glib/gio/inotify/inotify-kernel.c

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/*
Copyright (C) 2005 John McCutchan
Copyright © 2015 Canonical Limited
The Gnome Library is free software; you can redistribute it and/or
modify it under the terms of the GNU Library General Public License as
published by the Free Software Foundation; either version 2 of the
License, or (at your option) any later version.
The Gnome Library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Library General Public License for more details.
You should have received a copy of the GNU Library General Public
License along with the Gnome Library; see the file COPYING.LIB. If not,
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see <http://www.gnu.org/licenses/>.
Authors:
Ryan Lortie <desrt@desrt.ca>
John McCutchan <john@johnmccutchan.com>
*/
#include "config.h"
#include <stdio.h>
#include <sys/ioctl.h>
#include <unistd.h>
#include <errno.h>
#include <string.h>
#include <glib.h>
#include "inotify-kernel.h"
#include <sys/inotify.h>
#include <glib/glib-unix.h>
#include "glib-private.h"
/* From inotify(7) */
#define MAX_EVENT_SIZE (sizeof(struct inotify_event) + NAME_MAX + 1)
/* Amount of time to sleep on receipt of uninteresting events */
#define BOREDOM_SLEEP_TIME (100 * G_TIME_SPAN_MILLISECOND)
/* Define limits on the maximum amount of time and maximum amount of
* interceding events between FROM/TO that can be merged.
*/
#define MOVE_PAIR_DELAY (10 * G_TIME_SPAN_MILLISECOND)
#define MOVE_PAIR_DISTANCE (100)
/* We use the lock from inotify-helper.c
*
* We only have to take it on our read callback.
*
* The rest of locking is taken care of in inotify-helper.c
*/
G_LOCK_EXTERN (inotify_lock);
static ik_event_t *
ik_event_new (struct inotify_event *kevent,
gint64 now)
{
ik_event_t *event = g_new0 (ik_event_t, 1);
event->wd = kevent->wd;
event->mask = kevent->mask;
event->cookie = kevent->cookie;
event->len = kevent->len;
event->timestamp = now;
if (event->len)
event->name = g_strdup (kevent->name);
else
substantially rework file monitors Remove all event merging and dispatch logic from GFileMonitor. The only implementation of GFileMonitor outside of glib is in gvfs and it already does these things properly. Get rid of GLocalDirectoryMonitor. We will use a single class, GLocalFileMonitor, for both directory and file monitoring. This will prevent every single backend from having to create two objects separately (eg: ginotifydirectorymonitor.c and ginotifyfilemonitor.c). Introduce GFileMonitorSource as a thread-safe cross-context dispatch mechanism. Put it in GLocalFileMonitor. All backends will be expected to dispatch via the source and not touch the GFileMonitor object at all from the worker thread. Remove all construct properties from GLocalFileMonitor and remove the "context" construct property from GFileMonitor. All backends must now get the information about what file to monitor from the ->start() call which is mandatory to implement. Remove the implementation of rate limiting in GFileMonitor and add an implementation in GLocalFileMonitor. gvfs never did anything with this anyway, but if it wanted to, it would have to implement it for itself. This was done in order to get the rate_limit field into the GFileMonitorSource so that it could be safely accessed from the worker thread. Expose g_local_file_is_remote() internally for NFS detection. With the "is_remote" functionality exposed, we can now move all functions for creating local file monitors to a proper location in glocalfilemonitor.c Port the inotify backend to adjust to the changes above. None of the other backends are ported yet. Those will come in future commits.
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event->name = NULL;
return event;
}
void
_ik_event_free (ik_event_t *event)
{
if (event->pair)
substantially rework file monitors Remove all event merging and dispatch logic from GFileMonitor. The only implementation of GFileMonitor outside of glib is in gvfs and it already does these things properly. Get rid of GLocalDirectoryMonitor. We will use a single class, GLocalFileMonitor, for both directory and file monitoring. This will prevent every single backend from having to create two objects separately (eg: ginotifydirectorymonitor.c and ginotifyfilemonitor.c). Introduce GFileMonitorSource as a thread-safe cross-context dispatch mechanism. Put it in GLocalFileMonitor. All backends will be expected to dispatch via the source and not touch the GFileMonitor object at all from the worker thread. Remove all construct properties from GLocalFileMonitor and remove the "context" construct property from GFileMonitor. All backends must now get the information about what file to monitor from the ->start() call which is mandatory to implement. Remove the implementation of rate limiting in GFileMonitor and add an implementation in GLocalFileMonitor. gvfs never did anything with this anyway, but if it wanted to, it would have to implement it for itself. This was done in order to get the rate_limit field into the GFileMonitorSource so that it could be safely accessed from the worker thread. Expose g_local_file_is_remote() internally for NFS detection. With the "is_remote" functionality exposed, we can now move all functions for creating local file monitors to a proper location in glocalfilemonitor.c Port the inotify backend to adjust to the changes above. None of the other backends are ported yet. Those will come in future commits.
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{
event->pair->pair = NULL;
_ik_event_free (event->pair);
}
g_free (event->name);
g_free (event);
}
typedef struct
{
GSource source;
GQueue queue;
gpointer fd_tag;
gint fd;
GHashTable *unmatched_moves;
gboolean is_bored;
} InotifyKernelSource;
static InotifyKernelSource *inotify_source;
static gint64
ik_source_get_dispatch_time (InotifyKernelSource *iks)
{
ik_event_t *head;
head = g_queue_peek_head (&iks->queue);
/* nothing in the queue: not ready */
if (!head)
return -1;
/* if it's not an unpaired move, it is ready now */
if (~head->mask & IN_MOVED_FROM || head->pair)
return 0;
/* if the queue is too long then it's ready now */
if (iks->queue.length > MOVE_PAIR_DISTANCE)
return 0;
/* otherwise, it's ready after the delay */
return head->timestamp + MOVE_PAIR_DELAY;
}
static gboolean
ik_source_can_dispatch_now (InotifyKernelSource *iks,
gint64 now)
{
gint64 dispatch_time;
dispatch_time = ik_source_get_dispatch_time (iks);
return 0 <= dispatch_time && dispatch_time <= now;
}
static gsize
ik_source_read_some_events (InotifyKernelSource *iks,
gchar *buffer,
gsize buffer_len)
{
gssize result;
again:
result = read (iks->fd, buffer, buffer_len);
if (result < 0)
{
if (errno == EINTR)
goto again;
if (errno == EAGAIN)
return 0;
g_error ("inotify read(): %s", g_strerror (errno));
}
else if (result == 0)
g_error ("inotify unexpectedly hit eof");
return result;
}
static gchar *
ik_source_read_all_the_events (InotifyKernelSource *iks,
gchar *buffer,
gsize buffer_len,
gsize *length_out)
{
gsize n_read;
n_read = ik_source_read_some_events (iks, buffer, buffer_len);
/* Check if we might have gotten another event if we had passed in a
* bigger buffer...
*/
if (n_read + MAX_EVENT_SIZE > buffer_len)
{
gchar *new_buffer;
guint n_readable;
gint result;
/* figure out how many more bytes there are to read */
result = ioctl (iks->fd, FIONREAD, &n_readable);
if (result != 0)
g_error ("inotify ioctl(FIONREAD): %s", g_strerror (errno));
if (n_readable != 0)
{
/* there is in fact more data. allocate a new buffer, copy
* the existing data, and then append the remaining.
*/
new_buffer = g_malloc (n_read + n_readable);
memcpy (new_buffer, buffer, n_read);
n_read += ik_source_read_some_events (iks, new_buffer + n_read, n_readable);
buffer = new_buffer;
/* There may be new events in the buffer that were added after
* the FIONREAD was performed, but we can't risk getting into
* a loop. We'll get them next time.
*/
}
}
*length_out = n_read;
return buffer;
}
static gboolean
ik_source_dispatch (GSource *source,
GSourceFunc func,
gpointer user_data)
{
InotifyKernelSource *iks = (InotifyKernelSource *) source;
gboolean (*user_callback) (ik_event_t *event) = (void *) func;
gboolean interesting = FALSE;
gint64 now;
now = g_source_get_time (source);
if (iks->is_bored || g_source_query_unix_fd (source, iks->fd_tag))
{
gchar stack_buffer[4096];
gsize buffer_len;
gchar *buffer;
gsize offset;
/* We want to read all of the available events.
*
* We need to do it in a finite number of steps so that we don't
* get caught in a loop of read() with another process
* continuously adding events each time we drain them.
*
* In the normal case we will have only a few events in the queue,
* so start out by reading into a small stack-allocated buffer.
* Even though we're on a fresh stack frame, there is no need to
* pointlessly blow up with the size of the worker thread stack
* with a huge buffer here.
*
* If the result is large enough to cause us to suspect that
* another event may be pending then we allocate a buffer on the
* heap that can hold all of the events and read (once!) into that
* buffer.
*/
buffer = ik_source_read_all_the_events (iks, stack_buffer, sizeof stack_buffer, &buffer_len);
offset = 0;
while (offset < buffer_len)
{
struct inotify_event *kevent = (struct inotify_event *) (buffer + offset);
ik_event_t *event;
event = ik_event_new (kevent, now);
offset += sizeof (struct inotify_event) + event->len;
if (event->mask & IN_MOVED_TO)
{
ik_event_t *pair;
pair = g_hash_table_lookup (iks->unmatched_moves, GUINT_TO_POINTER (event->cookie));
if (pair != NULL)
{
g_assert (!pair->pair);
g_hash_table_remove (iks->unmatched_moves, GUINT_TO_POINTER (event->cookie));
event->is_second_in_pair = TRUE;
event->pair = pair;
pair->pair = event;
continue;
}
interesting = TRUE;
}
else if (event->mask & IN_MOVED_FROM)
{
gboolean new;
new = g_hash_table_insert (iks->unmatched_moves, GUINT_TO_POINTER (event->cookie), event);
if G_UNLIKELY (!new)
g_warning ("inotify: got IN_MOVED_FROM event with already-pending cookie %#x", event->cookie);
interesting = TRUE;
}
g_queue_push_tail (&iks->queue, event);
}
if (buffer_len == 0)
{
/* We can end up reading nothing if we arrived here due to a
* boredom timer but the stream of events stopped meanwhile.
*
* In that case, we need to switch back to polling the file
* descriptor in the usual way.
*/
g_assert (iks->is_bored);
interesting = TRUE;
}
if (buffer != stack_buffer)
g_free (buffer);
}
while (ik_source_can_dispatch_now (iks, now))
{
ik_event_t *event;
/* callback will free the event */
event = g_queue_pop_head (&iks->queue);
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if (event->mask & IN_MOVED_TO && !event->pair)
g_hash_table_remove (iks->unmatched_moves, GUINT_TO_POINTER (event->cookie));
G_LOCK (inotify_lock);
interesting |= (* user_callback) (event);
G_UNLOCK (inotify_lock);
}
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/* The queue gets blocked iff we have unmatched moves */
g_assert ((iks->queue.length > 0) == (g_hash_table_size (iks->unmatched_moves) > 0));
/* Here's where we decide what will wake us up next.
*
* If the last event was interesting then we will wake up on the fd or
* when the timeout is reached on an unpaired move (if any).
*
* If the last event was uninteresting then we will wake up after the
* shorter of the boredom sleep or any timeout for a unpaired move.
*/
if (interesting)
{
if (iks->is_bored)
{
g_source_modify_unix_fd (source, iks->fd_tag, G_IO_IN);
iks->is_bored = FALSE;
}
g_source_set_ready_time (source, ik_source_get_dispatch_time (iks));
}
else
{
guint64 dispatch_time = ik_source_get_dispatch_time (iks);
guint64 boredom_time = now + BOREDOM_SLEEP_TIME;
if (!iks->is_bored)
{
g_source_modify_unix_fd (source, iks->fd_tag, 0);
iks->is_bored = TRUE;
}
g_source_set_ready_time (source, MIN (dispatch_time, boredom_time));
}
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return TRUE;
}
static InotifyKernelSource *
ik_source_new (gboolean (* callback) (ik_event_t *event))
{
static GSourceFuncs source_funcs = {
NULL, NULL,
ik_source_dispatch
/* should have a finalize, but it will never happen */
};
InotifyKernelSource *iks;
GSource *source;
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source = g_source_new (&source_funcs, sizeof (InotifyKernelSource));
iks = (InotifyKernelSource *) source;
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g_source_set_name (source, "inotify kernel source");
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iks->unmatched_moves = g_hash_table_new (NULL, NULL);
iks->fd = inotify_init1 (IN_CLOEXEC);
if (iks->fd < 0)
iks->fd = inotify_init ();
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if (iks->fd >= 0)
{
GError *error = NULL;
g_unix_set_fd_nonblocking (iks->fd, TRUE, &error);
g_assert_no_error (error);
iks->fd_tag = g_source_add_unix_fd (source, iks->fd, G_IO_IN);
}
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g_source_set_callback (source, (GSourceFunc) callback, NULL, NULL);
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g_source_attach (source, GLIB_PRIVATE_CALL (g_get_worker_context) ());
return iks;
}
gboolean
_ik_startup (gboolean (*cb)(ik_event_t *event))
{
if (g_once_init_enter (&inotify_source))
g_once_init_leave (&inotify_source, ik_source_new (cb));
return inotify_source->fd >= 0;
}
gint32
_ik_watch (const char *path,
guint32 mask,
int *err)
{
gint32 wd = -1;
g_assert (path != NULL);
g_assert (inotify_source && inotify_source->fd >= 0);
wd = inotify_add_watch (inotify_source->fd, path, mask);
if (wd < 0)
{
int e = errno;
/* FIXME: debug msg failed to add watch */
if (err)
*err = e;
return wd;
}
g_assert (wd >= 0);
return wd;
}
int
_ik_ignore (const char *path,
gint32 wd)
{
g_assert (wd >= 0);
g_assert (inotify_source && inotify_source->fd >= 0);
if (inotify_rm_watch (inotify_source->fd, wd) < 0)
{
/* int e = errno; */
/* failed to rm watch */
return -1;
}
return 0;
}