERT(tll->tll_msg_pending); tll->tll_msg_pending = 0; mp = tll->tll_msg_deferred; if (mp != NULL) { tll->tll_msg_deferred = mp->b_next; mp->b_next = NULL; tll->tll_msg_pending = 1; putnext(tll->tll_wq, mp); } } /* * Send down queued "close" messages to lower stream. These were * enqueued right after the stream was originally allocated, when the * tll_style was set by PPPTUN_SINFO. */ static int tll_close_req(tunll_t *tll) { mblk_t *mb, *mbnext; if ((mb = tll->tll_onclose) == NULL) tll->tll_flags |= TLLF_SHUTDOWN_DONE; else { tll->tll_onclose = NULL; while (mb != NULL) { mbnext = mb->b_next; mb->b_next = NULL; message_send(tll, mb); mb = mbnext; } } return (0); } /* * This function is called when a backenable occurs on the write side of a * lower stream. It walks over the client streams, looking for ones that use * the given tunll_t lower stream. Each client is then backenabled. */ static void tclvm_backenable(void *arg, void *firstv, size_t numv) { tunll_t *tll = arg; int minorn = (int)(uintptr_t)firstv; int minormax = minorn + numv; tuncl_t *tcl; queue_t *q; while (minorn < minormax) { tcl = tcl_slots[minorn - 1]; if ((tcl->tcl_data_tll == tll || tcl->tcl_ctrl_tll == tll) && (q = tcl->tcl_rq) != NULL) { qenable(OTHERQ(q)); } minorn++; } } /* * sppptun_uwsrv() * * MT-Perimeters: * exclusive inner, shared outer. * * Description: * Upper write-side service procedure. In addition to the usual * STREAMS queue service handling, this routine also handles the * transmission of the unbind/detach messages to the lower stream * driver when a lower stream is being closed. (See the use of * qenable/qwait in sppptun_close().) */ static int sppptun_uwsrv(queue_t *q) { tuncl_t *tcl; mblk_t *mp; queue_t *nextq; tcl = q->q_ptr; if (!(tcl->tcl_flags & TCLF_ISCLIENT)) { tunll_t *tll = (tunll_t *)tcl; if ((tll->tll_flags & (TLLF_CLOSING|TLLF_CLOSE_DONE)) == TLLF_CLOSING) { tll->tll_error = tll_close_req(tll); tll->tll_flags |= TLLF_CLOSE_DONE; } else { /* * We've been enabled here because of a backenable on * output flow control. Backenable clients using this * lower layer. */ vmem_walk(tcl_minor_arena, VMEM_ALLOC, tclvm_backenable, tll); } return (0); } while ((mp = getq(q)) != NULL) { if ((nextq = sppptun_outpkt(q, &mp)) != NULL) { putnext(nextq, mp); } else if (mp != NULL) { (void) putbq(q, mp); break; } } return (0); } /* * sppptun_lwput() * * MT-Perimeters: * shared inner, shared outer. * * Description: * Lower write-side put procedure. Nothing should be sending * packets down this stream. */ static void sppptun_lwput(queue_t *q, mblk_t *mp) { switch (MTYPE(mp)) { case M_PROTO: putnext(q, mp); break; default: freemsg(mp); break; } } /* * sppptun_lrput() * * MT-Perimeters: * shared inner, shared outer. * * Description: * Lower read-side put procedure. Nothing should arrive here. */ static void sppptun_lrput(queue_t *q, mblk_t *mp) { tuncl_t *tcl; switch (MTYPE(mp)) { case M_IOCTL: miocnak(q, mp, 0, EINVAL); return; case M_FLUSH: if (*mp->b_rptr & FLUSHR) { flushq(q, FLUSHDATA); } if (*mp->b_rptr & FLUSHW) { *mp->b_rptr &= ~FLUSHR; qreply(q, mp); } else { freemsg(mp); } return; } /* * Try to forward the message to the put procedure for the upper * control stream for this lower stream. If there are already messages * queued here, queue this one up to preserve message ordering. */ if ((tcl = (tuncl_t *)q->q_ptr) == NULL || tcl->tcl_rq == NULL) { freemsg(mp); return; } if (queclass(mp) == QPCTL || (q->q_first == NULL && canput(tcl->tcl_rq))) { put(tcl->tcl_rq, mp); } else { if (!putq(q, mp)) freemsg(mp); } } /* * MT-Perimeters: * shared inner, shared outer. * * Handle non-data DLPI messages. Used with PPPoE, which runs over * Ethernet only. */ static void urput_dlpi(queue_t *q, mblk_t *mp) { int err; union DL_primitives *dlp = (union DL_primitives *)mp->b_rptr; tunll_t *tll = q->q_ptr; size_t mlen = MBLKL(mp); switch (dlp->dl_primitive) { case DL_UDERROR_IND: break; case DL_ERROR_ACK: if (mlen < DL_ERROR_ACK_SIZE) break; err = dlp->error_ack.dl_unix_errno ? dlp->error_ack.dl_unix_errno : ENXIO; switch (dlp->error_ack.dl_error_primitive) { case DL_UNBIND_REQ: message_done(tll); break; case DL_DETACH_REQ: message_done(tll); tll->tll_error = err; tll->tll_flags |= TLLF_SHUTDOWN_DONE; break; case DL_PHYS_ADDR_REQ: message_done(tll); break; case DL_INFO_REQ: case DL_ATTACH_REQ: case DL_BIND_REQ: message_done(tll); tll->tll_error = err; break; } break; case DL_INFO_ACK: message_done(tll); break; case DL_BIND_ACK: message_done(tll); break; case DL_PHYS_ADDR_ACK: break; case DL_OK_ACK: if (mlen < DL_OK_ACK_SIZE) break; switch (dlp->ok_ack.dl_correct_primitive) { case DL_UNBIND_REQ: message_done(tll); break; case DL_DETACH_REQ: tll->tll_flags |= TLLF_SHUTDOWN_DONE; break; case DL_ATTACH_REQ: message_done(tll); break; } break; } freemsg(mp); } /* Search structure used with PPPoE only; see tclvm_pppoe_search(). */ struct poedat { uint_t sessid; tunll_t *tll; const void *srcaddr; int isdata; tuncl_t *tcl; }; /* * This function is called by vmem_walk from within sppptun_recv. It * iterates over a span of allocated minor node numbers to search for * the appropriate lower stream, session ID, and peer MAC address. * * (This is necessary due to a design flaw in the PPPoE protocol * itself. The protocol assigns session IDs from the server side * only. Both server and client use the same number. Thus, if there * are multiple clients on a single host, there can be session ID * conflicts between servers and there's no way to detangle them * except by looking at the remote MAC address.) * * (This could have been handled by linking together sessions that * differ only in the remote MAC address. This isn't done because it * would involve extra per-session storage and it's very unlikely that * PPPoE would be used this way.) */ static void tclvm_pppoe_search(void *arg, void *firstv, size_t numv) { struct poedat *poedat = (struct poedat *)arg; int minorn = (int)(uintptr_t)firstv; int minormax = minorn + numv; tuncl_t *tcl; if (poedat->tcl != NULL) return; while (minorn < minormax) { tcl = tcl_slots[minorn - 1]; ASSERT(tcl != NULL); if (tcl->tcl_rsessid == poedat->sessid && ((!poedat->isdata && tcl->tcl_ctrl_tll == poedat->tll) || (poedat->isdata && tcl->tcl_data_tll == poedat->tll)) && bcmp(tcl->tcl_address.pta_pppoe.ptma_mac, poedat->srcaddr, sizeof (tcl->tcl_address.pta_pppoe.ptma_mac)) == 0) { poedat->tcl = tcl; break; } minorn++; } } /* * sppptun_recv() * * MT-Perimeters: * shared inner, shared outer. * * Description: * Receive function called by sppptun_urput, which is called when * the lower read-side put or service procedure sends a message * upstream to the a device user (PPP). It attempts to find an * appropriate queue on the module above us (depending on what the * associated upper stream for the protocol would be), and if not * possible, it will find an upper control stream for the protocol. * Returns a pointer to the upper queue_t, or NULL if the message * has been discarded. * * About demultiplexing: * * All four protocols (L2F, PPTP, L2TP, and PPPoE) support a * locally assigned ID for demultiplexing incoming traffic. For * L2F, this is called the Client ID, for PPTP the Call ID, for * L2TP the Session ID, and for PPPoE the SESSION_ID. This is a * 16 bit number for all four protocols, and is used to directly * index into a list of upper streams. With the upper stream in * hand, we verify that this is the right stream and deliver the * data. * * L2TP has a Tunnel ID, which represents a bundle of PPP * sessions between the peers. Because we always assign unique * session ID numbers, we merely check that the given ID matches * the assigned ID for the upper stream. * * L2F has a Multiplex ID, which is unique per connection. It * does not have L2TP's concept of multiple-connections-within- * a-tunnel. The same checking is done. * * PPPoE is a horribly broken protocol. Only one ID is assigned * per connection. The client must somehow demultiplex based on * an ID number assigned by the server. It's not necessarily * unique. The search is done based on {ID,peerEthernet} (using * tcl_rsessid) for all packet types except PADI and PADS. * * Neither PPPoE nor PPTP supports additional ID numbers. * * Both L2F and L2TP come in over UDP. They are distinguished by * looking at the GRE version field -- 001 for L2F and 010 for * L2TP. */ static queue_t * sppptun_recv(queue_t *q, mblk_t **mpp, const void *srcaddr) { mblk_t *mp; tunll_t *tll; tuncl_t *tcl; int sessid; int remlen; int msglen; int isdata; int i; const uchar_t *ucp; const poep_t *poep; mblk_t *mnew; ppptun_atype *pap; mp = *mpp; tll = q->q_ptr; ASSERT(!(tll->tll_flags & TLLF_NOTLOWER)); tcl = NULL; switch (tll->tll_style) { case PTS_PPPOE: /* Note that poep_t alignment is uint16_t */ if ((!IS_P2ALIGNED(mp->b_rptr, sizeof (uint16_t)) || MBLKL(mp) < sizeof (poep_t)) && !pullupmsg(mp, sizeof (poep_t))) break; poep = (const poep_t *)mp->b_rptr; if (poep->poep_version_type != POE_VERSION) break; /* * First, extract a session ID number. All protocols have * this. */ isdata = (poep->poep_code == POECODE_DATA); sessid = ntohs(poep->poep_session_id); remlen = sizeof (*poep); msglen = ntohs(poep->poep_length); i = poep->poep_code; if (i == POECODE_PADI || i == POECODE_PADR) { /* These go to the server daemon only. */ tcl = tll->tll_defcl; } else if (i == POECODE_PADO || i == POECODE_PADS) { /* * These go to a client only, and are demuxed * by the Host-Uniq field (into which we stuff * our local ID number when generating * PADI/PADR). */ ucp = (const uchar_t *)(poep + 1); i = msglen; while (i > POET_HDRLEN) { if (POET_GET_TYPE(ucp) == POETT_END) { i = 0; break; } if (POET_GET_TYPE(ucp) == POETT_UNIQ && POET_GET_LENG(ucp) >= sizeof (uint32_t)) break; i -= POET_GET_LENG(ucp) + POET_HDRLEN; ucp = POET_NEXT(ucp); } if (i >= POET_HDRLEN + 4) sessid = GETLONG(ucp + POET_HDRLEN); tcl = tcl_by_minor((minor_t)sessid); } else { /* * Try minor number as session ID first, since * it's used that way on server side. It's * not used that way on the client, though, so * this might not work. If this isn't the * right one, then try the tll cache. If * neither is right, then search all open * clients. Did I mention that the PPPoE * protocol is badly designed? */ tcl = tcl_by_minor((minor_t)sessid); if (tcl == NULL || (!isdata && tcl->tcl_ctrl_tll != tll) || (isdata && tcl->tcl_data_tll != tll) || sessid != tcl->tcl_rsessid || bcmp(srcaddr, tcl->tcl_address.pta_pppoe.ptma_mac, sizeof (tcl->tcl_address.pta_pppoe.ptma_mac)) != 0) tcl = tll->tll_lastcl; if (tcl == NULL || (!isdata && tcl->tcl_ctrl_tll != tll) || (isdata && tcl->tcl_data_tll != tll) || sessid != tcl->tcl_rsessid || bcmp(srcaddr, tcl->tcl_address.pta_pppoe.ptma_mac, sizeof (tcl->tcl_address.pta_pppoe.ptma_mac)) != 0) tcl = NULL; if (tcl == NULL && sessid != 0) { struct poedat poedat; /* * Slow mode. Too bad. If you don't like it, * you can always choose a better protocol. */ poedat.sessid = sessid; poedat.tll = tll; poedat.srcaddr = srcaddr; poedat.tcl = NULL; poedat.isdata = isdata; vmem_walk(tcl_minor_arena, VMEM_ALLOC, tclvm_pppoe_search, &poedat); KLINCR(lks_walks); if ((tcl = poedat.tcl) != NULL) { tll->tll_lastcl = tcl; KCINCR(cks_walks); } } } break; } if (tcl == NULL || tcl->tcl_rq == NULL) { DTRACE_PROBE3(sppptun__recv__discard, int, sessid, tuncl_t *, tcl, mblk_t *, mp); if (tcl == NULL) { KLINCR(lks_in_nomatch); } if (isdata) { KLINCR(lks_indata_drops); if (tcl != NULL) tcl->tcl_stats.ppp_ierrors++; } else { KLINCR(lks_inctrl_drops); if (tcl != NULL) { KCINCR(cks_inctrl_drops); } } freemsg(mp); return (NULL); } if (tcl->tcl_data_tll == tll && isdata) { if (!adjmsg(mp, remlen) || (i = msgsize(mp)) < msglen || (i > msglen && !adjmsg(mp, msglen - i))) { KLINCR(lks_indata_drops); tcl->tcl_stats.ppp_ierrors++; freemsg(mp); return (NULL); } /* XXX -- address/control handling in pppd needs help. */ if (*mp->b_rptr != 0xFF) { if ((mp = prependb(mp, 2, 1)) == NULL) { KLINCR(lks_indata_drops); tcl->tcl_stats.ppp_ierrors++; return (NULL); } mp->b_rptr[0] = 0xFF; mp->b_rptr[1] = 0x03; } MTYPE(mp) = M_DATA; tcl->tcl_stats.ppp_ibytes += msgsize(mp); tcl->tcl_stats.ppp_ipackets++; KLINCR(lks_indata); } else { if (isdata || tcl->tcl_ctrl_tll != tll || (mnew = make_control(tcl, tll, PTCA_CONTROL, tcl)) == NULL) { KLINCR(lks_inctrl_drops); KCINCR(cks_inctrl_drops); freemsg(mp); return (NULL); } /* Fix up source address; peer might not be set yet. */ pap = &((struct ppptun_control *)mnew->b_rptr)->ptc_address; bcopy(srcaddr, pap->pta_pppoe.ptma_mac, sizeof (pap->pta_pppoe.ptma_mac)); mnew->b_cont = mp; mp = mnew; KLINCR(lks_inctrls); KCINCR(cks_inctrls); } *mpp = mp; return (tcl->tcl_rq); } /* * sppptun_urput() * * MT-Perimeters: * shared inner, shared outer. * * Description: * Upper read-side put procedure. Messages from the underlying * lower stream driver arrive here. See sppptun_recv for the * demultiplexing logic. */ static void sppptun_urput(queue_t *q, mblk_t *mp) { union DL_primitives *dlprim; mblk_t *mpnext; tunll_t *tll; queue_t *nextq; tll = q->q_ptr; ASSERT(!(tll->tll_flags & TLLF_NOTLOWER)); switch (MTYPE(mp)) { case M_DATA: /* * When we're bound over IP, data arrives here. The * packet starts with the IP header itself. */ if ((nextq = sppptun_recv(q, &mp, NULL)) != NULL) putnext(nextq, mp); break; case M_PROTO: case M_PCPROTO: /* Data arrives here for UDP or raw Ethernet, not IP. */ switch (tll->tll_style) { /* PPTP control messages are over TCP only. */ case PTS_PPTP: default: ASSERT(0); /* how'd that happen? */ break; case PTS_PPPOE: /* DLPI message */ if (MBLKL(mp) < sizeof (t_uscalar_t)) break; dlprim = (union DL_primitives *)mp->b_rptr; switch (dlprim->dl_primitive) { case DL_UNITDATA_IND: { size_t mlen = MBLKL(mp); if (mlen < DL_UNITDATA_IND_SIZE) break; if (dlprim->unitdata_ind.dl_src_addr_offset < DL_UNITDATA_IND_SIZE || dlprim->unitdata_ind.dl_src_addr_offset + dlprim->unitdata_ind.dl_src_addr_length > mlen) break; } /* FALLTHROUGH */ case DL_UNITDATA_REQ: /* For loopback support. */ if (dlprim->dl_primitive == DL_UNITDATA_REQ && MBLKL(mp) < DL_UNITDATA_REQ_SIZE) break; if ((mpnext = mp->b_cont) == NULL) break; MTYPE(mpnext) = M_DATA; nextq = sppptun_recv(q, &mpnext, dlprim->dl_primitive == DL_UNITDATA_IND ? mp->b_rptr + dlprim->unitdata_ind.dl_src_addr_offset : tll->tll_lcladdr.pta_pppoe.ptma_mac); if (nextq != NULL) putnext(nextq, mpnext); freeb(mp); return; default: urput_dlpi(q, mp); return; } break; } freemsg(mp); break; default: freemsg(mp); break; } } /* * sppptun_ursrv() * * MT-Perimeters: * exclusive inner, shared outer. * * Description: * Upper read-side service procedure. This procedure services the * client streams. We get here because the client (PPP) asserts * flow control down to us. */ static int sppptun_ursrv(queue_t *q) { mblk_t *mp; ASSERT(q->q_ptr != NULL); while ((mp = getq(q)) != NULL) { if (canputnext(q)) { putnext(q, mp); } else { (void) putbq(q, mp); break; } } return (0); } /* * Dummy constructor/destructor functions for kmem_cache_create. * We're just using kmem as an allocator of integers, not real * storage. */ /*ARGSUSED*/ static int tcl_constructor(void *maddr, void *arg, int kmflags) { return (0); } /*ARGSUSED*/ static void tcl_destructor(void *maddr, void *arg) { } /* * Total size occupied by one tunnel client. Each tunnel client * consumes one pointer for tcl_slots array, one tuncl_t structure and * two messages preallocated for close. */ #define TUNCL_SIZE (sizeof (tuncl_t) + sizeof (tuncl_t *) + \ 2 * sizeof (dblk_t)) /* * Clear all bits of x except the highest bit */ #define truncate(x) ((x) <= 2 ? (x) : (1 << (highbit(x) - 1))) /* * This function initializes some well-known global variables inside * the module. * * Called by sppptun_mod.c:_init() before installing the module. */ void sppptun_init(void) { tunll_list.q_forw = tunll_list.q_back = &tunll_list; } /* * This function allocates the initial internal storage for the * sppptun driver. * * Called by sppptun_mod.c:_init() after installing module. */ void sppptun_tcl_init(void) { uint_t i, j; rw_init(&tcl_rwlock, NULL, RW_DRIVER, NULL); rw_enter(&tcl_rwlock, RW_WRITER); tcl_nslots = sppptun_init_cnt; tcl_slots = kmem_zalloc(tcl_nslots * sizeof (tuncl_t *), KM_SLEEP); tcl_cache = kmem_cache_create("sppptun_map", sizeof (tuncl_t), 0, tcl_constructor, tcl_destructor, NULL, NULL, NULL, 0); /* Allocate integer space for minor numbers */ tcl_minor_arena = vmem_create("sppptun_minor", (void *)1, tcl_nslots, 1, NULL, NULL, NULL, 0, VM_SLEEP | VMC_IDENTIFIER); /* * Calculate available number of tunnels - how many tunnels * can we allocate in sppptun_pctofmem % of available * memory. The value is rounded up to the nearest power of 2. */ i = (sppptun_pctofmem * kmem_maxavail()) / (100 * TUNCL_SIZE); j = truncate(i); /* i with non-high bits stripped */ if (i != j) j *= 2; tcl_minormax = j; rw_exit(&tcl_rwlock); } /* * This function checks that there are no plumbed streams or other users. * * Called by sppptun_mod.c:_fini(). Assumes that we're exclusive on * both perimeters. */ int sppptun_tcl_fintest(void) { if (tunll_list.q_forw != &tunll_list || tcl_inuse > 0) return (EBUSY); else return (0); } /* * If no lower streams are plumbed, then this function deallocates all * internal storage in preparation for unload. * * Called by sppptun_mod.c:_fini(). Assumes that we're exclusive on * both perimeters. */ void sppptun_tcl_fini(void) { if (tcl_minor_arena != NULL) { vmem_destroy(tcl_minor_arena); tcl_minor_arena = NULL; } if (tcl_cache != NULL) { kmem_cache_destroy(tcl_cache); tcl_cache = NULL; } kmem_free(tcl_slots, tcl_nslots * sizeof (tuncl_t *)); tcl_slots = NULL; rw_destroy(&tcl_rwlock); ASSERT(tcl_slots == NULL); ASSERT(tcl_cache == NULL); ASSERT(tcl_minor_arena == NULL); }