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672 lines
19 KiB
C
672 lines
19 KiB
C
/* protj.c
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The 'j' protocol.
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Copyright (C) 1992 Ian Lance Taylor
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This file is part of the Taylor UUCP package.
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This program is free software; you can redistribute it and/or
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modify it under the terms of the GNU General Public License as
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published by the Free Software Foundation; either version 2 of the
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License, or (at your option) any later version.
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This program is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program; if not, write to the Free Software
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Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
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The author of the program may be contacted at ian@airs.com or
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c/o Infinity Development Systems, P.O. Box 520, Waltham, MA 02254.
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*/
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#include "uucp.h"
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#if USE_RCS_ID
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const char protj_rcsid[] = "$Id: protj.c,v 1.1 1993/08/04 19:36:23 jtc Exp $";
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#endif
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#include <ctype.h>
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#include <errno.h>
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#include "uudefs.h"
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#include "conn.h"
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#include "trans.h"
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#include "system.h"
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#include "prot.h"
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/* The 'j' protocol.
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The 'j' protocol is a wrapper around the 'i' protocol, which avoids
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the use of certain characters, such as XON and XOFF.
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Each 'j' protocol packet begins with a '^' character, followed by a
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two byte encoded size giving the total number of bytes in the
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packet. The first byte is HIGH, the second byte is LOW, and the
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number of bytes is (HIGH - 32) * 64 + (LOW - 32), where 32 <= HIGH
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< 127 and 32 <= LOW < 96 (i.e., HIGH and LOW are printable ASCII
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characters). This is followed by a '=' character. The next two
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bytes are the number of data bytes in the packet, using the same
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encoding. This is followed by a '@' character, and then that
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number of data bytes. The remaining bytes in the packet are
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indices of bytes which must be transformed, followed by a trailing
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'~' character. The indices are encoded in the following overly
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complex format.
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Each byte index is two bytes long. The first byte in the index is
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INDEX-HIGH and the second is INDEX-LOW. If 32 <= INDEX-HIGH < 126,
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the byte index refers to the byte at position (INDEX-HIGH - 32) *
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32 + INDEX-LOW % 32 in the actual data, where 32 <= INDEX-LOW <
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127. If 32 <= INDEX-LOW < 64, then 128 must be added to the
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indexed byte. If 64 <= INDEX-LOW < 96, then the indexed byte must
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be exclusive or'red with 32. If 96 <= INDEX-LOW < 127, both
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operations must be performed. If INDEX-HIGH == 126, then the byte
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index refers to the byte at position (INDEX-LOW - 32) * 32 + 31,
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where 32 <= INDEX-LOW < 126. 128 must be added to the byte, and it
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must be exclusive or'red with 32. This unfortunately requires a
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special test (when encoding INDEX-LOW must be checked for 127; when
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decoding INDEX-HIGH must be checked for 126). It does, however,
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permit the byte indices field to consist exclusively of printable
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ASCII characters.
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The maximum value for a byte index is (125 - 32) * 32 + 31 == 3007,
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so the is the maximum number of data bytes permitted. Since it is
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convenient to have each 'j' protocol packet correspond to each 'i'
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protocol packet, we restrict the 'i' protocol accordingly.
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Note that this encoding method assumes that we can send all
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printable ASCII characters. */
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/* The first byte of each packet. I just picked these values
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randomly, trying to get characters that were perhaps slightly less
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likely to appear in normal text. */
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#define FIRST '\136'
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/* The fourth byte of each packet. */
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#define FOURTH '\075'
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/* The seventh byte of each packet. */
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#define SEVENTH '\100'
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/* The trailing byte of each packet. */
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#define TRAILER '\176'
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/* The length of the header. */
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#define CHDRLEN (7)
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/* Get a number of bytes encoded in a two byte length at the start of
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a packet. */
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#define CGETLENGTH(b1, b2) (((b1) - 32) * 64 + ((b2) - 32))
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/* Set the high and low bytes of a two byte length at the start of a
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packet. */
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#define ISETLENGTH_FIRST(i) ((i) / 64 + 32)
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#define ISETLENGTH_SECOND(i) ((i) % 64 + 32)
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/* The maximum packet size we support, as determined by the byte
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indices. */
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#define IMAXPACKSIZE ((125 - 32) * 32 + 31)
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/* Amount to offset the bytes in the byte index by. */
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#define INDEX_OFFSET (32)
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/* Maximum value of INDEX-LOW, before offsetting. */
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#define INDEX_MAX_LOW (32)
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/* Maximum value of INDEX-HIGH, before offsetting. */
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#define INDEX_MAX_HIGH (94)
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/* The set of characters to avoid. */
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static char *zJavoid;
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/* The number of characters to avoid. */
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static size_t cJavoid;
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/* A buffer used when sending data. */
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static char *zJbuf;
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/* The end of the undecoded data in abPrecbuf. */
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static int iJrecend;
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/* Local functions. */
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static boolean fjsend_data P((struct sconnection *qconn, const char *zsend,
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size_t csend, boolean fdoread));
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static boolean fjreceive_data P((struct sconnection *qconn, size_t cneed,
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size_t *pcrec, int ctimeout,
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boolean freport));
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static boolean fjprocess_data P((size_t *pcneed));
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/* Start the protocol. We first send over the list of characters to
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avoid as an escape sequence, starting with FIRST and ending with
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TRAILER. There is no error checking done on this string. */
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boolean
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fjstart (qdaemon, pzlog)
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struct sdaemon *qdaemon;
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char **pzlog;
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{
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size_t clen;
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char *zsend;
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int b;
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size_t cbuf, cgot;
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char *zbuf;
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int i;
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/* Send the characters we want to avoid to the other side. */
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clen = strlen (zJavoid_parameter);
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zsend = zbufalc (clen + 3);
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zsend[0] = FIRST;
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memcpy (zsend + 1, zJavoid_parameter, clen);
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zsend[clen + 1] = TRAILER;
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zsend[clen + 2] = '\0';
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if (! fsend_data (qdaemon->qconn, zsend, clen + 2, TRUE))
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{
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ubuffree (zsend);
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return FALSE;
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}
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ubuffree (zsend);
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/* Read the characters the other side wants to avoid. */
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while ((b = breceive_char (qdaemon->qconn, cIsync_timeout, TRUE))
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!= FIRST)
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{
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if (b < 0)
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{
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if (b == -1)
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ulog (LOG_ERROR, "Timed out in 'j' protocol startup");
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return FALSE;
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}
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}
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cbuf = 20;
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zbuf = zbufalc (cbuf);
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cgot = 0;
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while ((b = breceive_char (qdaemon->qconn, cIsync_timeout, TRUE))
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!= TRAILER)
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{
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if (b < 0)
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{
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ubuffree (zbuf);
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if (b == -1)
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ulog (LOG_ERROR, "Timed out in 'j' protocol startup");
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return FALSE;
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}
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if (cgot + 1 >= cbuf)
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{
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char *znew;
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cbuf += 20;
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znew = zbufalc (cbuf);
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memcpy (znew, zbuf, cgot);
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ubuffree (zbuf);
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zbuf = znew;
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}
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zbuf[cgot] = b;
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++cgot;
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}
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zbuf[cgot] = '\0';
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/* Merge the local and remote avoid bytes into one list, translated
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into bytes. */
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cgot = cescape (zbuf);
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clen = strlen (zJavoid_parameter);
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zJavoid = zbufalc (clen + cgot + 1);
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memcpy (zJavoid, zJavoid_parameter, clen + 1);
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cJavoid = cescape (zJavoid);
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for (i = 0; i < cgot; i++)
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{
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if (memchr (zJavoid, zbuf[i], cJavoid) == NULL)
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{
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zJavoid[cJavoid] = zbuf[i];
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++cJavoid;
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}
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}
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ubuffree (zbuf);
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/* We can't avoid ASCII printable characters, since the encoding
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method assumes that they can always be sent. If it ever turns
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out to be important, a different encoding method could be used,
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perhaps keyed by a different FIRST character. */
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if (cJavoid == 0)
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{
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ulog (LOG_ERROR, "No characters to avoid in 'j' protocol");
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return FALSE;
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}
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for (i = 0; i < cJavoid; i++)
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{
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if (zJavoid[i] >= 32 && zJavoid[i] <= 126)
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{
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ulog (LOG_ERROR, "'j' protocol can't avoid character '\\%03o'",
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zJavoid[i]);
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return FALSE;
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}
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}
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/* If we are avoiding XON and XOFF, use XON/XOFF handshaking. */
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if (memchr (zJavoid, '\021', cJavoid) != NULL
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&& memchr (zJavoid, '\023', cJavoid) != NULL)
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{
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if (! fconn_set (qdaemon->qconn, PARITYSETTING_NONE,
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STRIPSETTING_EIGHTBITS, XONXOFF_ON))
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return FALSE;
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}
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/* Let the port settle. */
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usysdep_sleep (2);
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/* Allocate a buffer we use when sending data. We will probably
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never actually need one this big; if this code is ported to a
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computer with small amounts of memory, this should be changed to
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increase the buffer size as needed. */
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zJbuf = zbufalc (CHDRLEN + IMAXPACKSIZE * 3 + 1);
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zJbuf[0] = FIRST;
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zJbuf[3] = FOURTH;
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zJbuf[6] = SEVENTH;
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/* iJrecend is the end of the undecoded data, and iPrecend is the
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end of the decoded data. At this point there is no decoded data,
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and we must initialize the variables accordingly. */
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iJrecend = iPrecend;
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iPrecend = iPrecstart;
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/* Now do the 'i' protocol startup. */
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return fijstart (qdaemon, pzlog, IMAXPACKSIZE, fjsend_data,
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fjreceive_data);
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}
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/* Shut down the protocol. */
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boolean
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fjshutdown (qdaemon)
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struct sdaemon *qdaemon;
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{
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boolean fret;
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fret = fishutdown (qdaemon);
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ubuffree (zJavoid);
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ubuffree (zJbuf);
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return fret;
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}
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/* Encode a packet of data and send it. This copies the data, which
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is a waste of time, but calling fsend_data three times (for the
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header, the body, and the trailer) would waste even more time. */
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static boolean
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fjsend_data (qconn, zsend, csend, fdoread)
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struct sconnection *qconn;
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const char *zsend;
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size_t csend;
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boolean fdoread;
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{
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char *zput, *zindex;
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const char *zfrom, *zend;
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char bfirst, bsecond;
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int iprecendhold;
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boolean fret;
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zput = zJbuf + CHDRLEN;
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zindex = zput + csend;
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zfrom = zsend;
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zend = zsend + csend;
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/* Optimize for the common case of avoiding two characters. */
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bfirst = zJavoid[0];
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if (cJavoid <= 1)
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bsecond = bfirst;
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else
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bsecond = zJavoid[1];
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while (zfrom < zend)
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{
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char b;
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boolean f128, f32;
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int i, ihigh, ilow;
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b = *zfrom++;
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if (b != bfirst && b != bsecond)
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{
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int ca;
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char *za;
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if (cJavoid <= 2)
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{
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*zput++ = b;
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continue;
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}
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ca = cJavoid - 2;
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za = zJavoid + 2;
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while (ca-- != 0)
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if (*za++ == b)
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break;
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if (ca < 0)
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{
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*zput++ = b;
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continue;
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}
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}
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if ((b & 0x80) == 0)
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f128 = FALSE;
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else
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{
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b &=~ 0x80;
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f128 = TRUE;
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}
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if (b >= 32 && b != 127)
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f32 = FALSE;
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else
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{
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b ^= 0x20;
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f32 = TRUE;
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}
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/* We must now put the byte index into the buffer. The byte
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index is encoded similarly to the length of the actual data,
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but the byte index also encodes the operations that must be
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performed on the byte. The first byte in the index is the
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most significant bits. If we only had to subtract 128 from
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the byte, we use the second byte directly. If we had to xor
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the byte with 32, we add 32 to the second byte index. If we
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had to perform both operations, we add 64 to the second byte
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index. However, if we had to perform both operations, and
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the second byte index was 31, then after adding 64 and
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offsetting by 32 we would come up with 127, which we are not
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permitted to use. Therefore, in this special case we set the
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first byte of the index to 126 and put the original first
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byte into the second byte position instead. This is why we
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could not permit the high byte of the length of the actual
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data to be 126. We can get away with the switch because both
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the value of the second byte index (31) and the operations to
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perform (both) are known. */
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i = zput - (zJbuf + CHDRLEN);
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ihigh = i / INDEX_MAX_LOW;
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ilow = i % INDEX_MAX_LOW;
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if (f128 && ! f32)
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;
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else if (f32 && ! f128)
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ilow += INDEX_MAX_LOW;
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else
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{
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/* Both operations had to be performed. */
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if (ilow != INDEX_MAX_LOW - 1)
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ilow += 2 * INDEX_MAX_LOW;
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else
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{
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ilow = ihigh;
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ihigh = INDEX_MAX_HIGH;
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}
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}
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*zindex++ = ihigh + INDEX_OFFSET;
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*zindex++ = ilow + INDEX_OFFSET;
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*zput++ = b;
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}
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*zindex++ = TRAILER;
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/* Set the lengths into the buffer. zJbuf[0,3,6] were set when
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zJbuf was allocated, and are never changed thereafter. */
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zJbuf[1] = ISETLENGTH_FIRST (zindex - zJbuf);
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zJbuf[2] = ISETLENGTH_SECOND (zindex - zJbuf);
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zJbuf[4] = ISETLENGTH_FIRST (csend);
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zJbuf[5] = ISETLENGTH_SECOND (csend);
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/* Send the data over the line. We must preserve iPrecend as
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discussed in fjreceive_data. */
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iprecendhold = iPrecend;
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iPrecend = iJrecend;
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fret = fsend_data (qconn, zJbuf, (size_t) (zindex - zJbuf), fdoread);
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iJrecend = iPrecend;
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iPrecend = iprecendhold;
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/* Process any bytes that may have been placed in abPrecbuf. */
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if (fret && iPrecend != iJrecend)
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{
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if (! fjprocess_data ((size_t *) NULL))
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return FALSE;
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}
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return fret;
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}
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/* Receive and decode data. This is called by fiwait_for_packet. We
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need to be able to return decoded data between iPrecstart and
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iPrecend, while not losing any undecoded partial packets we may
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have read. We use iJrecend as a pointer to the end of the
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undecoded data, and set iPrecend for the decoded data. iPrecend
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points to the start of the undecoded data. */
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static boolean
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fjreceive_data (qconn, cineed, pcrec, ctimeout, freport)
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struct sconnection *qconn;
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size_t cineed;
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size_t *pcrec;
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int ctimeout;
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boolean freport;
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{
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int iprecendstart;
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size_t cjneed;
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size_t crec;
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int cnew;
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iprecendstart = iPrecend;
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/* Figure out how many bytes we need to decode the next packet. */
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if (! fjprocess_data (&cjneed))
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return FALSE;
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/* As we long as we read some data but don't have enough to decode a
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packet, we try to read some more. We decrease the timeout each
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time so that we will not wait forever if the connection starts
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dribbling data. */
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do
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{
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int iprecendhold;
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size_t cneed;
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if (cjneed > cineed)
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cneed = cjneed;
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else
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cneed = cineed;
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/* We are setting iPrecend to the end of the decoded data for
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the 'i' protocol. When we do the actual read, we have to set
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it to the end of the undecoded data so that any undecoded
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data we have received is not overwritten. */
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iprecendhold = iPrecend;
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iPrecend = iJrecend;
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if (! freceive_data (qconn, cneed, &crec, ctimeout, freport))
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return FALSE;
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iJrecend = iPrecend;
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iPrecend = iprecendhold;
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/* Process any data we have received. This will set iPrecend to
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the end of the new decoded data. */
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if (! fjprocess_data (&cjneed))
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return FALSE;
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cnew = iPrecend - iprecendstart;
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if (cnew < 0)
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cnew += CRECBUFLEN;
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if (cnew > cineed)
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cineed = 0;
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else
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cineed -= cnew;
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--ctimeout;
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}
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while (cnew == 0 && crec > 0 && ctimeout > 0);
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DEBUG_MESSAGE1 (DEBUG_PROTO, "fjreceive_data: Got %d decoded bytes",
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cnew);
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*pcrec = cnew;
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return TRUE;
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}
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/* Decode the data in the buffer, optionally returning the number of
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bytes needed to complete the next packet. */
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||
|
||
static boolean
|
||
fjprocess_data (pcneed)
|
||
size_t *pcneed;
|
||
{
|
||
int istart;
|
||
|
||
istart = iPrecend;
|
||
while (istart != iJrecend)
|
||
{
|
||
int i, iget;
|
||
char ab[CHDRLEN];
|
||
int cpacket, cdata, chave;
|
||
int iindex, iendindex;
|
||
|
||
/* Find the next occurrence of FIRST. If we have to skip some
|
||
garbage bytes to get to it, zero them out (so they don't
|
||
confuse the 'i' protocol) and advance iPrecend. This will
|
||
save us from looking at them again. */
|
||
if (abPrecbuf[istart] != FIRST)
|
||
{
|
||
int cintro;
|
||
char *zintro;
|
||
size_t cskipped;
|
||
|
||
cintro = iJrecend - istart;
|
||
if (cintro < 0)
|
||
cintro = CRECBUFLEN - istart;
|
||
|
||
zintro = memchr (abPrecbuf + istart, FIRST, (size_t) cintro);
|
||
if (zintro == NULL)
|
||
{
|
||
bzero (abPrecbuf + istart, (size_t) cintro);
|
||
istart = (istart + cintro) % CRECBUFLEN;
|
||
iPrecend = istart;
|
||
continue;
|
||
}
|
||
|
||
cskipped = zintro - (abPrecbuf + istart);
|
||
bzero (abPrecbuf + istart, cskipped);
|
||
istart += cskipped;
|
||
iPrecend = istart;
|
||
}
|
||
|
||
for (i = 0, iget = istart;
|
||
i < CHDRLEN && iget != iJrecend;
|
||
++i, iget = (iget + 1) % CRECBUFLEN)
|
||
ab[i] = abPrecbuf[iget];
|
||
|
||
if (i < CHDRLEN)
|
||
{
|
||
if (pcneed != NULL)
|
||
*pcneed = CHDRLEN - i;
|
||
return TRUE;
|
||
}
|
||
|
||
cpacket = CGETLENGTH (ab[1], ab[2]);
|
||
cdata = CGETLENGTH (ab[4], ab[5]);
|
||
|
||
/* Make sure the header has the right magic characters, that the
|
||
data is not larger than the packet, and that we have an even
|
||
number of byte index characters. */
|
||
if (ab[3] != FOURTH
|
||
|| ab[6] != SEVENTH
|
||
|| cdata > cpacket - CHDRLEN - 1
|
||
|| (cpacket - cdata - CHDRLEN - 1) % 2 == 1)
|
||
{
|
||
istart = (istart + 1) % CRECBUFLEN;
|
||
continue;
|
||
}
|
||
|
||
chave = iJrecend - istart;
|
||
if (chave < 0)
|
||
chave += CRECBUFLEN;
|
||
|
||
if (chave < cpacket)
|
||
{
|
||
if (pcneed != NULL)
|
||
*pcneed = cpacket - chave;
|
||
return TRUE;
|
||
}
|
||
|
||
/* Figure out where the byte indices start and end. */
|
||
iindex = (istart + CHDRLEN + cdata) % CRECBUFLEN;
|
||
iendindex = (istart + cpacket - 1) % CRECBUFLEN;
|
||
|
||
/* Make sure the magic trailer character is there. */
|
||
if (abPrecbuf[iendindex] != TRAILER)
|
||
{
|
||
istart = (istart + 1) % CRECBUFLEN;
|
||
continue;
|
||
}
|
||
|
||
/* We have a packet to decode. The decoding process is simpler
|
||
than the encoding process, since all we have to do is examine
|
||
the byte indices. We zero out the byte indices as we go, so
|
||
that they will not confuse the 'i' protocol. */
|
||
while (iindex != iendindex)
|
||
{
|
||
int ihigh, ilow;
|
||
boolean f32, f128;
|
||
int iset;
|
||
|
||
ihigh = abPrecbuf[iindex] - INDEX_OFFSET;
|
||
abPrecbuf[iindex] = 0;
|
||
iindex = (iindex + 1) % CRECBUFLEN;
|
||
ilow = abPrecbuf[iindex] - INDEX_OFFSET;
|
||
abPrecbuf[iindex] = 0;
|
||
iindex = (iindex + 1) % CRECBUFLEN;
|
||
|
||
/* Now we must undo the encoding, by adding 128 and xoring
|
||
with 32 as appropriate. Which to do is encoded in the
|
||
low byte, except that if the high byte is the special
|
||
value 126, then the low byte is actually the high byte
|
||
and both operations are performed. */
|
||
f128 = TRUE;
|
||
f32 = TRUE;
|
||
if (ihigh == INDEX_MAX_HIGH)
|
||
iset = ilow * INDEX_MAX_LOW + INDEX_MAX_LOW - 1;
|
||
else
|
||
{
|
||
iset = ihigh * INDEX_MAX_LOW + ilow % INDEX_MAX_LOW;
|
||
if (ilow < INDEX_MAX_LOW)
|
||
f32 = FALSE;
|
||
else if (ilow < 2 * INDEX_MAX_LOW)
|
||
f128 = FALSE;
|
||
}
|
||
|
||
/* Now iset is the index from the start of the data to the
|
||
byte to modify; adjust it to an index in abPrecbuf. */
|
||
iset = (istart + CHDRLEN + iset) % CRECBUFLEN;
|
||
|
||
if (f128)
|
||
abPrecbuf[iset] |= 0x80;
|
||
if (f32)
|
||
abPrecbuf[iset] ^= 0x20;
|
||
}
|
||
|
||
/* Zero out the header and trailer to avoid confusing the 'i'
|
||
protocol, and update iPrecend to the end of decoded data. */
|
||
for (i = 0, iget = istart;
|
||
i < CHDRLEN && iget != iJrecend;
|
||
++i, iget = (iget + 1) % CRECBUFLEN)
|
||
abPrecbuf[iget] = 0;
|
||
abPrecbuf[iendindex] = 0;
|
||
iPrecend = (iendindex + 1) % CRECBUFLEN;
|
||
istart = iPrecend;
|
||
}
|
||
|
||
if (pcneed != NULL)
|
||
*pcneed = CHDRLEN + 1;
|
||
return TRUE;
|
||
}
|