4.4BSD/usr/src/contrib/gdb-4.7.lbl/readline/doc/texindex.c
/* Prepare Tex index dribble output into an actual index.
Copyright (C) 1987 Free Software Foundation, Inc.
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 1, 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., 675 Mass Ave, Cambridge, MA 02139, USA. */
#include <stdio.h>
#include <ctype.h>
#include <errno.h>
extern int errno;
#ifdef VMS
#ifndef VAX11C
#define noshare
#endif
#include <perror.h>
#include <file.h>
#define EXIT_SUCCESS ((1 << 28) | 1)
#define EXIT_FATAL ((1 << 28) | 4)
#define unlink delete
#define tell(fd) lseek(fd, 0L, 1)
#else /* Not VMS */
#ifdef USG
#include <sys/types.h>
#include <sys/fcntl.h>
#endif
#include <sys/file.h>
#define EXIT_SUCCESS 0
#define EXIT_FATAL 1
#endif /* Not VMS */
#ifndef L_XTND
#define L_XTND 2
#endif
#ifdef VMS
extern noshare int sys_nerr;
extern noshare char *sys_errlist[];
#else
extern int sys_nerr;
extern char *sys_errlist[];
#endif
/* When sorting in core, this structure describes one line
and the position and length of its first keyfield. */
struct lineinfo
{
char *text; /* The actual text of the line */
union
{ /* The start of the key (for textual comparison) */
char *text;
long number; /* or the numeric value (for numeric comparison) */
} key;
long keylen; /* Length of key field */
};
/* This structure describes a field to use as a sort key */
struct keyfield
{
int startwords; /* # words to skip */
int startchars; /* and # additional chars to skip, to start of field */
int endwords; /* similar, from beg (or end) of line, to find end of field */
int endchars;
char ignore_blanks; /* Ignore spaces and tabs within the field */
char fold_case; /* Convert upper case to lower before comparing */
char reverse; /* Compare in reverse order */
char numeric; /* Parse text as an integer and compare the integers */
char positional; /* Sort according to position within the file */
char braced; /* Count balanced-braced groupings as fields */
};
/* Vector of keyfields to use */
struct keyfield keyfields[3];
/* Number of keyfields stored in that vector. */
int num_keyfields = 3;
/* Vector of input file names, terminated with a zero (null pointer) */
char **infiles;
/* Vector of corresponding output file names, or zero meaning default it */
char **outfiles;
/* Length of `infiles' */
int num_infiles;
/* Pointer to the array of pointers to lines being sorted */
char **linearray;
/* The allocated length of `linearray'. */
long nlines;
/* Directory to use for temporary files. On Unix, it ends with a slash. */
char *tempdir;
/* Start of filename to use for temporary files. */
char *tempbase;
/* Number of last temporary file. */
int tempcount;
/* Number of last temporary file already deleted.
Temporary files are deleted by `flush_tempfiles' in order of creation. */
int last_deleted_tempcount;
/* During in-core sort, this points to the base of the data block
which contains all the lines of data. */
char *text_base;
/* Additional command switches */
int keep_tempfiles; /* Nonzero means do not delete tempfiles -- for debugging */
/* Forward declarations of functions in this file */
void decode_command ();
void sort_in_core ();
void sort_offline ();
char **parsefile ();
char *find_field ();
char *find_pos ();
long find_value ();
char *find_braced_pos ();
char *find_braced_end ();
void writelines ();
int compare_full ();
long readline ();
int merge_files ();
int merge_direct ();
char *concat ();
char *maketempname ();
void flush_tempfiles ();
char *tempcopy ();
extern char *mktemp ();
�
#define MAX_IN_CORE_SORT 500000
int
main (argc, argv)
int argc;
char **argv;
{
int i;
tempcount = 0;
last_deleted_tempcount = 0;
/* Describe the kind of sorting to do. */
/* The first keyfield uses the first braced field and folds case */
keyfields[0].braced = 1;
keyfields[0].fold_case = 1;
keyfields[0].endwords = -1;
keyfields[0].endchars = -1;
/* The second keyfield uses the second braced field, numerically */
keyfields[1].braced = 1;
keyfields[1].numeric = 1;
keyfields[1].startwords = 1;
keyfields[1].endwords = -1;
keyfields[1].endchars = -1;
/* The third keyfield (which is ignored while discarding duplicates)
compares the whole line */
keyfields[2].endwords = -1;
keyfields[2].endchars = -1;
decode_command (argc, argv);
tempbase = mktemp (concat ("txiXXXXXX", "", ""));
/* Process input files completely, one by one. */
for (i = 0; i < num_infiles; i++)
{
int desc;
long ptr;
char *outfile;
char *p;
desc = open (infiles[i], 0, 0);
if (desc < 0) pfatal_with_name (infiles[i]);
lseek (desc, 0, L_XTND);
ptr = tell (desc);
close (desc);
outfile = outfiles[i];
if (!outfile)
{
outfile = concat (infiles[i], "s", "");
}
if (ptr < MAX_IN_CORE_SORT)
/* Sort a small amount of data */
sort_in_core (infiles[i], ptr, outfile);
else
sort_offline (infiles[i], ptr, outfile);
}
flush_tempfiles (tempcount);
exit (EXIT_SUCCESS);
}
�
/* This page decodes the command line arguments to set the parameter variables
and set up the vector of keyfields and the vector of input files */
void
decode_command (argc, argv)
int argc;
char **argv;
{
int i;
char **ip;
char **op;
/* Store default values into parameter variables */
#ifdef VMS
tempdir = "sys$scratch:";
#else
tempdir = "/tmp/";
#endif
keep_tempfiles = 0;
/* Allocate argc input files, which must be enough. */
infiles = (char **) xmalloc (argc * sizeof (char *));
outfiles = (char **) xmalloc (argc * sizeof (char *));
ip = infiles;
op = outfiles;
/* First find all switches that control the default kind-of-sort */
for (i = 1; i < argc; i++)
{
int tem = classify_arg (argv[i]);
char c;
char *p;
if (tem <= 0)
{
*ip++ = argv[i];
*op++ = 0;
continue;
}
if (tem > 1)
{
if (i + 1 == argc)
fatal ("switch %s given with no argument following it", argv[i]);
else if (!strcmp (argv[i], "-T"))
tempdir = argv[i + 1];
else if (!strcmp (argv[i], "-o"))
*(op - 1) = argv[i + 1];
i += tem - 1;
continue;
}
p = &argv[i][1];
while (c = *p++)
switch (c)
{
case 'k':
keep_tempfiles = 1;
break;
default:
fatal ("invalid command switch %c", c);
}
switchdone: ;
}
/* Record number of keyfields, terminate list of filenames */
num_infiles = ip - infiles;
*ip = 0;
}
/* Return 0 for an argument that is not a switch;
for a switch, return 1 plus the number of following arguments that the switch swallows.
*/
int
classify_arg (arg)
char *arg;
{
if (!strcmp (arg, "-T") || !strcmp (arg, "-o"))
return 2;
if (arg[0] == '-')
return 1;
return 0;
}
�
/* Create a name for a temporary file */
char *
maketempname (count)
int count;
{
char tempsuffix[10];
sprintf (tempsuffix, "%d", count);
return concat (tempdir, tempbase, tempsuffix);
}
/* Delete all temporary files up to the specified count */
void
flush_tempfiles (to_count)
int to_count;
{
if (keep_tempfiles) return;
while (last_deleted_tempcount < to_count)
unlink (maketempname (++last_deleted_tempcount));
}
/* Copy an input file into a temporary file, and return the temporary file name */
#define BUFSIZE 1024
char *
tempcopy (idesc)
int idesc;
{
char *outfile = maketempname (++tempcount);
int odesc;
char buffer[BUFSIZE];
odesc = open (outfile, O_WRONLY | O_CREAT, 0666);
if (odesc < 0) pfatal_with_name (outfile);
while (1)
{
int nread = read (idesc, buffer, BUFSIZE);
write (odesc, buffer, nread);
if (!nread) break;
}
close (odesc);
return outfile;
}
�
/* Compare two lines, provided as pointers to pointers to text,
according to the specified set of keyfields */
int
compare_full (line1, line2)
char **line1, **line2;
{
int i;
/* Compare using the first keyfield;
if that does not distinguish the lines, try the second keyfield; and so on. */
for (i = 0; i < num_keyfields; i++)
{
long length1, length2;
char *start1 = find_field (&keyfields[i], *line1, &length1);
char *start2 = find_field (&keyfields[i], *line2, &length2);
int tem = compare_field (&keyfields[i], start1, length1, *line1 - text_base,
start2, length2, *line2 - text_base);
if (tem)
{
if (keyfields[i].reverse)
return - tem;
return tem;
}
}
return 0; /* Lines match exactly */
}
/* Compare two lines described by structures
in which the first keyfield is identified in advance.
For positional sorting, assumes that the order of the lines in core
reflects their nominal order. */
int
compare_prepared (line1, line2)
struct lineinfo *line1, *line2;
{
int i;
int tem;
char *text1, *text2;
/* Compare using the first keyfield, which has been found for us already */
if (keyfields->positional)
{
if (line1->text - text_base > line2->text - text_base)
tem = 1;
else
tem = -1;
}
else if (keyfields->numeric)
tem = line1->key.number - line2->key.number;
else
tem = compare_field (keyfields, line1->key.text, line1->keylen, 0, line2->key.text, line2->keylen, 0);
if (tem)
{
if (keyfields->reverse)
return - tem;
return tem;
}
text1 = line1->text;
text2 = line2->text;
/* Compare using the second keyfield;
if that does not distinguish the lines, try the third keyfield; and so on. */
for (i = 1; i < num_keyfields; i++)
{
long length1, length2;
char *start1 = find_field (&keyfields[i], text1, &length1);
char *start2 = find_field (&keyfields[i], text2, &length2);
int tem = compare_field (&keyfields[i], start1, length1, text1 - text_base,
start2, length2, text2 - text_base);
if (tem)
{
if (keyfields[i].reverse)
return - tem;
return tem;
}
}
return 0; /* Lines match exactly */
}
/* Like compare_full but more general.
You can pass any strings, and you can say how many keyfields to use.
`pos1' and `pos2' should indicate the nominal positional ordering of
the two lines in the input. */
int
compare_general (str1, str2, pos1, pos2, use_keyfields)
char *str1, *str2;
long pos1, pos2;
int use_keyfields;
{
int i;
/* Compare using the first keyfield;
if that does not distinguish the lines, try the second keyfield; and so on. */
for (i = 0; i < use_keyfields; i++)
{
long length1, length2;
char *start1 = find_field (&keyfields[i], str1, &length1);
char *start2 = find_field (&keyfields[i], str2, &length2);
int tem = compare_field (&keyfields[i], start1, length1, pos1, start2, length2, pos2);
if (tem)
{
if (keyfields[i].reverse)
return - tem;
return tem;
}
}
return 0; /* Lines match exactly */
}
/* Find the start and length of a field in `str' according to `keyfield'.
A pointer to the starting character is returned, and the length
is stored into the int that `lengthptr' points to. */
char *
find_field (keyfield, str, lengthptr)
struct keyfield *keyfield;
char *str;
long *lengthptr;
{
char *start;
char *end;
char *(*fun) ();
if (keyfield->braced) fun = find_braced_pos;
else fun = find_pos;
start = ( *fun )(str, keyfield->startwords, keyfield->startchars,
keyfield->ignore_blanks);
if (keyfield->endwords < 0)
{
if (keyfield->braced)
end = find_braced_end (start);
else
{
end = start;
while (*end && *end != '\n') end++;
}
}
else
{
end = ( *fun )(str, keyfield->endwords, keyfield->endchars, 0);
if (end - str < start - str) end = start;
}
*lengthptr = end - start;
return start;
}
/* Find a pointer to a specified place within `str',
skipping (from the beginning) `words' words and then `chars' chars.
If `ignore_blanks' is nonzero, we skip all blanks
after finding the specified word. */
char *
find_pos (str, words, chars, ignore_blanks)
char *str;
int words, chars;
int ignore_blanks;
{
int i;
char *p = str;
for (i = 0; i < words; i++)
{
char c;
/* Find next bunch of nonblanks and skip them. */
while ((c = *p) == ' ' || c == '\t') p++;
while ((c = *p) && c != '\n' && !(c == ' ' || c == '\t')) p++;
if (!*p || *p == '\n') return p;
}
while (*p == ' ' || *p == '\t') p++;
for (i = 0; i < chars; i++)
{
if (!*p || *p == '\n') break;
p++;
}
return p;
}
/* Like find_pos but assumes that each field is surrounded by braces
and that braces within fields are balanced. */
char *
find_braced_pos (str, words, chars, ignore_blanks)
char *str;
int words, chars;
int ignore_blanks;
{
int i;
int bracelevel;
char *p = str;
char c;
for (i = 0; i < words; i++)
{
bracelevel = 1;
while ((c = *p++) != '{' && c != '\n' && c);
if (c != '{')
return p - 1;
while (bracelevel)
{
c = *p++;
if (c == '{') bracelevel++;
if (c == '}') bracelevel--;
#if 0
if (c == '\\' || c == '@') c = *p++; /* \ quotes braces and \ */
#endif
if (c == 0 || c == '\n') return p-1;
}
}
while ((c = *p++) != '{' && c != '\n' && c);
if (c != '{')
return p-1;
if (ignore_blanks)
while ((c = *p) == ' ' || c == '\t') p++;
for (i = 0; i < chars; i++)
{
if (!*p || *p == '\n') break;
p++;
}
return p;
}
/* Find the end of the balanced-brace field which starts at `str'.
The position returned is just before the closing brace. */
char *
find_braced_end (str)
char *str;
{
int bracelevel;
char *p = str;
char c;
bracelevel = 1;
while (bracelevel)
{
c = *p++;
if (c == '{') bracelevel++;
if (c == '}') bracelevel--;
#if 0
if (c == '\\' || c == '@') c = *p++;
#endif
if (c == 0 || c == '\n') return p-1;
}
return p - 1;
}
long
find_value (start, length)
char *start;
long length;
{
while (length != 0L) {
if (isdigit(*start))
return atol(start);
length--;
start++;
}
return 0l;
}
/* Vector used to translate characters for comparison.
This is how we make all alphanumerics follow all else,
and ignore case in the first sorting. */
int char_order[256];
init_char_order ()
{
int i;
for (i = 1; i < 256; i++)
char_order[i] = i;
for (i = '0'; i <= '9'; i++)
char_order[i] += 512;
for (i = 'a'; i <= 'z'; i++) {
char_order[i] = 512 + i;
char_order[i + 'A' - 'a'] = 512 + i;
}
}
/* Compare two fields (each specified as a start pointer and a character count)
according to `keyfield'. The sign of the value reports the relation between the fields */
int
compare_field (keyfield, start1, length1, pos1, start2, length2, pos2)
struct keyfield *keyfield;
char *start1;
long length1;
long pos1;
char *start2;
long length2;
long pos2;
{
if (keyfields->positional)
{
if (pos1 > pos2)
return 1;
else
return -1;
}
if (keyfield->numeric)
{
long value = find_value (start1, length1) - find_value (start2, length2);
if (value > 0) return 1;
if (value < 0) return -1;
return 0;
}
else
{
char *p1 = start1;
char *p2 = start2;
char *e1 = start1 + length1;
char *e2 = start2 + length2;
int fold_case = keyfield->fold_case;
while (1)
{
int c1, c2;
if (p1 == e1) c1 = 0;
else c1 = *p1++;
if (p2 == e2) c2 = 0;
else c2 = *p2++;
if (char_order[c1] != char_order[c2])
return char_order[c1] - char_order[c2];
if (!c1) break;
}
/* Strings are equal except possibly for case. */
p1 = start1;
p2 = start2;
while (1)
{
int c1, c2;
if (p1 == e1) c1 = 0;
else c1 = *p1++;
if (p2 == e2) c2 = 0;
else c2 = *p2++;
if (c1 != c2)
/* Reverse sign here so upper case comes out last. */
return c2 - c1;
if (!c1) break;
}
return 0;
}
}
�
/* A `struct linebuffer' is a structure which holds a line of text.
`readline' reads a line from a stream into a linebuffer
and works regardless of the length of the line. */
struct linebuffer
{
long size;
char *buffer;
};
/* Initialize a linebuffer for use */
void
initbuffer (linebuffer)
struct linebuffer *linebuffer;
{
linebuffer->size = 200;
linebuffer->buffer = (char *) xmalloc (200);
}
/* Read a line of text from `stream' into `linebuffer'.
Return the length of the line. */
long
readline (linebuffer, stream)
struct linebuffer *linebuffer;
FILE *stream;
{
char *buffer = linebuffer->buffer;
char *p = linebuffer->buffer;
char *end = p + linebuffer->size;
while (1)
{
int c = getc (stream);
if (p == end)
{
buffer = (char *) xrealloc (buffer, linebuffer->size *= 2);
p += buffer - linebuffer->buffer;
end += buffer - linebuffer->buffer;
linebuffer->buffer = buffer;
}
if (c < 0 || c == '\n')
{
*p = 0;
break;
}
*p++ = c;
}
return p - buffer;
}
�
/* Sort an input file too big to sort in core. */
void
sort_offline (infile, nfiles, total, outfile)
char *infile;
long total;
char *outfile;
{
int ntemps = 2 * (total + MAX_IN_CORE_SORT - 1) / MAX_IN_CORE_SORT; /* More than enough */
char **tempfiles = (char **) xmalloc (ntemps * sizeof (char *));
FILE *istream = fopen (infile, "r");
int i;
struct linebuffer lb;
long linelength;
int failure = 0;
initbuffer (&lb);
/* Read in one line of input data. */
linelength = readline (&lb, istream);
if (lb.buffer[0] != '\\' && lb.buffer[0] != '@')
{
error ("%s: not a texinfo index file", infile);
return;
}
/* Split up the input into `ntemps' temporary files, or maybe fewer,
and put the new files' names into `tempfiles' */
for (i = 0; i < ntemps; i++)
{
char *outname = maketempname (++tempcount);
FILE *ostream = fopen (outname, "w");
long tempsize = 0;
if (!ostream) pfatal_with_name (outname);
tempfiles[i] = outname;
/* Copy lines into this temp file as long as it does not make file "too big"
or until there are no more lines. */
while (tempsize + linelength + 1 <= MAX_IN_CORE_SORT)
{
tempsize += linelength + 1;
fputs (lb.buffer, ostream);
putc ('\n', ostream);
/* Read another line of input data. */
linelength = readline (&lb, istream);
if (!linelength && feof (istream)) break;
if (lb.buffer[0] != '\\' && lb.buffer[0] != '@')
{
error ("%s: not a texinfo index file", infile);
failure = 1;
goto fail;
}
}
fclose (ostream);
if (feof (istream)) break;
}
free (lb.buffer);
fail:
/* Record number of temp files we actually needed. */
ntemps = i;
/* Sort each tempfile into another tempfile.
Delete the first set of tempfiles and put the names of the second into `tempfiles' */
for (i = 0; i < ntemps; i++)
{
char *newtemp = maketempname (++tempcount);
sort_in_core (&tempfiles[i], MAX_IN_CORE_SORT, newtemp);
if (!keep_tempfiles)
unlink (tempfiles[i]);
tempfiles[i] = newtemp;
}
if (failure)
return;
/* Merge the tempfiles together and indexify */
merge_files (tempfiles, ntemps, outfile);
}
�
/* Sort `infile', whose size is `total',
assuming that is small enough to be done in-core,
then indexify it and send the output to `outfile' (or to stdout). */
void
sort_in_core (infile, total, outfile)
char *infile;
long total;
char *outfile;
{
char **nextline;
char *data = (char *) xmalloc (total + 1);
char *file_data;
long file_size;
int i;
FILE *ostream = stdout;
struct lineinfo *lineinfo;
/* Read the contents of the file into the moby array `data' */
int desc = open (infile, 0, 0);
if (desc < 0)
fatal ("failure reopening %s", infile);
for (file_size = 0; ; )
{
if ((i = read (desc, data + file_size, total - file_size)) <= 0)
break;
file_size += i;
}
file_data = data;
data[file_size] = 0;
close (desc);
if (file_size > 0 && data[0] != '\\' && data[0] != '@')
{
error ("%s: not a texinfo index file", infile);
return;
}
init_char_order ();
/* Sort routines want to know this address */
text_base = data;
/* Create the array of pointers to lines, with a default size frequently enough. */
nlines = total / 50;
if (!nlines) nlines = 2;
linearray = (char **) xmalloc (nlines * sizeof (char *));
/* `nextline' points to the next free slot in this array.
`nlines' is the allocated size. */
nextline = linearray;
/* Parse the input file's data, and make entries for the lines. */
nextline = parsefile (infile, nextline, file_data, file_size);
if (nextline == 0)
{
error ("%s: not a texinfo index file", infile);
return;
}
/* Sort the lines */
/* If we have enough space, find the first keyfield of each line in advance.
Make a `struct lineinfo' for each line, which records the keyfield
as well as the line, and sort them. */
lineinfo = (struct lineinfo *) malloc ((nextline - linearray) * sizeof (struct lineinfo));
if (lineinfo)
{
struct lineinfo *lp;
char **p;
for (lp = lineinfo, p = linearray; p != nextline; lp++, p++)
{
lp->text = *p;
lp->key.text = find_field (keyfields, *p, &lp->keylen);
if (keyfields->numeric)
lp->key.number = find_value (lp->key.text, lp->keylen);
}
qsort (lineinfo, nextline - linearray, sizeof (struct lineinfo), compare_prepared);
for (lp = lineinfo, p = linearray; p != nextline; lp++, p++)
*p = lp->text;
free (lineinfo);
}
else
qsort (linearray, nextline - linearray, sizeof (char *), compare_full);
/* Open the output file */
if (outfile)
{
ostream = fopen (outfile, "w");
if (!ostream)
pfatal_with_name (outfile);
}
writelines (linearray, nextline - linearray, ostream);
if (outfile) fclose (ostream);
free (linearray);
free (data);
}
�
/* Parse an input string in core into lines.
DATA is the input string, and SIZE is its length.
Data goes in LINEARRAY starting at NEXTLINE.
The value returned is the first entry in LINEARRAY still unused.
Value 0 means input file contents are invalid. */
char **
parsefile (filename, nextline, data, size)
char *filename;
char **nextline;
char *data;
long size;
{
char *p, *end;
char **line = nextline;
p = data;
end = p + size;
*end = 0;
while (p != end)
{
if (p[0] != '\\' && p[0] != '@')
return 0;
*line = p;
while (*p && *p != '\n') p++;
if (p != end) p++;
line++;
if (line == linearray + nlines)
{
char **old = linearray;
linearray = (char **) xrealloc (linearray, sizeof (char *) * (nlines *= 4));
line += linearray - old;
}
}
return line;
}
�
/* Indexification is a filter applied to the sorted lines
as they are being written to the output file.
Multiple entries for the same name, with different page numbers,
get combined into a single entry with multiple page numbers.
The first braced field, which is used for sorting, is discarded.
However, its first character is examined, folded to lower case,
and if it is different from that in the previous line fed to us
a \initial line is written with one argument, the new initial.
If an entry has four braced fields, then the second and third
constitute primary and secondary names.
In this case, each change of primary name
generates a \primary line which contains only the primary name,
and in between these are \secondary lines which contain
just a secondary name and page numbers.
*/
/* The last primary name we wrote a \primary entry for.
If only one level of indexing is being done, this is the last name seen */
char *lastprimary;
int lastprimarylength; /* Length of storage allocated for lastprimary */
/* Similar, for the secondary name. */
char *lastsecondary;
int lastsecondarylength;
/* Zero if we are not in the middle of writing an entry.
One if we have written the beginning of an entry but have not
yet written any page numbers into it.
Greater than one if we have written the beginning of an entry
plus at least one page number. */
int pending;
/* The initial (for sorting purposes) of the last primary entry written.
When this changes, a \initial {c} line is written */
char * lastinitial;
int lastinitiallength;
/* When we need a string of length 1 for the value of lastinitial,
store it here. */
char lastinitial1[2];
/* Initialize static storage for writing an index */
void
init_index ()
{
pending = 0;
lastinitial = lastinitial1;
lastinitial1[0] = 0;
lastinitial1[1] = 0;
lastinitiallength = 0;
lastprimarylength = 100;
lastprimary = (char *) xmalloc (lastprimarylength + 1);
bzero (lastprimary, lastprimarylength + 1);
lastsecondarylength = 100;
lastsecondary = (char *) xmalloc (lastsecondarylength + 1);
bzero (lastsecondary, lastsecondarylength + 1);
}
/* Indexify. Merge entries for the same name,
insert headers for each initial character, etc. */
indexify (line, ostream)
char *line;
FILE *ostream;
{
char *primary, *secondary, *pagenumber;
int primarylength, secondarylength, pagelength;
int len = strlen (line);
int nosecondary;
int initiallength;
char *initial;
char initial1[2];
register char *p;
/* First, analyze the parts of the entry fed to us this time */
p = find_braced_pos (line, 0, 0, 0);
if (*p == '{')
{
initial = p;
/* Get length of inner pair of braces starting at p,
including that inner pair of braces. */
initiallength = find_braced_end (p + 1) + 1 - p;
}
else
{
initial = initial1;
initial1[0] = *p;
initial1[1] = 0;
initiallength = 1;
if (initial1[0] >= 'a' && initial1[0] <= 'z')
initial1[0] -= 040;
}
pagenumber = find_braced_pos (line, 1, 0, 0);
pagelength = find_braced_end (pagenumber) - pagenumber;
if (pagelength == 0)
abort ();
primary = find_braced_pos (line, 2, 0, 0);
primarylength = find_braced_end (primary) - primary;
secondary = find_braced_pos (line, 3, 0, 0);
nosecondary = !*secondary;
if (!nosecondary)
secondarylength = find_braced_end (secondary) - secondary;
/* If the primary is different from before, make a new primary entry */
if (strncmp (primary, lastprimary, primarylength))
{
/* Close off current secondary entry first, if one is open */
if (pending)
{
fputs ("}\n", ostream);
pending = 0;
}
/* If this primary has a different initial, include an entry for the initial */
if (initiallength != lastinitiallength ||
strncmp (initial, lastinitial, initiallength))
{
fprintf (ostream, "\\initial {");
fwrite (initial, 1, initiallength, ostream);
fprintf (ostream, "}\n", initial);
if (initial == initial1)
{
lastinitial = lastinitial1;
*lastinitial1 = *initial1;
}
else
{
lastinitial = initial;
}
lastinitiallength = initiallength;
}
/* Make the entry for the primary. */
if (nosecondary)
fputs ("\\entry {", ostream);
else
fputs ("\\primary {", ostream);
fwrite (primary, primarylength, 1, ostream);
if (nosecondary)
{
fputs ("}{", ostream);
pending = 1;
}
else
fputs ("}\n", ostream);
/* Record name of most recent primary */
if (lastprimarylength < primarylength)
{
lastprimarylength = primarylength + 100;
lastprimary = (char *) xrealloc (lastprimary,
1 + lastprimarylength);
}
strncpy (lastprimary, primary, primarylength);
lastprimary[primarylength] = 0;
/* There is no current secondary within this primary, now */
lastsecondary[0] = 0;
}
/* Should not have an entry with no subtopic following one with a subtopic */
if (nosecondary && *lastsecondary)
error ("entry %s follows an entry with a secondary name", line);
/* Start a new secondary entry if necessary */
if (!nosecondary && strncmp (secondary, lastsecondary, secondarylength))
{
if (pending)
{
fputs ("}\n", ostream);
pending = 0;
}
/* Write the entry for the secondary. */
fputs ("\\secondary {", ostream);
fwrite (secondary, secondarylength, 1, ostream);
fputs ("}{", ostream);
pending = 1;
/* Record name of most recent secondary */
if (lastsecondarylength < secondarylength)
{
lastsecondarylength = secondarylength + 100;
lastsecondary = (char *) xrealloc (lastsecondary,
1 + lastsecondarylength);
}
strncpy (lastsecondary, secondary, secondarylength);
lastsecondary[secondarylength] = 0;
}
/* Here to add one more page number to the current entry */
if (pending++ != 1)
fputs (", ", ostream); /* Punctuate first, if this is not the first */
fwrite (pagenumber, pagelength, 1, ostream);
}
/* Close out any unfinished output entry */
void
finish_index (ostream)
FILE *ostream;
{
if (pending)
fputs ("}\n", ostream);
free (lastprimary);
free (lastsecondary);
}
�
/* Copy the lines in the sorted order.
Each line is copied out of the input file it was found in. */
void
writelines (linearray, nlines, ostream)
char **linearray;
int nlines;
FILE *ostream;
{
char **stop_line = linearray + nlines;
char **next_line;
init_index ();
/* Output the text of the lines, and free the buffer space */
for (next_line = linearray; next_line != stop_line; next_line++)
{
/* If -u was specified, output the line only if distinct from previous one. */
if (next_line == linearray
/* Compare previous line with this one, using only the explicitly specd keyfields */
|| compare_general (*(next_line - 1), *next_line, 0L, 0L, num_keyfields - 1))
{
char *p = *next_line;
char c;
while ((c = *p++) && c != '\n');
*(p-1) = 0;
indexify (*next_line, ostream);
}
}
finish_index (ostream);
}
�
/* Assume (and optionally verify) that each input file is sorted;
merge them and output the result.
Returns nonzero if any input file fails to be sorted.
This is the high-level interface that can handle an unlimited number of files. */
#define MAX_DIRECT_MERGE 10
int
merge_files (infiles, nfiles, outfile)
char **infiles;
int nfiles;
char *outfile;
{
char **tempfiles;
int ntemps;
int i;
int value = 0;
int start_tempcount = tempcount;
if (nfiles <= MAX_DIRECT_MERGE)
return merge_direct (infiles, nfiles, outfile);
/* Merge groups of MAX_DIRECT_MERGE input files at a time,
making a temporary file to hold each group's result. */
ntemps = (nfiles + MAX_DIRECT_MERGE - 1) / MAX_DIRECT_MERGE;
tempfiles = (char **) xmalloc (ntemps * sizeof (char *));
for (i = 0; i < ntemps; i++)
{
int nf = MAX_DIRECT_MERGE;
if (i + 1 == ntemps)
nf = nfiles - i * MAX_DIRECT_MERGE;
tempfiles[i] = maketempname (++tempcount);
value |= merge_direct (&infiles[i * MAX_DIRECT_MERGE], nf, tempfiles[i]);
}
/* All temporary files that existed before are no longer needed
since their contents have been merged into our new tempfiles.
So delete them. */
flush_tempfiles (start_tempcount);
/* Now merge the temporary files we created. */
merge_files (tempfiles, ntemps, outfile);
free (tempfiles);
return value;
}
�
/* Assume (and optionally verify) that each input file is sorted;
merge them and output the result.
Returns nonzero if any input file fails to be sorted.
This version of merging will not work if the number of
input files gets too high. Higher level functions
use it only with a bounded number of input files. */
int
merge_direct (infiles, nfiles, outfile)
char **infiles;
int nfiles;
char *outfile;
{
char **ip = infiles;
struct linebuffer *lb1, *lb2;
struct linebuffer **thisline, **prevline;
FILE **streams;
int i;
int nleft;
int lossage = 0;
int *file_lossage;
struct linebuffer *prev_out = 0;
FILE *ostream = stdout;
if (outfile)
{
ostream = fopen (outfile, "w");
}
if (!ostream) pfatal_with_name (outfile);
init_index ();
if (nfiles == 0)
{
if (outfile)
fclose (ostream);
return 0;
}
/* For each file, make two line buffers.
Also, for each file, there is an element of `thisline'
which points at any time to one of the file's two buffers,
and an element of `prevline' which points to the other buffer.
`thisline' is supposed to point to the next available line from the file,
while `prevline' holds the last file line used,
which is remembered so that we can verify that the file is properly sorted. */
/* lb1 and lb2 contain one buffer each per file */
lb1 = (struct linebuffer *) xmalloc (nfiles * sizeof (struct linebuffer));
lb2 = (struct linebuffer *) xmalloc (nfiles * sizeof (struct linebuffer));
/* thisline[i] points to the linebuffer holding the next available line in file i,
or is zero if there are no lines left in that file. */
thisline = (struct linebuffer **) xmalloc (nfiles * sizeof (struct linebuffer *));
/* prevline[i] points to the linebuffer holding the last used line from file i.
This is just for verifying that file i is properly sorted. */
prevline = (struct linebuffer **) xmalloc (nfiles * sizeof (struct linebuffer *));
/* streams[i] holds the input stream for file i. */
streams = (FILE **) xmalloc (nfiles * sizeof (FILE *));
/* file_lossage[i] is nonzero if we already know file i is not properly sorted. */
file_lossage = (int *) xmalloc (nfiles * sizeof (int));
/* Allocate and initialize all that storage */
for (i = 0; i < nfiles; i++)
{
initbuffer (&lb1[i]);
initbuffer (&lb2[i]);
thisline[i] = &lb1[i];
prevline[i] = &lb2[i];
file_lossage[i] = 0;
streams[i] = fopen (infiles[i], "r");
if (!streams[i])
pfatal_with_name (infiles[i]);
readline (thisline[i], streams[i]);
}
/* Keep count of number of files not at eof */
nleft = nfiles;
while (nleft)
{
struct linebuffer *best = 0;
struct linebuffer *exch;
int bestfile = -1;
int i;
/* Look at the next avail line of each file; choose the least one. */
for (i = 0; i < nfiles; i++)
{
if (thisline[i] &&
(!best ||
0 < compare_general (best->buffer, thisline[i]->buffer,
(long) bestfile, (long) i, num_keyfields)))
{
best = thisline[i];
bestfile = i;
}
}
/* Output that line, unless it matches the previous one and we don't want duplicates */
if (!(prev_out &&
!compare_general (prev_out->buffer, best->buffer, 0L, 1L, num_keyfields - 1)))
indexify (best->buffer, ostream);
prev_out = best;
/* Now make the line the previous of its file, and fetch a new line from that file */
exch = prevline[bestfile];
prevline[bestfile] = thisline[bestfile];
thisline[bestfile] = exch;
while (1)
{
/* If the file has no more, mark it empty */
if (feof (streams[bestfile]))
{
thisline[bestfile] = 0;
nleft--; /* Update the number of files still not empty */
break;
}
readline (thisline[bestfile], streams[bestfile]);
if (thisline[bestfile]->buffer[0] || !feof (streams[bestfile])) break;
}
}
finish_index (ostream);
/* Free all storage and close all input streams */
for (i = 0; i < nfiles; i++)
{
fclose (streams[i]);
free (lb1[i].buffer);
free (lb2[i].buffer);
}
free (file_lossage);
free (lb1);
free (lb2);
free (thisline);
free (prevline);
free (streams);
if (outfile)
fclose (ostream);
return lossage;
}
�
/* Print error message and exit. */
fatal (s1, s2)
char *s1, *s2;
{
error (s1, s2);
exit (EXIT_FATAL);
}
/* Print error message. `s1' is printf control string, `s2' is arg for it. */
error (s1, s2)
char *s1, *s2;
{
printf ("texindex: ");
printf (s1, s2);
printf ("\n");
}
perror_with_name (name)
char *name;
{
char *s;
if (errno < sys_nerr)
s = concat ("", sys_errlist[errno], " for %s");
else
s = "cannot open %s";
error (s, name);
}
pfatal_with_name (name)
char *name;
{
char *s;
if (errno < sys_nerr)
s = concat ("", sys_errlist[errno], " for %s");
else
s = "cannot open %s";
fatal (s, name);
}
/* Return a newly-allocated string whose contents concatenate those of s1, s2, s3. */
char *
concat (s1, s2, s3)
char *s1, *s2, *s3;
{
int len1 = strlen (s1), len2 = strlen (s2), len3 = strlen (s3);
char *result = (char *) xmalloc (len1 + len2 + len3 + 1);
strcpy (result, s1);
strcpy (result + len1, s2);
strcpy (result + len1 + len2, s3);
*(result + len1 + len2 + len3) = 0;
return result;
}
/* Like malloc but get fatal error if memory is exhausted. */
int
xmalloc (size)
int size;
{
int result = malloc (size);
if (!result)
fatal ("virtual memory exhausted", 0);
return result;
}
int
xrealloc (ptr, size)
char *ptr;
int size;
{
int result = realloc (ptr, size);
if (!result)
fatal ("virtual memory exhausted");
return result;
}
bzero (b, length)
register char *b;
register int length;
{
#ifdef VMS
short zero = 0;
long max_str = 65535;
long len;
while (length > max_str)
{
(void) LIB$MOVC5 (&zero, &zero, &zero, &max_str, b);
length -= max_str;
b += max_str;
}
len = length;
(void) LIB$MOVC5 (&zero, &zero, &zero, &len, b);
#else
while (length-- > 0)
*b++ = 0;
#endif /* not VMS */
}