| inotify |
| a powerful yet simple file change notification system |
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| Document started 15 Mar 2005 by Robert Love <rml@novell.com> |
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| (i) User Interface |
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| Inotify is controlled by a set of three sys calls |
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| First step in using inotify is to initialise an inotify instance |
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| int fd = inotify_init (); |
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| Change events are managed by "watches". A watch is an (object,mask) pair where |
| the object is a file or directory and the mask is a bit mask of one or more |
| inotify events that the application wishes to receive. See <linux/inotify.h> |
| for valid events. A watch is referenced by a watch descriptor, or wd. |
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| Watches are added via a path to the file. |
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| Watches on a directory will return events on any files inside of the directory. |
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| Adding a watch is simple, |
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| int wd = inotify_add_watch (fd, path, mask); |
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| You can add a large number of files via something like |
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| for each file to watch { |
| int wd = inotify_add_watch (fd, file, mask); |
| } |
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| You can update an existing watch in the same manner, by passing in a new mask. |
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| An existing watch is removed via the INOTIFY_IGNORE ioctl, for example |
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| inotify_rm_watch (fd, wd); |
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| Events are provided in the form of an inotify_event structure that is read(2) |
| from a inotify instance fd. The filename is of dynamic length and follows the |
| struct. It is of size len. The filename is padded with null bytes to ensure |
| proper alignment. This padding is reflected in len. |
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| You can slurp multiple events by passing a large buffer, for example |
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| size_t len = read (fd, buf, BUF_LEN); |
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| Will return as many events as are available and fit in BUF_LEN. |
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| each inotify instance fd is also select()- and poll()-able. |
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| You can find the size of the current event queue via the FIONREAD ioctl. |
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| All watches are destroyed and cleaned up on close. |
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| (ii) Internal Kernel Implementation |
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| Each open inotify instance is associated with an inotify_device structure. |
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| Each watch is associated with an inotify_watch structure. Watches are chained |
| off of each associated device and each associated inode. |
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| See fs/inotify.c for the locking and lifetime rules. |
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| (iii) Rationale |
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| Q: What is the design decision behind not tying the watch to the open fd of |
| the watched object? |
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| A: Watches are associated with an open inotify device, not an open file. |
| This solves the primary problem with dnotify: keeping the file open pins |
| the file and thus, worse, pins the mount. Dnotify is therefore infeasible |
| for use on a desktop system with removable media as the media cannot be |
| unmounted. |
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| Q: What is the design decision behind using an-fd-per-device as opposed to |
| an fd-per-watch? |
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| A: An fd-per-watch quickly consumes more file descriptors than are allowed, |
| more fd's than are feasible to manage, and more fd's than are optimally |
| select()-able. Yes, root can bump the per-process fd limit and yes, users |
| can use epoll, but requiring both is a silly and extraneous requirement. |
| A watch consumes less memory than an open file, separating the number |
| spaces is thus sensible. The current design is what user-space developers |
| want: Users initialize inotify, once, and add n watches, requiring but one fd |
| and no twiddling with fd limits. Initializing an inotify instance two |
| thousand times is silly. If we can implement user-space's preferences |
| cleanly--and we can, the idr layer makes stuff like this trivial--then we |
| should. |
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| There are other good arguments. With a single fd, there is a single |
| item to block on, which is mapped to a single queue of events. The single |
| fd returns all watch events and also any potential out-of-band data. If |
| every fd was a separate watch, |
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| - There would be no way to get event ordering. Events on file foo and |
| file bar would pop poll() on both fd's, but there would be no way to tell |
| which happened first. A single queue trivially gives you ordering. Such |
| ordering is crucial to existing applications such as Beagle. Imagine |
| "mv a b ; mv b a" events without ordering. |
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| - We'd have to maintain n fd's and n internal queues with state, |
| versus just one. It is a lot messier in the kernel. A single, linear |
| queue is the data structure that makes sense. |
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| - User-space developers prefer the current API. The Beagle guys, for |
| example, love it. Trust me, I asked. It is not a surprise: Who'd want |
| to manage and block on 1000 fd's via select? |
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| - You'd have to manage the fd's, as an example: Call close() when you |
| received a delete event. |
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| - No way to get out of band data. |
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| - 1024 is still too low. ;-) |
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| When you talk about designing a file change notification system that |
| scales to 1000s of directories, juggling 1000s of fd's just does not seem |
| the right interface. It is too heavy. |
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| Q: Why the system call approach? |
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| A: The poor user-space interface is the second biggest problem with dnotify. |
| Signals are a terrible, terrible interface for file notification. Or for |
| anything, for that matter. The ideal solution, from all perspectives, is a |
| file descriptor-based one that allows basic file I/O and poll/select. |
| Obtaining the fd and managing the watches could have been done either via a |
| device file or a family of new system calls. We decided to implement a |
| family of system calls because that is the preffered approach for new kernel |
| features and it means our user interface requirements. |
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| Additionally, it _is_ possible to more than one instance and |
| juggle more than one queue and thus more than one associated fd. |
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