blob: b12c89538680aaf5f2cf3f5f872321f73a3d57ab [file] [log] [blame]
Changes since 2.5.0:
New helpers: sb_bread(), sb_getblk(), sb_find_get_block(), set_bh(),
sb_set_blocksize() and sb_min_blocksize().
Use them.
(sb_find_get_block() replaces 2.4's get_hash_table())
New methods: ->alloc_inode() and ->destroy_inode().
Remove inode->u.foo_inode_i
struct foo_inode_info {
/* fs-private stuff */
struct inode vfs_inode;
static inline struct foo_inode_info *FOO_I(struct inode *inode)
return list_entry(inode, struct foo_inode_info, vfs_inode);
Use FOO_I(inode) instead of &inode->u.foo_inode_i;
Add foo_alloc_inode() and foo_destroy_inode() - the former should allocate
foo_inode_info and return the address of ->vfs_inode, the latter should free
FOO_I(inode) (see in-tree filesystems for examples).
Make them ->alloc_inode and ->destroy_inode in your super_operations.
Keep in mind that now you need explicit initialization of private data
typically between calling iget_locked() and unlocking the inode.
At some point that will become mandatory.
Change of file_system_type method (->read_super to ->get_sb)
->read_super() is no more. Ditto for DECLARE_FSTYPE and DECLARE_FSTYPE_DEV.
Turn your foo_read_super() into a function that would return 0 in case of
success and negative number in case of error (-EINVAL unless you have more
informative error value to report). Call it foo_fill_super(). Now declare
int foo_get_sb(struct file_system_type *fs_type,
int flags, const char *dev_name, void *data, struct vfsmount *mnt)
return get_sb_bdev(fs_type, flags, dev_name, data, foo_fill_super,
(or similar with s/bdev/nodev/ or s/bdev/single/, depending on the kind of
Replace DECLARE_FSTYPE... with explicit initializer and have ->get_sb set as
Locking change: ->s_vfs_rename_sem is taken only by cross-directory renames.
Most likely there is no need to change anything, but if you relied on
global exclusion between renames for some internal purpose - you need to
change your internal locking. Otherwise exclusion warranties remain the
same (i.e. parents and victim are locked, etc.).
Now we have the exclusion between ->lookup() and directory removal (by
->rmdir() and ->rename()). If you used to need that exclusion and do
it by internal locking (most of filesystems couldn't care less) - you
can relax your locking.
->lookup(), ->truncate(), ->create(), ->unlink(), ->mknod(), ->mkdir(),
->rmdir(), ->link(), ->lseek(), ->symlink(), ->rename()
and ->readdir() are called without BKL now. Grab it on entry, drop upon return
- that will guarantee the same locking you used to have. If your method or its
parts do not need BKL - better yet, now you can shift lock_kernel() and
unlock_kernel() so that they would protect exactly what needs to be
BKL is also moved from around sb operations. ->write_super() Is now called
without BKL held. BKL should have been shifted into individual fs sb_op
functions. If you don't need it, remove it.
check for ->link() target not being a directory is done by callers. Feel
free to drop it...
->link() callers hold ->i_mutex on the object we are linking to. Some of your
problems might be over...
new file_system_type method - kill_sb(superblock). If you are converting
an existing filesystem, set it according to ->fs_flags:
FS_REQUIRES_DEV - kill_block_super
FS_LITTER - kill_litter_super
neither - kill_anon_super
FS_LITTER is gone - just remove it from fs_flags.
FS_SINGLE is gone (actually, that had happened back when ->get_sb()
went in - and hadn't been documented ;-/). Just remove it from fs_flags
(and see ->get_sb() entry for other actions).
->setattr() is called without BKL now. Caller _always_ holds ->i_mutex, so
watch for ->i_mutex-grabbing code that might be used by your ->setattr().
Callers of notify_change() need ->i_mutex now.
New super_block field "struct export_operations *s_export_op" for
explicit support for exporting, e.g. via NFS. The structure is fully
documented at its declaration in include/linux/fs.h, and in
Briefly it allows for the definition of decode_fh and encode_fh operations
to encode and decode filehandles, and allows the filesystem to use
a standard helper function for decode_fh, and provide file-system specific
support for this helper, particularly get_parent.
It is planned that this will be required for exporting once the code
settles down a bit.
s_export_op is now required for exporting a filesystem.
isofs, ext2, ext3, resierfs, fat
can be used as examples of very different filesystems.
iget4() and the read_inode2 callback have been superseded by iget5_locked()
which has the following prototype,
struct inode *iget5_locked(struct super_block *sb, unsigned long ino,
int (*test)(struct inode *, void *),
int (*set)(struct inode *, void *),
void *data);
'test' is an additional function that can be used when the inode
number is not sufficient to identify the actual file object. 'set'
should be a non-blocking function that initializes those parts of a
newly created inode to allow the test function to succeed. 'data' is
passed as an opaque value to both test and set functions.
When the inode has been created by iget5_locked(), it will be returned with the
I_NEW flag set and will still be locked. The filesystem then needs to finalize
the initialization. Once the inode is initialized it must be unlocked by
calling unlock_new_inode().
The filesystem is responsible for setting (and possibly testing) i_ino
when appropriate. There is also a simpler iget_locked function that
just takes the superblock and inode number as arguments and does the
test and set for you.
inode = iget_locked(sb, ino);
if (inode->i_state & I_NEW) {
err = read_inode_from_disk(inode);
if (err < 0) {
return err;
Note that if the process of setting up a new inode fails, then iget_failed()
should be called on the inode to render it dead, and an appropriate error
should be passed back to the caller.
->getattr() finally getting used. See instances in nfs, minix, etc.
->revalidate() is gone. If your filesystem had it - provide ->getattr()
and let it call whatever you had as ->revlidate() + (for symlinks that
had ->revalidate()) add calls in ->follow_link()/->readlink().
->d_parent changes are not protected by BKL anymore. Read access is safe
if at least one of the following is true:
* filesystem has no cross-directory rename()
* dcache_lock is held
* we know that parent had been locked (e.g. we are looking at
->d_parent of ->lookup() argument).
* we are called from ->rename().
* the child's ->d_lock is held
Audit your code and add locking if needed. Notice that any place that is
not protected by the conditions above is risky even in the old tree - you
had been relying on BKL and that's prone to screwups. Old tree had quite
a few holes of that kind - unprotected access to ->d_parent leading to
anything from oops to silent memory corruption.
FS_NOMOUNT is gone. If you use it - just set MS_NOUSER in flags
(see rootfs for one kind of solution and bdev/socket/pipe for another).
Use bdev_read_only(bdev) instead of is_read_only(kdev). The latter
is still alive, but only because of the mess in drivers/s390/block/dasd.c.
As soon as it gets fixed is_read_only() will die.
->permission() is called without BKL now. Grab it on entry, drop upon
return - that will guarantee the same locking you used to have. If
your method or its parts do not need BKL - better yet, now you can
shift lock_kernel() and unlock_kernel() so that they would protect
exactly what needs to be protected.
->statfs() is now called without BKL held. BKL should have been
shifted into individual fs sb_op functions where it's not clear that
it's safe to remove it. If you don't need it, remove it.
is_read_only() is gone; use bdev_read_only() instead.
destroy_buffers() is gone; use invalidate_bdev().
fsync_dev() is gone; use fsync_bdev(). NOTE: lvm breakage is
deliberate; as soon as struct block_device * is propagated in a reasonable
way by that code fixing will become trivial; until then nothing can be
block truncatation on error exit from ->write_begin, and ->direct_IO
moved from generic methods (block_write_begin, cont_write_begin,
nobh_write_begin, blockdev_direct_IO*) to callers. Take a look at
ext2_write_failed and callers for an example.
->truncate is going away. The whole truncate sequence needs to be
implemented in ->setattr, which is now mandatory for filesystems
implementing on-disk size changes. Start with a copy of the old inode_setattr
and vmtruncate, and the reorder the vmtruncate + foofs_vmtruncate sequence to
be in order of zeroing blocks using block_truncate_page or similar helpers,
size update and on finally on-disk truncation which should not fail.
inode_change_ok now includes the size checks for ATTR_SIZE and must be called
in the beginning of ->setattr unconditionally.
->clear_inode() and ->delete_inode() are gone; ->evict_inode() should
be used instead. It gets called whenever the inode is evicted, whether it has
remaining links or not. Caller does *not* evict the pagecache or inode-associated
metadata buffers; getting rid of those is responsibility of method, as it had
been for ->delete_inode().
->drop_inode() returns int now; it's called on final iput() with inode_lock
held and it returns true if filesystems wants the inode to be dropped. As before,
generic_drop_inode() is still the default and it's been updated appropriately.
generic_delete_inode() is also alive and it consists simply of return 1. Note that
all actual eviction work is done by caller after ->drop_inode() returns.
clear_inode() is gone; use end_writeback() instead. As before, it must
be called exactly once on each call of ->evict_inode() (as it used to be for
each call of ->delete_inode()). Unlike before, if you are using inode-associated
metadata buffers (i.e. mark_buffer_dirty_inode()), it's your responsibility to
call invalidate_inode_buffers() before end_writeback().
No async writeback (and thus no calls of ->write_inode()) will happen
after end_writeback() returns, so actions that should not overlap with ->write_inode()
(e.g. freeing on-disk inode if i_nlink is 0) ought to be done after that call.
NOTE: checking i_nlink in the beginning of ->write_inode() and bailing out
if it's zero is not *and* *never* *had* *been* enough. Final unlink() and iput()
may happen while the inode is in the middle of ->write_inode(); e.g. if you blindly
free the on-disk inode, you may end up doing that while ->write_inode() is writing
to it.