1184 lines
50 KiB
Text
1184 lines
50 KiB
Text
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Overview of the Linux Virtual File System
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Original author: Richard Gooch <rgooch@atnf.csiro.au>
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Last updated on June 24, 2007.
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Copyright (C) 1999 Richard Gooch
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Copyright (C) 2005 Pekka Enberg
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This file is released under the GPLv2.
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Introduction
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============
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The Virtual File System (also known as the Virtual Filesystem Switch)
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is the software layer in the kernel that provides the filesystem
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interface to userspace programs. It also provides an abstraction
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within the kernel which allows different filesystem implementations to
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coexist.
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VFS system calls open(2), stat(2), read(2), write(2), chmod(2) and so
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on are called from a process context. Filesystem locking is described
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in the document Documentation/filesystems/Locking.
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Directory Entry Cache (dcache)
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------------------------------
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The VFS implements the open(2), stat(2), chmod(2), and similar system
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calls. The pathname argument that is passed to them is used by the VFS
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to search through the directory entry cache (also known as the dentry
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cache or dcache). This provides a very fast look-up mechanism to
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translate a pathname (filename) into a specific dentry. Dentries live
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in RAM and are never saved to disc: they exist only for performance.
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The dentry cache is meant to be a view into your entire filespace. As
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most computers cannot fit all dentries in the RAM at the same time,
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some bits of the cache are missing. In order to resolve your pathname
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into a dentry, the VFS may have to resort to creating dentries along
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the way, and then loading the inode. This is done by looking up the
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inode.
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The Inode Object
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----------------
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An individual dentry usually has a pointer to an inode. Inodes are
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filesystem objects such as regular files, directories, FIFOs and other
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beasts. They live either on the disc (for block device filesystems)
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or in the memory (for pseudo filesystems). Inodes that live on the
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disc are copied into the memory when required and changes to the inode
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are written back to disc. A single inode can be pointed to by multiple
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dentries (hard links, for example, do this).
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To look up an inode requires that the VFS calls the lookup() method of
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the parent directory inode. This method is installed by the specific
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filesystem implementation that the inode lives in. Once the VFS has
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the required dentry (and hence the inode), we can do all those boring
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things like open(2) the file, or stat(2) it to peek at the inode
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data. The stat(2) operation is fairly simple: once the VFS has the
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dentry, it peeks at the inode data and passes some of it back to
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userspace.
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The File Object
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---------------
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Opening a file requires another operation: allocation of a file
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structure (this is the kernel-side implementation of file
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descriptors). The freshly allocated file structure is initialized with
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a pointer to the dentry and a set of file operation member functions.
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These are taken from the inode data. The open() file method is then
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called so the specific filesystem implementation can do its work. You
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can see that this is another switch performed by the VFS. The file
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structure is placed into the file descriptor table for the process.
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Reading, writing and closing files (and other assorted VFS operations)
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is done by using the userspace file descriptor to grab the appropriate
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file structure, and then calling the required file structure method to
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do whatever is required. For as long as the file is open, it keeps the
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dentry in use, which in turn means that the VFS inode is still in use.
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Registering and Mounting a Filesystem
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=====================================
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To register and unregister a filesystem, use the following API
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functions:
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#include <linux/fs.h>
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extern int register_filesystem(struct file_system_type *);
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extern int unregister_filesystem(struct file_system_type *);
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The passed struct file_system_type describes your filesystem. When a
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request is made to mount a filesystem onto a directory in your namespace,
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the VFS will call the appropriate mount() method for the specific
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filesystem. New vfsmount referring to the tree returned by ->mount()
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will be attached to the mountpoint, so that when pathname resolution
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reaches the mountpoint it will jump into the root of that vfsmount.
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You can see all filesystems that are registered to the kernel in the
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file /proc/filesystems.
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struct file_system_type
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-----------------------
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This describes the filesystem. As of kernel 2.6.39, the following
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members are defined:
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struct file_system_type {
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const char *name;
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int fs_flags;
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struct dentry *(*mount) (struct file_system_type *, int,
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const char *, void *);
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void (*kill_sb) (struct super_block *);
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struct module *owner;
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struct file_system_type * next;
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struct list_head fs_supers;
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struct lock_class_key s_lock_key;
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struct lock_class_key s_umount_key;
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};
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name: the name of the filesystem type, such as "ext2", "iso9660",
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"msdos" and so on
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fs_flags: various flags (i.e. FS_REQUIRES_DEV, FS_NO_DCACHE, etc.)
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mount: the method to call when a new instance of this
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filesystem should be mounted
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kill_sb: the method to call when an instance of this filesystem
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should be shut down
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owner: for internal VFS use: you should initialize this to THIS_MODULE in
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most cases.
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next: for internal VFS use: you should initialize this to NULL
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s_lock_key, s_umount_key: lockdep-specific
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The mount() method has the following arguments:
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struct file_system_type *fs_type: describes the filesystem, partly initialized
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by the specific filesystem code
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int flags: mount flags
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const char *dev_name: the device name we are mounting.
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void *data: arbitrary mount options, usually comes as an ASCII
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string (see "Mount Options" section)
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The mount() method must return the root dentry of the tree requested by
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caller. An active reference to its superblock must be grabbed and the
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superblock must be locked. On failure it should return ERR_PTR(error).
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The arguments match those of mount(2) and their interpretation
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depends on filesystem type. E.g. for block filesystems, dev_name is
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interpreted as block device name, that device is opened and if it
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contains a suitable filesystem image the method creates and initializes
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struct super_block accordingly, returning its root dentry to caller.
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->mount() may choose to return a subtree of existing filesystem - it
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doesn't have to create a new one. The main result from the caller's
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point of view is a reference to dentry at the root of (sub)tree to
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be attached; creation of new superblock is a common side effect.
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The most interesting member of the superblock structure that the
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mount() method fills in is the "s_op" field. This is a pointer to
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a "struct super_operations" which describes the next level of the
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filesystem implementation.
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Usually, a filesystem uses one of the generic mount() implementations
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and provides a fill_super() callback instead. The generic variants are:
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mount_bdev: mount a filesystem residing on a block device
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mount_nodev: mount a filesystem that is not backed by a device
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mount_single: mount a filesystem which shares the instance between
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all mounts
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A fill_super() callback implementation has the following arguments:
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struct super_block *sb: the superblock structure. The callback
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must initialize this properly.
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void *data: arbitrary mount options, usually comes as an ASCII
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string (see "Mount Options" section)
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int silent: whether or not to be silent on error
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The Superblock Object
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=====================
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A superblock object represents a mounted filesystem.
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struct super_operations
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-----------------------
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This describes how the VFS can manipulate the superblock of your
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filesystem. As of kernel 2.6.22, the following members are defined:
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struct super_operations {
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struct inode *(*alloc_inode)(struct super_block *sb);
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void (*destroy_inode)(struct inode *);
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void (*dirty_inode) (struct inode *, int flags);
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int (*write_inode) (struct inode *, int);
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void (*drop_inode) (struct inode *);
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void (*delete_inode) (struct inode *);
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void (*put_super) (struct super_block *);
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int (*sync_fs)(struct super_block *sb, int wait);
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int (*freeze_fs) (struct super_block *);
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int (*unfreeze_fs) (struct super_block *);
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int (*statfs) (struct dentry *, struct kstatfs *);
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int (*remount_fs) (struct super_block *, int *, char *);
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void (*clear_inode) (struct inode *);
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void (*umount_begin) (struct super_block *);
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int (*show_options)(struct seq_file *, struct dentry *);
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ssize_t (*quota_read)(struct super_block *, int, char *, size_t, loff_t);
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ssize_t (*quota_write)(struct super_block *, int, const char *, size_t, loff_t);
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int (*nr_cached_objects)(struct super_block *);
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void (*free_cached_objects)(struct super_block *, int);
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};
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All methods are called without any locks being held, unless otherwise
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noted. This means that most methods can block safely. All methods are
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only called from a process context (i.e. not from an interrupt handler
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or bottom half).
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alloc_inode: this method is called by alloc_inode() to allocate memory
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for struct inode and initialize it. If this function is not
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defined, a simple 'struct inode' is allocated. Normally
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alloc_inode will be used to allocate a larger structure which
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contains a 'struct inode' embedded within it.
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destroy_inode: this method is called by destroy_inode() to release
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resources allocated for struct inode. It is only required if
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->alloc_inode was defined and simply undoes anything done by
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->alloc_inode.
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dirty_inode: this method is called by the VFS to mark an inode dirty.
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write_inode: this method is called when the VFS needs to write an
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inode to disc. The second parameter indicates whether the write
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should be synchronous or not, not all filesystems check this flag.
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drop_inode: called when the last access to the inode is dropped,
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with the inode->i_lock spinlock held.
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This method should be either NULL (normal UNIX filesystem
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semantics) or "generic_delete_inode" (for filesystems that do not
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want to cache inodes - causing "delete_inode" to always be
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called regardless of the value of i_nlink)
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The "generic_delete_inode()" behavior is equivalent to the
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old practice of using "force_delete" in the put_inode() case,
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but does not have the races that the "force_delete()" approach
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had.
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delete_inode: called when the VFS wants to delete an inode
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put_super: called when the VFS wishes to free the superblock
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(i.e. unmount). This is called with the superblock lock held
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sync_fs: called when VFS is writing out all dirty data associated with
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a superblock. The second parameter indicates whether the method
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should wait until the write out has been completed. Optional.
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freeze_fs: called when VFS is locking a filesystem and
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forcing it into a consistent state. This method is currently
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used by the Logical Volume Manager (LVM).
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unfreeze_fs: called when VFS is unlocking a filesystem and making it writable
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again.
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statfs: called when the VFS needs to get filesystem statistics.
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remount_fs: called when the filesystem is remounted. This is called
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with the kernel lock held
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clear_inode: called then the VFS clears the inode. Optional
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umount_begin: called when the VFS is unmounting a filesystem.
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show_options: called by the VFS to show mount options for
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/proc/<pid>/mounts. (see "Mount Options" section)
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quota_read: called by the VFS to read from filesystem quota file.
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quota_write: called by the VFS to write to filesystem quota file.
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nr_cached_objects: called by the sb cache shrinking function for the
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filesystem to return the number of freeable cached objects it contains.
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Optional.
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free_cache_objects: called by the sb cache shrinking function for the
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filesystem to scan the number of objects indicated to try to free them.
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Optional, but any filesystem implementing this method needs to also
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implement ->nr_cached_objects for it to be called correctly.
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We can't do anything with any errors that the filesystem might
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encountered, hence the void return type. This will never be called if
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the VM is trying to reclaim under GFP_NOFS conditions, hence this
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method does not need to handle that situation itself.
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Implementations must include conditional reschedule calls inside any
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scanning loop that is done. This allows the VFS to determine
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appropriate scan batch sizes without having to worry about whether
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implementations will cause holdoff problems due to large scan batch
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sizes.
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Whoever sets up the inode is responsible for filling in the "i_op" field. This
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is a pointer to a "struct inode_operations" which describes the methods that
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can be performed on individual inodes.
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The Inode Object
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================
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An inode object represents an object within the filesystem.
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struct inode_operations
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-----------------------
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This describes how the VFS can manipulate an inode in your
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filesystem. As of kernel 2.6.22, the following members are defined:
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struct inode_operations {
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int (*create) (struct inode *,struct dentry *, umode_t, bool);
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struct dentry * (*lookup) (struct inode *,struct dentry *, unsigned int);
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int (*link) (struct dentry *,struct inode *,struct dentry *);
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int (*unlink) (struct inode *,struct dentry *);
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int (*symlink) (struct inode *,struct dentry *,const char *);
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int (*mkdir) (struct inode *,struct dentry *,umode_t);
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int (*rmdir) (struct inode *,struct dentry *);
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int (*mknod) (struct inode *,struct dentry *,umode_t,dev_t);
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int (*rename) (struct inode *, struct dentry *,
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struct inode *, struct dentry *);
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int (*rename2) (struct inode *, struct dentry *,
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struct inode *, struct dentry *, unsigned int);
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int (*readlink) (struct dentry *, char __user *,int);
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void * (*follow_link) (struct dentry *, struct nameidata *);
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void (*put_link) (struct dentry *, struct nameidata *, void *);
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int (*permission) (struct inode *, int);
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int (*get_acl)(struct inode *, int);
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int (*setattr) (struct dentry *, struct iattr *);
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int (*getattr) (struct vfsmount *mnt, struct dentry *, struct kstat *);
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int (*setxattr) (struct dentry *, const char *,const void *,size_t,int);
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ssize_t (*getxattr) (struct dentry *, const char *, void *, size_t);
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ssize_t (*listxattr) (struct dentry *, char *, size_t);
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int (*removexattr) (struct dentry *, const char *);
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void (*update_time)(struct inode *, struct timespec *, int);
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int (*atomic_open)(struct inode *, struct dentry *, struct file *,
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unsigned open_flag, umode_t create_mode, int *opened);
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int (*tmpfile) (struct inode *, struct dentry *, umode_t);
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int (*dentry_open)(struct dentry *, struct file *, const struct cred *);
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};
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Again, all methods are called without any locks being held, unless
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otherwise noted.
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create: called by the open(2) and creat(2) system calls. Only
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required if you want to support regular files. The dentry you
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get should not have an inode (i.e. it should be a negative
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dentry). Here you will probably call d_instantiate() with the
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dentry and the newly created inode
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lookup: called when the VFS needs to look up an inode in a parent
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directory. The name to look for is found in the dentry. This
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method must call d_add() to insert the found inode into the
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dentry. The "i_count" field in the inode structure should be
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incremented. If the named inode does not exist a NULL inode
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should be inserted into the dentry (this is called a negative
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dentry). Returning an error code from this routine must only
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be done on a real error, otherwise creating inodes with system
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calls like create(2), mknod(2), mkdir(2) and so on will fail.
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If you wish to overload the dentry methods then you should
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initialise the "d_dop" field in the dentry; this is a pointer
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to a struct "dentry_operations".
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This method is called with the directory inode semaphore held
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link: called by the link(2) system call. Only required if you want
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to support hard links. You will probably need to call
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d_instantiate() just as you would in the create() method
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unlink: called by the unlink(2) system call. Only required if you
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want to support deleting inodes
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symlink: called by the symlink(2) system call. Only required if you
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want to support symlinks. You will probably need to call
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d_instantiate() just as you would in the create() method
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mkdir: called by the mkdir(2) system call. Only required if you want
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to support creating subdirectories. You will probably need to
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call d_instantiate() just as you would in the create() method
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rmdir: called by the rmdir(2) system call. Only required if you want
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to support deleting subdirectories
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mknod: called by the mknod(2) system call to create a device (char,
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block) inode or a named pipe (FIFO) or socket. Only required
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if you want to support creating these types of inodes. You
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will probably need to call d_instantiate() just as you would
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in the create() method
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rename: called by the rename(2) system call to rename the object to
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have the parent and name given by the second inode and dentry.
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rename2: this has an additional flags argument compared to rename.
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If no flags are supported by the filesystem then this method
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need not be implemented. If some flags are supported then the
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filesystem must return -EINVAL for any unsupported or unknown
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flags. Currently the following flags are implemented:
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(1) RENAME_NOREPLACE: this flag indicates that if the target
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of the rename exists the rename should fail with -EEXIST
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instead of replacing the target. The VFS already checks for
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existence, so for local filesystems the RENAME_NOREPLACE
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implementation is equivalent to plain rename.
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(2) RENAME_EXCHANGE: exchange source and target. Both must
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exist; this is checked by the VFS. Unlike plain rename,
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source and target may be of different type.
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readlink: called by the readlink(2) system call. Only required if
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you want to support reading symbolic links
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follow_link: called by the VFS to follow a symbolic link to the
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inode it points to. Only required if you want to support
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symbolic links. This method returns a void pointer cookie
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that is passed to put_link().
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put_link: called by the VFS to release resources allocated by
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follow_link(). The cookie returned by follow_link() is passed
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to this method as the last parameter. It is used by
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filesystems such as NFS where page cache is not stable
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(i.e. page that was installed when the symbolic link walk
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started might not be in the page cache at the end of the
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walk).
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permission: called by the VFS to check for access rights on a POSIX-like
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filesystem.
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May be called in rcu-walk mode (mask & MAY_NOT_BLOCK). If in rcu-walk
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mode, the filesystem must check the permission without blocking or
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storing to the inode.
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If a situation is encountered that rcu-walk cannot handle, return
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-ECHILD and it will be called again in ref-walk mode.
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setattr: called by the VFS to set attributes for a file. This method
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is called by chmod(2) and related system calls.
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getattr: called by the VFS to get attributes of a file. This method
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is called by stat(2) and related system calls.
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setxattr: called by the VFS to set an extended attribute for a file.
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Extended attribute is a name:value pair associated with an
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inode. This method is called by setxattr(2) system call.
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getxattr: called by the VFS to retrieve the value of an extended
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attribute name. This method is called by getxattr(2) function
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call.
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listxattr: called by the VFS to list all extended attributes for a
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given file. This method is called by listxattr(2) system call.
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removexattr: called by the VFS to remove an extended attribute from
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a file. This method is called by removexattr(2) system call.
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update_time: called by the VFS to update a specific time or the i_version of
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an inode. If this is not defined the VFS will update the inode itself
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and call mark_inode_dirty_sync.
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|
|
atomic_open: called on the last component of an open. Using this optional
|
|
method the filesystem can look up, possibly create and open the file in
|
|
one atomic operation. If it cannot perform this (e.g. the file type
|
|
turned out to be wrong) it may signal this by returning 1 instead of
|
|
usual 0 or -ve . This method is only called if the last component is
|
|
negative or needs lookup. Cached positive dentries are still handled by
|
|
f_op->open(). If the file was created, the FILE_CREATED flag should be
|
|
set in "opened". In case of O_EXCL the method must only succeed if the
|
|
file didn't exist and hence FILE_CREATED shall always be set on success.
|
|
|
|
tmpfile: called in the end of O_TMPFILE open(). Optional, equivalent to
|
|
atomically creating, opening and unlinking a file in given directory.
|
|
|
|
The Address Space Object
|
|
========================
|
|
|
|
The address space object is used to group and manage pages in the page
|
|
cache. It can be used to keep track of the pages in a file (or
|
|
anything else) and also track the mapping of sections of the file into
|
|
process address spaces.
|
|
|
|
There are a number of distinct yet related services that an
|
|
address-space can provide. These include communicating memory
|
|
pressure, page lookup by address, and keeping track of pages tagged as
|
|
Dirty or Writeback.
|
|
|
|
The first can be used independently to the others. The VM can try to
|
|
either write dirty pages in order to clean them, or release clean
|
|
pages in order to reuse them. To do this it can call the ->writepage
|
|
method on dirty pages, and ->releasepage on clean pages with
|
|
PagePrivate set. Clean pages without PagePrivate and with no external
|
|
references will be released without notice being given to the
|
|
address_space.
|
|
|
|
To achieve this functionality, pages need to be placed on an LRU with
|
|
lru_cache_add and mark_page_active needs to be called whenever the
|
|
page is used.
|
|
|
|
Pages are normally kept in a radix tree index by ->index. This tree
|
|
maintains information about the PG_Dirty and PG_Writeback status of
|
|
each page, so that pages with either of these flags can be found
|
|
quickly.
|
|
|
|
The Dirty tag is primarily used by mpage_writepages - the default
|
|
->writepages method. It uses the tag to find dirty pages to call
|
|
->writepage on. If mpage_writepages is not used (i.e. the address
|
|
provides its own ->writepages) , the PAGECACHE_TAG_DIRTY tag is
|
|
almost unused. write_inode_now and sync_inode do use it (through
|
|
__sync_single_inode) to check if ->writepages has been successful in
|
|
writing out the whole address_space.
|
|
|
|
The Writeback tag is used by filemap*wait* and sync_page* functions,
|
|
via filemap_fdatawait_range, to wait for all writeback to
|
|
complete. While waiting ->sync_page (if defined) will be called on
|
|
each page that is found to require writeback.
|
|
|
|
An address_space handler may attach extra information to a page,
|
|
typically using the 'private' field in the 'struct page'. If such
|
|
information is attached, the PG_Private flag should be set. This will
|
|
cause various VM routines to make extra calls into the address_space
|
|
handler to deal with that data.
|
|
|
|
An address space acts as an intermediate between storage and
|
|
application. Data is read into the address space a whole page at a
|
|
time, and provided to the application either by copying of the page,
|
|
or by memory-mapping the page.
|
|
Data is written into the address space by the application, and then
|
|
written-back to storage typically in whole pages, however the
|
|
address_space has finer control of write sizes.
|
|
|
|
The read process essentially only requires 'readpage'. The write
|
|
process is more complicated and uses write_begin/write_end or
|
|
set_page_dirty to write data into the address_space, and writepage,
|
|
sync_page, and writepages to writeback data to storage.
|
|
|
|
Adding and removing pages to/from an address_space is protected by the
|
|
inode's i_mutex.
|
|
|
|
When data is written to a page, the PG_Dirty flag should be set. It
|
|
typically remains set until writepage asks for it to be written. This
|
|
should clear PG_Dirty and set PG_Writeback. It can be actually
|
|
written at any point after PG_Dirty is clear. Once it is known to be
|
|
safe, PG_Writeback is cleared.
|
|
|
|
Writeback makes use of a writeback_control structure...
|
|
|
|
struct address_space_operations
|
|
-------------------------------
|
|
|
|
This describes how the VFS can manipulate mapping of a file to page cache in
|
|
your filesystem. The following members are defined:
|
|
|
|
struct address_space_operations {
|
|
int (*writepage)(struct page *page, struct writeback_control *wbc);
|
|
int (*readpage)(struct file *, struct page *);
|
|
int (*writepages)(struct address_space *, struct writeback_control *);
|
|
int (*set_page_dirty)(struct page *page);
|
|
int (*readpages)(struct file *filp, struct address_space *mapping,
|
|
struct list_head *pages, unsigned nr_pages);
|
|
int (*write_begin)(struct file *, struct address_space *mapping,
|
|
loff_t pos, unsigned len, unsigned flags,
|
|
struct page **pagep, void **fsdata);
|
|
int (*write_end)(struct file *, struct address_space *mapping,
|
|
loff_t pos, unsigned len, unsigned copied,
|
|
struct page *page, void *fsdata);
|
|
sector_t (*bmap)(struct address_space *, sector_t);
|
|
void (*invalidatepage) (struct page *, unsigned int, unsigned int);
|
|
int (*releasepage) (struct page *, int);
|
|
void (*freepage)(struct page *);
|
|
ssize_t (*direct_IO)(int, struct kiocb *, struct iov_iter *iter, loff_t offset);
|
|
struct page* (*get_xip_page)(struct address_space *, sector_t,
|
|
int);
|
|
/* migrate the contents of a page to the specified target */
|
|
int (*migratepage) (struct page *, struct page *);
|
|
int (*launder_page) (struct page *);
|
|
int (*is_partially_uptodate) (struct page *, unsigned long,
|
|
unsigned long);
|
|
void (*is_dirty_writeback) (struct page *, bool *, bool *);
|
|
int (*error_remove_page) (struct mapping *mapping, struct page *page);
|
|
int (*swap_activate)(struct file *);
|
|
int (*swap_deactivate)(struct file *);
|
|
};
|
|
|
|
writepage: called by the VM to write a dirty page to backing store.
|
|
This may happen for data integrity reasons (i.e. 'sync'), or
|
|
to free up memory (flush). The difference can be seen in
|
|
wbc->sync_mode.
|
|
The PG_Dirty flag has been cleared and PageLocked is true.
|
|
writepage should start writeout, should set PG_Writeback,
|
|
and should make sure the page is unlocked, either synchronously
|
|
or asynchronously when the write operation completes.
|
|
|
|
If wbc->sync_mode is WB_SYNC_NONE, ->writepage doesn't have to
|
|
try too hard if there are problems, and may choose to write out
|
|
other pages from the mapping if that is easier (e.g. due to
|
|
internal dependencies). If it chooses not to start writeout, it
|
|
should return AOP_WRITEPAGE_ACTIVATE so that the VM will not keep
|
|
calling ->writepage on that page.
|
|
|
|
See the file "Locking" for more details.
|
|
|
|
readpage: called by the VM to read a page from backing store.
|
|
The page will be Locked when readpage is called, and should be
|
|
unlocked and marked uptodate once the read completes.
|
|
If ->readpage discovers that it needs to unlock the page for
|
|
some reason, it can do so, and then return AOP_TRUNCATED_PAGE.
|
|
In this case, the page will be relocated, relocked and if
|
|
that all succeeds, ->readpage will be called again.
|
|
|
|
writepages: called by the VM to write out pages associated with the
|
|
address_space object. If wbc->sync_mode is WBC_SYNC_ALL, then
|
|
the writeback_control will specify a range of pages that must be
|
|
written out. If it is WBC_SYNC_NONE, then a nr_to_write is given
|
|
and that many pages should be written if possible.
|
|
If no ->writepages is given, then mpage_writepages is used
|
|
instead. This will choose pages from the address space that are
|
|
tagged as DIRTY and will pass them to ->writepage.
|
|
|
|
set_page_dirty: called by the VM to set a page dirty.
|
|
This is particularly needed if an address space attaches
|
|
private data to a page, and that data needs to be updated when
|
|
a page is dirtied. This is called, for example, when a memory
|
|
mapped page gets modified.
|
|
If defined, it should set the PageDirty flag, and the
|
|
PAGECACHE_TAG_DIRTY tag in the radix tree.
|
|
|
|
readpages: called by the VM to read pages associated with the address_space
|
|
object. This is essentially just a vector version of
|
|
readpage. Instead of just one page, several pages are
|
|
requested.
|
|
readpages is only used for read-ahead, so read errors are
|
|
ignored. If anything goes wrong, feel free to give up.
|
|
|
|
write_begin:
|
|
Called by the generic buffered write code to ask the filesystem to
|
|
prepare to write len bytes at the given offset in the file. The
|
|
address_space should check that the write will be able to complete,
|
|
by allocating space if necessary and doing any other internal
|
|
housekeeping. If the write will update parts of any basic-blocks on
|
|
storage, then those blocks should be pre-read (if they haven't been
|
|
read already) so that the updated blocks can be written out properly.
|
|
|
|
The filesystem must return the locked pagecache page for the specified
|
|
offset, in *pagep, for the caller to write into.
|
|
|
|
It must be able to cope with short writes (where the length passed to
|
|
write_begin is greater than the number of bytes copied into the page).
|
|
|
|
flags is a field for AOP_FLAG_xxx flags, described in
|
|
include/linux/fs.h.
|
|
|
|
A void * may be returned in fsdata, which then gets passed into
|
|
write_end.
|
|
|
|
Returns 0 on success; < 0 on failure (which is the error code), in
|
|
which case write_end is not called.
|
|
|
|
write_end: After a successful write_begin, and data copy, write_end must
|
|
be called. len is the original len passed to write_begin, and copied
|
|
is the amount that was able to be copied (copied == len is always true
|
|
if write_begin was called with the AOP_FLAG_UNINTERRUPTIBLE flag).
|
|
|
|
The filesystem must take care of unlocking the page and releasing it
|
|
refcount, and updating i_size.
|
|
|
|
Returns < 0 on failure, otherwise the number of bytes (<= 'copied')
|
|
that were able to be copied into pagecache.
|
|
|
|
bmap: called by the VFS to map a logical block offset within object to
|
|
physical block number. This method is used by the FIBMAP
|
|
ioctl and for working with swap-files. To be able to swap to
|
|
a file, the file must have a stable mapping to a block
|
|
device. The swap system does not go through the filesystem
|
|
but instead uses bmap to find out where the blocks in the file
|
|
are and uses those addresses directly.
|
|
|
|
dentry_open: *WARNING: probably going away soon, do not use!* This is an
|
|
alternative to f_op->open(), the difference is that this method may open
|
|
a file not necessarily originating from the same filesystem as the one
|
|
i_op->open() was called on. It may be useful for stacking filesystems
|
|
which want to allow native I/O directly on underlying files.
|
|
|
|
|
|
invalidatepage: If a page has PagePrivate set, then invalidatepage
|
|
will be called when part or all of the page is to be removed
|
|
from the address space. This generally corresponds to either a
|
|
truncation, punch hole or a complete invalidation of the address
|
|
space (in the latter case 'offset' will always be 0 and 'length'
|
|
will be PAGE_CACHE_SIZE). Any private data associated with the page
|
|
should be updated to reflect this truncation. If offset is 0 and
|
|
length is PAGE_CACHE_SIZE, then the private data should be released,
|
|
because the page must be able to be completely discarded. This may
|
|
be done by calling the ->releasepage function, but in this case the
|
|
release MUST succeed.
|
|
|
|
releasepage: releasepage is called on PagePrivate pages to indicate
|
|
that the page should be freed if possible. ->releasepage
|
|
should remove any private data from the page and clear the
|
|
PagePrivate flag. If releasepage() fails for some reason, it must
|
|
indicate failure with a 0 return value.
|
|
releasepage() is used in two distinct though related cases. The
|
|
first is when the VM finds a clean page with no active users and
|
|
wants to make it a free page. If ->releasepage succeeds, the
|
|
page will be removed from the address_space and become free.
|
|
|
|
The second case is when a request has been made to invalidate
|
|
some or all pages in an address_space. This can happen
|
|
through the fadvice(POSIX_FADV_DONTNEED) system call or by the
|
|
filesystem explicitly requesting it as nfs and 9fs do (when
|
|
they believe the cache may be out of date with storage) by
|
|
calling invalidate_inode_pages2().
|
|
If the filesystem makes such a call, and needs to be certain
|
|
that all pages are invalidated, then its releasepage will
|
|
need to ensure this. Possibly it can clear the PageUptodate
|
|
bit if it cannot free private data yet.
|
|
|
|
freepage: freepage is called once the page is no longer visible in
|
|
the page cache in order to allow the cleanup of any private
|
|
data. Since it may be called by the memory reclaimer, it
|
|
should not assume that the original address_space mapping still
|
|
exists, and it should not block.
|
|
|
|
direct_IO: called by the generic read/write routines to perform
|
|
direct_IO - that is IO requests which bypass the page cache
|
|
and transfer data directly between the storage and the
|
|
application's address space.
|
|
|
|
get_xip_page: called by the VM to translate a block number to a page.
|
|
The page is valid until the corresponding filesystem is unmounted.
|
|
Filesystems that want to use execute-in-place (XIP) need to implement
|
|
it. An example implementation can be found in fs/ext2/xip.c.
|
|
|
|
migrate_page: This is used to compact the physical memory usage.
|
|
If the VM wants to relocate a page (maybe off a memory card
|
|
that is signalling imminent failure) it will pass a new page
|
|
and an old page to this function. migrate_page should
|
|
transfer any private data across and update any references
|
|
that it has to the page.
|
|
|
|
launder_page: Called before freeing a page - it writes back the dirty page. To
|
|
prevent redirtying the page, it is kept locked during the whole
|
|
operation.
|
|
|
|
is_partially_uptodate: Called by the VM when reading a file through the
|
|
pagecache when the underlying blocksize != pagesize. If the required
|
|
block is up to date then the read can complete without needing the IO
|
|
to bring the whole page up to date.
|
|
|
|
is_dirty_writeback: Called by the VM when attempting to reclaim a page.
|
|
The VM uses dirty and writeback information to determine if it needs
|
|
to stall to allow flushers a chance to complete some IO. Ordinarily
|
|
it can use PageDirty and PageWriteback but some filesystems have
|
|
more complex state (unstable pages in NFS prevent reclaim) or
|
|
do not set those flags due to locking problems (jbd). This callback
|
|
allows a filesystem to indicate to the VM if a page should be
|
|
treated as dirty or writeback for the purposes of stalling.
|
|
|
|
error_remove_page: normally set to generic_error_remove_page if truncation
|
|
is ok for this address space. Used for memory failure handling.
|
|
Setting this implies you deal with pages going away under you,
|
|
unless you have them locked or reference counts increased.
|
|
|
|
swap_activate: Called when swapon is used on a file to allocate
|
|
space if necessary and pin the block lookup information in
|
|
memory. A return value of zero indicates success,
|
|
in which case this file can be used to back swapspace. The
|
|
swapspace operations will be proxied to this address space's
|
|
->swap_{out,in} methods.
|
|
|
|
swap_deactivate: Called during swapoff on files where swap_activate
|
|
was successful.
|
|
|
|
|
|
The File Object
|
|
===============
|
|
|
|
A file object represents a file opened by a process.
|
|
|
|
|
|
struct file_operations
|
|
----------------------
|
|
|
|
This describes how the VFS can manipulate an open file. As of kernel
|
|
3.12, the following members are defined:
|
|
|
|
struct file_operations {
|
|
struct module *owner;
|
|
loff_t (*llseek) (struct file *, loff_t, int);
|
|
ssize_t (*read) (struct file *, char __user *, size_t, loff_t *);
|
|
ssize_t (*write) (struct file *, const char __user *, size_t, loff_t *);
|
|
ssize_t (*aio_read) (struct kiocb *, const struct iovec *, unsigned long, loff_t);
|
|
ssize_t (*aio_write) (struct kiocb *, const struct iovec *, unsigned long, loff_t);
|
|
ssize_t (*read_iter) (struct kiocb *, struct iov_iter *);
|
|
ssize_t (*write_iter) (struct kiocb *, struct iov_iter *);
|
|
int (*iterate) (struct file *, struct dir_context *);
|
|
unsigned int (*poll) (struct file *, struct poll_table_struct *);
|
|
long (*unlocked_ioctl) (struct file *, unsigned int, unsigned long);
|
|
long (*compat_ioctl) (struct file *, unsigned int, unsigned long);
|
|
int (*mmap) (struct file *, struct vm_area_struct *);
|
|
int (*open) (struct inode *, struct file *);
|
|
int (*flush) (struct file *);
|
|
int (*release) (struct inode *, struct file *);
|
|
int (*fsync) (struct file *, loff_t, loff_t, int datasync);
|
|
int (*aio_fsync) (struct kiocb *, int datasync);
|
|
int (*fasync) (int, struct file *, int);
|
|
int (*lock) (struct file *, int, struct file_lock *);
|
|
ssize_t (*sendpage) (struct file *, struct page *, int, size_t, loff_t *, int);
|
|
unsigned long (*get_unmapped_area)(struct file *, unsigned long, unsigned long, unsigned long, unsigned long);
|
|
int (*check_flags)(int);
|
|
int (*flock) (struct file *, int, struct file_lock *);
|
|
ssize_t (*splice_write)(struct pipe_inode_info *, struct file *, size_t, unsigned int);
|
|
ssize_t (*splice_read)(struct file *, struct pipe_inode_info *, size_t, unsigned int);
|
|
int (*setlease)(struct file *, long arg, struct file_lock **, void **);
|
|
long (*fallocate)(struct file *, int mode, loff_t offset, loff_t len);
|
|
int (*show_fdinfo)(struct seq_file *m, struct file *f);
|
|
};
|
|
|
|
Again, all methods are called without any locks being held, unless
|
|
otherwise noted.
|
|
|
|
llseek: called when the VFS needs to move the file position index
|
|
|
|
read: called by read(2) and related system calls
|
|
|
|
aio_read: vectored, possibly asynchronous read
|
|
|
|
read_iter: possibly asynchronous read with iov_iter as destination
|
|
|
|
write: called by write(2) and related system calls
|
|
|
|
aio_write: vectored, possibly asynchronous write
|
|
|
|
write_iter: possibly asynchronous write with iov_iter as source
|
|
|
|
iterate: called when the VFS needs to read the directory contents
|
|
|
|
poll: called by the VFS when a process wants to check if there is
|
|
activity on this file and (optionally) go to sleep until there
|
|
is activity. Called by the select(2) and poll(2) system calls
|
|
|
|
unlocked_ioctl: called by the ioctl(2) system call.
|
|
|
|
compat_ioctl: called by the ioctl(2) system call when 32 bit system calls
|
|
are used on 64 bit kernels.
|
|
|
|
mmap: called by the mmap(2) system call
|
|
|
|
open: called by the VFS when an inode should be opened. When the VFS
|
|
opens a file, it creates a new "struct file". It then calls the
|
|
open method for the newly allocated file structure. You might
|
|
think that the open method really belongs in
|
|
"struct inode_operations", and you may be right. I think it's
|
|
done the way it is because it makes filesystems simpler to
|
|
implement. The open() method is a good place to initialize the
|
|
"private_data" member in the file structure if you want to point
|
|
to a device structure
|
|
|
|
flush: called by the close(2) system call to flush a file
|
|
|
|
release: called when the last reference to an open file is closed
|
|
|
|
fsync: called by the fsync(2) system call
|
|
|
|
fasync: called by the fcntl(2) system call when asynchronous
|
|
(non-blocking) mode is enabled for a file
|
|
|
|
lock: called by the fcntl(2) system call for F_GETLK, F_SETLK, and F_SETLKW
|
|
commands
|
|
|
|
get_unmapped_area: called by the mmap(2) system call
|
|
|
|
check_flags: called by the fcntl(2) system call for F_SETFL command
|
|
|
|
flock: called by the flock(2) system call
|
|
|
|
splice_write: called by the VFS to splice data from a pipe to a file. This
|
|
method is used by the splice(2) system call
|
|
|
|
splice_read: called by the VFS to splice data from file to a pipe. This
|
|
method is used by the splice(2) system call
|
|
|
|
setlease: called by the VFS to set or release a file lock lease. setlease
|
|
implementations should call generic_setlease to record or remove
|
|
the lease in the inode after setting it.
|
|
|
|
fallocate: called by the VFS to preallocate blocks or punch a hole.
|
|
|
|
Note that the file operations are implemented by the specific
|
|
filesystem in which the inode resides. When opening a device node
|
|
(character or block special) most filesystems will call special
|
|
support routines in the VFS which will locate the required device
|
|
driver information. These support routines replace the filesystem file
|
|
operations with those for the device driver, and then proceed to call
|
|
the new open() method for the file. This is how opening a device file
|
|
in the filesystem eventually ends up calling the device driver open()
|
|
method.
|
|
|
|
|
|
Directory Entry Cache (dcache)
|
|
==============================
|
|
|
|
|
|
struct dentry_operations
|
|
------------------------
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This describes how a filesystem can overload the standard dentry
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operations. Dentries and the dcache are the domain of the VFS and the
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individual filesystem implementations. Device drivers have no business
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here. These methods may be set to NULL, as they are either optional or
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the VFS uses a default. As of kernel 2.6.22, the following members are
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defined:
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struct dentry_operations {
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int (*d_revalidate)(struct dentry *, unsigned int);
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int (*d_weak_revalidate)(struct dentry *, unsigned int);
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int (*d_hash)(const struct dentry *, struct qstr *);
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int (*d_compare)(const struct dentry *, const struct dentry *,
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unsigned int, const char *, const struct qstr *);
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int (*d_delete)(const struct dentry *);
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void (*d_release)(struct dentry *);
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void (*d_iput)(struct dentry *, struct inode *);
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char *(*d_dname)(struct dentry *, char *, int);
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struct vfsmount *(*d_automount)(struct path *);
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int (*d_manage)(struct dentry *, bool);
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};
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d_revalidate: called when the VFS needs to revalidate a dentry. This
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is called whenever a name look-up finds a dentry in the
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dcache. Most local filesystems leave this as NULL, because all their
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dentries in the dcache are valid. Network filesystems are different
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since things can change on the server without the client necessarily
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being aware of it.
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This function should return a positive value if the dentry is still
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valid, and zero or a negative error code if it isn't.
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d_revalidate may be called in rcu-walk mode (flags & LOOKUP_RCU).
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If in rcu-walk mode, the filesystem must revalidate the dentry without
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blocking or storing to the dentry, d_parent and d_inode should not be
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used without care (because they can change and, in d_inode case, even
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become NULL under us).
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If a situation is encountered that rcu-walk cannot handle, return
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-ECHILD and it will be called again in ref-walk mode.
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d_weak_revalidate: called when the VFS needs to revalidate a "jumped" dentry.
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This is called when a path-walk ends at dentry that was not acquired by
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doing a lookup in the parent directory. This includes "/", "." and "..",
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as well as procfs-style symlinks and mountpoint traversal.
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In this case, we are less concerned with whether the dentry is still
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fully correct, but rather that the inode is still valid. As with
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d_revalidate, most local filesystems will set this to NULL since their
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dcache entries are always valid.
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This function has the same return code semantics as d_revalidate.
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d_weak_revalidate is only called after leaving rcu-walk mode.
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d_hash: called when the VFS adds a dentry to the hash table. The first
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dentry passed to d_hash is the parent directory that the name is
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to be hashed into.
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Same locking and synchronisation rules as d_compare regarding
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what is safe to dereference etc.
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d_compare: called to compare a dentry name with a given name. The first
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dentry is the parent of the dentry to be compared, the second is
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the child dentry. len and name string are properties of the dentry
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to be compared. qstr is the name to compare it with.
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Must be constant and idempotent, and should not take locks if
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possible, and should not or store into the dentry.
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Should not dereference pointers outside the dentry without
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lots of care (eg. d_parent, d_inode, d_name should not be used).
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However, our vfsmount is pinned, and RCU held, so the dentries and
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inodes won't disappear, neither will our sb or filesystem module.
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->d_sb may be used.
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It is a tricky calling convention because it needs to be called under
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"rcu-walk", ie. without any locks or references on things.
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d_delete: called when the last reference to a dentry is dropped and the
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dcache is deciding whether or not to cache it. Return 1 to delete
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immediately, or 0 to cache the dentry. Default is NULL which means to
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always cache a reachable dentry. d_delete must be constant and
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idempotent.
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d_release: called when a dentry is really deallocated
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d_iput: called when a dentry loses its inode (just prior to its
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being deallocated). The default when this is NULL is that the
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VFS calls iput(). If you define this method, you must call
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iput() yourself
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d_dname: called when the pathname of a dentry should be generated.
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Useful for some pseudo filesystems (sockfs, pipefs, ...) to delay
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pathname generation. (Instead of doing it when dentry is created,
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it's done only when the path is needed.). Real filesystems probably
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dont want to use it, because their dentries are present in global
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dcache hash, so their hash should be an invariant. As no lock is
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held, d_dname() should not try to modify the dentry itself, unless
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appropriate SMP safety is used. CAUTION : d_path() logic is quite
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tricky. The correct way to return for example "Hello" is to put it
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at the end of the buffer, and returns a pointer to the first char.
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dynamic_dname() helper function is provided to take care of this.
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d_automount: called when an automount dentry is to be traversed (optional).
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This should create a new VFS mount record and return the record to the
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caller. The caller is supplied with a path parameter giving the
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automount directory to describe the automount target and the parent
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VFS mount record to provide inheritable mount parameters. NULL should
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be returned if someone else managed to make the automount first. If
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the vfsmount creation failed, then an error code should be returned.
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If -EISDIR is returned, then the directory will be treated as an
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ordinary directory and returned to pathwalk to continue walking.
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If a vfsmount is returned, the caller will attempt to mount it on the
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mountpoint and will remove the vfsmount from its expiration list in
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the case of failure. The vfsmount should be returned with 2 refs on
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it to prevent automatic expiration - the caller will clean up the
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additional ref.
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This function is only used if DCACHE_NEED_AUTOMOUNT is set on the
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dentry. This is set by __d_instantiate() if S_AUTOMOUNT is set on the
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inode being added.
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d_manage: called to allow the filesystem to manage the transition from a
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dentry (optional). This allows autofs, for example, to hold up clients
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waiting to explore behind a 'mountpoint' whilst letting the daemon go
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past and construct the subtree there. 0 should be returned to let the
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calling process continue. -EISDIR can be returned to tell pathwalk to
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use this directory as an ordinary directory and to ignore anything
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mounted on it and not to check the automount flag. Any other error
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code will abort pathwalk completely.
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If the 'rcu_walk' parameter is true, then the caller is doing a
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pathwalk in RCU-walk mode. Sleeping is not permitted in this mode,
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and the caller can be asked to leave it and call again by returning
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-ECHILD. -EISDIR may also be returned to tell pathwalk to
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ignore d_automount or any mounts.
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This function is only used if DCACHE_MANAGE_TRANSIT is set on the
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dentry being transited from.
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Example :
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static char *pipefs_dname(struct dentry *dent, char *buffer, int buflen)
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{
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return dynamic_dname(dentry, buffer, buflen, "pipe:[%lu]",
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dentry->d_inode->i_ino);
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}
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Each dentry has a pointer to its parent dentry, as well as a hash list
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of child dentries. Child dentries are basically like files in a
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directory.
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Directory Entry Cache API
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--------------------------
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There are a number of functions defined which permit a filesystem to
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manipulate dentries:
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dget: open a new handle for an existing dentry (this just increments
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the usage count)
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dput: close a handle for a dentry (decrements the usage count). If
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the usage count drops to 0, and the dentry is still in its
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parent's hash, the "d_delete" method is called to check whether
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it should be cached. If it should not be cached, or if the dentry
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is not hashed, it is deleted. Otherwise cached dentries are put
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into an LRU list to be reclaimed on memory shortage.
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d_drop: this unhashes a dentry from its parents hash list. A
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subsequent call to dput() will deallocate the dentry if its
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usage count drops to 0
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d_delete: delete a dentry. If there are no other open references to
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the dentry then the dentry is turned into a negative dentry
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(the d_iput() method is called). If there are other
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references, then d_drop() is called instead
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d_add: add a dentry to its parents hash list and then calls
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d_instantiate()
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d_instantiate: add a dentry to the alias hash list for the inode and
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updates the "d_inode" member. The "i_count" member in the
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inode structure should be set/incremented. If the inode
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pointer is NULL, the dentry is called a "negative
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dentry". This function is commonly called when an inode is
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created for an existing negative dentry
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d_lookup: look up a dentry given its parent and path name component
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It looks up the child of that given name from the dcache
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hash table. If it is found, the reference count is incremented
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and the dentry is returned. The caller must use dput()
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to free the dentry when it finishes using it.
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Mount Options
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=============
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Parsing options
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---------------
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On mount and remount the filesystem is passed a string containing a
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comma separated list of mount options. The options can have either of
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these forms:
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option
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option=value
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The <linux/parser.h> header defines an API that helps parse these
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options. There are plenty of examples on how to use it in existing
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filesystems.
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Showing options
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---------------
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If a filesystem accepts mount options, it must define show_options()
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to show all the currently active options. The rules are:
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- options MUST be shown which are not default or their values differ
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from the default
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- options MAY be shown which are enabled by default or have their
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default value
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Options used only internally between a mount helper and the kernel
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(such as file descriptors), or which only have an effect during the
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mounting (such as ones controlling the creation of a journal) are exempt
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from the above rules.
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The underlying reason for the above rules is to make sure, that a
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mount can be accurately replicated (e.g. umounting and mounting again)
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based on the information found in /proc/mounts.
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A simple method of saving options at mount/remount time and showing
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them is provided with the save_mount_options() and
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generic_show_options() helper functions. Please note, that using
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these may have drawbacks. For more info see header comments for these
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functions in fs/namespace.c.
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Resources
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=========
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(Note some of these resources are not up-to-date with the latest kernel
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version.)
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Creating Linux virtual filesystems. 2002
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<http://lwn.net/Articles/13325/>
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The Linux Virtual File-system Layer by Neil Brown. 1999
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<http://www.cse.unsw.edu.au/~neilb/oss/linux-commentary/vfs.html>
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A tour of the Linux VFS by Michael K. Johnson. 1996
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<http://www.tldp.org/LDP/khg/HyperNews/get/fs/vfstour.html>
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A small trail through the Linux kernel by Andries Brouwer. 2001
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<http://www.win.tue.nl/~aeb/linux/vfs/trail.html>
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