/* Miscellaneous generic support functions for GNU Make. Copyright (C) 1988, 1989, 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006 Free Software Foundation, Inc. This file is part of GNU Make. GNU Make is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. GNU Make 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 GNU Make; see the file COPYING. If not, write to the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. */ #include "make.h" #include "dep.h" #include "debug.h" /* Variadic functions. We go through contortions to allow proper function prototypes for both ANSI and pre-ANSI C compilers, and also for those which support stdarg.h vs. varargs.h, and finally those which have vfprintf(), etc. and those who have _doprnt... or nothing. This fancy stuff all came from GNU fileutils, except for the VA_PRINTF and VA_END macros used here since we have multiple print functions. */ #if USE_VARIADIC # if HAVE_STDARG_H # include # define VA_START(args, lastarg) va_start(args, lastarg) # else # include # define VA_START(args, lastarg) va_start(args) # endif # if HAVE_VPRINTF # define VA_PRINTF(fp, lastarg, args) vfprintf((fp), (lastarg), (args)) # else # define VA_PRINTF(fp, lastarg, args) _doprnt((lastarg), (args), (fp)) # endif # define VA_END(args) va_end(args) #else /* We can't use any variadic interface! */ # define va_alist a1, a2, a3, a4, a5, a6, a7, a8 # define va_dcl char *a1, *a2, *a3, *a4, *a5, *a6, *a7, *a8; # define VA_START(args, lastarg) # define VA_PRINTF(fp, lastarg, args) fprintf((fp), (lastarg), va_alist) # define VA_END(args) #endif /* Compare strings *S1 and *S2. Return negative if the first is less, positive if it is greater, zero if they are equal. */ int alpha_compare (const void *v1, const void *v2) { const char *s1 = *((char **)v1); const char *s2 = *((char **)v2); if (*s1 != *s2) return *s1 - *s2; return strcmp (s1, s2); } /* Discard each backslash-newline combination from LINE. Backslash-backslash-newline combinations become backslash-newlines. This is done by copying the text at LINE into itself. */ void collapse_continuations (char *line) { register char *in, *out, *p; register int backslash; register unsigned int bs_write; in = strchr (line, '\n'); if (in == 0) return; out = in; while (out > line && out[-1] == '\\') --out; while (*in != '\0') { /* BS_WRITE gets the number of quoted backslashes at the end just before IN, and BACKSLASH gets nonzero if the next character is quoted. */ backslash = 0; bs_write = 0; for (p = in - 1; p >= line && *p == '\\'; --p) { if (backslash) ++bs_write; backslash = !backslash; /* It should be impossible to go back this far without exiting, but if we do, we can't get the right answer. */ if (in == out - 1) abort (); } /* Output the appropriate number of backslashes. */ while (bs_write-- > 0) *out++ = '\\'; /* Skip the newline. */ ++in; /* If the newline is quoted, discard following whitespace and any preceding whitespace; leave just one space. */ if (backslash) { in = next_token (in); while (out > line && isblank ((unsigned char)out[-1])) --out; *out++ = ' '; } else /* If the newline isn't quoted, put it in the output. */ *out++ = '\n'; /* Now copy the following line to the output. Stop when we find backslashes followed by a newline. */ while (*in != '\0') if (*in == '\\') { p = in + 1; while (*p == '\\') ++p; if (*p == '\n') { in = p; break; } while (in < p) *out++ = *in++; } else *out++ = *in++; } *out = '\0'; } /* Print N spaces (used in debug for target-depth). */ void print_spaces (unsigned int n) { while (n-- > 0) putchar (' '); } /* Return a newly-allocated string whose contents concatenate those of s1, s2, s3. */ char * concat (const char *s1, const char *s2, const char *s3) { unsigned int len1, len2, len3; char *result; len1 = *s1 != '\0' ? strlen (s1) : 0; len2 = *s2 != '\0' ? strlen (s2) : 0; len3 = *s3 != '\0' ? strlen (s3) : 0; result = xmalloc (len1 + len2 + len3 + 1); if (*s1 != '\0') memcpy (result, s1, len1); if (*s2 != '\0') memcpy (result + len1, s2, len2); if (*s3 != '\0') memcpy (result + len1 + len2, s3, len3); *(result + len1 + len2 + len3) = '\0'; return result; } /* Print a message on stdout. */ void #if HAVE_ANSI_COMPILER && USE_VARIADIC && HAVE_STDARG_H message (int prefix, const char *fmt, ...) #else message (prefix, fmt, va_alist) int prefix; const char *fmt; va_dcl #endif { #if USE_VARIADIC va_list args; #endif log_working_directory (1); if (fmt != 0) { if (prefix) { if (makelevel == 0) printf ("%s: ", program); else printf ("%s[%u]: ", program, makelevel); } VA_START (args, fmt); VA_PRINTF (stdout, fmt, args); VA_END (args); putchar ('\n'); } fflush (stdout); } /* Print an error message. */ void #if HAVE_ANSI_COMPILER && USE_VARIADIC && HAVE_STDARG_H error (const struct floc *flocp, const char *fmt, ...) #else error (flocp, fmt, va_alist) const struct floc *flocp; const char *fmt; va_dcl #endif { #if USE_VARIADIC va_list args; #endif log_working_directory (1); if (flocp && flocp->filenm) fprintf (stderr, "%s:%lu: ", flocp->filenm, flocp->lineno); else if (makelevel == 0) fprintf (stderr, "%s: ", program); else fprintf (stderr, "%s[%u]: ", program, makelevel); VA_START(args, fmt); VA_PRINTF (stderr, fmt, args); VA_END (args); putc ('\n', stderr); fflush (stderr); } /* Print an error message and exit. */ void #if HAVE_ANSI_COMPILER && USE_VARIADIC && HAVE_STDARG_H fatal (const struct floc *flocp, const char *fmt, ...) #else fatal (flocp, fmt, va_alist) const struct floc *flocp; const char *fmt; va_dcl #endif { #if USE_VARIADIC va_list args; #endif log_working_directory (1); if (flocp && flocp->filenm) fprintf (stderr, "%s:%lu: *** ", flocp->filenm, flocp->lineno); else if (makelevel == 0) fprintf (stderr, "%s: *** ", program); else fprintf (stderr, "%s[%u]: *** ", program, makelevel); VA_START(args, fmt); VA_PRINTF (stderr, fmt, args); VA_END (args); fputs (_(". Stop.\n"), stderr); die (2); } #ifndef HAVE_STRERROR #undef strerror char * strerror (int errnum) { extern int errno, sys_nerr; #ifndef __DECC extern char *sys_errlist[]; #endif static char buf[] = "Unknown error 12345678901234567890"; if (errno < sys_nerr) return sys_errlist[errnum]; sprintf (buf, _("Unknown error %d"), errnum); return buf; } #endif /* Print an error message from errno. */ void perror_with_name (const char *str, const char *name) { error (NILF, _("%s%s: %s"), str, name, strerror (errno)); } /* Print an error message from errno and exit. */ void pfatal_with_name (const char *name) { fatal (NILF, _("%s: %s"), name, strerror (errno)); /* NOTREACHED */ } /* Like malloc but get fatal error if memory is exhausted. */ /* Don't bother if we're using dmalloc; it provides these for us. */ #ifndef HAVE_DMALLOC_H #undef xmalloc #undef xrealloc #undef xstrdup void * xmalloc (unsigned int size) { /* Make sure we don't allocate 0, for pre-ANSI libraries. */ void *result = malloc (size ? size : 1); if (result == 0) fatal (NILF, _("virtual memory exhausted")); return result; } void * xrealloc (void *ptr, unsigned int size) { void *result; /* Some older implementations of realloc() don't conform to ANSI. */ if (! size) size = 1; result = ptr ? realloc (ptr, size) : malloc (size); if (result == 0) fatal (NILF, _("virtual memory exhausted")); return result; } char * xstrdup (const char *ptr) { char *result; #ifdef HAVE_STRDUP result = strdup (ptr); #else result = malloc (strlen (ptr) + 1); #endif if (result == 0) fatal (NILF, _("virtual memory exhausted")); #ifdef HAVE_STRDUP return result; #else return strcpy (result, ptr); #endif } #endif /* HAVE_DMALLOC_H */ char * savestring (const char *str, unsigned int length) { char *out = xmalloc (length + 1); if (length > 0) memcpy (out, str, length); out[length] = '\0'; return out; } /* Limited INDEX: Search through the string STRING, which ends at LIMIT, for the character C. Returns a pointer to the first occurrence, or nil if none is found. Like INDEX except that the string searched ends where specified instead of at the first null. */ char * lindex (const char *s, const char *limit, int c) { while (s < limit) if (*s++ == c) return (char *)(s - 1); return 0; } /* Return the address of the first whitespace or null in the string S. */ char * end_of_token (const char *s) { while (*s != '\0' && !isblank ((unsigned char)*s)) ++s; return (char *)s; } #ifdef WINDOWS32 /* * Same as end_of_token, but take into account a stop character */ char * end_of_token_w32 (char *s, char stopchar) { register char *p = s; register int backslash = 0; while (*p != '\0' && *p != stopchar && (backslash || !isblank ((unsigned char)*p))) { if (*p++ == '\\') { backslash = !backslash; while (*p == '\\') { backslash = !backslash; ++p; } } else backslash = 0; } return p; } #endif /* Return the address of the first nonwhitespace or null in the string S. */ char * next_token (const char *s) { while (isblank ((unsigned char)*s)) ++s; return (char *)s; } /* Find the next token in PTR; return the address of it, and store the length of the token into *LENGTHPTR if LENGTHPTR is not nil. */ char * find_next_token (char **ptr, unsigned int *lengthptr) { char *p = next_token (*ptr); char *end; if (*p == '\0') return 0; *ptr = end = end_of_token (p); if (lengthptr != 0) *lengthptr = end - p; return p; } /* Allocate a new `struct dep' with all fields initialized to 0. */ struct dep * alloc_dep () { struct dep *d = xmalloc (sizeof (struct dep)); memset (d, '\0', sizeof (struct dep)); return d; } /* Free `struct dep' along with `name' and `stem'. */ void free_dep (struct dep *d) { if (d->name != 0) free (d->name); if (d->stem != 0) free (d->stem); free (d); } /* Copy a chain of `struct dep', making a new chain with the same contents as the old one. */ struct dep * copy_dep_chain (const struct dep *d) { register struct dep *c; struct dep *firstnew = 0; struct dep *lastnew = 0; while (d != 0) { c = xmalloc (sizeof (struct dep)); memcpy (c, d, sizeof (struct dep)); if (c->name != 0) c->name = xstrdup (c->name); if (c->stem != 0) c->stem = xstrdup (c->stem); c->next = 0; if (firstnew == 0) firstnew = lastnew = c; else lastnew = lastnew->next = c; d = d->next; } return firstnew; } /* Free a chain of 'struct dep'. */ void free_dep_chain (struct dep *d) { while (d != 0) { struct dep *df = d; d = d->next; free_dep (df); } } /* Free a chain of `struct nameseq'. Each nameseq->name is freed as well. For `struct dep' chains use free_dep_chain. */ void free_ns_chain (struct nameseq *n) { register struct nameseq *tmp; while (n != 0) { if (n->name != 0) free (n->name); tmp = n; n = n->next; free (tmp); } } #ifdef iAPX286 /* The losing compiler on this machine can't handle this macro. */ char * dep_name (struct dep *dep) { return dep->name == 0 ? dep->file->name : dep->name; } #endif #ifdef GETLOADAVG_PRIVILEGED #ifdef POSIX /* Hopefully if a system says it's POSIX.1 and has the setuid and setgid functions, they work as POSIX.1 says. Some systems (Alpha OSF/1 1.2, for example) which claim to be POSIX.1 also have the BSD setreuid and setregid functions, but they don't work as in BSD and only the POSIX.1 way works. */ #undef HAVE_SETREUID #undef HAVE_SETREGID #else /* Not POSIX. */ /* Some POSIX.1 systems have the seteuid and setegid functions. In a POSIX-like system, they are the best thing to use. However, some non-POSIX systems have them too but they do not work in the POSIX style and we must use setreuid and setregid instead. */ #undef HAVE_SETEUID #undef HAVE_SETEGID #endif /* POSIX. */ #ifndef HAVE_UNISTD_H extern int getuid (), getgid (), geteuid (), getegid (); extern int setuid (), setgid (); #ifdef HAVE_SETEUID extern int seteuid (); #else #ifdef HAVE_SETREUID extern int setreuid (); #endif /* Have setreuid. */ #endif /* Have seteuid. */ #ifdef HAVE_SETEGID extern int setegid (); #else #ifdef HAVE_SETREGID extern int setregid (); #endif /* Have setregid. */ #endif /* Have setegid. */ #endif /* No . */ /* Keep track of the user and group IDs for user- and make- access. */ static int user_uid = -1, user_gid = -1, make_uid = -1, make_gid = -1; #define access_inited (user_uid != -1) static enum { make, user } current_access; /* Under -d, write a message describing the current IDs. */ static void log_access (const char *flavor) { if (! ISDB (DB_JOBS)) return; /* All the other debugging messages go to stdout, but we write this one to stderr because it might be run in a child fork whose stdout is piped. */ fprintf (stderr, _("%s: user %lu (real %lu), group %lu (real %lu)\n"), flavor, (unsigned long) geteuid (), (unsigned long) getuid (), (unsigned long) getegid (), (unsigned long) getgid ()); fflush (stderr); } static void init_access (void) { #ifndef VMS user_uid = getuid (); user_gid = getgid (); make_uid = geteuid (); make_gid = getegid (); /* Do these ever fail? */ if (user_uid == -1 || user_gid == -1 || make_uid == -1 || make_gid == -1) pfatal_with_name ("get{e}[gu]id"); log_access (_("Initialized access")); current_access = make; #endif } #endif /* GETLOADAVG_PRIVILEGED */ /* Give the process appropriate permissions for access to user data (i.e., to stat files, or to spawn a child process). */ void user_access (void) { #ifdef GETLOADAVG_PRIVILEGED if (!access_inited) init_access (); if (current_access == user) return; /* We are in "make access" mode. This means that the effective user and group IDs are those of make (if it was installed setuid or setgid). We now want to set the effective user and group IDs to the real IDs, which are the IDs of the process that exec'd make. */ #ifdef HAVE_SETEUID /* Modern systems have the seteuid/setegid calls which set only the effective IDs, which is ideal. */ if (seteuid (user_uid) < 0) pfatal_with_name ("user_access: seteuid"); #else /* Not HAVE_SETEUID. */ #ifndef HAVE_SETREUID /* System V has only the setuid/setgid calls to set user/group IDs. There is an effective ID, which can be set by setuid/setgid. It can be set (unless you are root) only to either what it already is (returned by geteuid/getegid, now in make_uid/make_gid), the real ID (return by getuid/getgid, now in user_uid/user_gid), or the saved set ID (what the effective ID was before this set-ID executable (make) was exec'd). */ if (setuid (user_uid) < 0) pfatal_with_name ("user_access: setuid"); #else /* HAVE_SETREUID. */ /* In 4BSD, the setreuid/setregid calls set both the real and effective IDs. They may be set to themselves or each other. So you have two alternatives at any one time. If you use setuid/setgid, the effective will be set to the real, leaving only one alternative. Using setreuid/setregid, however, you can toggle between your two alternatives by swapping the values in a single setreuid or setregid call. */ if (setreuid (make_uid, user_uid) < 0) pfatal_with_name ("user_access: setreuid"); #endif /* Not HAVE_SETREUID. */ #endif /* HAVE_SETEUID. */ #ifdef HAVE_SETEGID if (setegid (user_gid) < 0) pfatal_with_name ("user_access: setegid"); #else #ifndef HAVE_SETREGID if (setgid (user_gid) < 0) pfatal_with_name ("user_access: setgid"); #else if (setregid (make_gid, user_gid) < 0) pfatal_with_name ("user_access: setregid"); #endif #endif current_access = user; log_access (_("User access")); #endif /* GETLOADAVG_PRIVILEGED */ } /* Give the process appropriate permissions for access to make data (i.e., the load average). */ void make_access (void) { #ifdef GETLOADAVG_PRIVILEGED if (!access_inited) init_access (); if (current_access == make) return; /* See comments in user_access, above. */ #ifdef HAVE_SETEUID if (seteuid (make_uid) < 0) pfatal_with_name ("make_access: seteuid"); #else #ifndef HAVE_SETREUID if (setuid (make_uid) < 0) pfatal_with_name ("make_access: setuid"); #else if (setreuid (user_uid, make_uid) < 0) pfatal_with_name ("make_access: setreuid"); #endif #endif #ifdef HAVE_SETEGID if (setegid (make_gid) < 0) pfatal_with_name ("make_access: setegid"); #else #ifndef HAVE_SETREGID if (setgid (make_gid) < 0) pfatal_with_name ("make_access: setgid"); #else if (setregid (user_gid, make_gid) < 0) pfatal_with_name ("make_access: setregid"); #endif #endif current_access = make; log_access (_("Make access")); #endif /* GETLOADAVG_PRIVILEGED */ } /* Give the process appropriate permissions for a child process. This is like user_access, but you can't get back to make_access. */ void child_access (void) { #ifdef GETLOADAVG_PRIVILEGED if (!access_inited) abort (); /* Set both the real and effective UID and GID to the user's. They cannot be changed back to make's. */ #ifndef HAVE_SETREUID if (setuid (user_uid) < 0) pfatal_with_name ("child_access: setuid"); #else if (setreuid (user_uid, user_uid) < 0) pfatal_with_name ("child_access: setreuid"); #endif #ifndef HAVE_SETREGID if (setgid (user_gid) < 0) pfatal_with_name ("child_access: setgid"); #else if (setregid (user_gid, user_gid) < 0) pfatal_with_name ("child_access: setregid"); #endif log_access (_("Child access")); #endif /* GETLOADAVG_PRIVILEGED */ } #ifdef NEED_GET_PATH_MAX unsigned int get_path_max (void) { static unsigned int value; if (value == 0) { long int x = pathconf ("/", _PC_PATH_MAX); if (x > 0) value = x; else return MAXPATHLEN; } return value; } #endif /* This code is stolen from gnulib. If/when we abandon the requirement to work with K&R compilers, we can remove this (and perhaps other parts of GNU make!) and migrate to using gnulib directly. This is called only through atexit(), which means die() has already been invoked. So, call exit() here directly. Apparently that works...? */ /* Close standard output, exiting with status 'exit_failure' on failure. If a program writes *anything* to stdout, that program should close stdout and make sure that it succeeds before exiting. Otherwise, suppose that you go to the extreme of checking the return status of every function that does an explicit write to stdout. The last printf can succeed in writing to the internal stream buffer, and yet the fclose(stdout) could still fail (due e.g., to a disk full error) when it tries to write out that buffered data. Thus, you would be left with an incomplete output file and the offending program would exit successfully. Even calling fflush is not always sufficient, since some file systems (NFS and CODA) buffer written/flushed data until an actual close call. Besides, it's wasteful to check the return value from every call that writes to stdout -- just let the internal stream state record the failure. That's what the ferror test is checking below. It's important to detect such failures and exit nonzero because many tools (most notably `make' and other build-management systems) depend on being able to detect failure in other tools via their exit status. */ void close_stdout (void) { int prev_fail = ferror (stdout); int fclose_fail = fclose (stdout); if (prev_fail || fclose_fail) { if (fclose_fail) error (NILF, _("write error: %s"), strerror (errno)); else error (NILF, _("write error")); exit (EXIT_FAILURE); } }