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PROLOG
This manual page is part of the POSIX Programmer's Manual. The Linux implementation of
this interface may differ (consult the corresponding Linux manual page for details of
Linux behavior), or the interface may not be implemented on Linux.
NAME
pread, read — read from a file
SYNOPSIS
#include <unistd.h>
ssize_t pread(int fildes, void *buf, size_t nbyte, off_t offset);
ssize_t read(int fildes, void *buf, size_t nbyte);
DESCRIPTION
The read() function shall attempt to read nbyte bytes from the file associated with the
open file descriptor, fildes, into the buffer pointed to by buf. The behavior of multiple
concurrent reads on the same pipe, FIFO, or terminal device is unspecified.
Before any action described below is taken, and if nbyte is zero, the read() function may
detect and return errors as described below. In the absence of errors, or if error
detection is not performed, the read() function shall return zero and have no other
results.
On files that support seeking (for example, a regular file), the read() shall start at a
position in the file given by the file offset associated with fildes. The file offset
shall be incremented by the number of bytes actually read.
Files that do not support seeking—for example, terminals—always read from the current
position. The value of a file offset associated with such a file is undefined.
No data transfer shall occur past the current end-of-file. If the starting position is at
or after the end-of-file, 0 shall be returned. If the file refers to a device special
file, the result of subsequent read() requests is implementation-defined.
If the value of nbyte is greater than {SSIZE_MAX}, the result is implementation-defined.
When attempting to read from an empty pipe or FIFO:
* If no process has the pipe open for writing, read() shall return 0 to indicate end-of-
file.
* If some process has the pipe open for writing and O_NONBLOCK is set, read() shall
return −1 and set errno to [EAGAIN].
* If some process has the pipe open for writing and O_NONBLOCK is clear, read() shall
block the calling thread until some data is written or the pipe is closed by all
processes that had the pipe open for writing.
When attempting to read a file (other than a pipe or FIFO) that supports non-blocking
reads and has no data currently available:
* If O_NONBLOCK is set, read() shall return −1 and set errno to [EAGAIN].
* If O_NONBLOCK is clear, read() shall block the calling thread until some data becomes
available.
* The use of the O_NONBLOCK flag has no effect if there is some data available.
The read() function reads data previously written to a file. If any portion of a regular
file prior to the end-of-file has not been written, read() shall return bytes with value
0. For example, lseek() allows the file offset to be set beyond the end of existing data
in the file. If data is later written at this point, subsequent reads in the gap between
the previous end of data and the newly written data shall return bytes with value 0 until
data is written into the gap.
Upon successful completion, where nbyte is greater than 0, read() shall mark for update
the last data access timestamp of the file, and shall return the number of bytes read.
This number shall never be greater than nbyte. The value returned may be less than nbyte
if the number of bytes left in the file is less than nbyte, if the read() request was
interrupted by a signal, or if the file is a pipe or FIFO or special file and has fewer
than nbyte bytes immediately available for reading. For example, a read() from a file
associated with a terminal may return one typed line of data.
If a read() is interrupted by a signal before it reads any data, it shall return −1 with
errno set to [EINTR].
If a read() is interrupted by a signal after it has successfully read some data, it shall
return the number of bytes read.
For regular files, no data transfer shall occur past the offset maximum established in the
open file description associated with fildes.
If fildes refers to a socket, read() shall be equivalent to recv() with no flags set.
If the O_DSYNC and O_RSYNC bits have been set, read I/O operations on the file descriptor
shall complete as defined by synchronized I/O data integrity completion. If the O_SYNC and
O_RSYNC bits have been set, read I/O operations on the file descriptor shall complete as
defined by synchronized I/O file integrity completion.
If fildes refers to a shared memory object, the result of the read() function is
unspecified.
If fildes refers to a typed memory object, the result of the read() function is
unspecified.
A read() from a STREAMS file can read data in three different modes: byte-stream mode,
message-nondiscard mode, and message-discard mode. The default shall be byte-stream mode.
This can be changed using the I_SRDOPT ioctl() request, and can be tested with I_GRDOPT
ioctl(). In byte-stream mode, read() shall retrieve data from the STREAM until as many
bytes as were requested are transferred, or until there is no more data to be retrieved.
Byte-stream mode ignores message boundaries.
In STREAMS message-nondiscard mode, read() shall retrieve data until as many bytes as were
requested are transferred, or until a message boundary is reached. If read() does not
retrieve all the data in a message, the remaining data shall be left on the STREAM, and
can be retrieved by the next read() call. Message-discard mode also retrieves data until
as many bytes as were requested are transferred, or a message boundary is reached.
However, unread data remaining in a message after the read() returns shall be discarded,
and shall not be available for a subsequent read(), getmsg(), or getpmsg() call.
How read() handles zero-byte STREAMS messages is determined by the current read mode
setting. In byte-stream mode, read() shall accept data until it has read nbyte bytes, or
until there is no more data to read, or until a zero-byte message block is encountered.
The read() function shall then return the number of bytes read, and place the zero-byte
message back on the STREAM to be retrieved by the next read(), getmsg(), or getpmsg(). In
message-nondiscard mode or message-discard mode, a zero-byte message shall return 0 and
the message shall be removed from the STREAM. When a zero-byte message is read as the
first message on a STREAM, the message shall be removed from the STREAM and 0 shall be
returned, regardless of the read mode.
A read() from a STREAMS file shall return the data in the message at the front of the
STREAM head read queue, regardless of the priority band of the message.
By default, STREAMs are in control-normal mode, in which a read() from a STREAMS file can
only process messages that contain a data part but do not contain a control part. The
read() shall fail if a message containing a control part is encountered at the STREAM
head. This default action can be changed by placing the STREAM in either control-data mode
or control-discard mode with the I_SRDOPT ioctl() command. In control-data mode, read()
shall convert any control part to data and pass it to the application before passing any
data part originally present in the same message. In control-discard mode, read() shall
discard message control parts but return to the process any data part in the message.
In addition, read() shall fail if the STREAM head had processed an asynchronous error
before the call. In this case, the value of errno shall not reflect the result of read(),
but reflect the prior error. If a hangup occurs on the STREAM being read, read() shall
continue to operate normally until the STREAM head read queue is empty. Thereafter, it
shall return 0.
The pread() function shall be equivalent to read(), except that it shall read from a given
position in the file without changing the file pointer. The first three arguments to
pread() are the same as read() with the addition of a fourth argument offset for the
desired position inside the file. An attempt to perform a pread() on a file that is
incapable of seeking shall result in an error.
RETURN VALUE
Upon successful completion, these functions shall return a non-negative integer indicating
the number of bytes actually read. Otherwise, the functions shall return −1 and set errno
to indicate the error.
ERRORS
These functions shall fail if:
EAGAIN The file is neither a pipe, nor a FIFO, nor a socket, the O_NONBLOCK flag is set
for the file descriptor, and the thread would be delayed in the read operation.
EBADF The fildes argument is not a valid file descriptor open for reading.
EBADMSG
The file is a STREAM file that is set to control-normal mode and the message
waiting to be read includes a control part.
EINTR The read operation was terminated due to the receipt of a signal, and no data was
transferred.
EINVAL The STREAM or multiplexer referenced by fildes is linked (directly or indirectly)
downstream from a multiplexer.
EIO The process is a member of a background process group attempting to read from its
controlling terminal, and either the calling thread is blocking SIGTTIN or the
process is ignoring SIGTTIN or the process group of the process is orphaned. This
error may also be generated for implementation-defined reasons.
EISDIR The fildes argument refers to a directory and the implementation does not allow the
directory to be read using read() or pread(). The readdir() function should be
used instead.
EOVERFLOW
The file is a regular file, nbyte is greater than 0, the starting position is
before the end-of-file, and the starting position is greater than or equal to the
offset maximum established in the open file description associated with fildes.
The pread() function shall fail if:
EINVAL The file is a regular file or block special file, and the offset argument is
negative. The file pointer shall remain unchanged.
ESPIPE The file is a pipe, FIFO, or socket.
The read() function shall fail if:
EAGAIN The file is a pipe or FIFO, the O_NONBLOCK flag is set for the file descriptor, and
the thread would be delayed in the read operation.
EAGAIN or EWOULDBLOCK
The file is a socket, the O_NONBLOCK flag is set for the file descriptor, and the
thread would be delayed in the read operation.
ECONNRESET
A read was attempted on a socket and the connection was forcibly closed by its
peer.
ENOTCONN
A read was attempted on a socket that is not connected.
ETIMEDOUT
A read was attempted on a socket and a transmission timeout occurred.
These functions may fail if:
EIO A physical I/O error has occurred.
ENOBUFS
Insufficient resources were available in the system to perform the operation.
ENOMEM Insufficient memory was available to fulfill the request.
ENXIO A request was made of a nonexistent device, or the request was outside the
capabilities of the device.
The following sections are informative.
EXAMPLES
Reading Data into a Buffer
The following example reads data from the file associated with the file descriptor fd into
the buffer pointed to by buf.
#include <sys/types.h>
#include <unistd.h>
...
char buf[20];
size_t nbytes;
ssize_t bytes_read;
int fd;
...
nbytes = sizeof(buf);
bytes_read = read(fd, buf, nbytes);
...
APPLICATION USAGE
None.
RATIONALE
This volume of POSIX.1‐2008 does not specify the value of the file offset after an error
is returned; there are too many cases. For programming errors, such as [EBADF], the
concept is meaningless since no file is involved. For errors that are detected
immediately, such as [EAGAIN], clearly the pointer should not change. After an interrupt
or hardware error, however, an updated value would be very useful and is the behavior of
many implementations.
Note that a read() of zero bytes does not modify the last data access timestamp. A read()
that requests more than zero bytes, but returns zero, is required to modify the last data
access timestamp.
Implementations are allowed, but not required, to perform error checking for read()
requests of zero bytes.
Input and Output
The use of I/O with large byte counts has always presented problems. Ideas such as
lread() and lwrite() (using and returning longs) were considered at one time. The current
solution is to use abstract types on the ISO C standard function to read() and write().
The abstract types can be declared so that existing functions work, but can also be
declared so that larger types can be represented in future implementations. It is presumed
that whatever constraints limit the maximum range of size_t also limit portable I/O
requests to the same range. This volume of POSIX.1‐2008 also limits the range further by
requiring that the byte count be limited so that a signed return value remains meaningful.
Since the return type is also a (signed) abstract type, the byte count can be defined by
the implementation to be larger than an int can hold.
The standard developers considered adding atomicity requirements to a pipe or FIFO, but
recognized that due to the nature of pipes and FIFOs there could be no guarantee of
atomicity of reads of {PIPE_BUF} or any other size that would be an aid to applications
portability.
This volume of POSIX.1‐2008 requires that no action be taken for read() or write() when
nbyte is zero. This is not intended to take precedence over detection of errors (such as
invalid buffer pointers or file descriptors). This is consistent with the rest of this
volume of POSIX.1‐2008, but the phrasing here could be misread to require detection of the
zero case before any other errors. A value of zero is to be considered a correct value,
for which the semantics are a no-op.
I/O is intended to be atomic to ordinary files and pipes and FIFOs. Atomic means that all
the bytes from a single operation that started out together end up together, without
interleaving from other I/O operations. It is a known attribute of terminals that this is
not honored, and terminals are explicitly (and implicitly permanently) excepted, making
the behavior unspecified. The behavior for other device types is also left unspecified,
but the wording is intended to imply that future standards might choose to specify
atomicity (or not).
There were recommendations to add format parameters to read() and write() in order to
handle networked transfers among heterogeneous file system and base hardware types. Such a
facility may be required for support by the OSI presentation of layer services. However,
it was determined that this should correspond with similar C-language facilities, and that
is beyond the scope of this volume of POSIX.1‐2008. The concept was suggested to the
developers of the ISO C standard for their consideration as a possible area for future
work.
In 4.3 BSD, a read() or write() that is interrupted by a signal before transferring any
data does not by default return an [EINTR] error, but is restarted. In 4.2 BSD, 4.3 BSD,
and the Eighth Edition, there is an additional function, select(), whose purpose is to
pause until specified activity (data to read, space to write, and so on) is detected on
specified file descriptors. It is common in applications written for those systems for
select() to be used before read() in situations (such as keyboard input) where
interruption of I/O due to a signal is desired.
The issue of which files or file types are interruptible is considered an implementation
design issue. This is often affected primarily by hardware and reliability issues.
There are no references to actions taken following an ``unrecoverable error''. It is
considered beyond the scope of this volume of POSIX.1‐2008 to describe what happens in the
case of hardware errors.
Earlier versions of this standard allowed two very different behaviors with regard to the
handling of interrupts. In order to minimize the resulting confusion, it was decided that
POSIX.1‐2008 should support only one of these behaviors. Historical practice on AT&T-
derived systems was to have read() and write() return −1 and set errno to [EINTR] when
interrupted after some, but not all, of the data requested had been transferred. However,
the US Department of Commerce FIPS 151‐1 and FIPS 151‐2 require the historical BSD
behavior, in which read() and write() return the number of bytes actually transferred
before the interrupt. If −1 is returned when any data is transferred, it is difficult to
recover from the error on a seekable device and impossible on a non-seekable device. Most
new implementations support this behavior. The behavior required by POSIX.1‐2008 is to
return the number of bytes transferred.
POSIX.1‐2008 does not specify when an implementation that buffers read()s actually moves
the data into the user-supplied buffer, so an implementation may choose to do this at the
latest possible moment. Therefore, an interrupt arriving earlier may not cause read() to
return a partial byte count, but rather to return −1 and set errno to [EINTR].
Consideration was also given to combining the two previous options, and setting errno to
[EINTR] while returning a short count. However, not only is there no existing practice
that implements this, it is also contradictory to the idea that when errno is set, the
function responsible shall return −1.
This volume of POSIX.1‐2008 intentionally does not specify any pread() errors related to
pipes, FIFOs, and sockets other than [ESPIPE].
FUTURE DIRECTIONS
None.
SEE ALSO
fcntl(), ioctl(), lseek(), open(), pipe(), readv()
The Base Definitions volume of POSIX.1‐2008, Chapter 11, General Terminal Interface,
<stropts.h>, <sys_uio.h>, <unistd.h>
COPYRIGHT
Portions of this text are reprinted and reproduced in electronic form from IEEE Std
1003.1, 2013 Edition, Standard for Information Technology -- Portable Operating System
Interface (POSIX), The Open Group Base Specifications Issue 7, Copyright (C) 2013 by the
Institute of Electrical and Electronics Engineers, Inc and The Open Group. (This is
POSIX.1-2008 with the 2013 Technical Corrigendum 1 applied.) In the event of any
discrepancy between this version and the original IEEE and The Open Group Standard, the
original IEEE and The Open Group Standard is the referee document. The original Standard
can be obtained online at http://www.unix.org/online.html .
Any typographical or formatting errors that appear in this page are most likely to have
been introduced during the conversion of the source files to man page format. To report
such errors, see https://www.kernel.org/doc/man-pages/reporting_bugs.html .