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INODE(7)                                                                Linux Programmer's Manual                                                               INODE(7)

NAME
       inode - file inode information

DESCRIPTION
       Each  file  has  an  inode  containing metadata about the file.  An application can retrieve this metadata using stat(2) (or related calls), which returns a stat
       structure, or statx(2), which returns a statx structure.

       The following is a list of the information typically found in, or associated with, the file inode, with the names of the corresponding structure fields  returned
       by stat(2) and statx(2):

       Device where inode resides
              stat.st_dev; statx.stx_dev_minor and statx.stx_dev_major

              Each inode (as well as the associated file) resides in a filesystem that is hosted on a device.  That device is identified by the combination of its major
              ID (which identifies the general class of device) and minor ID (which identifies a specific instance in the general class).

       Inode number
              stat.st_ino; statx.stx_ino

              Each file in a filesystem has a unique inode number.  Inode numbers are guaranteed to be unique only within a filesystem (i.e., the same inode numbers may
              be used by different filesystems, which is the reason that hard links may not cross filesystem boundaries).  This field contains the file's inode number.

       File type and mode
              stat.st_mode; statx.stx_mode

              See the discussion of file type and mode, below.

       Link count
              stat.st_nlink; statx.stx_nlink

              This field contains the number of hard links to the file.  Additional links to an existing file are created using link(2).

       User ID
              st_uid stat.st_uid; statx.stx_uid

              This field records the user ID of the owner of the file.  For newly created files, the file user ID is the effective user ID of the creating process.  The
              user ID of a file can be changed using chown(2).

       Group ID
              stat.st_gid; statx.stx_gid

              The inode records the ID of the group owner of the file.  For newly created files, the file group ID is either the group ID of the parent directory or the
              effective  group ID of the creating process, depending on whether or not the set-group-ID bit is set on the parent directory (see below).  The group ID of
              a file can be changed using chown(2).

       Device represented by this inode
              stat.st_rdev; statx.stx_rdev_minor and statx.stx_rdev_major

              If this file (inode) represents a device, then the inode records the major and minor ID of that device.

       File size
              stat.st_size; statx.stx_size

              This field gives the size of the file (if it is a regular file or a symbolic link) in bytes.  The size of a symbolic link is the length of the pathname it
              contains, without a terminating null byte.

       Preferred block size for I/O
              stat.st_blksize; statx.stx_blksize

              This  field  gives  the "preferred" blocksize for efficient filesystem I/O.  (Writing to a file in smaller chunks may cause an inefficient read-modify-reā€
              write.)

       Number of blocks allocated to the file
              stat.st_blocks; statx.stx_size

              This field indicates the number of blocks allocated to the file, 512-byte units, (This may be smaller than st_size/512 when the file has holes.)

              The POSIX.1 standard notes that the unit for the st_blocks member of the stat structure is not defined by the standard.  On many   implementations  it  is
              512 bytes; on a few systems, a different unit is used, such as 1024.  Furthermore, the unit may differ on a per-filesystem basis.

       Last access timestamp (atime)
              stat.st_atime; statx.stx_atime

              This  is  the  file's last access timestamp.  It is changed by file accesses, for example, by execve(2), mknod(2), pipe(2), utime(2), and read(2) (of more
              than zero bytes).  Other interfaces, such as mmap(2), may or may not update the atime timestamp

              Some filesystem types allow mounting in such a way that file and/or directory accesses do not cause an update of the atime timestamp.  (See noatime, nodiā€
              ratime,  and  relatime  in  mount(8),  and related information in mount(2).)  In addition, the atime timestamp is not updated if a file is opened with the
              O_NOATIME flag; see open(2).

       File creation (birth) timestamp (btime)
              (not returned in the stat structure); statx.stx_btime

              The file's creation timestamp.  This is set on file creation and not changed subsequently.

              The btime timestamp was not historically present on UNIX systems and is not currently supported by most Linux filesystems.

       Last modification timestamp (mtime)
              stat.st_mtime; statx.stx_mtime

              This is the file's last modification timestamp.  It is changed by file modifications, for example, by mknod(2), truncate(2), utime(2),  and  write(2)  (of
              more  than  zero bytes).  Moreover, the mtime timestamp of a directory is changed by the creation or deletion of files in that directory.  The mtime timeā€
              stamp is not changed for changes in owner, group, hard link count, or mode.

       Last status change timestamp (ctime)
              stat.st_ctime; statx.stx_ctime

              This is the file's last status change timestamp.  It is changed by writing or by setting inode information (i.e., owner, group, link count, mode, etc.).

       The timestamp fields report time measured with a zero point at the Epoch, 1970-01-01 00:00:00 +0000, UTC (see time(7)).

       Nanosecond timestamps are supported on XFS, JFS, Btrfs, and ext4 (since Linux 2.6.23).  Nanosecond timestamps are not supported in ext2, ext3, and Reiserfs.   In
       order  to  return timestamps with nanosecond precision, the timestamp fields in the stat and statx structures are defined as structures that include a nanosecond
       component.  See stat(2) and statx(2) for details.  On filesystems that do not support subsecond timestamps, the nanosecond fields in the stat  and  statx  strucā€
       tures are returned with the value 0.

   The file type and mode
       The stat.st_mode field (for statx(2), the statx.stx_mode field) contains the file type and mode.

       POSIX refers to the stat.st_mode bits corresponding to the mask S_IFMT (see below) as the file type, the 12 bits corresponding to the mask 07777 as the file mode
       bits and the least significant 9 bits (0777) as the file permission bits.

       The following mask values are defined for the file type:

           S_IFMT     0170000   bit mask for the file type bit field

           S_IFSOCK   0140000   socket
           S_IFLNK    0120000   symbolic link
           S_IFREG    0100000   regular file
           S_IFBLK    0060000   block device
           S_IFDIR    0040000   directory
           S_IFCHR    0020000   character device
           S_IFIFO    0010000   FIFO

       Thus, to test for a regular file (for example), one could write:

           stat(pathname, &sb);
           if ((sb.st_mode & S_IFMT) == S_IFREG) {
               /* Handle regular file */
           }

       Because tests of the above form are common, additional macros are defined by POSIX to allow the test of the file type in st_mode to be written more concisely:

           S_ISREG(m)  is it a regular file?

           S_ISDIR(m)  directory?

           S_ISCHR(m)  character device?

           S_ISBLK(m)  block device?

           S_ISFIFO(m) FIFO (named pipe)?

           S_ISLNK(m)  symbolic link?  (Not in POSIX.1-1996.)

           S_ISSOCK(m) socket?  (Not in POSIX.1-1996.)

       The preceding code snippet could thus be rewritten as:

           stat(pathname, &sb);
           if (S_ISREG(sb.st_mode)) {
               /* Handle regular file */
           }

       The definitions of most of the above file type test macros are provided if any of the following feature test macros is defined: _BSD_SOURCE (in  glibc  2.19  and
       earlier),  _SVID_SOURCE  (in  glibc  2.19 and earlier), or _DEFAULT_SOURCE (in glibc 2.20 and later).  In addition, definitions of all of the above macros except
       S_IFSOCK and S_ISSOCK() are provided if _XOPEN_SOURCE is defined.

       The definition of S_IFSOCK can also be exposed either by defining _XOPEN_SOURCE with a  value  of  500  or  greater  or  (since  glibc  2.24)  by  defining  both
       _XOPEN_SOURCE and _XOPEN_SOURCE_EXTENDED.

       The  definition  of  S_ISSOCK()  is  exposed if any of the following feature test macros is defined: _BSD_SOURCE (in glibc 2.19 and earlier), _DEFAULT_SOURCE (in
       glibc 2.20 and later), _XOPEN_SOURCE with a value of 500 or greater, _POSIX_C_SOURCE with a value of 200112L or greater, or (since glibc 2.24) by  defining  both
       _XOPEN_SOURCE and _XOPEN_SOURCE_EXTENDED.

       The following mask values are defined for the file mode component of the st_mode field:

           S_ISUID     04000   set-user-ID bit (see execve(2))
           S_ISGID     02000   set-group-ID bit (see below)
           S_ISVTX     01000   sticky bit (see below)

           S_IRWXU     00700   owner has read, write, and execute permission
           S_IRUSR     00400   owner has read permission
           S_IWUSR     00200   owner has write permission
           S_IXUSR     00100   owner has execute permission

           S_IRWXG     00070   group has read, write, and execute permission
           S_IRGRP     00040   group has read permission
           S_IWGRP     00020   group has write permission
           S_IXGRP     00010   group has execute permission

           S_IRWXO     00007   others (not in group) have read, write, and execute permission
           S_IROTH     00004   others have read permission
           S_IWOTH     00002   others have write permission
           S_IXOTH     00001   others have execute permission

       The set-group-ID bit (S_ISGID) has several special uses.  For a directory, it indicates that BSD semantics are to be used for that directory: files created there
       inherit their group ID from the directory, not from the effective group ID of the creating process, and directories created there will also get the  S_ISGID  bit
       set.   For an executable file, the set-group-ID bit causes the effective group ID of a process that executes the file to change as described in execve(2).  For a
       file that does not have the group execution bit (S_IXGRP) set, the set-group-ID bit indicates mandatory file/record locking.

       The sticky bit (S_ISVTX) on a directory means that a file in that directory can be renamed or deleted only by the owner of the file, by the owner of the directoā€
       ry, and by a privileged process.

CONFORMING TO
       If  you  need  to obtain the definition of the blkcnt_t or blksize_t types from <sys/stat.h>, then define _XOPEN_SOURCE with the value 500 or greater (before inā€
       cluding any header files).

       POSIX.1-1990 did not describe the S_IFMT, S_IFSOCK, S_IFLNK, S_IFREG, S_IFBLK, S_IFDIR, S_IFCHR, S_IFIFO, and S_ISVTX constants, but instead specified the use of
       the macros S_ISDIR() and so on.  The S_IF* constants are present in POSIX.1-2001 and later.

       The S_ISLNK() and S_ISSOCK() macros were not in POSIX.1-1996, but both are present in POSIX.1-2001; the former is from SVID 4, the latter from SUSv2.

       UNIX V7 (and later systems) had S_IREAD, S_IWRITE, S_IEXEC, and where POSIX prescribes the synonyms S_IRUSR, S_IWUSR, and S_IXUSR.

NOTES
       For pseudofiles that are autogenerated by the kernel, the file size (stat.st_size; statx.stx_size) reported by the kernel is not accurate.  For example, the valā€
       ue 0 is returned for many files under the /proc directory, while various files under /sys report a size of 4096 bytes, even though the file content  is  smaller.
       For such files, one should simply try to read as many bytes as possible (and append '\0' to the returned buffer if it is to be interpreted as a string).

SEE ALSO
       stat(1), stat(2), statx(2), symlink(7)

Linux                                                                          2021-03-22                                                                       INODE(7)