Documentation/filesystems/files.rst - pub/scm/linux/kernel/git/deller/linux-fbdev - Git at Google

 .. SPDX-License-Identifier: GPL-2.0

 ===================================
 File management in the Linux kernel
 ===================================

 This document describes how locking for files (struct file)
 and file descriptor table (struct files) works.

 Up until 2.6.12, the file descriptor table has been protected
 with a lock (files->file_lock) and reference count (files->count).
 ->file_lock protected accesses to all the file related fields
 of the table. ->count was used for sharing the file descriptor
 table between tasks cloned with CLONE_FILES flag. Typically
 this would be the case for posix threads. As with the common
 refcounting model in the kernel, the last task doing
 a put_files_struct() frees the file descriptor (fd) table.
 The files (struct file) themselves are protected using
 reference count (->f_count).

 In the new lock-free model of file descriptor management,
 the reference counting is similar, but the locking is
 based on RCU. The file descriptor table contains multiple
 elements - the fd sets (open_fds and close_on_exec, the
 array of file pointers, the sizes of the sets and the array
 etc.). In order for the updates to appear atomic to
 a lock-free reader, all the elements of the file descriptor
 table are in a separate structure - struct fdtable.
 files_struct contains a pointer to struct fdtable through
 which the actual fd table is accessed. Initially the
 fdtable is embedded in files_struct itself. On a subsequent
 expansion of fdtable, a new fdtable structure is allocated
 and files->fdtab points to the new structure. The fdtable
 structure is freed with RCU and lock-free readers either
 see the old fdtable or the new fdtable making the update
 appear atomic. Here are the locking rules for
 the fdtable structure -

 1. All references to the fdtable must be done through
    the files_fdtable() macro::

 	struct fdtable *fdt;

 	rcu_read_lock();

 	fdt = files_fdtable(files);
 	....
 	if (n <= fdt->max_fds)
 		....
 	...
 	rcu_read_unlock();

    files_fdtable() uses rcu_dereference() macro which takes care of
    the memory barrier requirements for lock-free dereference.
    The fdtable pointer must be read within the read-side
    critical section.

 2. Reading of the fdtable as described above must be protected
    by rcu_read_lock()/rcu_read_unlock().

 3. For any update to the fd table, files->file_lock must
    be held.

 4. To look up the file structure given an fd, a reader
    must use either lookup_fdget_rcu() or files_lookup_fdget_rcu() APIs. These
    take care of barrier requirements due to lock-free lookup.

    An example::

 	struct file *file;

 	rcu_read_lock();
 	file = lookup_fdget_rcu(fd);
 	rcu_read_unlock();
 	if (file) {
 		...
                 fput(file);
 	}
 	....

 5. Since both fdtable and file structures can be looked up
    lock-free, they must be installed using rcu_assign_pointer()
    API. If they are looked up lock-free, rcu_dereference()
    must be used. However it is advisable to use files_fdtable()
    and lookup_fdget_rcu()/files_lookup_fdget_rcu() which take care of these
    issues.

 6. While updating, the fdtable pointer must be looked up while
    holding files->file_lock. If ->file_lock is dropped, then
    another thread expand the files thereby creating a new
    fdtable and making the earlier fdtable pointer stale.

    For example::

 	spin_lock(&files->file_lock);
 	fd = locate_fd(files, file, start);
 	if (fd >= 0) {
 		/* locate_fd() may have expanded fdtable, load the ptr */
 		fdt = files_fdtable(files);
 		__set_open_fd(fd, fdt);
 		__clear_close_on_exec(fd, fdt);
 		spin_unlock(&files->file_lock);
 	.....

    Since locate_fd() can drop ->file_lock (and reacquire ->file_lock),
    the fdtable pointer (fdt) must be loaded after locate_fd().

 On newer kernels rcu based file lookup has been switched to rely on
 SLAB_TYPESAFE_BY_RCU instead of call_rcu(). It isn't sufficient anymore
 to just acquire a reference to the file in question under rcu using
 atomic_long_inc_not_zero() since the file might have already been
 recycled and someone else might have bumped the reference. In other
 words, callers might see reference count bumps from newer users. For
 this is reason it is necessary to verify that the pointer is the same
 before and after the reference count increment. This pattern can be seen
 in get_file_rcu() and __files_get_rcu().

 In addition, it isn't possible to access or check fields in struct file
 without first acquiring a reference on it under rcu lookup. Not doing
 that was always very dodgy and it was only usable for non-pointer data
 in struct file. With SLAB_TYPESAFE_BY_RCU it is necessary that callers
 either first acquire a reference or they must hold the files_lock of the
 fdtable.
	.. SPDX-License-Identifier: GPL-2.0

	===================================
	File management in the Linux kernel
	===================================

	This document describes how locking for files (struct file)
	and file descriptor table (struct files) works.

	Up until 2.6.12, the file descriptor table has been protected
	with a lock (files->file_lock) and reference count (files->count).
	->file_lock protected accesses to all the file related fields
	of the table. ->count was used for sharing the file descriptor
	table between tasks cloned with CLONE_FILES flag. Typically
	this would be the case for posix threads. As with the common
	refcounting model in the kernel, the last task doing
	a put_files_struct() frees the file descriptor (fd) table.
	The files (struct file) themselves are protected using
	reference count (->f_count).

	In the new lock-free model of file descriptor management,
	the reference counting is similar, but the locking is
	based on RCU. The file descriptor table contains multiple
	elements - the fd sets (open_fds and close_on_exec, the
	array of file pointers, the sizes of the sets and the array
	etc.). In order for the updates to appear atomic to
	a lock-free reader, all the elements of the file descriptor
	table are in a separate structure - struct fdtable.
	files_struct contains a pointer to struct fdtable through
	which the actual fd table is accessed. Initially the
	fdtable is embedded in files_struct itself. On a subsequent
	expansion of fdtable, a new fdtable structure is allocated
	and files->fdtab points to the new structure. The fdtable
	structure is freed with RCU and lock-free readers either
	see the old fdtable or the new fdtable making the update
	appear atomic. Here are the locking rules for
	the fdtable structure -

	1. All references to the fdtable must be done through
	the files_fdtable() macro::

	struct fdtable *fdt;

	rcu_read_lock();

	fdt = files_fdtable(files);
	....
	if (n <= fdt->max_fds)
	....
	...
	rcu_read_unlock();

	files_fdtable() uses rcu_dereference() macro which takes care of
	the memory barrier requirements for lock-free dereference.
	The fdtable pointer must be read within the read-side
	critical section.

	2. Reading of the fdtable as described above must be protected
	by rcu_read_lock()/rcu_read_unlock().

	3. For any update to the fd table, files->file_lock must
	be held.

	4. To look up the file structure given an fd, a reader
	must use either lookup_fdget_rcu() or files_lookup_fdget_rcu() APIs. These
	take care of barrier requirements due to lock-free lookup.

	An example::

	struct file *file;

	rcu_read_lock();
	file = lookup_fdget_rcu(fd);
	rcu_read_unlock();
	if (file) {
	...
	fput(file);
	}
	....

	5. Since both fdtable and file structures can be looked up
	lock-free, they must be installed using rcu_assign_pointer()
	API. If they are looked up lock-free, rcu_dereference()
	must be used. However it is advisable to use files_fdtable()
	and lookup_fdget_rcu()/files_lookup_fdget_rcu() which take care of these
	issues.

	6. While updating, the fdtable pointer must be looked up while
	holding files->file_lock. If ->file_lock is dropped, then
	another thread expand the files thereby creating a new
	fdtable and making the earlier fdtable pointer stale.

	For example::

	spin_lock(&files->file_lock);
	fd = locate_fd(files, file, start);
	if (fd >= 0) {
	/* locate_fd() may have expanded fdtable, load the ptr */
	fdt = files_fdtable(files);
	__set_open_fd(fd, fdt);
	__clear_close_on_exec(fd, fdt);
	spin_unlock(&files->file_lock);
	.....

	Since locate_fd() can drop ->file_lock (and reacquire ->file_lock),
	the fdtable pointer (fdt) must be loaded after locate_fd().

	On newer kernels rcu based file lookup has been switched to rely on
	SLAB_TYPESAFE_BY_RCU instead of call_rcu(). It isn't sufficient anymore
	to just acquire a reference to the file in question under rcu using
	atomic_long_inc_not_zero() since the file might have already been
	recycled and someone else might have bumped the reference. In other
	words, callers might see reference count bumps from newer users. For
	this is reason it is necessary to verify that the pointer is the same
	before and after the reference count increment. This pattern can be seen
	in get_file_rcu() and __files_get_rcu().

	In addition, it isn't possible to access or check fields in struct file
	without first acquiring a reference on it under rcu lookup. Not doing
	that was always very dodgy and it was only usable for non-pointer data
	in struct file. With SLAB_TYPESAFE_BY_RCU it is necessary that callers
	either first acquire a reference or they must hold the files_lock of the
	fdtable.