obsolete

NAME

oldfstat, oldlstat, oldstat, oldolduname, olduname - obsolete system calls  

SYNOPSIS

Obsolete system calls.  

DESCRIPTION

The Linux 2.0 kernel implements these calls to support old executables. These calls return structures which have grown since their first implementation, but old executables must continue to receive old smaller structures.

Current executables should be linked with current libraries and never use these calls.  

CONFORMING TO

These calls are unique to Linux and should not be used at all in new programs.  

SEE ALSO

fstat(2), lstat(2), stat(2), uname(2), unimplemented(2)

oldlstat

NAME

oldfstat, oldlstat, oldstat, oldolduname, olduname - obsolete system calls  

SYNOPSIS

Obsolete system calls.  

DESCRIPTION

The Linux 2.0 kernel implements these calls to support old executables. These calls return structures which have grown since their first implementation, but old executables must continue to receive old smaller structures.

Current executables should be linked with current libraries and never use these calls.  

CONFORMING TO

These calls are unique to Linux and should not be used at all in new programs.  

SEE ALSO

fstat(2), lstat(2), stat(2), uname(2), unimplemented(2)

oldstat

NAME

oldfstat, oldlstat, oldstat, oldolduname, olduname - obsolete system calls  

SYNOPSIS

Obsolete system calls.  

DESCRIPTION

The Linux 2.0 kernel implements these calls to support old executables. These calls return structures which have grown since their first implementation, but old executables must continue to receive old smaller structures.

Current executables should be linked with current libraries and never use these calls.  

CONFORMING TO

These calls are unique to Linux and should not be used at all in new programs.  

SEE ALSO

fstat(2), lstat(2), stat(2), uname(2), unimplemented(2)

open

NAME

open, creat - open and possibly create a file or device  

SYNOPSIS

#include <sys/types.h> #include <sys/stat.h> #include <fcntl.h> int open(const char *pathname, int flags); int open(const char *pathname, int flags, mode_t mode); int creat(const char *pathname, mode_t mode);

 

DESCRIPTION

The open() system call is used to convert a pathname into a file descriptor (a small, non-negative integer for use in subsequent I/O as with read, write, etc.). When the call is successful, the file descriptor returned will be the lowest file descriptor not currently open for the process. This call creates a new open file, not shared with any other process. (But shared open files may arise via the fork(2) system call.) The new file descriptor is set to remain open across exec functions (see fcntl(2)). The file offset is set to the beginning of the file.

The parameter flags is one of O_RDONLY, O_WRONLY or O_RDWR which request opening the file read-only, write-only or read/write, respectively, bitwise-or`d with zero or more of the following:

O_CREAT

If the file does not exist it will be created. The owner (user ID) of the file is set to the effective user ID of the process. The group ownership (group ID) is set either to the effective group ID of the process or to the group ID of the parent directory (depending on filesystem type and mount options, and the mode of the parent directory, see, e.g., the mount options bsdgroups and sysvgroups of the ext2 filesystem, as described in mount(8)).

O_EXCL

When used with O_CREAT, if the file already exists it is an error and the open will fail. In this context, a symbolic link exists, regardless of where its points to. O_EXCL is broken on NFS file systems, programs which rely on it for performing locking tasks will contain a race condition. The solution for performing atomic file locking using a lockfile is to create a unique file on the same fs (e.g., incorporating hostname and pid), use link(2) to make a link to the lockfile. If link() returns 0, the lock is successful. Otherwise, use stat(2) on the unique file to check if its link count has increased to 2, in which case the lock is also successful.

O_NOCTTY

If pathname refers to a terminal device --- see tty(4) --- it will not become the process`s controlling terminal even if the process does not have one.

O_TRUNC

If the file already exists and is a regular file and the open mode allows writing (i.e., is O_RDWR or O_WRONLY) it will be truncated to length 0. If the file is a FIFO or terminal device file, the O_TRUNC flag is ignored. Otherwise the effect of O_TRUNC is unspecified.

O_APPEND

The file is opened in append mode. Before each write, the file pointer is positioned at the end of the file, as if with lseek. O_APPEND may lead to corrupted files on NFS file systems if more than one process appends data to a file at once. This is because NFS does not support appending to a file, so the client kernel has to simulate it, which can`t be done without a race condition.

O_NONBLOCK or O_NDELAY

When possible, the file is opened in non-blocking mode. Neither the open nor any subsequent operations on the file descriptor which is returned will cause the calling process to wait. For the handling of FIFOs (named pipes), see also fifo(4). This mode need not have any effect on files other than FIFOs.

O_SYNC

The file is opened for synchronous I/O. Any writes on the resulting file descriptor will block the calling process until the data has been physically written to the underlying hardware. See RESTRICTIONS below, though.

O_NOFOLLOW

If pathname is a symbolic link, then the open fails. This is a FreeBSD extension, which was added to Linux in version 2.1.126. Symbolic links in earlier components of the pathname will still be followed. The headers from glibc 2.0.100 and later include a definition of this flag; kernels before 2.1.126 will ignore it if used.

O_DIRECTORY

If pathname is not a directory, cause the open to fail. This flag is Linux-specific, and was added in kernel version 2.1.126, to avoid denial-of-service problems if opendir(3) is called on a FIFO or tape device, but should not be used outside of the implementation of opendir.

O_DIRECT

Try to minimize cache effects of the I/O to and from this file. In general this will degrade performance, but it is useful in special situations, such as when applications do their own caching. File I/O is done directly to/from user space buffers. The I/O is synchronous, i.e., at the completion of the read(2) or write(2) system call, data is guaranteed to have been transferred. Under Linux 2.4 transfer sizes, and the alignment of user buffer and file offset must all be multiples of the logical block size of the file system. Under Linux 2.6 alignment to 512-byte boundaries suffices.
A semantically similar interface for block devices is described in raw(8).

O_ASYNC

Generate a signal (SIGIO by default, but this can be changed via fcntl(2)) when input or output becomes possible on this file descriptor. This feature is only available for terminals, pseudo-terminals, and sockets. See fcntl(2) for further details.

O_LARGEFILE

On 32-bit systems that support the Large Files System, allow files whose sizes cannot be represented in 31 bits to be opened.

Some of these optional flags can be altered using fcntl after the file has been opened.

The argument mode specifies the permissions to use in case a new file is created. It is modified by the process`s umask in the usual way: the permissions of the created file are (mode & ~umask). Note that this mode only applies to future accesses of the newly created file; the open call that creates a read-only file may well return a read/write file descriptor.

The following symbolic constants are provided for mode:

S_IRWXU

00700 user (file owner) has read, write and execute permission

S_IRUSR (S_IREAD)

00400 user has read permission

S_IWUSR (S_IWRITE)

00200 user has write permission

S_IXUSR (S_IEXEC)

00100 user 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 have read, write and execute permission

S_IROTH

00004 others have read permission

S_IWOTH

00002 others have write permisson

S_IXOTH

00001 others have execute permission

mode must be specified when O_CREAT is in the flags, and is ignored otherwise.

creat is equivalent to open with flags equal to O_CREAT|O_WRONLY|O_TRUNC.  

RETURN VALUE

open and creat return the new file descriptor, or -1 if an error occurred (in which case, errno is set appropriately). Note that open can open device special files, but creat cannot create them - use mknod(2) instead.

On NFS file systems with UID mapping enabled, open may return a file descriptor but e.g. read(2) requests are denied with EACCES. This is because the client performs open by checking the permissions, but UID mapping is performed by the server upon read and write requests.

If the file is newly created, its atime, ctime, mtime fields are set to the current time, and so are the ctime and mtime fields of the parent directory. Otherwise, if the file is modified because of the O_TRUNC flag, its ctime and mtime fields are set to the current time.

 

ERRORS

EEXIST

pathname already exists and O_CREAT and O_EXCL were used.

EISDIR

pathname refers to a directory and the access requested involved writing (that is, O_WRONLY or O_RDWR is set).

EACCES

The requested access to the file is not allowed, or one of the directories in pathname did not allow search (execute) permission, or the file did not exist yet and write access to the parent directory is not allowed.

ENAMETOOLONG

pathname was too long.

ENOENT

O_CREAT is not set and the named file does not exist. Or, a directory component in pathname does not exist or is a dangling symbolic link.

ENOTDIR

A component used as a directory in pathname is not, in fact, a directory, or O_DIRECTORY was specified and pathname was not a directory.

ENXIO

O_NONBLOCK | O_WRONLY is set, the named file is a FIFO and no process has the file open for reading. Or, the file is a device special file and no corresponding device exists.

ENODEV

pathname refers to a device special file and no corresponding device exists. (This is a Linux kernel bug - in this situation ENXIO must be returned.)

EROFS

pathname refers to a file on a read-only filesystem and write access was requested.

ETXTBSY

pathname refers to an executable image which is currently being executed and write access was requested.

EFAULT

pathname points outside your accessible address space.

ELOOP

Too many symbolic links were encountered in resolving pathname, or O_NOFOLLOW was specified but pathname was a symbolic link.

ENOSPC

pathname was to be created but the device containing pathname has no room for the new file.

ENOMEM

Insufficient kernel memory was available.

EMFILE

The process already has the maximum number of files open.

ENFILE

The limit on the total number of files open on the system has been reached.

 

NOTE

Under Linux, the O_NONBLOCK flag indicates that one wants to open but does not necessarily have the intention to read or write. This is typically used to open devices in order to get a file descriptor for use with ioctl(2).  

CONFORMING TO

SVr4, SVID, POSIX, X/OPEN, BSD 4.3. The O_NOFOLLOW and O_DIRECTORY flags are Linux-specific. One may have to define the _GNU_SOURCE macro to get their definitions.

The (undefined) effect of O_RDONLY | O_TRUNC various among implementations. On many systems the file is actually truncated.

The O_DIRECT flag was introduced in SGI IRIX, where it has alignment restrictions similar to those of Linux 2.4. IRIX has also a fcntl(2) call to query appropriate alignments, and sizes. FreeBSD 4.x introduced a flag of same name, but without alignment restrictions. Support was added under Linux in kernel version 2.4.10. Older Linux kernels simply ignore this flag.  

BUGS

"The thing that has always disturbed me about O_DIRECT is that the whole interface is just stupid, and was probably designed by a deranged monkey on some serious mind-controlling substances." -- Linus  

RESTRICTIONS

There are many infelicities in the protocol underlying NFS, affecting amongst others O_SYNC and O_NDELAY.

POSIX provides for three different variants of synchronised I/O, corresponding to the flags O_SYNC, O_DSYNC and O_RSYNC. Currently (2.1.130) these are all synonymous under Linux.  

SEE ALSO

read(2), write(2), fcntl(2), close(2), link(2), mknod(2), mount(2), stat(2), umask(2), unlink(2), socket(2), fopen(3), fifo(4)

outb_p

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

outl_p

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

outsl

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

outw

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

oldfstat

NAME

oldfstat, oldlstat, oldstat, oldolduname, olduname - obsolete system calls  

SYNOPSIS

Obsolete system calls.  

DESCRIPTION

The Linux 2.0 kernel implements these calls to support old executables. These calls return structures which have grown since their first implementation, but old executables must continue to receive old smaller structures.

Current executables should be linked with current libraries and never use these calls.  

CONFORMING TO

These calls are unique to Linux and should not be used at all in new programs.  

SEE ALSO

fstat(2), lstat(2), stat(2), uname(2), unimplemented(2)

oldolduname

NAME

oldfstat, oldlstat, oldstat, oldolduname, olduname - obsolete system calls  

SYNOPSIS

Obsolete system calls.  

DESCRIPTION

The Linux 2.0 kernel implements these calls to support old executables. These calls return structures which have grown since their first implementation, but old executables must continue to receive old smaller structures.

Current executables should be linked with current libraries and never use these calls.  

CONFORMING TO

These calls are unique to Linux and should not be used at all in new programs.  

SEE ALSO

fstat(2), lstat(2), stat(2), uname(2), unimplemented(2)

olduname

NAME

oldfstat, oldlstat, oldstat, oldolduname, olduname - obsolete system calls  

SYNOPSIS

Obsolete system calls.  

DESCRIPTION

The Linux 2.0 kernel implements these calls to support old executables. These calls return structures which have grown since their first implementation, but old executables must continue to receive old smaller structures.

Current executables should be linked with current libraries and never use these calls.  

CONFORMING TO

These calls are unique to Linux and should not be used at all in new programs.  

SEE ALSO

fstat(2), lstat(2), stat(2), uname(2), unimplemented(2)

outb

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

outl

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

outsb

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

outsw

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)

outw_p

NAME

outb, outw, outl, outsb, outsw, outsl, inb, inw, inl, insb, insw, insl, outb_p, outw_p, outl_p, inb_p, inw_p, inl_p - port I/O

 

DESCRIPTION

This family of functions is used to do low level port input and output. The out* functions do port output, the in* functions do port input; the b-suffix functions are byte-width and the w-suffix functions word-width; the _p-suffix functions pause until the I/O completes.

They are primarily designed for internal kernel use, but can be used from user space.

You compile with -O or -O2 or similar. The functions are defined as inline macros, and will not be substituted in without optimization enabled, causing unresolved references at link time.

You use ioperm(2) or alternatively iopl(2) to tell the kernel to allow the user space application to access the I/O ports in question. Failure to do this will cause the application to receive a segmentation fault.

 

CONFORMING TO

outb and friends are hardware specific. The port and value arguments are in the opposite order from most DOS implementations.  

SEE ALSO

ioperm(2), iopl(2)