/* * Copyright (C) 1993-1997 by Darren Reed. * * Redistribution and use in source and binary forms are permitted * provided that this notice is preserved and due credit is given * to the original author and the contributors. */ /* #pragma ident "@(#)solaris.c 1.12 6/5/96 (C) 1995 Darren Reed"*/ #pragma ident "@(#)$Id: solaris.c,v 2.0.2.22.2.4 1998/02/28 02:35:21 darrenr Exp $"; #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ip_compat.h" #include "ipl.h" #include "ip_fil.h" #include "ip_nat.h" char _depends_on[] = "drv/ip"; void solipdrvattach __P((void)); int solipdrvdetach __P((void)); void solattach __P((void)); int soldetach __P((void)); extern struct filterstats frstats[]; extern kmutex_t ipf_mutex, ipfs_mutex, ipf_nat; extern int fr_flags; extern ipnat_t *nat_list; static qif_t *qif_head = NULL; static int ipf_getinfo __P((dev_info_t *, ddi_info_cmd_t, void *, void **)); static int ipf_probe __P((dev_info_t *)); static int ipf_identify __P((dev_info_t *)); static int ipf_attach __P((dev_info_t *, ddi_attach_cmd_t)); static int ipf_detach __P((dev_info_t *, ddi_detach_cmd_t)); static qif_t *qif_from_queue __P((queue_t *)); static void fr_donotip __P((int, qif_t *, queue_t *, mblk_t *, mblk_t *, ip_t *, int)); static char *ipf_devfiles[] = { IPL_NAME, IPL_NAT, IPL_STATE, IPL_AUTH, NULL }; #ifdef IPFDEBUG void printire __P((ire_t *)); #endif static int fr_precheck __P((mblk_t **, queue_t *, qif_t *, int)); static struct cb_ops ipf_cb_ops = { iplopen, iplclose, nodev, /* strategy */ nodev, /* print */ nodev, /* dump */ iplread, nodev, /* write */ iplioctl, /* ioctl */ nodev, /* devmap */ nodev, /* mmap */ nodev, /* segmap */ nochpoll, /* poll */ ddi_prop_op, NULL, D_MTSAFE, #if SOLARIS2 > 4 CB_REV, nodev, /* aread */ nodev, /* awrite */ #endif }; static struct dev_ops ipf_ops = { DEVO_REV, 0, ipf_getinfo, ipf_identify, ipf_probe, ipf_attach, ipf_detach, nodev, /* reset */ &ipf_cb_ops, (struct bus_ops *)0 }; extern struct mod_ops mod_driverops; static struct modldrv iplmod = { &mod_driverops, IPL_VERSION, &ipf_ops }; static struct modlinkage modlink1 = { MODREV_1, &iplmod, NULL }; static dev_info_t *ipf_dev_info = NULL; int _init() { #ifdef IPFDEBUG int ipfinst = mod_install(&modlink1); cmn_err(CE_NOTE, "IP Filter: _init() = %d\n", ipfinst); return ipfinst; #else return mod_install(&modlink1); #endif } int _fini(void) { #ifdef IPFDEBUG int ipfinst = mod_remove(&modlink1); cmn_err(CE_NOTE, "IP Filter: _fini() = %d\n", ipfinst); return ipfinst; #else return mod_remove(&modlink1); #endif } int _info(modinfop) struct modinfo *modinfop; { #ifdef IPFDEBUG int ipfinst = mod_info(&modlink1, modinfop); cmn_err(CE_NOTE, "IP Filter: _info(%x) = %x\n", modinfop, ipfinst); return ipfinst; #else return mod_info(&modlink1, modinfop); #endif } static int ipf_probe(dip) dev_info_t *dip; { #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: ipf_probe(%x)", dip); #endif return DDI_PROBE_SUCCESS; } static int ipf_identify(dip) dev_info_t *dip; { #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: ipf_identify(%x)", dip); #endif if (strcmp(ddi_get_name(dip), "ipf") == 0) return (DDI_IDENTIFIED); return (DDI_NOT_IDENTIFIED); } static int ipf_attach(dip, cmd) dev_info_t *dip; ddi_attach_cmd_t cmd; { #ifdef IPFDEBUG int instance; cmn_err(CE_NOTE, "IP Filter: ipf_attach(%x,%x)", dip, cmd); #endif switch (cmd) { case DDI_ATTACH: #ifdef IPFDEBUG instance = ddi_get_instance(dip); cmn_err(CE_NOTE, "IP Filter: attach ipf instance %d", instance); #endif if (ddi_create_minor_node(dip, "ipf", S_IFCHR, IPL_LOGIPF, DDI_PSEUDO, 0) == DDI_FAILURE) { ddi_remove_minor_node(dip, NULL); goto attach_failed; } if (ddi_create_minor_node(dip, "ipnat", S_IFCHR, IPL_LOGNAT, DDI_PSEUDO, 0) == DDI_FAILURE) { ddi_remove_minor_node(dip, NULL); goto attach_failed; } if (ddi_create_minor_node(dip, "ipstate", S_IFCHR,IPL_LOGSTATE, DDI_PSEUDO, 0) == DDI_FAILURE) { ddi_remove_minor_node(dip, NULL); goto attach_failed; } if (ddi_create_minor_node(dip, "ipauth", S_IFCHR, IPL_LOGAUTH, DDI_PSEUDO, 0) == DDI_FAILURE) { ddi_remove_minor_node(dip, NULL); goto attach_failed; } ipf_dev_info = dip; sync(); /* * Initialize mutex's */ iplattach(); solattach(); solipdrvattach(); cmn_err(CE_CONT, "IP Filter: attaching complete.\n"); return (DDI_SUCCESS); default: return (DDI_FAILURE); } attach_failed: cmn_err(CE_NOTE, "IP Filter: failed to attach\n"); /* * Use our own detach routine to toss * away any stuff we allocated above. */ (void) ipf_detach(dip, DDI_DETACH); return (DDI_FAILURE); } static int ipf_detach(dip, cmd) dev_info_t *dip; ddi_detach_cmd_t cmd; { int instance; #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: ipf_detach(%x,%x)", dip, cmd); #endif switch (cmd) { case DDI_DETACH: /* * Undo what we did in ipf_attach, freeing resources * and removing things we installed. The system * framework guarantees we are not active with this devinfo * node in any other entry points at this time. */ ddi_prop_remove_all(dip); instance = ddi_get_instance(dip); ddi_remove_minor_node(dip, NULL); sync(); solipdrvdetach(); if (!soldetach()) { cmn_err(CE_CONT, "IP Filter: detached\n"); return (DDI_SUCCESS); } default: return (DDI_FAILURE); } } static int ipf_getinfo(dip, infocmd, arg, result) dev_info_t *dip; ddi_info_cmd_t infocmd; void *arg, **result; { int error = DDI_FAILURE; #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: ipf_getinfo(%x,%x)", dip, infocmd); #endif switch (infocmd) { case DDI_INFO_DEVT2DEVINFO: *result = ipf_dev_info; error = DDI_SUCCESS; break; case DDI_INFO_DEVT2INSTANCE: *result = (void *)getminor((dev_t) arg); error = DDI_SUCCESS; break; default: break; } return (error); } /* * find the filter structure setup for this queue */ static qif_t *qif_from_queue(q) queue_t *q; { qif_t *qif; for (qif = qif_head; qif; qif = qif->qf_next) if ((qif->qf_iptr == q->q_ptr) || (qif->qf_optr == q->q_ptr)) break; return qif; } /* * OK, this is pretty scrappy code, but then it's essentially just here for * debug purposes and that's it. Packets should not normally come through * here, and if they do, well, we would like to see as much information as * possible about them and what they claim to hold. */ void fr_donotip(out, qif, q, m, mt, ip, off) int out; qif_t *qif; queue_t *q; mblk_t *m, *mt; ip_t *ip; int off; { u_char *s, outb[256], *t; int i; outb[0] = '\0'; outb[1] = '\0'; outb[2] = '\0'; outb[3] = '\0'; s = ip ? (u_char *)ip : outb; if (!ip && (m == mt) && m->b_cont && (MTYPE(m) != M_DATA)) m = m->b_cont; printf("!IP %s:%d %p %p %p %d %p %p %p %d %d %p\n%02x%02x%02x%02x\n", qif ? qif->qf_name : "?", out, q, q ? q->q_ptr : NULL, q ? q->q_qinfo : NULL, mt->b_wptr - mt->b_rptr, m, mt, m->b_rptr, m->b_wptr - m->b_rptr, off, ip, *s, *(s+1), *(s+2), *(s+3)); if (m != mt) { i = 0; t = outb; s = mt->b_rptr; sprintf(t, "%d:", MTYPE(mt)); t += strlen(t); for (; (i < 100) && (s < mt->b_wptr); i++) { sprintf(t, "%02x%s", *s++, ((i & 3) == 3) ? " " : ""); t += ((i & 3) == 3) ? 3 : 2; } *t++ = '\n'; *t = '\0'; printf("%s", outb); } i = 0; t = outb; s = m->b_rptr; sprintf(t, "%d:", MTYPE(m)); t += strlen(t); for (; (i < 100) && (s < m->b_wptr); i++) { sprintf(t, "%02x%s", *s++, ((i & 3) == 3) ? " " : ""); t += ((i & 3) == 3) ? 3 : 2; } *t++ = '\n'; *t = '\0'; printf("%s", outb); } /* * find the first data mblk, if present, in the chain we're processing. Also * make a few sanity checks to try prevent the filter from causing a panic - * none of the nice IP sanity checks (including checksumming) should have been * done yet - dangerous! */ static int fr_precheck(mp, q, qif, out) mblk_t **mp; queue_t *q; qif_t *qif; int out; { u_long lbuf[48]; mblk_t *m, *mt = *mp; register ip_t *ip; int iphlen, hlen, len, err, mlen, off, synced = 0; #ifndef sparc u_short __iplen, __ipoff; #endif tryagain: /* * If there is only M_DATA for a packet going out, then any header * information (which would otherwise appear in an M_PROTO mblk before * the M_DATA) is prepended before the IP header. We need to set the * offset to account for this. - see MMM */ off = (out) ? qif->qf_hl : 0; /* * Find the first data block, count the data blocks in this chain and * the total amount of data. */ for (m = mt; m && (MTYPE(m) != M_DATA); m = m->b_cont) off = 0; /* Any non-M_DATA cancels the offset */ if (!m) return 0; /* No data blocks */ ip = (ip_t *)(m->b_rptr + off); /* MMM */ /* * We might have a 1st data block which is really M_PROTO, i.e. it is * only big enough for the link layer header */ while ((u_char *)ip >= m->b_wptr) { len = (u_char *)ip - m->b_wptr; if (!(m = m->b_cont)) return 0; /* not enough data for IP */ ip = (ip_t *)(m->b_rptr + len); } if ((off = (u_char *)ip - m->b_rptr)) m->b_rptr = (u_char *)ip; mlen = msgdsize(m); /* * Ok, the IP header isn't on a 32bit aligned address. To get around * this, we copy the data to an aligned buffer and work with that. */ if (!OK_32PTR(ip)) { len = MIN(mlen, sizeof(ip_t)); copyout_mblk(m, 0, len, (char *)lbuf); frstats[out].fr_pull[0]++; ip = (ip_t *)lbuf; } else len = m->b_wptr - (u_char *)ip; if (ip->ip_v != IPVERSION) { m->b_rptr -= off; if (!synced) { synced = 1; ipfsync(); goto tryagain; } fr_donotip(out, qif, q, m, mt, ip, off); frstats[out].fr_notip++; return (fr_flags & FF_BLOCKNONIP) ? -1 : 0; } hlen = iphlen = ip->ip_hl << 2; /* * Make hlen the total size of the IP header plus TCP/UDP/ICMP header * (if it is one of these three). */ if (!(ntohs((u_short)ip->ip_off) & 0x1fff)) switch (ip->ip_p) { case IPPROTO_TCP : hlen += sizeof(tcphdr_t); break; case IPPROTO_UDP : hlen += sizeof(udphdr_t); break; case IPPROTO_ICMP : /* 76 bytes is enough for a complete ICMP error. */ hlen += 76 + sizeof(icmphdr_t); break; default : break; } /* * If we don't have enough data in the mblk or we haven't yet copied * enough (above), then copy some more. */ if ((hlen > len)) { len = MIN(hlen, sizeof(lbuf)); len = MIN(mlen, len); copyout_mblk(m, 0, len, (char *)lbuf); frstats[out].fr_pull[0]++; ip = (ip_t *)lbuf; } #ifndef sparc __iplen = (u_short)ip->ip_len, __ipoff = (u_short)ip->ip_off; ip->ip_len = htons(__iplen); ip->ip_off = htons(__ipoff); #endif if ((iphlen < sizeof(ip_t)) || (iphlen > (u_short)ip->ip_len) || (mlen < (u_short)ip->ip_len)) { /* * Bad IP packet or not enough data/data length mismatches */ m->b_rptr -= off; frstats[out].fr_bad++; return -1; } qif->qf_m = m; qif->qf_q = q; qif->qf_off = off; qif->qf_len = len; err = fr_check(ip, iphlen, qif->qf_ill, out, qif, mp); /* * Copy back the ip header data if it was changed, we haven't yet * freed the message and we aren't going to drop the packet. */ #ifndef sparc if (*mp) { __iplen = (u_short)ip->ip_len, __ipoff = (u_short)ip->ip_off; ip->ip_len = htons(__iplen); ip->ip_off = htons(__ipoff); } #endif if (err == -2) { if (*mp && (ip == (ip_t *)lbuf)) { copyin_mblk(m, 0, len, (char *)lbuf); frstats[out].fr_pull[1]++; } err = 0; } m->b_rptr -= off; return err; } int fr_qin(q, mb) queue_t *q; mblk_t *mb; { int (*pnext) __P((queue_t *, mblk_t *)), type, synced = 0; qif_t qfb, *qif; again: mutex_enter(&ipfs_mutex); while (!(qif = qif_from_queue(q))) { for (qif = qif_head; qif; qif = qif->qf_next) if (&qif->qf_rqinit == q->q_qinfo && qif->qf_rqinfo && qif->qf_rqinfo->qi_putp) { pnext = qif->qf_rqinfo->qi_putp; mutex_exit(&ipfs_mutex); frstats[0].fr_notip++; if (!synced) { ipfsync(); synced = 1; goto again; } /* fr_donotip(0, NULL, q, mb, mb, NULL, 0); */ return (*pnext)(q, mb); } mutex_exit(&ipfs_mutex); if (!synced) { ipfsync(); synced = 1; goto again; } cmn_err(CE_WARN, "IP Filter: dropped: fr_qin(%x,%x): type %x qif %x", q, mb, MTYPE(mb), qif); cmn_err(CE_CONT, "IP Filter: info %x next %x ptr %x fsrv %x bsrv %x\n", q->q_qinfo, q->q_next, q->q_ptr, q->q_nfsrv, q->q_nbsrv); cmn_err(CE_CONT, "IP Filter: info: putp %x srvp %x info %x\n", q->q_qinfo->qi_putp, q->q_qinfo->qi_srvp, #if SOLARIS > 3 q->q_qinfo->qi_infop #else 0 #endif ); frstats[0].fr_drop++; freemsg(mb); return 0; } /* * So we can be more re-entrant. */ bcopy((char *)qif, (char *)&qfb, sizeof(*qif)); mutex_exit(&ipfs_mutex); qif = &qfb; pnext = qif->qf_rqinfo->qi_putp; type = MTYPE(mb); if (type == M_DATA || type == M_PROTO || type == M_PCPROTO) if (fr_precheck(&mb, q, qif, 0)) { if (mb) freemsg(mb); return 0; } if (mb) { if (pnext) return (*pnext)(q, mb); cmn_err(CE_WARN, "IP Filter: inp NULL: qif %x %s q %x info %x", qif, qif->qf_name, q, q->q_qinfo); freemsg(mb); } return 0; } int fr_qout(q, mb) queue_t *q; mblk_t *mb; { int (*pnext) __P((queue_t *, mblk_t *)), type, synced = 0; qif_t qfb, *qif; again: mutex_enter(&ipfs_mutex); if (!(qif = qif_from_queue(q))) { for (qif = qif_head; qif; qif = qif->qf_next) if (&qif->qf_wqinit == q->q_qinfo && qif->qf_wqinfo && qif->qf_wqinfo->qi_putp) { pnext = qif->qf_wqinfo->qi_putp; mutex_exit(&ipfs_mutex); frstats[1].fr_notip++; if (!synced) { ipfsync(); synced = 1; goto again; } /* fr_donotip(0, NULL, q, mb, mb, NULL, 0); */ return (*pnext)(q, mb); } mutex_exit(&ipfs_mutex); if (!synced) { ipfsync(); synced = 1; goto again; } cmn_err(CE_WARN, "IP Filter: dropped: fr_qout(%x,%x): type %x: qif %x", q, mb, MTYPE(mb), qif); cmn_err(CE_CONT, "IP Filter: info %x next %x ptr %x fsrv %x bsrv %x\n", q->q_qinfo, q->q_next, q->q_ptr, q->q_nfsrv, q->q_nbsrv); cmn_err(CE_CONT, "IP Filter: info: putp %x srvp %x info %x\n", q->q_qinfo->qi_putp, q->q_qinfo->qi_srvp, #if SOLARIS > 3 q->q_qinfo->qi_infop #else 0 #endif ); if (q->q_nfsrv) cmn_err(CE_CONT, "IP Filter: nfsrv: info %x next %x ptr %x\n", q->q_nfsrv->q_qinfo, q->q_nfsrv->q_next, q->q_nfsrv->q_ptr); if (q->q_nbsrv) cmn_err(CE_CONT, "IP Filter: nbsrv: info %x next %x ptr %x\n", q->q_nbsrv->q_qinfo, q->q_nbsrv->q_next, q->q_nbsrv->q_ptr); frstats[1].fr_drop++; freemsg(mb); return 0; } /* * So we can be more re-entrant. */ bcopy((char *)qif, (char *)&qfb, sizeof(*qif)); mutex_exit(&ipfs_mutex); qif = &qfb; pnext = qif->qf_wqinfo->qi_putp; type = MTYPE(mb); if (type == M_DATA || type == M_PROTO || type == M_PCPROTO) if (fr_precheck(&mb, q, qif, 1)) { if (mb) freemsg(mb); return 0; } if (mb) { if (pnext) return (*pnext)(q, mb); cmn_err(CE_WARN, "IP Filter: outp NULL: qif %x %s q %x info %x", qif, qif->qf_name, q, q->q_qinfo); freemsg(mb); } return 0; } static int (*ipf_ip_inp) __P((queue_t *, mblk_t *)) = NULL; #include #include static int synctimeoutid = 0; void ipf_synctimeout(arg) caddr_t arg; { ipfsync(); mutex_enter(&ipfs_mutex); synctimeoutid = 0; mutex_exit(&ipfs_mutex); } static int ipf_ip_qin(q, mp) queue_t *q; mblk_t *mp; { struct iocblk *ioc; int ret; if (mp->b_datap->db_type != M_IOCTL) return (*ipf_ip_inp)(q, mp); ioc = (struct iocblk *)mp->b_rptr; switch (ioc->ioc_cmd) { case I_LINK: case I_UNLINK: case SIOCSIFADDR: case SIOCSIFFLAGS: #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: ipf_ip_qin() M_IOCTL type=0x%x\n", ioc->ioc_cmd); #endif ret = (*ipf_ip_inp)(q, mp); mutex_enter(&ipfs_mutex); if (synctimeoutid == 0) { synctimeoutid = timeout( ipf_synctimeout, NULL, drv_usectohz(1000000) /*1 sec*/ ); mutex_exit(&ipfs_mutex); } else mutex_exit(&ipfs_mutex); return ret; default: return (*ipf_ip_inp)(q, mp); } } static int ipdrvattcnt = 0; extern struct streamtab ipinfo; void solipdrvattach() { #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: solipdrvattach() ipinfo=0x%lx\n", &ipinfo); #endif if (++ipdrvattcnt == 1) { if (ipf_ip_inp == NULL) { ipf_ip_inp = ipinfo.st_wrinit->qi_putp; ipinfo.st_wrinit->qi_putp = ipf_ip_qin; } } } int solipdrvdetach() { #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: solipdrvdetach() ipinfo=0x%lx\n", &ipinfo); #endif if (--ipdrvattcnt <= 0) { if (ipf_ip_inp && (ipinfo.st_wrinit->qi_putp == ipf_ip_qin)) { ipinfo.st_wrinit->qi_putp = ipf_ip_inp; ipf_ip_inp = NULL; } mutex_enter(&ipfs_mutex); if (synctimeoutid) { synctimeoutid = 0; mutex_exit(&ipfs_mutex); untimeout(synctimeoutid); } else mutex_exit(&ipfs_mutex); } } /* * attach the packet filter to each interface that is defined as having an * IP address associated with it and save some of the info. for that struct * so we're not out of date as soon as te ill disappears - but we must sync * to be correct! */ void solattach() { queue_t *in, *out; qif_t *qif, *qf2; ill_t *il; struct frentry *f; ipnat_t *np; int len; for (il = ill_g_head; il; il = il->ill_next) { in = il->ill_rq; if (!in || !il->ill_wq) continue; out = il->ill_wq->q_next; mutex_enter(&ipfs_mutex); /* * Look for entry already setup for this device */ for (qif = qif_head; qif; qif = qif->qf_next) if (qif->qf_iptr == in->q_ptr && qif->qf_optr == out->q_ptr) break; if (qif) { mutex_exit(&ipfs_mutex); continue; } #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: il %x ipt %x opt %x ipu %x opu %x i %x/%x", il, in->q_ptr, out->q_ptr, in->q_qinfo->qi_putp, out->q_qinfo->qi_putp, out->q_qinfo, in->q_qinfo); #endif KMALLOC(qif, qif_t *, sizeof(*qif)); if (!qif) { cmn_err(CE_NOTE, "IP Filter: malloc(%d) for qif_t failed\n", sizeof(qif_t)); continue; } if (in->q_qinfo->qi_putp == fr_qin) { for (qf2 = qif_head; qf2; qf2 = qf2->qf_next) if (&qf2->qf_rqinit == in->q_qinfo) { qif->qf_rqinfo = qf2->qf_rqinfo; break; } if (!qf2) { #ifdef IPFDEBUG cmn_err(CE_WARN, "IP Filter: rq:%s put %x qi %x", il->ill_name, in->q_qinfo->qi_putp, in->q_qinfo); #endif mutex_exit(&ipfs_mutex); KFREE(qif); continue; } } else qif->qf_rqinfo = in->q_qinfo; if (out->q_qinfo->qi_putp == fr_qout) { for (qf2 = qif_head; qf2; qf2 = qf2->qf_next) if (&qf2->qf_wqinit == out->q_qinfo) { qif->qf_wqinfo = qf2->qf_wqinfo; break; } if (!qf2) { #ifdef IPFDEBUG cmn_err(CE_WARN, "IP Filter: wq:%s put %x qi %x", il->ill_name, out->q_qinfo->qi_putp, out->q_qinfo); #endif mutex_exit(&ipfs_mutex); KFREE(qif); continue; } } else qif->qf_wqinfo = out->q_qinfo; qif->qf_ill = il; qif->qf_iptr = in->q_ptr; qif->qf_optr = out->q_ptr; qif->qf_hl = il->ill_hdr_length; strncpy(qif->qf_name, il->ill_name, sizeof(qif->qf_name)); qif->qf_name[sizeof(qif->qf_name) - 1] = '\0'; qif->qf_next = qif_head; qif_head = qif; /* * Activate any rules directly associated with this interface */ mutex_enter(&ipf_mutex); for (f = ipfilter[0][fr_active]; f; f = f->fr_next) { if ((f->fr_ifa == (struct ifnet *)-1)) { len = strlen(f->fr_ifname)+1; /* includes \0 */ if (len && (len == il->ill_name_length) && !strncmp(il->ill_name, f->fr_ifname, len)) f->fr_ifa = il; } } for (f = ipfilter[1][fr_active]; f; f = f->fr_next) { if ((f->fr_ifa == (struct ifnet *)-1)) { len = strlen(f->fr_ifname)+1; /* includes \0 */ if (len && (len == il->ill_name_length) && !strncmp(il->ill_name, f->fr_ifname, len)) f->fr_ifa = il; } } mutex_exit(&ipf_mutex); mutex_enter(&ipf_nat); for (np = nat_list; np; np = np->in_next) { if ((np->in_ifp == (struct ifnet *)-1)) { len = strlen(np->in_ifname)+1; /* includes \0 */ if (len && (len == il->ill_name_length) && !strncmp(il->ill_name, np->in_ifname, len)) np->in_ifp = il; } } mutex_exit(&ipf_nat); bcopy((caddr_t)qif->qf_rqinfo, (caddr_t)&qif->qf_rqinit, sizeof(struct qinit)); qif->qf_rqinit.qi_putp = fr_qin; #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: solattach: in queue(%lx)->q_qinfo FROM %lx TO %lx", in, in->q_qinfo, &qif->qf_rqinit ); #endif in->q_qinfo = &qif->qf_rqinit; bcopy((caddr_t)qif->qf_wqinfo, (caddr_t)&qif->qf_wqinit, sizeof(struct qinit)); qif->qf_wqinit.qi_putp = fr_qout; #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: solattach: out queue(%lx)->q_qinfo FROM %lx TO %lx", out, out->q_qinfo, &qif->qf_wqinit ); #endif out->q_qinfo = &qif->qf_wqinit; mutex_exit(&ipfs_mutex); cmn_err(CE_CONT, "IP Filter: attach to [%s,%d]\n", qif->qf_name, il->ill_ppa); } if (!qif_head) cmn_err(CE_CONT, "IP Filter: not attached to any interfaces\n"); return; } /* * look for bad consistancies between the list of interfaces the filter knows * about and those which are currently configured. */ int ipfsync() { register struct frentry *f; register ipnat_t *np; register qif_t *qif, **qp; register ill_t *il; queue_t *in, *out; mutex_enter(&ipfs_mutex); for (qp = &qif_head; (qif = *qp); ) { for (il = ill_g_head; il; il = il->ill_next) if ((qif->qf_ill == il) && !strcmp(qif->qf_name, il->ill_name)) { mblk_t *m = il->ill_hdr_mp; qif->qf_hl = il->ill_hdr_length; if (m && qif->qf_hl != (m->b_wptr - m->b_rptr)) cmn_err(CE_NOTE, "IP Filter: ILL Header Length Mismatch\n"); break; } if (il) { qp = &qif->qf_next; continue; } cmn_err(CE_CONT, "IP Filter: detaching [%s]\n", qif->qf_name); *qp = qif->qf_next; /* * Disable any rules directly associated with this interface */ mutex_enter(&ipf_nat); for (np = nat_list; np; np = np->in_next) if (np->in_ifp == (void *)qif->qf_ill) np->in_ifp = (struct ifnet *)-1; mutex_exit(&ipf_nat); mutex_enter(&ipf_mutex); for (f = ipfilter[0][fr_active]; f; f = f->fr_next) if (f->fr_ifa == (void *)qif->qf_ill) f->fr_ifa = (struct ifnet *)-1; for (f = ipfilter[1][fr_active]; f; f = f->fr_next) if (f->fr_ifa == (void *)qif->qf_ill) f->fr_ifa = (struct ifnet *)-1; /* * Restore q_qinfo pointers in interface queues */ il = qif->qf_ill; in = il->ill_rq; out = NULL; if (in && il->ill_wq) { out = il->ill_wq->q_next; } if (in) { #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: ipfsync: in queue(%lx)->q_qinfo FROM %lx TO %lx", in, in->q_qinfo, qif->qf_rqinfo ); #endif in->q_qinfo = qif->qf_rqinfo; } if (out) { #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: ipfsync: out queue(%lx)->q_qinfo FROM %lx TO %lx", out, out->q_qinfo, qif->qf_wqinfo ); #endif out->q_qinfo = qif->qf_wqinfo; } mutex_exit(&ipf_mutex); KFREE(qif); qif = *qp; } mutex_exit(&ipfs_mutex); solattach(); /* * Resync. any NAT `connections' using this interface and its IP #. */ for (il = ill_g_head; il; il = il->ill_next) ip_natsync((void *)il); return 0; } /* * unhook the IP filter from all defined interfaces with IP addresses */ int soldetach() { queue_t *in, *out; qif_t *qif, *qf2, **qp; ill_t *il; mutex_enter(&ipfs_mutex); /* * Make two passes, first get rid of all the unknown devices, next * unlink known devices. */ for (qp = &qif_head; (qif = *qp); ) { for (il = ill_g_head; il; il = il->ill_next) if (qif->qf_ill == il) break; if (il) { qp = &qif->qf_next; continue; } cmn_err(CE_CONT, "IP Filter: removing [%s]\n", qif->qf_name); *qp = qif->qf_next; KFREE(qif); } while ((qif = qif_head)) { qif_head = qif->qf_next; for (il = ill_g_head; il; il = il->ill_next) if (qif->qf_ill == il) break; if (il) { in = il->ill_rq; out = il->ill_wq->q_next; cmn_err(CE_CONT, "IP Filter: detaching [%s,%d]\n", qif->qf_name, il->ill_ppa); #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: soldetach: in queue(%lx)->q_qinfo FROM %lx TO %lx", in, in->q_qinfo, qif->qf_rqinfo); #endif in->q_qinfo = qif->qf_rqinfo; /* * and the write queue... */ #ifdef IPFDEBUG cmn_err(CE_NOTE, "IP Filter: soldetach: out queue(%lx)->q_qinfo FROM %lx TO %lx", out, out->q_qinfo, qif->qf_wqinfo); #endif out->q_qinfo = qif->qf_wqinfo; } KFREE(qif); } mutex_exit(&ipfs_mutex); return ipldetach(); } #ifdef IPFDEBUG void printire(ire) ire_t *ire; { printf("ire: ll_hdr_mp %p rfq %p stq %p src_addr %x max_frag %d\n", ire->ire_ll_hdr_mp, ire->ire_rfq, ire->ire_stq, ire->ire_src_addr, ire->ire_max_frag); printf("ire: mask %x addr %x gateway_addr %x type %d\n", ire->ire_mask, ire->ire_addr, ire->ire_gateway_addr, ire->ire_type); printf("ire: ll_hdr_length %d ll_hdr_saved_mp %p\n", ire->ire_ll_hdr_length, ire->ire_ll_hdr_saved_mp); } #endif int ipfr_fastroute(qf, ip, mb, mpp, fin, fdp) qif_t *qf; ip_t *ip; mblk_t *mb, **mpp; fr_info_t *fin; frdest_t *fdp; { mblk_t *mp = NULL; struct in_addr dst; ire_t *ir, *dir; int hlen = 0; u_char *s; queue_t *q = NULL; #ifndef sparc u_short __iplen, __ipoff; /* * If this is a duplicate mblk then we want ip to point at that * data, not the original, if and only if it is already pointing at * the current mblk data. */ if (ip == (ip_t *)qf->qf_m->b_rptr && qf->qf_m != mb) ip = (ip_t *)mb->b_rptr; /* * In fr_precheck(), we modify ip_len and ip_off in an aligned data * area. However, we only need to change it back if we didn't copy * the IP header data out. */ __iplen = (u_short)ip->ip_len, __ipoff = (u_short)ip->ip_off; ip->ip_len = htons(__iplen); ip->ip_off = htons(__ipoff); #endif if (ip != (ip_t *)mb->b_rptr) { copyin_mblk(mb, 0, qf->qf_len, (char *)ip); frstats[fin->fin_out].fr_pull[1]++; } /* * If there is another M_PROTO, we don't want it */ if (*mpp != mb) { (*mpp)->b_cont = NULL; freemsg(*mpp); } ir = (ire_t *)fdp->fd_ifp; if (fdp->fd_ip.s_addr) dst = fdp->fd_ip; else dst = fin->fin_fi.fi_dst; #if SOLARIS2 > 5 dir = ire_route_lookup(dst.s_addr, 0, 0, 0, NULL, NULL, NULL, MATCH_IRE_DSTONLY); #else dir = ire_lookup(dst.s_addr); #endif if (dir) if (!dir->ire_ll_hdr_mp || !dir->ire_ll_hdr_length) dir = NULL; if (!ir) ir = dir; if (ir && dir) { if ((mp = dir->ire_ll_hdr_mp)) { hlen = dir->ire_ll_hdr_length; s = mb->b_rptr; if (hlen && (s - mb->b_datap->db_base) >= hlen) { s -= hlen; mb->b_rptr = (u_char *)s; bcopy((char *)mp->b_rptr, (char *)s, hlen); } else { mblk_t *mp2; mp2 = copyb(mp); if (!mp2) goto bad_fastroute; mp2->b_cont = mb; mb = mp2; } } if (ir->ire_stq) q = ir->ire_stq; else if (ir->ire_rfq) q = WR(ir->ire_rfq); if (q) { putnext(q, mb); ipl_frouteok[0]++; return 0; } } bad_fastroute: ipl_frouteok[0]++; return -1; } void copyout_mblk(m, off, len, buf) mblk_t *m; int off, len; char *buf; { char *s, *bp = buf; int mlen, olen, clen; for (; m && len; m = m->b_cont) { if (MTYPE(m) != M_DATA) continue; s = m->b_rptr; mlen = (char *)m->b_wptr - s; olen = MIN(off, mlen); if ((olen == mlen) || (olen < off)) { off -= olen; continue; } else if (olen) { off -= olen; s += olen; mlen -= olen; } clen = MIN(mlen, len); bcopy(s, bp, clen); len -= clen; bp += clen; } } void copyin_mblk(m, off, len, buf) mblk_t *m; int off, len; char *buf; { char *s, *bp = buf; int mlen, olen, clen; for (; m && len; m = m->b_cont) { if (MTYPE(m) != M_DATA) continue; s = m->b_rptr; mlen = (char *)m->b_wptr - s; olen = MIN(off, mlen); if ((olen == mlen) || (olen < off)) { off -= olen; continue; } else if (olen) { off -= olen; s += olen; mlen -= olen; } clen = MIN(mlen, len); bcopy(bp, s, clen); len -= clen; bp += clen; } }