FCNTL(2) | System Calls Manual | FCNTL(2) |
fcntl
— file
control
Standard C Library (libc, -lc)
#include
<fcntl.h>
int
fcntl
(int
fd, int cmd,
...);
The
fcntl
()
system call provides for control over descriptors. The argument
fd is a descriptor to be operated on by
cmd as described below. Depending on the value of
cmd, fcntl
() can take an
additional third argument int arg.
F_DUPFD
FD_CLOEXEC
associated
with the new file descriptor is cleared, so the file descriptor is to
remain open across execve(2) system calls.F_DUPFD_CLOEXEC
F_DUPFD
, but the
FD_CLOEXEC
flag associated with the new file
descriptor is set, so the file descriptor is closed when
execve(2) system call executes.F_DUP2FD
dup2(fd, arg)
F_DUP2FD_CLOEXEC
F_DUP2FD
, but the
FD_CLOEXEC
flag associated with the new file
descriptor is set.
The F_DUP2FD
and
F_DUP2FD_CLOEXEC
constants are not portable, so
they should not be used if portability is needed. Use
dup2
()
instead of F_DUP2FD
.
F_GETFD
FD_CLOEXEC
. If the
returned value ANDed with FD_CLOEXEC
is 0, the
file will remain open across
exec
(),
otherwise the file will be closed upon execution of
exec
() (arg is
ignored).F_SETFD
FD_CLOEXEC
, as described above.F_GETFL
F_SETFL
F_GETOWN
SIGIO
and SIGURG
signals;
process groups are returned as negative values (arg
is ignored).F_SETOWN
SIGIO
and SIGURG
signals; process groups are specified
by supplying arg as negative, otherwise
arg is interpreted as a process ID.F_READAHEAD
F_RDAHEAD
The flags for the F_GETFL
and
F_SETFL
flags are as follows:
O_NONBLOCK
EAGAIN
.O_APPEND
O_APPEND
flag of open(2).O_DIRECT
O_ASYNC
SIGIO
signal to be sent to the process
group when I/O is possible, e.g., upon availability of data to be
read.Several commands are available for doing advisory file locking; they all operate on the following structure:
struct flock { off_t l_start; /* starting offset */ off_t l_len; /* len = 0 means until end of file */ pid_t l_pid; /* lock owner */ short l_type; /* lock type: read/write, etc. */ short l_whence; /* type of l_start */ int l_sysid; /* remote system id or zero for local */ };
F_GETLK
fcntl
()
in the flock structure. If no lock is found that
would prevent this lock from being created, the structure is left
unchanged by this system call except for the lock type which is set to
F_UNLCK
.F_SETLK
F_SETLK
is used to establish shared (or read)
locks (F_RDLCK
) or exclusive (or write) locks,
(F_WRLCK
), as well as remove either type of lock
(F_UNLCK
). If a shared or exclusive lock cannot be
set, fcntl
() returns immediately with
EAGAIN
.F_SETLKW
F_SETLK
except that if
a shared or exclusive lock is blocked by other locks, the process waits
until the request can be satisfied. If a signal that is to be caught is
received while fcntl
() is waiting for a region,
the fcntl
() will be interrupted if the signal
handler has not specified the SA_RESTART
(see
sigaction(2)).When a shared lock has been set on a segment of a file, other processes can set shared locks on that segment or a portion of it. A shared lock prevents any other process from setting an exclusive lock on any portion of the protected area. A request for a shared lock fails if the file descriptor was not opened with read access.
An exclusive lock prevents any other process from setting a shared lock or an exclusive lock on any portion of the protected area. A request for an exclusive lock fails if the file was not opened with write access.
The value of l_whence is
SEEK_SET
, SEEK_CUR
, or
SEEK_END
to indicate that the relative offset,
l_start bytes, will be measured from the start of the
file, current position, or end of the file, respectively. The value of
l_len is the number of consecutive bytes to be locked.
If l_len is negative, l_start
means end edge of the region. The l_pid and
l_sysid fields are only used with
F_GETLK
to return the process ID of the process
holding a blocking lock and the system ID of the system that owns that
process. Locks created by the local system will have a system ID of zero.
After a successful F_GETLK
request, the value of
l_whence is SEEK_SET
.
Locks may start and extend beyond the current end of a file, but may not start or extend before the beginning of the file. A lock is set to extend to the largest possible value of the file offset for that file if l_len is set to zero. If l_whence and l_start point to the beginning of the file, and l_len is zero, the entire file is locked. If an application wishes only to do entire file locking, the flock(2) system call is much more efficient.
There is at most one type of lock set for each byte in the file.
Before a successful return from an F_SETLK
or an
F_SETLKW
request when the calling process has
previously existing locks on bytes in the region specified by the request,
the previous lock type for each byte in the specified region is replaced by
the new lock type. As specified above under the descriptions of shared locks
and exclusive locks, an F_SETLK
or an
F_SETLKW
request fails or blocks respectively when
another process has existing locks on bytes in the specified region and the
type of any of those locks conflicts with the type specified in the
request.
The queuing for F_SETLKW
requests on local
files is fair; that is, while the thread is blocked, subsequent requests
conflicting with its requests will not be granted, even if these requests do
not conflict with existing locks.
This interface follows the completely stupid semantics of System V and IEEE Std 1003.1-1988 (“POSIX.1”) that require that all locks associated with a file for a given process are removed when any file descriptor for that file is closed by that process. This semantic means that applications must be aware of any files that a subroutine library may access. For example if an application for updating the password file locks the password file database while making the update, and then calls getpwnam(3) to retrieve a record, the lock will be lost because getpwnam(3) opens, reads, and closes the password database. The database close will release all locks that the process has associated with the database, even if the library routine never requested a lock on the database. Another minor semantic problem with this interface is that locks are not inherited by a child process created using the fork(2) system call. The flock(2) interface has much more rational last close semantics and allows locks to be inherited by child processes. The flock(2) system call is recommended for applications that want to ensure the integrity of their locks when using library routines or wish to pass locks to their children.
The
fcntl
(),
flock(2), and lockf(3) locks are
compatible. Processes using different locking interfaces can cooperate over
the same file safely. However, only one of such interfaces should be used
within the same process. If a file is locked by a process through
flock(2), any record within the file will be seen as
locked from the viewpoint of another process using
fcntl
() or lockf(3), and vice
versa. Note that
fcntl
(F_GETLK) returns -1 in
l_pid if the process holding a blocking lock
previously locked the file descriptor by flock(2).
All locks associated with a file for a given process are removed when the process terminates.
All locks obtained before a call to execve(2) remain in effect until the new program releases them. If the new program does not know about the locks, they will not be released until the program exits.
A potential for deadlock occurs if a process controlling a locked
region is put to sleep by attempting to lock the locked region of another
process. This implementation detects that sleeping until a locked region is
unlocked would cause a deadlock and fails with an
EDEADLK
error.
Upon successful completion, the value returned depends on cmd as follows:
Otherwise, a value of -1 is returned and errno is set to indicate the error.
The fcntl
() system call will fail if:
EAGAIN
]F_SETLK
,
the type of lock (l_type) is a shared lock
(F_RDLCK
) or exclusive lock
(F_WRLCK
), and the segment of a file to be locked
is already exclusive-locked by another process; or the type is an
exclusive lock and some portion of the segment of a file to be locked is
already shared-locked or exclusive-locked by another process.EBADF
]The argument cmd is
F_DUP2FD
, and arg is not a
valid file descriptor.
The argument cmd is
F_SETLK
or F_SETLKW
, the
type of lock (l_type) is a shared lock
(F_RDLCK
), and fd is not a
valid file descriptor open for reading.
The argument cmd is
F_SETLK
or F_SETLKW
, the
type of lock (l_type) is an exclusive lock
(F_WRLCK
), and fd is not a
valid file descriptor open for writing.
EDEADLK
]F_SETLKW
, and a deadlock condition was
detected.EINTR
]F_SETLKW
, and the system call was interrupted by a
signal.EINVAL
]F_DUPFD
and arg is negative or greater than the maximum
allowable number (see getdtablesize(2)).
The argument cmd is
F_GETLK
, F_SETLK
or
F_SETLKW
and the data to which
arg points is not valid.
EMFILE
]F_DUPFD
and the maximum number of file descriptors permitted for the process are
already in use, or no file descriptors greater than or equal to
arg are available.ENOTTY
]ENOLCK
]F_SETLK
or F_SETLKW
, and satisfying the lock or unlock
request would result in the number of locked regions in the system
exceeding a system-imposed limit.EOPNOTSUPP
]F_GETLK
,
F_SETLK
or F_SETLKW
and
fd refers to a file for which locking is not
supported.EOVERFLOW
]F_GETLK
,
F_SETLK
or F_SETLKW
and an
off_t calculation overflowed.EPERM
]F_SETOWN
and the process ID or process group given as an argument is in a different
session than the caller.ESRCH
]F_SETOWN
and the process ID given as argument is not in use.In addition, if fd refers to a descriptor
open on a terminal device (as opposed to a descriptor open on a socket), a
cmd of F_SETOWN
can fail for
the same reasons as in tcsetpgrp(3), and a
cmd of F_GETOWN
for the
reasons as stated in tcgetpgrp(3).
close(2), dup2(2), execve(2), flock(2), getdtablesize(2), open(2), sigaction(2), lockf(3), tcgetpgrp(3), tcsetpgrp(3)
The F_DUP2FD
constant is non portable. It
is provided for compatibility with AIX and Solaris.
Per Version 4 of the Single UNIX
Specification (“SUSv4”), a call with
F_SETLKW
should fail with
[EINTR
] after any caught signal and should continue
waiting during thread suspension such as a stop signal. However, in this
implementation a call with F_SETLKW
is restarted
after catching a signal with a SA_RESTART
handler or
a thread suspension such as a stop signal.
The fcntl
() system call appeared in
4.2BSD.
The F_DUP2FD
constant first appeared in
FreeBSD 7.1.
May 2, 2018 | Debian |