1 /* Job execution and handling for GNU Make.
2 Copyright (C) 1988, 1989, 1990, 1991, 1992, 1993, 1994, 1995, 1996, 1997,
3 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006 Free Software
4 Foundation, Inc.
5 This file is part of GNU Make.
6
7 GNU Make is free software; you can redistribute it and/or modify it under the
8 terms of the GNU General Public License as published by the Free Software
9 Foundation; either version 2, or (at your option) any later version.
10
11 GNU Make is distributed in the hope that it will be useful, but WITHOUT ANY
12 WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
13 A PARTICULAR PURPOSE. See the GNU General Public License for more details.
14
15 You should have received a copy of the GNU General Public License along with
16 GNU Make; see the file COPYING. If not, write to the Free Software
17 Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. */
18
19 #include "make.h"
20
21 #include <assert.h>
22
23 #include "job.h"
24 #include "debug.h"
25 #include "filedef.h"
26 #include "commands.h"
27 #include "variable.h"
28 #include "debug.h"
29
30 #include <string.h>
31
32 /* Default shell to use. */
33 #ifdef WINDOWS32
34 #include <windows.h>
35
36 char *default_shell = "sh.exe";
37 int no_default_sh_exe = 1;
38 int batch_mode_shell = 1;
39 HANDLE main_thread;
40
41 #elif defined (_AMIGA)
42
43 char default_shell[] = "";
44 extern int MyExecute (char **);
45 int batch_mode_shell = 0;
46
47 #elif defined (__MSDOS__)
48
49 /* The default shell is a pointer so we can change it if Makefile
50 says so. It is without an explicit path so we get a chance
51 to search the $PATH for it (since MSDOS doesn't have standard
52 directories we could trust). */
53 char *default_shell = "command.com";
54 int batch_mode_shell = 0;
55
56 #elif defined (__EMX__)
57
58 char *default_shell = "/bin/sh";
59 int batch_mode_shell = 0;
60
61 #elif defined (VMS)
62
63 # include <descrip.h>
64 char default_shell[] = "";
65 int batch_mode_shell = 0;
66
67 #elif defined (__riscos__)
68
69 char default_shell[] = "";
70 int batch_mode_shell = 0;
71
72 #else
73
74 char default_shell[] = "/bin/sh";
75 int batch_mode_shell = 0;
76
77 #endif
78
79 #ifdef __MSDOS__
80 # include <process.h>
81 static int execute_by_shell;
82 static int dos_pid = 123;
83 int dos_status;
84 int dos_command_running;
85 #endif /* __MSDOS__ */
86
87 #ifdef _AMIGA
88 # include <proto/dos.h>
89 static int amiga_pid = 123;
90 static int amiga_status;
91 static char amiga_bname[32];
92 static int amiga_batch_file;
93 #endif /* Amiga. */
94
95 #ifdef VMS
96 # ifndef __GNUC__
97 # include <processes.h>
98 # endif
99 # include <starlet.h>
100 # include <lib$routines.h>
101 static void vmsWaitForChildren PARAMS ((int *));
102 #endif
103
104 #ifdef WINDOWS32
105 # include <windows.h>
106 # include <io.h>
107 # include <process.h>
108 # include "sub_proc.h"
109 # include "w32err.h"
110 # include "pathstuff.h"
111 #endif /* WINDOWS32 */
112
113 #ifdef __EMX__
114 # include <process.h>
115 #endif
116
117 #if defined (HAVE_SYS_WAIT_H) || defined (HAVE_UNION_WAIT)
118 # include <sys/wait.h>
119 #endif
120
121 #ifdef HAVE_WAITPID
122 # define WAIT_NOHANG(status) waitpid (-1, (status), WNOHANG)
123 #else /* Don't have waitpid. */
124 # ifdef HAVE_WAIT3
125 # ifndef wait3
126 extern int wait3 ();
127 # endif
128 # define WAIT_NOHANG(status) wait3 ((status), WNOHANG, (struct rusage *) 0)
129 # endif /* Have wait3. */
130 #endif /* Have waitpid. */
131
132 #if !defined (wait) && !defined (POSIX)
133 extern int wait ();
134 #endif
135
136 #ifndef HAVE_UNION_WAIT
137
138 # define WAIT_T int
139
140 # ifndef WTERMSIG
141 # define WTERMSIG(x) ((x) & 0x7f)
142 # endif
143 # ifndef WCOREDUMP
144 # define WCOREDUMP(x) ((x) & 0x80)
145 # endif
146 # ifndef WEXITSTATUS
147 # define WEXITSTATUS(x) (((x) >> 8) & 0xff)
148 # endif
149 # ifndef WIFSIGNALED
150 # define WIFSIGNALED(x) (WTERMSIG (x) != 0)
151 # endif
152 # ifndef WIFEXITED
153 # define WIFEXITED(x) (WTERMSIG (x) == 0)
154 # endif
155
156 #else /* Have `union wait'. */
157
158 # define WAIT_T union wait
159 # ifndef WTERMSIG
160 # define WTERMSIG(x) ((x).w_termsig)
161 # endif
162 # ifndef WCOREDUMP
163 # define WCOREDUMP(x) ((x).w_coredump)
164 # endif
165 # ifndef WEXITSTATUS
166 # define WEXITSTATUS(x) ((x).w_retcode)
167 # endif
168 # ifndef WIFSIGNALED
169 # define WIFSIGNALED(x) (WTERMSIG(x) != 0)
170 # endif
171 # ifndef WIFEXITED
172 # define WIFEXITED(x) (WTERMSIG(x) == 0)
173 # endif
174
175 #endif /* Don't have `union wait'. */
176
177 #ifndef HAVE_UNISTD_H
178 extern int dup2 ();
179 extern int execve ();
180 extern void _exit ();
181 # ifndef VMS
182 extern int geteuid ();
183 extern int getegid ();
184 extern int setgid ();
185 extern int getgid ();
186 # endif
187 #endif
188
189 extern char *allocated_variable_expand_for_file PARAMS ((char *line, struct file *file));
190
191 extern int getloadavg PARAMS ((double loadavg[], int nelem));
192 extern int start_remote_job PARAMS ((char **argv, char **envp, int stdin_fd,
193 int *is_remote, int *id_ptr, int *used_stdin));
194 extern int start_remote_job_p PARAMS ((int));
195 extern int remote_status PARAMS ((int *exit_code_ptr, int *signal_ptr,
196 int *coredump_ptr, int block));
197
198 RETSIGTYPE child_handler PARAMS ((int));
199 static void free_child PARAMS ((struct child *));
200 static void start_job_command PARAMS ((struct child *child));
201 static int load_too_high PARAMS ((void));
202 static int job_next_command PARAMS ((struct child *));
203 static int start_waiting_job PARAMS ((struct child *));
204
205 /* Chain of all live (or recently deceased) children. */
206
207 struct child *children = 0;
208
209 /* Number of children currently running. */
210
211 unsigned int job_slots_used = 0;
212
213 /* Nonzero if the `good' standard input is in use. */
214
215 static int good_stdin_used = 0;
216
217 /* Chain of children waiting to run until the load average goes down. */
218
219 static struct child *waiting_jobs = 0;
220
221 /* Non-zero if we use a *real* shell (always so on Unix). */
222
223 int unixy_shell = 1;
224
225 /* Number of jobs started in the current second. */
226
227 unsigned long job_counter = 0;
228
229 /* Number of jobserver tokens this instance is currently using. */
230
231 unsigned int jobserver_tokens = 0;
232
233 #ifdef WINDOWS32
234 /*
235 * The macro which references this function is defined in make.h.
236 */
237 int
w32_kill(intptr_t pid,int sig)238 w32_kill(intptr_t pid, int sig)
239 {
240 return ((process_kill((HANDLE)pid, sig) == TRUE) ? 0 : -1);
241 }
242
243 /* This function creates a temporary file name with an extension specified
244 * by the unixy arg.
245 * Return an xmalloc'ed string of a newly created temp file and its
246 * file descriptor, or die. */
247 static char *
create_batch_file(char const * base,int unixy,int * fd)248 create_batch_file (char const *base, int unixy, int *fd)
249 {
250 const char *const ext = unixy ? "sh" : "bat";
251 const char *error = NULL;
252 char temp_path[MAXPATHLEN]; /* need to know its length */
253 unsigned path_size = GetTempPath(sizeof temp_path, temp_path);
254 int path_is_dot = 0;
255 unsigned uniq = 1;
256 const unsigned sizemax = strlen (base) + strlen (ext) + 10;
257
258 if (path_size == 0)
259 {
260 path_size = GetCurrentDirectory (sizeof temp_path, temp_path);
261 path_is_dot = 1;
262 }
263
264 while (path_size > 0 &&
265 path_size + sizemax < sizeof temp_path &&
266 uniq < 0x10000)
267 {
268 unsigned size = sprintf (temp_path + path_size,
269 "%s%s-%x.%s",
270 temp_path[path_size - 1] == '\\' ? "" : "\\",
271 base, uniq, ext);
272 HANDLE h = CreateFile (temp_path, /* file name */
273 GENERIC_READ | GENERIC_WRITE, /* desired access */
274 0, /* no share mode */
275 NULL, /* default security attributes */
276 CREATE_NEW, /* creation disposition */
277 FILE_ATTRIBUTE_NORMAL | /* flags and attributes */
278 FILE_ATTRIBUTE_TEMPORARY, /* we'll delete it */
279 NULL); /* no template file */
280
281 if (h == INVALID_HANDLE_VALUE)
282 {
283 const DWORD er = GetLastError();
284
285 if (er == ERROR_FILE_EXISTS || er == ERROR_ALREADY_EXISTS)
286 ++uniq;
287
288 /* the temporary path is not guaranteed to exist */
289 else if (path_is_dot == 0)
290 {
291 path_size = GetCurrentDirectory (sizeof temp_path, temp_path);
292 path_is_dot = 1;
293 }
294
295 else
296 {
297 error = map_windows32_error_to_string (er);
298 break;
299 }
300 }
301 else
302 {
303 const unsigned final_size = path_size + size + 1;
304 char *const path = (char *) xmalloc (final_size);
305 memcpy (path, temp_path, final_size);
306 *fd = _open_osfhandle ((intptr_t)h, 0);
307 if (unixy)
308 {
309 char *p;
310 int ch;
311 for (p = path; (ch = *p) != 0; ++p)
312 if (ch == '\\')
313 *p = '/';
314 }
315 return path; /* good return */
316 }
317 }
318
319 *fd = -1;
320 if (error == NULL)
321 error = _("Cannot create a temporary file\n");
322 fatal (NILF, error);
323
324 /* not reached */
325 return NULL;
326 }
327 #endif /* WINDOWS32 */
328
329 #ifdef __EMX__
330 /* returns whether path is assumed to be a unix like shell. */
331 int
_is_unixy_shell(const char * path)332 _is_unixy_shell (const char *path)
333 {
334 /* list of non unix shells */
335 const char *known_os2shells[] = {
336 "cmd.exe",
337 "cmd",
338 "4os2.exe",
339 "4os2",
340 "4dos.exe",
341 "4dos",
342 "command.com",
343 "command",
344 NULL
345 };
346
347 /* find the rightmost '/' or '\\' */
348 const char *name = strrchr (path, '/');
349 const char *p = strrchr (path, '\\');
350 unsigned i;
351
352 if (name && p) /* take the max */
353 name = (name > p) ? name : p;
354 else if (p) /* name must be 0 */
355 name = p;
356 else if (!name) /* name and p must be 0 */
357 name = path;
358
359 if (*name == '/' || *name == '\\') name++;
360
361 i = 0;
362 while (known_os2shells[i] != NULL) {
363 if (stricmp (name, known_os2shells[i]) == 0) /* strcasecmp() */
364 return 0; /* not a unix shell */
365 i++;
366 }
367
368 /* in doubt assume a unix like shell */
369 return 1;
370 }
371 #endif /* __EMX__ */
372
373
374 /* Write an error message describing the exit status given in
375 EXIT_CODE, EXIT_SIG, and COREDUMP, for the target TARGET_NAME.
376 Append "(ignored)" if IGNORED is nonzero. */
377
378 static void
child_error(char * target_name,int exit_code,int exit_sig,int coredump,int ignored)379 child_error (char *target_name, int exit_code, int exit_sig, int coredump,
380 int ignored)
381 {
382 if (ignored && silent_flag)
383 return;
384
385 #ifdef VMS
386 if (!(exit_code & 1))
387 error (NILF,
388 (ignored ? _("*** [%s] Error 0x%x (ignored)")
389 : _("*** [%s] Error 0x%x")),
390 target_name, exit_code);
391 #else
392 if (exit_sig == 0)
393 error (NILF, ignored ? _("[%s] Error %d (ignored)") :
394 _("*** [%s] Error %d"),
395 target_name, exit_code);
396 else
397 error (NILF, "*** [%s] %s%s",
398 target_name, strsignal (exit_sig),
399 coredump ? _(" (core dumped)") : "");
400 #endif /* VMS */
401 }
402
403
404 /* Handle a dead child. This handler may or may not ever be installed.
405
406 If we're using the jobserver feature, we need it. First, installing it
407 ensures the read will interrupt on SIGCHLD. Second, we close the dup'd
408 read FD to ensure we don't enter another blocking read without reaping all
409 the dead children. In this case we don't need the dead_children count.
410
411 If we don't have either waitpid or wait3, then make is unreliable, but we
412 use the dead_children count to reap children as best we can. */
413
414 static unsigned int dead_children = 0;
415
416 RETSIGTYPE
child_handler(int sig UNUSED)417 child_handler (int sig UNUSED)
418 {
419 ++dead_children;
420
421 if (job_rfd >= 0)
422 {
423 close (job_rfd);
424 job_rfd = -1;
425 }
426
427 #ifdef __EMX__
428 /* The signal handler must called only once! */
429 signal (SIGCHLD, SIG_DFL);
430 #endif
431
432 /* This causes problems if the SIGCHLD interrupts a printf().
433 DB (DB_JOBS, (_("Got a SIGCHLD; %u unreaped children.\n"), dead_children));
434 */
435 }
436
437 extern int shell_function_pid, shell_function_completed;
438
439 /* Reap all dead children, storing the returned status and the new command
440 state (`cs_finished') in the `file' member of the `struct child' for the
441 dead child, and removing the child from the chain. In addition, if BLOCK
442 nonzero, we block in this function until we've reaped at least one
443 complete child, waiting for it to die if necessary. If ERR is nonzero,
444 print an error message first. */
445
446 void
reap_children(int block,int err)447 reap_children (int block, int err)
448 {
449 #ifndef WINDOWS32
450 WAIT_T status;
451 /* Initially, assume we have some. */
452 int reap_more = 1;
453 #endif
454
455 #ifdef WAIT_NOHANG
456 # define REAP_MORE reap_more
457 #else
458 # define REAP_MORE dead_children
459 #endif
460
461 /* As long as:
462
463 We have at least one child outstanding OR a shell function in progress,
464 AND
465 We're blocking for a complete child OR there are more children to reap
466
467 we'll keep reaping children. */
468
469 while ((children != 0 || shell_function_pid != 0)
470 && (block || REAP_MORE))
471 {
472 int remote = 0;
473 pid_t pid;
474 int exit_code, exit_sig, coredump;
475 register struct child *lastc, *c;
476 int child_failed;
477 int any_remote, any_local;
478 int dontcare;
479
480 if (err && block)
481 {
482 static int printed = 0;
483
484 /* We might block for a while, so let the user know why.
485 Only print this message once no matter how many jobs are left. */
486 fflush (stdout);
487 if (!printed)
488 error (NILF, _("*** Waiting for unfinished jobs...."));
489 printed = 1;
490 }
491
492 /* We have one less dead child to reap. As noted in
493 child_handler() above, this count is completely unimportant for
494 all modern, POSIX-y systems that support wait3() or waitpid().
495 The rest of this comment below applies only to early, broken
496 pre-POSIX systems. We keep the count only because... it's there...
497
498 The test and decrement are not atomic; if it is compiled into:
499 register = dead_children - 1;
500 dead_children = register;
501 a SIGCHLD could come between the two instructions.
502 child_handler increments dead_children.
503 The second instruction here would lose that increment. But the
504 only effect of dead_children being wrong is that we might wait
505 longer than necessary to reap a child, and lose some parallelism;
506 and we might print the "Waiting for unfinished jobs" message above
507 when not necessary. */
508
509 if (dead_children > 0)
510 --dead_children;
511
512 any_remote = 0;
513 any_local = shell_function_pid != 0;
514 for (c = children; c != 0; c = c->next)
515 {
516 any_remote |= c->remote;
517 any_local |= ! c->remote;
518 DB (DB_JOBS, (_("Live child %p (%s) PID %ld %s\n"),
519 c, c->file->name,
520 (long) c->pid, c->remote ? _(" (remote)") : ""));
521 #ifdef VMS
522 break;
523 #endif
524 }
525
526 /* First, check for remote children. */
527 if (any_remote)
528 pid = remote_status (&exit_code, &exit_sig, &coredump, 0);
529 else
530 pid = 0;
531
532 if (pid > 0)
533 /* We got a remote child. */
534 remote = 1;
535 else if (pid < 0)
536 {
537 /* A remote status command failed miserably. Punt. */
538 remote_status_lose:
539 pfatal_with_name ("remote_status");
540 }
541 else
542 {
543 /* No remote children. Check for local children. */
544 #if !defined(__MSDOS__) && !defined(_AMIGA) && !defined(WINDOWS32)
545 if (any_local)
546 {
547 #ifdef VMS
548 vmsWaitForChildren (&status);
549 pid = c->pid;
550 #else
551 #ifdef WAIT_NOHANG
552 if (!block)
553 pid = WAIT_NOHANG (&status);
554 else
555 #endif
556 pid = wait (&status);
557 #endif /* !VMS */
558 }
559 else
560 pid = 0;
561
562 if (pid < 0)
563 {
564 /* The wait*() failed miserably. Punt. */
565 pfatal_with_name ("wait");
566 }
567 else if (pid > 0)
568 {
569 /* We got a child exit; chop the status word up. */
570 exit_code = WEXITSTATUS (status);
571 exit_sig = WIFSIGNALED (status) ? WTERMSIG (status) : 0;
572 coredump = WCOREDUMP (status);
573
574 /* If we have started jobs in this second, remove one. */
575 if (job_counter)
576 --job_counter;
577 }
578 else
579 {
580 /* No local children are dead. */
581 reap_more = 0;
582
583 if (!block || !any_remote)
584 break;
585
586 /* Now try a blocking wait for a remote child. */
587 pid = remote_status (&exit_code, &exit_sig, &coredump, 1);
588 if (pid < 0)
589 goto remote_status_lose;
590 else if (pid == 0)
591 /* No remote children either. Finally give up. */
592 break;
593
594 /* We got a remote child. */
595 remote = 1;
596 }
597 #endif /* !__MSDOS__, !Amiga, !WINDOWS32. */
598
599 #ifdef __MSDOS__
600 /* Life is very different on MSDOS. */
601 pid = dos_pid - 1;
602 status = dos_status;
603 exit_code = WEXITSTATUS (status);
604 if (exit_code == 0xff)
605 exit_code = -1;
606 exit_sig = WIFSIGNALED (status) ? WTERMSIG (status) : 0;
607 coredump = 0;
608 #endif /* __MSDOS__ */
609 #ifdef _AMIGA
610 /* Same on Amiga */
611 pid = amiga_pid - 1;
612 status = amiga_status;
613 exit_code = amiga_status;
614 exit_sig = 0;
615 coredump = 0;
616 #endif /* _AMIGA */
617 #ifdef WINDOWS32
618 {
619 HANDLE hPID;
620 int werr;
621 HANDLE hcTID, hcPID;
622 exit_code = 0;
623 exit_sig = 0;
624 coredump = 0;
625
626 /* Record the thread ID of the main process, so that we
627 could suspend it in the signal handler. */
628 if (!main_thread)
629 {
630 hcTID = GetCurrentThread ();
631 hcPID = GetCurrentProcess ();
632 if (!DuplicateHandle (hcPID, hcTID, hcPID, &main_thread, 0,
633 FALSE, DUPLICATE_SAME_ACCESS))
634 {
635 DWORD e = GetLastError ();
636 fprintf (stderr,
637 "Determine main thread ID (Error %ld: %s)\n",
638 e, map_windows32_error_to_string(e));
639 }
640 else
641 DB (DB_VERBOSE, ("Main thread handle = %p\n",
642 main_thread));
643 }
644
645 /* wait for anything to finish */
646 hPID = process_wait_for_any();
647 if (hPID)
648 {
649
650 /* was an error found on this process? */
651 werr = process_last_err(hPID);
652
653 /* get exit data */
654 exit_code = process_exit_code(hPID);
655
656 if (werr)
657 fprintf(stderr, "make (e=%d): %s",
658 exit_code, map_windows32_error_to_string(exit_code));
659
660 /* signal */
661 exit_sig = process_signal(hPID);
662
663 /* cleanup process */
664 process_cleanup(hPID);
665
666 coredump = 0;
667 }
668 pid = (pid_t) hPID;
669 }
670 #endif /* WINDOWS32 */
671 }
672
673 /* Check if this is the child of the `shell' function. */
674 if (!remote && pid == shell_function_pid)
675 {
676 /* It is. Leave an indicator for the `shell' function. */
677 if (exit_sig == 0 && exit_code == 127)
678 shell_function_completed = -1;
679 else
680 shell_function_completed = 1;
681 break;
682 }
683
684 child_failed = exit_sig != 0 || exit_code != 0;
685
686 /* Search for a child matching the deceased one. */
687 lastc = 0;
688 for (c = children; c != 0; lastc = c, c = c->next)
689 if (c->remote == remote && c->pid == pid)
690 break;
691
692 if (c == 0)
693 /* An unknown child died.
694 Ignore it; it was inherited from our invoker. */
695 continue;
696
697 DB (DB_JOBS, (child_failed
698 ? _("Reaping losing child %p PID %ld %s\n")
699 : _("Reaping winning child 0x%08lx PID %ld %s\n"),
700 c, (long) c->pid,
701 c->remote ? _(" (remote)") : ""));
702
703 if (c->sh_batch_file) {
704 DB (DB_JOBS, (_("Cleaning up temp batch file %s\n"),
705 c->sh_batch_file));
706
707 /* just try and remove, don't care if this fails */
708 remove (c->sh_batch_file);
709
710 /* all done with memory */
711 free (c->sh_batch_file);
712 c->sh_batch_file = NULL;
713 }
714
715 /* If this child had the good stdin, say it is now free. */
716 if (c->good_stdin)
717 good_stdin_used = 0;
718
719 dontcare = c->dontcare;
720
721 if (child_failed && !c->noerror && !ignore_errors_flag)
722 {
723 /* The commands failed. Write an error message,
724 delete non-precious targets, and abort. */
725 static int delete_on_error = -1;
726
727 if (!dontcare)
728 child_error (c->file->name, exit_code, exit_sig, coredump, 0);
729
730 c->file->update_status = 2;
731 if (delete_on_error == -1)
732 {
733 struct file *f = lookup_file (".DELETE_ON_ERROR");
734 delete_on_error = f != 0 && f->is_target;
735 }
736 if (exit_sig != 0 || delete_on_error)
737 delete_child_targets (c);
738 }
739 else
740 {
741 if (child_failed)
742 {
743 /* The commands failed, but we don't care. */
744 child_error (c->file->name,
745 exit_code, exit_sig, coredump, 1);
746 child_failed = 0;
747 }
748
749 /* If there are more commands to run, try to start them. */
750 if (job_next_command (c))
751 {
752 if (handling_fatal_signal)
753 {
754 /* Never start new commands while we are dying.
755 Since there are more commands that wanted to be run,
756 the target was not completely remade. So we treat
757 this as if a command had failed. */
758 c->file->update_status = 2;
759 }
760 else
761 {
762 /* Check again whether to start remotely.
763 Whether or not we want to changes over time.
764 Also, start_remote_job may need state set up
765 by start_remote_job_p. */
766 c->remote = start_remote_job_p (0);
767 start_job_command (c);
768 /* Fatal signals are left blocked in case we were
769 about to put that child on the chain. But it is
770 already there, so it is safe for a fatal signal to
771 arrive now; it will clean up this child's targets. */
772 unblock_sigs ();
773 if (c->file->command_state == cs_running)
774 /* We successfully started the new command.
775 Loop to reap more children. */
776 continue;
777 }
778
779 if (c->file->update_status != 0)
780 /* We failed to start the commands. */
781 delete_child_targets (c);
782 }
783 else
784 /* There are no more commands. We got through them all
785 without an unignored error. Now the target has been
786 successfully updated. */
787 c->file->update_status = 0;
788 }
789
790 /* When we get here, all the commands for C->file are finished
791 (or aborted) and C->file->update_status contains 0 or 2. But
792 C->file->command_state is still cs_running if all the commands
793 ran; notice_finish_file looks for cs_running to tell it that
794 it's interesting to check the file's modtime again now. */
795
796 if (! handling_fatal_signal)
797 /* Notice if the target of the commands has been changed.
798 This also propagates its values for command_state and
799 update_status to its also_make files. */
800 notice_finished_file (c->file);
801
802 DB (DB_JOBS, (_("Removing child %p PID %ld%s from chain.\n"),
803 c, (long) c->pid,
804 c->remote ? _(" (remote)") : ""));
805
806 /* Block fatal signals while frobnicating the list, so that
807 children and job_slots_used are always consistent. Otherwise
808 a fatal signal arriving after the child is off the chain and
809 before job_slots_used is decremented would believe a child was
810 live and call reap_children again. */
811 block_sigs ();
812
813 /* There is now another slot open. */
814 if (job_slots_used > 0)
815 --job_slots_used;
816
817 /* Remove the child from the chain and free it. */
818 if (lastc == 0)
819 children = c->next;
820 else
821 lastc->next = c->next;
822
823 free_child (c);
824
825 unblock_sigs ();
826
827 /* If the job failed, and the -k flag was not given, die,
828 unless we are already in the process of dying. */
829 if (!err && child_failed && !dontcare && !keep_going_flag &&
830 /* fatal_error_signal will die with the right signal. */
831 !handling_fatal_signal)
832 die (2);
833
834 /* Only block for one child. */
835 block = 0;
836 }
837
838 return;
839 }
840
841 /* Free the storage allocated for CHILD. */
842
843 static void
free_child(struct child * child)844 free_child (struct child *child)
845 {
846 if (!jobserver_tokens)
847 fatal (NILF, "INTERNAL: Freeing child %p (%s) but no tokens left!\n",
848 child, child->file->name);
849
850 /* If we're using the jobserver and this child is not the only outstanding
851 job, put a token back into the pipe for it. */
852
853 if (job_fds[1] >= 0 && jobserver_tokens > 1)
854 {
855 char token = '+';
856 int r;
857
858 /* Write a job token back to the pipe. */
859
860 EINTRLOOP (r, write (job_fds[1], &token, 1));
861 if (r != 1)
862 pfatal_with_name (_("write jobserver"));
863
864 DB (DB_JOBS, (_("Released token for child %p (%s).\n"),
865 child, child->file->name));
866 }
867
868 --jobserver_tokens;
869
870 if (handling_fatal_signal) /* Don't bother free'ing if about to die. */
871 return;
872
873 if (child->command_lines != 0)
874 {
875 register unsigned int i;
876 for (i = 0; i < child->file->cmds->ncommand_lines; ++i)
877 free (child->command_lines[i]);
878 free ((char *) child->command_lines);
879 }
880
881 if (child->environment != 0)
882 {
883 register char **ep = child->environment;
884 while (*ep != 0)
885 free (*ep++);
886 free ((char *) child->environment);
887 }
888
889 free ((char *) child);
890 }
891
892 #ifdef POSIX
893 extern sigset_t fatal_signal_set;
894 #endif
895
896 void
block_sigs(void)897 block_sigs (void)
898 {
899 #ifdef POSIX
900 (void) sigprocmask (SIG_BLOCK, &fatal_signal_set, (sigset_t *) 0);
901 #else
902 # ifdef HAVE_SIGSETMASK
903 (void) sigblock (fatal_signal_mask);
904 # endif
905 #endif
906 }
907
908 #ifdef POSIX
909 void
unblock_sigs(void)910 unblock_sigs (void)
911 {
912 sigset_t empty;
913 sigemptyset (&empty);
914 sigprocmask (SIG_SETMASK, &empty, (sigset_t *) 0);
915 }
916 #endif
917
918 #ifdef MAKE_JOBSERVER
919 RETSIGTYPE
job_noop(int sig UNUSED)920 job_noop (int sig UNUSED)
921 {
922 }
923 /* Set the child handler action flags to FLAGS. */
924 static void
set_child_handler_action_flags(int set_handler,int set_alarm)925 set_child_handler_action_flags (int set_handler, int set_alarm)
926 {
927 struct sigaction sa;
928
929 #ifdef __EMX__
930 /* The child handler must be turned off here. */
931 signal (SIGCHLD, SIG_DFL);
932 #endif
933
934 bzero ((char *) &sa, sizeof sa);
935 sa.sa_handler = child_handler;
936 sa.sa_flags = set_handler ? 0 : SA_RESTART;
937 #if defined SIGCHLD
938 sigaction (SIGCHLD, &sa, NULL);
939 #endif
940 #if defined SIGCLD && SIGCLD != SIGCHLD
941 sigaction (SIGCLD, &sa, NULL);
942 #endif
943 #if defined SIGALRM
944 if (set_alarm)
945 {
946 /* If we're about to enter the read(), set an alarm to wake up in a
947 second so we can check if the load has dropped and we can start more
948 work. On the way out, turn off the alarm and set SIG_DFL. */
949 alarm (set_handler ? 1 : 0);
950 sa.sa_handler = set_handler ? job_noop : SIG_DFL;
951 sa.sa_flags = 0;
952 sigaction (SIGALRM, &sa, NULL);
953 }
954 #endif
955 }
956 #endif
957
958
959 /* Start a job to run the commands specified in CHILD.
960 CHILD is updated to reflect the commands and ID of the child process.
961
962 NOTE: On return fatal signals are blocked! The caller is responsible
963 for calling `unblock_sigs', once the new child is safely on the chain so
964 it can be cleaned up in the event of a fatal signal. */
965
966 static void
start_job_command(struct child * child)967 start_job_command (struct child *child)
968 {
969 #if !defined(_AMIGA) && !defined(WINDOWS32)
970 static int bad_stdin = -1;
971 #endif
972 register char *p;
973 int flags;
974 #ifdef VMS
975 char *argv;
976 #else
977 char **argv;
978 #endif
979
980 /* If we have a completely empty commandset, stop now. */
981 if (!child->command_ptr)
982 goto next_command;
983
984 /* Combine the flags parsed for the line itself with
985 the flags specified globally for this target. */
986 flags = (child->file->command_flags
987 | child->file->cmds->lines_flags[child->command_line - 1]);
988
989 p = child->command_ptr;
990 child->noerror = ((flags & COMMANDS_NOERROR) != 0);
991
992 while (*p != '\0')
993 {
994 if (*p == '@')
995 flags |= COMMANDS_SILENT;
996 else if (*p == '+')
997 flags |= COMMANDS_RECURSE;
998 else if (*p == '-')
999 child->noerror = 1;
1000 else if (!isblank ((unsigned char)*p))
1001 break;
1002 ++p;
1003 }
1004
1005 /* Update the file's command flags with any new ones we found. We only
1006 keep the COMMANDS_RECURSE setting. Even this isn't 100% correct; we are
1007 now marking more commands recursive than should be in the case of
1008 multiline define/endef scripts where only one line is marked "+". In
1009 order to really fix this, we'll have to keep a lines_flags for every
1010 actual line, after expansion. */
1011 child->file->cmds->lines_flags[child->command_line - 1]
1012 |= flags & COMMANDS_RECURSE;
1013
1014 /* Figure out an argument list from this command line. */
1015
1016 {
1017 char *end = 0;
1018 #ifdef VMS
1019 argv = p;
1020 #else
1021 argv = construct_command_argv (p, &end, child->file, &child->sh_batch_file);
1022 #endif
1023 if (end == NULL)
1024 child->command_ptr = NULL;
1025 else
1026 {
1027 *end++ = '\0';
1028 child->command_ptr = end;
1029 }
1030 }
1031
1032 /* If -q was given, say that updating `failed' if there was any text on the
1033 command line, or `succeeded' otherwise. The exit status of 1 tells the
1034 user that -q is saying `something to do'; the exit status for a random
1035 error is 2. */
1036 if (argv != 0 && question_flag && !(flags & COMMANDS_RECURSE))
1037 {
1038 #ifndef VMS
1039 free (argv[0]);
1040 free ((char *) argv);
1041 #endif
1042 child->file->update_status = 1;
1043 notice_finished_file (child->file);
1044 return;
1045 }
1046
1047 if (touch_flag && !(flags & COMMANDS_RECURSE))
1048 {
1049 /* Go on to the next command. It might be the recursive one.
1050 We construct ARGV only to find the end of the command line. */
1051 #ifndef VMS
1052 if (argv)
1053 {
1054 free (argv[0]);
1055 free ((char *) argv);
1056 }
1057 #endif
1058 argv = 0;
1059 }
1060
1061 if (argv == 0)
1062 {
1063 next_command:
1064 #ifdef __MSDOS__
1065 execute_by_shell = 0; /* in case construct_command_argv sets it */
1066 #endif
1067 /* This line has no commands. Go to the next. */
1068 if (job_next_command (child))
1069 start_job_command (child);
1070 else
1071 {
1072 /* No more commands. Make sure we're "running"; we might not be if
1073 (e.g.) all commands were skipped due to -n. */
1074 set_command_state (child->file, cs_running);
1075 child->file->update_status = 0;
1076 notice_finished_file (child->file);
1077 }
1078 return;
1079 }
1080
1081 /* Print out the command. If silent, we call `message' with null so it
1082 can log the working directory before the command's own error messages
1083 appear. */
1084
1085 message (0, (just_print_flag || (!(flags & COMMANDS_SILENT) && !silent_flag))
1086 ? "%s" : (char *) 0, p);
1087
1088 /* Tell update_goal_chain that a command has been started on behalf of
1089 this target. It is important that this happens here and not in
1090 reap_children (where we used to do it), because reap_children might be
1091 reaping children from a different target. We want this increment to
1092 guaranteedly indicate that a command was started for the dependency
1093 chain (i.e., update_file recursion chain) we are processing. */
1094
1095 ++commands_started;
1096
1097 /* Optimize an empty command. People use this for timestamp rules,
1098 so avoid forking a useless shell. Do this after we increment
1099 commands_started so make still treats this special case as if it
1100 performed some action (makes a difference as to what messages are
1101 printed, etc. */
1102
1103 #if !defined(VMS) && !defined(_AMIGA)
1104 if (
1105 #if defined __MSDOS__ || defined (__EMX__)
1106 unixy_shell /* the test is complicated and we already did it */
1107 #else
1108 (argv[0] && !strcmp (argv[0], "/bin/sh"))
1109 #endif
1110 && (argv[1]
1111 && argv[1][0] == '-' && argv[1][1] == 'c' && argv[1][2] == '\0')
1112 && (argv[2] && argv[2][0] == ':' && argv[2][1] == '\0')
1113 && argv[3] == NULL)
1114 {
1115 free (argv[0]);
1116 free ((char *) argv);
1117 goto next_command;
1118 }
1119 #endif /* !VMS && !_AMIGA */
1120
1121 /* If -n was given, recurse to get the next line in the sequence. */
1122
1123 if (just_print_flag && !(flags & COMMANDS_RECURSE))
1124 {
1125 #ifndef VMS
1126 free (argv[0]);
1127 free ((char *) argv);
1128 #endif
1129 goto next_command;
1130 }
1131
1132 /* Flush the output streams so they won't have things written twice. */
1133
1134 fflush (stdout);
1135 fflush (stderr);
1136
1137 #ifndef VMS
1138 #if !defined(WINDOWS32) && !defined(_AMIGA) && !defined(__MSDOS__)
1139
1140 /* Set up a bad standard input that reads from a broken pipe. */
1141
1142 if (bad_stdin == -1)
1143 {
1144 /* Make a file descriptor that is the read end of a broken pipe.
1145 This will be used for some children's standard inputs. */
1146 int pd[2];
1147 if (pipe (pd) == 0)
1148 {
1149 /* Close the write side. */
1150 (void) close (pd[1]);
1151 /* Save the read side. */
1152 bad_stdin = pd[0];
1153
1154 /* Set the descriptor to close on exec, so it does not litter any
1155 child's descriptor table. When it is dup2'd onto descriptor 0,
1156 that descriptor will not close on exec. */
1157 CLOSE_ON_EXEC (bad_stdin);
1158 }
1159 }
1160
1161 #endif /* !WINDOWS32 && !_AMIGA && !__MSDOS__ */
1162
1163 /* Decide whether to give this child the `good' standard input
1164 (one that points to the terminal or whatever), or the `bad' one
1165 that points to the read side of a broken pipe. */
1166
1167 child->good_stdin = !good_stdin_used;
1168 if (child->good_stdin)
1169 good_stdin_used = 1;
1170
1171 #endif /* !VMS */
1172
1173 child->deleted = 0;
1174
1175 #ifndef _AMIGA
1176 /* Set up the environment for the child. */
1177 if (child->environment == 0)
1178 child->environment = target_environment (child->file);
1179 #endif
1180
1181 #if !defined(__MSDOS__) && !defined(_AMIGA) && !defined(WINDOWS32)
1182
1183 #ifndef VMS
1184 /* start_waiting_job has set CHILD->remote if we can start a remote job. */
1185 if (child->remote)
1186 {
1187 int is_remote, id, used_stdin;
1188 if (start_remote_job (argv, child->environment,
1189 child->good_stdin ? 0 : bad_stdin,
1190 &is_remote, &id, &used_stdin))
1191 /* Don't give up; remote execution may fail for various reasons. If
1192 so, simply run the job locally. */
1193 goto run_local;
1194 else
1195 {
1196 if (child->good_stdin && !used_stdin)
1197 {
1198 child->good_stdin = 0;
1199 good_stdin_used = 0;
1200 }
1201 child->remote = is_remote;
1202 child->pid = id;
1203 }
1204 }
1205 else
1206 #endif /* !VMS */
1207 {
1208 /* Fork the child process. */
1209
1210 char **parent_environ;
1211
1212 run_local:
1213 block_sigs ();
1214
1215 child->remote = 0;
1216
1217 #ifdef VMS
1218 if (!child_execute_job (argv, child)) {
1219 /* Fork failed! */
1220 perror_with_name ("vfork", "");
1221 goto error;
1222 }
1223
1224 #else
1225
1226 parent_environ = environ;
1227
1228 # ifdef __EMX__
1229 /* If we aren't running a recursive command and we have a jobserver
1230 pipe, close it before exec'ing. */
1231 if (!(flags & COMMANDS_RECURSE) && job_fds[0] >= 0)
1232 {
1233 CLOSE_ON_EXEC (job_fds[0]);
1234 CLOSE_ON_EXEC (job_fds[1]);
1235 }
1236 if (job_rfd >= 0)
1237 CLOSE_ON_EXEC (job_rfd);
1238
1239 /* Never use fork()/exec() here! Use spawn() instead in exec_command() */
1240 child->pid = child_execute_job (child->good_stdin ? 0 : bad_stdin, 1,
1241 argv, child->environment);
1242 if (child->pid < 0)
1243 {
1244 /* spawn failed! */
1245 unblock_sigs ();
1246 perror_with_name ("spawn", "");
1247 goto error;
1248 }
1249
1250 /* undo CLOSE_ON_EXEC() after the child process has been started */
1251 if (!(flags & COMMANDS_RECURSE) && job_fds[0] >= 0)
1252 {
1253 fcntl (job_fds[0], F_SETFD, 0);
1254 fcntl (job_fds[1], F_SETFD, 0);
1255 }
1256 if (job_rfd >= 0)
1257 fcntl (job_rfd, F_SETFD, 0);
1258
1259 #else /* !__EMX__ */
1260
1261 child->pid = vfork ();
1262 environ = parent_environ; /* Restore value child may have clobbered. */
1263 if (child->pid == 0)
1264 {
1265 /* We are the child side. */
1266 unblock_sigs ();
1267
1268 /* If we aren't running a recursive command and we have a jobserver
1269 pipe, close it before exec'ing. */
1270 if (!(flags & COMMANDS_RECURSE) && job_fds[0] >= 0)
1271 {
1272 close (job_fds[0]);
1273 close (job_fds[1]);
1274 }
1275 if (job_rfd >= 0)
1276 close (job_rfd);
1277
1278 child_execute_job (child->good_stdin ? 0 : bad_stdin, 1,
1279 argv, child->environment);
1280 }
1281 else if (child->pid < 0)
1282 {
1283 /* Fork failed! */
1284 unblock_sigs ();
1285 perror_with_name ("vfork", "");
1286 goto error;
1287 }
1288 # endif /* !__EMX__ */
1289 #endif /* !VMS */
1290 }
1291
1292 #else /* __MSDOS__ or Amiga or WINDOWS32 */
1293 #ifdef __MSDOS__
1294 {
1295 int proc_return;
1296
1297 block_sigs ();
1298 dos_status = 0;
1299
1300 /* We call `system' to do the job of the SHELL, since stock DOS
1301 shell is too dumb. Our `system' knows how to handle long
1302 command lines even if pipes/redirection is needed; it will only
1303 call COMMAND.COM when its internal commands are used. */
1304 if (execute_by_shell)
1305 {
1306 char *cmdline = argv[0];
1307 /* We don't have a way to pass environment to `system',
1308 so we need to save and restore ours, sigh... */
1309 char **parent_environ = environ;
1310
1311 environ = child->environment;
1312
1313 /* If we have a *real* shell, tell `system' to call
1314 it to do everything for us. */
1315 if (unixy_shell)
1316 {
1317 /* A *real* shell on MSDOS may not support long
1318 command lines the DJGPP way, so we must use `system'. */
1319 cmdline = argv[2]; /* get past "shell -c" */
1320 }
1321
1322 dos_command_running = 1;
1323 proc_return = system (cmdline);
1324 environ = parent_environ;
1325 execute_by_shell = 0; /* for the next time */
1326 }
1327 else
1328 {
1329 dos_command_running = 1;
1330 proc_return = spawnvpe (P_WAIT, argv[0], argv, child->environment);
1331 }
1332
1333 /* Need to unblock signals before turning off
1334 dos_command_running, so that child's signals
1335 will be treated as such (see fatal_error_signal). */
1336 unblock_sigs ();
1337 dos_command_running = 0;
1338
1339 /* If the child got a signal, dos_status has its
1340 high 8 bits set, so be careful not to alter them. */
1341 if (proc_return == -1)
1342 dos_status |= 0xff;
1343 else
1344 dos_status |= (proc_return & 0xff);
1345 ++dead_children;
1346 child->pid = dos_pid++;
1347 }
1348 #endif /* __MSDOS__ */
1349 #ifdef _AMIGA
1350 amiga_status = MyExecute (argv);
1351
1352 ++dead_children;
1353 child->pid = amiga_pid++;
1354 if (amiga_batch_file)
1355 {
1356 amiga_batch_file = 0;
1357 DeleteFile (amiga_bname); /* Ignore errors. */
1358 }
1359 #endif /* Amiga */
1360 #ifdef WINDOWS32
1361 {
1362 HANDLE hPID;
1363 char* arg0;
1364
1365 /* make UNC paths safe for CreateProcess -- backslash format */
1366 arg0 = argv[0];
1367 if (arg0 && arg0[0] == '/' && arg0[1] == '/')
1368 for ( ; arg0 && *arg0; arg0++)
1369 if (*arg0 == '/')
1370 *arg0 = '\\';
1371
1372 /* make sure CreateProcess() has Path it needs */
1373 sync_Path_environment();
1374
1375 hPID = process_easy(argv, child->environment);
1376
1377 if (hPID != INVALID_HANDLE_VALUE)
1378 child->pid = (intptr_t) hPID;
1379 else {
1380 int i;
1381 unblock_sigs();
1382 fprintf(stderr,
1383 _("process_easy() failed to launch process (e=%ld)\n"),
1384 process_last_err(hPID));
1385 for (i = 0; argv[i]; i++)
1386 fprintf(stderr, "%s ", argv[i]);
1387 fprintf(stderr, _("\nCounted %d args in failed launch\n"), i);
1388 goto error;
1389 }
1390 }
1391 #endif /* WINDOWS32 */
1392 #endif /* __MSDOS__ or Amiga or WINDOWS32 */
1393
1394 /* Bump the number of jobs started in this second. */
1395 ++job_counter;
1396
1397 /* We are the parent side. Set the state to
1398 say the commands are running and return. */
1399
1400 set_command_state (child->file, cs_running);
1401
1402 /* Free the storage used by the child's argument list. */
1403 #ifndef VMS
1404 free (argv[0]);
1405 free ((char *) argv);
1406 #endif
1407
1408 return;
1409
1410 error:
1411 child->file->update_status = 2;
1412 notice_finished_file (child->file);
1413 return;
1414 }
1415
1416 /* Try to start a child running.
1417 Returns nonzero if the child was started (and maybe finished), or zero if
1418 the load was too high and the child was put on the `waiting_jobs' chain. */
1419
1420 static int
start_waiting_job(struct child * c)1421 start_waiting_job (struct child *c)
1422 {
1423 struct file *f = c->file;
1424
1425 /* If we can start a job remotely, we always want to, and don't care about
1426 the local load average. We record that the job should be started
1427 remotely in C->remote for start_job_command to test. */
1428
1429 c->remote = start_remote_job_p (1);
1430
1431 /* If we are running at least one job already and the load average
1432 is too high, make this one wait. */
1433 if (!c->remote
1434 && ((job_slots_used > 0 && load_too_high ())
1435 #ifdef WINDOWS32
1436 || (process_used_slots () >= MAXIMUM_WAIT_OBJECTS)
1437 #endif
1438 ))
1439 {
1440 /* Put this child on the chain of children waiting for the load average
1441 to go down. */
1442 set_command_state (f, cs_running);
1443 c->next = waiting_jobs;
1444 waiting_jobs = c;
1445 return 0;
1446 }
1447
1448 /* Start the first command; reap_children will run later command lines. */
1449 start_job_command (c);
1450
1451 switch (f->command_state)
1452 {
1453 case cs_running:
1454 c->next = children;
1455 DB (DB_JOBS, (_("Putting child %p (%s) PID %ld%s on the chain.\n"),
1456 c, c->file->name,
1457 (long) c->pid, c->remote ? _(" (remote)") : ""));
1458 children = c;
1459 /* One more job slot is in use. */
1460 ++job_slots_used;
1461 unblock_sigs ();
1462 break;
1463
1464 case cs_not_started:
1465 /* All the command lines turned out to be empty. */
1466 f->update_status = 0;
1467 /* FALLTHROUGH */
1468
1469 case cs_finished:
1470 notice_finished_file (f);
1471 free_child (c);
1472 break;
1473
1474 default:
1475 assert (f->command_state == cs_finished);
1476 break;
1477 }
1478
1479 return 1;
1480 }
1481
1482 /* Create a `struct child' for FILE and start its commands running. */
1483
1484 void
new_job(struct file * file)1485 new_job (struct file *file)
1486 {
1487 register struct commands *cmds = file->cmds;
1488 register struct child *c;
1489 char **lines;
1490 register unsigned int i;
1491
1492 /* Let any previously decided-upon jobs that are waiting
1493 for the load to go down start before this new one. */
1494 start_waiting_jobs ();
1495
1496 /* Reap any children that might have finished recently. */
1497 reap_children (0, 0);
1498
1499 /* Chop the commands up into lines if they aren't already. */
1500 chop_commands (cmds);
1501
1502 /* Expand the command lines and store the results in LINES. */
1503 lines = (char **) xmalloc (cmds->ncommand_lines * sizeof (char *));
1504 for (i = 0; i < cmds->ncommand_lines; ++i)
1505 {
1506 /* Collapse backslash-newline combinations that are inside variable
1507 or function references. These are left alone by the parser so
1508 that they will appear in the echoing of commands (where they look
1509 nice); and collapsed by construct_command_argv when it tokenizes.
1510 But letting them survive inside function invocations loses because
1511 we don't want the functions to see them as part of the text. */
1512
1513 char *in, *out, *ref;
1514
1515 /* IN points to where in the line we are scanning.
1516 OUT points to where in the line we are writing.
1517 When we collapse a backslash-newline combination,
1518 IN gets ahead of OUT. */
1519
1520 in = out = cmds->command_lines[i];
1521 while ((ref = strchr (in, '$')) != 0)
1522 {
1523 ++ref; /* Move past the $. */
1524
1525 if (out != in)
1526 /* Copy the text between the end of the last chunk
1527 we processed (where IN points) and the new chunk
1528 we are about to process (where REF points). */
1529 bcopy (in, out, ref - in);
1530
1531 /* Move both pointers past the boring stuff. */
1532 out += ref - in;
1533 in = ref;
1534
1535 if (*ref == '(' || *ref == '{')
1536 {
1537 char openparen = *ref;
1538 char closeparen = openparen == '(' ? ')' : '}';
1539 int count;
1540 char *p;
1541
1542 *out++ = *in++; /* Copy OPENPAREN. */
1543 /* IN now points past the opening paren or brace.
1544 Count parens or braces until it is matched. */
1545 count = 0;
1546 while (*in != '\0')
1547 {
1548 if (*in == closeparen && --count < 0)
1549 break;
1550 else if (*in == '\\' && in[1] == '\n')
1551 {
1552 /* We have found a backslash-newline inside a
1553 variable or function reference. Eat it and
1554 any following whitespace. */
1555
1556 int quoted = 0;
1557 for (p = in - 1; p > ref && *p == '\\'; --p)
1558 quoted = !quoted;
1559
1560 if (quoted)
1561 /* There were two or more backslashes, so this is
1562 not really a continuation line. We don't collapse
1563 the quoting backslashes here as is done in
1564 collapse_continuations, because the line will
1565 be collapsed again after expansion. */
1566 *out++ = *in++;
1567 else
1568 {
1569 /* Skip the backslash, newline and
1570 any following whitespace. */
1571 in = next_token (in + 2);
1572
1573 /* Discard any preceding whitespace that has
1574 already been written to the output. */
1575 while (out > ref
1576 && isblank ((unsigned char)out[-1]))
1577 --out;
1578
1579 /* Replace it all with a single space. */
1580 *out++ = ' ';
1581 }
1582 }
1583 else
1584 {
1585 if (*in == openparen)
1586 ++count;
1587
1588 *out++ = *in++;
1589 }
1590 }
1591 }
1592 }
1593
1594 /* There are no more references in this line to worry about.
1595 Copy the remaining uninteresting text to the output. */
1596 if (out != in)
1597 strcpy (out, in);
1598
1599 /* Finally, expand the line. */
1600 lines[i] = allocated_variable_expand_for_file (cmds->command_lines[i],
1601 file);
1602 }
1603
1604 /* Start the command sequence, record it in a new
1605 `struct child', and add that to the chain. */
1606
1607 c = (struct child *) xmalloc (sizeof (struct child));
1608 bzero ((char *)c, sizeof (struct child));
1609 c->file = file;
1610 c->command_lines = lines;
1611 c->sh_batch_file = NULL;
1612
1613 /* Cache dontcare flag because file->dontcare can be changed once we
1614 return. Check dontcare inheritance mechanism for details. */
1615 c->dontcare = file->dontcare;
1616
1617 /* Fetch the first command line to be run. */
1618 job_next_command (c);
1619
1620 /* Wait for a job slot to be freed up. If we allow an infinite number
1621 don't bother; also job_slots will == 0 if we're using the jobserver. */
1622
1623 if (job_slots != 0)
1624 while (job_slots_used == job_slots)
1625 reap_children (1, 0);
1626
1627 #ifdef MAKE_JOBSERVER
1628 /* If we are controlling multiple jobs make sure we have a token before
1629 starting the child. */
1630
1631 /* This can be inefficient. There's a decent chance that this job won't
1632 actually have to run any subprocesses: the command script may be empty
1633 or otherwise optimized away. It would be nice if we could defer
1634 obtaining a token until just before we need it, in start_job_command.
1635 To do that we'd need to keep track of whether we'd already obtained a
1636 token (since start_job_command is called for each line of the job, not
1637 just once). Also more thought needs to go into the entire algorithm;
1638 this is where the old parallel job code waits, so... */
1639
1640 else if (job_fds[0] >= 0)
1641 while (1)
1642 {
1643 char token;
1644 int got_token;
1645 int saved_errno;
1646
1647 DB (DB_JOBS, ("Need a job token; we %shave children\n",
1648 children ? "" : "don't "));
1649
1650 /* If we don't already have a job started, use our "free" token. */
1651 if (!jobserver_tokens)
1652 break;
1653
1654 /* Read a token. As long as there's no token available we'll block.
1655 We enable interruptible system calls before the read(2) so that if
1656 we get a SIGCHLD while we're waiting, we'll return with EINTR and
1657 we can process the death(s) and return tokens to the free pool.
1658
1659 Once we return from the read, we immediately reinstate restartable
1660 system calls. This allows us to not worry about checking for
1661 EINTR on all the other system calls in the program.
1662
1663 There is one other twist: there is a span between the time
1664 reap_children() does its last check for dead children and the time
1665 the read(2) call is entered, below, where if a child dies we won't
1666 notice. This is extremely serious as it could cause us to
1667 deadlock, given the right set of events.
1668
1669 To avoid this, we do the following: before we reap_children(), we
1670 dup(2) the read FD on the jobserver pipe. The read(2) call below
1671 uses that new FD. In the signal handler, we close that FD. That
1672 way, if a child dies during the section mentioned above, the
1673 read(2) will be invoked with an invalid FD and will return
1674 immediately with EBADF. */
1675
1676 /* Make sure we have a dup'd FD. */
1677 if (job_rfd < 0)
1678 {
1679 DB (DB_JOBS, ("Duplicate the job FD\n"));
1680 job_rfd = dup (job_fds[0]);
1681 }
1682
1683 /* Reap anything that's currently waiting. */
1684 reap_children (0, 0);
1685
1686 /* Kick off any jobs we have waiting for an opportunity that
1687 can run now (ie waiting for load). */
1688 start_waiting_jobs ();
1689
1690 /* If our "free" slot has become available, use it; we don't need an
1691 actual token. */
1692 if (!jobserver_tokens)
1693 break;
1694
1695 /* There must be at least one child already, or we have no business
1696 waiting for a token. */
1697 if (!children)
1698 fatal (NILF, "INTERNAL: no children as we go to sleep on read\n");
1699
1700 /* Set interruptible system calls, and read() for a job token. */
1701 set_child_handler_action_flags (1, waiting_jobs != NULL);
1702 got_token = read (job_rfd, &token, 1);
1703 saved_errno = errno;
1704 set_child_handler_action_flags (0, waiting_jobs != NULL);
1705
1706 /* If we got one, we're done here. */
1707 if (got_token == 1)
1708 {
1709 DB (DB_JOBS, (_("Obtained token for child 0x%08lx (%s).\n"),
1710 (unsigned long int) c, c->file->name));
1711 break;
1712 }
1713
1714 /* If the error _wasn't_ expected (EINTR or EBADF), punt. Otherwise,
1715 go back and reap_children(), and try again. */
1716 errno = saved_errno;
1717 if (errno != EINTR && errno != EBADF)
1718 pfatal_with_name (_("read jobs pipe"));
1719 if (errno == EBADF)
1720 DB (DB_JOBS, ("Read returned EBADF.\n"));
1721 }
1722 #endif
1723
1724 ++jobserver_tokens;
1725
1726 /* The job is now primed. Start it running.
1727 (This will notice if there are in fact no commands.) */
1728 (void) start_waiting_job (c);
1729
1730 if (job_slots == 1 || not_parallel)
1731 /* Since there is only one job slot, make things run linearly.
1732 Wait for the child to die, setting the state to `cs_finished'. */
1733 while (file->command_state == cs_running)
1734 reap_children (1, 0);
1735
1736 return;
1737 }
1738
1739 /* Move CHILD's pointers to the next command for it to execute.
1740 Returns nonzero if there is another command. */
1741
1742 static int
job_next_command(struct child * child)1743 job_next_command (struct child *child)
1744 {
1745 while (child->command_ptr == 0 || *child->command_ptr == '\0')
1746 {
1747 /* There are no more lines in the expansion of this line. */
1748 if (child->command_line == child->file->cmds->ncommand_lines)
1749 {
1750 /* There are no more lines to be expanded. */
1751 child->command_ptr = 0;
1752 return 0;
1753 }
1754 else
1755 /* Get the next line to run. */
1756 child->command_ptr = child->command_lines[child->command_line++];
1757 }
1758 return 1;
1759 }
1760
1761 /* Determine if the load average on the system is too high to start a new job.
1762 The real system load average is only recomputed once a second. However, a
1763 very parallel make can easily start tens or even hundreds of jobs in a
1764 second, which brings the system to its knees for a while until that first
1765 batch of jobs clears out.
1766
1767 To avoid this we use a weighted algorithm to try to account for jobs which
1768 have been started since the last second, and guess what the load average
1769 would be now if it were computed.
1770
1771 This algorithm was provided by Thomas Riedl <thomas.riedl@siemens.com>,
1772 who writes:
1773
1774 ! calculate something load-oid and add to the observed sys.load,
1775 ! so that latter can catch up:
1776 ! - every job started increases jobctr;
1777 ! - every dying job decreases a positive jobctr;
1778 ! - the jobctr value gets zeroed every change of seconds,
1779 ! after its value*weight_b is stored into the 'backlog' value last_sec
1780 ! - weight_a times the sum of jobctr and last_sec gets
1781 ! added to the observed sys.load.
1782 !
1783 ! The two weights have been tried out on 24 and 48 proc. Sun Solaris-9
1784 ! machines, using a several-thousand-jobs-mix of cpp, cc, cxx and smallish
1785 ! sub-shelled commands (rm, echo, sed...) for tests.
1786 ! lowering the 'direct influence' factor weight_a (e.g. to 0.1)
1787 ! resulted in significant excession of the load limit, raising it
1788 ! (e.g. to 0.5) took bad to small, fast-executing jobs and didn't
1789 ! reach the limit in most test cases.
1790 !
1791 ! lowering the 'history influence' weight_b (e.g. to 0.1) resulted in
1792 ! exceeding the limit for longer-running stuff (compile jobs in
1793 ! the .5 to 1.5 sec. range),raising it (e.g. to 0.5) overrepresented
1794 ! small jobs' effects.
1795
1796 */
1797
1798 #define LOAD_WEIGHT_A 0.25
1799 #define LOAD_WEIGHT_B 0.25
1800
1801 static int
load_too_high(void)1802 load_too_high (void)
1803 {
1804 #if defined(__MSDOS__) || defined(VMS) || defined(_AMIGA) || defined(__riscos__)
1805 return 1;
1806 #else
1807 static double last_sec;
1808 static time_t last_now;
1809 double load, guess;
1810 time_t now;
1811
1812 #ifdef WINDOWS32
1813 /* sub_proc.c cannot wait for more than MAXIMUM_WAIT_OBJECTS children */
1814 if (process_used_slots () >= MAXIMUM_WAIT_OBJECTS)
1815 return 1;
1816 #endif
1817
1818 if (max_load_average < 0)
1819 return 0;
1820
1821 /* Find the real system load average. */
1822 make_access ();
1823 if (getloadavg (&load, 1) != 1)
1824 {
1825 static int lossage = -1;
1826 /* Complain only once for the same error. */
1827 if (lossage == -1 || errno != lossage)
1828 {
1829 if (errno == 0)
1830 /* An errno value of zero means getloadavg is just unsupported. */
1831 error (NILF,
1832 _("cannot enforce load limits on this operating system"));
1833 else
1834 perror_with_name (_("cannot enforce load limit: "), "getloadavg");
1835 }
1836 lossage = errno;
1837 load = 0;
1838 }
1839 user_access ();
1840
1841 /* If we're in a new second zero the counter and correct the backlog
1842 value. Only keep the backlog for one extra second; after that it's 0. */
1843 now = time (NULL);
1844 if (last_now < now)
1845 {
1846 if (last_now == now - 1)
1847 last_sec = LOAD_WEIGHT_B * job_counter;
1848 else
1849 last_sec = 0.0;
1850
1851 job_counter = 0;
1852 last_now = now;
1853 }
1854
1855 /* Try to guess what the load would be right now. */
1856 guess = load + (LOAD_WEIGHT_A * (job_counter + last_sec));
1857
1858 DB (DB_JOBS, ("Estimated system load = %f (actual = %f) (max requested = %f)\n",
1859 guess, load, max_load_average));
1860
1861 return guess >= max_load_average;
1862 #endif
1863 }
1864
1865 /* Start jobs that are waiting for the load to be lower. */
1866
1867 void
start_waiting_jobs(void)1868 start_waiting_jobs (void)
1869 {
1870 struct child *job;
1871
1872 if (waiting_jobs == 0)
1873 return;
1874
1875 do
1876 {
1877 /* Check for recently deceased descendants. */
1878 reap_children (0, 0);
1879
1880 /* Take a job off the waiting list. */
1881 job = waiting_jobs;
1882 waiting_jobs = job->next;
1883
1884 /* Try to start that job. We break out of the loop as soon
1885 as start_waiting_job puts one back on the waiting list. */
1886 }
1887 while (start_waiting_job (job) && waiting_jobs != 0);
1888
1889 return;
1890 }
1891
1892 #ifndef WINDOWS32
1893
1894 /* EMX: Start a child process. This function returns the new pid. */
1895 # if defined __MSDOS__ || defined __EMX__
1896 int
child_execute_job(int stdin_fd,int stdout_fd,char ** argv,char ** envp)1897 child_execute_job (int stdin_fd, int stdout_fd, char **argv, char **envp)
1898 {
1899 int pid;
1900 /* stdin_fd == 0 means: nothing to do for stdin;
1901 stdout_fd == 1 means: nothing to do for stdout */
1902 int save_stdin = (stdin_fd != 0) ? dup (0) : 0;
1903 int save_stdout = (stdout_fd != 1) ? dup (1): 1;
1904
1905 /* < 0 only if dup() failed */
1906 if (save_stdin < 0)
1907 fatal (NILF, _("no more file handles: could not duplicate stdin\n"));
1908 if (save_stdout < 0)
1909 fatal (NILF, _("no more file handles: could not duplicate stdout\n"));
1910
1911 /* Close unnecessary file handles for the child. */
1912 if (save_stdin != 0)
1913 CLOSE_ON_EXEC (save_stdin);
1914 if (save_stdout != 1)
1915 CLOSE_ON_EXEC (save_stdout);
1916
1917 /* Connect the pipes to the child process. */
1918 if (stdin_fd != 0)
1919 (void) dup2 (stdin_fd, 0);
1920 if (stdout_fd != 1)
1921 (void) dup2 (stdout_fd, 1);
1922
1923 /* stdin_fd and stdout_fd must be closed on exit because we are
1924 still in the parent process */
1925 if (stdin_fd != 0)
1926 CLOSE_ON_EXEC (stdin_fd);
1927 if (stdout_fd != 1)
1928 CLOSE_ON_EXEC (stdout_fd);
1929
1930 /* Run the command. */
1931 pid = exec_command (argv, envp);
1932
1933 /* Restore stdout/stdin of the parent and close temporary FDs. */
1934 if (stdin_fd != 0)
1935 {
1936 if (dup2 (save_stdin, 0) != 0)
1937 fatal (NILF, _("Could not restore stdin\n"));
1938 else
1939 close (save_stdin);
1940 }
1941
1942 if (stdout_fd != 1)
1943 {
1944 if (dup2 (save_stdout, 1) != 1)
1945 fatal (NILF, _("Could not restore stdout\n"));
1946 else
1947 close (save_stdout);
1948 }
1949
1950 return pid;
1951 }
1952
1953 #elif !defined (_AMIGA) && !defined (__MSDOS__) && !defined (VMS)
1954
1955 /* UNIX:
1956 Replace the current process with one executing the command in ARGV.
1957 STDIN_FD and STDOUT_FD are used as the process's stdin and stdout; ENVP is
1958 the environment of the new program. This function does not return. */
1959 void
child_execute_job(int stdin_fd,int stdout_fd,char ** argv,char ** envp)1960 child_execute_job (int stdin_fd, int stdout_fd, char **argv, char **envp)
1961 {
1962 if (stdin_fd != 0)
1963 (void) dup2 (stdin_fd, 0);
1964 if (stdout_fd != 1)
1965 (void) dup2 (stdout_fd, 1);
1966 if (stdin_fd != 0)
1967 (void) close (stdin_fd);
1968 if (stdout_fd != 1)
1969 (void) close (stdout_fd);
1970
1971 /* Run the command. */
1972 exec_command (argv, envp);
1973 }
1974 #endif /* !AMIGA && !__MSDOS__ && !VMS */
1975 #endif /* !WINDOWS32 */
1976
1977 #ifndef _AMIGA
1978 /* Replace the current process with one running the command in ARGV,
1979 with environment ENVP. This function does not return. */
1980
1981 /* EMX: This function returns the pid of the child process. */
1982 # ifdef __EMX__
1983 int
1984 # else
1985 void
1986 # endif
exec_command(char ** argv,char ** envp)1987 exec_command (char **argv, char **envp)
1988 {
1989 #ifdef VMS
1990 /* to work around a problem with signals and execve: ignore them */
1991 #ifdef SIGCHLD
1992 signal (SIGCHLD,SIG_IGN);
1993 #endif
1994 /* Run the program. */
1995 execve (argv[0], argv, envp);
1996 perror_with_name ("execve: ", argv[0]);
1997 _exit (EXIT_FAILURE);
1998 #else
1999 #ifdef WINDOWS32
2000 HANDLE hPID;
2001 HANDLE hWaitPID;
2002 int err = 0;
2003 int exit_code = EXIT_FAILURE;
2004
2005 /* make sure CreateProcess() has Path it needs */
2006 sync_Path_environment();
2007
2008 /* launch command */
2009 hPID = process_easy(argv, envp);
2010
2011 /* make sure launch ok */
2012 if (hPID == INVALID_HANDLE_VALUE)
2013 {
2014 int i;
2015 fprintf(stderr,
2016 _("process_easy() failed failed to launch process (e=%ld)\n"),
2017 process_last_err(hPID));
2018 for (i = 0; argv[i]; i++)
2019 fprintf(stderr, "%s ", argv[i]);
2020 fprintf(stderr, _("\nCounted %d args in failed launch\n"), i);
2021 exit(EXIT_FAILURE);
2022 }
2023
2024 /* wait and reap last child */
2025 hWaitPID = process_wait_for_any();
2026 while (hWaitPID)
2027 {
2028 /* was an error found on this process? */
2029 err = process_last_err(hWaitPID);
2030
2031 /* get exit data */
2032 exit_code = process_exit_code(hWaitPID);
2033
2034 if (err)
2035 fprintf(stderr, "make (e=%d, rc=%d): %s",
2036 err, exit_code, map_windows32_error_to_string(err));
2037
2038 /* cleanup process */
2039 process_cleanup(hWaitPID);
2040
2041 /* expect to find only last pid, warn about other pids reaped */
2042 if (hWaitPID == hPID)
2043 break;
2044 else
2045 fprintf(stderr,
2046 _("make reaped child pid %lld, still waiting for pid %lld\n"),
2047 (intptr_t)hWaitPID, (intptr_t)hPID);
2048 }
2049
2050 /* return child's exit code as our exit code */
2051 exit(exit_code);
2052
2053 #else /* !WINDOWS32 */
2054
2055 # ifdef __EMX__
2056 int pid;
2057 # endif
2058
2059 /* Be the user, permanently. */
2060 child_access ();
2061
2062 # ifdef __EMX__
2063
2064 /* Run the program. */
2065 pid = spawnvpe (P_NOWAIT, argv[0], argv, envp);
2066
2067 if (pid >= 0)
2068 return pid;
2069
2070 /* the file might have a strange shell extension */
2071 if (errno == ENOENT)
2072 errno = ENOEXEC;
2073
2074 # else
2075
2076 /* Run the program. */
2077 environ = envp;
2078 execvp (argv[0], argv);
2079
2080 # endif /* !__EMX__ */
2081
2082 switch (errno)
2083 {
2084 case ENOENT:
2085 error (NILF, _("%s: Command not found"), argv[0]);
2086 break;
2087 case ENOEXEC:
2088 {
2089 /* The file is not executable. Try it as a shell script. */
2090 extern char *getenv ();
2091 char *shell;
2092 char **new_argv;
2093 int argc;
2094 int i=1;
2095
2096 # ifdef __EMX__
2097 /* Do not use $SHELL from the environment */
2098 struct variable *p = lookup_variable ("SHELL", 5);
2099 if (p)
2100 shell = p->value;
2101 else
2102 shell = 0;
2103 # else
2104 shell = getenv ("SHELL");
2105 # endif
2106 if (shell == 0)
2107 shell = default_shell;
2108
2109 argc = 1;
2110 while (argv[argc] != 0)
2111 ++argc;
2112
2113 # ifdef __EMX__
2114 if (!unixy_shell)
2115 ++argc;
2116 # endif
2117
2118 new_argv = (char **) alloca ((1 + argc + 1) * sizeof (char *));
2119 new_argv[0] = shell;
2120
2121 # ifdef __EMX__
2122 if (!unixy_shell)
2123 {
2124 new_argv[1] = "/c";
2125 ++i;
2126 --argc;
2127 }
2128 # endif
2129
2130 new_argv[i] = argv[0];
2131 while (argc > 0)
2132 {
2133 new_argv[i + argc] = argv[argc];
2134 --argc;
2135 }
2136
2137 # ifdef __EMX__
2138 pid = spawnvpe (P_NOWAIT, shell, new_argv, envp);
2139 if (pid >= 0)
2140 break;
2141 # else
2142 execvp (shell, new_argv);
2143 # endif
2144 if (errno == ENOENT)
2145 error (NILF, _("%s: Shell program not found"), shell);
2146 else
2147 perror_with_name ("execvp: ", shell);
2148 break;
2149 }
2150
2151 # ifdef __EMX__
2152 case EINVAL:
2153 /* this nasty error was driving me nuts :-( */
2154 error (NILF, _("spawnvpe: environment space might be exhausted"));
2155 /* FALLTHROUGH */
2156 # endif
2157
2158 default:
2159 perror_with_name ("execvp: ", argv[0]);
2160 break;
2161 }
2162
2163 # ifdef __EMX__
2164 return pid;
2165 # else
2166 _exit (127);
2167 # endif
2168 #endif /* !WINDOWS32 */
2169 #endif /* !VMS */
2170 }
2171 #else /* On Amiga */
exec_command(char ** argv)2172 void exec_command (char **argv)
2173 {
2174 MyExecute (argv);
2175 }
2176
clean_tmp(void)2177 void clean_tmp (void)
2178 {
2179 DeleteFile (amiga_bname);
2180 }
2181
2182 #endif /* On Amiga */
2183
2184 #ifndef VMS
2185 /* Figure out the argument list necessary to run LINE as a command. Try to
2186 avoid using a shell. This routine handles only ' quoting, and " quoting
2187 when no backslash, $ or ` characters are seen in the quotes. Starting
2188 quotes may be escaped with a backslash. If any of the characters in
2189 sh_chars[] is seen, or any of the builtin commands listed in sh_cmds[]
2190 is the first word of a line, the shell is used.
2191
2192 If RESTP is not NULL, *RESTP is set to point to the first newline in LINE.
2193 If *RESTP is NULL, newlines will be ignored.
2194
2195 SHELL is the shell to use, or nil to use the default shell.
2196 IFS is the value of $IFS, or nil (meaning the default). */
2197
2198 static char **
construct_command_argv_internal(char * line,char ** restp,char * shell,char * ifs,char ** batch_filename_ptr)2199 construct_command_argv_internal (char *line, char **restp, char *shell,
2200 char *ifs, char **batch_filename_ptr)
2201 {
2202 #ifdef __MSDOS__
2203 /* MSDOS supports both the stock DOS shell and ports of Unixy shells.
2204 We call `system' for anything that requires ``slow'' processing,
2205 because DOS shells are too dumb. When $SHELL points to a real
2206 (unix-style) shell, `system' just calls it to do everything. When
2207 $SHELL points to a DOS shell, `system' does most of the work
2208 internally, calling the shell only for its internal commands.
2209 However, it looks on the $PATH first, so you can e.g. have an
2210 external command named `mkdir'.
2211
2212 Since we call `system', certain characters and commands below are
2213 actually not specific to COMMAND.COM, but to the DJGPP implementation
2214 of `system'. In particular:
2215
2216 The shell wildcard characters are in DOS_CHARS because they will
2217 not be expanded if we call the child via `spawnXX'.
2218
2219 The `;' is in DOS_CHARS, because our `system' knows how to run
2220 multiple commands on a single line.
2221
2222 DOS_CHARS also include characters special to 4DOS/NDOS, so we
2223 won't have to tell one from another and have one more set of
2224 commands and special characters. */
2225 static char sh_chars_dos[] = "*?[];|<>%^&()";
2226 static char *sh_cmds_dos[] = { "break", "call", "cd", "chcp", "chdir", "cls",
2227 "copy", "ctty", "date", "del", "dir", "echo",
2228 "erase", "exit", "for", "goto", "if", "md",
2229 "mkdir", "path", "pause", "prompt", "rd",
2230 "rmdir", "rem", "ren", "rename", "set",
2231 "shift", "time", "type", "ver", "verify",
2232 "vol", ":", 0 };
2233
2234 static char sh_chars_sh[] = "#;\"*?[]&|<>(){}$`^";
2235 static char *sh_cmds_sh[] = { "cd", "echo", "eval", "exec", "exit", "login",
2236 "logout", "set", "umask", "wait", "while",
2237 "for", "case", "if", ":", ".", "break",
2238 "continue", "export", "read", "readonly",
2239 "shift", "times", "trap", "switch", "unset",
2240 0 };
2241
2242 char *sh_chars;
2243 char **sh_cmds;
2244 #elif defined (__EMX__)
2245 static char sh_chars_dos[] = "*?[];|<>%^&()";
2246 static char *sh_cmds_dos[] = { "break", "call", "cd", "chcp", "chdir", "cls",
2247 "copy", "ctty", "date", "del", "dir", "echo",
2248 "erase", "exit", "for", "goto", "if", "md",
2249 "mkdir", "path", "pause", "prompt", "rd",
2250 "rmdir", "rem", "ren", "rename", "set",
2251 "shift", "time", "type", "ver", "verify",
2252 "vol", ":", 0 };
2253
2254 static char sh_chars_os2[] = "*?[];|<>%^()\"'&";
2255 static char *sh_cmds_os2[] = { "call", "cd", "chcp", "chdir", "cls", "copy",
2256 "date", "del", "detach", "dir", "echo",
2257 "endlocal", "erase", "exit", "for", "goto", "if",
2258 "keys", "md", "mkdir", "move", "path", "pause",
2259 "prompt", "rd", "rem", "ren", "rename", "rmdir",
2260 "set", "setlocal", "shift", "start", "time",
2261 "type", "ver", "verify", "vol", ":", 0 };
2262
2263 static char sh_chars_sh[] = "#;\"*?[]&|<>(){}$`^~'";
2264 static char *sh_cmds_sh[] = { "echo", "cd", "eval", "exec", "exit", "login",
2265 "logout", "set", "umask", "wait", "while",
2266 "for", "case", "if", ":", ".", "break",
2267 "continue", "export", "read", "readonly",
2268 "shift", "times", "trap", "switch", "unset",
2269 0 };
2270 char *sh_chars;
2271 char **sh_cmds;
2272
2273 #elif defined (_AMIGA)
2274 static char sh_chars[] = "#;\"|<>()?*$`";
2275 static char *sh_cmds[] = { "cd", "eval", "if", "delete", "echo", "copy",
2276 "rename", "set", "setenv", "date", "makedir",
2277 "skip", "else", "endif", "path", "prompt",
2278 "unset", "unsetenv", "version",
2279 0 };
2280 #elif defined (WINDOWS32)
2281 static char sh_chars_dos[] = "\"|&<>";
2282 static char *sh_cmds_dos[] = { "break", "call", "cd", "chcp", "chdir", "cls",
2283 "copy", "ctty", "date", "del", "dir", "echo",
2284 "erase", "exit", "for", "goto", "if", "if", "md",
2285 "mkdir", "path", "pause", "prompt", "rd", "rem",
2286 "ren", "rename", "rmdir", "set", "shift", "time",
2287 "type", "ver", "verify", "vol", ":", 0 };
2288 static char sh_chars_sh[] = "#;\"*?[]&|<>(){}$`^";
2289 static char *sh_cmds_sh[] = { "cd", "eval", "exec", "exit", "login",
2290 "logout", "set", "umask", "wait", "while", "for",
2291 "case", "if", ":", ".", "break", "continue",
2292 "export", "read", "readonly", "shift", "times",
2293 "trap", "switch", "test",
2294 #ifdef BATCH_MODE_ONLY_SHELL
2295 "echo",
2296 #endif
2297 0 };
2298 char* sh_chars;
2299 char** sh_cmds;
2300 #elif defined(__riscos__)
2301 static char sh_chars[] = "";
2302 static char *sh_cmds[] = { 0 };
2303 #else /* must be UNIX-ish */
2304 static char sh_chars[] = "#;\"*?[]&|<>(){}$`^~!";
2305 static char *sh_cmds[] = { ".", ":", "break", "case", "cd", "continue",
2306 "eval", "exec", "exit", "export", "for", "if",
2307 "login", "logout", "read", "readonly", "set",
2308 "shift", "switch", "test", "times", "trap",
2309 "umask", "wait", "while", 0 };
2310 #endif
2311 register int i;
2312 register char *p;
2313 register char *ap;
2314 char *end;
2315 int instring, word_has_equals, seen_nonequals, last_argument_was_empty;
2316 char **new_argv = 0;
2317 char *argstr = 0;
2318 #ifdef WINDOWS32
2319 int slow_flag = 0;
2320
2321 if (!unixy_shell) {
2322 sh_cmds = sh_cmds_dos;
2323 sh_chars = sh_chars_dos;
2324 } else {
2325 sh_cmds = sh_cmds_sh;
2326 sh_chars = sh_chars_sh;
2327 }
2328 #endif /* WINDOWS32 */
2329
2330 if (restp != NULL)
2331 *restp = NULL;
2332
2333 /* Make sure not to bother processing an empty line. */
2334 while (isblank ((unsigned char)*line))
2335 ++line;
2336 if (*line == '\0')
2337 return 0;
2338
2339 /* See if it is safe to parse commands internally. */
2340 if (shell == 0)
2341 shell = default_shell;
2342 #ifdef WINDOWS32
2343 else if (strcmp (shell, default_shell))
2344 {
2345 char *s1 = _fullpath(NULL, shell, 0);
2346 char *s2 = _fullpath(NULL, default_shell, 0);
2347
2348 slow_flag = strcmp((s1 ? s1 : ""), (s2 ? s2 : ""));
2349
2350 if (s1)
2351 free (s1);
2352 if (s2)
2353 free (s2);
2354 }
2355 if (slow_flag)
2356 goto slow;
2357 #else /* not WINDOWS32 */
2358 #if defined (__MSDOS__) || defined (__EMX__)
2359 else if (stricmp (shell, default_shell))
2360 {
2361 extern int _is_unixy_shell (const char *_path);
2362
2363 DB (DB_BASIC, (_("$SHELL changed (was `%s', now `%s')\n"),
2364 default_shell, shell));
2365 unixy_shell = _is_unixy_shell (shell);
2366 /* we must allocate a copy of shell: construct_command_argv() will free
2367 * shell after this function returns. */
2368 default_shell = xstrdup (shell);
2369 }
2370 if (unixy_shell)
2371 {
2372 sh_chars = sh_chars_sh;
2373 sh_cmds = sh_cmds_sh;
2374 }
2375 else
2376 {
2377 sh_chars = sh_chars_dos;
2378 sh_cmds = sh_cmds_dos;
2379 # ifdef __EMX__
2380 if (_osmode == OS2_MODE)
2381 {
2382 sh_chars = sh_chars_os2;
2383 sh_cmds = sh_cmds_os2;
2384 }
2385 # endif
2386 }
2387 #else /* !__MSDOS__ */
2388 else if (strcmp (shell, default_shell))
2389 goto slow;
2390 #endif /* !__MSDOS__ && !__EMX__ */
2391 #endif /* not WINDOWS32 */
2392
2393 if (ifs != 0)
2394 for (ap = ifs; *ap != '\0'; ++ap)
2395 if (*ap != ' ' && *ap != '\t' && *ap != '\n')
2396 goto slow;
2397
2398 i = strlen (line) + 1;
2399
2400 /* More than 1 arg per character is impossible. */
2401 new_argv = (char **) xmalloc (i * sizeof (char *));
2402
2403 /* All the args can fit in a buffer as big as LINE is. */
2404 ap = new_argv[0] = argstr = (char *) xmalloc (i);
2405 end = ap + i;
2406
2407 /* I is how many complete arguments have been found. */
2408 i = 0;
2409 instring = word_has_equals = seen_nonequals = last_argument_was_empty = 0;
2410 for (p = line; *p != '\0'; ++p)
2411 {
2412 assert (ap <= end);
2413
2414 if (instring)
2415 {
2416 /* Inside a string, just copy any char except a closing quote
2417 or a backslash-newline combination. */
2418 if (*p == instring)
2419 {
2420 instring = 0;
2421 if (ap == new_argv[0] || *(ap-1) == '\0')
2422 last_argument_was_empty = 1;
2423 }
2424 else if (*p == '\\' && p[1] == '\n')
2425 {
2426 /* Backslash-newline is handled differently depending on what
2427 kind of string we're in: inside single-quoted strings you
2428 keep them; in double-quoted strings they disappear.
2429 For DOS/Windows/OS2, if we don't have a POSIX shell,
2430 we keep the pre-POSIX behavior of removing the
2431 backslash-newline. */
2432 if (instring == '"'
2433 #if defined (__MSDOS__) || defined (__EMX__) || defined (WINDOWS32)
2434 || !unixy_shell
2435 #endif
2436 )
2437 ++p;
2438 else
2439 {
2440 *(ap++) = *(p++);
2441 *(ap++) = *p;
2442 }
2443 /* If there's a TAB here, skip it. */
2444 if (p[1] == '\t')
2445 ++p;
2446 }
2447 else if (*p == '\n' && restp != NULL)
2448 {
2449 /* End of the command line. */
2450 *restp = p;
2451 goto end_of_line;
2452 }
2453 /* Backslash, $, and ` are special inside double quotes.
2454 If we see any of those, punt.
2455 But on MSDOS, if we use COMMAND.COM, double and single
2456 quotes have the same effect. */
2457 else if (instring == '"' && strchr ("\\$`", *p) != 0 && unixy_shell)
2458 goto slow;
2459 else
2460 *ap++ = *p;
2461 }
2462 else if (strchr (sh_chars, *p) != 0)
2463 /* Not inside a string, but it's a special char. */
2464 goto slow;
2465 #ifdef __MSDOS__
2466 else if (*p == '.' && p[1] == '.' && p[2] == '.' && p[3] != '.')
2467 /* `...' is a wildcard in DJGPP. */
2468 goto slow;
2469 #endif
2470 else
2471 /* Not a special char. */
2472 switch (*p)
2473 {
2474 case '=':
2475 /* Equals is a special character in leading words before the
2476 first word with no equals sign in it. This is not the case
2477 with sh -k, but we never get here when using nonstandard
2478 shell flags. */
2479 if (! seen_nonequals && unixy_shell)
2480 goto slow;
2481 word_has_equals = 1;
2482 *ap++ = '=';
2483 break;
2484
2485 case '\\':
2486 /* Backslash-newline has special case handling, ref POSIX.
2487 We're in the fastpath, so emulate what the shell would do. */
2488 if (p[1] == '\n')
2489 {
2490 /* Throw out the backslash and newline. */
2491 ++p;
2492
2493 /* If there is a tab after a backslash-newline, remove it. */
2494 if (p[1] == '\t')
2495 ++p;
2496
2497 /* If there's nothing in this argument yet, skip any
2498 whitespace before the start of the next word. */
2499 if (ap == new_argv[i])
2500 p = next_token (p + 1) - 1;
2501 }
2502 else if (p[1] != '\0')
2503 {
2504 #ifdef HAVE_DOS_PATHS
2505 /* Only remove backslashes before characters special to Unixy
2506 shells. All other backslashes are copied verbatim, since
2507 they are probably DOS-style directory separators. This
2508 still leaves a small window for problems, but at least it
2509 should work for the vast majority of naive users. */
2510
2511 #ifdef __MSDOS__
2512 /* A dot is only special as part of the "..."
2513 wildcard. */
2514 if (strneq (p + 1, ".\\.\\.", 5))
2515 {
2516 *ap++ = '.';
2517 *ap++ = '.';
2518 p += 4;
2519 }
2520 else
2521 #endif
2522 if (p[1] != '\\' && p[1] != '\''
2523 && !isspace ((unsigned char)p[1])
2524 && strchr (sh_chars_sh, p[1]) == 0)
2525 /* back up one notch, to copy the backslash */
2526 --p;
2527 #endif /* HAVE_DOS_PATHS */
2528
2529 /* Copy and skip the following char. */
2530 *ap++ = *++p;
2531 }
2532 break;
2533
2534 case '\'':
2535 case '"':
2536 instring = *p;
2537 break;
2538
2539 case '\n':
2540 if (restp != NULL)
2541 {
2542 /* End of the command line. */
2543 *restp = p;
2544 goto end_of_line;
2545 }
2546 else
2547 /* Newlines are not special. */
2548 *ap++ = '\n';
2549 break;
2550
2551 case ' ':
2552 case '\t':
2553 /* We have the end of an argument.
2554 Terminate the text of the argument. */
2555 *ap++ = '\0';
2556 new_argv[++i] = ap;
2557 last_argument_was_empty = 0;
2558
2559 /* Update SEEN_NONEQUALS, which tells us if every word
2560 heretofore has contained an `='. */
2561 seen_nonequals |= ! word_has_equals;
2562 if (word_has_equals && ! seen_nonequals)
2563 /* An `=' in a word before the first
2564 word without one is magical. */
2565 goto slow;
2566 word_has_equals = 0; /* Prepare for the next word. */
2567
2568 /* If this argument is the command name,
2569 see if it is a built-in shell command.
2570 If so, have the shell handle it. */
2571 if (i == 1)
2572 {
2573 register int j;
2574 for (j = 0; sh_cmds[j] != 0; ++j)
2575 {
2576 if (streq (sh_cmds[j], new_argv[0]))
2577 goto slow;
2578 # ifdef __EMX__
2579 /* Non-Unix shells are case insensitive. */
2580 if (!unixy_shell
2581 && strcasecmp (sh_cmds[j], new_argv[0]) == 0)
2582 goto slow;
2583 # endif
2584 }
2585 }
2586
2587 /* Ignore multiple whitespace chars. */
2588 p = next_token (p) - 1;
2589 break;
2590
2591 default:
2592 *ap++ = *p;
2593 break;
2594 }
2595 }
2596 end_of_line:
2597
2598 if (instring)
2599 /* Let the shell deal with an unterminated quote. */
2600 goto slow;
2601
2602 /* Terminate the last argument and the argument list. */
2603
2604 *ap = '\0';
2605 if (new_argv[i][0] != '\0' || last_argument_was_empty)
2606 ++i;
2607 new_argv[i] = 0;
2608
2609 if (i == 1)
2610 {
2611 register int j;
2612 for (j = 0; sh_cmds[j] != 0; ++j)
2613 if (streq (sh_cmds[j], new_argv[0]))
2614 goto slow;
2615 }
2616
2617 if (new_argv[0] == 0)
2618 {
2619 /* Line was empty. */
2620 free (argstr);
2621 free ((char *)new_argv);
2622 return 0;
2623 }
2624
2625 return new_argv;
2626
2627 slow:;
2628 /* We must use the shell. */
2629
2630 if (new_argv != 0)
2631 {
2632 /* Free the old argument list we were working on. */
2633 free (argstr);
2634 free ((char *)new_argv);
2635 }
2636
2637 #ifdef __MSDOS__
2638 execute_by_shell = 1; /* actually, call `system' if shell isn't unixy */
2639 #endif
2640
2641 #ifdef _AMIGA
2642 {
2643 char *ptr;
2644 char *buffer;
2645 char *dptr;
2646
2647 buffer = (char *)xmalloc (strlen (line)+1);
2648
2649 ptr = line;
2650 for (dptr=buffer; *ptr; )
2651 {
2652 if (*ptr == '\\' && ptr[1] == '\n')
2653 ptr += 2;
2654 else if (*ptr == '@') /* Kludge: multiline commands */
2655 {
2656 ptr += 2;
2657 *dptr++ = '\n';
2658 }
2659 else
2660 *dptr++ = *ptr++;
2661 }
2662 *dptr = 0;
2663
2664 new_argv = (char **) xmalloc (2 * sizeof (char *));
2665 new_argv[0] = buffer;
2666 new_argv[1] = 0;
2667 }
2668 #else /* Not Amiga */
2669 #ifdef WINDOWS32
2670 /*
2671 * Not eating this whitespace caused things like
2672 *
2673 * sh -c "\n"
2674 *
2675 * which gave the shell fits. I think we have to eat
2676 * whitespace here, but this code should be considered
2677 * suspicious if things start failing....
2678 */
2679
2680 /* Make sure not to bother processing an empty line. */
2681 while (isspace ((unsigned char)*line))
2682 ++line;
2683 if (*line == '\0')
2684 return 0;
2685 #endif /* WINDOWS32 */
2686 {
2687 /* SHELL may be a multi-word command. Construct a command line
2688 "SHELL -c LINE", with all special chars in LINE escaped.
2689 Then recurse, expanding this command line to get the final
2690 argument list. */
2691
2692 unsigned int shell_len = strlen (shell);
2693 #ifndef VMS
2694 static char minus_c[] = " -c ";
2695 #else
2696 static char minus_c[] = "";
2697 #endif
2698 unsigned int line_len = strlen (line);
2699
2700 char *new_line = (char *) alloca (shell_len + (sizeof (minus_c) - 1)
2701 + (line_len * 2) + 1);
2702 char *command_ptr = NULL; /* used for batch_mode_shell mode */
2703
2704 # ifdef __EMX__ /* is this necessary? */
2705 if (!unixy_shell)
2706 minus_c[1] = '/'; /* " /c " */
2707 # endif
2708
2709 ap = new_line;
2710 bcopy (shell, ap, shell_len);
2711 ap += shell_len;
2712 bcopy (minus_c, ap, sizeof (minus_c) - 1);
2713 ap += sizeof (minus_c) - 1;
2714 command_ptr = ap;
2715 for (p = line; *p != '\0'; ++p)
2716 {
2717 if (restp != NULL && *p == '\n')
2718 {
2719 *restp = p;
2720 break;
2721 }
2722 else if (*p == '\\' && p[1] == '\n')
2723 {
2724 /* POSIX says we keep the backslash-newline, but throw out
2725 the next char if it's a TAB. If we don't have a POSIX
2726 shell on DOS/Windows/OS2, mimic the pre-POSIX behavior
2727 and remove the backslash/newline. */
2728 #if defined (__MSDOS__) || defined (__EMX__) || defined (WINDOWS32)
2729 # define PRESERVE_BSNL unixy_shell
2730 #else
2731 # define PRESERVE_BSNL 1
2732 #endif
2733 if (PRESERVE_BSNL)
2734 {
2735 *(ap++) = '\\';
2736 *(ap++) = '\\';
2737 *(ap++) = '\n';
2738 }
2739
2740 ++p;
2741 if (p[1] == '\t')
2742 ++p;
2743
2744 continue;
2745 }
2746
2747 /* DOS shells don't know about backslash-escaping. */
2748 if (unixy_shell && !batch_mode_shell &&
2749 (*p == '\\' || *p == '\'' || *p == '"'
2750 || isspace ((unsigned char)*p)
2751 || strchr (sh_chars, *p) != 0))
2752 *ap++ = '\\';
2753 #ifdef __MSDOS__
2754 else if (unixy_shell && strneq (p, "...", 3))
2755 {
2756 /* The case of `...' wildcard again. */
2757 strcpy (ap, "\\.\\.\\");
2758 ap += 5;
2759 p += 2;
2760 }
2761 #endif
2762 *ap++ = *p;
2763 }
2764 if (ap == new_line + shell_len + sizeof (minus_c) - 1)
2765 /* Line was empty. */
2766 return 0;
2767 *ap = '\0';
2768
2769 #ifdef WINDOWS32
2770 /* Some shells do not work well when invoked as 'sh -c xxx' to run a
2771 command line (e.g. Cygnus GNUWIN32 sh.exe on WIN32 systems). In these
2772 cases, run commands via a script file. */
2773 if (just_print_flag) {
2774 /* Need to allocate new_argv, although it's unused, because
2775 start_job_command will want to free it and its 0'th element. */
2776 new_argv = (char **) xmalloc(2 * sizeof (char *));
2777 new_argv[0] = xstrdup ("");
2778 new_argv[1] = NULL;
2779 } else if ((no_default_sh_exe || batch_mode_shell) && batch_filename_ptr) {
2780 int temp_fd;
2781 FILE* batch = NULL;
2782 int id = GetCurrentProcessId();
2783 PATH_VAR(fbuf);
2784
2785 /* create a file name */
2786 sprintf(fbuf, "make%d", id);
2787 *batch_filename_ptr = create_batch_file (fbuf, unixy_shell, &temp_fd);
2788
2789 DB (DB_JOBS, (_("Creating temporary batch file %s\n"),
2790 *batch_filename_ptr));
2791
2792 /* Create a FILE object for the batch file, and write to it the
2793 commands to be executed. Put the batch file in TEXT mode. */
2794 _setmode (temp_fd, _O_TEXT);
2795 batch = _fdopen (temp_fd, "wt");
2796 if (!unixy_shell)
2797 fputs ("@echo off\n", batch);
2798 fputs (command_ptr, batch);
2799 fputc ('\n', batch);
2800 fclose (batch);
2801
2802 /* create argv */
2803 new_argv = (char **) xmalloc(3 * sizeof (char *));
2804 if (unixy_shell) {
2805 new_argv[0] = xstrdup (shell);
2806 new_argv[1] = *batch_filename_ptr; /* only argv[0] gets freed later */
2807 } else {
2808 new_argv[0] = xstrdup (*batch_filename_ptr);
2809 new_argv[1] = NULL;
2810 }
2811 new_argv[2] = NULL;
2812 } else
2813 #endif /* WINDOWS32 */
2814 if (unixy_shell)
2815 new_argv = construct_command_argv_internal (new_line, (char **) NULL,
2816 (char *) 0, (char *) 0,
2817 (char **) 0);
2818 #ifdef __EMX__
2819 else if (!unixy_shell)
2820 {
2821 /* new_line is local, must not be freed therefore
2822 We use line here instead of new_line because we run the shell
2823 manually. */
2824 size_t line_len = strlen (line);
2825 char *p = new_line;
2826 char *q = new_line;
2827 memcpy (new_line, line, line_len + 1);
2828 /* replace all backslash-newline combination and also following tabs */
2829 while (*q != '\0')
2830 {
2831 if (q[0] == '\\' && q[1] == '\n')
2832 {
2833 q += 2; /* remove '\\' and '\n' */
2834 if (q[0] == '\t')
2835 q++; /* remove 1st tab in the next line */
2836 }
2837 else
2838 *p++ = *q++;
2839 }
2840 *p = '\0';
2841
2842 # ifndef NO_CMD_DEFAULT
2843 if (strnicmp (new_line, "echo", 4) == 0
2844 && (new_line[4] == ' ' || new_line[4] == '\t'))
2845 {
2846 /* the builtin echo command: handle it separately */
2847 size_t echo_len = line_len - 5;
2848 char *echo_line = new_line + 5;
2849
2850 /* special case: echo 'x="y"'
2851 cmd works this way: a string is printed as is, i.e., no quotes
2852 are removed. But autoconf uses a command like echo 'x="y"' to
2853 determine whether make works. autoconf expects the output x="y"
2854 so we will do exactly that.
2855 Note: if we do not allow cmd to be the default shell
2856 we do not need this kind of voodoo */
2857 if (echo_line[0] == '\''
2858 && echo_line[echo_len - 1] == '\''
2859 && strncmp (echo_line + 1, "ac_maketemp=",
2860 strlen ("ac_maketemp=")) == 0)
2861 {
2862 /* remove the enclosing quotes */
2863 memmove (echo_line, echo_line + 1, echo_len - 2);
2864 echo_line[echo_len - 2] = '\0';
2865 }
2866 }
2867 # endif
2868
2869 {
2870 /* Let the shell decide what to do. Put the command line into the
2871 2nd command line argument and hope for the best ;-) */
2872 size_t sh_len = strlen (shell);
2873
2874 /* exactly 3 arguments + NULL */
2875 new_argv = (char **) xmalloc (4 * sizeof (char *));
2876 /* Exactly strlen(shell) + strlen("/c") + strlen(line) + 3 times
2877 the trailing '\0' */
2878 new_argv[0] = (char *) malloc (sh_len + line_len + 5);
2879 memcpy (new_argv[0], shell, sh_len + 1);
2880 new_argv[1] = new_argv[0] + sh_len + 1;
2881 memcpy (new_argv[1], "/c", 3);
2882 new_argv[2] = new_argv[1] + 3;
2883 memcpy (new_argv[2], new_line, line_len + 1);
2884 new_argv[3] = NULL;
2885 }
2886 }
2887 #elif defined(__MSDOS__)
2888 else
2889 {
2890 /* With MSDOS shells, we must construct the command line here
2891 instead of recursively calling ourselves, because we
2892 cannot backslash-escape the special characters (see above). */
2893 new_argv = (char **) xmalloc (sizeof (char *));
2894 line_len = strlen (new_line) - shell_len - sizeof (minus_c) + 1;
2895 new_argv[0] = xmalloc (line_len + 1);
2896 strncpy (new_argv[0],
2897 new_line + shell_len + sizeof (minus_c) - 1, line_len);
2898 new_argv[0][line_len] = '\0';
2899 }
2900 #else
2901 else
2902 fatal (NILF, _("%s (line %d) Bad shell context (!unixy && !batch_mode_shell)\n"),
2903 __FILE__, __LINE__);
2904 #endif
2905 }
2906 #endif /* ! AMIGA */
2907
2908 return new_argv;
2909 }
2910 #endif /* !VMS */
2911
2912 /* Figure out the argument list necessary to run LINE as a command. Try to
2913 avoid using a shell. This routine handles only ' quoting, and " quoting
2914 when no backslash, $ or ` characters are seen in the quotes. Starting
2915 quotes may be escaped with a backslash. If any of the characters in
2916 sh_chars[] is seen, or any of the builtin commands listed in sh_cmds[]
2917 is the first word of a line, the shell is used.
2918
2919 If RESTP is not NULL, *RESTP is set to point to the first newline in LINE.
2920 If *RESTP is NULL, newlines will be ignored.
2921
2922 FILE is the target whose commands these are. It is used for
2923 variable expansion for $(SHELL) and $(IFS). */
2924
2925 char **
construct_command_argv(char * line,char ** restp,struct file * file,char ** batch_filename_ptr)2926 construct_command_argv (char *line, char **restp, struct file *file,
2927 char **batch_filename_ptr)
2928 {
2929 char *shell, *ifs;
2930 char **argv;
2931
2932 #ifdef VMS
2933 char *cptr;
2934 int argc;
2935
2936 argc = 0;
2937 cptr = line;
2938 for (;;)
2939 {
2940 while ((*cptr != 0)
2941 && (isspace ((unsigned char)*cptr)))
2942 cptr++;
2943 if (*cptr == 0)
2944 break;
2945 while ((*cptr != 0)
2946 && (!isspace((unsigned char)*cptr)))
2947 cptr++;
2948 argc++;
2949 }
2950
2951 argv = (char **)malloc (argc * sizeof (char *));
2952 if (argv == 0)
2953 abort ();
2954
2955 cptr = line;
2956 argc = 0;
2957 for (;;)
2958 {
2959 while ((*cptr != 0)
2960 && (isspace ((unsigned char)*cptr)))
2961 cptr++;
2962 if (*cptr == 0)
2963 break;
2964 DB (DB_JOBS, ("argv[%d] = [%s]\n", argc, cptr));
2965 argv[argc++] = cptr;
2966 while ((*cptr != 0)
2967 && (!isspace((unsigned char)*cptr)))
2968 cptr++;
2969 if (*cptr != 0)
2970 *cptr++ = 0;
2971 }
2972 #else
2973 {
2974 /* Turn off --warn-undefined-variables while we expand SHELL and IFS. */
2975 int save = warn_undefined_variables_flag;
2976 warn_undefined_variables_flag = 0;
2977
2978 shell = allocated_variable_expand_for_file ("$(SHELL)", file);
2979 #ifdef WINDOWS32
2980 /*
2981 * Convert to forward slashes so that construct_command_argv_internal()
2982 * is not confused.
2983 */
2984 if (shell) {
2985 char *p = w32ify (shell, 0);
2986 strcpy (shell, p);
2987 }
2988 #endif
2989 #ifdef __EMX__
2990 {
2991 static const char *unixroot = NULL;
2992 static const char *last_shell = "";
2993 static int init = 0;
2994 if (init == 0)
2995 {
2996 unixroot = getenv ("UNIXROOT");
2997 /* unixroot must be NULL or not empty */
2998 if (unixroot && unixroot[0] == '\0') unixroot = NULL;
2999 init = 1;
3000 }
3001
3002 /* if we have an unixroot drive and if shell is not default_shell
3003 (which means it's either cmd.exe or the test has already been
3004 performed) and if shell is an absolute path without drive letter,
3005 try whether it exists e.g.: if "/bin/sh" does not exist use
3006 "$UNIXROOT/bin/sh" instead. */
3007 if (unixroot && shell && strcmp (shell, last_shell) != 0
3008 && (shell[0] == '/' || shell[0] == '\\'))
3009 {
3010 /* trying a new shell, check whether it exists */
3011 size_t size = strlen (shell);
3012 char *buf = xmalloc (size + 7);
3013 memcpy (buf, shell, size);
3014 memcpy (buf + size, ".exe", 5); /* including the trailing '\0' */
3015 if (access (shell, F_OK) != 0 && access (buf, F_OK) != 0)
3016 {
3017 /* try the same for the unixroot drive */
3018 memmove (buf + 2, buf, size + 5);
3019 buf[0] = unixroot[0];
3020 buf[1] = unixroot[1];
3021 if (access (buf, F_OK) == 0)
3022 /* we have found a shell! */
3023 /* free(shell); */
3024 shell = buf;
3025 else
3026 free (buf);
3027 }
3028 else
3029 free (buf);
3030 }
3031 }
3032 #endif /* __EMX__ */
3033
3034 ifs = allocated_variable_expand_for_file ("$(IFS)", file);
3035
3036 warn_undefined_variables_flag = save;
3037 }
3038
3039 argv = construct_command_argv_internal (line, restp, shell, ifs, batch_filename_ptr);
3040
3041 free (shell);
3042 free (ifs);
3043 #endif /* !VMS */
3044 return argv;
3045 }
3046
3047 #if !defined(HAVE_DUP2) && !defined(_AMIGA)
3048 int
dup2(int old,int new)3049 dup2 (int old, int new)
3050 {
3051 int fd;
3052
3053 (void) close (new);
3054 fd = dup (old);
3055 if (fd != new)
3056 {
3057 (void) close (fd);
3058 errno = EMFILE;
3059 return -1;
3060 }
3061
3062 return fd;
3063 }
3064 #endif /* !HAPE_DUP2 && !_AMIGA */
3065
3066 /* On VMS systems, include special VMS functions. */
3067
3068 #ifdef VMS
3069 #include "vmsjobs.c"
3070 #endif
3071