/* trans.c Routines to handle file transfers. Copyright (C) 1992, 1993, 1995 Ian Lance Taylor This file is part of the Taylor UUCP package. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. The author of the program may be contacted at ian@airs.com or c/o Cygnus Support, 48 Grove Street, Somerville, MA 02144. */ #include "uucp.h" #if USE_RCS_ID const char trans_rcsid[] = "$Id: trans.c,v 1.1 1995/10/18 08:38:41 deraadt Exp $"; #endif #include #include "uudefs.h" #include "uuconf.h" #include "prot.h" #include "system.h" #include "trans.h" /* Local functions. */ static void utqueue P((struct stransfer **, struct stransfer *, boolean fhead)); static void utdequeue P((struct stransfer *)); static void utchanalc P((struct sdaemon *qdaemon, struct stransfer *qtrans)); __inline__ static struct stransfer *qtchan P((int ichan)); __inline__ static void utchanfree P((struct stransfer *qtrans)); static boolean fttime P((struct sdaemon *qdaemon, long *pisecs, long *pimicros)); static boolean fcheck_queue P((struct sdaemon *qdaemon)); static boolean ftadd_cmd P((struct sdaemon *qdaemon, const char *z, size_t cdata, int iremote, boolean flast)); static boolean fremote_hangup_reply P((struct stransfer *qtrans, struct sdaemon *qdaemon)); static boolean flocal_poll_file P((struct stransfer *qtrans, struct sdaemon *qdaemon)); /* Queue of transfer structures that are ready to start which have been requested by the local system. These are only permitted to start when the local system is the master. */ static struct stransfer *qTlocal; /* Queue of transfer structures that are ready to start which have been requested by the remote system. These are responses to commands received from the remote system, and should be started as soon as possible. */ static struct stransfer *qTremote; /* Queue of transfer structures that have been started and want to send information. This should be static, but the 'a' protocol looks at it, at least for now. */ struct stransfer *qTsend; /* Queue of transfer structures that have been started and are waiting to receive information. */ static struct stransfer *qTreceive; /* Queue of free transfer structures. */ static struct stransfer *qTavail; /* Array of transfer structures indexed by local channel number. This is maintained for local jobs. */ static struct stransfer *aqTchan[IMAX_CHAN + 1]; /* Number of local channel numbers currently allocated. */ static int cTchans; /* Next channel number to allocate. */ static int iTchan; /* Array of transfer structures indexed by remote channel number. This is maintained for remote jobs. */ static struct stransfer *aqTremote[IMAX_CHAN + 1]; /* The transaction we are currently receiving. This is used to avoid getting the time too frequently. */ static struct stransfer *qTtiming_rec; /* The time from which to charge any received data. This is either the last time we charged for received data, or the last time something was put on the empty receive queue. */ static long iTrecsecs; static long iTrecmicros; /* The minimum amount of time, in seconds, to wait between times we check the spool directory, if we are busy transferring data. If we have nothing to do, we will check the spool directory regardless of how long ago the last check was. This should probably be configurable. */ #define CCHECKWAIT (600) /* The time we last checked the spool directory for work. This is set from the return value of ixsysdep_process_time, not ixsysdep_time, for convenience in the routines which use it. */ static long iTchecktime; /* The size of the command we have read so far in ftadd_cmd. */ static size_t cTcmdlen; /* The structure we use when waiting for an acknowledgement of a confirmed received file in fsent_receive_ack, and a list of those structures. */ struct sreceive_ack { struct sreceive_ack *qnext; char *zto; char *ztemp; boolean fmarked; }; static struct sreceive_ack *qTreceive_ack; /* Queue up a transfer structure before *pq. This puts it at the head or the tail of the list headed by *pq. */ static void utqueue (pq, q, fhead) struct stransfer **pq; struct stransfer *q; boolean fhead; { if (*pq == NULL) { *pq = q; q->qprev = q->qnext = q; } else { q->qnext = *pq; q->qprev = (*pq)->qprev; q->qprev->qnext = q; q->qnext->qprev = q; if (fhead) *pq = q; } q->pqqueue = pq; } /* Dequeue a transfer structure. */ static void utdequeue (q) struct stransfer *q; { if (q->pqqueue != NULL) { if (*(q->pqqueue) == q) { if (q->qnext == q) *(q->pqqueue) = NULL; else *(q->pqqueue) = q->qnext; } q->pqqueue = NULL; } if (q->qprev != NULL) q->qprev->qnext = q->qnext; if (q->qnext != NULL) q->qnext->qprev = q->qprev; q->qprev = NULL; q->qnext = NULL; } /* Queue up a transfer structure requested by the local system. */ /*ARGSIGNORED*/ boolean fqueue_local (qdaemon, qtrans) struct sdaemon *qdaemon; struct stransfer *qtrans; { utdequeue (qtrans); utqueue (&qTlocal, qtrans, FALSE); return TRUE; } /* Queue up a transfer structure requested by the remote system. The stransfer structure should have the iremote field set. We need to record it, so that any subsequent data associated with this channel can be routed to the right place. */ boolean fqueue_remote (qdaemon, qtrans) struct sdaemon *qdaemon; struct stransfer *qtrans; { DEBUG_MESSAGE1 (DEBUG_UUCP_PROTO, "fqueue_remote: Channel %d", qtrans->iremote); if (qtrans->iremote > 0) aqTremote[qtrans->iremote] = qtrans; utdequeue (qtrans); utqueue (&qTremote, qtrans, FALSE); return TRUE; } /* Queue up a transfer with something to send. */ boolean fqueue_send (qdaemon, qtrans) struct sdaemon *qdaemon; struct stransfer *qtrans; { #if DEBUG > 0 if (qtrans->psendfn == NULL) ulog (LOG_FATAL, "fqueue_send: Bad call"); #endif utdequeue (qtrans); /* Sort the send queue to always send commands before files, and to sort jobs by grade. */ if (qTsend == NULL) utqueue (&qTsend, qtrans, FALSE); else { register struct stransfer *q; boolean ffirst; ffirst = TRUE; q = qTsend; do { if (! qtrans->fsendfile && q->fsendfile) break; if ((! qtrans->fsendfile || q->fsendfile) && UUCONF_GRADE_CMP (qtrans->s.bgrade, q->s.bgrade) < 0) break; ffirst = FALSE; q = q->qnext; } while (q != qTsend); qtrans->qnext = q; qtrans->qprev = q->qprev; q->qprev = qtrans; qtrans->qprev->qnext = qtrans; if (ffirst) qTsend = qtrans; qtrans->pqqueue = &qTsend; } return TRUE; } /* Queue up a transfer with something to receive. */ boolean fqueue_receive (qdaemon, qtrans) struct sdaemon *qdaemon; struct stransfer *qtrans; { #if DEBUG > 0 if (qtrans->precfn == NULL) ulog (LOG_FATAL, "fqueue_receive: Bad call"); #endif /* If this is the only item on the receive queue, we do not want to charge it for any time during which we have not been waiting for anything, so update the receive timestamp. */ if (qTreceive == NULL) iTrecsecs = ixsysdep_process_time (&iTrecmicros); utdequeue (qtrans); utqueue (&qTreceive, qtrans, FALSE); return TRUE; } /* Get a new local channel number. */ static void utchanalc (qdaemon, qtrans) struct sdaemon *qdaemon; struct stransfer *qtrans; { do { ++iTchan; if (iTchan > qdaemon->cchans) iTchan = 1; } while (aqTchan[iTchan] != NULL); qtrans->ilocal = iTchan; aqTchan[iTchan] = qtrans; ++cTchans; } /* Return the transfer for a channel number. */ __inline__ static struct stransfer * qtchan (ic) int ic; { return aqTchan[ic]; } /* Clear the channel number for a transfer. */ __inline__ static void utchanfree (qt) struct stransfer *qt; { if (qt->ilocal != 0) { aqTchan[qt->ilocal] = NULL; qt->ilocal = 0; --cTchans; } } /* Allocate a new transfer structure. */ struct stransfer * qtransalc (qcmd) struct scmd *qcmd; { register struct stransfer *q; q = qTavail; if (q != NULL) utdequeue (q); else q = (struct stransfer *) xmalloc (sizeof (struct stransfer)); q->qnext = NULL; q->qprev = NULL; q->pqqueue = NULL; q->psendfn = NULL; q->precfn = NULL; q->pinfo = NULL; q->fsendfile = FALSE; q->frecfile = FALSE; q->e = EFILECLOSED; q->ipos = 0; q->fcmd = FALSE; q->zcmd = NULL; q->ccmd = 0; q->ilocal = 0; q->iremote = 0; if (qcmd != NULL) { q->s = *qcmd; q->s.zfrom = zbufcpy (qcmd->zfrom); q->s.zto = zbufcpy (qcmd->zto); q->s.zuser = zbufcpy (qcmd->zuser); q->s.zoptions = zbufcpy (qcmd->zoptions); q->s.ztemp = zbufcpy (qcmd->ztemp); q->s.znotify = zbufcpy (qcmd->znotify); q->s.zcmd = zbufcpy (qcmd->zcmd); } else { q->s.zfrom = NULL; q->s.zto = NULL; q->s.zuser = NULL; q->s.zoptions = NULL; q->s.ztemp = NULL; q->s.znotify = NULL; q->s.zcmd = NULL; } q->zlog = NULL; q->isecs = 0; q->imicros = 0; q->cbytes = 0; return q; } /* Free a transfer structure. This does not free any pinfo information that may have been allocated. */ void utransfree (q) struct stransfer *q; { ubuffree (q->zcmd); ubuffree ((char *) q->s.zfrom); ubuffree ((char *) q->s.zto); ubuffree ((char *) q->s.zuser); ubuffree ((char *) q->s.zoptions); ubuffree ((char *) q->s.ztemp); ubuffree ((char *) q->s.znotify); ubuffree ((char *) q->s.zcmd); utchanfree (q); if (q->iremote > 0) { aqTremote[q->iremote] = NULL; q->iremote = 0; } #if DEBUG > 0 q->e = EFILECLOSED; q->zcmd = NULL; q->s.zfrom = NULL; q->s.zto = NULL; q->s.zuser = NULL; q->s.zoptions = NULL; q->s.ztemp = NULL; q->s.znotify = NULL; q->s.zcmd = NULL; q->psendfn = NULL; q->precfn = NULL; #endif /* Avoid any possible confusion in the timing code. */ if (qTtiming_rec == q) qTtiming_rec = NULL; utdequeue (q); utqueue (&qTavail, q, FALSE); } /* Get the time. This is a wrapper around ixsysdep_process_time. If enough time has elapsed since the last time we got the time, check the work queue. */ static boolean fttime (qdaemon, pisecs, pimicros) struct sdaemon *qdaemon; long *pisecs; long *pimicros; { *pisecs = ixsysdep_process_time (pimicros); if (*pisecs - iTchecktime >= CCHECKWAIT) { if (! fcheck_queue (qdaemon)) return FALSE; } return TRUE; } /* Gather local commands and queue them up for later processing. Also recompute time based control values. */ boolean fqueue (qdaemon, pfany) struct sdaemon *qdaemon; boolean *pfany; { const struct uuconf_system *qsys; long ival; int bgrade; struct uuconf_timespan *qlocal_size, *qremote_size; if (pfany != NULL) *pfany = FALSE; qsys = qdaemon->qsys; /* If we are not the caller, the grade will be set during the initial handshake, although this may be overridden by the calledtimegrade configuration option. */ if (! qdaemon->fcaller) { if (! ftimespan_match (qsys->uuconf_qcalledtimegrade, &ival, (int *) NULL)) bgrade = qdaemon->bgrade; else bgrade = (char) ival; } else { if (! ftimespan_match (qsys->uuconf_qtimegrade, &ival, (int *) NULL)) bgrade = '\0'; else bgrade = (char) ival; } /* Determine the maximum sizes we can send and receive. */ if (qdaemon->fcaller) { qlocal_size = qsys->uuconf_qcall_local_size; qremote_size = qsys->uuconf_qcall_remote_size; } else { qlocal_size = qsys->uuconf_qcalled_local_size; qremote_size = qsys->uuconf_qcalled_remote_size; } if (! ftimespan_match (qlocal_size, &qdaemon->clocal_size, (int *) NULL)) qdaemon->clocal_size = (long) -1; if (! ftimespan_match (qremote_size, &qdaemon->cremote_size, (int *) NULL)) qdaemon->cremote_size = (long) -1; if (bgrade == '\0') return TRUE; if (! fsysdep_get_work_init (qsys, bgrade)) return FALSE; while (TRUE) { struct scmd s; if (! fsysdep_get_work (qsys, bgrade, &s)) return FALSE; if (s.bcmd == 'H') { ulog_user ((const char *) NULL); break; } if (s.bcmd == 'P') { struct stransfer *qtrans; /* A poll file. */ ulog_user ((const char *) NULL); qtrans = qtransalc (&s); qtrans->psendfn = flocal_poll_file; if (! fqueue_local (qdaemon, qtrans)) return FALSE; continue; } ulog_user (s.zuser); switch (s.bcmd) { case 'S': case 'E': if (! flocal_send_file_init (qdaemon, &s)) return FALSE; break; case 'R': if (! flocal_rec_file_init (qdaemon, &s)) return FALSE; break; case 'X': if (! flocal_xcmd_init (qdaemon, &s)) return FALSE; break; #if DEBUG > 0 default: ulog (LOG_FATAL, "fqueue: Can't happen"); break; #endif } } if (pfany != NULL) *pfany = qTlocal != NULL; iTchecktime = ixsysdep_process_time ((long *) NULL); return TRUE; } /* Clear everything off the work queue. This is used when the call is complete, or if the call is never made. */ void uclear_queue (qdaemon) struct sdaemon *qdaemon; { int i; usysdep_get_work_free (qdaemon->qsys); qTlocal = NULL; qTremote = NULL; qTsend = NULL; qTreceive = NULL; cTchans = 0; iTchan = 0; qTtiming_rec = NULL; cTcmdlen = 0; qTreceive_ack = NULL; for (i = 0; i < IMAX_CHAN + 1; i++) { aqTchan[i] = NULL; aqTremote[i] = NULL; } } /* Recheck the work queue during a conversation. This is only called if it's been more than CCHECKWAIT seconds since the last time the queue was checked. */ static boolean fcheck_queue (qdaemon) struct sdaemon *qdaemon; { /* Only check if we are the master, or if there are multiple channels, or if we aren't already trying to get the other side to hang up. Otherwise, there's nothing we can do with any new jobs we might find. */ if (qdaemon->fmaster || qdaemon->cchans > 1 || ! qdaemon->frequest_hangup) { boolean fany; DEBUG_MESSAGE0 (DEBUG_UUCP_PROTO, "fcheck_queue: Rechecking work queue"); if (! fqueue (qdaemon, &fany)) return FALSE; /* If we found something to do, and we're not the master, and we don't have multiple channels to send new jobs over, try to get the other side to hang up. */ if (fany && ! qdaemon->fmaster && qdaemon->cchans <= 1) qdaemon->frequest_hangup = TRUE; } return TRUE; } /* The main transfer loop. The uucico daemon spends essentially all its time in this function. */ boolean floop (qdaemon) struct sdaemon *qdaemon; { boolean fret; fret = TRUE; while (! qdaemon->fhangup) { register struct stransfer *q; #if DEBUG > 1 /* If we're doing any debugging, close the log and debugging files regularly. This will let people copy them off and remove them while the conversation is in progresss. */ if (iDebug != 0) { ulog_close (); ustats_close (); } #endif if (qdaemon->fmaster) { boolean fhangup; /* We've managed to become the master, so we no longer want to request a hangup. */ qdaemon->frequest_hangup = FALSE; fhangup = FALSE; if (qdaemon->fhangup_requested && qTsend == NULL) { /* The remote system has requested that we transfer control by sending CYM after receiving a file. */ DEBUG_MESSAGE0 (DEBUG_UUCP_PROTO, "floop: Transferring control at remote request"); fhangup = TRUE; } else if (qTremote == NULL && qTlocal == NULL && qTsend == NULL && qTreceive == NULL) { /* We don't have anything to do. Try to find some new jobs. If we can't, transfer control. */ if (! fqueue (qdaemon, (boolean *) NULL)) { fret = FALSE; break; } if (qTlocal == NULL) { DEBUG_MESSAGE0 (DEBUG_UUCP_PROTO, "floop: No work for master"); fhangup = TRUE; } } if (fhangup) { if (! (*qdaemon->qproto->pfsendcmd) (qdaemon, "H", 0, 0)) { fret = FALSE; break; } qdaemon->fmaster = FALSE; } } /* If we are no long the master, clear any requested hangup. We may have already hung up before checking this variable in the block above. */ if (! qdaemon->fmaster) qdaemon->fhangup_requested = FALSE; /* Immediately queue up any remote jobs. We don't need local channel numbers for them, since we can disambiguate based on the remote channel number. */ while (qTremote != NULL) { q = qTremote; utdequeue (q); utqueue (&qTsend, q, TRUE); } /* If we are the master, or if we have multiple channels, try to queue up additional local jobs. */ if (qdaemon->fmaster || qdaemon->cchans > 1) { while (qTlocal != NULL && cTchans < qdaemon->cchans) { /* We have room for an additional channel. */ q = qTlocal; if (! fqueue_send (qdaemon, q)) { fret = FALSE; break; } utchanalc (qdaemon, q); } if (! fret) break; } q = qTsend; if (q == NULL) { ulog_user ((const char *) NULL); DEBUG_MESSAGE0 (DEBUG_UUCP_PROTO, "floop: Waiting for data"); if (! (*qdaemon->qproto->pfwait) (qdaemon)) { fret = FALSE; break; } } else { ulog_user (q->s.zuser); if (! q->fsendfile) { /* Technically, we should add the time required for this call to q->isecs and q->imicros. In practice, the amount of time required should be sufficiently small that it can be safely disregarded. */ if (! (*q->psendfn) (q, qdaemon)) { fret = FALSE; break; } } else { long isecs, imicros; boolean fcharged; long inextsecs = 0, inextmicros; if (! fttime (qdaemon, &isecs, &imicros)) { fret = FALSE; break; } fcharged = FALSE; if (q->zlog != NULL) { ulog (LOG_NORMAL, "%s", q->zlog); ubuffree (q->zlog); q->zlog = NULL; } /* We can read the file in a tight loop until we have a command to send, or the file send has been cancelled, or we have a remote job to deal with. We can disregard any changes to qTlocal since we already have something to send anyhow. */ while (q == qTsend && q->fsendfile && qTremote == NULL) { char *zdata; size_t cdata; long ipos; zdata = (*qdaemon->qproto->pzgetspace) (qdaemon, &cdata); if (zdata == NULL) { fret = FALSE; break; } if (ffileeof (q->e)) cdata = 0; else { cdata = cfileread (q->e, zdata, cdata); if (ffileioerror (q->e, cdata)) { /* There is no way to report a file reading error, so we just drop the connection. */ ulog (LOG_ERROR, "read: %s", strerror (errno)); fret = FALSE; break; } } ipos = q->ipos; q->ipos += cdata; q->cbytes += cdata; if (! (*qdaemon->qproto->pfsenddata) (qdaemon, zdata, cdata, q->ilocal, q->iremote, ipos)) { fret = FALSE; break; } if (cdata == 0) { /* We must update the time now, because this call may make an entry in the statistics file. */ inextsecs = ixsysdep_process_time (&inextmicros); DEBUG_MESSAGE4 (DEBUG_UUCP_PROTO, "floop: Charging %ld to %c %s %s", ((inextsecs - isecs) * 1000000 + inextmicros - imicros), q->s.bcmd, q->s.zfrom, q->s.zto); q->isecs += inextsecs - isecs; q->imicros += inextmicros - imicros; fcharged = TRUE; q->fsendfile = FALSE; if (! (*q->psendfn) (q, qdaemon)) fret = FALSE; break; } } if (! fret) break; if (! fcharged) { inextsecs = ixsysdep_process_time (&inextmicros); DEBUG_MESSAGE4 (DEBUG_UUCP_PROTO, "floop: Charging %ld to %c %s %s", ((inextsecs - isecs) * 1000000 + inextmicros - imicros), q->s.bcmd, q->s.zfrom, q->s.zto); q->isecs += inextsecs - isecs; q->imicros += inextmicros - imicros; } if (inextsecs - iTchecktime >= CCHECKWAIT) { if (! fcheck_queue (qdaemon)) { fret = FALSE; break; } } } } } ulog_user ((const char *) NULL); (void) (*qdaemon->qproto->pfshutdown) (qdaemon); if (fret) uwindow_acked (qdaemon, TRUE); else ufailed (qdaemon); return fret; } /* This is called by the protocol routines when they have received some data. If pfexit is not NULL, *pfexit should be set to TRUE if the protocol receive loop should exit back to the main floop routine, above. It is only important to set *pfexit to TRUE if the main loop called the pfwait entry point, so we need never set it to TRUE if we just receive data for a file. This routine never sets *pfexit to FALSE. */ boolean fgot_data (qdaemon, zfirst, cfirst, zsecond, csecond, ilocal, iremote, ipos, fallacked, pfexit) struct sdaemon *qdaemon; const char *zfirst; size_t cfirst; const char *zsecond; size_t csecond; int ilocal; int iremote; long ipos; boolean fallacked; boolean *pfexit; { struct stransfer *q; int cwrote; boolean fret; long isecs, imicros; if (fallacked && qTreceive_ack != NULL) uwindow_acked (qdaemon, TRUE); /* Now we have to decide which transfer structure gets the data. If ilocal is -1, it means that the protocol does not know where to route the data. In that case we route it to the first transfer that is waiting for data, or, if none, as a new command. If ilocal is 0, we either select based on the remote channel number or we have a new command. */ if (ilocal == -1 && qTreceive != NULL) q = qTreceive; else if (ilocal == 0 && iremote > 0 && aqTremote[iremote] != NULL) q = aqTremote[iremote]; else if (ilocal <= 0) { const char *znull; ulog_user ((const char *) NULL); /* This data is part of a command. If there is no null character in the data, this string will be continued by the next packet. Otherwise this must be the last string in the command, and we don't care about what comes after the null byte. */ znull = (const char *) memchr (zfirst, '\0', cfirst); if (znull != NULL) fret = ftadd_cmd (qdaemon, zfirst, (size_t) (znull - zfirst), iremote, TRUE); else { fret = ftadd_cmd (qdaemon, zfirst, cfirst, iremote, FALSE); if (fret && csecond > 0) { znull = (const char *) memchr (zsecond, '\0', csecond); if (znull != NULL) fret = ftadd_cmd (qdaemon, zsecond, (size_t) (znull - zsecond), iremote, TRUE); else fret = ftadd_cmd (qdaemon, zsecond, csecond, iremote, FALSE); } } if (pfexit != NULL && (qdaemon->fhangup || qTremote != NULL)) *pfexit = TRUE; /* Time spent waiting for a new command is not charged to anybody. */ if (! fttime (qdaemon, &iTrecsecs, &iTrecmicros)) fret = FALSE; return fret; } else { /* Get the transfer structure this data is intended for. */ q = qtchan (ilocal); } #if DEBUG > 0 if (q == NULL || q->precfn == NULL) { ulog (LOG_ERROR, "Protocol error: %lu bytes remote %d local %d", (unsigned long) (cfirst + csecond), iremote, ilocal); return FALSE; } #endif ulog_user (q->s.zuser); fret = TRUE; if (q->zlog != NULL && ! q->fsendfile) { ulog (LOG_NORMAL, "%s", q->zlog); ubuffree (q->zlog); q->zlog = NULL; } if (cfirst == 0 || q->fcmd || ! q->frecfile || q != qTtiming_rec) { struct stransfer *qcharge; /* Either we are receiving some sort of command, or we are receiving data for a transfer other than the one we are currently timing. It we are currently timing a transfer, charge any accumulated time to it. Otherwise, if we currently have something to send, just forget about the accumulated time (when using a bidirectional protocol, it's very difficult to charge this time correctly). Otherwise, charge it to whatever transfer receives it. */ if (! fttime (qdaemon, &isecs, &imicros)) fret = FALSE; if (qTtiming_rec != NULL) qcharge = qTtiming_rec; else if (qTsend != NULL) qcharge = NULL; else qcharge = q; if (qcharge != NULL) { DEBUG_MESSAGE4 (DEBUG_UUCP_PROTO, "fgot_data: Charging %ld to %c %s %s", ((isecs - iTrecsecs) * 1000000 + imicros - iTrecmicros), qcharge->s.bcmd, qcharge->s.zfrom, qcharge->s.zto); qcharge->isecs += isecs - iTrecsecs; qcharge->imicros += imicros - iTrecmicros; } iTrecsecs = isecs; iTrecmicros = imicros; /* If we received file data, start timing the new transfer. */ if (cfirst == 0 || q->fcmd || ! q->frecfile) qTtiming_rec = NULL; else qTtiming_rec = q; } /* If we're receiving a command, then accumulate it up to the null byte. */ if (q->fcmd) { const char *znull; znull = NULL; while (cfirst > 0) { size_t cnew; char *znew; znull = (const char *) memchr (zfirst, '\0', cfirst); if (znull != NULL) cnew = znull - zfirst; else cnew = cfirst; znew = zbufalc (q->ccmd + cnew + 1); if (q->ccmd > 0) memcpy (znew, q->zcmd, q->ccmd); memcpy (znew + q->ccmd, zfirst, cnew); znew[q->ccmd + cnew] = '\0'; ubuffree (q->zcmd); q->zcmd = znew; q->ccmd += cnew; if (znull != NULL) break; zfirst = zsecond; cfirst = csecond; csecond = 0; } if (znull != NULL) { char *zcmd; size_t ccmd; zcmd = q->zcmd; ccmd = q->ccmd; q->fcmd = FALSE; q->zcmd = NULL; q->ccmd = 0; if (! (*q->precfn) (q, qdaemon, zcmd, ccmd + 1)) fret = FALSE; ubuffree (zcmd); } if (pfexit != NULL && (qdaemon->fhangup || qdaemon->fmaster || qTsend != NULL)) *pfexit = TRUE; } else if (! q->frecfile || cfirst == 0) { /* We're either not receiving a file or the file transfer is complete. */ q->frecfile = FALSE; if (! (*q->precfn) (q, qdaemon, zfirst, cfirst)) fret = FALSE; if (fret && csecond > 0) return fgot_data (qdaemon, zsecond, csecond, (const char *) NULL, (size_t) 0, ilocal, iremote, ipos + (long) cfirst, FALSE, pfexit); if (pfexit != NULL && (qdaemon->fhangup || qdaemon->fmaster || qTsend != NULL)) *pfexit = TRUE; } else { if (ipos != -1 && ipos != q->ipos) { DEBUG_MESSAGE1 (DEBUG_UUCP_PROTO, "fgot_data: Seeking to %ld", ipos); if (! ffileseek (q->e, ipos)) { ulog (LOG_ERROR, "seek: %s", strerror (errno)); fret = FALSE; } q->ipos = ipos; } if (fret) { while (cfirst > 0) { cwrote = cfilewrite (q->e, (char *) zfirst, cfirst); if (cwrote == cfirst) { #if FREE_SPACE_DELTA > 0 long cfree_space; /* Check that there is still enough space on the disk. If there isn't, we drop the connection, because we have no way to abort a file transfer in progress. */ cfree_space = qdaemon->qsys->uuconf_cfree_space; if (cfree_space > 0 && ((q->cbytes / FREE_SPACE_DELTA) != (q->cbytes + cfirst) / FREE_SPACE_DELTA) && ! frec_check_free (q, cfree_space)) { fret = FALSE; break; } #endif q->cbytes += cfirst; q->ipos += cfirst; } else { if (ffileioerror (q->e, cwrote)) ulog (LOG_ERROR, "write: %s", strerror (errno)); else ulog (LOG_ERROR, "Wrote %d to file when trying to write %lu", cwrote, (unsigned long) cfirst); /* Any write error is almost certainly a temporary condition, or else UUCP would not be functioning at all. If we continue to accept the file, we will wind up rejecting it at the end (what else could we do?) and the remote system will throw away the request. We're better off just dropping the connection, which is what happens when we return FALSE, and trying again later. */ fret = FALSE; break; } zfirst = zsecond; cfirst = csecond; csecond = 0; } } if (pfexit != NULL && qdaemon->fhangup) *pfexit = TRUE; } return fret; } /* Accumulate a string into a command. If the command is complete, start up a new transfer. */ static boolean ftadd_cmd (qdaemon, z, clen, iremote, flast) struct sdaemon *qdaemon; const char *z; size_t clen; int iremote; boolean flast; { static char *zbuf; static size_t cbuf; size_t cneed; struct scmd s; cneed = cTcmdlen + clen + 1; if (cneed > cbuf) { zbuf = (char *) xrealloc ((pointer) zbuf, cneed); cbuf = cneed; } memcpy (zbuf + cTcmdlen, z, clen); zbuf[cTcmdlen + clen] = '\0'; if (! flast) { cTcmdlen += clen; return TRUE; } /* Don't save this string for next time. */ cTcmdlen = 0; DEBUG_MESSAGE1 (DEBUG_UUCP_PROTO, "ftadd_cmd: Got command \"%s\"", zbuf); if (! fparse_cmd (zbuf, &s) || s.bcmd == 'P') { ulog (LOG_ERROR, "Received garbled command \"%s\"", zbuf); return TRUE; } /* Some systems seem to sometimes send garbage at the end of the command. Avoid interpreting it as a size if sizes are not supported. */ if ((qdaemon->ifeatures & FEATURE_SIZES) == 0) s.cbytes = -1; if (s.bcmd != 'H' && s.bcmd != 'Y' && s.bcmd != 'N') ulog_user (s.zuser); else ulog_user ((const char *) NULL); switch (s.bcmd) { case 'S': case 'E': return fremote_send_file_init (qdaemon, &s, iremote); case 'R': return fremote_rec_file_init (qdaemon, &s, iremote); case 'X': return fremote_xcmd_init (qdaemon, &s, iremote); case 'H': /* This is a remote request for a hangup. We close the log files so that they may be moved at this point. */ ulog_close (); ustats_close (); { struct stransfer *q; q = qtransalc ((struct scmd *) NULL); q->psendfn = fremote_hangup_reply; q->iremote = iremote; q->s.bcmd = 'H'; return fqueue_remote (qdaemon, q); } case 'N': /* This means a hangup request is being denied; we just ignore this and wait for further commands. */ return TRUE; case 'Y': /* This is a remote confirmation of a hangup. We reconfirm. */ if (qdaemon->fhangup) return TRUE; #if DEBUG > 0 if (qdaemon->fmaster) ulog (LOG_ERROR, "Got hangup reply as master"); #endif /* Don't check errors rigorously here, since the other side might jump the gun and hang up. The fLog_sighup variable will get set TRUE again when the port is closed. */ fLog_sighup = FALSE; (void) (*qdaemon->qproto->pfsendcmd) (qdaemon, "HY", 0, iremote); qdaemon->fhangup = TRUE; return TRUE; #if DEBUG > 0 default: ulog (LOG_FATAL, "ftadd_cmd: Can't happen"); return FALSE; #endif } } /* The remote system is requesting a hang up. If we have something to do, send an HN. Otherwise send two HY commands (the other side is presumed to send an HY command between the first and second, but we don't bother to wait for it) and hang up. */ static boolean fremote_hangup_reply (qtrans, qdaemon) struct stransfer *qtrans; struct sdaemon *qdaemon; { boolean fret; utransfree (qtrans); if (qTremote == NULL && qTlocal == NULL && qTsend == NULL && qTreceive == NULL) { if (! fqueue (qdaemon, (boolean *) NULL)) return FALSE; if (qTlocal == NULL) { DEBUG_MESSAGE0 (DEBUG_UUCP_PROTO, "fremote_hangup_reply: No work"); fret = ((*qdaemon->qproto->pfsendcmd) (qdaemon, "HY", 0, 0) && (*qdaemon->qproto->pfsendcmd) (qdaemon, "HY", 0, 0)); qdaemon->fhangup = TRUE; return fret; } } DEBUG_MESSAGE0 (DEBUG_UUCP_PROTO, "fremote_hangup_reply: Found work"); fret = (*qdaemon->qproto->pfsendcmd) (qdaemon, "HN", 0, 0); qdaemon->fmaster = TRUE; return fret; } /* As described in system.h, we need to keep track of which files have been successfully received for which we do not know that the other system has received our acknowledgement. This routine is called to keep a list of such files. */ static struct sreceive_ack *qTfree_receive_ack; void usent_receive_ack (qdaemon, qtrans) struct sdaemon *qdaemon; struct stransfer *qtrans; { struct sreceive_ack *q; if (qTfree_receive_ack == NULL) q = (struct sreceive_ack *) xmalloc (sizeof (struct sreceive_ack)); else { q = qTfree_receive_ack; qTfree_receive_ack = q->qnext; } q->qnext = qTreceive_ack; q->zto = zbufcpy (qtrans->s.zto); q->ztemp = zbufcpy (qtrans->s.ztemp); q->fmarked = FALSE; qTreceive_ack = q; } /* This routine is called by the protocol code when either all outstanding data has been acknowledged or one complete window has passed. It may be called directly by the protocol, or it may be called via fgot_data. If one complete window has passed, then all unmarked receives are marked, and we know that all marked ones have been acked. */ void uwindow_acked (qdaemon, fallacked) struct sdaemon *qdaemon; boolean fallacked; { register struct sreceive_ack **pq; pq = &qTreceive_ack; while (*pq != NULL) { if (fallacked || (*pq)->fmarked) { struct sreceive_ack *q; q = *pq; (void) fsysdep_forget_reception (qdaemon->qsys, q->zto, q->ztemp); ubuffree (q->zto); ubuffree (q->ztemp); *pq = q->qnext; q->qnext = qTfree_receive_ack; qTfree_receive_ack = q; } else { (*pq)->fmarked = TRUE; pq = &(*pq)->qnext; } } } /* This routine is called when an error occurred and we are crashing out of the connection. It is used to report statistics on failed transfers to the statistics file, and it also discards useless temporary files for file receptions. Note that the number of bytes we report as having been sent has little or nothing to do with the number of bytes the remote site actually received. */ void ufailed (qdaemon) struct sdaemon *qdaemon; { register struct stransfer *q; if (qTsend != NULL) { q = qTsend; do { if ((q->fsendfile || q->frecfile) && q->cbytes > 0) { ustats (FALSE, q->s.zuser, qdaemon->qsys->uuconf_zname, q->fsendfile, q->cbytes, q->isecs, q->imicros, qdaemon->fcaller); if (q->fsendfile) qdaemon->csent += q->cbytes; else qdaemon->creceived += q->cbytes; } if (q->frecfile) (void) frec_discard_temp (qdaemon, q); q = q->qnext; } while (q != qTsend); } if (qTreceive != NULL) { q = qTreceive; do { if ((q->fsendfile || q->frecfile) && q->cbytes > 0) { ustats (FALSE, q->s.zuser, qdaemon->qsys->uuconf_zname, q->fsendfile, q->cbytes, q->isecs, q->imicros, qdaemon->fcaller); if (q->fsendfile) qdaemon->csent += q->cbytes; else qdaemon->creceived += q->cbytes; } if (q->frecfile) (void) frec_discard_temp (qdaemon, q); q = q->qnext; } while (q != qTreceive); } } /* When a local poll file is found, it is entered on the queue like any other job. When it is pulled off the queue, this function is called. It just calls fsysdep_did_work, which will remove the poll file. This ensures that poll files are only removed if the system is actually called. */ /*ARGSUSED*/ static boolean flocal_poll_file (qtrans, qdaemon) struct stransfer *qtrans; struct sdaemon *qdaemon; { boolean fret; fret = fsysdep_did_work (qtrans->s.pseq); utransfree (qtrans); return fret; }