/* * 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 2010 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 "sctp_impl.h" #include "sctp_asconf.h" #include "sctp_addr.h" typedef struct sctp_asconf_s { mblk_t *head; uint32_t cid; } sctp_asconf_t; /* * This is only used on a clustered node to maintain pre-allocated buffer info. * before sending an ASCONF chunk. The reason for pre-allocation is we don't * want to fail allocating memory when we get then ASCONF-ACK in order to * update the clustering subsystem's state for this assoc. */ typedef struct sctp_cl_ainfo_s { uchar_t *sctp_cl_alist; size_t sctp_cl_asize; uchar_t *sctp_cl_dlist; size_t sctp_cl_dsize; } sctp_cl_ainfo_t; /* * The ASCONF chunk per-parameter request interface. ph is the * parameter header for the parameter in the request, and cid * is the parameters correlation ID. cont should be set to 1 * if the ASCONF framework should continue processing request * parameters following this one, or 0 if it should stop. If * cont is -1, this indicates complete memory depletion, which * will cause the ASCONF framework to abort building a reply. If * act is 1, the callback should take whatever action it needs * to fulfil this request. If act is 0, this request has already * been processed, so the callback should only verify and pass * back error parameters, and not take any action. * * The callback should return an mblk with any reply enclosed, * with the correlation ID in the first four bytes of the * message. A NULL return implies implicit success to the * requestor. */ typedef mblk_t *sctp_asconf_func_t(sctp_t *, sctp_parm_hdr_t *ph, uint32_t cid, sctp_faddr_t *, int *cont, int act, in6_addr_t *addr); /* * The ASCONF chunk per-parameter ACK interface. ph is the parameter * header for the parameter returned in the ACK, and oph is the * original parameter sent out in the ASCONF request. * If the peer implicitly responded OK (by not including an * explicit OK for the request), ph will be NULL. * ph can also point to an Unrecognized Parameter parameter, * in which case the peer did not understand the request * parameter. * * ph and oph parameter headers are in host byte order. Encapsulated * parameters will still be in network byte order. */ typedef void sctp_asconf_ack_func_t(sctp_t *, sctp_parm_hdr_t *ph, sctp_parm_hdr_t *oph, sctp_faddr_t *, in6_addr_t *addr); typedef struct { uint16_t id; sctp_asconf_func_t *asconf; sctp_asconf_ack_func_t *asconf_ack; } dispatch_t; static sctp_asconf_func_t sctp_addip_req, sctp_setprim_req, sctp_asconf_unrec_parm; static sctp_asconf_ack_func_t sctp_addip_ack, sctp_setprim_ack, sctp_asconf_ack_unrec_parm; static const dispatch_t sctp_asconf_dispatch_tbl[] = { /* ID ASCONF ASCONF_ACK */ { PARM_ADD_IP, sctp_addip_req, sctp_addip_ack }, { PARM_DEL_IP, sctp_addip_req, sctp_addip_ack }, { PARM_SET_PRIMARY, sctp_setprim_req, sctp_setprim_ack } }; static const dispatch_t sctp_asconf_default_dispatch = { 0, sctp_asconf_unrec_parm, sctp_asconf_ack_unrec_parm }; /* * ASCONF framework */ static const dispatch_t * sctp_lookup_asconf_dispatch(int id) { int i; for (i = 0; i < A_CNT(sctp_asconf_dispatch_tbl); i++) { if (sctp_asconf_dispatch_tbl[i].id == id) { return (sctp_asconf_dispatch_tbl + i); } } return (&sctp_asconf_default_dispatch); } /* * Frees mp on failure */ static mblk_t * sctp_asconf_prepend_errwrap(mblk_t *mp, uint32_t cid) { mblk_t *wmp; sctp_parm_hdr_t *wph; /* Prepend a wrapper err cause ind param */ wmp = allocb(sizeof (*wph) + sizeof (cid), BPRI_MED); if (wmp == NULL) { freemsg(mp); return (NULL); } wmp->b_wptr += sizeof (*wph) + sizeof (cid); wph = (sctp_parm_hdr_t *)wmp->b_rptr; wph->sph_type = htons(PARM_ERROR_IND); wph->sph_len = htons(msgdsize(mp) + sizeof (*wph) + sizeof (cid)); bcopy(&cid, wph + 1, sizeof (uint32_t)); wmp->b_cont = mp; return (wmp); } /*ARGSUSED*/ static mblk_t * sctp_asconf_unrec_parm(sctp_t *sctp, sctp_parm_hdr_t *ph, uint32_t cid, sctp_faddr_t *fp, int *cont, int act, in6_addr_t *addr) { mblk_t *mp = NULL; /* Unrecognized param; check the high order bits */ if ((ph->sph_type & SCTP_UNREC_PARAM_MASK) == (SCTP_CONT_PROC_PARAMS | SCTP_REPORT_THIS_PARAM)) { /* report unrecognized param, and keep processing */ sctp_add_unrec_parm(ph, &mp, B_FALSE); if (mp == NULL) { *cont = -1; return (NULL); } /* Prepend a the CID and a wrapper err cause ind param */ mp = sctp_asconf_prepend_errwrap(mp, cid); if (mp == NULL) { *cont = -1; return (NULL); } *cont = 1; return (mp); } if (ph->sph_type & SCTP_REPORT_THIS_PARAM) { /* Stop processing and drop; report unrecognized param */ sctp_add_unrec_parm(ph, &mp, B_FALSE); if (mp == NULL) { *cont = -1; return (NULL); } /* Prepend a the CID and a wrapper err cause ind param */ mp = sctp_asconf_prepend_errwrap(mp, cid); if (mp == NULL) { *cont = -1; return (NULL); } *cont = 0; return (mp); } if (ph->sph_type & SCTP_CONT_PROC_PARAMS) { /* skip and continue processing */ *cont = 1; return (NULL); } /* 2 high bits are clear; stop processing and drop packet */ *cont = 0; return (NULL); } /*ARGSUSED*/ static void sctp_asconf_ack_unrec_parm(sctp_t *sctp, sctp_parm_hdr_t *ph, sctp_parm_hdr_t *oph, sctp_faddr_t *fp, in6_addr_t *laddr) { ASSERT(ph); sctp_error_event(sctp, (sctp_chunk_hdr_t *)ph, B_TRUE); } static void sctp_asconf_init(sctp_asconf_t *asc) { ASSERT(asc != NULL); asc->head = NULL; asc->cid = 0; } static int sctp_asconf_add(sctp_asconf_t *asc, mblk_t *mp) { uint32_t *cp; /* XXX can't exceed MTU */ cp = (uint32_t *)(mp->b_rptr + sizeof (sctp_parm_hdr_t)); *cp = asc->cid++; if (asc->head == NULL) asc->head = mp; else linkb(asc->head, mp); return (0); } static void sctp_asconf_destroy(sctp_asconf_t *asc) { if (asc->head != NULL) { freemsg(asc->head); asc->head = NULL; } asc->cid = 0; } static int sctp_asconf_send(sctp_t *sctp, sctp_asconf_t *asc, sctp_faddr_t *fp, sctp_cl_ainfo_t *ainfo) { mblk_t *mp, *nmp; sctp_chunk_hdr_t *ch; boolean_t isv4; size_t msgsize; ASSERT(asc != NULL && asc->head != NULL); isv4 = (fp != NULL) ? fp->isv4 : sctp->sctp_current->isv4; /* SCTP chunk header + Serial Number + Address Param TLV */ msgsize = sizeof (*ch) + sizeof (uint32_t) + (isv4 ? PARM_ADDR4_LEN : PARM_ADDR6_LEN); mp = allocb(msgsize, BPRI_MED); if (mp == NULL) return (ENOMEM); mp->b_wptr += msgsize; mp->b_cont = asc->head; ch = (sctp_chunk_hdr_t *)mp->b_rptr; ch->sch_id = CHUNK_ASCONF; ch->sch_flags = 0; ch->sch_len = htons(msgdsize(mp)); nmp = msgpullup(mp, -1); if (nmp == NULL) { freeb(mp); return (ENOMEM); } /* * Stash the address list and the count so that when the operation * completes, i.e. when as get an ACK, we can update the clustering's * state for this association. */ if (ainfo != NULL) { ASSERT(cl_sctp_assoc_change != NULL); ASSERT(nmp->b_prev == NULL); nmp->b_prev = (mblk_t *)ainfo; } /* Clean up the temporary mblk chain */ freemsg(mp); asc->head = NULL; asc->cid = 0; /* Queue it ... */ if (sctp->sctp_cxmit_list == NULL) { sctp->sctp_cxmit_list = nmp; } else { linkb(sctp->sctp_cxmit_list, nmp); } BUMP_LOCAL(sctp->sctp_obchunks); /* And try to send it. */ sctp_wput_asconf(sctp, fp); return (0); } /* * If the peer does not understand an ASCONF chunk, we simply * clear out the cxmit_list, since we can send nothing further * that the peer will understand. * * Assumes chunk length has already been checked. */ /*ARGSUSED*/ void sctp_asconf_free_cxmit(sctp_t *sctp, sctp_chunk_hdr_t *ch) { mblk_t *mp; mblk_t *mp1; sctp_cl_ainfo_t *ainfo; if (sctp->sctp_cxmit_list == NULL) { /* Nothing pending */ return; } mp = sctp->sctp_cxmit_list; while (mp != NULL) { mp1 = mp->b_cont; mp->b_cont = NULL; if (mp->b_prev != NULL) { ainfo = (sctp_cl_ainfo_t *)mp->b_prev; mp->b_prev = NULL; kmem_free(ainfo->sctp_cl_alist, ainfo->sctp_cl_asize); kmem_free(ainfo->sctp_cl_dlist, ainfo->sctp_cl_dsize); kmem_free(ainfo, sizeof (*ainfo)); } freeb(mp); mp = mp1; } sctp->sctp_cxmit_list = NULL; } void sctp_input_asconf(sctp_t *sctp, sctp_chunk_hdr_t *ch, sctp_faddr_t *fp) { const dispatch_t *dp; mblk_t *hmp; mblk_t *mp; uint32_t *idp; uint32_t *hidp; ssize_t rlen; sctp_parm_hdr_t *ph; sctp_chunk_hdr_t *ach; int cont; int act; uint16_t plen; uchar_t *alist = NULL; size_t asize = 0; uchar_t *dlist = NULL; size_t dsize = 0; uchar_t *aptr = NULL; uchar_t *dptr = NULL; int acount = 0; int dcount = 0; sctp_stack_t *sctps = sctp->sctp_sctps; ASSERT(ch->sch_id == CHUNK_ASCONF); idp = (uint32_t *)(ch + 1); rlen = ntohs(ch->sch_len) - sizeof (*ch) - sizeof (*idp); if (rlen < 0 || rlen < sizeof (*idp)) { /* nothing there; bail out */ return; } /* Check for duplicates */ *idp = ntohl(*idp); if (*idp == (sctp->sctp_fcsn + 1)) { act = 1; } else if (*idp == sctp->sctp_fcsn) { act = 0; } else { /* stale or malicious packet; drop */ return; } /* Create the ASCONF_ACK header */ hmp = sctp_make_mp(sctp, fp, sizeof (*ach) + sizeof (*idp)); if (hmp == NULL) { /* Let the peer retransmit */ SCTP_KSTAT(sctps, sctp_send_asconf_ack_failed); return; } ach = (sctp_chunk_hdr_t *)hmp->b_wptr; ach->sch_id = CHUNK_ASCONF_ACK; ach->sch_flags = 0; /* Set the length later */ hidp = (uint32_t *)(ach + 1); *hidp = htonl(*idp); hmp->b_wptr = (uchar_t *)(hidp + 1); /* Move to the Address Parameter */ ph = (sctp_parm_hdr_t *)(idp + 1); if (rlen <= ntohs(ph->sph_len)) { freeb(hmp); return; } /* * We already have the association here, so this address parameter * doesn't seem to be very useful, should we make sure this is part * of the association and send an error, if not? * Ignore it for now. */ rlen -= ntohs(ph->sph_len); ph = (sctp_parm_hdr_t *)((char *)ph + ntohs(ph->sph_len)); /* * We need to pre-allocate buffer before processing the ASCONF * chunk. We don't want to fail allocating buffers after processing * the ASCONF chunk. So, we walk the list and get the number of * addresses added and/or deleted. */ if (cl_sctp_assoc_change != NULL) { sctp_parm_hdr_t *oph = ph; ssize_t orlen = rlen; /* * This not very efficient, but there is no better way of * doing it. It should be fine since normally the param list * will not be very long. */ while (orlen > 0) { /* Sanity checks */ if (orlen < sizeof (*oph)) break; plen = ntohs(oph->sph_len); if (plen < sizeof (*oph) || plen > orlen) break; if (oph->sph_type == htons(PARM_ADD_IP)) acount++; if (oph->sph_type == htons(PARM_DEL_IP)) dcount++; oph = sctp_next_parm(oph, &orlen); if (oph == NULL) break; } if (acount > 0 || dcount > 0) { if (acount > 0) { asize = sizeof (in6_addr_t) * acount; alist = kmem_alloc(asize, KM_NOSLEEP); if (alist == NULL) { freeb(hmp); SCTP_KSTAT(sctps, sctp_cl_assoc_change); return; } } if (dcount > 0) { dsize = sizeof (in6_addr_t) * dcount; dlist = kmem_alloc(dsize, KM_NOSLEEP); if (dlist == NULL) { if (acount > 0) kmem_free(alist, asize); freeb(hmp); SCTP_KSTAT(sctps, sctp_cl_assoc_change); return; } } aptr = alist; dptr = dlist; /* * We will get the actual count when we process * the chunk. */ acount = 0; dcount = 0; } } cont = 1; while (rlen > 0 && cont) { in6_addr_t addr; /* Sanity checks */ if (rlen < sizeof (*ph)) break; plen = ntohs(ph->sph_len); if (plen < sizeof (*ph) || plen > rlen) { break; } idp = (uint32_t *)(ph + 1); dp = sctp_lookup_asconf_dispatch(ntohs(ph->sph_type)); ASSERT(dp); if (dp->asconf) { mp = dp->asconf(sctp, ph, *idp, fp, &cont, act, &addr); if (cont == -1) { /* * Not even enough memory to create * an out-of-resources error. Free * everything and return; the peer * should retransmit. */ freemsg(hmp); if (alist != NULL) kmem_free(alist, asize); if (dlist != NULL) kmem_free(dlist, dsize); return; } if (mp != NULL) { linkb(hmp, mp); } else if (act != 0) { /* update the add/delete list */ if (cl_sctp_assoc_change != NULL) { if (ph->sph_type == htons(PARM_ADD_IP)) { ASSERT(alist != NULL); bcopy(&addr, aptr, sizeof (addr)); aptr += sizeof (addr); acount++; } else if (ph->sph_type == htons(PARM_DEL_IP)) { ASSERT(dlist != NULL); bcopy(&addr, dptr, sizeof (addr)); dptr += sizeof (addr); dcount++; } } } } ph = sctp_next_parm(ph, &rlen); if (ph == NULL) break; } /* * Update clustering's state for this assoc. Note acount/dcount * could be zero (i.e. if the add/delete address(es) were not * processed successfully). Regardless, if the ?size is > 0, * it is the clustering module's responsibility to free the lists. */ if (cl_sctp_assoc_change != NULL) { (*cl_sctp_assoc_change)(sctp->sctp_connp->conn_family, alist, asize, acount, dlist, dsize, dcount, SCTP_CL_PADDR, (cl_sctp_handle_t)sctp); /* alist and dlist will be freed by the clustering module */ } /* Now that the params have been processed, increment the fcsn */ if (act) { sctp->sctp_fcsn++; } BUMP_LOCAL(sctp->sctp_obchunks); if (fp->isv4) ach->sch_len = htons(msgdsize(hmp) - sctp->sctp_hdr_len); else ach->sch_len = htons(msgdsize(hmp) - sctp->sctp_hdr6_len); sctp_set_iplen(sctp, hmp, fp->ixa); (void) conn_ip_output(hmp, fp->ixa); BUMP_LOCAL(sctp->sctp_opkts); sctp_validate_peer(sctp); } static sctp_parm_hdr_t * sctp_lookup_asconf_param(sctp_parm_hdr_t *ph, uint32_t cid, ssize_t rlen) { uint32_t *idp; while (rlen > 0) { idp = (uint32_t *)(ph + 1); if (*idp == cid) { return (ph); } ph = sctp_next_parm(ph, &rlen); if (ph == NULL) break; } return (NULL); } void sctp_input_asconf_ack(sctp_t *sctp, sctp_chunk_hdr_t *ch, sctp_faddr_t *fp) { const dispatch_t *dp; uint32_t *idp; uint32_t *snp; ssize_t rlen; ssize_t plen; sctp_parm_hdr_t *ph; sctp_parm_hdr_t *oph; sctp_parm_hdr_t *fph; mblk_t *mp; sctp_chunk_hdr_t *och; int redosrcs = 0; uint16_t param_len; uchar_t *alist; uchar_t *dlist; uint_t acount = 0; uint_t dcount = 0; uchar_t *aptr; uchar_t *dptr; sctp_cl_ainfo_t *ainfo; in6_addr_t addr; ASSERT(ch->sch_id == CHUNK_ASCONF_ACK); snp = (uint32_t *)(ch + 1); rlen = ntohs(ch->sch_len) - sizeof (*ch) - sizeof (*snp); if (rlen < 0) { return; } /* Accept only an ACK for the current serial number */ *snp = ntohl(*snp); if (sctp->sctp_cxmit_list == NULL || *snp != (sctp->sctp_lcsn - 1)) { /* Need to send an abort */ return; } sctp->sctp_cchunk_pend = 0; SCTP_FADDR_RC_TIMER_STOP(fp); mp = sctp->sctp_cxmit_list; /* * We fill in the addresses here to update the clustering's state for * this assoc. */ if (mp != NULL && cl_sctp_assoc_change != NULL) { ASSERT(mp->b_prev != NULL); ainfo = (sctp_cl_ainfo_t *)mp->b_prev; alist = ainfo->sctp_cl_alist; dlist = ainfo->sctp_cl_dlist; aptr = alist; dptr = dlist; } /* * Pass explicit replies to callbacks: * For each reply in the ACK, look up the corresponding * original parameter in the request using the correlation * ID, and pass it to the right callback. */ och = (sctp_chunk_hdr_t *)sctp->sctp_cxmit_list->b_rptr; plen = ntohs(och->sch_len) - sizeof (*och) - sizeof (*idp); idp = (uint32_t *)(och + 1); /* Get to the 1st ASCONF param, need to skip Address TLV parm */ fph = (sctp_parm_hdr_t *)(idp + 1); plen -= ntohs(fph->sph_len); fph = (sctp_parm_hdr_t *)((char *)fph + ntohs(fph->sph_len)); ph = (sctp_parm_hdr_t *)(snp + 1); while (rlen > 0) { /* Sanity checks */ if (rlen < sizeof (*ph)) { break; } param_len = ntohs(ph->sph_len); if (param_len < sizeof (*ph) || param_len > rlen) { break; } idp = (uint32_t *)(ph + 1); oph = sctp_lookup_asconf_param(fph, *idp, plen); if (oph != NULL) { dp = sctp_lookup_asconf_dispatch(ntohs(oph->sph_type)); ASSERT(dp); if (dp->asconf_ack) { dp->asconf_ack(sctp, ph, oph, fp, &addr); /* hack. see below */ if (oph->sph_type == htons(PARM_ADD_IP) || oph->sph_type == htons(PARM_DEL_IP)) { redosrcs = 1; /* * If the address was sucessfully * processed, add it to the add/delete * list to send to the clustering * module. */ if (cl_sctp_assoc_change != NULL && !SCTP_IS_ADDR_UNSPEC( IN6_IS_ADDR_V4MAPPED(&addr), addr)) { if (oph->sph_type == htons(PARM_ADD_IP)) { bcopy(&addr, aptr, sizeof (addr)); aptr += sizeof (addr); acount++; } else { bcopy(&addr, dptr, sizeof (addr)); dptr += sizeof (addr); dcount++; } } } } } ph = sctp_next_parm(ph, &rlen); if (ph == NULL) break; } /* * Pass implicit replies to callbacks: * For each original request, look up its parameter * in the ACK. If there is no corresponding reply, * call the callback with a NULL parameter, indicating * success. */ rlen = plen; plen = ntohs(ch->sch_len) - sizeof (*ch) - sizeof (*idp); oph = fph; fph = (sctp_parm_hdr_t *)((char *)ch + sizeof (sctp_chunk_hdr_t) + sizeof (uint32_t)); while (rlen > 0) { idp = (uint32_t *)(oph + 1); ph = sctp_lookup_asconf_param(fph, *idp, plen); if (ph == NULL) { dp = sctp_lookup_asconf_dispatch(ntohs(oph->sph_type)); ASSERT(dp); if (dp->asconf_ack) { dp->asconf_ack(sctp, NULL, oph, fp, &addr); /* hack. see below */ if (oph->sph_type == htons(PARM_ADD_IP) || oph->sph_type == htons(PARM_DEL_IP)) { redosrcs = 1; /* * If the address was sucessfully * processed, add it to the add/delete * list to send to the clustering * module. */ if (cl_sctp_assoc_change != NULL && !SCTP_IS_ADDR_UNSPEC( IN6_IS_ADDR_V4MAPPED(&addr), addr)) { if (oph->sph_type == htons(PARM_ADD_IP)) { bcopy(&addr, aptr, sizeof (addr)); aptr += sizeof (addr); acount++; } else { bcopy(&addr, dptr, sizeof (addr)); dptr += sizeof (addr); dcount++; } } } } } oph = sctp_next_parm(oph, &rlen); if (oph == NULL) { break; } } /* We can now free up the first chunk in the cxmit list */ sctp->sctp_cxmit_list = mp->b_cont; mp->b_cont = NULL; fp = SCTP_CHUNK_DEST(mp); ASSERT(fp != NULL && fp->suna >= MBLKL(mp)); fp->suna -= MBLKL(mp); /* * Update clustering's state for this assoc. Note acount/dcount * could be zero (i.e. if the add/delete address(es) did not * succeed). Regardless, if the ?size is > 0, it is the clustering * module's responsibility to free the lists. */ if (cl_sctp_assoc_change != NULL) { ASSERT(mp->b_prev != NULL); mp->b_prev = NULL; ainfo->sctp_cl_alist = NULL; ainfo->sctp_cl_dlist = NULL; (*cl_sctp_assoc_change)(sctp->sctp_connp->conn_family, alist, ainfo->sctp_cl_asize, acount, dlist, ainfo->sctp_cl_dsize, dcount, SCTP_CL_LADDR, (cl_sctp_handle_t)sctp); /* alist and dlist will be freed by the clustering module */ ainfo->sctp_cl_asize = 0; ainfo->sctp_cl_dsize = 0; kmem_free(ainfo, sizeof (*ainfo)); } freeb(mp); /* can now send the next control chunk */ if (sctp->sctp_cxmit_list != NULL) sctp_wput_asconf(sctp, NULL); /* * If an add-ip or del-ip has completed (successfully or * unsuccessfully), the pool of available source addresses * may have changed, so we need to redo faddr source * address selections. This is a bit of a hack since * this really belongs in the add/del-ip code. However, * that code consists of callbacks called for *each* * add/del-ip parameter, and sctp_redo_faddr_srcs() is * expensive enough that we really don't want to be * doing it for each one. So we do it once here. */ if (redosrcs) sctp_redo_faddr_srcs(sctp); } static void sctp_rc_timer(sctp_t *sctp, sctp_faddr_t *fp) { #define SCTP_CLR_SENT_FLAG(mp) ((mp)->b_flag &= ~SCTP_CHUNK_FLAG_SENT) sctp_faddr_t *nfp; sctp_faddr_t *ofp; sctp_stack_t *sctps = sctp->sctp_sctps; ASSERT(fp != NULL); fp->rc_timer_running = 0; if (sctp->sctp_state != SCTPS_ESTABLISHED || sctp->sctp_cxmit_list == NULL) { return; } /* * Not a retransmission, this was deferred due to some error * condition */ if (!SCTP_CHUNK_ISSENT(sctp->sctp_cxmit_list)) { sctp_wput_asconf(sctp, fp); return; } /* * The sent flag indicates if the msg has been sent on this fp. */ SCTP_CLR_SENT_FLAG(sctp->sctp_cxmit_list); /* Retransmission */ if (sctp->sctp_strikes >= sctp->sctp_pa_max_rxt) { /* time to give up */ BUMP_MIB(&sctps->sctps_mib, sctpAborted); sctp_assoc_event(sctp, SCTP_COMM_LOST, 0, NULL); sctp_clean_death(sctp, ETIMEDOUT); return; } if (fp->strikes >= fp->max_retr) { if (sctp_faddr_dead(sctp, fp, SCTP_FADDRS_DOWN) == -1) return; } fp->strikes++; sctp->sctp_strikes++; SCTP_CALC_RXT(sctp, fp); nfp = sctp_rotate_faddr(sctp, fp); sctp->sctp_cchunk_pend = 0; ofp = SCTP_CHUNK_DEST(sctp->sctp_cxmit_list); SCTP_SET_CHUNK_DEST(sctp->sctp_cxmit_list, NULL); ASSERT(ofp != NULL && ofp == fp); ASSERT(ofp->suna >= MBLKL(sctp->sctp_cxmit_list)); /* * Enter slow start for this destination. * XXX anything in the data path that needs to be considered? */ ofp->ssthresh = ofp->cwnd / 2; if (ofp->ssthresh < 2 * ofp->sfa_pmss) ofp->ssthresh = 2 * ofp->sfa_pmss; ofp->cwnd = ofp->sfa_pmss; ofp->pba = 0; ofp->suna -= MBLKL(sctp->sctp_cxmit_list); /* * The rexmit flags is used to determine if a serial number needs to * be assigned or not, so once set we leave it there. */ if (!SCTP_CHUNK_WANT_REXMIT(sctp->sctp_cxmit_list)) SCTP_CHUNK_REXMIT(sctp->sctp_cxmit_list); sctp_wput_asconf(sctp, nfp); #undef SCTP_CLR_SENT_FLAG } void sctp_wput_asconf(sctp_t *sctp, sctp_faddr_t *fp) { #define SCTP_SET_SENT_FLAG(mp) ((mp)->b_flag = SCTP_CHUNK_FLAG_SENT) mblk_t *mp; mblk_t *ipmp; uint32_t *snp; sctp_parm_hdr_t *ph; boolean_t isv4; sctp_stack_t *sctps = sctp->sctp_sctps; boolean_t saddr_set; if (sctp->sctp_cchunk_pend || sctp->sctp_cxmit_list == NULL || /* Queue it for later transmission if not yet established */ sctp->sctp_state < SCTPS_ESTABLISHED) { ip2dbg(("sctp_wput_asconf: cchunk pending? (%d) or null "\ "sctp_cxmit_list? (%s) or incorrect state? (%x)\n", sctp->sctp_cchunk_pend, sctp->sctp_cxmit_list == NULL ? "yes" : "no", sctp->sctp_state)); return; } if (fp == NULL) fp = sctp->sctp_current; /* OK to send */ ipmp = sctp_make_mp(sctp, fp, 0); if (ipmp == NULL) { SCTP_FADDR_RC_TIMER_RESTART(sctp, fp, fp->rto); SCTP_KSTAT(sctps, sctp_send_asconf_failed); return; } mp = sctp->sctp_cxmit_list; /* Fill in the mandatory Address Parameter TLV */ isv4 = (fp != NULL) ? fp->isv4 : sctp->sctp_current->isv4; ph = (sctp_parm_hdr_t *)(mp->b_rptr + sizeof (sctp_chunk_hdr_t) + sizeof (uint32_t)); if (isv4) { ipha_t *ipha = (ipha_t *)ipmp->b_rptr; in6_addr_t ipaddr; ipaddr_t addr4; ph->sph_type = htons(PARM_ADDR4); ph->sph_len = htons(PARM_ADDR4_LEN); if (ipha->ipha_src != INADDR_ANY) { bcopy(&ipha->ipha_src, ph + 1, IP_ADDR_LEN); } else { ipaddr = sctp_get_valid_addr(sctp, B_FALSE, &saddr_set); /* * All the addresses are down. * Maybe we might have better luck next time. */ if (!saddr_set) { SCTP_FADDR_RC_TIMER_RESTART(sctp, fp, fp->rto); freeb(ipmp); return; } IN6_V4MAPPED_TO_IPADDR(&ipaddr, addr4); bcopy(&addr4, ph + 1, IP_ADDR_LEN); } } else { ip6_t *ip6 = (ip6_t *)ipmp->b_rptr; in6_addr_t ipaddr; ph->sph_type = htons(PARM_ADDR6); ph->sph_len = htons(PARM_ADDR6_LEN); if (!IN6_IS_ADDR_UNSPECIFIED(&ip6->ip6_src)) { bcopy(&ip6->ip6_src, ph + 1, IPV6_ADDR_LEN); } else { ipaddr = sctp_get_valid_addr(sctp, B_TRUE, &saddr_set); /* * All the addresses are down. * Maybe we might have better luck next time. */ if (!saddr_set) { SCTP_FADDR_RC_TIMER_RESTART(sctp, fp, fp->rto); freeb(ipmp); return; } bcopy(&ipaddr, ph + 1, IPV6_ADDR_LEN); } } /* Don't exceed CWND */ if ((MBLKL(mp) > (fp->cwnd - fp->suna)) || ((mp = dupb(sctp->sctp_cxmit_list)) == NULL)) { SCTP_FADDR_RC_TIMER_RESTART(sctp, fp, fp->rto); freeb(ipmp); return; } /* Set the serial number now, if sending for the first time */ if (!SCTP_CHUNK_WANT_REXMIT(mp)) { snp = (uint32_t *)(mp->b_rptr + sizeof (sctp_chunk_hdr_t)); *snp = htonl(sctp->sctp_lcsn++); } SCTP_CHUNK_CLEAR_FLAGS(mp); fp->suna += MBLKL(mp); /* Attach the header and send the chunk */ ipmp->b_cont = mp; sctp->sctp_cchunk_pend = 1; SCTP_SET_SENT_FLAG(sctp->sctp_cxmit_list); SCTP_SET_CHUNK_DEST(sctp->sctp_cxmit_list, fp); sctp_set_iplen(sctp, ipmp, fp->ixa); (void) conn_ip_output(ipmp, fp->ixa); BUMP_LOCAL(sctp->sctp_opkts); SCTP_FADDR_RC_TIMER_RESTART(sctp, fp, fp->rto); #undef SCTP_SET_SENT_FLAG } /* * Generate ASCONF error param, include errph, if present. */ static mblk_t * sctp_asconf_adderr(int err, sctp_parm_hdr_t *errph, uint32_t cid) { mblk_t *mp; sctp_parm_hdr_t *eph; sctp_parm_hdr_t *wph; size_t len; size_t elen = 0; len = sizeof (*wph) + sizeof (*eph) + sizeof (cid); if (errph != NULL) { elen = ntohs(errph->sph_len); len += elen; } mp = allocb(len, BPRI_MED); if (mp == NULL) { return (NULL); } wph = (sctp_parm_hdr_t *)mp->b_rptr; /* error cause wrapper */ wph->sph_type = htons(PARM_ERROR_IND); wph->sph_len = htons(len); bcopy(&cid, wph + 1, sizeof (uint32_t)); /* error cause */ eph = (sctp_parm_hdr_t *)((char *)wph + sizeof (sctp_parm_hdr_t) + sizeof (cid)); eph->sph_type = htons(err); eph->sph_len = htons(len - sizeof (*wph) - sizeof (cid)); mp->b_wptr = (uchar_t *)(eph + 1); /* details */ if (elen > 0) { bcopy(errph, mp->b_wptr, elen); mp->b_wptr += elen; } return (mp); } static mblk_t * sctp_check_addip_addr(sctp_parm_hdr_t *ph, sctp_parm_hdr_t *oph, int *cont, uint32_t cid, in6_addr_t *raddr) { uint16_t atype; uint16_t alen; mblk_t *mp; in6_addr_t addr; ipaddr_t *addr4; atype = ntohs(ph->sph_type); alen = ntohs(ph->sph_len); if (atype != PARM_ADDR4 && atype != PARM_ADDR6) { mp = sctp_asconf_adderr(SCTP_ERR_BAD_MANDPARM, oph, cid); if (mp == NULL) { *cont = -1; } return (mp); } if ((atype == PARM_ADDR4 && alen < PARM_ADDR4_LEN) || (atype == PARM_ADDR6 && alen < PARM_ADDR6_LEN)) { mp = sctp_asconf_adderr(SCTP_ERR_BAD_MANDPARM, oph, cid); if (mp == NULL) { *cont = -1; } return (mp); } /* Address parameter is present; extract and screen it */ if (atype == PARM_ADDR4) { addr4 = (ipaddr_t *)(ph + 1); IN6_IPADDR_TO_V4MAPPED(*addr4, &addr); /* screen XXX loopback to scoping */ if (*addr4 == 0 || *addr4 == INADDR_BROADCAST || *addr4 == htonl(INADDR_LOOPBACK) || CLASSD(*addr4)) { dprint(1, ("addip: addr not unicast: %x:%x:%x:%x\n", SCTP_PRINTADDR(addr))); mp = sctp_asconf_adderr(SCTP_ERR_BAD_MANDPARM, oph, cid); if (mp == NULL) { *cont = -1; } return (mp); } /* * XXX also need to check for subnet * broadcasts. This should probably * wait until we have full access * to the ILL tables. */ } else { bcopy(ph + 1, &addr, sizeof (addr)); /* screen XXX loopback to scoping */ if (IN6_IS_ADDR_LINKLOCAL(&addr) || IN6_IS_ADDR_MULTICAST(&addr) || IN6_IS_ADDR_LOOPBACK(&addr)) { dprint(1, ("addip: addr not unicast: %x:%x:%x:%x\n", SCTP_PRINTADDR(addr))); mp = sctp_asconf_adderr(SCTP_ERR_BAD_MANDPARM, oph, cid); if (mp == NULL) { *cont = -1; } return (mp); } } /* OK */ *raddr = addr; return (NULL); } /* * Handles both add and delete address requests. */ static mblk_t * sctp_addip_req(sctp_t *sctp, sctp_parm_hdr_t *ph, uint32_t cid, sctp_faddr_t *fp, int *cont, int act, in6_addr_t *raddr) { in6_addr_t addr; uint16_t type; mblk_t *mp; sctp_faddr_t *nfp; sctp_parm_hdr_t *oph = ph; int err; sctp_stack_t *sctps = sctp->sctp_sctps; *cont = 1; /* Send back an authorization error if addip is disabled */ if (!sctps->sctps_addip_enabled) { err = SCTP_ERR_UNAUTHORIZED; goto error_handler; } /* Check input */ if (ntohs(ph->sph_len) < (sizeof (*ph) * 2)) { err = SCTP_ERR_BAD_MANDPARM; goto error_handler; } type = ntohs(ph->sph_type); ph = (sctp_parm_hdr_t *)((char *)ph + sizeof (sctp_parm_hdr_t) + sizeof (cid)); mp = sctp_check_addip_addr(ph, oph, cont, cid, &addr); if (mp != NULL) return (mp); if (raddr != NULL) *raddr = addr; if (type == PARM_ADD_IP) { if (sctp_lookup_faddr(sctp, &addr) != NULL) { /* Address is already part of association */ dprint(1, ("addip: addr already here: %x:%x:%x:%x\n", SCTP_PRINTADDR(addr))); err = SCTP_ERR_BAD_MANDPARM; goto error_handler; } if (!act) { return (NULL); } /* Add the new address */ mutex_enter(&sctp->sctp_conn_tfp->tf_lock); err = sctp_add_faddr(sctp, &addr, KM_NOSLEEP, B_FALSE); mutex_exit(&sctp->sctp_conn_tfp->tf_lock); if (err == ENOMEM) { /* no memory */ *cont = -1; return (NULL); } if (err != 0) { err = SCTP_ERR_BAD_MANDPARM; goto error_handler; } sctp_intf_event(sctp, addr, SCTP_ADDR_ADDED, 0); } else if (type == PARM_DEL_IP) { nfp = sctp_lookup_faddr(sctp, &addr); if (nfp == NULL) { /* * Peer is trying to delete an address that is not * part of the association. */ dprint(1, ("delip: addr not here: %x:%x:%x:%x\n", SCTP_PRINTADDR(addr))); err = SCTP_ERR_BAD_MANDPARM; goto error_handler; } if (sctp->sctp_faddrs == nfp && nfp->next == NULL) { /* Peer is trying to delete last address */ dprint(1, ("delip: del last addr: %x:%x:%x:%x\n", SCTP_PRINTADDR(addr))); err = SCTP_ERR_DEL_LAST_ADDR; goto error_handler; } if (nfp == fp) { /* Peer is trying to delete source address */ dprint(1, ("delip: del src addr: %x:%x:%x:%x\n", SCTP_PRINTADDR(addr))); err = SCTP_ERR_DEL_SRC_ADDR; goto error_handler; } if (!act) { return (NULL); } sctp_unlink_faddr(sctp, nfp); /* Update all references to the deleted faddr */ if (sctp->sctp_primary == nfp) { sctp->sctp_primary = fp; } if (sctp->sctp_current == nfp) { sctp_set_faddr_current(sctp, fp); } if (sctp->sctp_lastdata == nfp) { sctp->sctp_lastdata = fp; } if (sctp->sctp_shutdown_faddr == nfp) { sctp->sctp_shutdown_faddr = nfp; } if (sctp->sctp_lastfaddr == nfp) { for (fp = sctp->sctp_faddrs; fp->next; fp = fp->next) ; sctp->sctp_lastfaddr = fp; } sctp_intf_event(sctp, addr, SCTP_ADDR_REMOVED, 0); } else { ASSERT(0); } /* Successful, don't need to return anything. */ return (NULL); error_handler: mp = sctp_asconf_adderr(err, oph, cid); if (mp == NULL) *cont = -1; return (mp); } /* * Handles both add and delete IP ACKs. */ /*ARGSUSED*/ static void sctp_addip_ack(sctp_t *sctp, sctp_parm_hdr_t *ph, sctp_parm_hdr_t *oph, sctp_faddr_t *fp, in6_addr_t *laddr) { in6_addr_t addr; sctp_saddr_ipif_t *sp; ipaddr_t *addr4; boolean_t backout = B_FALSE; uint16_t type; uint32_t *cid; /* could be an ASSERT */ if (laddr != NULL) IN6_IPADDR_TO_V4MAPPED(0, laddr); /* If the peer doesn't understand Add-IP, remember it */ if (ph != NULL && ph->sph_type == htons(PARM_UNRECOGNIZED)) { sctp->sctp_understands_addip = B_FALSE; backout = B_TRUE; } /* * If OK, continue with the add / delete action, otherwise * back out the action. */ if (ph != NULL && ph->sph_type != htons(PARM_SUCCESS)) { backout = B_TRUE; sctp_error_event(sctp, (sctp_chunk_hdr_t *)ph, B_TRUE); } type = ntohs(oph->sph_type); cid = (uint32_t *)(oph + 1); oph = (sctp_parm_hdr_t *)(cid + 1); if (oph->sph_type == htons(PARM_ADDR4)) { addr4 = (ipaddr_t *)(oph + 1); IN6_IPADDR_TO_V4MAPPED(*addr4, &addr); } else { bcopy(oph + 1, &addr, sizeof (addr)); } /* Signifies that the address was sucessfully processed */ if (!backout && laddr != NULL) *laddr = addr; sp = sctp_saddr_lookup(sctp, &addr, 0); ASSERT(sp != NULL); if (type == PARM_ADD_IP) { if (backout) { sctp_del_saddr(sctp, sp); } else { sp->saddr_ipif_dontsrc = 0; } } else if (type == PARM_DEL_IP) { if (backout) { sp->saddr_ipif_delete_pending = 0; sp->saddr_ipif_dontsrc = 0; } else { sctp_del_saddr(sctp, sp); } } else { /* Must be either PARM_ADD_IP or PARM_DEL_IP */ ASSERT(0); } } /*ARGSUSED*/ static mblk_t * sctp_setprim_req(sctp_t *sctp, sctp_parm_hdr_t *ph, uint32_t cid, sctp_faddr_t *fp, int *cont, int act, in6_addr_t *raddr) { mblk_t *mp; sctp_parm_hdr_t *oph; sctp_faddr_t *nfp; in6_addr_t addr; *cont = 1; /* Does the peer understand ASCONF and Add-IP? */ if (!sctp->sctp_understands_asconf || !sctp->sctp_understands_addip) { mp = sctp_asconf_adderr(SCTP_ERR_UNAUTHORIZED, ph, cid); if (mp == NULL) { *cont = -1; } return (mp); } /* Check input */ if (ntohs(ph->sph_len) < (sizeof (*ph) * 2)) { mp = sctp_asconf_adderr(SCTP_ERR_BAD_MANDPARM, ph, cid); if (mp == NULL) { *cont = -1; } return (mp); } oph = ph; ph = (sctp_parm_hdr_t *)((char *)ph + sizeof (sctp_parm_hdr_t) + sizeof (cid)); mp = sctp_check_addip_addr(ph, oph, cont, cid, &addr); if (mp != NULL) { return (mp); } nfp = sctp_lookup_faddr(sctp, &addr); if (nfp == NULL) { /* * Peer is trying to set an address that is not * part of the association. */ dprint(1, ("setprim: addr not here: %x:%x:%x:%x\n", SCTP_PRINTADDR(addr))); mp = sctp_asconf_adderr(SCTP_ERR_BAD_MANDPARM, oph, cid); if (mp == NULL) { *cont = -1; } return (mp); } sctp_intf_event(sctp, addr, SCTP_ADDR_MADE_PRIM, 0); sctp->sctp_primary = nfp; if (nfp->state != SCTP_FADDRS_ALIVE || nfp == sctp->sctp_current) { return (NULL); } sctp_set_faddr_current(sctp, nfp); return (NULL); } /*ARGSUSED*/ static void sctp_setprim_ack(sctp_t *sctp, sctp_parm_hdr_t *ph, sctp_parm_hdr_t *oph, sctp_faddr_t *fp, in6_addr_t *laddr) { if (ph != NULL && ph->sph_type != htons(PARM_SUCCESS)) { /* If the peer doesn't understand Add-IP, remember it */ if (ph->sph_type == htons(PARM_UNRECOGNIZED)) { sctp->sctp_understands_addip = B_FALSE; } sctp_error_event(sctp, (sctp_chunk_hdr_t *)ph, B_TRUE); } /* On success we do nothing */ } int sctp_add_ip(sctp_t *sctp, const void *addrs, uint32_t cnt) { struct sockaddr_in *sin4; struct sockaddr_in6 *sin6; mblk_t *mp; int error = 0; int i; sctp_addip4_t *ad4; sctp_addip6_t *ad6; sctp_asconf_t asc[1]; uint16_t type = htons(PARM_ADD_IP); boolean_t v4mapped = B_FALSE; sctp_cl_ainfo_t *ainfo = NULL; conn_t *connp = sctp->sctp_connp; /* Does the peer understand ASCONF and Add-IP? */ if (!sctp->sctp_understands_asconf || !sctp->sctp_understands_addip) return (EOPNOTSUPP); /* * On a clustered node, we need to pass this list when * we get an ASCONF-ACK. We only pre-allocate memory for the * list, but fill in the addresses when it is processed * successfully after we get an ASCONF-ACK. */ if (cl_sctp_assoc_change != NULL) { ainfo = kmem_zalloc(sizeof (*ainfo), KM_SLEEP); /* * Reserve space for the list of new addresses */ ainfo->sctp_cl_asize = sizeof (in6_addr_t) * cnt; ainfo->sctp_cl_alist = kmem_alloc(ainfo->sctp_cl_asize, KM_SLEEP); } sctp_asconf_init(asc); /* * Screen addresses: * If adding: * o Must not already be a part of the association * o Must be AF_INET or AF_INET6 * o XXX Must be valid source address for this node * o Must be unicast * o XXX Must fit scoping rules * If deleting: * o Must be part of the association */ for (i = 0; i < cnt; i++) { switch (connp->conn_family) { case AF_INET: sin4 = (struct sockaddr_in *)addrs + i; v4mapped = B_TRUE; break; case AF_INET6: sin6 = (struct sockaddr_in6 *)addrs + i; break; } if (v4mapped) { mp = allocb(sizeof (*ad4), BPRI_MED); if (mp == NULL) { error = ENOMEM; goto fail; } mp->b_wptr += sizeof (*ad4); ad4 = (sctp_addip4_t *)mp->b_rptr; ad4->sad4_addip_ph.sph_type = type; ad4->sad4_addip_ph.sph_len = htons(sizeof (sctp_parm_hdr_t) + PARM_ADDR4_LEN + sizeof (ad4->asconf_req_cid)); ad4->sad4_addr4_ph.sph_type = htons(PARM_ADDR4); ad4->sad4_addr4_ph.sph_len = htons(PARM_ADDR4_LEN); ad4->sad4_addr = sin4->sin_addr.s_addr; } else { mp = allocb(sizeof (*ad6), BPRI_MED); if (mp == NULL) { error = ENOMEM; goto fail; } mp->b_wptr += sizeof (*ad6); ad6 = (sctp_addip6_t *)mp->b_rptr; ad6->sad6_addip_ph.sph_type = type; ad6->sad6_addip_ph.sph_len = htons(sizeof (sctp_parm_hdr_t) + PARM_ADDR6_LEN + sizeof (ad6->asconf_req_cid)); ad6->sad6_addr6_ph.sph_type = htons(PARM_ADDR6); ad6->sad6_addr6_ph.sph_len = htons(PARM_ADDR6_LEN); ad6->sad6_addr = sin6->sin6_addr; } error = sctp_asconf_add(asc, mp); if (error != 0) goto fail; } error = sctp_asconf_send(sctp, asc, sctp->sctp_current, ainfo); if (error != 0) goto fail; return (0); fail: if (ainfo != NULL) { kmem_free(ainfo->sctp_cl_alist, ainfo->sctp_cl_asize); ainfo->sctp_cl_asize = 0; kmem_free(ainfo, sizeof (*ainfo)); } sctp_asconf_destroy(asc); return (error); } int sctp_del_ip(sctp_t *sctp, const void *addrs, uint32_t cnt, uchar_t *ulist, size_t usize) { struct sockaddr_in *sin4; struct sockaddr_in6 *sin6; mblk_t *mp; int error = 0; int i; int addrcnt = 0; sctp_addip4_t *ad4; sctp_addip6_t *ad6; sctp_asconf_t asc[1]; sctp_saddr_ipif_t *nsp; uint16_t type = htons(PARM_DEL_IP); boolean_t v4mapped = B_FALSE; in6_addr_t addr; boolean_t asconf = B_TRUE; uint_t ifindex; sctp_cl_ainfo_t *ainfo = NULL; uchar_t *p = ulist; boolean_t check_lport = B_FALSE; sctp_stack_t *sctps = sctp->sctp_sctps; conn_t *connp = sctp->sctp_connp; /* Does the peer understand ASCONF and Add-IP? */ if (sctp->sctp_state <= SCTPS_LISTEN || !sctps->sctps_addip_enabled || !sctp->sctp_understands_asconf || !sctp->sctp_understands_addip) { asconf = B_FALSE; } if (sctp->sctp_state > SCTPS_BOUND) check_lport = B_TRUE; if (asconf) { /* * On a clustered node, we need to pass this list when * we get an ASCONF-ACK. We only pre-allocate memory for the * list, but fill in the addresses when it is processed * successfully after we get an ASCONF-ACK. */ if (cl_sctp_assoc_change != NULL) { ainfo = kmem_alloc(sizeof (*ainfo), KM_SLEEP); ainfo->sctp_cl_dsize = sizeof (in6_addr_t) * cnt; ainfo->sctp_cl_dlist = kmem_alloc(ainfo->sctp_cl_dsize, KM_SLEEP); } sctp_asconf_init(asc); } /* * Screen addresses: * If adding: * o Must not already be a part of the association * o Must be AF_INET or AF_INET6 * o XXX Must be valid source address for this node * o Must be unicast * o XXX Must fit scoping rules * If deleting: * o Must be part of the association */ for (i = 0; i < cnt; i++) { ifindex = 0; switch (connp->conn_family) { case AF_INET: sin4 = (struct sockaddr_in *)addrs + i; if (check_lport && sin4->sin_port != connp->conn_lport) { error = EINVAL; goto fail; } v4mapped = B_TRUE; IN6_IPADDR_TO_V4MAPPED(sin4->sin_addr.s_addr, &addr); break; case AF_INET6: sin6 = (struct sockaddr_in6 *)addrs + i; if (check_lport && sin6->sin6_port != connp->conn_lport) { error = EINVAL; goto fail; } addr = sin6->sin6_addr; ifindex = sin6->sin6_scope_id; break; } nsp = sctp_saddr_lookup(sctp, &addr, ifindex); if (nsp == NULL) { error = EADDRNOTAVAIL; goto fail; } /* Collect the list of addresses, if required */ if (usize >= sizeof (addr)) { bcopy(&addr, p, sizeof (addr)); p += sizeof (addr); usize -= sizeof (addr); } if (!asconf) continue; nsp->saddr_ipif_delete_pending = 1; nsp->saddr_ipif_dontsrc = 1; addrcnt++; if (v4mapped) { mp = allocb(sizeof (*ad4), BPRI_MED); if (mp == NULL) { error = ENOMEM; goto fail; } mp->b_wptr += sizeof (*ad4); ad4 = (sctp_addip4_t *)mp->b_rptr; ad4->sad4_addip_ph.sph_type = type; ad4->sad4_addip_ph.sph_len = htons(sizeof (sctp_parm_hdr_t) + PARM_ADDR4_LEN + sizeof (ad4->asconf_req_cid)); ad4->sad4_addr4_ph.sph_type = htons(PARM_ADDR4); ad4->sad4_addr4_ph.sph_len = htons(PARM_ADDR4_LEN); ad4->sad4_addr = sin4->sin_addr.s_addr; } else { mp = allocb(sizeof (*ad6), BPRI_MED); if (mp == NULL) { error = ENOMEM; goto fail; } mp->b_wptr += sizeof (*ad6); ad6 = (sctp_addip6_t *)mp->b_rptr; ad6->sad6_addip_ph.sph_type = type; ad6->sad6_addip_ph.sph_len = htons(sizeof (sctp_parm_hdr_t) + PARM_ADDR6_LEN + sizeof (ad6->asconf_req_cid)); ad6->sad6_addr6_ph.sph_type = htons(PARM_ADDR6); ad6->sad6_addr6_ph.sph_len = htons(PARM_ADDR6_LEN); ad6->sad6_addr = addr; } error = sctp_asconf_add(asc, mp); if (error != 0) goto fail; } if (!asconf) { sctp_del_saddr_list(sctp, addrs, cnt, B_FALSE); return (0); } error = sctp_asconf_send(sctp, asc, sctp->sctp_current, ainfo); if (error != 0) goto fail; sctp_redo_faddr_srcs(sctp); return (0); fail: if (ainfo != NULL) { kmem_free(ainfo->sctp_cl_dlist, ainfo->sctp_cl_dsize); ainfo->sctp_cl_dsize = 0; kmem_free(ainfo, sizeof (*ainfo)); } if (!asconf) return (error); for (i = 0; i < addrcnt; i++) { ifindex = 0; switch (connp->conn_family) { case AF_INET: sin4 = (struct sockaddr_in *)addrs + i; IN6_INADDR_TO_V4MAPPED(&(sin4->sin_addr), &addr); break; case AF_INET6: sin6 = (struct sockaddr_in6 *)addrs + i; addr = sin6->sin6_addr; ifindex = sin6->sin6_scope_id; break; } nsp = sctp_saddr_lookup(sctp, &addr, ifindex); ASSERT(nsp != NULL); nsp->saddr_ipif_delete_pending = 0; nsp->saddr_ipif_dontsrc = 0; } sctp_asconf_destroy(asc); return (error); } int sctp_set_peerprim(sctp_t *sctp, const void *inp) { const struct sctp_setprim *prim = inp; const struct sockaddr_storage *ss; struct sockaddr_in *sin; struct sockaddr_in6 *sin6; in6_addr_t addr; mblk_t *mp; sctp_saddr_ipif_t *sp; sctp_addip4_t *ad4; sctp_addip6_t *ad6; sctp_asconf_t asc[1]; int error = 0; uint_t ifindex = 0; /* Does the peer understand ASCONF and Add-IP? */ if (!sctp->sctp_understands_asconf || !sctp->sctp_understands_addip) { return (EOPNOTSUPP); } /* Don't do anything if we are not connected */ if (sctp->sctp_state != SCTPS_ESTABLISHED) return (EINVAL); ss = &prim->ssp_addr; sin = NULL; sin6 = NULL; if (ss->ss_family == AF_INET) { sin = (struct sockaddr_in *)ss; IN6_IPADDR_TO_V4MAPPED(sin->sin_addr.s_addr, &addr); } else if (ss->ss_family == AF_INET6) { sin6 = (struct sockaddr_in6 *)ss; addr = sin6->sin6_addr; ifindex = sin6->sin6_scope_id; } else { return (EAFNOSUPPORT); } sp = sctp_saddr_lookup(sctp, &addr, ifindex); if (sp == NULL) return (EADDRNOTAVAIL); sctp_asconf_init(asc); if (sin) { mp = allocb(sizeof (*ad4), BPRI_MED); if (mp == NULL) { error = ENOMEM; goto fail; } mp->b_wptr += sizeof (*ad4); ad4 = (sctp_addip4_t *)mp->b_rptr; ad4->sad4_addip_ph.sph_type = htons(PARM_SET_PRIMARY); ad4->sad4_addip_ph.sph_len = htons(sizeof (sctp_parm_hdr_t) + PARM_ADDR4_LEN + sizeof (ad4->asconf_req_cid)); ad4->sad4_addr4_ph.sph_type = htons(PARM_ADDR4); ad4->sad4_addr4_ph.sph_len = htons(PARM_ADDR4_LEN); ad4->sad4_addr = sin->sin_addr.s_addr; } else { mp = allocb(sizeof (*ad6), BPRI_MED); if (mp == NULL) { error = ENOMEM; goto fail; } mp->b_wptr += sizeof (*ad6); ad6 = (sctp_addip6_t *)mp->b_rptr; ad6->sad6_addip_ph.sph_type = htons(PARM_SET_PRIMARY); ad6->sad6_addip_ph.sph_len = htons(sizeof (sctp_parm_hdr_t) + PARM_ADDR6_LEN + sizeof (ad6->asconf_req_cid)); ad6->sad6_addr6_ph.sph_type = htons(PARM_ADDR6); ad6->sad6_addr6_ph.sph_len = htons(PARM_ADDR6_LEN); ad6->sad6_addr = sin6->sin6_addr; } error = sctp_asconf_add(asc, mp); if (error != 0) { goto fail; } error = sctp_asconf_send(sctp, asc, sctp->sctp_current, NULL); if (error == 0) { return (0); } fail: sctp_asconf_destroy(asc); return (error); }