pwritev2 (2) - Linux Manuals
pwritev2: read or write data into multiple buffers
NAME
readv, writev, preadv, pwritev, preadv2, pwritev2 - read or write data into multiple buffers
SYNOPSIS
#include <sys/uio.h> ssize_t readv(int fd, const struct iovec *iov, int iovcnt); ssize_t writev(int fd, const struct iovec *iov, int iovcnt); ssize_t preadv(int fd, const struct iovec *iov, int iovcnt, off_t offset); ssize_t pwritev(int fd, const struct iovec *iov, int iovcnt, off_t offset); ssize_t preadv2(int fd, const struct iovec *iov, int iovcnt, off_t offset, int flags); ssize_t pwritev2(int fd, const struct iovec *iov, int iovcnt, off_t offset, int flags);
Feature Test Macro Requirements for glibc (see feature_test_macros(7)):
preadv(),
pwritev():
The
writev()
system call writes
iovcnt
buffers of data described by
iov
to the file associated with the file descriptor
fd
("gather output").
The pointer
iov
points to an array of
iovec
structures,
defined in
<sys/uio.h>
as:
struct iovec {
The
readv()
system call works just like
read(2)
except that multiple buffers are filled.
The
writev()
system call works just like
write(2)
except that multiple buffers are written out.
Buffers are processed in array order.
This means that
readv()
completely fills
iov[0]
before proceeding to
iov[1],
and so on.
(If there is insufficient data, then not all buffers pointed to by
iov
may be filled.)
Similarly,
writev()
writes out the entire contents of
iov[0]
before proceeding to
iov[1],
and so on.
The data transfers performed by
readv()
and
writev()
are atomic: the data written by
writev()
is written as a single block that is not intermingled with output
from writes in other processes (but see
pipe(7)
for an exception);
analogously,
readv()
is guaranteed to read a contiguous block of data from the file,
regardless of read operations performed in other threads or processes
that have file descriptors referring to the same open file description
(see
open(2)).
The
pwritev()
system call combines the functionality of
writev()
and
pwrite(2).
It performs the same task as
writev(),
but adds a fourth argument,
offset,
which specifies the file offset at which the output operation
is to be performed.
The file offset is not changed by these system calls.
The file referred to by
fd
must be capable of seeking.
Unlike
preadv()
and
pwritev(),
if the
offset
argument is -1, then the current file offset is used and updated.
The
flags
argument contains a bitwise OR of zero or more of the following flags:
Note that it is not an error for a successful call to transfer fewer bytes
than requested (see
read(2)
and
write(2)).
On error, -1 is returned, and errno is set appropriately.
preadv2()
and
pwritev2()
first appeared in Linux 4.6.
Library support was added in glibc 2.26.
preadv(),
pwritev():
nonstandard, but present also on the modern BSDs.
preadv2(),
pwritev2():
nonstandard Linux extension.
unsigned long pos_l, unsigned long pos
These arguments contain, respectively, the low order and high order 32 bits of
offset.
The need for this extra effort in the glibc wrapper functions
went away with Linux 2.2 and later.
However, glibc continued to provide this behavior until version 2.10.
Starting with glibc version 2.9,
the wrapper functions provide this behavior only if the library detects
that the system is running a Linux kernel older than version 2.6.18
(an arbitrarily selected kernel version).
And since glibc 2.20
(which requires a minimum Linux kernel version of 2.6.32),
the glibc wrapper functions always just directly invoke the system calls.
char *str0 = "hello ";
char *str1 = "world\n";
struct iovec iov[2];
ssize_t nwritten;
iov[0].iov_base = str0;
iov[0].iov_len = strlen(str0);
iov[1].iov_base = str1;
iov[1].iov_len = strlen(str1);
nwritten = writev(STDOUT_FILENO, iov, 2);
DESCRIPTION
The
readv()
system call reads
iovcnt
buffers from the file associated with the file descriptor
fd
into the buffers described by
iov
("scatter input").
preadv() and pwritev()
The
preadv()
system call combines the functionality of
readv()
and
pread(2).
It performs the same task as
readv(),
but adds a fourth argument,
offset,
which specifies the file offset at which the input operation
is to be performed.
preadv2() and pwritev2()
These system calls are similar to
preadv()
and
pwritev()
calls, but add a fifth argument,
flags,
which modifies the behavior on a per-call basis.
RETURN VALUE
On success,
readv(),
preadv(),
and
preadv2()
return the number of bytes read;
writev(),
pwritev(),
and
pwritev2()
return the number of bytes written.
ERRORS
The errors are as given for
read(2)
and
write(2).
Furthermore,
preadv(),
preadv2(),
pwritev(),
and
pwritev2()
can also fail for the same reasons as
lseek(2).
Additionally, the following errors are defined:
VERSIONS
preadv()
and
pwritev()
first appeared in Linux 2.6.30; library support was added in glibc 2.10.
CONFORMING TO
readv(),
writev():
POSIX.1-2001, POSIX.1-2008,
4.4BSD (these system calls first appeared in 4.2BSD).
NOTES
POSIX.1 allows an implementation to place a limit on
the number of items that can be passed in
iov.
An implementation can advertise its limit by defining
IOV_MAX
in
<limits.h>
or at run time via the return value from
sysconf(_SC_IOV_MAX).
On modern Linux systems, the limit is 1024.
Back in Linux 2.0 days, this limit was 16.
C library/kernel differences
The raw
preadv()
and
pwritev()
system calls have call signatures that differ slightly from that of the
corresponding GNU C library wrapper functions shown in the SYNOPSIS.
The final argument,
offset,
is unpacked by the wrapper functions into two arguments in the system calls:
Historical C library/kernel differences
To deal with the fact that
IOV_MAX
was so low on early versions of Linux,
the glibc wrapper functions for
readv()
and
writev()
did some extra work if they detected that the underlying kernel
system call failed because this limit was exceeded.
In the case of
readv(),
the wrapper function allocated a temporary buffer large enough
for all of the items specified by
iov,
passed that buffer in a call to
read(2),
copied data from the buffer to the locations specified by the
iov_base
fields of the elements of
iov,
and then freed the buffer.
The wrapper function for
writev()
performed the analogous task using a temporary buffer and a call to
write(2).
EXAMPLES
The following code sample demonstrates the use of
writev():
COLOPHON
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man-pages
project.
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https://www.kernel.org/doc/man-pages/.