Xref: utzoo comp.sources.bugs:2923 comp.compression:593 Path: utzoo!utgpu!news-server.csri.toronto.edu!bonnie.concordia.ca!uunet!viusys!alembic!csu From: csu@alembic.acs.com (Dave Mack) Newsgroups: comp.sources.bugs,comp.compression Subject: Re: Problem with compress Keywords: compress bug symlinks Message-ID: <1991May19.171426.15437@alembic.acs.com> Date: 19 May 91 17:14:26 GMT References: <1991May14.044431.23932@sparky.IMD.Sterling.COM> Organization: Alembic Computer Services, McLean VA Lines: 2125 In article <1991May14.044431.23932@sparky.IMD.Sterling.COM> kent@sparky.IMD.Sterling.COM (Kent Landfield) writes: >Have I missed something here ? Is this a known problem that some consider >a feature ? I would much prefer that compress fail on symlinks as it does >on hard links. How often have you "strolled" into a directory when space >was becoming a problem and typed "compress *" without even considering >which were symlinks and which were regular files ? (only 1/4 :-)) > >Wasn't the idea to save space instead of generate more disk usage ? >Has someone fixed this already ? Yes. I've been using this version of compress for 4 years without problems. It has a "-r" flag to do recursive compression of directory trees (*much* faster than compressdir.) As a side- effect, it ignores anything that isn't a regular file, including symlinks. WARNING: this hasn't been tested on anything but BSD machines - use on SYSV at your own risk. I'm posting the shar file because it's reasonably short. If you think it's of sufficient interest, feel free to pump it through comp.sources.misc. Dave Mack -------------------------------- cut here -------------------------------- #! /bin/sh # This is a shell archive. Remove anything before this line, then unpack # it by saving it into a file and typing "sh file". To overwrite existing # files, type "sh file -c". You can also feed this as standard input via # unshar, or by typing "sh 'README' <<'END_OF_FILE' XModifications for version 4.1: X o Added -r command line flag to allow recursive compression/ X decompression. As a side-effect, compress no longer tries X to compress/decompress anything that isn't a regular file. X o Decompression silently ignores any file that doesn't X end in ".Z". The previous behavior (appending a .Z and X continuing) was wrong in too many cases. X XWARNING: version 4.1 has NOT been tested on System V, Xenix or any Xother non-Berkeleyoid Unix. Watch your step. X XCompress version 4.0 improvements: X o compress() speedup (10-50%) by changing division hash to xor X o decompress() speedup (5-10%) X o Memory requirements reduced (3-30%) X o Stack requirements reduced to less than 4kb X o Removed 'Big+Fast' compress code (FBITS) because of compress speedup X o Portability mods for Z8000 and PC/XT (but not zeus 3.2) X o Default to 'quiet' mode X o Unification of 'force' flags X o Manual page overhaul X o Portability enhancement for M_XENIX X o Removed text on #else and #endif X o Added "-V" switch to print version and options X o Added #defines for SIGNED_COMPARE_SLOW X o Added Makefile and "usermem" program X o Removed all floating point computations X o New programs: X compressdir - compress all files on a directory X uncompressdir - uncompress all files on a directory X zcmp - cmp compressed files X zdiff - diff compressed files X The following are with thanks to philabs!per: X btoa - convert binary to ascii for mailing X atob - convert ascii to binary with checksum X tarmail - tar, compress, btoa, and mail files X untarmail - restore "tarmail" files X X WARNING: These last few programs are not compatible X with the original ones from the net. The encoding X has changed. See btoa.c for more info. X XThe "usermem" script attempts to determine the maximum process size. Some Xediting of the script may be necessary (see the comments). If you can't get Xit to work at all, just create file "USERMEM" containing the maximum process Xsize in decimal. X XThe following preprocessor symbols control the compilation of "compress.c": X X o USERMEM Maximum process memory on the system X o SACREDMEM Amount to reserve for other proceses X o SIGNED_COMPARE_SLOW Unsigned compare instructions are faster X o NO_UCHAR Don't use "unsigned char" types X o BITS Overrules default set by USERMEM-SACREDMEM X o vax Generate inline assembler X o interdata Defines SIGNED_COMPARE_SLOW X o M_XENIX Makes arrays < 65536 bytes each X o pdp11 BITS=12, NO_UCHAR X o z8000 BITS=12 X o pcxt BITS=12 X o BSD4_2 Allow long filenames ( > 14 characters) & X Call setlinebuf(stderr) X XThe difference "usermem-sacredmem" determines the maximum BITS that can be Xspecified with the "-b" flag. X Xmemory: at least BITS X------ -- ----- ---- X 433,484 16 X 229,600 15 X 127,536 14 X 73,464 13 X 0 12 X XThe default is BITS=16. X XThe maximum bits can be overrulled by specifying "-DBITS=bits" at Xcompilation time. X XWARNING: files compressed on a large machine with more bits than allowed by Xa version of compress on a smaller machine cannot be decompressed! Use the X"-b12" flag to generate a file on a large machine that can be uncompressed Xon a 16-bit machine. X XThe output of compress 4.0 is fully compatible with that of compress 3.0. XIn other words, the output of compress 4.0 may be fed into uncompress 3.0 or Xthe output of compress 3.0 may be fed into uncompress 4.0. X XThe output of compress 4.0 not compatable with that of Xcompress 2.0. However, compress 4.0 still accepts the output of Xcompress 2.0. To generate output that is compatable with compress X2.0, use the undocumented "-C" flag. X XCheck the Makefile, then "make". END_OF_FILE if test 3682 -ne `wc -c <'README'`; then echo shar: \"'README'\" unpacked with wrong size! fi # end of 'README' fi if test -f 'Makefile' -a "${1}" != "-c" ; then echo shar: Will not clobber existing file \"'Makefile'\" else echo shar: Extracting \"'Makefile'\" \(1634 characters\) sed "s/^X//" >'Makefile' <<'END_OF_FILE' X# X# Makefile for compress version 4.1 X# XCC=cc X# X# set your compile flags. X# The BSD4_2 flag attempts to compensate for the SYSV short filename X# deficiency. Since I've never tested this under SYSV, I don't know X# how well it works. X# The README file describes other flags you may need. X# XCFLAGS=-O -DBSD4_2 X# X# BIN is where the compress executable and the uncompress and zcat X# links will be installed X# XBIN=/usr/local/bin X# X# MAN says where to install the man page X# XMAN=/usr/man/manl X# X# MANSUF is the suffix the installed manual page should have X# XMANSUF=l X# X# LN is how to make links (hard or symbolic) on your system X# XLN=ln -s X# X# LIBS contains any additional libraries you may need to link. X# In particular, you may need -lndir or equiv. to get the X# public domain directory access routines if they aren't in your libc. X# XLIBS= X X XSHARFILES=README Makefile usermem compress.c compress.1 X Xall: compress X Xcompress: USERMEM compress.c X $(CC) $(CFLAGS) -DUSERMEM=`cat USERMEM` -o compress compress.c $(LIBS) X X# USERMEM may have to be set by hand. It should contain the amount of X# available user memory in bytes. See the README file for more info. XUSERMEM: X sh usermem > USERMEM X Xinstall: compress compress.1 X cp compress $(BIN) X rm -f $(BIN)/uncompress $(BIN)/zcat X $(LN) $(BIN)/compress $(BIN)/uncompress X $(LN) $(BIN)/compress $(BIN)/zcat X cp compress.1 $(MAN)/compress.$(MANSUF) X rm -f $(MAN)/uncompress.$(MANSUF) $(MAN)/zcat.$(MANSUF) X $(LN) $(MAN)/compress.$(MANSUF) $(MAN)/uncompress.$(MANSUF) X $(LN) $(MAN)/compress.$(MANSUF) $(MAN)/zcat.$(MANSUF) X Xclean: X rm -f compress core X Xshar: X shar -o compress41.shar $(SHARFILES) END_OF_FILE if test 1634 -ne `wc -c <'Makefile'`; then echo shar: \"'Makefile'\" unpacked with wrong size! fi # end of 'Makefile' fi if test -f 'usermem' -a "${1}" != "-c" ; then echo shar: Will not clobber existing file \"'usermem'\" else echo shar: Extracting \"'usermem'\" \(1748 characters\) sed "s/^X//" >'usermem' <<'END_OF_FILE' X: This shell script snoops around to find the maximum amount of available X: user memory. These variables need to be set only if there is no X: /usr/adm/messages. KMEM, UNIX, and CLICKSIZE can be set on the command X: line, if desired, e.g. UNIX=/unix XKMEM=/dev/kmem # User needs read access to KMEM XUNIX= X# VAX CLICKSIZE=512, UNIX=/vmunix X# PDP-11 CLICKSIZE=64, UNIX=/unix X# CADLINC 68000 CLICKSIZE=4096, UNIX=/unix X# Perkin-Elmer 3205 CLICKSIZE=4096, UNIX=/edition7 X# Perkin-Elmer all others, CLICKSIZE=2048, UNIX=/edition7 XCLICKSIZE=512 Xeval $* X XSIZE=0 Xif test -r /usr/adm/messages # probably the most transportable Xthen X SIZE=`grep avail /usr/adm/messages | sed -n '$s/.*[ ]//p'` Xfi X Xif test 0$SIZE -le 0 # no SIZE in /usr/adm/messages Xthen X if test -r $KMEM # Readable KMEM X then X if test -n "$UNIX" X then X : User must have specified it already. X elif test -r /vmunix X then X UNIX=/vmunix X CLICKSIZE=512 # Probably VAX X elif test -r /edition7 X then X UNIX=/edition7 X CLICKSIZE=2048 # Perkin-Elmer: change to 4096 on a 3205 X elif test -r /unix X then X UNIX=/unix # Could be anything X fi X if test -n "$UNIX" X then X SIZE=`echo maxmem/D | adb $UNIX $KMEM | sed -n '$s/.*[ ]//p'` X if test 0$SIZE -le 0 X then X SIZE=`echo physmem/D | adb $UNIX $KMEM | sed -n '$s/.*[ ]//p'` X fi X SIZE=`expr 0$SIZE '*' $CLICKSIZE` X fi X fi Xfi X Xcase $UNIX in X /vmunix) # Assume 4.2bsd: check for resource limits X MAXSIZE=`csh -c limit | awk 'BEGIN { MAXSIZE = 1000000 } X/datasize|memoryuse/ && NF == 3 { if ($2 < MAXSIZE) MAXSIZE = $2 } XEND { print MAXSIZE * 1000 }'` X if test $MAXSIZE -lt $SIZE X then X SIZE=$MAXSIZE X fi X ;; Xesac X Xif test 0$SIZE -le 0 Xthen X echo 0;exit 1 Xelse X echo $SIZE Xfi END_OF_FILE if test 1748 -ne `wc -c <'usermem'`; then echo shar: \"'usermem'\" unpacked with wrong size! fi chmod +x 'usermem' # end of 'usermem' fi if test -f 'compress.c' -a "${1}" != "-c" ; then echo shar: Will not clobber existing file \"'compress.c'\" else echo shar: Extracting \"'compress.c'\" \(41053 characters\) sed "s/^X//" >'compress.c' <<'END_OF_FILE' X/* X * Compress - data compression program X */ X#define min(a,b) ((a>b) ? b : a) X X/* X * machine variants which require cc -Dmachine: pdp11, z8000, pcxt X */ X X/* X * Set USERMEM to the maximum amount of physical user memory available X * in bytes. USERMEM is used to determine the maximum BITS that can be used X * for compression. X * X * SACREDMEM is the amount of physical memory saved for others; compress X * will hog the rest. X */ X#ifndef SACREDMEM X#define SACREDMEM 0 X#endif X X#ifndef USERMEM X# define USERMEM 450000 /* default user memory */ X#endif X X#ifdef interdata /* (Perkin-Elmer) */ X#define SIGNED_COMPARE_SLOW /* signed compare is slower than unsigned */ X#endif X X#ifdef pdp11 X# define BITS 12 /* max bits/code for 16-bit machine */ X# define NO_UCHAR /* also if "unsigned char" functions as signed char */ X# undef USERMEM X#endif /* pdp11 */ /* don't forget to compile with -i */ X X#ifdef z8000 X# define BITS 12 X# undef vax /* weird preprocessor */ X# undef USERMEM X#endif /* z8000 */ X X#ifdef pcxt X# define BITS 12 X# undef USERMEM X#endif /* pcxt */ X X#ifdef USERMEM X# if USERMEM >= (433484+SACREDMEM) X# define PBITS 16 X# else X# if USERMEM >= (229600+SACREDMEM) X# define PBITS 15 X# else X# if USERMEM >= (127536+SACREDMEM) X# define PBITS 14 X# else X# if USERMEM >= (73464+SACREDMEM) X# define PBITS 13 X# else X# define PBITS 12 X# endif X# endif X# endif X# endif X# undef USERMEM X#endif /* USERMEM */ X X#ifdef PBITS /* Preferred BITS for this memory size */ X# ifndef BITS X# define BITS PBITS X# endif BITS X#endif /* PBITS */ X X#if BITS == 16 X# define HSIZE 69001 /* 95% occupancy */ X#endif X#if BITS == 15 X# define HSIZE 35023 /* 94% occupancy */ X#endif X#if BITS == 14 X# define HSIZE 18013 /* 91% occupancy */ X#endif X#if BITS == 13 X# define HSIZE 9001 /* 91% occupancy */ X#endif X#if BITS <= 12 X# define HSIZE 5003 /* 80% occupancy */ X#endif X X#ifdef M_XENIX /* Stupid compiler can't handle arrays with */ X# if BITS == 16 /* more than 65535 bytes - so we fake it */ X# define XENIX_16 X# else X# if BITS > 13 /* Code only handles BITS = 12, 13, or 16 */ X# define BITS 13 X# endif X# endif X#endif X X/* X * a code_int must be able to hold 2**BITS values of type int, and also -1 X */ X#if BITS > 15 Xtypedef long int code_int; X#else Xtypedef int code_int; X#endif X X#ifdef SIGNED_COMPARE_SLOW Xtypedef unsigned long int count_int; Xtypedef unsigned short int count_short; X#else Xtypedef long int count_int; X#endif X X#ifdef NO_UCHAR X typedef char char_type; X#else X typedef unsigned char char_type; X#endif /* UCHAR */ Xchar_type magic_header[] = { "\037\235" }; /* 1F 9D */ X X/* Defines for third byte of header */ X#define BIT_MASK 0x1f X#define BLOCK_MASK 0x80 X/* Masks 0x40 and 0x20 are free. I think 0x20 should mean that there is X a fourth header byte (for expansion). X*/ X#define INIT_BITS 9 /* initial number of bits/code */ X X/* X * compress.c - File compression ala IEEE Computer, June 1984. X * X * Authors: Spencer W. Thomas (decvax!harpo!utah-cs!utah-gr!thomas) X * Jim McKie (decvax!mcvax!jim) X * Steve Davies (decvax!vax135!petsd!peora!srd) X * Ken Turkowski (decvax!decwrl!turtlevax!ken) X * James A. Woods (decvax!ihnp4!ames!jaw) X * Joe Orost (decvax!vax135!petsd!joe) X * X * $Header: compress.c,v 4.0 85/07/30 12:50:00 joe Release $ X * $Log: compress.c,v $ X * Revision 4.1 87/05/29 now inco!mack X * Modified to recursively compress directories ('r' flag). As a side X * effect, compress will no longer attempt to compress things that X * aren't "regular" files. X * X * Revision 4.0 85/07/30 12:50:00 joe X * Removed ferror() calls in output routine on every output except first. X * Prepared for release to the world. X * X * Revision 3.6 85/07/04 01:22:21 joe X * Remove much wasted storage by overlaying hash table with the tables X * used by decompress: tab_suffix[1<putc] and X * added signal catcher [plus beef in writeerr()] to delete effluvia. X * X * Revision 2.0 84/08/28 22:00:00 petsd!joe X * Add check for foreground before prompting user. Insert maxbits into X * compressed file. Force file being uncompressed to end with ".Z". X * Added "-c" flag and "zcat". Prepared for release. X * X * Revision 1.10 84/08/24 18:28:00 turtlevax!ken X * Will only compress regular files (no directories), added a magic number X * header (plus an undocumented -n flag to handle old files without headers), X * added -f flag to force overwriting of possibly existing destination file, X * otherwise the user is prompted for a response. Will tack on a .Z to a X * filename if it doesn't have one when decompressing. Will only replace X * file if it was compressed. X * X * Revision 1.9 84/08/16 17:28:00 turtlevax!ken X * Removed scanargs(), getopt(), added .Z extension and unlimited number of X * filenames to compress. Flags may be clustered (-Ddvb12) or separated X * (-D -d -v -b 12), or combination thereof. Modes and other status is X * copied with copystat(). -O bug for 4.2 seems to have disappeared with X * 1.8. X * X * Revision 1.8 84/08/09 23:15:00 joe X * Made it compatible with vax version, installed jim's fixes/enhancements X * X * Revision 1.6 84/08/01 22:08:00 joe X * Sped up algorithm significantly by sorting the compress chain. X * X * Revision 1.5 84/07/13 13:11:00 srd X * Added C version of vax asm routines. Changed structure to arrays to X * save much memory. Do unsigned compares where possible (faster on X * Perkin-Elmer) X * X * Revision 1.4 84/07/05 03:11:11 thomas X * Clean up the code a little and lint it. (Lint complains about all X * the regs used in the asm, but I'm not going to "fix" this.) X * X * Revision 1.3 84/07/05 02:06:54 thomas X * Minor fixes. X * X * Revision 1.2 84/07/05 00:27:27 thomas X * Add variable bit length output. X * X */ Xstatic char rcs_ident[] = "$Header: compress.c,v 4.0 85/07/30 12:50:00 joe Release $"; X X#include X#include X#include X#include X#include X#ifdef BSD4_2 X#include X#endif X X#define ARGVAL() (*++(*argv) || (--argc && *++argv)) X Xint n_bits; /* number of bits/code */ Xint maxbits = BITS; /* user settable max # bits/code */ Xcode_int maxcode; /* maximum code, given n_bits */ Xcode_int maxmaxcode = 1 << BITS; /* should NEVER generate this code */ X#ifdef COMPATIBLE /* But wrong! */ X# define MAXCODE(n_bits) (1 << (n_bits) - 1) X#else X# define MAXCODE(n_bits) ((1 << (n_bits)) - 1) X#endif /* COMPATIBLE */ X X#ifdef XENIX_16 Xcount_int htab0[8192]; Xcount_int htab1[8192]; Xcount_int htab2[8192]; Xcount_int htab3[8192]; Xcount_int htab4[8192]; Xcount_int htab5[8192]; Xcount_int htab6[8192]; Xcount_int htab7[8192]; Xcount_int htab8[HSIZE-65536]; Xcount_int * htab[9] = { X htab0, htab1, htab2, htab3, htab4, htab5, htab6, htab7, htab8 }; X X#define htabof(i) (htab[(i) >> 13][(i) & 0x1fff]) Xunsigned short code0tab[16384]; Xunsigned short code1tab[16384]; Xunsigned short code2tab[16384]; Xunsigned short code3tab[16384]; Xunsigned short code4tab[16384]; Xunsigned short * codetab[5] = { X code0tab, code1tab, code2tab, code3tab, code4tab }; X X#define codetabof(i) (codetab[(i) >> 14][(i) & 0x3fff]) X X#else /* Normal machine */ Xcount_int htab [HSIZE]; Xunsigned short codetab [HSIZE]; X#define htabof(i) htab[i] X#define codetabof(i) codetab[i] X#endif /* XENIX_16 */ Xcode_int hsize = HSIZE; /* for dynamic table sizing */ Xcount_int fsize; X X/* X * To save much memory, we overlay the table used by compress() with those X * used by decompress(). The tab_prefix table is the same size and type X * as the codetab. The tab_suffix table needs 2**BITS characters. We X * get this from the beginning of htab. The output stack uses the rest X * of htab, and contains characters. There is plenty of room for any X * possible stack (stack used to be 8000 characters). X */ X X#define tab_prefixof(i) codetabof(i) X#ifdef XENIX_16 X# define tab_suffixof(i) ((char_type *)htab[(i)>>15])[(i) & 0x7fff] X# define de_stack ((char_type *)(htab2)) X#else /* Normal machine */ X# define tab_suffixof(i) ((char_type *)(htab))[i] X# define de_stack ((char_type *)&tab_suffixof(1< debug X * -V => print Version; debug verbose X * -d => do_decomp X * -v => unquiet X * -f => force overwrite of output file X * -n => no header: useful to uncompress old files X * -b maxbits => maxbits. If -b is specified, then maxbits MUST be X * given also. X * -c => cat all output to stdout X * -C => generate output compatible with compress 2.0. X * -r => recursively compress directories X * if a string is left, must be an input filename. X */ X for (argc--, argv++; argc > 0; argc--, argv++) { X if (**argv == '-') { /* A flag argument */ X while (*++(*argv)) { /* Process all flags in this arg */ X switch (**argv) { X#ifdef DEBUG X case 'D': X debug = 1; X break; X case 'V': X verbose = 1; X version(); X break; X#else X case 'V': X version(); X break; X#endif /* DEBUG */ X case 'v': X quiet = 0; X break; X case 'd': X do_decomp = 1; X break; X case 'f': X case 'F': X overwrite = 1; X force = 1; X break; X case 'n': X nomagic = 1; X break; X case 'C': X block_compress = 0; X break; X case 'b': X if (!ARGVAL()) { X fprintf(stderr, "Missing maxbits\n"); X Usage(); X exit(1); X } X maxbits = atoi(*argv); X goto nextarg; X case 'c': X zcat_flg = 1; X break; X case 'q': X quiet = 1; X break; X case 'r': X case 'R': X recursive = 1; X break; X default: X fprintf(stderr, "Unknown flag: '%c'; ", **argv); X Usage(); X exit(1); X } X } X } X else { /* Input file name */ X *fileptr++ = *argv; /* Build input file list */ X *fileptr = NULL; X /* process nextarg; */ X } X nextarg: continue; X } X X if(maxbits < INIT_BITS) maxbits = INIT_BITS; X if (maxbits > BITS) maxbits = BITS; X maxmaxcode = 1 << maxbits; X X if (*filelist != NULL) { X for (fileptr = filelist; *fileptr; fileptr++) { X comprexx(fileptr); X } X } else { /* Standard input */ X if (do_decomp == 0) { X compress(); X if(!quiet) X putc('\n', stderr); X } else { X /* Check the magic number */ X if (nomagic == 0) { X if ((getchar()!=(magic_header[0] & 0xFF)) X || (getchar()!=(magic_header[1] & 0xFF))) { X fprintf(stderr, "stdin: not in compressed format\n"); X exit(1); X } X maxbits = getchar(); /* set -b from file */ X block_compress = maxbits & BLOCK_MASK; X maxbits &= BIT_MASK; X maxmaxcode = 1 << maxbits; X fsize = 100000; /* assume stdin large for USERMEM */ X if(maxbits > BITS) { X fprintf(stderr, X "stdin: compressed with %d bits, can only handle %d bits\n", X maxbits, BITS); X exit(1); X } X } X#ifndef DEBUG X decompress(); X#else DEBUG X if (debug == 0) decompress(); X else printcodes(); X if (verbose) dump_tab(); X#endif DEBUG X } X } X exit(exit_stat); X} Xcomprexx(fileptr) Xchar **fileptr; X{ X struct stat statbuf,insbuf; X char tempname[100]; X if (lstat(*fileptr,&insbuf) == -1) { X perror(*fileptr); X return; X } X switch (insbuf.st_mode & S_IFMT) { X X case S_IFDIR: X if (recursive) X compdir(*fileptr); X break; X X case S_IFREG: X exit_stat = 0; X if (do_decomp != 0) { /* DECOMPRESSION */ X /* Check for .Z suffix */ X if (strcmp(*fileptr + strlen(*fileptr) - 2, ".Z") != 0) { X/* X** I don't believe this is the correct behavior (or at least, I don't X** like it.) - DWM X*/ X#ifdef notdef X /* No .Z: tack one on */ X strcpy(tempname, *fileptr); X strcat(tempname, ".Z"); X *fileptr = tempname; X#endif notdef X return; X } X /* Open input file */ X if ((freopen(*fileptr, "r", stdin)) == NULL) { X perror(*fileptr); return; X } X /* Check the magic number */ X if (nomagic == 0) { X if ((getchar() != (magic_header[0] & 0xFF)) X || (getchar() != (magic_header[1] & 0xFF))) { X fprintf(stderr, "%s: not in compressed format\n", X *fileptr); X return; X } X maxbits = getchar(); /* set -b from file */ X block_compress = maxbits & BLOCK_MASK; X maxbits &= BIT_MASK; X maxmaxcode = 1 << maxbits; X if(maxbits > BITS) { X fprintf(stderr, X "%s: compressed with %d bits, can only handle %d bits\n", X *fileptr, maxbits, BITS); X return; X } X } X /* Generate output filename */ X strcpy(ofname, *fileptr); X /* Check for .Z suffix */ X if (strcmp(*fileptr + strlen(*fileptr) - 2, ".Z") == 0) { X ofname[strlen(*fileptr) - 2] = '\0'; /* Strip off .Z */ X } X } else { /* COMPRESSION */ X if (strcmp(*fileptr + strlen(*fileptr) - 2, ".Z") == 0) { X fprintf(stderr, "%s: already has .Z suffix -- no change\n", X *fileptr); X return; X } X /* Open input file */ X if ((freopen(*fileptr, "r", stdin)) == NULL) { X perror(*fileptr); return; X } X stat ( *fileptr, &statbuf ); X fsize = (long) statbuf.st_size; X /* X * tune hash table size for small files -- ad hoc, X * but the sizes match earlier #defines, which X * serve as upper bounds on the number of output codes. X */ X hsize = HSIZE; X if ( fsize < (1 << 12) ) X hsize = min ( 5003, HSIZE ); X else if ( fsize < (1 << 13) ) X hsize = min ( 9001, HSIZE ); X else if ( fsize < (1 << 14) ) X hsize = min ( 18013, HSIZE ); X else if ( fsize < (1 << 15) ) X hsize = min ( 35023, HSIZE ); X else if ( fsize < 47000 ) X hsize = min ( 50021, HSIZE ); X X /* Generate output filename */ X strcpy(ofname, *fileptr); X#ifndef BSD4_2 /* Short filenames */ X if ((cp=rindex(ofname,'/')) != NULL) cp++; X else cp = ofname; X if (strlen(cp) > 12) { X fprintf(stderr,"%s: filename too long to tack on .Z\n",cp); X return; X } X#endif /* BSD4_2 Long filenames allowed */ X strcat(ofname, ".Z"); X } X /* Check for overwrite of existing file */ X if (overwrite == 0 && zcat_flg == 0) { X if (stat(ofname, &statbuf) == 0) { X char response[2]; X response[0] = 'n'; X fprintf(stderr, "%s already exists;", ofname); X if (foreground()) { X fprintf(stderr, " do you wish to overwrite %s (y or n)? ", X ofname); X fflush(stderr); X read(2, response, 2); X while (response[1] != '\n') { X if (read(2, response+1, 1) < 0) { /* Ack! */ X perror("stderr"); break; X } X } X } X if (response[0] != 'y') { X fprintf(stderr, "\tnot overwritten\n"); X return; X } X } X } X if(zcat_flg == 0) { /* Open output file */ X if (freopen(ofname, "w", stdout) == NULL) { X perror(ofname); X return; X } X if(!quiet) X fprintf(stderr, "%s: ", *fileptr); X } X X /* Actually do the compression/decompression */ X if (do_decomp == 0) compress(); X#ifndef DEBUG X else decompress(); X#else X else if (debug == 0) decompress(); X else printcodes(); X if (verbose) dump_tab(); X#endif /* DEBUG */ X if(zcat_flg == 0) { X copystat(*fileptr, ofname); /* Copy stats */ X if((exit_stat == 1) || (!quiet)) X putc('\n', stderr); X } X default: X break; X } /* end switch */ X return; X} /* end comprexx */ X Xcompdir(dir) Xchar *dir; X{ X DIR *dirp; X register struct direct *dp; X char nbuf[1024]; X char *nptr = nbuf; X dirp = opendir(dir); X if (dirp == NULL) { X printf("%s unreadable\n", dir); /* not stderr! */ X return ; X } X while (dp = readdir(dirp)) { X if (dp->d_ino == 0) X continue; X if (strcmp(dp->d_name,".") == 0 || strcmp(dp->d_name,"..") == 0) X continue; X strcpy(nbuf,dir); X strcat(nbuf,"/"); X strcat(nbuf,dp->d_name); X comprexx(&nptr); X } X closedir(dirp); X return; X} /* end compdir */ X Xstatic int offset; Xlong int in_count = 1; /* length of input */ Xlong int bytes_out; /* length of compressed output */ Xlong int out_count = 0; /* # of codes output (for debugging) */ X X/* X * compress stdin to stdout X * X * Algorithm: use open addressing double hashing (no chaining) on the X * prefix code / next character combination. We do a variant of Knuth's X * algorithm D (vol. 3, sec. 6.4) along with G. Knott's relatively-prime X * secondary probe. Here, the modular division first probe is gives way X * to a faster exclusive-or manipulation. Also do block compression with X * an adaptive reset, whereby the code table is cleared when the compression X * ratio decreases, but after the table fills. The variable-length output X * codes are re-sized at this point, and a special CLEAR code is generated X * for the decompressor. Late addition: construct the table according to X * file size for noticeable speed improvement on small files. Please direct X * questions about this implementation to ames!jaw. X */ X Xcompress() { X register long fcode; X register code_int i = 0; X register int c; X register code_int ent; X#ifdef XENIX_16 X register code_int disp; X#else /* Normal machine */ X register int disp; X#endif X register code_int hsize_reg; X register int hshift; X X#ifndef COMPATIBLE X if (nomagic == 0) { X putchar(magic_header[0]); putchar(magic_header[1]); X putchar((char)(maxbits | block_compress)); X if(ferror(stdout)) X writeerr(); X } X#endif /* COMPATIBLE */ X X offset = 0; X bytes_out = 3; /* includes 3-byte header mojo */ X out_count = 0; X clear_flg = 0; X ratio = 0; X in_count = 1; X checkpoint = CHECK_GAP; X maxcode = MAXCODE(n_bits = INIT_BITS); X free_ent = ((block_compress) ? FIRST : 256 ); X X ent = getchar (); X X hshift = 0; X for ( fcode = (long) hsize; fcode < 65536L; fcode *= 2L ) X hshift++; X hshift = 8 - hshift; /* set hash code range bound */ X X hsize_reg = hsize; X cl_hash( (count_int) hsize_reg); /* clear hash table */ X X#ifdef SIGNED_COMPARE_SLOW X while ( (c = getchar()) != (unsigned) EOF ) { X#else X while ( (c = getchar()) != EOF ) { X#endif X in_count++; X fcode = (long) (((long) c << maxbits) + ent); X i = ((c << hshift) ^ ent); /* xor hashing */ X X if ( htabof (i) == fcode ) { X ent = codetabof (i); X continue; X } else if ( (long)htabof (i) < 0 ) /* empty slot */ X goto nomatch; X disp = hsize_reg - i; /* secondary hash (after G. Knott) */ X if ( i == 0 ) X disp = 1; Xprobe: X if ( (i -= disp) < 0 ) X i += hsize_reg; X X if ( htabof (i) == fcode ) { X ent = codetabof (i); X continue; X } X if ( (long)htabof (i) > 0 ) X goto probe; Xnomatch: X output ( (code_int) ent ); X out_count++; X ent = c; X#ifdef SIGNED_COMPARE_SLOW X if ( (unsigned) free_ent < (unsigned) maxmaxcode) { X#else X if ( free_ent < maxmaxcode ) { X#endif X codetabof (i) = free_ent++; /* code -> hashtable */ X htabof (i) = fcode; X } X else if ( (count_int)in_count >= checkpoint && block_compress ) X cl_block (); X } X /* X * Put out the final code. X */ X output( (code_int)ent ); X out_count++; X output( (code_int)-1 ); X X /* X * Print out stats on stderr X */ X if(zcat_flg == 0 && !quiet) { X#ifdef DEBUG X fprintf( stderr, X "%ld chars in, %ld codes (%ld bytes) out, compression factor: ", X in_count, out_count, bytes_out ); X prratio( stderr, in_count, bytes_out ); X fprintf( stderr, "\n"); X fprintf( stderr, "\tCompression as in compact: " ); X prratio( stderr, in_count-bytes_out, in_count ); X fprintf( stderr, "\n"); X fprintf( stderr, "\tLargest code (of last block) was %d (%d bits)\n", X free_ent - 1, n_bits ); X#else /* !DEBUG */ X fprintf( stderr, "Compression: " ); X prratio( stderr, in_count-bytes_out, in_count ); X#endif /* DEBUG */ X } X if(bytes_out > in_count) /* exit(2) if no savings */ X exit_stat = 2; X return; X} X X/***************************************************************** X * TAG( output ) X * X * Output the given code. X * Inputs: X * code: A n_bits-bit integer. If == -1, then EOF. This assumes X * that n_bits =< (long)wordsize - 1. X * Outputs: X * Outputs code to the file. X * Assumptions: X * Chars are 8 bits long. X * Algorithm: X * Maintain a BITS character long buffer (so that 8 codes will X * fit in it exactly). Use the VAX insv instruction to insert each X * code in turn. When the buffer fills up empty it and start over. X */ X Xstatic char buf[BITS]; X X#ifndef vax Xchar_type lmask[9] = {0xff, 0xfe, 0xfc, 0xf8, 0xf0, 0xe0, 0xc0, 0x80, 0x00}; Xchar_type rmask[9] = {0x00, 0x01, 0x03, 0x07, 0x0f, 0x1f, 0x3f, 0x7f, 0xff}; X#endif /* vax */ X Xoutput( code ) Xcode_int code; X{ X#ifdef DEBUG X static int col = 0; X#endif /* DEBUG */ X X /* X * On the VAX, it is important to have the register declarations X * in exactly the order given, or the asm will break. X */ X register int r_off = offset, bits= n_bits; X register char * bp = buf; X X#ifdef DEBUG X if ( verbose ) X fprintf( stderr, "%5d%c", code, X (col+=6) >= 74 ? (col = 0, '\n') : ' ' ); X#endif /* DEBUG */ X if ( code >= 0 ) { X#ifdef vax X /* VAX DEPENDENT!! Implementation on other machines is below. X * X * Translation: Insert BITS bits from the argument starting at X * offset bits from the beginning of buf. X */ X 0; /* Work around for pcc -O bug with asm and if stmt */ X asm( "insv 4(ap),r11,r10,(r9)" ); X#else /* not a vax */ X/* X * byte/bit numbering on the VAX is simulated by the following code X */ X /* X * Get to the first byte. X */ X bp += (r_off >> 3); X r_off &= 7; X /* X * Since code is always >= 8 bits, only need to mask the first X * hunk on the left. X */ X *bp = (*bp & rmask[r_off]) | (code << r_off) & lmask[r_off]; X bp++; X bits -= (8 - r_off); X code >>= 8 - r_off; X /* Get any 8 bit parts in the middle (<=1 for up to 16 bits). */ X if ( bits >= 8 ) { X *bp++ = code; X code >>= 8; X bits -= 8; X } X /* Last bits. */ X if(bits) X *bp = code; X#endif /* vax */ X offset += n_bits; X if ( offset == (n_bits << 3) ) { X bp = buf; X bits = n_bits; X bytes_out += bits; X do X putchar(*bp++); X while(--bits); X offset = 0; X } X X /* X * If the next entry is going to be too big for the code size, X * then increase it, if possible. X */ X if ( free_ent > maxcode || (clear_flg > 0)) X { X /* X * Write the whole buffer, because the input side won't X * discover the size increase until after it has read it. X */ X if ( offset > 0 ) { X if( fwrite( buf, 1, n_bits, stdout ) != n_bits) X writeerr(); X bytes_out += n_bits; X } X offset = 0; X X if ( clear_flg ) { X maxcode = MAXCODE (n_bits = INIT_BITS); X clear_flg = 0; X } X else { X n_bits++; X if ( n_bits == maxbits ) X maxcode = maxmaxcode; X else X maxcode = MAXCODE(n_bits); X } X#ifdef DEBUG X if ( debug ) { X fprintf( stderr, "\nChange to %d bits\n", n_bits ); X col = 0; X } X#endif /* DEBUG */ X } X } else { X /* X * At EOF, write the rest of the buffer. X */ X if ( offset > 0 ) X fwrite( buf, 1, (offset + 7) / 8, stdout ); X bytes_out += (offset + 7) / 8; X offset = 0; X fflush( stdout ); X#ifdef DEBUG X if ( verbose ) X fprintf( stderr, "\n" ); X#endif /* DEBUG */ X if( ferror( stdout ) ) X writeerr(); X } X} X X/* X * Decompress stdin to stdout. This routine adapts to the codes in the X * file building the "string" table on-the-fly; requiring no table to X * be stored in the compressed file. The tables used herein are shared X * with those of the compress() routine. See the definitions above. X */ X Xdecompress() { X register char_type *stackp; X register int finchar; X register code_int code, oldcode, incode; X X /* X * As above, initialize the first 256 entries in the table. X */ X maxcode = MAXCODE(n_bits = INIT_BITS); X for ( code = 255; code >= 0; code-- ) { X tab_prefixof(code) = 0; X tab_suffixof(code) = (char_type)code; X } X free_ent = ((block_compress) ? FIRST : 256 ); X X finchar = oldcode = getcode(); X if(oldcode == -1) /* EOF already? */ X return; /* Get out of here */ X putchar( (char)finchar ); /* first code must be 8 bits = char */ X if(ferror(stdout)) /* Crash if can't write */ X writeerr(); X stackp = de_stack; X X while ( (code = getcode()) > -1 ) { X X if ( (code == CLEAR) && block_compress ) { X for ( code = 255; code >= 0; code-- ) X tab_prefixof(code) = 0; X clear_flg = 1; X free_ent = FIRST - 1; X if ( (code = getcode ()) == -1 ) /* O, untimely death! */ X break; X } X incode = code; X /* X * Special case for KwKwK string. X */ X if ( code >= free_ent ) { X *stackp++ = finchar; X code = oldcode; X } X X /* X * Generate output characters in reverse order X */ X#ifdef SIGNED_COMPARE_SLOW X while ( ((unsigned long)code) >= ((unsigned long)256) ) { X#else X while ( code >= 256 ) { X#endif X *stackp++ = tab_suffixof(code); X code = tab_prefixof(code); X } X *stackp++ = finchar = tab_suffixof(code); X X /* X * And put them out in forward order X */ X do X putchar ( *--stackp ); X while ( stackp > de_stack ); X X /* X * Generate the new entry. X */ X if ( (code=free_ent) < maxmaxcode ) { X tab_prefixof(code) = (unsigned short)oldcode; X tab_suffixof(code) = finchar; X free_ent = code+1; X } X /* X * Remember previous code. X */ X oldcode = incode; X } X fflush( stdout ); X if(ferror(stdout)) X writeerr(); X} X X/***************************************************************** X * TAG( getcode ) X * X * Read one code from the standard input. If EOF, return -1. X * Inputs: X * stdin X * Outputs: X * code or -1 is returned. X */ X Xcode_int Xgetcode() { X /* X * On the VAX, it is important to have the register declarations X * in exactly the order given, or the asm will break. X */ X register code_int code; X static int offset = 0, size = 0; X static char_type buf[BITS]; X register int r_off, bits; X register char_type *bp = buf; X X if ( clear_flg > 0 || offset >= size || free_ent > maxcode ) { X /* X * If the next entry will be too big for the current code X * size, then we must increase the size. This implies reading X * a new buffer full, too. X */ X if ( free_ent > maxcode ) { X n_bits++; X if ( n_bits == maxbits ) X maxcode = maxmaxcode; /* won't get any bigger now */ X else X maxcode = MAXCODE(n_bits); X } X if ( clear_flg > 0) { X maxcode = MAXCODE (n_bits = INIT_BITS); X clear_flg = 0; X } X size = fread( buf, 1, n_bits, stdin ); X if ( size <= 0 ) X return -1; /* end of file */ X offset = 0; X /* Round size down to integral number of codes */ X size = (size << 3) - (n_bits - 1); X } X r_off = offset; X bits = n_bits; X#ifdef vax X asm( "extzv r10,r9,(r8),r11" ); X#else /* not a vax */ X /* X * Get to the first byte. X */ X bp += (r_off >> 3); X r_off &= 7; X /* Get first part (low order bits) */ X#ifdef NO_UCHAR X code = ((*bp++ >> r_off) & rmask[8 - r_off]) & 0xff; X#else X code = (*bp++ >> r_off); X#endif /* NO_UCHAR */ X bits -= (8 - r_off); X r_off = 8 - r_off; /* now, offset into code word */ X /* Get any 8 bit parts in the middle (<=1 for up to 16 bits). */ X if ( bits >= 8 ) { X#ifdef NO_UCHAR X code |= (*bp++ & 0xff) << r_off; X#else X code |= *bp++ << r_off; X#endif /* NO_UCHAR */ X r_off += 8; X bits -= 8; X } X /* high order bits. */ X code |= (*bp & rmask[bits]) << r_off; X#endif /* vax */ X offset += n_bits; X X return code; X} X Xchar * Xrindex(s, c) /* For those who don't have it in libc.a */ Xregister char *s, c; X{ X char *p; X for (p = NULL; *s; s++) X if (*s == c) X p = s; X return(p); X} X X#ifdef DEBUG Xprintcodes() X{ X /* X * Just print out codes from input file. For debugging. X */ X code_int code; X int col = 0, bits; X X bits = n_bits = INIT_BITS; X maxcode = MAXCODE(n_bits); X free_ent = ((block_compress) ? FIRST : 256 ); X while ( ( code = getcode() ) >= 0 ) { X if ( (code == CLEAR) && block_compress ) { X free_ent = FIRST - 1; X clear_flg = 1; X } X else if ( free_ent < maxmaxcode ) X free_ent++; X if ( bits != n_bits ) { X fprintf(stderr, "\nChange to %d bits\n", n_bits ); X bits = n_bits; X col = 0; X } X fprintf(stderr, "%5d%c", code, (col+=6) >= 74 ? (col = 0, '\n') : ' ' ); X } X putc( '\n', stderr ); X exit( 0 ); X} X Xcode_int sorttab[1<= 0) { X sorttab[codetabof(i)] = i; X } X } X first = block_compress ? FIRST : 256; X for(i = first; i < free_ent; i++) { X fprintf(stderr, "%5d: \"", i); X de_stack[--stack_top] = '\n'; X de_stack[--stack_top] = '"'; X stack_top = in_stack((htabof(sorttab[i])>>maxbits)&0xff, X stack_top); X for(ent=htabof(sorttab[i]) & ((1< 256; X ent=htabof(sorttab[ent]) & ((1<> maxbits, X stack_top); X } X stack_top = in_stack(ent, stack_top); X fwrite( &de_stack[stack_top], 1, STACK_SIZE-stack_top, stderr); X stack_top = STACK_SIZE; X } X } else if(!debug) { /* decompressing */ X X for ( i = 0; i < free_ent; i++ ) { X ent = i; X c = tab_suffixof(ent); X if ( isascii(c) && isprint(c) ) X fprintf( stderr, "%5d: %5d/'%c' \"", X ent, tab_prefixof(ent), c ); X else X fprintf( stderr, "%5d: %5d/\\%03o \"", X ent, tab_prefixof(ent), c ); X de_stack[--stack_top] = '\n'; X de_stack[--stack_top] = '"'; X for ( ; ent != NULL; X ent = (ent >= FIRST ? tab_prefixof(ent) : NULL) ) { X stack_top = in_stack(tab_suffixof(ent), stack_top); X } X fwrite( &de_stack[stack_top], 1, STACK_SIZE - stack_top, stderr ); X stack_top = STACK_SIZE; X } X } X} X Xint Xin_stack(c, stack_top) X register c, stack_top; X{ X if ( (isascii(c) && isprint(c) && c != '\\') || c == ' ' ) { X de_stack[--stack_top] = c; X } else { X switch( c ) { X case '\n': de_stack[--stack_top] = 'n'; break; X case '\t': de_stack[--stack_top] = 't'; break; X case '\b': de_stack[--stack_top] = 'b'; break; X case '\f': de_stack[--stack_top] = 'f'; break; X case '\r': de_stack[--stack_top] = 'r'; break; X case '\\': de_stack[--stack_top] = '\\'; break; X default: X de_stack[--stack_top] = '0' + c % 8; X de_stack[--stack_top] = '0' + (c / 8) % 8; X de_stack[--stack_top] = '0' + c / 64; X break; X } X de_stack[--stack_top] = '\\'; X } X return stack_top; X} X#endif /* DEBUG */ X Xwriteerr() X{ X perror ( ofname ); X unlink ( ofname ); X exit ( 1 ); X} X Xcopystat(ifname, ofname) Xchar *ifname, *ofname; X{ X struct stat statbuf; X int mode; X time_t timep[2]; X X fclose(stdout); X if (stat(ifname, &statbuf)) { /* Get stat on input file */ X perror(ifname); X return; X } X if ((statbuf.st_mode & S_IFMT/*0170000*/) != S_IFREG/*0100000*/) { X if(quiet) X fprintf(stderr, "%s: ", ifname); X fprintf(stderr, " -- not a regular file: unchanged"); X exit_stat = 1; X } else if (statbuf.st_nlink > 1) { X if(quiet) X fprintf(stderr, "%s: ", ifname); X fprintf(stderr, " -- has %d other links: unchanged", X statbuf.st_nlink - 1); X exit_stat = 1; X } else if (exit_stat == 2 && (!force)) { /* No compression: remove file.Z */ X if(!quiet) X fprintf(stderr, " -- file unchanged"); X } else { /* ***** Successful Compression ***** */ X exit_stat = 0; X mode = statbuf.st_mode & 07777; X if (chmod(ofname, mode)) /* Copy modes */ X perror(ofname); X chown(ofname, statbuf.st_uid, statbuf.st_gid); /* Copy ownership */ X timep[0] = statbuf.st_atime; X timep[1] = statbuf.st_mtime; X utime(ofname, timep); /* Update last accessed and modified times */ X if (unlink(ifname)) /* Remove input file */ X perror(ifname); X if(!quiet) X fprintf(stderr, " -- replaced with %s", ofname); X return; /* Successful return */ X } X X /* Unsuccessful return -- one of the tests failed */ X if (unlink(ofname)) X perror(ofname); X} X/* X * This routine returns 1 if we are running in the foreground and stderr X * is a tty. X */ Xforeground() X{ X if(bgnd_flag) { /* background? */ X return(0); X } else { /* foreground */ X if(isatty(2)) { /* and stderr is a tty */ X return(1); X } else { X return(0); X } X } X} X Xonintr ( ) X{ X unlink ( ofname ); X exit ( 1 ); X} X Xoops ( ) /* wild pointer -- assume bad input */ X{ X if ( do_decomp == 1 ) X fprintf ( stderr, "uncompress: corrupt input\n" ); X unlink ( ofname ); X exit ( 1 ); X} X Xcl_block () /* table clear for block compress */ X{ X register long int rat; X X checkpoint = in_count + CHECK_GAP; X#ifdef DEBUG X if ( debug ) { X fprintf ( stderr, "count: %ld, ratio: ", in_count ); X prratio ( stderr, in_count, bytes_out ); X fprintf ( stderr, "\n"); X } X#endif /* DEBUG */ X X if(in_count > 0x007fffff) { /* shift will overflow */ X rat = bytes_out >> 8; X if(rat == 0) { /* Don't divide by zero */ X rat = 0x7fffffff; X } else { X rat = in_count / rat; X } X } else { X rat = (in_count << 8) / bytes_out; /* 8 fractional bits */ X } X if ( rat > ratio ) { X ratio = rat; X } else { X ratio = 0; X#ifdef DEBUG X if(verbose) X dump_tab(); /* dump string table */ X#endif X cl_hash ( (count_int) hsize ); X free_ent = FIRST; X clear_flg = 1; X output ( (code_int) CLEAR ); X#ifdef DEBUG X if(debug) X fprintf ( stderr, "clear\n" ); X#endif /* DEBUG */ X } X} X Xcl_hash(hsize) /* reset code table */ X register count_int hsize; X{ X#ifndef XENIX_16 /* Normal machine */ X register count_int *htab_p = htab+hsize; X#else X register j; X register long k = hsize; X register count_int *htab_p; X#endif X register long i; X register long m1 = -1; X X#ifdef XENIX_16 X for(j=0; j<=8 && k>=0; j++,k-=8192) { X i = 8192; X if(k < 8192) { X i = k; X } X htab_p = &(htab[j][i]); X i -= 16; X if(i > 0) { X#else X i = hsize - 16; X#endif X do { /* might use Sys V memset(3) here */ X *(htab_p-16) = m1; X *(htab_p-15) = m1; X *(htab_p-14) = m1; X *(htab_p-13) = m1; X *(htab_p-12) = m1; X *(htab_p-11) = m1; X *(htab_p-10) = m1; X *(htab_p-9) = m1; X *(htab_p-8) = m1; X *(htab_p-7) = m1; X *(htab_p-6) = m1; X *(htab_p-5) = m1; X *(htab_p-4) = m1; X *(htab_p-3) = m1; X *(htab_p-2) = m1; X *(htab_p-1) = m1; X htab_p -= 16; X } while ((i -= 16) >= 0); X#ifdef XENIX_16 X } X } X#endif X for ( i += 16; i > 0; i-- ) X *--htab_p = m1; X} X Xprratio(stream, num, den) XFILE *stream; Xlong int num, den; X{ X register int q; /* Doesn't need to be long */ X X if(num > 214748L) { /* 2147483647/10000 */ X q = num / (den / 10000L); X } else { X q = 10000L * num / den; /* Long calculations, though */ X } X if (q < 0) { X putc('-', stream); X q = -q; X } X fprintf(stream, "%d.%02d%%", q / 100, q % 100); X} X Xversion() X{ X fprintf(stderr, "%s\n", rcs_ident); X fprintf(stderr, "Options: "); X#ifdef vax X fprintf(stderr, "vax, "); X#endif X#ifdef NO_UCHAR X fprintf(stderr, "NO_UCHAR, "); X#endif X#ifdef SIGNED_COMPARE_SLOW X fprintf(stderr, "SIGNED_COMPARE_SLOW, "); X#endif X#ifdef XENIX_16 X fprintf(stderr, "XENIX_16, "); X#endif X#ifdef COMPATIBLE X fprintf(stderr, "COMPATIBLE, "); X#endif X#ifdef DEBUG X fprintf(stderr, "DEBUG, "); X#endif X#ifdef BSD4_2 X fprintf(stderr, "BSD4_2, "); X#endif X fprintf(stderr, "BITS = %d\n", BITS); X} END_OF_FILE if test 41053 -ne `wc -c <'compress.c'`; then echo shar: \"'compress.c'\" unpacked with wrong size! fi # end of 'compress.c' fi if test -f 'compress.1' -a "${1}" != "-c" ; then echo shar: Will not clobber existing file \"'compress.1'\" else echo shar: Extracting \"'compress.1'\" \(5394 characters\) sed "s/^X//" >'compress.1' <<'END_OF_FILE' X.PU X.TH COMPRESS 1 local X.SH NAME Xcompress, uncompress, zcat \- compress and expand data X.SH SYNOPSIS X.ll +8 X.B compress X[ X.B \-f X] [ X.B \-v X] [ X.B \-c X] [ X.B \-V X] [ X.B \-r X] [ X.B \-b X.I bits X] [ X.I "name \&..." X] X.ll -8 X.br X.B uncompress X[ X.B \-f X] [ X.B \-v X] [ X.B \-c X] [ X.B \-V X] [ X.I "name \&..." X] X.br X.B zcat X[ X.B \-V X] [ X.I "name \&..." X] X.SH DESCRIPTION X.I Compress Xreduces the size of the named files using adaptive Lempel-Ziv coding. XWhenever possible, Xeach file is replaced by one with the extension X.B "\&.Z," Xwhile keeping the same ownership modes, access and modification times. XIf no files are specified, the standard input is compressed to the Xstandard output. XCompressed files can be restored to their original form using X.I uncompress Xor X.I zcat. X.PP XThe X.B \-f Xoption will force compression of X.I name. XThis is useful for compressing an entire directory, Xeven if some of the files do not actually shrink. XIf X.B \-f Xis not given and X.I compress Xis run in the foreground, Xthe user is prompted as to whether an existing file should be overwritten. X.PP XThe X.B \-c Xoption makes X.I compress/uncompress Xwrite to the standard output; no files are changed. XThe nondestructive behavior of X.I zcat Xis identical to that of X.I uncompress X.B \-c. X.PP XIf the X.B \-r Xflag is specified, X.I compress Xwill operate recursively. If any of the file names specified on the command Xline are directories, X.I compress Xwill descend into the directory and compress all the files it finds there. X.PP X.I Compress Xuses the modified Lempel-Ziv algorithm popularized in X"A Technique for High Performance Data Compression", XTerry A. Welch, X.I "IEEE Computer," Xvol. 17, no. 6 (June 1984), pp. 8-19. XCommon substrings in the file are first replaced by 9-bit codes 257 and up. XWhen code 512 is reached, the algorithm switches to 10-bit codes and Xcontinues to use more bits until the Xlimit specified by the X.B \-b Xflag is reached (default 16). X.I Bits Xmust be between 9 and 16. The default can be changed in the source to allow X.I compress Xto be run on a smaller machine. X.PP XAfter the X.I bits Xlimit is attained, X.I compress Xperiodically checks the compression ratio. If it is increasing, X.I compress Xcontinues to use the existing code dictionary. However, Xif the compression ratio decreases, X.I compress Xdiscards the table of substrings and rebuilds it from scratch. This allows Xthe algorithm to adapt to the next "block" of the file. X.PP XNote that the X.B \-b Xflag is omitted for X.I uncompress, Xsince the X.I bits Xparameter specified during compression Xis encoded within the output, along with Xa magic number to ensure that neither decompression of random data nor Xrecompression of compressed data is attempted. X.PP X.ne 8 XThe amount of compression obtained depends on the size of the Xinput, the number of X.I bits Xper code, and the distribution of common substrings. XTypically, text such as source code or English Xis reduced by 50\-60%. XCompression is generally much better than that achieved by XHuffman coding (as used in X.IR pack ), Xor adaptive Huffman coding X.RI ( compact ), Xand takes less time to compute. X.PP XUnder the X.B \-v Xoption, Xa message is printed yielding the percentage of Xreduction for each file compressed. X.PP XIf the X.B \-V Xoption is specified, the current version and compile options are printed on Xstderr. X.PP XExit status is normally 0; Xif the last file is larger after (attempted) compression, the status is 2; Xif an error occurs, exit status is 1. X.SH "SEE ALSO" Xpack(1), compact(1) X.SH "DIAGNOSTICS" XUsage: compress [\-dfvcV] [\-b maxbits] [file ...] X.in +8 XInvalid options were specified on the command line. X.in -8 XMissing maxbits X.in +8 XMaxbits must follow X.BR \-b \. X.in -8 X.IR file : Xnot in compressed format X.in +8 XThe file specified to X.I uncompress Xhas not been compressed. X.in -8 X.IR file : Xcompressed with X.I xx Xbits, can only handle X.I yy Xbits X.in +8 X.I File Xwas compressed by a program that could deal with Xmore X.I bits Xthan the compress code on this machine. XRecompress the file with smaller X.IR bits \. X.in -8 X.IR file : Xalready has .Z suffix -- no change X.in +8 XThe file is assumed to be already compressed. XRename the file and try again. X.in -8 X.IR file : Xfilename too long to tack on .Z X.in +8 XThe file cannot be compressed because its name is longer than X12 characters. XRename and try again. XThis message does not occur on BSD systems. X.in -8 X.I file Xalready exists; do you wish to overwrite (y or n)? X.in +8 XRespond "y" if you want the output file to be replaced; "n" if not. X.in -8 Xuncompress: corrupt input X.in +8 XA SIGSEGV violation was detected which usually means that the input file has Xbeen corrupted. X.in -8 XCompression: X.I "xx.xx%" X.in +8 XPercentage of the input saved by compression. X(Relevant only for X.BR \-v \.) X.in -8 X-- not a regular file: unchanged X.in +8 XWhen the input file is not a regular file, X(e.g. a directory), it is Xleft unaltered. X.in -8 X-- has X.I xx Xother links: unchanged X.in +8 XThe input file has links; it is left unchanged. See X.IR ln "(1)" Xfor more information. X.in -8 X-- file unchanged X.in +8 XNo savings is achieved by Xcompression. The input remains virgin. X.in -8 X.SH "BUGS" XAlthough compressed files are compatible between machines with large memory, X.BR \-b \12 Xshould be used for file transfer to architectures with Xa small process data space (64KB or less, as exhibited by the DEC PDP Xseries, the Intel 80286, etc.) END_OF_FILE if test 5394 -ne `wc -c <'compress.1'`; then echo shar: \"'compress.1'\" unpacked with wrong size! fi # end of 'compress.1' fi echo shar: End of shell archive. exit 0