xref: /freebsd/usr.sbin/cron/cron/do_command.c (revision f3e7afe2d7b262ab55ab818445d4dfdb6e0c70a9)
1 /* Copyright 1988,1990,1993,1994 by Paul Vixie
2  * All rights reserved
3  *
4  * Distribute freely, except: don't remove my name from the source or
5  * documentation (don't take credit for my work), mark your changes (don't
6  * get me blamed for your possible bugs), don't alter or remove this
7  * notice.  May be sold if buildable source is provided to buyer.  No
8  * warrantee of any kind, express or implied, is included with this
9  * software; use at your own risk, responsibility for damages (if any) to
10  * anyone resulting from the use of this software rests entirely with the
11  * user.
12  *
13  * Send bug reports, bug fixes, enhancements, requests, flames, etc., and
14  * I'll try to keep a version up to date.  I can be reached as follows:
15  * Paul Vixie          <paul@vix.com>          uunet!decwrl!vixie!paul
16  */
17 
18 #if !defined(lint) && !defined(LINT)
19 static const char rcsid[] =
20   "$FreeBSD$";
21 #endif
22 
23 
24 #include "cron.h"
25 #include <sys/signal.h>
26 #if defined(sequent)
27 # include <sys/universe.h>
28 #endif
29 #if defined(SYSLOG)
30 # include <syslog.h>
31 #endif
32 #if defined(LOGIN_CAP)
33 # include <login_cap.h>
34 #endif
35 #ifdef PAM
36 # include <security/pam_appl.h>
37 # include <security/openpam.h>
38 #endif
39 
40 
41 static void		child_process(entry *, user *),
42 			do_univ(user *);
43 
44 
45 void
46 do_command(e, u)
47 	entry	*e;
48 	user	*u;
49 {
50 	Debug(DPROC, ("[%d] do_command(%s, (%s,%d,%d))\n",
51 		getpid(), e->cmd, u->name, e->uid, e->gid))
52 
53 	/* fork to become asynchronous -- parent process is done immediately,
54 	 * and continues to run the normal cron code, which means return to
55 	 * tick().  the child and grandchild don't leave this function, alive.
56 	 *
57 	 * vfork() is unsuitable, since we have much to do, and the parent
58 	 * needs to be able to run off and fork other processes.
59 	 */
60 	switch (fork()) {
61 	case -1:
62 		log_it("CRON",getpid(),"error","can't fork");
63 		break;
64 	case 0:
65 		/* child process */
66 		pidfile_close(pfh);
67 		child_process(e, u);
68 		Debug(DPROC, ("[%d] child process done, exiting\n", getpid()))
69 		_exit(OK_EXIT);
70 		break;
71 	default:
72 		/* parent process */
73 		break;
74 	}
75 	Debug(DPROC, ("[%d] main process returning to work\n", getpid()))
76 }
77 
78 
79 static void
80 child_process(e, u)
81 	entry	*e;
82 	user	*u;
83 {
84 	int		stdin_pipe[2], stdout_pipe[2];
85 	register char	*input_data;
86 	char		*usernm, *mailto;
87 	int		children = 0;
88 # if defined(LOGIN_CAP)
89 	struct passwd	*pwd;
90 	login_cap_t *lc;
91 # endif
92 
93 	Debug(DPROC, ("[%d] child_process('%s')\n", getpid(), e->cmd))
94 
95 	/* mark ourselves as different to PS command watchers by upshifting
96 	 * our program name.  This has no effect on some kernels.
97 	 */
98 	setproctitle("running job");
99 
100 	/* discover some useful and important environment settings
101 	 */
102 	usernm = env_get("LOGNAME", e->envp);
103 	mailto = env_get("MAILTO", e->envp);
104 
105 #ifdef PAM
106 	/* use PAM to see if the user's account is available,
107 	 * i.e., not locked or expired or whatever.  skip this
108 	 * for system tasks from /etc/crontab -- they can run
109 	 * as any user.
110 	 */
111 	if (strcmp(u->name, SYS_NAME)) {	/* not equal */
112 		pam_handle_t *pamh = NULL;
113 		int pam_err;
114 		struct pam_conv pamc = {
115 			.conv = openpam_nullconv,
116 			.appdata_ptr = NULL
117 		};
118 
119 		Debug(DPROC, ("[%d] checking account with PAM\n", getpid()))
120 
121 		/* u->name keeps crontab owner name while LOGNAME is the name
122 		 * of user to run command on behalf of.  they should be the
123 		 * same for a task from a per-user crontab.
124 		 */
125 		if (strcmp(u->name, usernm)) {
126 			log_it(usernm, getpid(), "username ambiguity", u->name);
127 			exit(ERROR_EXIT);
128 		}
129 
130 		pam_err = pam_start("cron", usernm, &pamc, &pamh);
131 		if (pam_err != PAM_SUCCESS) {
132 			log_it("CRON", getpid(), "error", "can't start PAM");
133 			exit(ERROR_EXIT);
134 		}
135 
136 		pam_err = pam_acct_mgmt(pamh, PAM_SILENT);
137 		/* Expired password shouldn't prevent the job from running. */
138 		if (pam_err != PAM_SUCCESS && pam_err != PAM_NEW_AUTHTOK_REQD) {
139 			log_it(usernm, getpid(), "USER", "account unavailable");
140 			exit(ERROR_EXIT);
141 		}
142 
143 		pam_end(pamh, pam_err);
144 	}
145 #endif
146 
147 #ifdef USE_SIGCHLD
148 	/* our parent is watching for our death by catching SIGCHLD.  we
149 	 * do not care to watch for our children's deaths this way -- we
150 	 * use wait() explicitly.  so we have to disable the signal (which
151 	 * was inherited from the parent).
152 	 */
153 	(void) signal(SIGCHLD, SIG_DFL);
154 #else
155 	/* on system-V systems, we are ignoring SIGCLD.  we have to stop
156 	 * ignoring it now or the wait() in cron_pclose() won't work.
157 	 * because of this, we have to wait() for our children here, as well.
158 	 */
159 	(void) signal(SIGCLD, SIG_DFL);
160 #endif /*BSD*/
161 
162 	/* create some pipes to talk to our future child
163 	 */
164 	if (pipe(stdin_pipe) != 0 || pipe(stdout_pipe) != 0) {
165 		log_it("CRON", getpid(), "error", "can't pipe");
166 		exit(ERROR_EXIT);
167 	}
168 
169 	/* since we are a forked process, we can diddle the command string
170 	 * we were passed -- nobody else is going to use it again, right?
171 	 *
172 	 * if a % is present in the command, previous characters are the
173 	 * command, and subsequent characters are the additional input to
174 	 * the command.  Subsequent %'s will be transformed into newlines,
175 	 * but that happens later.
176 	 *
177 	 * If there are escaped %'s, remove the escape character.
178 	 */
179 	/*local*/{
180 		register int escaped = FALSE;
181 		register int ch;
182 		register char *p;
183 
184 		for (input_data = p = e->cmd; (ch = *input_data);
185 		     input_data++, p++) {
186 			if (p != input_data)
187 			    *p = ch;
188 			if (escaped) {
189 				if (ch == '%' || ch == '\\')
190 					*--p = ch;
191 				escaped = FALSE;
192 				continue;
193 			}
194 			if (ch == '\\') {
195 				escaped = TRUE;
196 				continue;
197 			}
198 			if (ch == '%') {
199 				*input_data++ = '\0';
200 				break;
201 			}
202 		}
203 		*p = '\0';
204 	}
205 
206 	/* fork again, this time so we can exec the user's command.
207 	 */
208 	switch (vfork()) {
209 	case -1:
210 		log_it("CRON",getpid(),"error","can't vfork");
211 		exit(ERROR_EXIT);
212 		/*NOTREACHED*/
213 	case 0:
214 		Debug(DPROC, ("[%d] grandchild process Vfork()'ed\n",
215 			      getpid()))
216 
217 		if (e->uid == ROOT_UID)
218 			Jitter = RootJitter;
219 		if (Jitter != 0) {
220 			srandom(getpid());
221 			sleep(random() % Jitter);
222 		}
223 
224 		/* write a log message.  we've waited this long to do it
225 		 * because it was not until now that we knew the PID that
226 		 * the actual user command shell was going to get and the
227 		 * PID is part of the log message.
228 		 */
229 		/*local*/{
230 			char *x = mkprints((u_char *)e->cmd, strlen(e->cmd));
231 
232 			log_it(usernm, getpid(), "CMD", x);
233 			free(x);
234 		}
235 
236 		/* that's the last thing we'll log.  close the log files.
237 		 */
238 #ifdef SYSLOG
239 		closelog();
240 #endif
241 
242 		/* get new pgrp, void tty, etc.
243 		 */
244 		(void) setsid();
245 
246 		/* close the pipe ends that we won't use.  this doesn't affect
247 		 * the parent, who has to read and write them; it keeps the
248 		 * kernel from recording us as a potential client TWICE --
249 		 * which would keep it from sending SIGPIPE in otherwise
250 		 * appropriate circumstances.
251 		 */
252 		close(stdin_pipe[WRITE_PIPE]);
253 		close(stdout_pipe[READ_PIPE]);
254 
255 		/* grandchild process.  make std{in,out} be the ends of
256 		 * pipes opened by our daddy; make stderr go to stdout.
257 		 */
258 		close(STDIN);	dup2(stdin_pipe[READ_PIPE], STDIN);
259 		close(STDOUT);	dup2(stdout_pipe[WRITE_PIPE], STDOUT);
260 		close(STDERR);	dup2(STDOUT, STDERR);
261 
262 		/* close the pipes we just dup'ed.  The resources will remain.
263 		 */
264 		close(stdin_pipe[READ_PIPE]);
265 		close(stdout_pipe[WRITE_PIPE]);
266 
267 		/* set our login universe.  Do this in the grandchild
268 		 * so that the child can invoke /usr/lib/sendmail
269 		 * without surprises.
270 		 */
271 		do_univ(u);
272 
273 # if defined(LOGIN_CAP)
274 		/* Set user's entire context, but skip the environment
275 		 * as cron provides a separate interface for this
276 		 */
277 		if ((pwd = getpwnam(usernm)) == NULL)
278 			pwd = getpwuid(e->uid);
279 		lc = NULL;
280 		if (pwd != NULL) {
281 			pwd->pw_gid = e->gid;
282 			if (e->class != NULL)
283 				lc = login_getclass(e->class);
284 		}
285 		if (pwd &&
286 		    setusercontext(lc, pwd, e->uid,
287 			    LOGIN_SETALL & ~(LOGIN_SETPATH|LOGIN_SETENV)) == 0)
288 			(void) endpwent();
289 		else {
290 			/* fall back to the old method */
291 			(void) endpwent();
292 # endif
293 			/* set our directory, uid and gid.  Set gid first,
294 			 * since once we set uid, we've lost root privileges.
295 			 */
296 			if (setgid(e->gid) != 0) {
297 				log_it(usernm, getpid(),
298 				    "error", "setgid failed");
299 				exit(ERROR_EXIT);
300 			}
301 # if defined(BSD)
302 			if (initgroups(usernm, e->gid) != 0) {
303 				log_it(usernm, getpid(),
304 				    "error", "initgroups failed");
305 				exit(ERROR_EXIT);
306 			}
307 # endif
308 			if (setlogin(usernm) != 0) {
309 				log_it(usernm, getpid(),
310 				    "error", "setlogin failed");
311 				exit(ERROR_EXIT);
312 			}
313 			if (setuid(e->uid) != 0) {
314 				log_it(usernm, getpid(),
315 				    "error", "setuid failed");
316 				exit(ERROR_EXIT);
317 			}
318 			/* we aren't root after this..*/
319 #if defined(LOGIN_CAP)
320 		}
321 		if (lc != NULL)
322 			login_close(lc);
323 #endif
324 		chdir(env_get("HOME", e->envp));
325 
326 		/* exec the command.
327 		 */
328 		{
329 			char	*shell = env_get("SHELL", e->envp);
330 
331 # if DEBUGGING
332 			if (DebugFlags & DTEST) {
333 				fprintf(stderr,
334 				"debug DTEST is on, not exec'ing command.\n");
335 				fprintf(stderr,
336 				"\tcmd='%s' shell='%s'\n", e->cmd, shell);
337 				_exit(OK_EXIT);
338 			}
339 # endif /*DEBUGGING*/
340 			execle(shell, shell, "-c", e->cmd, (char *)NULL,
341 			    e->envp);
342 			warn("execle: couldn't exec `%s'", shell);
343 			_exit(ERROR_EXIT);
344 		}
345 		break;
346 	default:
347 		/* parent process */
348 		break;
349 	}
350 
351 	children++;
352 
353 	/* middle process, child of original cron, parent of process running
354 	 * the user's command.
355 	 */
356 
357 	Debug(DPROC, ("[%d] child continues, closing pipes\n", getpid()))
358 
359 	/* close the ends of the pipe that will only be referenced in the
360 	 * grandchild process...
361 	 */
362 	close(stdin_pipe[READ_PIPE]);
363 	close(stdout_pipe[WRITE_PIPE]);
364 
365 	/*
366 	 * write, to the pipe connected to child's stdin, any input specified
367 	 * after a % in the crontab entry.  while we copy, convert any
368 	 * additional %'s to newlines.  when done, if some characters were
369 	 * written and the last one wasn't a newline, write a newline.
370 	 *
371 	 * Note that if the input data won't fit into one pipe buffer (2K
372 	 * or 4K on most BSD systems), and the child doesn't read its stdin,
373 	 * we would block here.  thus we must fork again.
374 	 */
375 
376 	if (*input_data && fork() == 0) {
377 		register FILE	*out = fdopen(stdin_pipe[WRITE_PIPE], "w");
378 		register int	need_newline = FALSE;
379 		register int	escaped = FALSE;
380 		register int	ch;
381 
382 		if (out == NULL) {
383 			warn("fdopen failed in child2");
384 			_exit(ERROR_EXIT);
385 		}
386 
387 		Debug(DPROC, ("[%d] child2 sending data to grandchild\n", getpid()))
388 
389 		/* close the pipe we don't use, since we inherited it and
390 		 * are part of its reference count now.
391 		 */
392 		close(stdout_pipe[READ_PIPE]);
393 
394 		/* translation:
395 		 *	\% -> %
396 		 *	%  -> \n
397 		 *	\x -> \x	for all x != %
398 		 */
399 		while ((ch = *input_data++)) {
400 			if (escaped) {
401 				if (ch != '%')
402 					putc('\\', out);
403 			} else {
404 				if (ch == '%')
405 					ch = '\n';
406 			}
407 
408 			if (!(escaped = (ch == '\\'))) {
409 				putc(ch, out);
410 				need_newline = (ch != '\n');
411 			}
412 		}
413 		if (escaped)
414 			putc('\\', out);
415 		if (need_newline)
416 			putc('\n', out);
417 
418 		/* close the pipe, causing an EOF condition.  fclose causes
419 		 * stdin_pipe[WRITE_PIPE] to be closed, too.
420 		 */
421 		fclose(out);
422 
423 		Debug(DPROC, ("[%d] child2 done sending to grandchild\n", getpid()))
424 		exit(0);
425 	}
426 
427 	/* close the pipe to the grandkiddie's stdin, since its wicked uncle
428 	 * ernie back there has it open and will close it when he's done.
429 	 */
430 	close(stdin_pipe[WRITE_PIPE]);
431 
432 	children++;
433 
434 	/*
435 	 * read output from the grandchild.  it's stderr has been redirected to
436 	 * it's stdout, which has been redirected to our pipe.  if there is any
437 	 * output, we'll be mailing it to the user whose crontab this is...
438 	 * when the grandchild exits, we'll get EOF.
439 	 */
440 
441 	Debug(DPROC, ("[%d] child reading output from grandchild\n", getpid()))
442 
443 	/*local*/{
444 		register FILE	*in = fdopen(stdout_pipe[READ_PIPE], "r");
445 		register int	ch;
446 
447 		if (in == NULL) {
448 			warn("fdopen failed in child");
449 			_exit(ERROR_EXIT);
450 		}
451 
452 		ch = getc(in);
453 		if (ch != EOF) {
454 			register FILE	*mail;
455 			register int	bytes = 1;
456 			int		status = 0;
457 
458 			Debug(DPROC|DEXT,
459 				("[%d] got data (%x:%c) from grandchild\n",
460 					getpid(), ch, ch))
461 
462 			/* get name of recipient.  this is MAILTO if set to a
463 			 * valid local username; USER otherwise.
464 			 */
465 			if (mailto == NULL) {
466 				/* MAILTO not present, set to USER,
467 				 * unless globally overriden.
468 				 */
469 				if (defmailto)
470 					mailto = defmailto;
471 				else
472 					mailto = usernm;
473 			}
474 			if (mailto && *mailto == '\0')
475 				mailto = NULL;
476 
477 			/* if we are supposed to be mailing, MAILTO will
478 			 * be non-NULL.  only in this case should we set
479 			 * up the mail command and subjects and stuff...
480 			 */
481 
482 			if (mailto) {
483 				register char	**env;
484 				auto char	mailcmd[MAX_COMMAND];
485 				auto char	hostname[MAXHOSTNAMELEN];
486 
487 				if (gethostname(hostname, MAXHOSTNAMELEN) == -1)
488 					hostname[0] = '\0';
489 				hostname[sizeof(hostname) - 1] = '\0';
490 				(void) snprintf(mailcmd, sizeof(mailcmd),
491 					       MAILARGS, MAILCMD);
492 				if (!(mail = cron_popen(mailcmd, "w", e))) {
493 					warn("%s", MAILCMD);
494 					(void) _exit(ERROR_EXIT);
495 				}
496 				fprintf(mail, "From: Cron Daemon <%s@%s>\n",
497 					usernm, hostname);
498 				fprintf(mail, "To: %s\n", mailto);
499 				fprintf(mail, "Subject: Cron <%s@%s> %s\n",
500 					usernm, first_word(hostname, "."),
501 					e->cmd);
502 # if defined(MAIL_DATE)
503 				fprintf(mail, "Date: %s\n",
504 					arpadate(&TargetTime));
505 # endif /* MAIL_DATE */
506 				for (env = e->envp;  *env;  env++)
507 					fprintf(mail, "X-Cron-Env: <%s>\n",
508 						*env);
509 				fprintf(mail, "\n");
510 
511 				/* this was the first char from the pipe
512 				 */
513 				putc(ch, mail);
514 			}
515 
516 			/* we have to read the input pipe no matter whether
517 			 * we mail or not, but obviously we only write to
518 			 * mail pipe if we ARE mailing.
519 			 */
520 
521 			while (EOF != (ch = getc(in))) {
522 				bytes++;
523 				if (mailto)
524 					putc(ch, mail);
525 			}
526 
527 			/* only close pipe if we opened it -- i.e., we're
528 			 * mailing...
529 			 */
530 
531 			if (mailto) {
532 				Debug(DPROC, ("[%d] closing pipe to mail\n",
533 					getpid()))
534 				/* Note: the pclose will probably see
535 				 * the termination of the grandchild
536 				 * in addition to the mail process, since
537 				 * it (the grandchild) is likely to exit
538 				 * after closing its stdout.
539 				 */
540 				status = cron_pclose(mail);
541 			}
542 
543 			/* if there was output and we could not mail it,
544 			 * log the facts so the poor user can figure out
545 			 * what's going on.
546 			 */
547 			if (mailto && status) {
548 				char buf[MAX_TEMPSTR];
549 
550 				snprintf(buf, sizeof(buf),
551 			"mailed %d byte%s of output but got status 0x%04x\n",
552 					bytes, (bytes==1)?"":"s",
553 					status);
554 				log_it(usernm, getpid(), "MAIL", buf);
555 			}
556 
557 		} /*if data from grandchild*/
558 
559 		Debug(DPROC, ("[%d] got EOF from grandchild\n", getpid()))
560 
561 		fclose(in);	/* also closes stdout_pipe[READ_PIPE] */
562 	}
563 
564 	/* wait for children to die.
565 	 */
566 	for (;  children > 0;  children--)
567 	{
568 		WAIT_T		waiter;
569 		PID_T		pid;
570 
571 		Debug(DPROC, ("[%d] waiting for grandchild #%d to finish\n",
572 			getpid(), children))
573 		pid = wait(&waiter);
574 		if (pid < OK) {
575 			Debug(DPROC, ("[%d] no more grandchildren--mail written?\n",
576 				getpid()))
577 			break;
578 		}
579 		Debug(DPROC, ("[%d] grandchild #%d finished, status=%04x",
580 			getpid(), pid, WEXITSTATUS(waiter)))
581 		if (WIFSIGNALED(waiter) && WCOREDUMP(waiter))
582 			Debug(DPROC, (", dumped core"))
583 		Debug(DPROC, ("\n"))
584 	}
585 }
586 
587 
588 static void
589 do_univ(u)
590 	user	*u;
591 {
592 #if defined(sequent)
593 /* Dynix (Sequent) hack to put the user associated with
594  * the passed user structure into the ATT universe if
595  * necessary.  We have to dig the gecos info out of
596  * the user's password entry to see if the magic
597  * "universe(att)" string is present.
598  */
599 
600 	struct	passwd	*p;
601 	char	*s;
602 	int	i;
603 
604 	p = getpwuid(u->uid);
605 	(void) endpwent();
606 
607 	if (p == NULL)
608 		return;
609 
610 	s = p->pw_gecos;
611 
612 	for (i = 0; i < 4; i++)
613 	{
614 		if ((s = strchr(s, ',')) == NULL)
615 			return;
616 		s++;
617 	}
618 	if (strcmp(s, "universe(att)"))
619 		return;
620 
621 	(void) universe(U_ATT);
622 #endif
623 }
624