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1 /* xwrap.c - wrappers around existing library functions.
2  *
3  * Functions with the x prefix are wrappers that either succeed or kill the
4  * program with an error message, but never return failure. They usually have
5  * the same arguments and return value as the function they wrap.
6  *
7  * Copyright 2006 Rob Landley <rob@landley.net>
8  */
9 
10 #include "toys.h"
11 
12 // strcpy and strncat with size checking. Size is the total space in "dest",
13 // including null terminator. Exit if there's not enough space for the string
14 // (including space for the null terminator), because silently truncating is
15 // still broken behavior. (And leaving the string unterminated is INSANE.)
xstrncpy(char * dest,char * src,size_t size)16 void xstrncpy(char *dest, char *src, size_t size)
17 {
18   if (strlen(src)+1 > size) error_exit("'%s' > %ld bytes", src, (long)size);
19   strcpy(dest, src);
20 }
21 
xstrncat(char * dest,char * src,size_t size)22 void xstrncat(char *dest, char *src, size_t size)
23 {
24   long len = strlen(dest);
25 
26   if (len+strlen(src)+1 > size)
27     error_exit("'%s%s' > %ld bytes", dest, src, (long)size);
28   strcpy(dest+len, src);
29 }
30 
31 // We replaced exit(), _exit(), and atexit() with xexit(), _xexit(), and
32 // sigatexit(). This gives _xexit() the option to siglongjmp(toys.rebound, 1)
33 // instead of exiting, lets xexit() report stdout flush failures to stderr
34 // and change the exit code to indicate error, lets our toys.exit function
35 // change happen for signal exit paths and lets us remove the functions
36 // after we've called them.
37 
_xexit(void)38 void _xexit(void)
39 {
40   if (toys.rebound) siglongjmp(*toys.rebound, 1);
41 
42   _exit(toys.exitval);
43 }
44 
xexit(void)45 void xexit(void)
46 {
47   // Call toys.xexit functions in reverse order added.
48   while (toys.xexit) {
49     // This is typecasting xexit->arg to a function pointer,then calling it.
50     // Using the invalid signal number 0 lets the signal handlers distinguish
51     // an actual signal from a regular exit.
52     ((void (*)(int))(toys.xexit->arg))(0);
53 
54     free(llist_pop(&toys.xexit));
55   }
56   if (fflush(NULL) || ferror(stdout))
57     if (!toys.exitval) perror_msg("write");
58   _xexit();
59 }
60 
xmmap(void * addr,size_t length,int prot,int flags,int fd,off_t off)61 void *xmmap(void *addr, size_t length, int prot, int flags, int fd, off_t off)
62 {
63   void *ret = mmap(addr, length, prot, flags, fd, off);
64   if (ret == MAP_FAILED) perror_exit("mmap");
65   return ret;
66 }
67 
68 // Die unless we can allocate memory.
xmalloc(size_t size)69 void *xmalloc(size_t size)
70 {
71   void *ret = malloc(size);
72   if (!ret) error_exit("xmalloc(%ld)", (long)size);
73 
74   return ret;
75 }
76 
77 // Die unless we can allocate prezeroed memory.
xzalloc(size_t size)78 void *xzalloc(size_t size)
79 {
80   void *ret = xmalloc(size);
81   memset(ret, 0, size);
82   return ret;
83 }
84 
85 // Die unless we can change the size of an existing allocation, possibly
86 // moving it.  (Notice different arguments from libc function.)
xrealloc(void * ptr,size_t size)87 void *xrealloc(void *ptr, size_t size)
88 {
89   ptr = realloc(ptr, size);
90   if (!ptr) error_exit("xrealloc");
91 
92   return ptr;
93 }
94 
95 // Die unless we can allocate a copy of this many bytes of string.
xstrndup(char * s,size_t n)96 char *xstrndup(char *s, size_t n)
97 {
98   char *ret = strndup(s, ++n);
99 
100   if (!ret) error_exit("xstrndup");
101   ret[--n] = 0;
102 
103   return ret;
104 }
105 
106 // Die unless we can allocate a copy of this string.
xstrdup(char * s)107 char *xstrdup(char *s)
108 {
109   return xstrndup(s, strlen(s));
110 }
111 
xmemdup(void * s,long len)112 void *xmemdup(void *s, long len)
113 {
114   void *ret = xmalloc(len);
115   memcpy(ret, s, len);
116 
117   return ret;
118 }
119 
120 // Die unless we can allocate enough space to sprintf() into.
xmprintf(char * format,...)121 char *xmprintf(char *format, ...)
122 {
123   va_list va, va2;
124   int len;
125   char *ret;
126 
127   va_start(va, format);
128   va_copy(va2, va);
129 
130   // How long is it?
131   len = vsnprintf(0, 0, format, va);
132   len++;
133   va_end(va);
134 
135   // Allocate and do the sprintf()
136   ret = xmalloc(len);
137   vsnprintf(ret, len, format, va2);
138   va_end(va2);
139 
140   return ret;
141 }
142 
xprintf(char * format,...)143 void xprintf(char *format, ...)
144 {
145   va_list va;
146   va_start(va, format);
147 
148   vprintf(format, va);
149   va_end(va);
150   if (fflush(stdout) || ferror(stdout)) perror_exit("write");
151 }
152 
xputs(char * s)153 void xputs(char *s)
154 {
155   if (EOF == puts(s) || fflush(stdout) || ferror(stdout)) perror_exit("write");
156 }
157 
xputc(char c)158 void xputc(char c)
159 {
160   if (EOF == fputc(c, stdout) || fflush(stdout) || ferror(stdout))
161     perror_exit("write");
162 }
163 
xflush(void)164 void xflush(void)
165 {
166   if (fflush(stdout) || ferror(stdout)) perror_exit("write");;
167 }
168 
169 // This is called through the XVFORK macro because parent/child of vfork
170 // share a stack, so child returning from a function would stomp the return
171 // address parent would need. Solution: make vfork() an argument so processes
172 // diverge before function gets called.
xvforkwrap(pid_t pid)173 pid_t __attribute__((returns_twice)) xvforkwrap(pid_t pid)
174 {
175   if (pid == -1) perror_exit("vfork");
176 
177   // Signal to xexec() and friends that we vforked so can't recurse
178   toys.stacktop = 0;
179 
180   return pid;
181 }
182 
183 // Die unless we can exec argv[] (or run builtin command).  Note that anything
184 // with a path isn't a builtin, so /bin/sh won't match the builtin sh.
xexec(char ** argv)185 void xexec(char **argv)
186 {
187   // Only recurse to builtin when we have multiplexer and !vfork context.
188   if (CFG_TOYBOX && !CFG_TOYBOX_NORECURSE && toys.stacktop) toy_exec(argv);
189   execvp(argv[0], argv);
190 
191   perror_msg("exec %s", argv[0]);
192   toys.exitval = 127;
193   if (!CFG_TOYBOX_FORK) _exit(toys.exitval);
194   xexit();
195 }
196 
197 // Spawn child process, capturing stdin/stdout.
198 // argv[]: command to exec. If null, child re-runs original program with
199 //         toys.stacktop zeroed.
200 // pipes[2]: stdin, stdout of new process, only allocated if zero on way in,
201 //           pass NULL to skip pipe allocation entirely.
202 // return: pid of child process
xpopen_both(char ** argv,int * pipes)203 pid_t xpopen_both(char **argv, int *pipes)
204 {
205   int cestnepasun[4], pid;
206 
207   // Make the pipes? Note this won't set either pipe to 0 because if fds are
208   // allocated in order and if fd0 was free it would go to cestnepasun[0]
209   if (pipes) {
210     for (pid = 0; pid < 2; pid++) {
211       if (pipes[pid] != 0) continue;
212       if (pipe(cestnepasun+(2*pid))) perror_exit("pipe");
213       pipes[pid] = cestnepasun[pid+1];
214     }
215   }
216 
217   // Child process.
218   if (!(pid = CFG_TOYBOX_FORK ? xfork() : XVFORK())) {
219     // Dance of the stdin/stdout redirection.
220     if (pipes) {
221       // if we had no stdin/out, pipe handles could overlap, so test for it
222       // and free up potentially overlapping pipe handles before reuse
223       if (pipes[1] != -1) close(cestnepasun[2]);
224       if (pipes[0] != -1) {
225         close(cestnepasun[1]);
226         if (cestnepasun[0]) {
227           dup2(cestnepasun[0], 0);
228           close(cestnepasun[0]);
229         }
230       }
231       if (pipes[1] != -1) {
232         dup2(cestnepasun[3], 1);
233         dup2(cestnepasun[3], 2);
234         if (cestnepasun[3] > 2 || !cestnepasun[3]) close(cestnepasun[3]);
235       }
236     }
237     if (argv) xexec(argv);
238 
239     // In fork() case, force recursion because we know it's us.
240     if (CFG_TOYBOX_FORK) {
241       toy_init(toys.which, toys.argv);
242       toys.stacktop = 0;
243       toys.which->toy_main();
244       xexit();
245     // In vfork() case, exec /proc/self/exe with high bit of first letter set
246     // to tell main() we reentered.
247     } else {
248       char *s = "/proc/self/exe";
249 
250       // We did a nommu-friendly vfork but must exec to continue.
251       // setting high bit of argv[0][0] to let new process know
252       **toys.argv |= 0x80;
253       execv(s, toys.argv);
254       perror_msg_raw(s);
255 
256       _exit(127);
257     }
258   }
259 
260   // Parent process
261   if (!CFG_TOYBOX_FORK) **toys.argv &= 0x7f;
262   if (pipes) {
263     if (pipes[0] != -1) close(cestnepasun[0]);
264     if (pipes[1] != -1) close(cestnepasun[3]);
265   }
266 
267   return pid;
268 }
269 
270 // Wait for child process to exit, then return adjusted exit code.
xwaitpid(pid_t pid)271 int xwaitpid(pid_t pid)
272 {
273   int status;
274 
275   while (-1 == waitpid(pid, &status, 0) && errno == EINTR);
276 
277   return WIFEXITED(status) ? WEXITSTATUS(status) : WTERMSIG(status)+127;
278 }
279 
xpclose_both(pid_t pid,int * pipes)280 int xpclose_both(pid_t pid, int *pipes)
281 {
282   if (pipes) {
283     close(pipes[0]);
284     close(pipes[1]);
285   }
286 
287   return xwaitpid(pid);
288 }
289 
290 // Wrapper to xpopen with a pipe for just one of stdin/stdout
xpopen(char ** argv,int * pipe,int isstdout)291 pid_t xpopen(char **argv, int *pipe, int isstdout)
292 {
293   int pipes[2], pid;
294 
295   pipes[!isstdout] = -1;
296   pipes[!!isstdout] = 0;
297   pid = xpopen_both(argv, pipes);
298   *pipe = pid ? pipes[!!isstdout] : -1;
299 
300   return pid;
301 }
302 
xpclose(pid_t pid,int pipe)303 int xpclose(pid_t pid, int pipe)
304 {
305   close(pipe);
306 
307   return xpclose_both(pid, 0);
308 }
309 
310 // Call xpopen and wait for it to finish, keeping existing stdin/stdout.
xrun(char ** argv)311 int xrun(char **argv)
312 {
313   return xpclose_both(xpopen_both(argv, 0), 0);
314 }
315 
xaccess(char * path,int flags)316 void xaccess(char *path, int flags)
317 {
318   if (access(path, flags)) perror_exit("Can't access '%s'", path);
319 }
320 
321 // Die unless we can delete a file.  (File must exist to be deleted.)
xunlink(char * path)322 void xunlink(char *path)
323 {
324   if (unlink(path)) perror_exit("unlink '%s'", path);
325 }
326 
327 // Die unless we can open/create a file, returning file descriptor.
328 // The meaning of O_CLOEXEC is reversed (it defaults on, pass it to disable)
329 // and WARN_ONLY tells us not to exit.
xcreate_stdio(char * path,int flags,int mode)330 int xcreate_stdio(char *path, int flags, int mode)
331 {
332   int fd = open(path, (flags^O_CLOEXEC)&~WARN_ONLY, mode);
333 
334   if (fd == -1) ((mode&WARN_ONLY) ? perror_msg_raw : perror_exit_raw)(path);
335   return fd;
336 }
337 
338 // Die unless we can open a file, returning file descriptor.
xopen_stdio(char * path,int flags)339 int xopen_stdio(char *path, int flags)
340 {
341   return xcreate_stdio(path, flags, 0);
342 }
343 
xpipe(int * pp)344 void xpipe(int *pp)
345 {
346   if (pipe(pp)) perror_exit("xpipe");
347 }
348 
xclose(int fd)349 void xclose(int fd)
350 {
351   if (close(fd)) perror_exit("xclose");
352 }
353 
xdup(int fd)354 int xdup(int fd)
355 {
356   if (fd != -1) {
357     fd = dup(fd);
358     if (fd == -1) perror_exit("xdup");
359   }
360   return fd;
361 }
362 
363 // Move file descriptor above stdin/stdout/stderr, using /dev/null to consume
364 // old one. (We should never be called with stdin/stdout/stderr closed, but...)
notstdio(int fd)365 int notstdio(int fd)
366 {
367   if (fd<0) return fd;
368 
369   while (fd<3) {
370     int fd2 = xdup(fd);
371 
372     close(fd);
373     xopen_stdio("/dev/null", O_RDWR);
374     fd = fd2;
375   }
376 
377   return fd;
378 }
379 
380 // Create a file but don't return stdin/stdout/stderr
xcreate(char * path,int flags,int mode)381 int xcreate(char *path, int flags, int mode)
382 {
383   return notstdio(xcreate_stdio(path, flags, mode));
384 }
385 
386 // Open a file descriptor NOT in stdin/stdout/stderr
xopen(char * path,int flags)387 int xopen(char *path, int flags)
388 {
389   return notstdio(xopen_stdio(path, flags));
390 }
391 
392 // Open read only, treating "-" as a synonym for stdin, defaulting to warn only
openro(char * path,int flags)393 int openro(char *path, int flags)
394 {
395   if (!strcmp(path, "-")) return 0;
396 
397   return xopen(path, flags^WARN_ONLY);
398 }
399 
400 // Open read only, treating "-" as a synonym for stdin.
xopenro(char * path)401 int xopenro(char *path)
402 {
403   return openro(path, O_RDONLY|WARN_ONLY);
404 }
405 
xfdopen(int fd,char * mode)406 FILE *xfdopen(int fd, char *mode)
407 {
408   FILE *f = fdopen(fd, mode);
409 
410   if (!f) perror_exit("xfdopen");
411 
412   return f;
413 }
414 
415 // Die unless we can open/create a file, returning FILE *.
xfopen(char * path,char * mode)416 FILE *xfopen(char *path, char *mode)
417 {
418   FILE *f = fopen(path, mode);
419   if (!f) perror_exit("No file %s", path);
420   return f;
421 }
422 
423 // Die if there's an error other than EOF.
xread(int fd,void * buf,size_t len)424 size_t xread(int fd, void *buf, size_t len)
425 {
426   ssize_t ret = read(fd, buf, len);
427   if (ret < 0) perror_exit("xread");
428 
429   return ret;
430 }
431 
xreadall(int fd,void * buf,size_t len)432 void xreadall(int fd, void *buf, size_t len)
433 {
434   if (len != readall(fd, buf, len)) perror_exit("xreadall");
435 }
436 
437 // There's no xwriteall(), just xwrite().  When we read, there may or may not
438 // be more data waiting.  When we write, there is data and it had better go
439 // somewhere.
440 
xwrite(int fd,void * buf,size_t len)441 void xwrite(int fd, void *buf, size_t len)
442 {
443   if (len != writeall(fd, buf, len)) perror_exit("xwrite");
444 }
445 
446 // Die if lseek fails, probably due to being called on a pipe.
447 
xlseek(int fd,off_t offset,int whence)448 off_t xlseek(int fd, off_t offset, int whence)
449 {
450   offset = lseek(fd, offset, whence);
451   if (offset<0) perror_exit("lseek");
452 
453   return offset;
454 }
455 
xgetcwd(void)456 char *xgetcwd(void)
457 {
458   char *buf = getcwd(NULL, 0);
459   if (!buf) perror_exit("xgetcwd");
460 
461   return buf;
462 }
463 
xstat(char * path,struct stat * st)464 void xstat(char *path, struct stat *st)
465 {
466   if(stat(path, st)) perror_exit("Can't stat %s", path);
467 }
468 
469 // Cannonicalize path, even to file with one or more missing components at end.
470 // if exact, require last path component to exist
xabspath(char * path,int exact)471 char *xabspath(char *path, int exact)
472 {
473   struct string_list *todo, *done = 0;
474   int try = 9999, dirfd = open("/", 0);;
475   char *ret;
476 
477   // If this isn't an absolute path, start with cwd.
478   if (*path != '/') {
479     char *temp = xgetcwd();
480 
481     splitpath(path, splitpath(temp, &todo));
482     free(temp);
483   } else splitpath(path, &todo);
484 
485   // Iterate through path components
486   while (todo) {
487     struct string_list *new = llist_pop(&todo), **tail;
488     ssize_t len;
489 
490     if (!try--) {
491       errno = ELOOP;
492       goto error;
493     }
494 
495     // Removable path componenents.
496     if (!strcmp(new->str, ".") || !strcmp(new->str, "..")) {
497       int x = new->str[1];
498 
499       free(new);
500       if (x) {
501         if (done) free(llist_pop(&done));
502         len = 0;
503       } else continue;
504 
505     // Is this a symlink?
506     } else len = readlinkat(dirfd, new->str, libbuf, sizeof(libbuf));
507 
508     if (len>4095) goto error;
509     if (len<1) {
510       int fd;
511       char *s = "..";
512 
513       // For .. just move dirfd
514       if (len) {
515         // Not a symlink: add to linked list, move dirfd, fail if error
516         if ((exact || todo) && errno != EINVAL) goto error;
517         new->next = done;
518         done = new;
519         if (errno == EINVAL && !todo) break;
520         s = new->str;
521       }
522       fd = openat(dirfd, s, 0);
523       if (fd == -1 && (exact || todo || errno != ENOENT)) goto error;
524       close(dirfd);
525       dirfd = fd;
526       continue;
527     }
528 
529     // If this symlink is to an absolute path, discard existing resolved path
530     libbuf[len] = 0;
531     if (*libbuf == '/') {
532       llist_traverse(done, free);
533       done=0;
534       close(dirfd);
535       dirfd = open("/", 0);
536     }
537     free(new);
538 
539     // prepend components of new path. Note symlink to "/" will leave new NULL
540     tail = splitpath(libbuf, &new);
541 
542     // symlink to "/" will return null and leave tail alone
543     if (new) {
544       *tail = todo;
545       todo = new;
546     }
547   }
548   close(dirfd);
549 
550   // At this point done has the path, in reverse order. Reverse list while
551   // calculating buffer length.
552 
553   try = 2;
554   while (done) {
555     struct string_list *temp = llist_pop(&done);;
556 
557     if (todo) try++;
558     try += strlen(temp->str);
559     temp->next = todo;
560     todo = temp;
561   }
562 
563   // Assemble return buffer
564 
565   ret = xmalloc(try);
566   *ret = '/';
567   ret [try = 1] = 0;
568   while (todo) {
569     if (try>1) ret[try++] = '/';
570     try = stpcpy(ret+try, todo->str) - ret;
571     free(llist_pop(&todo));
572   }
573 
574   return ret;
575 
576 error:
577   close(dirfd);
578   llist_traverse(todo, free);
579   llist_traverse(done, free);
580 
581   return NULL;
582 }
583 
xchdir(char * path)584 void xchdir(char *path)
585 {
586   if (chdir(path)) error_exit("chdir '%s'", path);
587 }
588 
xchroot(char * path)589 void xchroot(char *path)
590 {
591   if (chroot(path)) error_exit("chroot '%s'", path);
592   xchdir("/");
593 }
594 
xgetpwuid(uid_t uid)595 struct passwd *xgetpwuid(uid_t uid)
596 {
597   struct passwd *pwd = getpwuid(uid);
598   if (!pwd) error_exit("bad uid %ld", (long)uid);
599   return pwd;
600 }
601 
xgetgrgid(gid_t gid)602 struct group *xgetgrgid(gid_t gid)
603 {
604   struct group *group = getgrgid(gid);
605 
606   if (!group) perror_exit("gid %ld", (long)gid);
607   return group;
608 }
609 
xgetuid(char * name)610 unsigned xgetuid(char *name)
611 {
612   struct passwd *up = getpwnam(name);
613   char *s = 0;
614   long uid;
615 
616   if (up) return up->pw_uid;
617 
618   uid = estrtol(name, &s, 10);
619   if (!errno && s && !*s && uid>=0 && uid<=UINT_MAX) return uid;
620 
621   error_exit("bad user '%s'", name);
622 }
623 
xgetgid(char * name)624 unsigned xgetgid(char *name)
625 {
626   struct group *gr = getgrnam(name);
627   char *s = 0;
628   long gid;
629 
630   if (gr) return gr->gr_gid;
631 
632   gid = estrtol(name, &s, 10);
633   if (!errno && s && !*s && gid>=0 && gid<=UINT_MAX) return gid;
634 
635   error_exit("bad group '%s'", name);
636 }
637 
xgetpwnam(char * name)638 struct passwd *xgetpwnam(char *name)
639 {
640   struct passwd *up = getpwnam(name);
641 
642   if (!up) perror_exit("user '%s'", name);
643   return up;
644 }
645 
xgetgrnam(char * name)646 struct group *xgetgrnam(char *name)
647 {
648   struct group *gr = getgrnam(name);
649 
650   if (!gr) perror_exit("group '%s'", name);
651   return gr;
652 }
653 
654 // setuid() can fail (for example, too many processes belonging to that user),
655 // which opens a security hole if the process continues as the original user.
656 
xsetuser(struct passwd * pwd)657 void xsetuser(struct passwd *pwd)
658 {
659   if (initgroups(pwd->pw_name, pwd->pw_gid) || setgid(pwd->pw_uid)
660       || setuid(pwd->pw_uid)) perror_exit("xsetuser '%s'", pwd->pw_name);
661 }
662 
663 // This can return null (meaning file not found).  It just won't return null
664 // for memory allocation reasons.
xreadlink(char * name)665 char *xreadlink(char *name)
666 {
667   int len, size = 0;
668   char *buf = 0;
669 
670   // Grow by 64 byte chunks until it's big enough.
671   for(;;) {
672     size +=64;
673     buf = xrealloc(buf, size);
674     len = readlink(name, buf, size);
675 
676     if (len<0) {
677       free(buf);
678       return 0;
679     }
680     if (len<size) {
681       buf[len]=0;
682       return buf;
683     }
684   }
685 }
686 
xreadfile(char * name,char * buf,off_t len)687 char *xreadfile(char *name, char *buf, off_t len)
688 {
689   if (!(buf = readfile(name, buf, len))) perror_exit("Bad '%s'", name);
690 
691   return buf;
692 }
693 
694 // The data argument to ioctl() is actually long, but it's usually used as
695 // a pointer. If you need to feed in a number, do (void *)(long) typecast.
xioctl(int fd,int request,void * data)696 int xioctl(int fd, int request, void *data)
697 {
698   int rc;
699 
700   errno = 0;
701   rc = ioctl(fd, request, data);
702   if (rc == -1 && errno) perror_exit("ioctl %x", request);
703 
704   return rc;
705 }
706 
707 // Open a /var/run/NAME.pid file, dying if we can't write it or if it currently
708 // exists and is this executable.
xpidfile(char * name)709 void xpidfile(char *name)
710 {
711   char pidfile[256], spid[32];
712   int i, fd;
713   pid_t pid;
714 
715   sprintf(pidfile, "/var/run/%s.pid", name);
716   // Try three times to open the sucker.
717   for (i=0; i<3; i++) {
718     fd = open(pidfile, O_CREAT|O_EXCL|O_WRONLY, 0644);
719     if (fd != -1) break;
720 
721     // If it already existed, read it.  Loop for race condition.
722     fd = open(pidfile, O_RDONLY);
723     if (fd == -1) continue;
724 
725     // Is the old program still there?
726     spid[xread(fd, spid, sizeof(spid)-1)] = 0;
727     close(fd);
728     pid = atoi(spid);
729     if (pid < 1 || (kill(pid, 0) && errno == ESRCH)) unlink(pidfile);
730 
731     // An else with more sanity checking might be nice here.
732   }
733 
734   if (i == 3) error_exit("xpidfile %s", name);
735 
736   xwrite(fd, spid, sprintf(spid, "%ld\n", (long)getpid()));
737   close(fd);
738 }
739 
740 // Copy the rest of in to out and close both files.
741 
xsendfile(int in,int out)742 long long xsendfile(int in, int out)
743 {
744   long long total = 0;
745   long len;
746 
747   if (in<0) return 0;
748   for (;;) {
749     len = xread(in, libbuf, sizeof(libbuf));
750     if (len<1) break;
751     xwrite(out, libbuf, len);
752     total += len;
753   }
754 
755   return total;
756 }
757 
xstrtod(char * s)758 double xstrtod(char *s)
759 {
760   char *end;
761   double d;
762 
763   errno = 0;
764   d = strtod(s, &end);
765   if (!errno && *end) errno = E2BIG;
766   if (errno) perror_exit("strtod %s", s);
767 
768   return d;
769 }
770 
771 // parse fractional seconds with optional s/m/h/d suffix
xparsetime(char * arg,long units,long * fraction)772 long xparsetime(char *arg, long units, long *fraction)
773 {
774   double d;
775   long l;
776 
777   if (CFG_TOYBOX_FLOAT) d = strtod(arg, &arg);
778   else l = strtoul(arg, &arg, 10);
779 
780   // Parse suffix
781   if (*arg) {
782     int ismhd[]={1,60,3600,86400}, i = stridx("smhd", *arg);
783 
784     if (i == -1) error_exit("Unknown suffix '%c'", *arg);
785     if (CFG_TOYBOX_FLOAT) d *= ismhd[i];
786     else l *= ismhd[i];
787   }
788 
789   if (CFG_TOYBOX_FLOAT) {
790     l = (long)d;
791     if (fraction) *fraction = units*(d-l);
792   } else if (fraction) *fraction = 0;
793 
794   return l;
795 }
796 
797 // Compile a regular expression into a regex_t
xregcomp(regex_t * preg,char * regex,int cflags)798 void xregcomp(regex_t *preg, char *regex, int cflags)
799 {
800   int rc = regcomp(preg, regex, cflags);
801 
802   if (rc) {
803     regerror(rc, preg, libbuf, sizeof(libbuf));
804     error_exit("xregcomp: %s", libbuf);
805   }
806 }
807 
xtzset(char * new)808 char *xtzset(char *new)
809 {
810   char *old = getenv("TZ");
811 
812   if (old) old = xstrdup(old);
813   if (new ? setenv("TZ", new, 1) : unsetenv("TZ")) perror_exit("setenv");
814   tzset();
815 
816   return old;
817 }
818 
819 // Set a signal handler
xsignal(int signal,void * handler)820 void xsignal(int signal, void *handler)
821 {
822   struct sigaction *sa = (void *)libbuf;
823 
824   memset(sa, 0, sizeof(struct sigaction));
825   sa->sa_handler = handler;
826 
827   if (sigaction(signal, sa, 0)) perror_exit("xsignal %d", signal);
828 }
829