/* * Written by Eivind Eklund <eivind@yes.no> * for Yes Interactive * * Copyright (C) 1998, Yes Interactive. All rights reserved. * * Redistribution and use in any form is permitted. Redistribution in * source form should include the above copyright and this set of * conditions, because large sections american law seems to have been * created by a bunch of jerks on drugs that are now illegal, forcing * me to include this copyright-stuff instead of placing this in the * public domain. The name of of 'Yes Interactive' or 'Eivind Eklund' * may not be used to endorse or promote products derived from this * software without specific prior written permission. * THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED * WARRANTIES OF MERCHANTIBILITY AND FITNESS FOR A PARTICULAR PURPOSE. * */ #include <sys/param.h> #include <netinet/in.h> #include <netinet/in_systm.h> #include <netinet/ip.h> #include <sys/socket.h> #include <sys/time.h> #include <sys/un.h> #include <errno.h> #include <fcntl.h> #include <paths.h> #ifdef NOSUID #include <signal.h> #endif #include <stdarg.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <sys/uio.h> #include <sysexits.h> #include <termios.h> #include <time.h> #include <unistd.h> #include <utmpx.h> #if defined(__OpenBSD__) || defined(__NetBSD__) #include <sys/ioctl.h> #include <util.h> #else #include <libutil.h> #endif #include "layer.h" #ifndef NONAT #include "nat_cmd.h" #endif #include "proto.h" #include "acf.h" #include "vjcomp.h" #include "defs.h" #include "command.h" #include "mbuf.h" #include "log.h" #include "id.h" #include "timer.h" #include "fsm.h" #include "lqr.h" #include "hdlc.h" #include "lcp.h" #include "throughput.h" #include "sync.h" #include "async.h" #include "iplist.h" #include "slcompress.h" #include "ncpaddr.h" #include "ipcp.h" #include "filter.h" #include "descriptor.h" #include "ccp.h" #include "link.h" #include "physical.h" #include "mp.h" #ifndef NORADIUS #include "radius.h" #endif #include "ipv6cp.h" #include "ncp.h" #include "bundle.h" #include "prompt.h" #include "chat.h" #include "auth.h" #include "main.h" #include "chap.h" #include "cbcp.h" #include "datalink.h" #include "tcp.h" #include "udp.h" #include "exec.h" #include "tty.h" #ifndef NONETGRAPH #include "ether.h" #include "netgraph.h" #endif #include "tcpmss.h" static int physical_DescriptorWrite(struct fdescriptor *, struct bundle *, const fd_set *); static unsigned physical_DeviceSize(void) { return sizeof(struct device); } struct { struct device *(*create)(struct physical *); struct device *(*iov2device)(int, struct physical *, struct iovec *, int *, int, int *, int *); unsigned (*DeviceSize)(void); } devices[] = { { tty_Create, tty_iov2device, tty_DeviceSize }, #ifndef NONETGRAPH /* * This must come before ``udp'' so that the probe routine is * able to identify it as a more specific type of SOCK_DGRAM. */ { ether_Create, ether_iov2device, ether_DeviceSize }, #ifdef EXPERIMENTAL_NETGRAPH { ng_Create, ng_iov2device, ng_DeviceSize }, #endif #endif { tcp_Create, tcp_iov2device, tcp_DeviceSize }, { udp_Create, udp_iov2device, udp_DeviceSize }, { exec_Create, exec_iov2device, exec_DeviceSize } }; #define NDEVICES (sizeof devices / sizeof devices[0]) static int physical_UpdateSet(struct fdescriptor *d, fd_set *r, fd_set *w, fd_set *e, int *n) { return physical_doUpdateSet(d, r, w, e, n, 0); } void physical_SetDescriptor(struct physical *p) { p->desc.type = PHYSICAL_DESCRIPTOR; p->desc.UpdateSet = physical_UpdateSet; p->desc.IsSet = physical_IsSet; p->desc.Read = physical_DescriptorRead; p->desc.Write = physical_DescriptorWrite; } struct physical * physical_Create(struct datalink *dl, int type) { struct physical *p; p = (struct physical *)malloc(sizeof(struct physical)); if (!p) return NULL; p->link.type = PHYSICAL_LINK; p->link.name = dl->name; p->link.len = sizeof *p; /* The sample period is fixed - see physical2iov() & iov2physical() */ throughput_init(&p->link.stats.total, SAMPLE_PERIOD); p->link.stats.parent = dl->bundle->ncp.mp.active ? &dl->bundle->ncp.mp.link.stats.total : NULL; p->link.stats.gather = 1; memset(p->link.Queue, '\0', sizeof p->link.Queue); memset(p->link.proto_in, '\0', sizeof p->link.proto_in); memset(p->link.proto_out, '\0', sizeof p->link.proto_out); link_EmptyStack(&p->link); p->handler = NULL; physical_SetDescriptor(p); p->type = type; hdlc_Init(&p->hdlc, &p->link.lcp); async_Init(&p->async); p->fd = -1; p->out = NULL; p->connect_count = 0; p->dl = dl; p->input.sz = 0; *p->name.full = '\0'; p->name.base = p->name.full; p->Utmp = 0; p->session_owner = (pid_t)-1; p->cfg.rts_cts = MODEM_CTSRTS; p->cfg.speed = MODEM_SPEED; p->cfg.parity = CS8; memcpy(p->cfg.devlist, MODEM_LIST, sizeof MODEM_LIST); p->cfg.ndev = NMODEMS; p->cfg.cd.necessity = CD_DEFAULT; p->cfg.cd.delay = 0; /* reconfigured or device specific default */ lcp_Init(&p->link.lcp, dl->bundle, &p->link, &dl->fsmp); ccp_Init(&p->link.ccp, dl->bundle, &p->link, &dl->fsmp); return p; } static const struct parity { const char *name; const char *name1; int set; } validparity[] = { { "even", "P_EVEN", CS7 | PARENB }, { "odd", "P_ODD", CS7 | PARENB | PARODD }, { "none", "P_ZERO", CS8 }, { NULL, NULL, 0 }, }; static int GetParityValue(const char *str) { const struct parity *pp; for (pp = validparity; pp->name; pp++) { if (strcasecmp(pp->name, str) == 0 || strcasecmp(pp->name1, str) == 0) { return pp->set; } } return (-1); } int physical_SetParity(struct physical *p, const char *str) { struct termios rstio; int val; val = GetParityValue(str); if (val > 0) { p->cfg.parity = val; if (p->fd >= 0) { tcgetattr(p->fd, &rstio); rstio.c_cflag &= ~(CSIZE | PARODD | PARENB); rstio.c_cflag |= val; tcsetattr(p->fd, TCSADRAIN, &rstio); } return 0; } log_Printf(LogWARN, "%s: %s: Invalid parity\n", p->link.name, str); return -1; } unsigned physical_GetSpeed(struct physical *p) { if (p->handler && p->handler->speed) return (*p->handler->speed)(p); return 0; } int physical_SetSpeed(struct physical *p, unsigned speed) { if (UnsignedToSpeed(speed) != B0) { p->cfg.speed = speed; return 1; } return 0; } int physical_Raw(struct physical *p) { if (p->handler && p->handler->raw) return (*p->handler->raw)(p); return 1; } void physical_Offline(struct physical *p) { if (p->handler && p->handler->offline) (*p->handler->offline)(p); log_Printf(LogPHASE, "%s: Disconnected!\n", p->link.name); } static int physical_Lock(struct physical *p) { int res; if (*p->name.full == '/' && p->type != PHYS_DIRECT && (res = ID0uu_lock(p->name.base)) != UU_LOCK_OK) { if (res == UU_LOCK_INUSE) log_Printf(LogPHASE, "%s: %s is in use\n", p->link.name, p->name.full); else log_Printf(LogPHASE, "%s: %s is in use: uu_lock: %s\n", p->link.name, p->name.full, uu_lockerr(res)); return 0; } return 1; } static void physical_Unlock(struct physical *p) { if (*p->name.full == '/' && p->type != PHYS_DIRECT && ID0uu_unlock(p->name.base) == -1) log_Printf(LogALERT, "%s: Can't uu_unlock %s\n", p->link.name, p->name.base); } void physical_Close(struct physical *p) { int newsid; char fn[PATH_MAX]; struct utmpx ut; if (p->fd < 0) return; log_Printf(LogDEBUG, "%s: Close\n", p->link.name); if (p->handler && p->handler->cooked) (*p->handler->cooked)(p); physical_StopDeviceTimer(p); if (p->Utmp) { memset(&ut, 0, sizeof ut); ut.ut_type = DEAD_PROCESS; gettimeofday(&ut.ut_tv, NULL); snprintf(ut.ut_id, sizeof ut.ut_id, "%xppp", (int)getpid()); ID0logout(&ut); p->Utmp = 0; } newsid = tcgetpgrp(p->fd) == getpgrp(); close(p->fd); p->fd = -1; log_SetTtyCommandMode(p->dl); throughput_stop(&p->link.stats.total); throughput_log(&p->link.stats.total, LogPHASE, p->link.name); if (p->session_owner != (pid_t)-1) { log_Printf(LogPHASE, "%s: HUPing %ld\n", p->link.name, (long)p->session_owner); ID0kill(p->session_owner, SIGHUP); p->session_owner = (pid_t)-1; } if (newsid) bundle_setsid(p->dl->bundle, 0); if (*p->name.full == '/') { snprintf(fn, sizeof fn, "%s%s.if", _PATH_VARRUN, p->name.base); if (ID0unlink(fn) == -1) log_Printf(LogALERT, "%s: Can't remove %s: %s\n", p->link.name, fn, strerror(errno)); } physical_Unlock(p); if (p->handler && p->handler->destroy) (*p->handler->destroy)(p); p->handler = NULL; p->name.base = p->name.full; *p->name.full = '\0'; } void physical_Destroy(struct physical *p) { physical_Close(p); throughput_destroy(&p->link.stats.total); free(p); } static int physical_DescriptorWrite(struct fdescriptor *d, struct bundle *bundle __unused, const fd_set *fdset __unused) { struct physical *p = descriptor2physical(d); int nw, result = 0; if (p->out == NULL) p->out = link_Dequeue(&p->link); if (p->out) { nw = physical_Write(p, MBUF_CTOP(p->out), p->out->m_len); log_Printf(LogDEBUG, "%s: DescriptorWrite: wrote %d(%lu) to %d\n", p->link.name, nw, (unsigned long)p->out->m_len, p->fd); if (nw > 0) { p->out->m_len -= nw; p->out->m_offset += nw; if (p->out->m_len == 0) p->out = m_free(p->out); result = 1; } else if (nw < 0) { if (errno == EAGAIN) result = 1; else if (errno != ENOBUFS) { log_Printf(LogPHASE, "%s: write (fd %d, len %zd): %s\n", p->link.name, p->fd, p->out->m_len, strerror(errno)); datalink_Down(p->dl, CLOSE_NORMAL); } } /* else we shouldn't really have been called ! select() is broken ! */ } return result; } int physical_ShowStatus(struct cmdargs const *arg) { struct physical *p = arg->cx->physical; struct cd *cd; const char *dev; int n, slot; prompt_Printf(arg->prompt, "Name: %s\n", p->link.name); prompt_Printf(arg->prompt, " State: "); if (p->fd < 0) prompt_Printf(arg->prompt, "closed\n"); else { slot = physical_Slot(p); if (p->handler && p->handler->openinfo) { if (slot == -1) prompt_Printf(arg->prompt, "open (%s)\n", (*p->handler->openinfo)(p)); else prompt_Printf(arg->prompt, "open (%s, port %d)\n", (*p->handler->openinfo)(p), slot); } else if (slot == -1) prompt_Printf(arg->prompt, "open\n"); else prompt_Printf(arg->prompt, "open (port %d)\n", slot); } prompt_Printf(arg->prompt, " Device: %s", *p->name.full ? p->name.full : p->type == PHYS_DIRECT ? "unknown" : "N/A"); if (p->session_owner != (pid_t)-1) prompt_Printf(arg->prompt, " (session owner: %ld)", (long)p->session_owner); prompt_Printf(arg->prompt, "\n Link Type: %s\n", mode2Nam(p->type)); prompt_Printf(arg->prompt, " Connect Count: %d\n", p->connect_count); #ifdef TIOCOUTQ if (p->fd >= 0 && ioctl(p->fd, TIOCOUTQ, &n) >= 0) prompt_Printf(arg->prompt, " Physical outq: %d\n", n); #endif prompt_Printf(arg->prompt, " Queued Packets: %lu\n", (u_long)link_QueueLen(&p->link)); prompt_Printf(arg->prompt, " Phone Number: %s\n", arg->cx->phone.chosen); prompt_Printf(arg->prompt, "\nDefaults:\n"); prompt_Printf(arg->prompt, " Device List: "); dev = p->cfg.devlist; for (n = 0; n < p->cfg.ndev; n++) { if (n) prompt_Printf(arg->prompt, ", "); prompt_Printf(arg->prompt, "\"%s\"", dev); dev += strlen(dev) + 1; } prompt_Printf(arg->prompt, "\n Characteristics: "); if (physical_IsSync(arg->cx->physical)) prompt_Printf(arg->prompt, "sync"); else prompt_Printf(arg->prompt, "%dbps", p->cfg.speed); switch (p->cfg.parity & CSIZE) { case CS7: prompt_Printf(arg->prompt, ", cs7"); break; case CS8: prompt_Printf(arg->prompt, ", cs8"); break; } if (p->cfg.parity & PARENB) { if (p->cfg.parity & PARODD) prompt_Printf(arg->prompt, ", odd parity"); else prompt_Printf(arg->prompt, ", even parity"); } else prompt_Printf(arg->prompt, ", no parity"); prompt_Printf(arg->prompt, ", CTS/RTS %s\n", (p->cfg.rts_cts ? "on" : "off")); prompt_Printf(arg->prompt, " CD check delay: "); cd = p->handler ? &p->handler->cd : &p->cfg.cd; if (cd->necessity == CD_NOTREQUIRED) prompt_Printf(arg->prompt, "no cd"); else if (p->cfg.cd.necessity == CD_DEFAULT) { prompt_Printf(arg->prompt, "device specific"); } else { prompt_Printf(arg->prompt, "%d second%s", p->cfg.cd.delay, p->cfg.cd.delay == 1 ? "" : "s"); if (p->cfg.cd.necessity == CD_REQUIRED) prompt_Printf(arg->prompt, " (required!)"); } prompt_Printf(arg->prompt, "\n\n"); throughput_disp(&p->link.stats.total, arg->prompt); return 0; } void physical_DescriptorRead(struct fdescriptor *d, struct bundle *bundle, const fd_set *fdset __unused) { struct physical *p = descriptor2physical(d); u_char *rbuff; int n, found; rbuff = p->input.buf + p->input.sz; /* something to read */ n = physical_Read(p, rbuff, sizeof p->input.buf - p->input.sz); log_Printf(LogDEBUG, "%s: DescriptorRead: read %d/%d from %d\n", p->link.name, n, (int)(sizeof p->input.buf - p->input.sz), p->fd); if (n <= 0) { if (n < 0) log_Printf(LogPHASE, "%s: read (%d): %s\n", p->link.name, p->fd, strerror(errno)); else log_Printf(LogPHASE, "%s: read (%d): Got zero bytes\n", p->link.name, p->fd); datalink_Down(p->dl, CLOSE_NORMAL); return; } rbuff -= p->input.sz; n += p->input.sz; if (p->link.lcp.fsm.state <= ST_CLOSED) { if (p->type != PHYS_DEDICATED) { found = hdlc_Detect((u_char const **)&rbuff, n, physical_IsSync(p)); if (rbuff != p->input.buf) log_WritePrompts(p->dl, "%.*s", (int)(rbuff - p->input.buf), p->input.buf); p->input.sz = n - (rbuff - p->input.buf); if (found) { /* LCP packet is detected. Turn ourselves into packet mode */ log_Printf(LogPHASE, "%s: PPP packet detected, coming up\n", p->link.name); log_SetTtyCommandMode(p->dl); datalink_Up(p->dl, 0, 1); link_PullPacket(&p->link, rbuff, p->input.sz, bundle); p->input.sz = 0; } else bcopy(rbuff, p->input.buf, p->input.sz); } else /* In -dedicated mode, we just discard input until LCP is started */ p->input.sz = 0; } else if (n > 0) link_PullPacket(&p->link, rbuff, n, bundle); } struct physical * iov2physical(struct datalink *dl, struct iovec *iov, int *niov, int maxiov, int fd, int *auxfd, int *nauxfd) { struct physical *p; int type; unsigned h; p = (struct physical *)iov[(*niov)++].iov_base; p->link.name = dl->name; memset(p->link.Queue, '\0', sizeof p->link.Queue); p->desc.UpdateSet = physical_UpdateSet; p->desc.IsSet = physical_IsSet; p->desc.Read = physical_DescriptorRead; p->desc.Write = physical_DescriptorWrite; p->type = PHYS_DIRECT; p->dl = dl; p->out = NULL; p->connect_count = 1; physical_SetDevice(p, p->name.full); p->link.lcp.fsm.bundle = dl->bundle; p->link.lcp.fsm.link = &p->link; memset(&p->link.lcp.fsm.FsmTimer, '\0', sizeof p->link.lcp.fsm.FsmTimer); memset(&p->link.lcp.fsm.OpenTimer, '\0', sizeof p->link.lcp.fsm.OpenTimer); memset(&p->link.lcp.fsm.StoppedTimer, '\0', sizeof p->link.lcp.fsm.StoppedTimer); p->link.lcp.fsm.parent = &dl->fsmp; lcp_SetupCallbacks(&p->link.lcp); p->link.ccp.fsm.bundle = dl->bundle; p->link.ccp.fsm.link = &p->link; /* Our in.state & out.state are NULL (no link-level ccp yet) */ memset(&p->link.ccp.fsm.FsmTimer, '\0', sizeof p->link.ccp.fsm.FsmTimer); memset(&p->link.ccp.fsm.OpenTimer, '\0', sizeof p->link.ccp.fsm.OpenTimer); memset(&p->link.ccp.fsm.StoppedTimer, '\0', sizeof p->link.ccp.fsm.StoppedTimer); p->link.ccp.fsm.parent = &dl->fsmp; ccp_SetupCallbacks(&p->link.ccp); p->hdlc.lqm.owner = &p->link.lcp; p->hdlc.ReportTimer.state = TIMER_STOPPED; p->hdlc.lqm.timer.state = TIMER_STOPPED; p->fd = fd; p->link.stats.total.in.SampleOctets = (long long *)iov[(*niov)++].iov_base; p->link.stats.total.out.SampleOctets = (long long *)iov[(*niov)++].iov_base; p->link.stats.parent = dl->bundle->ncp.mp.active ? &dl->bundle->ncp.mp.link.stats.total : NULL; p->link.stats.gather = 1; type = (long)p->handler; p->handler = NULL; for (h = 0; h < NDEVICES && p->handler == NULL; h++) p->handler = (*devices[h].iov2device)(type, p, iov, niov, maxiov, auxfd, nauxfd); if (p->handler == NULL) { log_Printf(LogPHASE, "%s: Unknown link type\n", p->link.name); free(iov[(*niov)++].iov_base); physical_SetupStack(p, "unknown", PHYSICAL_NOFORCE); } else log_Printf(LogPHASE, "%s: Device %s, link type is %s\n", p->link.name, p->name.full, p->handler->name); if (p->hdlc.lqm.method && p->hdlc.lqm.timer.load) lqr_reStart(&p->link.lcp); hdlc_StartTimer(&p->hdlc); throughput_restart(&p->link.stats.total, "physical throughput", Enabled(dl->bundle, OPT_THROUGHPUT)); return p; } unsigned physical_MaxDeviceSize(void) { unsigned biggest, sz, n; biggest = sizeof(struct device); for (n = 0; n < NDEVICES; n++) if (devices[n].DeviceSize) { sz = (*devices[n].DeviceSize)(); if (biggest < sz) biggest = sz; } return biggest; } int physical2iov(struct physical *p, struct iovec *iov, int *niov, int maxiov, int *auxfd, int *nauxfd) { struct device *h; int sz; h = NULL; if (p) { hdlc_StopTimer(&p->hdlc); lqr_StopTimer(p); timer_Stop(&p->link.lcp.fsm.FsmTimer); timer_Stop(&p->link.ccp.fsm.FsmTimer); timer_Stop(&p->link.lcp.fsm.OpenTimer); timer_Stop(&p->link.ccp.fsm.OpenTimer); timer_Stop(&p->link.lcp.fsm.StoppedTimer); timer_Stop(&p->link.ccp.fsm.StoppedTimer); if (p->handler) { h = p->handler; p->handler = (struct device *)(long)p->handler->type; } if (Enabled(p->dl->bundle, OPT_KEEPSESSION) || tcgetpgrp(p->fd) == getpgrp()) p->session_owner = getpid(); /* So I'll eventually get HUP'd */ else p->session_owner = (pid_t)-1; timer_Stop(&p->link.stats.total.Timer); } if (*niov + 2 >= maxiov) { log_Printf(LogERROR, "physical2iov: No room for physical + throughput" " + device !\n"); if (p) free(p); return -1; } iov[*niov].iov_base = (void *)p; iov[*niov].iov_len = sizeof *p; (*niov)++; iov[*niov].iov_base = p ? (void *)p->link.stats.total.in.SampleOctets : NULL; iov[*niov].iov_len = SAMPLE_PERIOD * sizeof(long long); (*niov)++; iov[*niov].iov_base = p ? (void *)p->link.stats.total.out.SampleOctets : NULL; iov[*niov].iov_len = SAMPLE_PERIOD * sizeof(long long); (*niov)++; sz = physical_MaxDeviceSize(); if (p) { if (h && h->device2iov) (*h->device2iov)(h, iov, niov, maxiov, auxfd, nauxfd); else { if ((iov[*niov].iov_base = malloc(sz)) == NULL) { log_Printf(LogALERT, "physical2iov: Out of memory (%d bytes)\n", sz); AbortProgram(EX_OSERR); } if (h) memcpy(iov[*niov].iov_base, h, sizeof *h); iov[*niov].iov_len = sz; (*niov)++; } } else { iov[*niov].iov_base = NULL; iov[*niov].iov_len = sz; (*niov)++; } return p ? p->fd : 0; } const char * physical_LockedDevice(struct physical *p) { if (p->fd >= 0 && *p->name.full == '/' && p->type != PHYS_DIRECT) return p->name.base; return NULL; } void physical_ChangedPid(struct physical *p, pid_t newpid) { if (physical_LockedDevice(p)) { int res; if ((res = ID0uu_lock_txfr(p->name.base, newpid)) != UU_LOCK_OK) log_Printf(LogPHASE, "uu_lock_txfr: %s\n", uu_lockerr(res)); } } int physical_IsSync(struct physical *p) { return p->cfg.speed == 0; } u_short physical_DeviceMTU(struct physical *p) { return p->handler ? p->handler->mtu : 0; } const char *physical_GetDevice(struct physical *p) { return p->name.full; } void physical_SetDeviceList(struct physical *p, int argc, const char *const *argv) { unsigned pos; int f; p->cfg.devlist[sizeof p->cfg.devlist - 1] = '\0'; for (f = 0, pos = 0; f < argc && pos < sizeof p->cfg.devlist - 1; f++) { if (pos) p->cfg.devlist[pos++] = '\0'; strncpy(p->cfg.devlist + pos, argv[f], sizeof p->cfg.devlist - pos - 1); pos += strlen(p->cfg.devlist + pos); } p->cfg.ndev = f; } void physical_SetSync(struct physical *p) { p->cfg.speed = 0; } int physical_SetRtsCts(struct physical *p, int enable) { p->cfg.rts_cts = enable ? 1 : 0; return 1; } ssize_t physical_Read(struct physical *p, void *buf, size_t nbytes) { ssize_t ret; if (p->handler && p->handler->read) ret = (*p->handler->read)(p, buf, nbytes); else ret = read(p->fd, buf, nbytes); log_DumpBuff(LogPHYSICAL, "read", buf, ret); return ret; } ssize_t physical_Write(struct physical *p, const void *buf, size_t nbytes) { log_DumpBuff(LogPHYSICAL, "write", buf, nbytes); if (p->handler && p->handler->write) return (*p->handler->write)(p, buf, nbytes); return write(p->fd, buf, nbytes); } int physical_doUpdateSet(struct fdescriptor *d, fd_set *r, fd_set *w, fd_set *e, int *n, int force) { struct physical *p = descriptor2physical(d); int sets; sets = 0; if (p->fd >= 0) { if (r) { FD_SET(p->fd, r); log_Printf(LogTIMER, "%s: fdset(r) %d\n", p->link.name, p->fd); sets++; } if (e) { FD_SET(p->fd, e); log_Printf(LogTIMER, "%s: fdset(e) %d\n", p->link.name, p->fd); sets++; } if (w && (force || link_QueueLen(&p->link) || p->out)) { FD_SET(p->fd, w); log_Printf(LogTIMER, "%s: fdset(w) %d\n", p->link.name, p->fd); sets++; } if (sets && *n < p->fd + 1) *n = p->fd + 1; } return sets; } int physical_RemoveFromSet(struct physical *p, fd_set *r, fd_set *w, fd_set *e) { if (p->handler && p->handler->removefromset) return (*p->handler->removefromset)(p, r, w, e); else { int sets; sets = 0; if (p->fd >= 0) { if (r && FD_ISSET(p->fd, r)) { FD_CLR(p->fd, r); log_Printf(LogTIMER, "%s: fdunset(r) %d\n", p->link.name, p->fd); sets++; } if (e && FD_ISSET(p->fd, e)) { FD_CLR(p->fd, e); log_Printf(LogTIMER, "%s: fdunset(e) %d\n", p->link.name, p->fd); sets++; } if (w && FD_ISSET(p->fd, w)) { FD_CLR(p->fd, w); log_Printf(LogTIMER, "%s: fdunset(w) %d\n", p->link.name, p->fd); sets++; } } return sets; } } int physical_IsSet(struct fdescriptor *d, const fd_set *fdset) { struct physical *p = descriptor2physical(d); return p->fd >= 0 && FD_ISSET(p->fd, fdset); } void physical_Login(struct physical *p, const char *name) { if (p->type == PHYS_DIRECT && *p->name.base && !p->Utmp) { struct utmpx ut; const char *connstr; char *colon; memset(&ut, 0, sizeof ut); ut.ut_type = USER_PROCESS; gettimeofday(&ut.ut_tv, NULL); snprintf(ut.ut_id, sizeof ut.ut_id, "%xppp", (int)getpid()); strncpy(ut.ut_user, name, sizeof ut.ut_user); if (p->handler && (p->handler->type == TCP_DEVICE || p->handler->type == UDP_DEVICE)) { strncpy(ut.ut_host, p->name.base, sizeof ut.ut_host); colon = memchr(ut.ut_host, ':', sizeof ut.ut_host); if (colon) *colon = '\0'; } else strncpy(ut.ut_line, p->name.base, sizeof ut.ut_line); if ((connstr = getenv("CONNECT"))) /* mgetty sets this to the connection speed */ strncpy(ut.ut_host, connstr, sizeof ut.ut_host); ID0login(&ut); p->Utmp = 1; } } int physical_SetMode(struct physical *p, int mode) { if ((p->type & (PHYS_DIRECT|PHYS_DEDICATED) || mode & (PHYS_DIRECT|PHYS_DEDICATED)) && (!(p->type & PHYS_DIRECT) || !(mode & PHYS_BACKGROUND))) { /* Note: The -direct -> -background is for callback ! */ log_Printf(LogWARN, "%s: Cannot change mode %s to %s\n", p->link.name, mode2Nam(p->type), mode2Nam(mode)); return 0; } p->type = mode; return 1; } void physical_DeleteQueue(struct physical *p) { if (p->out) { m_freem(p->out); p->out = NULL; } link_DeleteQueue(&p->link); } void physical_SetDevice(struct physical *p, const char *name) { int len = strlen(_PATH_DEV); if (name != p->name.full) { strncpy(p->name.full, name, sizeof p->name.full - 1); p->name.full[sizeof p->name.full - 1] = '\0'; } p->name.base = *p->name.full == '!' ? p->name.full + 1 : strncmp(p->name.full, _PATH_DEV, len) ? p->name.full : p->name.full + len; } static void physical_Found(struct physical *p) { FILE *lockfile; char fn[PATH_MAX]; if (*p->name.full == '/') { snprintf(fn, sizeof fn, "%s%s.if", _PATH_VARRUN, p->name.base); lockfile = ID0fopen(fn, "w"); if (lockfile != NULL) { fprintf(lockfile, "%s%d\n", TUN_NAME, p->dl->bundle->unit); fclose(lockfile); } else log_Printf(LogALERT, "%s: Can't create %s: %s\n", p->link.name, fn, strerror(errno)); } throughput_start(&p->link.stats.total, "physical throughput", Enabled(p->dl->bundle, OPT_THROUGHPUT)); p->connect_count++; p->input.sz = 0; log_Printf(LogPHASE, "%s: Connected!\n", p->link.name); } int physical_Open(struct physical *p) { char *dev; int devno, wasfd, err; unsigned h; if (p->fd >= 0) log_Printf(LogDEBUG, "%s: Open: Modem is already open!\n", p->link.name); /* We're going back into "term" mode */ else if (p->type == PHYS_DIRECT) { physical_SetDevice(p, ""); p->fd = STDIN_FILENO; for (h = 0; h < NDEVICES && p->handler == NULL && p->fd >= 0; h++) p->handler = (*devices[h].create)(p); close(STDOUT_FILENO); if (p->fd >= 0) { if (p->handler == NULL) { physical_SetupStack(p, "unknown", PHYSICAL_NOFORCE); log_Printf(LogDEBUG, "%s: stdin is unidentified\n", p->link.name); } physical_Found(p); } } else { dev = p->cfg.devlist; devno = 0; while (devno < p->cfg.ndev && p->fd < 0) { physical_SetDevice(p, dev); if (physical_Lock(p)) { err = 0; if (*p->name.full == '/') { p->fd = ID0open(p->name.full, O_RDWR | O_NONBLOCK); if (p->fd < 0) err = errno; } wasfd = p->fd; for (h = 0; h < NDEVICES && p->handler == NULL; h++) if ((p->handler = (*devices[h].create)(p)) == NULL && wasfd != p->fd) break; if (p->fd < 0) { if (h == NDEVICES) { if (err) log_Printf(LogWARN, "%s: %s: %s\n", p->link.name, p->name.full, strerror(errno)); else log_Printf(LogWARN, "%s: Device (%s) must begin with a '/'," " a '!' or contain at least one ':'\n", p->link.name, p->name.full); } physical_Unlock(p); } else physical_Found(p); } dev += strlen(dev) + 1; devno++; } } return p->fd; } void physical_SetupStack(struct physical *p, const char *who, int how) { link_EmptyStack(&p->link); if (how == PHYSICAL_FORCE_SYNC || how == PHYSICAL_FORCE_SYNCNOACF || (how == PHYSICAL_NOFORCE && physical_IsSync(p))) link_Stack(&p->link, &synclayer); else { link_Stack(&p->link, &asynclayer); link_Stack(&p->link, &hdlclayer); } if (how != PHYSICAL_FORCE_SYNCNOACF) link_Stack(&p->link, &acflayer); link_Stack(&p->link, &protolayer); link_Stack(&p->link, &lqrlayer); link_Stack(&p->link, &ccplayer); link_Stack(&p->link, &vjlayer); link_Stack(&p->link, &tcpmsslayer); #ifndef NONAT link_Stack(&p->link, &natlayer); #endif if (how == PHYSICAL_FORCE_ASYNC && physical_IsSync(p)) { log_Printf(LogWARN, "Sync device setting ignored for ``%s'' device\n", who); p->cfg.speed = MODEM_SPEED; } else if (how == PHYSICAL_FORCE_SYNC && !physical_IsSync(p)) { log_Printf(LogWARN, "Async device setting ignored for ``%s'' device\n", who); physical_SetSync(p); } } void physical_StopDeviceTimer(struct physical *p) { if (p->handler && p->handler->stoptimer) (*p->handler->stoptimer)(p); } int physical_AwaitCarrier(struct physical *p) { if (p->handler && p->handler->awaitcarrier) return (*p->handler->awaitcarrier)(p); return CARRIER_OK; } void physical_SetAsyncParams(struct physical *p, u_int32_t mymap, u_int32_t hismap) { if (p->handler && p->handler->setasyncparams) return (*p->handler->setasyncparams)(p, mymap, hismap); async_SetLinkParams(&p->async, mymap, hismap); } int physical_Slot(struct physical *p) { if (p->handler && p->handler->slot) return (*p->handler->slot)(p); return -1; } int physical_SetPPPoEnonstandard(struct physical *p, int enable) { p->cfg.nonstandard_pppoe = enable ? 1 : 0; p->cfg.pppoe_configured = 1; return 1; }