/* protg.c The 'g' protocol. Copyright (C) 1991, 1992, 1993, 1994, 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 protg_rcsid[] = "$Id$"; #endif #include #include #include "uudefs.h" #include "uuconf.h" #include "conn.h" #include "trans.h" #include "system.h" #include "prot.h" /* Each 'g' protocol packet begins with six bytes. They are: is the ASCII DLE character (^P or '\020'). if 1 <= <= 8, the packet is followed by 2 ** (k + 4) bytes of data; if == 9, these six bytes are a complete control packet; other value of are illegal. is the low byte of a checksum. is the high byte of a checksum. is a control byte (see below). is ^ ^ ^ . The control byte is divided into three bitfields: t t x x x y y y The two bit field tt is the packet type. The three bit field xxx is the control type for a control packet, or the sequence number for a data packet. The three bit field yyy is a value for a control packet, or the sequence number of the last packet received for a data packet. For all successfully recieved packets, the control byte is stored into iGpacket_control. */ /* Names for the bytes in the frame header. */ #define IFRAME_DLE (0) #define IFRAME_K (1) #define IFRAME_CHECKLOW (2) #define IFRAME_CHECKHIGH (3) #define IFRAME_CONTROL (4) #define IFRAME_XOR (5) /* Length of the frame header. */ #define CFRAMELEN (6) /* Macros to break apart the control bytes. */ #define CONTROL_TT(b) ((int)(((b) >> 6) & 03)) #define CONTROL_XXX(b) ((int)(((b) >> 3) & 07)) #define CONTROL_YYY(b) ((int)((b) & 07)) /* DLE value. */ #define DLE ('\020') /* Get the length of a packet given a pointer to the header. */ #define CPACKLEN(z) ((size_t) (1 << ((z)[IFRAME_K] + 4))) /* field value for a control message. */ #define KCONTROL (9) /* Get the next sequence number given a sequence number. */ #define INEXTSEQ(i) ((i + 1) & 07) /* Compute i1 - i2 modulo 8. */ #define CSEQDIFF(i1, i2) (((i1) + 8 - (i2)) & 07) /* Packet types. These are from the tt field. CONTROL -- control packet ALTCHAN -- alternate channel; not used by UUCP DATA -- full data segment SHORTDATA -- less than full data segment (all the bytes specified by the packet length are always transferred). Let be the number of bytes in the data segment not to be used. If <= 0x7f, the first byte of the data segment is and the data follows. If > 0x7f, the first byte of the data segment is 0x80 | ( & 0x7f), the second byte of the data segment is >> 7, and the data follows. The maximum possible data segment size is 2**12, so this handles all possible cases. */ #define CONTROL (0) #define ALTCHAN (1) #define DATA (2) #define SHORTDATA (3) /* Control types. These are from the xxx field if the type (tt field) is CONTROL. CLOSE -- close the connection RJ -- reject; packet yyy last to be received correctly SRJ -- selective reject; reject only packet yyy (not used by UUCP) RR -- receiver ready; packet yyy received correctly INITC -- third step of initialization; yyy holds window size INITB -- second step of initialization; yyy holds maximum value - 1 INITA -- first step of initialization; yyy holds window size. The yyy value for RR is the same as the yyy value for an ordinary data packet. */ #define CLOSE (1) #define RJ (2) #define SRJ (3) #define RR (4) #define INITC (5) #define INITB (6) #define INITA (7) /* Maximum amount of data in a single packet. This is set by the field in the header; the amount of data in a packet is 2 ** ( + 4). ranges from 1 to 8. */ #define CMAXDATAINDEX (8) #define CMAXDATA (1 << (CMAXDATAINDEX + 4)) /* Maximum window size. */ #define CMAXWINDOW (7) /* Defaults for the protocol parameters. These may all be changed by using the ``protocol-parameter g'' command, so there is no particular reason to change the values given here. */ /* The desired window size. This is what we tell the other system to use. It must be between 1 and 7, and there's no reason to use less than 7. Protocol parameter ``window''. */ #define IWINDOW (7) /* The desired packet size. Many implementations only support 64 byte packets. Protocol parameter ``packet-size''. */ #define IPACKSIZE (64) /* The number of times to retry the exchange of INIT packets when starting the protocol. Protocol parameter ``startup-retries''. */ #define CSTARTUP_RETRIES (8) /* The timeout to use when waiting for an INIT packet when starting up the protocol. Protocol parameter ``init-timeout''. */ #define CEXCHANGE_INIT_TIMEOUT (10) /* The number of times to retry sending and waiting for a single INIT packet when starting the protocol. This controls a single INIT packet, while CSTARTUP_RETRIES controls how many times to try the entire INIT sequence. Protocol parameter ``init-retries''. */ #define CEXCHANGE_INIT_RETRIES (4) /* The timeout to use when waiting for a packet. Protocol parameter ``timeout''. */ #define CTIMEOUT (10) /* The number of times to retry waiting for a packet. Each time the timeout fails we send a copy of our last data packet or a reject message for the packet we expect from the other side, depending on whether we are waiting for an acknowledgement or a data packet. This is the number of times we try doing that and then waiting again. Protocol parameter ``retries''. */ #define CRETRIES (6) /* If we see more than this much unrecognized data, we drop the connection. This must be larger than a single packet size, which means it must be larger than 4096 (the largest possible packet size). Protocol parameter ``garbage''. */ #define CGARBAGE (10000) /* If we see more than this many protocol errors, we drop the connection. Protocol parameter ``errors''. */ #define CERRORS (100) /* Default decay rate. Each time we send or receive this many packets succesfully, we decrement the error level by one (protocol parameter ``error-decay''). */ #define CERROR_DECAY (10) /* If this value is non-zero, it will be used as the remote window size regardless of what the other side requested. This can be useful for dealing with some particularly flawed packages. This default value should always be 0, and protocol parameter ``remote-window'' should be used for the affected systems. */ #define IREMOTE_WINDOW (0) /* If this value is non-zero, it will be used as the packet size to send to the remote system regardless of what it requested. It's difficult to imagine any circumstances where you would want to set this. Protocol parameter ``remote-packet-size''. */ #define IREMOTE_PACKSIZE (0) /* Local variables. */ /* Next sequence number to send. */ static int iGsendseq; /* Last sequence number that has been acked. */ static int iGremote_ack; /* Last sequence number to be retransmitted. */ static int iGretransmit_seq; /* Last sequence number we have received. */ static int iGrecseq; /* Last sequence number we have acked. */ static int iGlocal_ack; /* Window size to request (protocol parameter ``window''). */ static int iGrequest_winsize = IWINDOW; /* Packet size to request (protocol parameter ``packet-size''). */ static int iGrequest_packsize = IPACKSIZE; /* Remote window size (set during handshake). */ static int iGremote_winsize; /* Forced remote window size (protocol parameter ``remote-window''). */ static int iGforced_remote_winsize = IREMOTE_WINDOW; /* Remote segment size (set during handshake). This is one less than the value in a packet header. */ static int iGremote_segsize; /* Remote packet size (set based on iGremote_segsize). */ static size_t iGremote_packsize; /* Forced remote packet size (protocol parameter ``remote-packet-size''). */ static int iGforced_remote_packsize = IREMOTE_PACKSIZE; /* Recieved control byte. */ static int iGpacket_control; /* Number of times to retry the initial handshake. Protocol parameter ``startup-retries''. */ static int cGstartup_retries = CSTARTUP_RETRIES; /* Number of times to retry sending an initial control packet. Protocol parameter ``init-retries''. */ static int cGexchange_init_retries = CEXCHANGE_INIT_RETRIES; /* Timeout (seconds) for receiving an initial control packet. Protocol parameter ``init-timeout''. */ static int cGexchange_init_timeout = CEXCHANGE_INIT_TIMEOUT; /* Timeout (seconds) for receiving a data packet. Protocol parameter ``timeout''. */ static int cGtimeout = CTIMEOUT; /* Maximum number of timeouts when receiving a data packet or acknowledgement. Protocol parameter ``retries''. */ static int cGretries = CRETRIES; /* Amount of garbage data we are prepared to see before giving up. Protocol parameter ``garbage''. */ static int cGgarbage_data = CGARBAGE; /* Maximum number of errors we are prepared to see before giving up. Protocol parameter ``errors''. */ static int cGmax_errors = CERRORS; /* Each time we receive this many packets succesfully, we decrement the error level by one (protocol parameter ``error-decay''). */ static int cGerror_decay = CERROR_DECAY; /* Whether to use shorter packets when possible. Protocol parameter ``short-packets''. */ static boolean fGshort_packets = TRUE; /* Protocol parameter commands. */ struct uuconf_cmdtab asGproto_params[] = { { "window", UUCONF_CMDTABTYPE_INT, (pointer) &iGrequest_winsize, NULL }, { "packet-size", UUCONF_CMDTABTYPE_INT, (pointer) &iGrequest_packsize, NULL }, { "startup-retries", UUCONF_CMDTABTYPE_INT, (pointer) &cGstartup_retries, NULL }, { "init-timeout", UUCONF_CMDTABTYPE_INT, (pointer) &cGexchange_init_timeout, NULL }, { "init-retries", UUCONF_CMDTABTYPE_INT, (pointer) &cGexchange_init_retries, NULL }, { "timeout", UUCONF_CMDTABTYPE_INT, (pointer) &cGtimeout, NULL }, { "retries", UUCONF_CMDTABTYPE_INT, (pointer) &cGretries, NULL }, { "garbage", UUCONF_CMDTABTYPE_INT, (pointer) &cGgarbage_data, NULL }, { "errors", UUCONF_CMDTABTYPE_INT, (pointer) &cGmax_errors, NULL }, { "error-decay", UUCONF_CMDTABTYPE_INT, (pointer) &cGerror_decay, NULL }, { "remote-window", UUCONF_CMDTABTYPE_INT, (pointer) &iGforced_remote_winsize, NULL }, { "remote-packet-size", UUCONF_CMDTABTYPE_INT, (pointer) &iGforced_remote_packsize, NULL }, { "short-packets", UUCONF_CMDTABTYPE_BOOLEAN, (pointer) &fGshort_packets, NULL }, { NULL, 0, NULL, NULL } }; /* Statistics. */ /* Number of packets we have sent. */ static long cGsent_packets; /* Number of packets we have resent (these are not included in cGsent_packets). */ static long cGresent_packets; /* Number of packets we have delayed sending (these should not be counted in cGresent_packets). */ static long cGdelayed_packets; /* Number of packets we have received. */ static long cGrec_packets; /* Number of packets rejected because the header was bad. */ static long cGbad_hdr; /* Number of packets rejected because the checksum was bad. */ static long cGbad_checksum; /* Number of packets received out of order. */ static long cGbad_order; /* Number of packets rejected by receiver (number of RJ packets received). */ static long cGremote_rejects; /* Number of duplicate RR packets treated as RJ packets. Some UUCP packages appear to never send RJ packets, but only RR packets. If no RJ has been seen, fgprocess_data treats a duplicate RR as an RJ and increments this variable. */ static long cGremote_duprrs; /* The error level. This is the total number of errors as adjusted by cGerror_decay. */ static long cGerror_level; /* Each time we send an RJ, we can expect several out of order of packets, because the other side will probably have sent a full window by the time it sees the RJ. This variable keeps track of the number of out of order packets we expect to see. We don't count expected out of order packets against the error level. This is reset to 0 when an in order packet is received. */ static int cGexpect_bad_order; #if DEBUG > 1 /* Control packet names used for debugging. */ static const char * const azGcontrol[] = {"?0?", "CLOSE", "RJ", "SRJ", "RR", "INITC", "INITB", "INITA"}; #endif /* Local functions. */ static boolean fgexchange_init P((struct sdaemon *qdaemon, int ictl, int ival, int *piset)); static boolean fgsend_control P((struct sdaemon *qdaemon, int ictl, int ival)); static char *zgadjust_ack P((int iseq)); static boolean fgwait_for_packet P((struct sdaemon *qdaemon, boolean freturncontrol, int ctimeout, int cretries)); static boolean fgsend_acks P((struct sdaemon *qdaemon)); static boolean fggot_ack P((struct sdaemon *qdaemon, int iack)); static boolean fgprocess_data P((struct sdaemon *qdaemon, boolean fdoacks, boolean freturncontrol, boolean *pfexit, size_t *pcneed, boolean *pffound)); static boolean fginit_sendbuffers P((boolean fallocate)); static boolean fgcheck_errors P((struct sdaemon *qdaemon)); static int igchecksum P((const char *zdata, size_t clen)); static int igchecksum2 P((const char *zfirst, size_t cfirst, const char *zsecond, size_t csecond)); /* Start the protocol. This requires a three way handshake. Both sides must send and receive an INITA packet, an INITB packet, and an INITC packet. The INITA and INITC packets contain the window size, and the INITB packet contains the packet size. */ boolean fgstart (qdaemon, pzlog) struct sdaemon *qdaemon; char **pzlog; { int iseg; int i; boolean fgota, fgotb; *pzlog = NULL; /* The 'g' protocol requires a full eight bit interface. */ if (! fconn_set (qdaemon->qconn, PARITYSETTING_NONE, STRIPSETTING_EIGHTBITS, XONXOFF_OFF)) return FALSE; iGsendseq = 1; iGremote_ack = 0; iGretransmit_seq = -1; iGrecseq = 0; iGlocal_ack = 0; cGsent_packets = 0; cGresent_packets = 0; cGdelayed_packets = 0; cGrec_packets = 0; cGbad_hdr = 0; cGbad_checksum = 0; cGbad_order = 0; cGremote_rejects = 0; cGremote_duprrs = 0; cGerror_level = 0; cGexpect_bad_order = 0; /* We must determine the segment size based on the packet size which may have been modified by a protocol parameter command. A segment size of 2^n is passed as n - 5. */ i = iGrequest_packsize; iseg = -1; while (i > 0) { ++iseg; i >>= 1; } iseg -= 5; if (iseg < 0 || iseg > 7) { ulog (LOG_ERROR, "Illegal packet size %d for '%c' protocol", iGrequest_packsize, qdaemon->qproto->bname); iseg = 1; } if (iGrequest_winsize <= 0 || iGrequest_winsize > 7) { ulog (LOG_ERROR, "Illegal window size %d for '%c' protocol", iGrequest_winsize, qdaemon->qproto->bname); iGrequest_winsize = IWINDOW; } fgota = FALSE; fgotb = FALSE; for (i = 0; i < cGstartup_retries; i++) { if (fgota) { if (! fgsend_control (qdaemon, INITA, iGrequest_winsize)) return FALSE; } else { if (! fgexchange_init (qdaemon, INITA, iGrequest_winsize, &iGremote_winsize)) continue; } fgota = TRUE; if (fgotb) { if (! fgsend_control (qdaemon, INITB, iseg)) return FALSE; } else { if (! fgexchange_init (qdaemon, INITB, iseg, &iGremote_segsize)) continue; } fgotb = TRUE; if (! fgexchange_init (qdaemon, INITC, iGrequest_winsize, &iGremote_winsize)) continue; /* We have succesfully connected. Determine the remote packet size. */ iGremote_packsize = 1 << (iGremote_segsize + 5); /* If the user requested us to force specific remote window and packet sizes, do so now. */ if (iGforced_remote_winsize > 0 && iGforced_remote_winsize <= CMAXWINDOW) iGremote_winsize = iGforced_remote_winsize; if (iGforced_remote_packsize >= 32 && iGforced_remote_packsize <= 4096) { /* Force the value to a power of two. */ i = iGforced_remote_packsize; iseg = -1; while (i > 0) { ++iseg; i >>= 1; } iGremote_packsize = 1 << iseg; iGremote_segsize = iseg - 5; } /* Set up packet buffers to use. We don't do this until we know the maximum packet size we are going to send. */ if (! fginit_sendbuffers (TRUE)) return FALSE; *pzlog = zbufalc (sizeof "protocol '' sending packet/window / receiving /" + 64); sprintf (*pzlog, "protocol '%c' sending packet/window %d/%d receiving %d/%d", qdaemon->qproto->bname, (int) iGremote_packsize, (int) iGremote_winsize, (int) iGrequest_packsize, (int) iGrequest_winsize); return TRUE; } DEBUG_MESSAGE0 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgstart: Protocol startup failed"); return FALSE; } /* The 'G' protocol is identical to the 'g' protocol, except that short packets are never supported. */ boolean fbiggstart (qdaemon, pzlog) struct sdaemon *qdaemon; char **pzlog; { fGshort_packets = FALSE; return fgstart (qdaemon, pzlog); } /* The 'v' protocol is identical to the 'g' protocol, except that the packet size defaults to 512 bytes. Rather than really get it right, we automatically switch from the usual default of 64 to 512. This won't work correctly if somebody does protocol-parameter v packet-size 64. */ boolean fvstart (qdaemon, pzlog) struct sdaemon *qdaemon; char **pzlog; { if (iGrequest_packsize == IPACKSIZE) iGrequest_packsize = 1024; return fgstart (qdaemon, pzlog); } /* Exchange initialization messages with the other system. A problem: We send INITA; it gets received We receive INITA We send INITB; it gets garbled We receive INITB We have seen and sent INITB, so we start to send INITC. The other side as sent INITB but not seen it, so it times out and resends INITB. We will continue sending INITC and the other side will continue sending INITB until both sides give up and start again with INITA. It might seem as though if we are sending INITC and receive INITB, we should resend our INITB, but this could cause infinite echoing of INITB on a long-latency line. Rather than risk that, I have implemented a fast drop-back procedure. If we are sending INITB and receive INITC, the other side has gotten ahead of us. We immediately fail and begin again with INITA. For the other side, if we are sending INITC and see INITA, we also immediately fail back to INITA. Unfortunately, this doesn't work for the other case, in which we are sending INITB but the other side has not yet seen INITA. As far as I can see, if this happens we just have to wait until we time out and resend INITA. */ static boolean fgexchange_init (qdaemon, ictl, ival, piset) struct sdaemon *qdaemon; int ictl; int ival; int *piset; { int i; /* The three-way handshake should be independent of who initializes it, but it seems that some versions of uucico assume that the caller sends first and the callee responds. This only matters if we are the callee and the first packet is garbled. If we send a packet, the other side will assume that we must have seen the packet they sent and will never time out and send it again. Therefore, if we are the callee we don't send a packet the first time through the loop. This can still fail, but should usually work, and, after all, if the initialization packets are received correctly there will be no problem no matter what we do. */ for (i = 0; i < cGexchange_init_retries; i++) { long itime; int ctimeout; if (qdaemon->fcaller || i > 0) { if (! fgsend_control (qdaemon, ictl, ival)) return FALSE; } itime = ixsysdep_time ((long *) NULL); ctimeout = cGexchange_init_timeout; do { long inewtime; /* We pass 0 as the retry count to fgwait_for_packet because we want to handle retries here and because if it retried it would send a packet, which would be bad. */ if (! fgwait_for_packet (qdaemon, TRUE, ctimeout, 0)) break; if (CONTROL_TT (iGpacket_control) == CONTROL) { if (CONTROL_XXX (iGpacket_control) == ictl) { *piset = CONTROL_YYY (iGpacket_control); /* If we didn't already send our initialization packet, send it now. */ if (! qdaemon->fcaller && i == 0) { if (! fgsend_control (qdaemon, ictl, ival)) return FALSE; } return TRUE; } /* If the other side is farther along than we are, we have lost a packet. Fail immediately back to INITA (but don't fail if we are already doing INITA, since that would count against cStart_retries more than it should). */ if (CONTROL_XXX (iGpacket_control) < ictl && ictl != INITA) return FALSE; /* If we are sending INITC and we receive an INITA, the other side has failed back (we know this because we have seen an INITB from them). Fail back ourselves to start the whole handshake over again. */ if (CONTROL_XXX (iGpacket_control) == INITA && ictl == INITC) return FALSE; /* As a special hack, if we are sending INITC and we receive INITB, we update the segment size from the packet. This permits a second INITB to override the first one. It would be nice to do this in a cleaner way. */ if (CONTROL_XXX (iGpacket_control) == INITB && ictl == INITC) iGremote_segsize = CONTROL_YYY (iGpacket_control); } inewtime = ixsysdep_time ((long *) NULL); ctimeout -= inewtime - itime; } while (ctimeout > 0); } return FALSE; } /* Shut down the protocol. */ boolean fgshutdown (qdaemon) struct sdaemon *qdaemon; { (void) fgsend_control (qdaemon, CLOSE, 0); (void) fgsend_control (qdaemon, CLOSE, 0); (void) fginit_sendbuffers (FALSE); /* The count of sent packets may not be accurate, because some of them may have not been sent yet if the connection failed in the middle (the ones that counted for cGdelayed_packets). I don't think it's worth being precise. */ ulog (LOG_NORMAL, "Protocol '%c' packets: sent %ld, resent %ld, received %ld", qdaemon->qproto->bname, cGsent_packets, cGresent_packets - cGdelayed_packets, cGrec_packets); if (cGbad_hdr != 0 || cGbad_checksum != 0 || cGbad_order != 0 || cGremote_rejects != 0 || cGremote_duprrs != 0) ulog (LOG_NORMAL, "Errors: header %ld, checksum %ld, order %ld, remote rejects %ld", cGbad_hdr, cGbad_checksum, cGbad_order, cGremote_duprrs + cGremote_rejects); /* Reset all the parameters to their default values, so that the protocol parameters used for this connection do not affect the next one. */ iGrequest_winsize = IWINDOW; iGrequest_packsize = IPACKSIZE; cGstartup_retries = CSTARTUP_RETRIES; cGexchange_init_timeout = CEXCHANGE_INIT_TIMEOUT; cGexchange_init_retries = CEXCHANGE_INIT_RETRIES; cGtimeout = CTIMEOUT; cGretries = CRETRIES; cGgarbage_data = CGARBAGE; cGmax_errors = CERRORS; cGerror_decay = CERROR_DECAY; iGforced_remote_winsize = IREMOTE_WINDOW; iGforced_remote_packsize = IREMOTE_PACKSIZE; fGshort_packets = TRUE; return TRUE; } /* Send a command string. We send packets containing the string until the entire string has been sent. Each packet is full. */ /*ARGSUSED*/ boolean fgsendcmd (qdaemon, z, ilocal, iremote) struct sdaemon *qdaemon; const char *z; int ilocal; int iremote; { size_t clen; boolean fagain; DEBUG_MESSAGE1 (DEBUG_UUCP_PROTO, "fgsendcmd: Sending command \"%s\"", z); clen = strlen (z); do { char *zpacket; size_t cdummy; zpacket = zggetspace (qdaemon, &cdummy); if (clen < iGremote_packsize) { size_t csize; /* If the remote packet size is larger than 64 (the default, which may indicate an older UUCP package), try to fit this command into a smaller packet. We still always send a complete packet, though. */ if (iGremote_packsize <= 64 || ! fGshort_packets) csize = iGremote_packsize; else { csize = 32; while (csize <= clen) csize <<= 1; } memcpy (zpacket, z, clen); if (csize > clen) bzero (zpacket + clen, csize - clen); fagain = FALSE; if (! fgsenddata (qdaemon, zpacket, csize, 0, 0, (long) 0)) return FALSE; } else { memcpy (zpacket, z, iGremote_packsize); z += iGremote_packsize; clen -= iGremote_packsize; fagain = TRUE; if (! fgsenddata (qdaemon, zpacket, iGremote_packsize, 0, 0, (long) 0)) return FALSE; } } while (fagain); return TRUE; } /* We keep an array of buffers to retransmit as necessary. Rather than waste static space on large buffer sizes, we allocate the buffers once we know how large the other system expects them to be. The sequence numbers used in the 'g' protocol are only three bits long, so we allocate eight buffers and maintain a correspondence between buffer index and sequence number. This always wastes some buffer space, but it's easy to implement. We leave room at the front of the buffer for the frame header and two additional bytes. The two extra bytes are used for short packets, which essentially use a longer header and shorter data. We do this to avoid moving the data. We zero out any unused bytes before the frame, so we can locate the real header given a buffer by finding the first non-zero byte (which will be one of the first three bytes in the buffer). */ #define CSENDBUFFERS (CMAXWINDOW + 1) static char *azGsendbuffers[CSENDBUFFERS]; static boolean fginit_sendbuffers (fallocate) boolean fallocate; { int i; /* Free up any remaining old buffers. */ for (i = 0; i < CSENDBUFFERS; i++) { xfree ((pointer) azGsendbuffers[i]); if (fallocate) { azGsendbuffers[i] = (char *) malloc (CFRAMELEN + 2 + iGremote_packsize); if (azGsendbuffers[i] == NULL) return FALSE; /* This bzero might not seem necessary, since before we send out each packet we zero out any non-data bytes. However, if we receive an SRJ at the start of the conversation, we will send out the packet before it has been set to anything, thus sending the contents of our heap. We avoid this by using bzero. */ bzero (azGsendbuffers[i], CFRAMELEN + 2 + iGremote_packsize); } else azGsendbuffers[i] = NULL; } return TRUE; } /* Allocate a packet to send out. The return value of this function must be filled in and passed to fgsenddata, or discarded. This will ensure that the buffers and iGsendseq stay in synch. Set *pclen to the amount of data to place in the buffer. */ /*ARGSUSED*/ char * zggetspace (qdaemon, pclen) struct sdaemon *qdaemon; size_t *pclen; { *pclen = iGremote_packsize; return azGsendbuffers[iGsendseq] + CFRAMELEN + 2; } /* Send out a data packet. This computes the checksum, sets up the header, and sends the packet out. The argument zdata should point to the return value of zggetspace. */ /*ARGSIGNORED*/ boolean fgsenddata (qdaemon, zdata, cdata, ilocal, iremote, ipos) struct sdaemon *qdaemon; char *zdata; size_t cdata; int ilocal; int iremote; long ipos; { char *z; int itt, iseg; size_t csize; int iclr1, iclr2; unsigned short icheck; /* Set the initial length bytes. See the description at the definition of SHORTDATA, above. */ itt = DATA; csize = iGremote_packsize; iseg = iGremote_segsize + 1; #if DEBUG > 0 if (cdata > csize) ulog (LOG_FATAL, "fgsend_packet: Packet size too large"); #endif iclr1 = -1; iclr2 = -2; if (cdata < csize) { /* If the remote packet size is larger than 64, the default, we can assume they can handle a smaller packet as well, which will be more efficient to send. */ if (iGremote_packsize > 64 && fGshort_packets) { /* The packet size is 1 << (iseg + 4). */ iseg = 1; csize = 32; while (csize < cdata) { csize <<= 1; ++iseg; } } if (csize != cdata) { size_t cshort; /* We have to add bytes which indicate how short the packet is. We do this by pushing the header backward, which we can do because we allocated two extra bytes for this purpose. */ iclr2 = 0; itt = SHORTDATA; cshort = csize - cdata; if (cshort <= 127) { --zdata; zdata[0] = (char) cshort; zdata[-1] = '\0'; if (cshort > 1) bzero (zdata + cdata + 1, cshort - 1); } else { zdata -= 2; zdata[0] = (char) (0x80 | (cshort & 0x7f)); zdata[1] = (char) (cshort >> 7); bzero (zdata + cdata + 2, cshort - 2); iclr1 = 0; } } } z = zdata - CFRAMELEN; /* Zero out the preceding bytes, in case the last time this buffer was used those bytes were used. We need to zero out the initial bytes so that we can find the true start of the packet in zgadjust_ack. */ z[iclr1] = '\0'; z[iclr2] = '\0'; z[IFRAME_DLE] = DLE; z[IFRAME_K] = (char) iseg; icheck = (unsigned short) igchecksum (zdata, csize); /* We're just about ready to go. Wait until there is room in the receiver's window for us to send the packet. We do this now so that we send the correct value for the last packet received. Note that if iGsendseq == iGremote_ack, this means that the sequence numbers are actually 8 apart, since the packet could not have been acknowledged before it was sent; this can happen when the window size is 7. */ while (iGsendseq == iGremote_ack || CSEQDIFF (iGsendseq, iGremote_ack) > iGremote_winsize) { if (! fgwait_for_packet (qdaemon, TRUE, cGtimeout, cGretries)) return FALSE; } /* Ack all packets up to the next one, since the UUCP protocol requires that all packets be acked in order. */ while (CSEQDIFF (iGrecseq, iGlocal_ack) > 1) { iGlocal_ack = INEXTSEQ (iGlocal_ack); if (! fgsend_control (qdaemon, RR, iGlocal_ack)) return FALSE; } iGlocal_ack = iGrecseq; z[IFRAME_CONTROL] = (char) ((itt << 6) | (iGsendseq << 3) | iGrecseq); iGsendseq = INEXTSEQ (iGsendseq); icheck = ((unsigned short) ((0xaaaa - (icheck ^ (z[IFRAME_CONTROL] & 0xff))) & 0xffff)); z[IFRAME_CHECKLOW] = (char) (icheck & 0xff); z[IFRAME_CHECKHIGH] = (char) (icheck >> 8); z[IFRAME_XOR] = (char) (z[IFRAME_K] ^ z[IFRAME_CHECKLOW] ^ z[IFRAME_CHECKHIGH] ^ z[IFRAME_CONTROL]); /* If we're waiting for acks of retransmitted packets, then don't send this packet yet. The other side may not be ready for it yet. Instead, code in fggot_ack will send the outstanding packets when an ack is received. */ ++cGsent_packets; if (iGretransmit_seq != -1) { ++cGdelayed_packets; return TRUE; } DEBUG_MESSAGE2 (DEBUG_PROTO, "fgsenddata: Sending packet %d (%d bytes)", CONTROL_XXX (z[IFRAME_CONTROL]), cdata); return fsend_data (qdaemon->qconn, z, CFRAMELEN + csize, TRUE); } /* Recompute the control byte and checksum of a packet so that it includes the correct packet acknowledgement. This is called when a packet is retransmitted to make sure the retransmission does not confuse the other side. It returns a pointer to the start of the packet, skipping the bytes that may be unused at the start of azGsendbuffers[iseq]. */ static char * zgadjust_ack (iseq) int iseq; { register char *z; unsigned short icheck; z = azGsendbuffers[iseq]; if (*z == '\0') ++z; if (*z == '\0') ++z; /* If the received packet number is the same, there is nothing to do. */ if (CONTROL_YYY (z[IFRAME_CONTROL]) == iGrecseq) return z; /* Get the old checksum. */ icheck = (unsigned short) (((z[IFRAME_CHECKHIGH] & 0xff) << 8) | (z[IFRAME_CHECKLOW] & 0xff)); icheck = ((unsigned short) (((0xaaaa - icheck) ^ (z[IFRAME_CONTROL] & 0xff)) & 0xffff)); /* Update the control byte. */ z[IFRAME_CONTROL] = (char) ((z[IFRAME_CONTROL] &~ 07) | iGrecseq); /* Create the new checksum. */ icheck = ((unsigned short) ((0xaaaa - (icheck ^ (z[IFRAME_CONTROL] & 0xff))) & 0xffff)); z[IFRAME_CHECKLOW] = (char) (icheck & 0xff); z[IFRAME_CHECKHIGH] = (char) (icheck >> 8); /* Update the XOR byte. */ z[IFRAME_XOR] = (char) (z[IFRAME_K] ^ z[IFRAME_CHECKLOW] ^ z[IFRAME_CHECKHIGH] ^ z[IFRAME_CONTROL]); return z; } /* Send a control packet. These are fairly simple to construct. It seems reasonable to me that we should be able to send a control packet at any time, even if the receive window is closed. In particular, we don't want to delay when sending a CLOSE control message. If I'm wrong, it can be changed easily enough. */ static boolean fgsend_control (qdaemon, ixxx, iyyy) struct sdaemon *qdaemon; int ixxx; int iyyy; { char ab[CFRAMELEN]; int ictl; unsigned short icheck; #if DEBUG > 1 if (FDEBUGGING (DEBUG_PROTO) || (FDEBUGGING (DEBUG_ABNORMAL) && ixxx != RR)) ulog (LOG_DEBUG, "fgsend_control: Sending control %s %d", azGcontrol[ixxx], iyyy); #endif ab[IFRAME_DLE] = DLE; ab[IFRAME_K] = KCONTROL; ictl = (CONTROL << 6) | (ixxx << 3) | iyyy; icheck = (unsigned short) (0xaaaa - ictl); ab[IFRAME_CHECKLOW] = (char) (icheck & 0xff); ab[IFRAME_CHECKHIGH] = (char) (icheck >> 8); ab[IFRAME_CONTROL] = (char) ictl; ab[IFRAME_XOR] = (char) (ab[IFRAME_K] ^ ab[IFRAME_CHECKLOW] ^ ab[IFRAME_CHECKHIGH] ^ ab[IFRAME_CONTROL]); return fsend_data (qdaemon->qconn, ab, (size_t) CFRAMELEN, TRUE); } /* Wait for data to come in. This continues processing until a complete file or command has been received. */ boolean fgwait (qdaemon) struct sdaemon *qdaemon; { return fgwait_for_packet (qdaemon, FALSE, cGtimeout, cGretries); } /* Get a packet. This is called when we have nothing to send, but want to wait for a packet to come in. If freturncontrol is TRUE, this will return after getting any control packet. Otherwise, it will continue to receive packets until a complete file or a complete command has been received. The timeout and the number of retries are specified as arguments. The function returns FALSE if an error occurs or if cretries timeouts of ctimeout seconds were exceeded. */ static boolean fgwait_for_packet (qdaemon, freturncontrol, ctimeout, cretries) struct sdaemon *qdaemon; boolean freturncontrol; int ctimeout; int cretries; { int ctimeouts; int cgarbage; int cshort; ctimeouts = 0; cgarbage = 0; cshort = 0; while (TRUE) { boolean fexit; size_t cneed; boolean ffound; size_t crec; if (! fgprocess_data (qdaemon, TRUE, freturncontrol, &fexit, &cneed, &ffound)) return FALSE; if (fexit) return TRUE; DEBUG_MESSAGE1 (DEBUG_PROTO, "fgwait_for_packet: Need %lu bytes", (unsigned long) cneed); if (ffound) { ctimeouts = 0; cgarbage = 0; } else { if (cgarbage > cGgarbage_data) { ulog (LOG_ERROR, "Too much unrecognized data"); return FALSE; } } if (! freceive_data (qdaemon->qconn, cneed, &crec, ctimeout, TRUE)) return FALSE; cgarbage += crec; if (crec != 0) { /* If we don't get enough data twice in a row, we may have dropped some data and still be looking for the end of a large packet. Incrementing iPrecstart will force fgprocess_data to skip that packet and look through the rest of the data. In some situations, this will be a mistake. */ if (crec >= cneed) cshort = 0; else { ++cshort; if (cshort > 1) { iPrecstart = (iPrecstart + 1) % CRECBUFLEN; cshort = 0; } } } else { /* The read timed out. If we have an unacknowledged packet, send it again. Otherwise, send an RJ with the last packet we received correctly. */ ++ctimeouts; if (ctimeouts > cretries) { if (cretries > 0) ulog (LOG_ERROR, "Timed out waiting for packet"); return FALSE; } if (INEXTSEQ (iGremote_ack) != iGsendseq) { int inext; char *zsend; inext = INEXTSEQ (iGremote_ack); DEBUG_MESSAGE1 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgwait_for_packet: Resending packet %d", inext); ++cGresent_packets; zsend = zgadjust_ack (inext); if (! fsend_data (qdaemon->qconn, zsend, CFRAMELEN + CPACKLEN (zsend), TRUE)) return FALSE; iGretransmit_seq = inext; } else { /* Send all pending acks first, to avoid confusing the other side. */ if (iGlocal_ack != iGrecseq) { if (! fgsend_acks (qdaemon)) return FALSE; } if (! fgsend_control (qdaemon, RJ, iGrecseq)) return FALSE; } } } } /* Send acks for all packets we haven't acked yet. */ static boolean fgsend_acks (qdaemon) struct sdaemon *qdaemon; { while (iGlocal_ack != iGrecseq) { iGlocal_ack = INEXTSEQ (iGlocal_ack); if (! fgsend_control (qdaemon, RR, iGlocal_ack)) return FALSE; } return TRUE; } /* Handle an ack of a packet. According to Hanrahan's paper, this acknowledges all previous packets. If this is an ack for a retransmitted packet, continue by resending up to two more packets following the retransmitted one. This should recover quickly from a line glitch, while avoiding the problem of continual retransmission. */ static boolean fggot_ack (qdaemon, iack) struct sdaemon *qdaemon; int iack; { int inext; char *zsend; /* We only decrement the error level if we are not retransmitting packets. We want to catch a sudden downgrade in line quality as fast as possible. */ if (cGerror_level > 0 && iGretransmit_seq == -1 && cGsent_packets % cGerror_decay == 0) --cGerror_level; cGexpect_bad_order = 0; /* Each time packet 0 is acknowledged, we call uwindow_acked since a new window has been acked. */ if (iack < iGremote_ack) uwindow_acked (qdaemon, FALSE); iGremote_ack = iack; if (iGretransmit_seq == -1) return TRUE; inext = INEXTSEQ (iGretransmit_seq); if (inext == iGsendseq) iGretransmit_seq = -1; else { DEBUG_MESSAGE1 (DEBUG_PROTO, "fggot_ack: Sending packet %d", inext); ++cGresent_packets; zsend = zgadjust_ack (inext); if (! fsend_data (qdaemon->qconn, zsend, CFRAMELEN + CPACKLEN (zsend), TRUE)) return FALSE; inext = INEXTSEQ (inext); if (inext == iGsendseq) iGretransmit_seq = -1; else { DEBUG_MESSAGE1 (DEBUG_PROTO, "fggot_ack: Sending packet %d", inext); ++cGresent_packets; zsend = zgadjust_ack (inext); if (! fsend_data (qdaemon->qconn, zsend, CFRAMELEN + CPACKLEN (zsend), TRUE)) return FALSE; iGretransmit_seq = inext; } } return TRUE; } /* See if we've received more than the permitted number of errors. If we receive a bad packet, we can expect a window full (less one) of out of order packets to follow, so we discount cGbad_order accordingly. */ static boolean fgcheck_errors (qdaemon) struct sdaemon *qdaemon; { if (cGerror_level > cGmax_errors && cGmax_errors >= 0) { ulog (LOG_ERROR, "Too many '%c' protocol errors", qdaemon->qproto->bname); return FALSE; } return TRUE; } /* Process the receive buffer into a data packet, if possible. All control packets are handled here. When a data packet is received, fgprocess_data calls fgot_data with the data; if that sets its pfexit argument to TRUE fgprocess_data will set *pfexit to TRUE and return TRUE. Also, if the freturncontrol argument is TRUE fgprocess_data will set *pfexit to TRUE and return TRUE. Otherwise fgprocess_data will continue trying to process data. If some error occurs, fgprocess_data will return FALSE. If there is not enough data to form a complete packet, then *pfexit will be set to FALSE, *pcneed will be set to the number of bytes needed to form a complete packet (unless pcneed is NULL) and fgprocess_data will return TRUE. If this function found a data packet, and pffound is not NULL, it will set *pffound to TRUE; this can be used to tell valid data from an endless stream of garbage and control packets. If fdoacks is TRUE, received packets will be acknowledged; otherwise they must be acknowledged later. */ static boolean fgprocess_data (qdaemon, fdoacks, freturncontrol, pfexit, pcneed, pffound) struct sdaemon *qdaemon; boolean fdoacks; boolean freturncontrol; boolean *pfexit; size_t *pcneed; boolean *pffound; { *pfexit = FALSE; if (pffound != NULL) *pffound = FALSE; while (iPrecstart != iPrecend) { char ab[CFRAMELEN]; int i, iget, cwant; unsigned short ihdrcheck, idatcheck; const char *zfirst, *zsecond; int cfirst, csecond; boolean fduprr; /* Look for the DLE which must start a packet. */ if (abPrecbuf[iPrecstart] != DLE) { char *zdle; cfirst = iPrecend - iPrecstart; if (cfirst < 0) cfirst = CRECBUFLEN - iPrecstart; zdle = memchr (abPrecbuf + iPrecstart, DLE, (size_t) cfirst); if (zdle == NULL) { iPrecstart = (iPrecstart + cfirst) % CRECBUFLEN; continue; } /* We don't need % CRECBUFLEN here because zdle - (abPrecbuf + iPrecstart) < cfirst <= CRECBUFLEN - iPrecstart. */ iPrecstart += zdle - (abPrecbuf + iPrecstart); } /* Get the first six bytes into ab. */ for (i = 0, iget = iPrecstart; i < CFRAMELEN && iget != iPrecend; i++, iget = (iget + 1) % CRECBUFLEN) ab[i] = abPrecbuf[iget]; /* If there aren't six bytes, there is no packet. */ if (i < CFRAMELEN) { if (pcneed != NULL) *pcneed = CFRAMELEN - i; return TRUE; } /* Make sure these six bytes start a packet. The check on IFRAME_DLE is basically a debugging check, since the above code should have ensured that it will never fail. If this is not the start of a packet, bump iPrecstart and loop around to look for another DLE. */ if (ab[IFRAME_DLE] != DLE || ab[IFRAME_K] < 1 || ab[IFRAME_K] > 9 || ab[IFRAME_XOR] != (ab[IFRAME_K] ^ ab[IFRAME_CHECKLOW] ^ ab[IFRAME_CHECKHIGH] ^ ab[IFRAME_CONTROL]) || CONTROL_TT (ab[IFRAME_CONTROL]) == ALTCHAN) { ++cGbad_hdr; ++cGerror_level; DEBUG_MESSAGE4 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Bad header: K %d TT %d XOR byte %d calc %d", ab[IFRAME_K] & 0xff, CONTROL_TT (ab[IFRAME_CONTROL]), ab[IFRAME_XOR] & 0xff, (ab[IFRAME_K] ^ ab[IFRAME_CHECKLOW] ^ ab[IFRAME_CHECKHIGH] ^ ab[IFRAME_CONTROL]) & 0xff); if (! fgcheck_errors (qdaemon)) return FALSE; iPrecstart = (iPrecstart + 1) % CRECBUFLEN; continue; } /* The zfirst and cfirst pair point to the first set of data for this packet; the zsecond and csecond point to the second set, in case the packet wraps around the end of the buffer. */ zfirst = abPrecbuf + iPrecstart + CFRAMELEN; cfirst = 0; zsecond = NULL; csecond = 0; if (ab[IFRAME_K] == KCONTROL) { /* This is a control packet. It should not have any data. */ if (CONTROL_TT (ab[IFRAME_CONTROL]) != CONTROL) { ++cGbad_hdr; ++cGerror_level; DEBUG_MESSAGE0 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Bad header: control packet with data"); if (! fgcheck_errors (qdaemon)) return FALSE; iPrecstart = (iPrecstart + 1) % CRECBUFLEN; continue; } idatcheck = (unsigned short) (0xaaaa - ab[IFRAME_CONTROL]); cwant = 0; } else { int cinbuf; unsigned short icheck; /* This is a data packet. It should not be type CONTROL. */ if (CONTROL_TT (ab[IFRAME_CONTROL]) == CONTROL) { ++cGbad_hdr; ++cGerror_level; DEBUG_MESSAGE0 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Bad header: data packet is type CONTROL"); if (! fgcheck_errors (qdaemon)) return FALSE; iPrecstart = (iPrecstart + 1) % CRECBUFLEN; continue; } cinbuf = iPrecend - iPrecstart; if (cinbuf < 0) cinbuf += CRECBUFLEN; cinbuf -= CFRAMELEN; /* Make sure we have enough data. If we don't, wait for more. */ cwant = (int) CPACKLEN (ab); if (cinbuf < cwant) { if (pcneed != NULL) *pcneed = cwant - cinbuf; return TRUE; } /* Set up the data pointers and compute the checksum. */ if (iPrecend >= iPrecstart) cfirst = cwant; else { cfirst = CRECBUFLEN - (iPrecstart + CFRAMELEN); if (cfirst >= cwant) cfirst = cwant; else if (cfirst > 0) { zsecond = abPrecbuf; csecond = cwant - cfirst; } else { /* Here cfirst is non-positive, so subtracting from abPrecbuf will actually skip the appropriate number of bytes at the start of abPrecbuf. */ zfirst = abPrecbuf - cfirst; cfirst = cwant; } } if (csecond == 0) icheck = (unsigned short) igchecksum (zfirst, (size_t) cfirst); else icheck = (unsigned short) igchecksum2 (zfirst, (size_t) cfirst, zsecond, (size_t) csecond); idatcheck = ((unsigned short) (((0xaaaa - (icheck ^ (ab[IFRAME_CONTROL] & 0xff))) & 0xffff))); } ihdrcheck = (unsigned short) (((ab[IFRAME_CHECKHIGH] & 0xff) << 8) | (ab[IFRAME_CHECKLOW] & 0xff)); if (ihdrcheck != idatcheck) { DEBUG_MESSAGE2 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Bad checksum: header 0x%x, data 0x%x", ihdrcheck, idatcheck); ++cGbad_checksum; ++cGerror_level; if (! fgcheck_errors (qdaemon)) return FALSE; /* If the checksum failed for a data packet, then if it was the one we were expecting send an RJ, otherwise ignore it. Previously if this code got the wrong packet number it would send an RR, but that may confuse some Telebit modems and it doesn't help in any case since the receiver will probably just ignore the RR as a duplicate (that's basically what this code does). If we totally missed the packet we will time out and send an RJ in the function fgwait_for_packet above. */ if (CONTROL_TT (ab[IFRAME_CONTROL]) != CONTROL) { /* Make sure we've acked everything up to this point. */ if (iGrecseq != iGlocal_ack) { if (! fgsend_acks (qdaemon)) return FALSE; } /* If this is the packet we wanted, tell the sender that it failed. */ if (CONTROL_XXX (ab[IFRAME_CONTROL]) == INEXTSEQ (iGrecseq)) { if (! fgsend_control (qdaemon, RJ, iGrecseq)) return FALSE; cGexpect_bad_order += iGrequest_winsize - 1; } } /* We can't skip the packet data after this, because if we have lost incoming bytes the next DLE will be somewhere in what we thought was the packet data. */ iPrecstart = (iPrecstart + 1) % CRECBUFLEN; continue; } /* We have a packet; remove the processed bytes from the receive buffer. */ iPrecstart = (iPrecstart + cwant + CFRAMELEN) % CRECBUFLEN; /* Store the control byte for the handshake routines. */ iGpacket_control = ab[IFRAME_CONTROL] & 0xff; /* Annoyingly, some UUCP packages appear to send an RR packet rather than an RJ packet when they want a packet to be resent. If we get a duplicate RR and we've never seen an RJ, we treat the RR as an RJ. */ fduprr = FALSE; if (cGremote_rejects == 0 && CONTROL_TT (ab[IFRAME_CONTROL]) == CONTROL && CONTROL_XXX (ab[IFRAME_CONTROL]) == RR && iGremote_ack == CONTROL_YYY (ab[IFRAME_CONTROL]) && INEXTSEQ (iGremote_ack) != iGsendseq && iGretransmit_seq == -1) { DEBUG_MESSAGE0 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Treating duplicate RR as RJ"); fduprr = TRUE; } /* Update the received sequence number from the yyy field of a data packet (if it is the one we are expecting) or an RR control packet. If we've been delaying sending packets until we received an ack, this may send out some packets. */ if ((CONTROL_TT (ab[IFRAME_CONTROL]) != CONTROL && CONTROL_XXX (ab[IFRAME_CONTROL]) == INEXTSEQ (iGrecseq)) || (CONTROL_XXX (ab[IFRAME_CONTROL]) == RR && ! fduprr)) { if (! fggot_ack (qdaemon, CONTROL_YYY (ab[IFRAME_CONTROL]))) return FALSE; } /* If this isn't a control message, make sure we have received the expected packet sequence number, acknowledge the packet if it's the right one, and process the data. */ if (CONTROL_TT (ab[IFRAME_CONTROL]) != CONTROL) { if (CONTROL_XXX (ab[IFRAME_CONTROL]) != INEXTSEQ (iGrecseq)) { /* We got the wrong packet number. */ DEBUG_MESSAGE2 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Got packet %d; expected %d", CONTROL_XXX (ab[IFRAME_CONTROL]), INEXTSEQ (iGrecseq)); if (cGexpect_bad_order > 0) --cGexpect_bad_order; else { ++cGbad_order; ++cGerror_level; if (! fgcheck_errors (qdaemon)) return FALSE; } /* This code used to send an RR to encourage the other side to get back in synch, but that may confuse some Telebit modems and does little good in any case, since the other side will probably just ignore it anyhow (that's what this code does). */ continue; } /* We got the packet we expected. */ ++cGrec_packets; if (cGerror_level > 0 && cGrec_packets % cGerror_decay == 0) --cGerror_level; cGexpect_bad_order = 0; iGrecseq = INEXTSEQ (iGrecseq); DEBUG_MESSAGE1 (DEBUG_PROTO, "fgprocess_data: Got packet %d", iGrecseq); /* Tell the caller that we found something. */ if (pffound != NULL) *pffound = TRUE; /* If we are supposed to do acknowledgements here, send back an RR packet. */ if (fdoacks) { if (! fgsend_acks (qdaemon)) return FALSE; } /* If this is a short data packet, adjust the data pointers and lengths. */ if (CONTROL_TT (ab[IFRAME_CONTROL]) == SHORTDATA) { int cshort, cmove; if ((zfirst[0] & 0x80) == 0) { cshort = zfirst[0] & 0xff; cmove = 1; } else { int cbyte2; if (cfirst > 1) cbyte2 = zfirst[1] & 0xff; else cbyte2 = zsecond[0] & 0xff; cshort = (zfirst[0] & 0x7f) + (cbyte2 << 7); cmove = 2; } DEBUG_MESSAGE1 (DEBUG_PROTO, "fgprocess_data: Packet short by %d", cshort); /* Adjust the start of the buffer for the bytes used by the count. */ if (cfirst > cmove) { zfirst += cmove; cfirst -= cmove; } else { zfirst = zsecond + (cmove - cfirst); cfirst = csecond - (cmove - cfirst); csecond = 0; } /* Adjust the length of the buffer for the bytes we are not supposed to consider. */ cshort -= cmove; if (csecond >= cshort) csecond -= cshort; else { cfirst -= cshort - csecond; csecond = 0; } #if DEBUG > 0 /* This should not happen, but just in case. */ if (cfirst < 0) cfirst = 0; #endif } if (! fgot_data (qdaemon, zfirst, (size_t) cfirst, zsecond, (size_t) csecond, -1, -1, (long) -1, INEXTSEQ (iGremote_ack) == iGsendseq, pfexit)) return FALSE; /* If fgot_data told us that we were finished, get out. */ if (*pfexit) return TRUE; /* If we've been asked to return control packets, get out now. */ if (freturncontrol) { *pfexit = TRUE; return TRUE; } continue; } /* Handle control messages here. */ #if DEBUG > 1 if (FDEBUGGING (DEBUG_PROTO) || (FDEBUGGING (DEBUG_ABNORMAL) && CONTROL_XXX (ab[IFRAME_CONTROL]) != RR)) ulog (LOG_DEBUG, "fgprocess_data: Got control %s %d", azGcontrol[CONTROL_XXX (ab[IFRAME_CONTROL])], CONTROL_YYY (ab[IFRAME_CONTROL])); #endif switch (CONTROL_XXX (ab[IFRAME_CONTROL])) { case CLOSE: /* The other side has closed the connection. */ if (fLog_sighup) { ulog (LOG_ERROR, "Received unexpected CLOSE packet"); (void) fgsend_control (qdaemon, CLOSE, 0); } return FALSE; case RR: /* Acknowledge receipt of a packet. This was already handled above, unless we are treating it as RJ. */ if (! fduprr) break; /* Fall through. */ case RJ: /* The other side dropped a packet. Begin retransmission with the packet following the one acknowledged. We don't retransmit the packets immediately, but instead wait for the first one to be acked. This prevents us from sending an entire window several times if we get several RJ packets. */ iGremote_ack = CONTROL_YYY (ab[IFRAME_CONTROL]); iGretransmit_seq = INEXTSEQ (iGremote_ack); if (iGretransmit_seq == iGsendseq) iGretransmit_seq = -1; else { char *zpack; DEBUG_MESSAGE2 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Remote reject: next %d resending %d", iGsendseq, iGretransmit_seq); ++cGresent_packets; if (fduprr) ++cGremote_duprrs; else ++cGremote_rejects; ++cGerror_level; if (! fgcheck_errors (qdaemon)) return FALSE; zpack = zgadjust_ack (iGretransmit_seq); if (! fsend_data (qdaemon->qconn, zpack, CFRAMELEN + CPACKLEN (zpack), TRUE)) return FALSE; } break; case SRJ: /* Selectively reject a particular packet. This is not used by UUCP, but it's easy to support. */ DEBUG_MESSAGE1 (DEBUG_PROTO | DEBUG_ABNORMAL, "fgprocess_data: Selective reject of %d", CONTROL_YYY (ab[IFRAME_CONTROL])); { char *zpack; ++cGresent_packets; ++cGremote_rejects; ++cGerror_level; zpack = zgadjust_ack (CONTROL_YYY (ab[IFRAME_CONTROL])); if (! fsend_data (qdaemon->qconn, zpack, CFRAMELEN + CPACKLEN (zpack), TRUE)) return FALSE; } break; case INITC: case INITB: case INITA: /* Ignore attempts to reinitialize. */ break; } /* If we've been asked to return control packets, get out. */ if (freturncontrol) { *pfexit = TRUE; return TRUE; } /* Loop around to look for the next packet, if any. */ } /* There is no data left in the receive buffer. */ if (pcneed != NULL) *pcneed = CFRAMELEN; return TRUE; } /* Compute the 'g' protocol checksum. This is unfortunately rather awkward. This is the most time consuming code in the entire program. It's also not a great checksum, since it can be fooled by some single bit errors. */ /* Sorry about this knavery, but it speeds up the VAX code significantly. It would be better to rewrite the whole routine in assembler. */ #ifdef __GNUC__ #ifdef __vax__ #define VAX_ASM 1 #endif #endif #if VAX_ASM #define ROTATE(i) \ asm ("cvtwl %1,%0\n\trotl $1,%0,%0" : "=g" (i) : "g" (i)) #else #define ROTATE(i) i += i + ((i & 0x8000) >> 15) #endif #define ITERATION \ /* Rotate ichk1 left. */ \ ROTATE (ichk1); \ \ /* The guts of the checksum. */ \ b = BUCHAR (*z++); \ if (b != 0) \ { \ ichk1 &= 0xffff; \ ichk1 += b; \ ichk2 += ichk1 ^ c; \ if ((ichk1 >> 16) != 0) \ ichk1 ^= ichk2; \ } \ else \ { \ ichk2 += ichk1 ^ c; \ ichk1 ^= ichk2; \ } \ \ --c static int igchecksum (z, c) register const char *z; register size_t c; { register unsigned long ichk1, ichk2; ichk1 = 0xffff; ichk2 = 0; do { register unsigned int b; ITERATION; ITERATION; ITERATION; ITERATION; } while (c > 0); return ichk1 & 0xffff; } /* We use a separate function compute the checksum if the block is split around the end of the receive buffer since it occurs much less frequently and the checksum is already high up in the profiles. These functions are almost identical, and this one actually only has a few more instructions in the inner loop. */ static int igchecksum2 (zfirst, cfirst, zsecond, csecond) const char *zfirst; size_t cfirst; const char *zsecond; size_t csecond; { register unsigned long ichk1, ichk2; register const char *z; register size_t c; z = zfirst; c = cfirst + csecond; ichk1 = 0xffff; ichk2 = 0; do { register unsigned int b; ITERATION; /* If the first buffer has been finished, switch to the second. */ --cfirst; if (cfirst == 0) z = zsecond; } while (c > 0); return ichk1 & 0xffff; }