Current Path : /compat/linux/proc/self/root/usr/src/usr.sbin/ppp/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //compat/linux/proc/self/root/usr/src/usr.sbin/ppp/mp.c |
/*- * Copyright (c) 1998 Brian Somers <brian@Awfulhak.org> * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD: release/9.1.0/usr.sbin/ppp/mp.c 134833 2004-09-06 00:07:58Z marcel $ */ #include <sys/param.h> #include <netinet/in.h> #include <netinet/in_systm.h> #include <netinet/ip.h> #include <arpa/inet.h> #include <net/if_dl.h> #include <sys/socket.h> #include <sys/un.h> #include <errno.h> #include <paths.h> #include <stdarg.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <sys/stat.h> #include <termios.h> #include <unistd.h> #include "layer.h" #ifndef NONAT #include "nat_cmd.h" #endif #include "vjcomp.h" #include "ua.h" #include "defs.h" #include "command.h" #include "mbuf.h" #include "log.h" #include "timer.h" #include "fsm.h" #include "iplist.h" #include "throughput.h" #include "slcompress.h" #include "lqr.h" #include "hdlc.h" #include "ncpaddr.h" #include "ipcp.h" #include "auth.h" #include "lcp.h" #include "async.h" #include "ccp.h" #include "link.h" #include "descriptor.h" #include "physical.h" #include "chat.h" #include "proto.h" #include "filter.h" #include "mp.h" #include "chap.h" #include "cbcp.h" #include "datalink.h" #ifndef NORADIUS #include "radius.h" #endif #include "ipv6cp.h" #include "ncp.h" #include "bundle.h" #include "prompt.h" #include "id.h" #include "arp.h" void peerid_Init(struct peerid *peer) { peer->enddisc.class = 0; *peer->enddisc.address = '\0'; peer->enddisc.len = 0; *peer->authname = '\0'; } int peerid_Equal(const struct peerid *p1, const struct peerid *p2) { return !strcmp(p1->authname, p2->authname) && p1->enddisc.class == p2->enddisc.class && p1->enddisc.len == p2->enddisc.len && !memcmp(p1->enddisc.address, p2->enddisc.address, p1->enddisc.len); } static u_int32_t inc_seq(unsigned is12bit, u_int32_t seq) { seq++; if (is12bit) { if (seq & 0xfffff000) seq = 0; } else if (seq & 0xff000000) seq = 0; return seq; } static int isbefore(unsigned is12bit, u_int32_t seq1, u_int32_t seq2) { u_int32_t max = (is12bit ? 0xfff : 0xffffff) - 0x200; if (seq1 > max) { if (seq2 < 0x200 || seq2 > seq1) return 1; } else if ((seq1 > 0x200 || seq2 <= max) && seq1 < seq2) return 1; return 0; } static int mp_ReadHeader(struct mp *mp, struct mbuf *m, struct mp_header *header) { if (mp->local_is12bit) { u_int16_t val; ua_ntohs(MBUF_CTOP(m), &val); if (val & 0x3000) { log_Printf(LogWARN, "Oops - MP header without required zero bits\n"); return 0; } header->begin = val & 0x8000 ? 1 : 0; header->end = val & 0x4000 ? 1 : 0; header->seq = val & 0x0fff; return 2; } else { ua_ntohl(MBUF_CTOP(m), &header->seq); if (header->seq & 0x3f000000) { log_Printf(LogWARN, "Oops - MP header without required zero bits\n"); return 0; } header->begin = header->seq & 0x80000000 ? 1 : 0; header->end = header->seq & 0x40000000 ? 1 : 0; header->seq &= 0x00ffffff; return 4; } } static void mp_LayerStart(void *v __unused, struct fsm *fp __unused) { /* The given FSM (ccp) is about to start up ! */ } static void mp_LayerUp(void *v __unused, struct fsm *fp) { /* The given fsm (ccp) is now up */ bundle_CalculateBandwidth(fp->bundle); /* Against ccp_MTUOverhead */ } static void mp_LayerDown(void *v __unused, struct fsm *fp __unused) { /* The given FSM (ccp) has been told to come down */ } static void mp_LayerFinish(void *v __unused, struct fsm *fp) { /* The given fsm (ccp) is now down */ if (fp->state == ST_CLOSED && fp->open_mode == OPEN_PASSIVE) fsm_Open(fp); /* CCP goes to ST_STOPPED */ } static void mp_UpDown(void *v) { struct mp *mp = (struct mp *)v; int percent; percent = MAX(mp->link.stats.total.in.OctetsPerSecond, mp->link.stats.total.out.OctetsPerSecond) * 800 / mp->bundle->bandwidth; if (percent >= mp->cfg.autoload.max) { log_Printf(LogDEBUG, "%d%% saturation - bring a link up ?\n", percent); bundle_AutoAdjust(mp->bundle, percent, AUTO_UP); } else if (percent <= mp->cfg.autoload.min) { log_Printf(LogDEBUG, "%d%% saturation - bring a link down ?\n", percent); bundle_AutoAdjust(mp->bundle, percent, AUTO_DOWN); } } void mp_StopAutoloadTimer(struct mp *mp) { throughput_stop(&mp->link.stats.total); } void mp_CheckAutoloadTimer(struct mp *mp) { if (mp->link.stats.total.SamplePeriod != mp->cfg.autoload.period) { throughput_destroy(&mp->link.stats.total); throughput_init(&mp->link.stats.total, mp->cfg.autoload.period); throughput_callback(&mp->link.stats.total, mp_UpDown, mp); } if (bundle_WantAutoloadTimer(mp->bundle)) throughput_start(&mp->link.stats.total, "MP throughput", 1); else mp_StopAutoloadTimer(mp); } void mp_RestartAutoloadTimer(struct mp *mp) { if (mp->link.stats.total.SamplePeriod != mp->cfg.autoload.period) mp_CheckAutoloadTimer(mp); else throughput_clear(&mp->link.stats.total, THROUGHPUT_OVERALL, NULL); } void mp_Init(struct mp *mp, struct bundle *bundle) { mp->peer_is12bit = mp->local_is12bit = 0; mp->peer_mrru = mp->local_mrru = 0; peerid_Init(&mp->peer); mp->out.seq = 0; mp->out.link = 0; mp->out.af = AF_INET; mp->seq.min_in = 0; mp->seq.next_in = 0; mp->inbufs = NULL; mp->bundle = bundle; mp->link.type = LOGICAL_LINK; mp->link.name = "mp"; mp->link.len = sizeof *mp; mp->cfg.autoload.period = SAMPLE_PERIOD; mp->cfg.autoload.min = mp->cfg.autoload.max = 0; throughput_init(&mp->link.stats.total, mp->cfg.autoload.period); throughput_callback(&mp->link.stats.total, mp_UpDown, mp); mp->link.stats.parent = NULL; mp->link.stats.gather = 0; /* Let the physical links gather stats */ memset(mp->link.Queue, '\0', sizeof mp->link.Queue); memset(mp->link.proto_in, '\0', sizeof mp->link.proto_in); memset(mp->link.proto_out, '\0', sizeof mp->link.proto_out); mp->fsmp.LayerStart = mp_LayerStart; mp->fsmp.LayerUp = mp_LayerUp; mp->fsmp.LayerDown = mp_LayerDown; mp->fsmp.LayerFinish = mp_LayerFinish; mp->fsmp.object = mp; mpserver_Init(&mp->server); mp->cfg.mrru = 0; mp->cfg.shortseq = NEG_ENABLED|NEG_ACCEPTED; mp->cfg.negenddisc = NEG_ENABLED|NEG_ACCEPTED; mp->cfg.enddisc.class = 0; *mp->cfg.enddisc.address = '\0'; mp->cfg.enddisc.len = 0; lcp_Init(&mp->link.lcp, mp->bundle, &mp->link, NULL); ccp_Init(&mp->link.ccp, mp->bundle, &mp->link, &mp->fsmp); link_EmptyStack(&mp->link); link_Stack(&mp->link, &protolayer); link_Stack(&mp->link, &ccplayer); link_Stack(&mp->link, &vjlayer); #ifndef NONAT link_Stack(&mp->link, &natlayer); #endif } int mp_Up(struct mp *mp, struct datalink *dl) { struct lcp *lcp = &dl->physical->link.lcp; if (mp->active) { /* We're adding a link - do a last validation on our parameters */ if (!peerid_Equal(&dl->peer, &mp->peer)) { log_Printf(LogPHASE, "%s: Inappropriate peer !\n", dl->name); log_Printf(LogPHASE, " Attached to peer %s/%s\n", mp->peer.authname, mp_Enddisc(mp->peer.enddisc.class, mp->peer.enddisc.address, mp->peer.enddisc.len)); log_Printf(LogPHASE, " New link is peer %s/%s\n", dl->peer.authname, mp_Enddisc(dl->peer.enddisc.class, dl->peer.enddisc.address, dl->peer.enddisc.len)); return MP_FAILED; } if (mp->local_mrru != lcp->want_mrru || mp->peer_mrru != lcp->his_mrru || mp->local_is12bit != lcp->want_shortseq || mp->peer_is12bit != lcp->his_shortseq) { log_Printf(LogPHASE, "%s: Invalid MRRU/SHORTSEQ MP parameters !\n", dl->name); return MP_FAILED; } return MP_ADDED; } else { /* First link in multilink mode */ mp->local_mrru = lcp->want_mrru; mp->peer_mrru = lcp->his_mrru; mp->local_is12bit = lcp->want_shortseq; mp->peer_is12bit = lcp->his_shortseq; mp->peer = dl->peer; throughput_destroy(&mp->link.stats.total); throughput_init(&mp->link.stats.total, mp->cfg.autoload.period); throughput_callback(&mp->link.stats.total, mp_UpDown, mp); memset(mp->link.Queue, '\0', sizeof mp->link.Queue); memset(mp->link.proto_in, '\0', sizeof mp->link.proto_in); memset(mp->link.proto_out, '\0', sizeof mp->link.proto_out); /* Tell the link who it belongs to */ dl->physical->link.stats.parent = &mp->link.stats.total; mp->out.seq = 0; mp->out.link = 0; mp->out.af = AF_INET; mp->seq.min_in = 0; mp->seq.next_in = 0; /* * Now we create our server socket. * If it already exists, join it. Otherwise, create and own it */ switch (mpserver_Open(&mp->server, &mp->peer)) { case MPSERVER_CONNECTED: log_Printf(LogPHASE, "mp: Transfer link on %s\n", mp->server.socket.sun_path); mp->server.send.dl = dl; /* Defer 'till it's safe to send */ return MP_LINKSENT; case MPSERVER_FAILED: return MP_FAILED; case MPSERVER_LISTENING: log_Printf(LogPHASE, "mp: Listening on %s\n", mp->server.socket.sun_path); log_Printf(LogPHASE, " First link: %s\n", dl->name); /* Re-point our NCP layers at our MP link */ ncp_SetLink(&mp->bundle->ncp, &mp->link); /* Our lcp's already up 'cos of the NULL parent */ if (ccp_SetOpenMode(&mp->link.ccp)) { fsm_Up(&mp->link.ccp.fsm); fsm_Open(&mp->link.ccp.fsm); } mp->active = 1; break; } } return MP_UP; } void mp_Down(struct mp *mp) { if (mp->active) { struct mbuf *next; /* Stop that ! */ mp_StopAutoloadTimer(mp); /* Don't want any more of these */ mpserver_Close(&mp->server); /* CCP goes down with a bang */ fsm2initial(&mp->link.ccp.fsm); /* Received fragments go in the bit-bucket */ while (mp->inbufs) { next = mp->inbufs->m_nextpkt; m_freem(mp->inbufs); mp->inbufs = next; } peerid_Init(&mp->peer); mp->active = 0; } } void mp_linkInit(struct mp_link *mplink) { mplink->seq = 0; mplink->bandwidth = 0; } static void mp_Assemble(struct mp *mp, struct mbuf *m, struct physical *p) { struct mp_header mh, h; struct mbuf *q, *last; u_int32_t seq; /* * When `m' and `p' are NULL, it means our oldest link has gone down. * We want to determine a new min, and process any intermediate stuff * as normal */ if (m && mp_ReadHeader(mp, m, &mh) == 0) { m_freem(m); return; } if (p) { seq = p->dl->mp.seq; p->dl->mp.seq = mh.seq; } else seq = mp->seq.min_in; if (mp->seq.min_in == seq) { /* * We've received new data on the link that has our min (oldest) seq. * Figure out which link now has the smallest (oldest) seq. */ struct datalink *dl; mp->seq.min_in = (u_int32_t)-1; for (dl = mp->bundle->links; dl; dl = dl->next) if (dl->state == DATALINK_OPEN && (mp->seq.min_in == (u_int32_t)-1 || isbefore(mp->local_is12bit, dl->mp.seq, mp->seq.min_in))) mp->seq.min_in = dl->mp.seq; } /* * Now process as many of our fragments as we can, adding our new * fragment in as we go, and ordering with the oldest at the top of * the queue. */ last = NULL; seq = mp->seq.next_in; q = mp->inbufs; while (q || m) { if (!q) { if (last) last->m_nextpkt = m; else mp->inbufs = m; q = m; m = NULL; h = mh; } else { mp_ReadHeader(mp, q, &h); if (m && isbefore(mp->local_is12bit, mh.seq, h.seq)) { /* Our received fragment fits in before this one, so link it in */ if (last) last->m_nextpkt = m; else mp->inbufs = m; m->m_nextpkt = q; q = m; h = mh; m = NULL; } } if (h.seq != seq) { /* we're missing something :-( */ if (isbefore(mp->local_is12bit, seq, mp->seq.min_in)) { /* we're never gonna get it */ struct mbuf *next; /* Zap all older fragments */ while (mp->inbufs != q) { log_Printf(LogDEBUG, "Drop frag\n"); next = mp->inbufs->m_nextpkt; m_freem(mp->inbufs); mp->inbufs = next; } /* * Zap everything until the next `end' fragment OR just before * the next `begin' fragment OR 'till seq.min_in - whichever * comes first. */ do { mp_ReadHeader(mp, mp->inbufs, &h); if (h.begin) { /* We might be able to process this ! */ h.seq--; /* We're gonna look for fragment with h.seq+1 */ break; } next = mp->inbufs->m_nextpkt; log_Printf(LogDEBUG, "Drop frag %u\n", h.seq); m_freem(mp->inbufs); mp->inbufs = next; } while (mp->inbufs && (isbefore(mp->local_is12bit, mp->seq.min_in, h.seq) || h.end)); /* * Continue processing things from here. * This deals with the possibility that we received a fragment * on the slowest link that invalidates some of our data (because * of the hole at `q'), but where there are subsequent `whole' * packets that have already been received. */ mp->seq.next_in = seq = inc_seq(mp->local_is12bit, h.seq); last = NULL; q = mp->inbufs; } else /* we may still receive the missing fragment */ break; } else if (h.end) { /* We've got something, reassemble */ struct mbuf **frag = &q; int len; long long first = -1; do { *frag = mp->inbufs; mp->inbufs = mp->inbufs->m_nextpkt; len = mp_ReadHeader(mp, *frag, &h); if (first == -1) first = h.seq; if (frag == &q && !h.begin) { log_Printf(LogWARN, "Oops - MP frag %lu should have a begin flag\n", (u_long)h.seq); m_freem(q); q = NULL; } else if (frag != &q && h.begin) { log_Printf(LogWARN, "Oops - MP frag %lu should have an end flag\n", (u_long)h.seq - 1); /* * Stuff our fragment back at the front of the queue and zap * our half-assembled packet. */ (*frag)->m_nextpkt = mp->inbufs; mp->inbufs = *frag; *frag = NULL; m_freem(q); q = NULL; frag = &q; h.end = 0; /* just in case it's a whole packet */ } else { (*frag)->m_offset += len; (*frag)->m_len -= len; (*frag)->m_nextpkt = NULL; do frag = &(*frag)->m_next; while (*frag != NULL); } } while (!h.end); if (q) { q = m_pullup(q); log_Printf(LogDEBUG, "MP: Reassembled frags %lu-%lu, length %zd\n", (u_long)first, (u_long)h.seq, m_length(q)); link_PullPacket(&mp->link, MBUF_CTOP(q), q->m_len, mp->bundle); m_freem(q); } mp->seq.next_in = seq = inc_seq(mp->local_is12bit, h.seq); last = NULL; q = mp->inbufs; } else { /* Look for the next fragment */ seq = inc_seq(mp->local_is12bit, seq); last = q; q = q->m_nextpkt; } } if (m) { /* We still have to find a home for our new fragment */ last = NULL; for (q = mp->inbufs; q; last = q, q = q->m_nextpkt) { mp_ReadHeader(mp, q, &h); if (isbefore(mp->local_is12bit, mh.seq, h.seq)) break; } /* Our received fragment fits in here */ if (last) last->m_nextpkt = m; else mp->inbufs = m; m->m_nextpkt = q; } } struct mbuf * mp_Input(struct bundle *bundle, struct link *l, struct mbuf *bp) { struct physical *p = link2physical(l); if (!bundle->ncp.mp.active) /* Let someone else deal with it ! */ return bp; if (p == NULL) { log_Printf(LogWARN, "DecodePacket: Can't do MP inside MP !\n"); m_freem(bp); } else { m_settype(bp, MB_MPIN); mp_Assemble(&bundle->ncp.mp, bp, p); } return NULL; } static void mp_Output(struct mp *mp, struct bundle *bundle, struct link *l, struct mbuf *m, u_int32_t begin, u_int32_t end) { char prepend[4]; /* Stuff an MP header on the front of our packet and send it */ if (mp->peer_is12bit) { u_int16_t val; val = (begin << 15) | (end << 14) | (u_int16_t)mp->out.seq; ua_htons(&val, prepend); m = m_prepend(m, prepend, 2, 0); } else { u_int32_t val; val = (begin << 31) | (end << 30) | (u_int32_t)mp->out.seq; ua_htonl(&val, prepend); m = m_prepend(m, prepend, 4, 0); } if (log_IsKept(LogDEBUG)) log_Printf(LogDEBUG, "MP[frag %d]: Send %zd bytes on link `%s'\n", mp->out.seq, m_length(m), l->name); mp->out.seq = inc_seq(mp->peer_is12bit, mp->out.seq); if (l->ccp.fsm.state != ST_OPENED && ccp_Required(&l->ccp)) { log_Printf(LogPHASE, "%s: Not transmitting... waiting for CCP\n", l->name); return; } link_PushPacket(l, m, bundle, LINK_QUEUES(l) - 1, PROTO_MP); } int mp_FillPhysicalQueues(struct bundle *bundle) { struct mp *mp = &bundle->ncp.mp; struct datalink *dl, *fdl; size_t total, add, len; int thislink, nlinks, nopenlinks, sendasip; u_int32_t begin, end; struct mbuf *m, *mo; struct link *bestlink; thislink = nlinks = nopenlinks = 0; for (fdl = NULL, dl = bundle->links; dl; dl = dl->next) { /* Include non-open links here as mp->out.link will stay more correct */ if (!fdl) { if (thislink == mp->out.link) fdl = dl; else thislink++; } nlinks++; if (dl->state == DATALINK_OPEN) nopenlinks++; } if (!fdl) { fdl = bundle->links; if (!fdl) return 0; thislink = 0; } total = 0; for (dl = fdl; nlinks > 0; dl = dl->next, nlinks--, thislink++) { if (!dl) { dl = bundle->links; thislink = 0; } if (dl->state != DATALINK_OPEN) continue; if (dl->physical->out) /* this link has suffered a short write. Let it continue */ continue; add = link_QueueLen(&dl->physical->link); if (add) { /* this link has got stuff already queued. Let it continue */ total += add; continue; } if (!mp_QueueLen(mp)) { int mrutoosmall; /* * If there's only a single open link in our bundle and we haven't got * MP level link compression, queue outbound traffic directly via that * link's protocol stack rather than using the MP link. This results * in the outbound traffic going out as PROTO_IP or PROTO_IPV6 rather * than PROTO_MP. */ mrutoosmall = 0; sendasip = nopenlinks < 2; if (sendasip) { if (dl->physical->link.lcp.his_mru < mp->peer_mrru) { /* * Actually, forget it. This test is done against the MRRU rather * than the packet size so that we don't end up sending some data * in MP fragments and some data in PROTO_IP packets. That's just * too likely to upset some ppp implementations. */ mrutoosmall = 1; sendasip = 0; } } bestlink = sendasip ? &dl->physical->link : &mp->link; if (!ncp_PushPacket(&bundle->ncp, &mp->out.af, bestlink)) break; /* Nothing else to send */ if (mrutoosmall) log_Printf(LogDEBUG, "Don't send data as PROTO_IP, MRU < MRRU\n"); else if (sendasip) log_Printf(LogDEBUG, "Sending data as PROTO_IP, not PROTO_MP\n"); if (sendasip) { add = link_QueueLen(&dl->physical->link); if (add) { /* this link has got stuff already queued. Let it continue */ total += add; continue; } } } m = link_Dequeue(&mp->link); if (m) { len = m_length(m); begin = 1; end = 0; while (!end) { if (dl->state == DATALINK_OPEN) { /* Write at most his_mru bytes to the physical link */ if (len <= dl->physical->link.lcp.his_mru) { mo = m; end = 1; m_settype(mo, MB_MPOUT); } else { /* It's > his_mru, chop the packet (`m') into bits */ mo = m_get(dl->physical->link.lcp.his_mru, MB_MPOUT); len -= mo->m_len; m = mbuf_Read(m, MBUF_CTOP(mo), mo->m_len); } mp_Output(mp, bundle, &dl->physical->link, mo, begin, end); begin = 0; } if (!end) { nlinks--; dl = dl->next; if (!dl) { dl = bundle->links; thislink = 0; } else thislink++; } } } } mp->out.link = thislink; /* Start here next time */ return total; } int mp_SetDatalinkBandwidth(struct cmdargs const *arg) { int val; if (arg->argc != arg->argn+1) return -1; val = atoi(arg->argv[arg->argn]); if (val <= 0) { log_Printf(LogWARN, "The link bandwidth must be greater than zero\n"); return 1; } arg->cx->mp.bandwidth = val; if (arg->cx->state == DATALINK_OPEN) bundle_CalculateBandwidth(arg->bundle); return 0; } int mp_ShowStatus(struct cmdargs const *arg) { struct mp *mp = &arg->bundle->ncp.mp; prompt_Printf(arg->prompt, "Multilink is %sactive\n", mp->active ? "" : "in"); if (mp->active) { struct mbuf *m, *lm; int bufs = 0; lm = NULL; prompt_Printf(arg->prompt, "Socket: %s\n", mp->server.socket.sun_path); for (m = mp->inbufs; m; m = m->m_nextpkt) { bufs++; lm = m; } prompt_Printf(arg->prompt, "Pending frags: %d", bufs); if (bufs) { struct mp_header mh; unsigned long first, last; first = mp_ReadHeader(mp, mp->inbufs, &mh) ? mh.seq : 0; last = mp_ReadHeader(mp, lm, &mh) ? mh.seq : 0; prompt_Printf(arg->prompt, " (Have %lu - %lu, want %lu, lowest %lu)\n", first, last, (unsigned long)mp->seq.next_in, (unsigned long)mp->seq.min_in); prompt_Printf(arg->prompt, " First has %sbegin bit and " "%send bit", mh.begin ? "" : "no ", mh.end ? "" : "no "); } prompt_Printf(arg->prompt, "\n"); } prompt_Printf(arg->prompt, "\nMy Side:\n"); if (mp->active) { prompt_Printf(arg->prompt, " Output SEQ: %u\n", mp->out.seq); prompt_Printf(arg->prompt, " MRRU: %u\n", mp->local_mrru); prompt_Printf(arg->prompt, " Short Seq: %s\n", mp->local_is12bit ? "on" : "off"); } prompt_Printf(arg->prompt, " Discriminator: %s\n", mp_Enddisc(mp->cfg.enddisc.class, mp->cfg.enddisc.address, mp->cfg.enddisc.len)); prompt_Printf(arg->prompt, "\nHis Side:\n"); if (mp->active) { prompt_Printf(arg->prompt, " Auth Name: %s\n", mp->peer.authname); prompt_Printf(arg->prompt, " Input SEQ: %u\n", mp->seq.next_in); prompt_Printf(arg->prompt, " MRRU: %u\n", mp->peer_mrru); prompt_Printf(arg->prompt, " Short Seq: %s\n", mp->peer_is12bit ? "on" : "off"); } prompt_Printf(arg->prompt, " Discriminator: %s\n", mp_Enddisc(mp->peer.enddisc.class, mp->peer.enddisc.address, mp->peer.enddisc.len)); prompt_Printf(arg->prompt, "\nDefaults:\n"); prompt_Printf(arg->prompt, " MRRU: "); if (mp->cfg.mrru) prompt_Printf(arg->prompt, "%d (multilink enabled)\n", mp->cfg.mrru); else prompt_Printf(arg->prompt, "disabled\n"); prompt_Printf(arg->prompt, " Short Seq: %s\n", command_ShowNegval(mp->cfg.shortseq)); prompt_Printf(arg->prompt, " Discriminator: %s\n", command_ShowNegval(mp->cfg.negenddisc)); prompt_Printf(arg->prompt, " AutoLoad: min %d%%, max %d%%," " period %d secs\n", mp->cfg.autoload.min, mp->cfg.autoload.max, mp->cfg.autoload.period); return 0; } const char * mp_Enddisc(u_char c, const char *address, size_t len) { static char result[100]; /* Used immediately after it's returned */ unsigned f, header; switch (c) { case ENDDISC_NULL: sprintf(result, "Null Class"); break; case ENDDISC_LOCAL: snprintf(result, sizeof result, "Local Addr: %.*s", (int)len, address); break; case ENDDISC_IP: if (len == 4) snprintf(result, sizeof result, "IP %s", inet_ntoa(*(const struct in_addr *)address)); else sprintf(result, "IP[%zd] ???", len); break; case ENDDISC_MAC: if (len == 6) { const u_char *m = (const u_char *)address; snprintf(result, sizeof result, "MAC %02x:%02x:%02x:%02x:%02x:%02x", m[0], m[1], m[2], m[3], m[4], m[5]); } else sprintf(result, "MAC[%zd] ???", len); break; case ENDDISC_MAGIC: sprintf(result, "Magic: 0x"); header = strlen(result); if (len + header + 1 > sizeof result) len = sizeof result - header - 1; for (f = 0; f < len; f++) sprintf(result + header + 2 * f, "%02x", address[f]); break; case ENDDISC_PSN: snprintf(result, sizeof result, "PSN: %.*s", (int)len, address); break; default: sprintf(result, "%d: ", (int)c); header = strlen(result); if (len + header + 1 > sizeof result) len = sizeof result - header - 1; for (f = 0; f < len; f++) sprintf(result + header + 2 * f, "%02x", address[f]); break; } return result; } int mp_SetEnddisc(struct cmdargs const *arg) { struct mp *mp = &arg->bundle->ncp.mp; struct in_addr addr; switch (bundle_Phase(arg->bundle)) { case PHASE_DEAD: break; case PHASE_ESTABLISH: /* Make sure none of our links are DATALINK_LCP or greater */ if (bundle_HighestState(arg->bundle) >= DATALINK_LCP) { log_Printf(LogWARN, "enddisc: Only changable before" " LCP negotiations\n"); return 1; } break; default: log_Printf(LogWARN, "enddisc: Only changable at phase DEAD/ESTABLISH\n"); return 1; } if (arg->argc == arg->argn) { mp->cfg.enddisc.class = 0; *mp->cfg.enddisc.address = '\0'; mp->cfg.enddisc.len = 0; } else if (arg->argc > arg->argn) { if (!strcasecmp(arg->argv[arg->argn], "label")) { mp->cfg.enddisc.class = ENDDISC_LOCAL; strcpy(mp->cfg.enddisc.address, arg->bundle->cfg.label); mp->cfg.enddisc.len = strlen(mp->cfg.enddisc.address); } else if (!strcasecmp(arg->argv[arg->argn], "ip")) { if (arg->bundle->ncp.ipcp.my_ip.s_addr == INADDR_ANY) ncprange_getip4addr(&arg->bundle->ncp.ipcp.cfg.my_range, &addr); else addr = arg->bundle->ncp.ipcp.my_ip; memcpy(mp->cfg.enddisc.address, &addr.s_addr, sizeof addr.s_addr); mp->cfg.enddisc.class = ENDDISC_IP; mp->cfg.enddisc.len = sizeof arg->bundle->ncp.ipcp.my_ip.s_addr; } else if (!strcasecmp(arg->argv[arg->argn], "mac")) { struct sockaddr_dl hwaddr; if (arg->bundle->ncp.ipcp.my_ip.s_addr == INADDR_ANY) ncprange_getip4addr(&arg->bundle->ncp.ipcp.cfg.my_range, &addr); else addr = arg->bundle->ncp.ipcp.my_ip; if (arp_EtherAddr(addr, &hwaddr, 1)) { mp->cfg.enddisc.class = ENDDISC_MAC; memcpy(mp->cfg.enddisc.address, hwaddr.sdl_data + hwaddr.sdl_nlen, hwaddr.sdl_alen); mp->cfg.enddisc.len = hwaddr.sdl_alen; } else { log_Printf(LogWARN, "set enddisc: Can't locate MAC address for %s\n", inet_ntoa(addr)); return 4; } } else if (!strcasecmp(arg->argv[arg->argn], "magic")) { int f; randinit(); for (f = 0; f < 20; f += sizeof(long)) *(long *)(mp->cfg.enddisc.address + f) = random(); mp->cfg.enddisc.class = ENDDISC_MAGIC; mp->cfg.enddisc.len = 20; } else if (!strcasecmp(arg->argv[arg->argn], "psn")) { if (arg->argc > arg->argn+1) { mp->cfg.enddisc.class = ENDDISC_PSN; strcpy(mp->cfg.enddisc.address, arg->argv[arg->argn+1]); mp->cfg.enddisc.len = strlen(mp->cfg.enddisc.address); } else { log_Printf(LogWARN, "PSN endpoint requires additional data\n"); return 5; } } else { log_Printf(LogWARN, "%s: Unrecognised endpoint type\n", arg->argv[arg->argn]); return 6; } } return 0; } static int mpserver_UpdateSet(struct fdescriptor *d, fd_set *r, fd_set *w, fd_set *e, int *n) { struct mpserver *s = descriptor2mpserver(d); int result; result = 0; if (s->send.dl != NULL) { /* We've connect()ed */ if (!link_QueueLen(&s->send.dl->physical->link) && !s->send.dl->physical->out) { /* Only send if we've transmitted all our data (i.e. the ConfigAck) */ result -= datalink_RemoveFromSet(s->send.dl, r, w, e); bundle_SendDatalink(s->send.dl, s->fd, &s->socket); s->send.dl = NULL; s->fd = -1; } else /* Never read from a datalink that's on death row ! */ result -= datalink_RemoveFromSet(s->send.dl, r, NULL, NULL); } else if (r && s->fd >= 0) { if (*n < s->fd + 1) *n = s->fd + 1; FD_SET(s->fd, r); log_Printf(LogTIMER, "mp: fdset(r) %d\n", s->fd); result++; } return result; } static int mpserver_IsSet(struct fdescriptor *d, const fd_set *fdset) { struct mpserver *s = descriptor2mpserver(d); return s->fd >= 0 && FD_ISSET(s->fd, fdset); } static void mpserver_Read(struct fdescriptor *d, struct bundle *bundle, const fd_set *fdset __unused) { struct mpserver *s = descriptor2mpserver(d); bundle_ReceiveDatalink(bundle, s->fd); } static int mpserver_Write(struct fdescriptor *d __unused, struct bundle *bundle __unused, const fd_set *fdset __unused) { /* We never want to write here ! */ log_Printf(LogALERT, "mpserver_Write: Internal error: Bad call !\n"); return 0; } void mpserver_Init(struct mpserver *s) { s->desc.type = MPSERVER_DESCRIPTOR; s->desc.UpdateSet = mpserver_UpdateSet; s->desc.IsSet = mpserver_IsSet; s->desc.Read = mpserver_Read; s->desc.Write = mpserver_Write; s->send.dl = NULL; s->fd = -1; memset(&s->socket, '\0', sizeof s->socket); } int mpserver_Open(struct mpserver *s, struct peerid *peer) { int f, l; mode_t mask; if (s->fd != -1) { log_Printf(LogALERT, "Internal error ! mpserver already open\n"); mpserver_Close(s); } l = snprintf(s->socket.sun_path, sizeof s->socket.sun_path, "%sppp-%s-%02x-", _PATH_VARRUN, peer->authname, peer->enddisc.class); if (l < 0) { log_Printf(LogERROR, "mpserver: snprintf(): %s\n", strerror(errno)); return MPSERVER_FAILED; } for (f = 0; f < peer->enddisc.len && (size_t)l < sizeof s->socket.sun_path - 2; f++) { snprintf(s->socket.sun_path + l, sizeof s->socket.sun_path - l, "%02x", *(u_char *)(peer->enddisc.address+f)); l += 2; } s->socket.sun_family = AF_LOCAL; s->socket.sun_len = sizeof s->socket; s->fd = ID0socket(PF_LOCAL, SOCK_DGRAM, 0); if (s->fd < 0) { log_Printf(LogERROR, "mpserver: socket(): %s\n", strerror(errno)); return MPSERVER_FAILED; } setsockopt(s->fd, SOL_SOCKET, SO_REUSEADDR, (struct sockaddr *)&s->socket, sizeof s->socket); mask = umask(0177); /* * Try to bind the socket. If we succeed we play server, if we fail * we connect() and hand the link off. */ if (ID0bind_un(s->fd, &s->socket) < 0) { if (errno != EADDRINUSE) { log_Printf(LogPHASE, "mpserver: can't create bundle socket %s (%s)\n", s->socket.sun_path, strerror(errno)); umask(mask); close(s->fd); s->fd = -1; return MPSERVER_FAILED; } /* So we're the sender */ umask(mask); if (ID0connect_un(s->fd, &s->socket) < 0) { log_Printf(LogPHASE, "mpserver: can't connect to bundle socket %s (%s)\n", s->socket.sun_path, strerror(errno)); if (errno == ECONNREFUSED) log_Printf(LogPHASE, " The previous server died badly !\n"); close(s->fd); s->fd = -1; return MPSERVER_FAILED; } /* Donate our link to the other guy */ return MPSERVER_CONNECTED; } return MPSERVER_LISTENING; } void mpserver_Close(struct mpserver *s) { if (s->send.dl != NULL) { bundle_SendDatalink(s->send.dl, s->fd, &s->socket); s->send.dl = NULL; s->fd = -1; } else if (s->fd >= 0) { close(s->fd); if (ID0unlink(s->socket.sun_path) == -1) log_Printf(LogERROR, "%s: Failed to remove: %s\n", s->socket.sun_path, strerror(errno)); memset(&s->socket, '\0', sizeof s->socket); s->fd = -1; } } void mp_LinkLost(struct mp *mp, struct datalink *dl) { if (mp->seq.min_in == dl->mp.seq) /* We've lost the link that's holding everything up ! */ mp_Assemble(mp, NULL, NULL); } size_t mp_QueueLen(struct mp *mp) { return link_QueueLen(&mp->link); }