inotify(7)


NAME

   inotify - monitoring filesystem events

DESCRIPTION

   The  inotify API provides a mechanism for monitoring filesystem events.
   Inotify can  be  used  to  monitor  individual  files,  or  to  monitor
   directories.  When a directory is monitored, inotify will return events
   for the directory itself, and for files inside the directory.

   The following system calls are used with this API:

   *  inotify_init(2) creates an  inotify  instance  and  returns  a  file
      descriptor  referring  to  the  inotify  instance.   The more recent
      inotify_init1(2) is like inotify_init(2), but has a  flags  argument
      that provides access to some extra functionality.

   *  inotify_add_watch(2) manipulates the "watch list" associated with an
      inotify instance.  Each item ("watch") in the watch  list  specifies
      the  pathname  of a file or directory, along with some set of events
      that the kernel should monitor for the  file  referred  to  by  that
      pathname.   inotify_add_watch(2) either creates a new watch item, or
      modifies  an  existing  watch.   Each  watch  has  a  unique  "watch
      descriptor",  an  integer  returned by inotify_add_watch(2) when the
      watch is created.

   *  When events occur for monitored files and directories, those  events
      are made available to the application as structured data that can be
      read from the inotify file descriptor using read(2) (see below).

   *  inotify_rm_watch(2) removes an item from an inotify watch list.

   *  When all file descriptors referring to an inotify instance have been
      closed (using close(2)), the underlying object and its resources are
      freed  for  reuse  by  the  kernel;  all  associated   watches   are
      automatically freed.

   With careful programming, an application can use inotify to efficiently
   monitor and cache the state of a set of filesystem  objects.   However,
   robust  applications  should  allow  for  the  fact  that  bugs  in the
   monitoring logic or races of the kind described  below  may  leave  the
   cache  inconsistent  with the filesystem state.  It is probably wise to
   do  some   consistency   checking,   and   rebuild   the   cache   when
   inconsistencies are detected.

   Reading events from an inotify file descriptor
   To  determine  what  events have occurred, an application read(2)s from
   the inotify file descriptor.  If no events have so far occurred,  then,
   assuming  a blocking file descriptor, read(2) will block until at least
   one event occurs (unless interrupted by a signal,  in  which  case  the
   call fails with the error EINTR; see signal(7)).

   Each  successful read(2) returns a buffer containing one or more of the
   following structures:

       struct inotify_event {
           int      wd;       /* Watch descriptor */
           uint32_t mask;     /* Mask describing event */
           uint32_t cookie;   /* Unique cookie associating related
                                 events (for rename(2)) */
           uint32_t len;      /* Size of name field */
           char     name[];   /* Optional null-terminated name */
       };

   wd identifies the watch for which this event occurs.  It is one of  the
   watch descriptors returned by a previous call to inotify_add_watch(2).

   mask contains bits that describe the event that occurred (see below).

   cookie  is  a  unique integer that connects related events.  Currently,
   this is used only for rename events, and allows the resulting  pair  of
   IN_MOVED_FROM   and   IN_MOVED_TO   events   to  be  connected  by  the
   application.  For all other event types, cookie is set to 0.

   The name field is present only when an event is  returned  for  a  file
   inside  a  watched  directory; it identifies the filename within to the
   watched directory.  This filename is null-terminated, and  may  include
   further  null  bytes  ('\0')  to  align  subsequent reads to a suitable
   address boundary.

   The len field counts all of the  bytes  in  name,  including  the  null
   bytes; the length of each inotify_event structure is thus sizeof(struct
   inotify_event)+len.

   The behavior when the buffer given to read(2) is too  small  to  return
   information  about  the  next  event  depends on the kernel version: in
   kernels before 2.6.21, read(2) returns 0; since kernel 2.6.21,  read(2)
   fails with the error EINVAL.  Specifying a buffer of size

       sizeof(struct inotify_event) + NAME_MAX + 1

   will be sufficient to read at least one event.

   inotify events
   The  inotify_add_watch(2)  mask  argument  and  the  mask  field of the
   inotify_event  structure  returned  when  read(2)ing  an  inotify  file
   descriptor   are  both  bit  masks  identifying  inotify  events.   The
   following   bits   can   be   specified   in    mask    when    calling
   inotify_add_watch(2)  and may be returned in the mask field returned by
   read(2):

       IN_ACCESS (+)
              File was accessed (e.g., read(2), execve(2)).

       IN_ATTRIB (*)
              Metadata changed---for example, permissions (e.g.,  chmod(2)),
              timestamps   (e.g.,   utimensat(2)),   extended   attributes
              (setxattr(2)), link count (since Linux 2.6.25; e.g., for the
              target  of  link(2)  and  for  unlink(2)), and user/group ID
              (e.g., chown(2)).

       IN_CLOSE_WRITE (+)
              File opened for writing was closed.

       IN_CLOSE_NOWRITE (*)
              File or directory not opened for writing was closed.

       IN_CREATE (+)
              File/directory created in watched directory  (e.g.,  open(2)
              O_CREAT,  mkdir(2),  link(2),  symlink(2), bind(2) on a UNIX
              domain socket).

       IN_DELETE (+)
              File/directory deleted from watched directory.

       IN_DELETE_SELF
              Watched file/directory was itself deleted.  (This event also
              occurs  if  an  object is moved to another filesystem, since
              mv(1) in effect copies the file to the other filesystem  and
              then deletes it from the original filesystem.)  In addition,
              an IN_IGNORED event will subsequently be generated  for  the
              watch descriptor.

       IN_MODIFY (+)
              File was modified (e.g., write(2), truncate(2)).

       IN_MOVE_SELF
              Watched file/directory was itself moved.

       IN_MOVED_FROM (+)
              Generated for the directory containing the old filename when
              a file is renamed.

       IN_MOVED_TO (+)
              Generated for the directory containing the new filename when
              a file is renamed.

       IN_OPEN (*)
              File or directory was opened.

   When monitoring a directory:

   *  the  events marked above with an asterisk (*) can occur both for the
      directory itself and for objects inside the directory; and

   *  the events marked with a plus sign (+) occur only for objects inside
      the directory (not for the directory itself).

   Note:  when  monitoring  a  directory, events are not generated for the
   files inside the directory when the events are performed via a pathname
   (i.e., a link) that lies outside the monitored directory.

   When  events  are generated for objects inside a watched directory, the
   name field in the returned inotify_event structure identifies the  name
   of the file within the directory.

   The  IN_ALL_EVENTS  macro  is defined as a bit mask of all of the above
   events.  This macro can be used  as  the  mask  argument  when  calling
   inotify_add_watch(2).

   Two additional convenience macros are defined:

       IN_MOVE
              Equates to IN_MOVED_FROM | IN_MOVED_TO.

       IN_CLOSE
              Equates to IN_CLOSE_WRITE | IN_CLOSE_NOWRITE.

   The  following  further  bits  can  be  specified  in mask when calling
   inotify_add_watch(2):

       IN_DONT_FOLLOW (since Linux 2.6.15)
              Don't dereference pathname if it is a symbolic link.

       IN_EXCL_UNLINK (since Linux 2.6.36)
              By default, when  watching  events  on  the  children  of  a
              directory, events are generated for children even after they
              have been unlinked from the directory.  This can  result  in
              large  numbers of uninteresting events for some applications
              (e.g., if watching /tmp, in which many  applications  create
              temporary  files  whose  names  are  immediately  unlinked).
              Specifying IN_EXCL_UNLINK changes the default  behavior,  so
              that  events  are not generated for children after they have
              been unlinked from the watched directory.

       IN_MASK_ADD
              If a watch instance already exists for the filesystem object
              corresponding  to  pathname,  add (OR) the events in mask to
              the watch mask (instead of replacing the mask).

       IN_ONESHOT
              Monitor the filesystem object corresponding to pathname  for
              one event, then remove from watch list.

       IN_ONLYDIR (since Linux 2.6.15)
              Watch  pathname  only if it is a directory.  Using this flag
              provides an application with a  race-free  way  of  ensuring
              that the monitored object is a directory.

   The following bits may be set in the mask field returned by read(2):

       IN_IGNORED
              Watch   was   removed  explicitly  (inotify_rm_watch(2))  or
              automatically  (file  was   deleted,   or   filesystem   was
              unmounted).  See also BUGS.

       IN_ISDIR
              Subject of this event is a directory.

       IN_Q_OVERFLOW
              Event queue overflowed (wd is -1 for this event).

       IN_UNMOUNT
              Filesystem  containing  watched  object  was  unmounted.  In
              addition, an IN_IGNORED event will subsequently be generated
              for the watch descriptor.

   Examples
   Suppose  an  application  is  watching  the  directory dir and the file
   dir/myfile for all events.  The examples below show  some  events  that
   will be generated for these two objects.

       fd = open("dir/myfile", O_RDWR);
              Generates IN_OPEN events for both dir and dir/myfile.

       read(fd, buf, count);
              Generates IN_ACCESS events for both dir and dir/myfile.

       write(fd, buf, count);
              Generates IN_MODIFY events for both dir and dir/myfile.

       fchmod(fd, mode);
              Generates IN_ATTRIB events for both dir and dir/myfile.

       close(fd);
              Generates IN_CLOSE_WRITE events for both dir and dir/myfile.

   Suppose  an  application is watching the directories dir1 and dir2, and
   the file dir1/myfile.  The following examples show some events that may
   be generated.

       link("dir1/myfile", "dir2/new");
              Generates  an  IN_ATTRIB  event  for myfile and an IN_CREATE
              event for dir2.

       rename("dir1/myfile", "dir2/myfile");
              Generates an IN_MOVED_FROM event for  dir1,  an  IN_MOVED_TO
              event  for  dir2, and an IN_MOVE_SELF event for myfile.  The
              IN_MOVED_FROM and IN_MOVED_TO  events  will  have  the  same
              cookie value.

   Suppose that dir1/xx and dir2/yy are (the only) links to the same file,
   and an application  is  watching  dir1,  dir2,  dir1/xx,  and  dir2/yy.
   Executing  the  following  calls in the order given below will generate
   the following events:

       unlink("dir2/yy");
              Generates an IN_ATTRIB event for xx (because its link  count
              changes) and an IN_DELETE event for dir2.

       unlink("dir1/xx");
              Generates  IN_ATTRIB,  IN_DELETE_SELF, and IN_IGNORED events
              for xx, and an IN_DELETE event for dir1.

   Suppose an application is watching the directory dir  and  (the  empty)
   directory dir/subdir.  The following examples show some events that may
   be generated.

       mkdir("dir/new", mode);
              Generates an IN_CREATE | IN_ISDIR event for dir.

       rmdir("dir/subdir");
              Generates IN_DELETE_SELF and IN_IGNORED events  for  subdir,
              and an IN_DELETE | IN_ISDIR event for dir.

   /proc interfaces
   The  following  interfaces  can  be  used to limit the amount of kernel
   memory consumed by inotify:

   /proc/sys/fs/inotify/max_queued_events
          The value in  this  file  is  used  when  an  application  calls
          inotify_init(2)  to  set  an upper limit on the number of events
          that can  be  queued  to  the  corresponding  inotify  instance.
          Events in excess of this limit are dropped, but an IN_Q_OVERFLOW
          event is always generated.

   /proc/sys/fs/inotify/max_user_instances
          This specifies an upper limit on the number of inotify instances
          that can be created per real user ID.

   /proc/sys/fs/inotify/max_user_watches
          This  specifies an upper limit on the number of watches that can
          be created per real user ID.

VERSIONS

   Inotify was merged into the 2.6.13 Linux kernel.  The required  library
   interfaces  were  added  to  glibc  in  version  2.4.  (IN_DONT_FOLLOW,
   IN_MASK_ADD, and IN_ONLYDIR were added in glibc version 2.5.)

CONFORMING TO

   The inotify API is Linux-specific.

NOTES

   Inotify file descriptors can be monitored using select(2), poll(2), and
   epoll(7).  When an event is available, the file descriptor indicates as
   readable.

   Since Linux 2.6.25, signal-driven I/O  notification  is  available  for
   inotify  file  descriptors;  see the discussion of F_SETFL (for setting
   the O_ASYNC flag), F_SETOWN, and F_SETSIG in fcntl(2).   The  siginfo_t
   structure  (described  in  sigaction(2))  that  is passed to the signal
   handler has the following fields set: si_fd is set to the inotify  file
   descriptor number; si_signo is set to the signal number; si_code is set
   to POLL_IN; and POLLIN is set in si_band.

   If successive output  inotify  events  produced  on  the  inotify  file
   descriptor  are  identical (same wd, mask, cookie, and name), then they
   are coalesced into a single event if the older event has not  yet  been
   read (but see BUGS).  This reduces the amount of kernel memory required
   for the event queue, but also  means  that  an  application  can't  use
   inotify to reliably count file events.

   The  events returned by reading from an inotify file descriptor form an
   ordered queue.  Thus, for example, it is guaranteed that when  renaming
   from  one  directory to another, events will be produced in the correct
   order on the inotify file descriptor.

   The set of watch descriptors that is being  monitored  via  an  inotify
   file  descriptor  can  be  viewed  via  the  entry for the inotify file
   descriptor in the process's /proc/[pid]/fdinfo directory.  See  proc(5)
   for further details.  The FIONREAD ioctl(2) returns the number of bytes
   available to read from an inotify file descriptor.

   Limitations and caveats
   The inotify API provides no information about the user or process  that
   triggered the inotify event.  In particular, there is no easy way for a
   process that is monitoring events via  inotify  to  distinguish  events
   that  it  triggers  itself  from  those  that  are  triggered  by other
   processes.

   Inotify reports only events that a user-space program triggers  through
   the  filesystem API.  As a result, it does not catch remote events that
   occur on network filesystems.  (Applications must fall back to  polling
   the  filesystem  to  catch  such events.)  Furthermore, various pseudo-
   filesystems such as /proc, /sys, and /dev/pts are not monitorable  with
   inotify.

   The  inotify  API  does not report file accesses and modifications that
   may occur because of mmap(2), msync(2), and munmap(2).

   The inotify API identifies affected files by filename.  However, by the
   time  an  application  processes  an  inotify  event,  the filename may
   already have been deleted or renamed.

   The inotify API identifies events via watch  descriptors.   It  is  the
   application's  responsibility  to  cache  a  mapping (if one is needed)
   between watch descriptors  and  pathnames.   Be  aware  that  directory
   renamings may affect multiple cached pathnames.

   Inotify   monitoring  of  directories  is  not  recursive:  to  monitor
   subdirectories under a directory, additional watches must  be  created.
   This can take a significant amount time for large directory trees.

   If  monitoring  an  entire directory subtree, and a new subdirectory is
   created in that tree or an existing  directory  is  renamed  into  that
   tree,  be  aware  that  by  the  time  you  create  a watch for the new
   subdirectory, new files (and subdirectories) may already  exist  inside
   the  subdirectory.  Therefore, you may want to scan the contents of the
   subdirectory immediately after  adding  the  watch  (and,  if  desired,
   recursively add watches for any subdirectories that it contains).

   Note that the event queue can overflow.  In this case, events are lost.
   Robust applications  should  handle  the  possibility  of  lost  events
   gracefully.  For example, it may be necessary to rebuild part or all of
   the application cache.  (One simple, but possibly  expensive,  approach
   is  to close the inotify file descriptor, empty the cache, create a new
   inotify file descriptor, and then re-create watches and  cache  entries
   for the objects to be monitored.)

   Dealing with rename() events
   As  noted  above,  the IN_MOVED_FROM and IN_MOVED_TO event pair that is
   generated by rename(2) can be matched up via their shared cookie value.
   However, the task of matching has some challenges.

   These  two events are usually consecutive in the event stream available
   when reading from the inotify file descriptor.  However,  this  is  not
   guaranteed.   If multiple processes are triggering events for monitored
   objects, then (on rare occasions) an arbitrary number of  other  events
   may   appear   between   the   IN_MOVED_FROM  and  IN_MOVED_TO  events.
   Furthermore, it is not guaranteed that the  event  pair  is  atomically
   inserted  into  the  queue:  there  may  be  a brief interval where the
   IN_MOVED_FROM has appeared, but the IN_MOVED_TO has not.

   Matching up the IN_MOVED_FROM and IN_MOVED_TO event pair  generated  by
   rename(2)  is thus inherently racy.  (Don't forget that if an object is
   renamed outside of a monitored directory, there  may  not  even  be  an
   IN_MOVED_TO  event.)  Heuristic approaches (e.g., assume the events are
   always consecutive) can be used to ensure a match in  most  cases,  but
   will  inevitably  miss  some cases, causing the application to perceive
   the IN_MOVED_FROM and IN_MOVED_TO events as being unrelated.  If  watch
   descriptors  are destroyed and re-created as a result, then those watch
   descriptors will be inconsistent with  the  watch  descriptors  in  any
   pending   events.    (Re-creating   the  inotify  file  descriptor  and
   rebuilding the cache may be useful to deal with this scenario.)

   Applications  should  also  allow  for   the   possibility   that   the
   IN_MOVED_FROM  event  was  the  last event that could fit in the buffer
   returned  by  the  current  call  to  read(2),  and  the   accompanying
   IN_MOVED_TO  event  might  be  fetched  only on the next read(2), which
   should be done with a (small)  timeout  to  allow  for  the  fact  that
   insertion  of  the  IN_MOVED_FROM-IN_MOVED_TO event pair is not atomic,
   and also the possibility that there may not be any IN_MOVED_TO event.

BUGS

   Before Linux 3.19, fallocate(2) did  not  create  any  inotify  events.
   Since Linux 3.19, calls to fallocate(2) generate IN_MODIFY events.

   In kernels before 2.6.16, the IN_ONESHOT mask flag does not work.

   As  originally  designed  and  implemented, the IN_ONESHOT flag did not
   cause an IN_IGNORED event to be generated when the  watch  was  dropped
   after  one  event.   However, as an unintended effect of other changes,
   since Linux 2.6.36, an IN_IGNORED event is generated in this case.

   Before kernel 2.6.25, the kernel code that  was  intended  to  coalesce
   successive  identical  events  (i.e.,  the two most recent events could
   potentially be coalesced if the older had not yet  been  read)  instead
   checked  if  the  most  recent event could be coalesced with the oldest
   unread event.

   When a watch descriptor is removed by calling  inotify_rm_watch(2)  (or
   because  a  watch file is deleted or the filesystem that contains it is
   unmounted), any pending unread events for that watch descriptor  remain
   available  to  read.   As  watch descriptors are subsequently allocated
   with inotify_add_watch(2), the  kernel  cycles  through  the  range  of
   possible   watch   descriptors  (0  to  INT_MAX)  incrementally.   When
   allocating a free watch descriptor, no check is  made  to  see  whether
   that  watch  descriptor  number  has  any  pending unread events in the
   inotify queue.   Thus,  it  can  happen  that  a  watch  descriptor  is
   reallocated  even  when  pending  unread  events  exist  for a previous
   incarnation of that watch descriptor number, with the result  that  the
   application  might  then  read  those  events  and  interpret  them  as
   belonging  to  the  file  associated  with  the  newly  recycled  watch
   descriptor.   In  practice,  the  likelihood of hitting this bug may be
   extremely low, since it requires  that  an  application  cycle  through
   INT_MAX  watch  descriptors,  release  a watch descriptor while leaving
   unread events for that watch descriptor in the queue, and then  recycle
   that watch descriptor.  For this reason, and because there have been no
   reports of the bug occurring in real-world applications,  as  of  Linux
   3.15,  no  kernel changes have yet been made to eliminate this possible
   bug.

EXAMPLE

   The following program demonstrates the usage of the  inotify  API.   It
   marks  the directories passed as a command-line arguments and waits for
   events of type IN_OPEN, IN_CLOSE_NOWRITE and IN_CLOSE_WRITE.

   The  following   output   was   recorded   while   editing   the   file
   /home/user/temp/foo  and  listing  directory /tmp.  Before the file and
   the directory were opened, IN_OPEN events occurred.  After the file was
   closed,  an  IN_CLOSE_WRITE  event  occurred.   After the directory was
   closed, an IN_CLOSE_NOWRITE event occurred.  Execution of  the  program
   ended when the user pressed the ENTER key.

   Example output
       $ ./a.out /tmp /home/user/temp
       Press enter key to terminate.
       Listening for events.
       IN_OPEN: /home/user/temp/foo [file]
       IN_CLOSE_WRITE: /home/user/temp/foo [file]
       IN_OPEN: /tmp/ [directory]
       IN_CLOSE_NOWRITE: /tmp/ [directory]

       Listening for events stopped.

   Program source
   #include <errno.h>
   #include <poll.h>
   #include <stdio.h>
   #include <stdlib.h>
   #include <sys/inotify.h>
   #include <unistd.h>

   /* Read all available inotify events from the file descriptor 'fd'.
      wd is the table of watch descriptors for the directories in argv.
      argc is the length of wd and argv.
      argv is the list of watched directories.
      Entry 0 of wd and argv is unused. */

   static void
   handle_events(int fd, int *wd, int argc, char* argv[])
   {
       /* Some systems cannot read integer variables if they are not
          properly aligned. On other systems, incorrect alignment may
          decrease performance. Hence, the buffer used for reading from
          the inotify file descriptor should have the same alignment as
          struct inotify_event. */

       char buf[4096]
           __attribute__ ((aligned(__alignof__(struct inotify_event))));
       const struct inotify_event *event;
       int i;
       ssize_t len;
       char *ptr;

       /* Loop while events can be read from inotify file descriptor. */

       for (;;) {

           /* Read some events. */

           len = read(fd, buf, sizeof buf);
           if (len == -1 && errno != EAGAIN) {
               perror("read");
               exit(EXIT_FAILURE);
           }

           /* If the nonblocking read() found no events to read, then
              it returns -1 with errno set to EAGAIN. In that case,
              we exit the loop. */

           if (len <= 0)
               break;

           /* Loop over all events in the buffer */

           for (ptr = buf; ptr < buf + len;
                   ptr += sizeof(struct inotify_event) + event->len) {

               event = (const struct inotify_event *) ptr;

               /* Print event type */

               if (event->mask & IN_OPEN)
                   printf("IN_OPEN: ");
               if (event->mask & IN_CLOSE_NOWRITE)
                   printf("IN_CLOSE_NOWRITE: ");
               if (event->mask & IN_CLOSE_WRITE)
                   printf("IN_CLOSE_WRITE: ");

               /* Print the name of the watched directory */

               for (i = 1; i < argc; ++i) {
                   if (wd[i] == event->wd) {
                       printf("%s/", argv[i]);
                       break;
                   }
               }

               /* Print the name of the file */

               if (event->len)
                   printf("%s", event->name);

               /* Print type of filesystem object */

               if (event->mask & IN_ISDIR)
                   printf(" [directory]\n");
               else
                   printf(" [file]\n");
           }
       }
   }

   int
   main(int argc, char* argv[])
   {
       char buf;
       int fd, i, poll_num;
       int *wd;
       nfds_t nfds;
       struct pollfd fds[2];

       if (argc < 2) {
           printf("Usage: %s PATH [PATH ...]\n", argv[0]);
           exit(EXIT_FAILURE);
       }

       printf("Press ENTER key to terminate.\n");

       /* Create the file descriptor for accessing the inotify API */

       fd = inotify_init1(IN_NONBLOCK);
       if (fd == -1) {
           perror("inotify_init1");
           exit(EXIT_FAILURE);
       }

       /* Allocate memory for watch descriptors */

       wd = calloc(argc, sizeof(int));
       if (wd == NULL) {
           perror("calloc");
           exit(EXIT_FAILURE);
       }

       /* Mark directories for events
          - file was opened
          - file was closed */

       for (i = 1; i < argc; i++) {
           wd[i] = inotify_add_watch(fd, argv[i],
                                     IN_OPEN | IN_CLOSE);
           if (wd[i] == -1) {
               fprintf(stderr, "Cannot watch '%s'\n", argv[i]);
               perror("inotify_add_watch");
               exit(EXIT_FAILURE);
           }
       }

       /* Prepare for polling */

       nfds = 2;

       /* Console input */

       fds[0].fd = STDIN_FILENO;
       fds[0].events = POLLIN;

       /* Inotify input */

       fds[1].fd = fd;
       fds[1].events = POLLIN;

       /* Wait for events and/or terminal input */

       printf("Listening for events.\n");
       while (1) {
           poll_num = poll(fds, nfds, -1);
           if (poll_num == -1) {
               if (errno == EINTR)
                   continue;
               perror("poll");
               exit(EXIT_FAILURE);
           }

           if (poll_num > 0) {

               if (fds[0].revents & POLLIN) {

                   /* Console input is available. Empty stdin and quit */

                   while (read(STDIN_FILENO, &buf, 1) > 0 && buf != '\n')
                       continue;
                   break;
               }

               if (fds[1].revents & POLLIN) {

                   /* Inotify events are available */

                   handle_events(fd, wd, argc, argv);
               }
           }
       }

       printf("Listening for events stopped.\n");

       /* Close inotify file descriptor */

       close(fd);

       free(wd);
       exit(EXIT_SUCCESS);
   }

SEE ALSO

   inotifywait(1), inotifywatch(1), inotify_add_watch(2), inotify_init(2),
   inotify_init1(2), inotify_rm_watch(2), read(2), stat(2), fanotify(7)

   Documentation/filesystems/inotify.txt in the Linux kernel source tree

COLOPHON

   This page is part of release 4.09 of the Linux  man-pages  project.   A
   description  of  the project, information about reporting bugs, and the
   latest    version    of    this    page,    can     be     found     at
   https://www.kernel.org/doc/man-pages/.





Opportunity


Personal Opportunity - Free software gives you access to billions of dollars of software at no cost. Use this software for your business, personal use or to develop a profitable skill. Access to source code provides access to a level of capabilities/information that companies protect though copyrights. Open source is a core component of the Internet and it is available to you. Leverage the billions of dollars in resources and capabilities to build a career, establish a business or change the world. The potential is endless for those who understand the opportunity.

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The Free Books Library is a collection of thousands of the most popular public domain books in an online readable format. The collection includes great classical literature and more recent works where the U.S. copyright has expired. These books are yours to read and use without restrictions.


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Education


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Linux Manual Pages - A man or manual page is a form of software documentation found on Linux/Unix operating systems. Topics covered include computer programs (including library and system calls), formal standards and conventions, and even abstract concepts.