Inode - Wikipedia, the free encyclopedia



INODE Details

When a UNIX file system is created, data structures that contain information about files are created. Each file has an inode and is identified by an inode number (often "i-number" or even shorter, "ino") in the file system where it resides.

Inodes store information on files such as user and group ownership, access mode (read, write, execute permissions) and type of file. There is a fixed number of inodes, which indicates the maximum number of files each file system can hold. Typically when a file system is created about 1% of it is devoted to inodes.

The term inode usually refers to inodes on block devices that manage regular files, directories, and possibly symbolic links. The concept is particularly important to the recovery of damaged file systems.

• The inode number indexes a table of inodes in a known location on the device; from the inode number, the kernel can access the contents of the inode, including the data pointers, and so the contents of the file.

• A file's inode number can be found using the ls -i command, while the ls -l command will retrieve inode information.

• Non-traditional Unix-style filesystems such as ReiserFS may avoid having a table of inodes, but must store equivalent data in order to provide equivalent function. The data may be called stat data, in reference to the stat system call that provides the data to programs.

File names and directory implications

• Inodes do not contain filenames, only file contents.

• Unix directories are lists of "link" structures, each of which contains one filename and one inode number.

• The kernel must search a directory looking for a particular filename and then convert the filename to the correct corresponding inode number if the name is found.

The kernel's in-memory representation of this data is called struct inode in Linux. Systems derived from BSD use the term vnode, with the v of vnode referring to the kernel's virtual file system layer.

inode description

Regular files are required to have the following attributes:

• The length of the file in bytes.

• Device ID (this identifies the device containing the file).

• The User ID of the file's owner.

• The Group ID of the file.

• The file mode, which determines what users can read, write, and execute the file.

• Timestamps telling when the inode itself was last modified (ctime, change time), the file content last modified (mtime, modification time), and last accessed (atime, access time).

• A reference count telling how many hard links point to the inode.

• Pointers to the disk blocks that store the file's contents.

Example of structure:

[pic]

Implications

The properties of a file system that makes use of inodes surprise many users who are not used to the concept:

• If multiple names link to the same inode (they are all hard links to it) then all of the names are equivalent. The first one to have been created has no special status. This is unlike the sometimes more familiar symbolic links, where all of the links depend on the original name.

• An inode can even have no links at all. Normally such a file would be removed from the disk and its resources freed for reallocation (the normal process of deleting a file) but if any processes are holding the file open, they may continue to access it, and the file will only be finally deleted when the last reference to it is closed. This includes executable images which are implicitly held open by the processes executing them. For this reason, when programs are updated, it is recommended to delete the old executable first and create a new inode for the updated version, so that any instances of the old version currently executing may continue to do so unbothered.

• Typically, it is not possible to map from an open file to the filename that was used to open it. The operating system would convert the filename to an inode number at the first possible chance, then forget the filename. This means that the getcwd() and getwd() library functions would need to search the parent directory to find a file with an inode matching the "." directory, then search the grandparent directory for that directory, and so on until reaching the "/" directory. SVR4 and Linux systems retain extra information to avoid this awkwardness.

• Historically, it was possible to hard link directories. This made the directory structure be an arbitrary directed graph instead of a DAG. It was possible for a directory to be its own parent. Modern systems generally prohibit this confusing state, except that the root directory is still its own parent.

• A file's inode number will stay the same when it is moved to another directory on the same device, or when the disk is defragmented. Therefore, moving either a file's directory entry or its data (or both) is not enough to prevent a running process from accessing it, if the process ever had a chance of finding out the inode number. This also implies that completely conforming behavior of inodes is impossible to implement with many non-Unix file systems, such as FAT and its descendants, which don't have a way of storing this lasting "sameness" when both a file's directory entry and its data are moved around.

Variations in inode file systems

There are some important variations in inode file systems in current use that must be noted.

• Swap file systems in Linux typically don't support double indirection, or in some cases single indirection.

• The swap file and sleep mode swap file don't need to be any bigger than 10 GiB, as a matter of practice.

Defragmentation

• An inode file system would have to be offline to be fully defragmented on most systems -- but some online defragmenation tools exist.

• inode systems when defragmented can have data extraction rates higher than FAT32 or NTFS under optimal conditions

Practical considerations

Many computer programs used by system administrators in UNIX operating systems often give inode numbers to designate a file. Popular disk integrity checking utility fsck or pfiles command may serve here as examples.

Thus need naturally arises to translate inode numbers to file pathnames and vice versa.

This can be accomplished using file-finding utility find with option -inum or ls command with proper option which on many platforms is -i.

Y2038 problem

Some Inode file systems are Y2038 (aka Unix time) safe with respect to date overflow prevention -- but not all Inode file systems in use are protected from this problem. When setting up a server it will become more important over time to avoid the use of these non-POSIX compliant file systems. POSIX in its latest revsion supports system time and date

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