Name
fsync, fdatasync — synchronize a file's in-core state with storage device
Synopsis
#include <unistd.h>
int
fsync( |
int | fd); |
int
fdatasync( |
int | fd); |
![[Note]](../stylesheet/note.png) |
Note | ||||
|---|---|---|---|---|---|
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DESCRIPTION
fsync() transfers
("flushes") all modified in-core data of (i.e., modified
buffer cache pages for) the file referred to by the file
descriptor fd to the
disk device (or other permanent storage device) where that
file resides. The call blocks until the device reports that
the transfer has completed. It also flushes metadata
information associated with the file (see stat(2)).
Calling fsync() does not
necessarily ensure that the entry in the directory containing
the file has also reached disk. For that an explicit
fsync() on a file descriptor
for the directory is also needed.
fdatasync() is similar to
fsync(), but does not flush
modified metadata unless that metadata is needed in order to
allow a subsequent data retrieval to be correctly handled.
For example, changes to st_atime or st_mtime (respectively, time
of last access and time of last modification; see stat(2)) do not require
flushing because they are not necessary for a subsequent data
read to be handled correctly. On the other hand, a change to
the file size (st_size, as made by say
ftruncate(2)), would
require a metadata flush.
The aim of fdatasync() is to
reduce disk activity for applications that do not require all
metadata to be synchronized with the disk.
RETURN VALUE
On success, these system calls return zero. On error,
−1 is returned, and errno
is set appropriately.
ERRORS
- EBADF
-
fdis not a valid file descriptor open for writing. - EIO
-
An error occurred during synchronization.
- EROFS, EINVAL
-
fdis bound to a special file which does not support synchronization.
AVAILABILITY
On POSIX systems on which fdatasync() is available, _POSIX_SYNCHRONIZED_IO is defined in
<unistd.h>
to a value greater than 0. (See also sysconf(3).)
NOTES
Applications that access databases or log files often
write a tiny data fragment (e.g., one line in a log file) and
then call fsync() immediately
in order to ensure that the written data is physically stored
on the harddisk. Unfortunately, fsync() will always initiate two write
operations: one for the newly written data and another one in
order to update the modification time stored in the inode. If
the modification time is not a part of the transaction
concept fdatasync() can be used
to avoid unnecessary inode disk write operations.
If the underlying hard disk has write caching enabled,
then the data may not really be on permanent storage when
fsync() / fdatasync() return.
When an ext2 file system is mounted with the sync option, directory entries are also
implicitly synced by fsync().
On kernels before 2.4, fsync() on big files can be inefficient. An
alternative might be to use the O_SYNC flag to open(2).
In Linux 2.2 and earlier, fdatasync() is equivalent to fsync(), and so has no performance
advantage.