freebsd-skq/contrib/flex/filter.c

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/* filter - postprocessing of flex output through filters */
/* This file is part of flex. */
/* Redistribution and use in source and binary forms, with or without */
/* modification, are permitted provided that the following conditions */
/* are met: */
/* 1. Redistributions of source code must retain the above copyright */
/* notice, this list of conditions and the following disclaimer. */
/* 2. Redistributions in binary form must reproduce the above copyright */
/* notice, this list of conditions and the following disclaimer in the */
/* documentation and/or other materials provided with the distribution. */
/* Neither the name of the University nor the names of its contributors */
/* may be used to endorse or promote products derived from this software */
/* without specific prior written permission. */
/* THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR */
/* IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED */
/* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR */
/* PURPOSE. */
#include "flexdef.h"
static const char * check_4_gnu_m4 =
"m4_dnl ifdef(`__gnu__', ,"
"`errprint(Flex requires GNU M4. Set the PATH or set the M4 environment variable to its path name.)"
" m4exit(2)')\n";
/** global chain. */
struct filter *output_chain = NULL;
/* Allocate and initialize an external filter.
* @param chain the current chain or NULL for new chain
* @param cmd the command to execute.
* @param ... a NULL terminated list of (const char*) arguments to command,
* not including argv[0].
* @return newest filter in chain
*/
struct filter *filter_create_ext (struct filter *chain, const char *cmd,
...)
{
struct filter *f;
int max_args;
const char *s;
va_list ap;
/* allocate and initialize new filter */
f = (struct filter *) flex_alloc (sizeof (struct filter));
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if (!f)
flexerror (_("flex_alloc failed (f) in filter_create_ext"));
memset (f, 0, sizeof (*f));
f->filter_func = NULL;
f->extra = NULL;
f->next = NULL;
f->argc = 0;
if (chain != NULL) {
/* append f to end of chain */
while (chain->next)
chain = chain->next;
chain->next = f;
}
/* allocate argv, and populate it with the argument list. */
max_args = 8;
f->argv =
(const char **) flex_alloc (sizeof (char *) *
(max_args + 1));
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if (!f->argv)
flexerror (_("flex_alloc failed (f->argv) in filter_create_ext"));
f->argv[f->argc++] = cmd;
va_start (ap, cmd);
while ((s = va_arg (ap, const char *)) != NULL) {
if (f->argc >= max_args) {
max_args += 8;
f->argv =
(const char **) flex_realloc (f->argv,
sizeof (char
*) *
(max_args +
1));
}
f->argv[f->argc++] = s;
}
f->argv[f->argc] = NULL;
va_end (ap);
return f;
}
/* Allocate and initialize an internal filter.
* @param chain the current chain or NULL for new chain
* @param filter_func The function that will perform the filtering.
* filter_func should return 0 if successful, and -1
* if an error occurs -- or it can simply exit().
* @param extra optional user-defined data to pass to the filter.
* @return newest filter in chain
*/
struct filter *filter_create_int (struct filter *chain,
int (*filter_func) (struct filter *),
void *extra)
{
struct filter *f;
/* allocate and initialize new filter */
f = (struct filter *) flex_alloc (sizeof (struct filter));
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if (!f)
flexerror (_("flex_alloc failed in filter_create_int"));
memset (f, 0, sizeof (*f));
f->next = NULL;
f->argc = 0;
f->argv = NULL;
f->filter_func = filter_func;
f->extra = extra;
if (chain != NULL) {
/* append f to end of chain */
while (chain->next)
chain = chain->next;
chain->next = f;
}
return f;
}
/** Fork and exec entire filter chain.
* @param chain The head of the chain.
* @return true on success.
*/
bool filter_apply_chain (struct filter * chain)
{
int pid, pipes[2];
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/* Tricky recursion, since we want to begin the chain
* at the END. Why? Because we need all the forked processes
* to be children of the main flex process.
*/
if (chain)
filter_apply_chain (chain->next);
else
return true;
/* Now we are the right-most unprocessed link in the chain.
*/
fflush (stdout);
fflush (stderr);
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if (pipe (pipes) == -1)
flexerror (_("pipe failed"));
if ((pid = fork ()) == -1)
flexerror (_("fork failed"));
if (pid == 0) {
/* child */
/* We need stdin (the FILE* stdin) to connect to this new pipe.
* There is no portable way to set stdin to a new file descriptor,
* as stdin is not an lvalue on some systems (BSD).
* So we dup the new pipe onto the stdin descriptor and use a no-op fseek
* to sync the stream. This is a Hail Mary situation. It seems to work.
*/
close (pipes[1]);
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clearerr(stdin);
if (dup2 (pipes[0], fileno (stdin)) == -1)
flexfatal (_("dup2(pipes[0],0)"));
close (pipes[0]);
fseek (stdin, 0, SEEK_CUR);
/* run as a filter, either internally or by exec */
if (chain->filter_func) {
int r;
if ((r = chain->filter_func (chain)) == -1)
flexfatal (_("filter_func failed"));
exit (0);
}
else {
execvp (chain->argv[0],
(char **const) (chain->argv));
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lerrsf_fatal ( _("exec of %s failed"),
chain->argv[0]);
}
exit (1);
}
/* Parent */
close (pipes[0]);
if (dup2 (pipes[1], fileno (stdout)) == -1)
flexfatal (_("dup2(pipes[1],1)"));
close (pipes[1]);
fseek (stdout, 0, SEEK_CUR);
return true;
}
/** Truncate the chain to max_len number of filters.
* @param chain the current chain.
* @param max_len the maximum length of the chain.
* @return the resulting length of the chain.
*/
int filter_truncate (struct filter *chain, int max_len)
{
int len = 1;
if (!chain)
return 0;
while (chain->next && len < max_len) {
chain = chain->next;
++len;
}
chain->next = NULL;
return len;
}
/** Splits the chain in order to write to a header file.
* Similar in spirit to the 'tee' program.
* The header file name is in extra.
* @return 0 (zero) on success, and -1 on failure.
*/
int filter_tee_header (struct filter *chain)
{
/* This function reads from stdin and writes to both the C file and the
* header file at the same time.
*/
const int readsz = 512;
char *buf;
int to_cfd = -1;
FILE *to_c = NULL, *to_h = NULL;
bool write_header;
write_header = (chain->extra != NULL);
/* Store a copy of the stdout pipe, which is already piped to C file
* through the running chain. Then create a new pipe to the H file as
* stdout, and fork the rest of the chain again.
*/
if ((to_cfd = dup (1)) == -1)
flexfatal (_("dup(1) failed"));
to_c = fdopen (to_cfd, "w");
if (write_header) {
if (freopen ((char *) chain->extra, "w", stdout) == NULL)
flexfatal (_("freopen(headerfilename) failed"));
filter_apply_chain (chain->next);
to_h = stdout;
}
/* Now to_c is a pipe to the C branch, and to_h is a pipe to the H branch.
*/
if (write_header) {
fputs (check_4_gnu_m4, to_h);
fputs ("m4_changecom`'m4_dnl\n", to_h);
fputs ("m4_changequote`'m4_dnl\n", to_h);
fputs ("m4_changequote([[,]])[[]]m4_dnl\n", to_h);
fputs ("m4_define([[M4_YY_NOOP]])[[]]m4_dnl\n", to_h);
fputs ("m4_define( [[M4_YY_IN_HEADER]],[[]])m4_dnl\n",
to_h);
fprintf (to_h, "#ifndef %sHEADER_H\n", prefix);
fprintf (to_h, "#define %sHEADER_H 1\n", prefix);
fprintf (to_h, "#define %sIN_HEADER 1\n\n", prefix);
fprintf (to_h,
"m4_define( [[M4_YY_OUTFILE_NAME]],[[%s]])m4_dnl\n",
headerfilename ? headerfilename : "<stdout>");
}
fputs (check_4_gnu_m4, to_c);
fputs ("m4_changecom`'m4_dnl\n", to_c);
fputs ("m4_changequote`'m4_dnl\n", to_c);
fputs ("m4_changequote([[,]])[[]]m4_dnl\n", to_c);
fputs ("m4_define([[M4_YY_NOOP]])[[]]m4_dnl\n", to_c);
fprintf (to_c, "m4_define( [[M4_YY_OUTFILE_NAME]],[[%s]])m4_dnl\n",
outfilename ? outfilename : "<stdout>");
buf = (char *) flex_alloc (readsz);
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if (!buf)
flexerror (_("flex_alloc failed in filter_tee_header"));
while (fgets (buf, readsz, stdin)) {
fputs (buf, to_c);
if (write_header)
fputs (buf, to_h);
}
if (write_header) {
fprintf (to_h, "\n");
/* write a fake line number. It will get fixed by the linedir filter. */
fprintf (to_h, "#line 4000 \"M4_YY_OUTFILE_NAME\"\n");
fprintf (to_h, "#undef %sIN_HEADER\n", prefix);
fprintf (to_h, "#endif /* %sHEADER_H */\n", prefix);
fputs ("m4_undefine( [[M4_YY_IN_HEADER]])m4_dnl\n", to_h);
fflush (to_h);
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if (ferror (to_h))
lerrsf (_("error writing output file %s"),
(char *) chain->extra);
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else if (fclose (to_h))
lerrsf (_("error closing output file %s"),
(char *) chain->extra);
}
fflush (to_c);
if (ferror (to_c))
lerrsf (_("error writing output file %s"),
outfilename ? outfilename : "<stdout>");
else if (fclose (to_c))
lerrsf (_("error closing output file %s"),
outfilename ? outfilename : "<stdout>");
while (wait (0) > 0) ;
exit (0);
return 0;
}
/** Adjust the line numbers in the #line directives of the generated scanner.
* After the m4 expansion, the line numbers are incorrect since the m4 macros
* can add or remove lines. This only adjusts line numbers for generated code,
* not user code. This also happens to be a good place to squeeze multiple
* blank lines into a single blank line.
*/
int filter_fix_linedirs (struct filter *chain)
{
char *buf;
const int readsz = 512;
int lineno = 1;
bool in_gen = true; /* in generated code */
bool last_was_blank = false;
if (!chain)
return 0;
buf = (char *) flex_alloc (readsz);
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if (!buf)
flexerror (_("flex_alloc failed in filter_fix_linedirs"));
while (fgets (buf, readsz, stdin)) {
regmatch_t m[10];
/* Check for #line directive. */
if (buf[0] == '#'
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&& regexec (&regex_linedir, buf, 3, m, 0) == 0) {
int num;
char *fname;
/* extract the line number and filename */
num = regmatch_strtol (&m[1], buf, NULL, 0);
fname = regmatch_dup (&m[2], buf);
if (strcmp (fname,
outfilename ? outfilename : "<stdout>")
== 0
|| strcmp (fname,
headerfilename ? headerfilename : "<stdout>")
== 0) {
char *s1, *s2;
char filename[MAXLINE];
s1 = fname;
s2 = filename;
while ((s2 - filename) < (MAXLINE - 1) && *s1) {
/* Escape the backslash */
if (*s1 == '\\')
*s2++ = '\\';
/* Escape the double quote */
if (*s1 == '\"')
*s2++ = '\\';
/* Copy the character as usual */
*s2++ = *s1++;
}
*s2 = '\0';
/* Adjust the line directives. */
in_gen = true;
snprintf (buf, readsz, "#line %d \"%s\"\n",
lineno + 1, filename);
}
else {
/* it's a #line directive for code we didn't write */
in_gen = false;
}
free (fname);
last_was_blank = false;
}
/* squeeze blank lines from generated code */
else if (in_gen
&& regexec (&regex_blank_line, buf, 0, NULL,
0) == 0) {
if (last_was_blank)
continue;
else
last_was_blank = true;
}
else {
/* it's a line of normal, non-empty code. */
last_was_blank = false;
}
fputs (buf, stdout);
lineno++;
}
fflush (stdout);
if (ferror (stdout))
lerrsf (_("error writing output file %s"),
outfilename ? outfilename : "<stdout>");
else if (fclose (stdout))
lerrsf (_("error closing output file %s"),
outfilename ? outfilename : "<stdout>");
return 0;
}
/* vim:set expandtab cindent tabstop=4 softtabstop=4 shiftwidth=4 textwidth=0: */