SELECT_TUT
Section: Linux Programmer's Manual (2)
Updated: 2013-12-30
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NAME
select, pselect, FD_CLR, FD_ISSET, FD_SET, FD_ZERO -
synchronous I/O multiplexing
SYNOPSIS
/* According to POSIX.1-2001 */
#include <sys/select.h>
/* According to earlier standards */
#include <sys/time.h>
#include <sys/types.h>
#include <unistd.h>
int select(int nfds, fd_set *readfds, fd_set *writefds,
fd_set *exceptfds, struct timeval *utimeout);
void FD_CLR(int fd, fd_set *set);
int FD_ISSET(int fd, fd_set *set);
void FD_SET(int fd, fd_set *set);
void FD_ZERO(fd_set *set);
#include <sys/select.h>
int pselect(int nfds, fd_set *readfds, fd_set *writefds,
fd_set *exceptfds, const struct timespec *ntimeout,
const sigset_t *sigmask);
Feature Test Macro Requirements for glibc (see
feature_test_macros(7)):
pselect():
_POSIX_C_SOURCE >= 200112L || _XOPEN_SOURCE >= 600
DESCRIPTION
select()
(or
pselect())
is used to efficiently monitor multiple file descriptors,
to see if any of them is, or becomes, "ready";
that is, to see whether I/O becomes possible,
or an "exceptional condition" has occurred on any of the descriptors.
Its principal arguments are three "sets" of file descriptors:
readfds, writefds, and exceptfds.
Each set is declared as type
fd_set,
and its contents can be manipulated with the macros
FD_CLR(),
FD_ISSET(),
FD_SET(),
and
FD_ZERO().
A newly declared set should first be cleared using
FD_ZERO().
select()
modifies the contents of the sets according to the rules
described below; after calling
select()
you can test if a file descriptor is still present in a set with the
FD_ISSET()
macro.
FD_ISSET()
returns nonzero if a specified file descriptor is present in a set
and zero if it is not.
FD_CLR()
removes a file descriptor from a set.
Arguments
- readfds
-
This set is watched to see if data is available for reading from any of
its file descriptors.
After
select()
has returned, readfds will be
cleared of all file descriptors except for those that
are immediately available for reading.
- writefds
-
This set is watched to see if there is space to write data to any of
its file descriptors.
After
select()
has returned, writefds will be
cleared of all file descriptors except for those that
are immediately available for writing.
- exceptfds
-
This set is watched for "exceptional conditions".
In practice, only one such exceptional condition is common:
the availability of out-of-band (OOB) data for reading
from a TCP socket.
See
recv(2),
send(2),
and
tcp(7)
for more details about OOB data.
(One other less common case where
select(2)
indicates an exceptional condition occurs with pseudoterminals
in packet mode; see
tty_ioctl(4).)
After
select()
has returned,
exceptfds will be cleared of all file descriptors except for those
for which an exceptional condition has occurred.
- nfds
-
This is an integer one more than the maximum of any file descriptor in
any of the sets.
In other words, while adding file descriptors to each of the sets,
you must calculate the maximum integer value of all of them,
then increment this value by one, and then pass this as nfds.
- utimeout
-
This is the longest time
select()
may wait before returning, even if nothing interesting happened.
If this value is passed as NULL, then
select()
blocks indefinitely waiting for a file descriptor to become ready.
utimeout can be set to zero seconds, which causes
select()
to return immediately, with information about the readiness
of file descriptors at the time of the call.
The structure struct timeval is defined as:
-
struct timeval {
time_t tv_sec; /* seconds */
long tv_usec; /* microseconds */
};
- ntimeout
-
This argument for
pselect()
has the same meaning as
utimeout,
but
struct timespec
has nanosecond precision as follows:
-
struct timespec {
long tv_sec; /* seconds */
long tv_nsec; /* nanoseconds */
};
- sigmask
-
This argument holds a set of signals that the kernel should unblock
(i.e., remove from the signal mask of the calling thread),
while the caller is blocked inside the
pselect()
call (see
sigaddset(3)
and
sigprocmask(2)).
It may be NULL,
in which case the call does not modify the signal mask on
entry and exit to the function.
In this case,
pselect()
will then behave just like
select().
Combining signal and data events
pselect()
is useful if you are waiting for a signal as well as
for file descriptor(s) to become ready for I/O.
Programs that receive signals
normally use the signal handler only to raise a global flag.
The global flag will indicate that the event must be processed
in the main loop of the program.
A signal will cause the
select()
(or
pselect())
call to return with errno set to EINTR.
This behavior is essential so that signals can be processed
in the main loop of the program, otherwise
select()
would block indefinitely.
Now, somewhere
in the main loop will be a conditional to check the global flag.
So we must ask:
what if a signal arrives after the conditional, but before the
select()
call?
The answer is that
select()
would block indefinitely, even though an event is actually pending.
This race condition is solved by the
pselect()
call.
This call can be used to set the signal mask to a set of signals
that are only to be received within the
pselect()
call.
For instance, let us say that the event in question
was the exit of a child process.
Before the start of the main loop, we
would block SIGCHLD using
sigprocmask(2).
Our
pselect()
call would enable
SIGCHLD
by using an empty signal mask.
Our program would look like:
static volatile sig_atomic_t got_SIGCHLD = 0;
static void
child_sig_handler(int sig)
{
got_SIGCHLD = 1;
}
int
main(int argc, char *argv[])
{
sigset_t sigmask, empty_mask;
struct sigaction sa;
fd_set readfds, writefds, exceptfds;
int r;
sigemptyset(&sigmask);
sigaddset(&sigmask, SIGCHLD);
if (sigprocmask(SIG_BLOCK, &sigmask, NULL) == -1) {
perror("sigprocmask");
exit(EXIT_FAILURE);
}
sa.sa_flags = 0;
sa.sa_handler = child_sig_handler;
sigemptyset(&sa.sa_mask);
if (sigaction(SIGCHLD, &sa, NULL) == -1) {
perror("sigaction");
exit(EXIT_FAILURE);
}
sigemptyset(&empty_mask);
for (;;) { /* main loop */
/* Initialize readfds, writefds, and exceptfds
before the pselect() call. (Code omitted.) */
r = pselect(nfds, &readfds, &writefds, &exceptfds,
NULL, &empty_mask);
if (r == -1 && errno != EINTR) {
/* Handle error */
}
if (got_SIGCHLD) {
got_SIGCHLD = 0;
/* Handle signalled event here; e.g., wait() for all
terminated children. (Code omitted.) */
}
/* main body of program */
}
}
Practical
So what is the point of
select()?
Can't I just read and write to my descriptors whenever I want?
The point of
select()
is that it watches
multiple descriptors at the same time and properly puts the process to
sleep if there is no activity.
UNIX programmers often find
themselves in a position where they have to handle I/O from more than one
file descriptor where the data flow may be intermittent.
If you were to merely create a sequence of
read(2)
and
write(2)
calls, you would
find that one of your calls may block waiting for data from/to a file
descriptor, while another file descriptor is unused though ready for I/O.
select()
efficiently copes with this situation.
Select law
Many people who try to use
select()
come across behavior that is
difficult to understand and produces nonportable or borderline results.
For instance, the above program is carefully written not to
block at any point, even though it does not set its file descriptors to
nonblocking mode.
It is easy to introduce
subtle errors that will remove the advantage of using
select(),
so here is a list of essentials to watch for when using
select().
- 1.
-
You should always try to use
select()
without a timeout.
Your program
should have nothing to do if there is no data available.
Code that
depends on timeouts is not usually portable and is difficult to debug.
- 2.
-
The value nfds must be properly calculated for efficiency as
explained above.
- 3.
-
No file descriptor must be added to any set if you do not intend
to check its result after the
select()
call, and respond appropriately.
See next rule.
- 4.
-
After
select()
returns, all file descriptors in all sets
should be checked to see if they are ready.
- 5.
-
The functions
read(2),
recv(2),
write(2),
and
send(2)
do not necessarily read/write the full amount of data
that you have requested.
If they do read/write the full amount, it's
because you have a low traffic load and a fast stream.
This is not always going to be the case.
You should cope with the case of your
functions managing to send or receive only a single byte.
- 6.
-
Never read/write only in single bytes at a time unless you are really
sure that you have a small amount of data to process.
It is extremely
inefficient not to read/write as much data as you can buffer each time.
The buffers in the example below are 1024 bytes although they could
easily be made larger.
- 7.
-
The functions
read(2),
recv(2),
write(2),
and
send(2)
as well as the
select()
call can return -1 with
errno
set to EINTR,
or with
errno
set to EAGAIN (EWOULDBLOCK).
These results must be properly managed (not done properly above).
If your program is not going to receive any signals, then
it is unlikely you will get EINTR.
If your program does not set nonblocking I/O,
you will not get EAGAIN.
- 8.
-
Never call
read(2),
recv(2),
write(2),
or
send(2)
with a buffer length of zero.
- 9.
-
If the functions
read(2),
recv(2),
write(2),
and
send(2)
fail with errors other than those listed in 7.,
or one of the input functions returns 0, indicating end of file,
then you should not pass that descriptor to
select()
again.
In the example below,
I close the descriptor immediately, and then set it to -1
to prevent it being included in a set.
- 10.
-
The timeout value must be initialized with each new call to
select(),
since some operating systems modify the structure.
pselect()
however does not modify its timeout structure.
- 11.
-
Since
select()
modifies its file descriptor sets,
if the call is being used in a loop,
then the sets must be reinitialized before each call.
Usleep emulation
On systems that do not have a
usleep(3)
function, you can call
select()
with a finite timeout and no file descriptors as
follows:
struct timeval tv;
tv.tv_sec = 0;
tv.tv_usec = 200000; /* 0.2 seconds */
select(0, NULL, NULL, NULL, &tv);
This is guaranteed to work only on UNIX systems, however.
RETURN VALUE
On success,
select()
returns the total number of file descriptors
still present in the file descriptor sets.
If
select()
timed out, then the return value will be zero.
The file descriptors set should be all
empty (but may not be on some systems).
A return value of -1 indicates an error, with errno being
set appropriately.
In the case of an error, the contents of the returned sets and
the struct timeout contents are undefined and should not be used.
pselect()
however never modifies ntimeout.
NOTES
Generally speaking,
all operating systems that support sockets also support
select().
select()
can be used to solve
many problems in a portable and efficient way that naive programmers try
to solve in a more complicated manner using
threads, forking, IPCs, signals, memory sharing, and so on.
The
poll(2)
system call has the same functionality as
select(),
and is somewhat more efficient when monitoring sparse
file descriptor sets.
It is nowadays widely available, but historically was less portable than
select().
The Linux-specific
epoll(7)
API provides an interface that is more efficient than
select(2)
and
poll(2)
when monitoring large numbers of file descriptors.
EXAMPLE
Here is an example that better demonstrates the true utility of
select().
The listing below is a TCP forwarding program that forwards
from one TCP port to another.
#include <stdlib.h>
#include <stdio.h>
#include <unistd.h>
#include <sys/time.h>
#include <sys/types.h>
#include <string.h>
#include <signal.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <errno.h>
static int forward_port;
#undef max
#define max(x,y) ((x) > (y) ? (x) : (y))
static int
listen_socket(int listen_port)
{
struct sockaddr_in a;
int s;
int yes;
s = socket(AF_INET, SOCK_STREAM, 0);
if (s == -1) {
perror("socket");
return -1;
}
yes = 1;
if (setsockopt(s, SOL_SOCKET, SO_REUSEADDR,
&yes, sizeof(yes)) == -1) {
perror("setsockopt");
close(s);
return -1;
}
memset(&a, 0, sizeof(a));
a.sin_port = htons(listen_port);
a.sin_family = AF_INET;
if (bind(s, (struct sockaddr *) &a, sizeof(a)) == -1) {
perror("bind");
close(s);
return -1;
}
printf("accepting connections on port %d\n", listen_port);
listen(s, 10);
return s;
}
static int
connect_socket(int connect_port, char *address)
{
struct sockaddr_in a;
int s;
s = socket(AF_INET, SOCK_STREAM, 0);
if (s == -1) {
perror("socket");
close(s);
return -1;
}
memset(&a, 0, sizeof(a));
a.sin_port = htons(connect_port);
a.sin_family = AF_INET;
if (!inet_aton(address, (struct in_addr *) &a.sin_addr.s_addr)) {
perror("bad IP address format");
close(s);
return -1;
}
if (connect(s, (struct sockaddr *) &a, sizeof(a)) == -1) {
perror("connect()");
shutdown(s, SHUT_RDWR);
close(s);
return -1;
}
return s;
}
#define SHUT_FD1 do { \
if (fd1 >= 0) { \
shutdown(fd1, SHUT_RDWR); \
close(fd1); \
fd1 = -1; \
} \
} while (0)
#define SHUT_FD2 do { \
if (fd2 >= 0) { \
shutdown(fd2, SHUT_RDWR); \
close(fd2); \
fd2 = -1; \
} \
} while (0)
#define BUF_SIZE 1024
int
main(int argc, char *argv[])
{
int h;
int fd1 = -1, fd2 = -1;
char buf1[BUF_SIZE], buf2[BUF_SIZE];
int buf1_avail, buf1_written;
int buf2_avail, buf2_written;
if (argc != 4) {
fprintf(stderr, "Usage\n\tfwd <listen-port> "
"<forward-to-port> <forward-to-ip-address>\n");
exit(EXIT_FAILURE);
}
signal(SIGPIPE, SIG_IGN);
forward_port = atoi(argv[2]);
h = listen_socket(atoi(argv[1]));
if (h == -1)
exit(EXIT_FAILURE);
for (;;) {
int r, nfds = 0;
fd_set rd, wr, er;
FD_ZERO(&rd);
FD_ZERO(&wr);
FD_ZERO(&er);
FD_SET(h, &rd);
nfds = max(nfds, h);
if (fd1 > 0 && buf1_avail < BUF_SIZE) {
FD_SET(fd1, &rd);
nfds = max(nfds, fd1);
}
if (fd2 > 0 && buf2_avail < BUF_SIZE) {
FD_SET(fd2, &rd);
nfds = max(nfds, fd2);
}
if (fd1 > 0 && buf2_avail - buf2_written > 0) {
FD_SET(fd1, &wr);
nfds = max(nfds, fd1);
}
if (fd2 > 0 && buf1_avail - buf1_written > 0) {
FD_SET(fd2, &wr);
nfds = max(nfds, fd2);
}
if (fd1 > 0) {
FD_SET(fd1, &er);
nfds = max(nfds, fd1);
}
if (fd2 > 0) {
FD_SET(fd2, &er);
nfds = max(nfds, fd2);
}
r = select(nfds + 1, &rd, &wr, &er, NULL);
if (r == -1 && errno == EINTR)
continue;
if (r == -1) {
perror("select()");
exit(EXIT_FAILURE);
}
if (FD_ISSET(h, &rd)) {
unsigned int l;
struct sockaddr_in client_address;
memset(&client_address, 0, l = sizeof(client_address));
r = accept(h, (struct sockaddr *) &client_address, &l);
if (r == -1) {
perror("accept()");
} else {
SHUT_FD1;
SHUT_FD2;
buf1_avail = buf1_written = 0;
buf2_avail = buf2_written = 0;
fd1 = r;
fd2 = connect_socket(forward_port, argv[3]);
if (fd2 == -1)
SHUT_FD1;
else
printf("connect from %s\n",
inet_ntoa(client_address.sin_addr));
}
}
/* NB: read oob data before normal reads */
if (fd1 > 0)
if (FD_ISSET(fd1, &er)) {
char c;
r = recv(fd1, &c, 1, MSG_OOB);
if (r < 1)
SHUT_FD1;
else
send(fd2, &c, 1, MSG_OOB);
}
if (fd2 > 0)
if (FD_ISSET(fd2, &er)) {
char c;
r = recv(fd2, &c, 1, MSG_OOB);
if (r < 1)
SHUT_FD2;
else
send(fd1, &c, 1, MSG_OOB);
}
if (fd1 > 0)
if (FD_ISSET(fd1, &rd)) {
r = read(fd1, buf1 + buf1_avail,
BUF_SIZE - buf1_avail);
if (r < 1)
SHUT_FD1;
else
buf1_avail += r;
}
if (fd2 > 0)
if (FD_ISSET(fd2, &rd)) {
r = read(fd2, buf2 + buf2_avail,
BUF_SIZE - buf2_avail);
if (r < 1)
SHUT_FD2;
else
buf2_avail += r;
}
if (fd1 > 0)
if (FD_ISSET(fd1, &wr)) {
r = write(fd1, buf2 + buf2_written,
buf2_avail - buf2_written);
if (r < 1)
SHUT_FD1;
else
buf2_written += r;
}
if (fd2 > 0)
if (FD_ISSET(fd2, &wr)) {
r = write(fd2, buf1 + buf1_written,
buf1_avail - buf1_written);
if (r < 1)
SHUT_FD2;
else
buf1_written += r;
}
/* check if write data has caught read data */
if (buf1_written == buf1_avail)
buf1_written = buf1_avail = 0;
if (buf2_written == buf2_avail)
buf2_written = buf2_avail = 0;
/* one side has closed the connection, keep
writing to the other side until empty */
if (fd1 < 0 && buf1_avail - buf1_written == 0)
SHUT_FD2;
if (fd2 < 0 && buf2_avail - buf2_written == 0)
SHUT_FD1;
}
exit(EXIT_SUCCESS);
}
The above program properly forwards most kinds of TCP connections
including OOB signal data transmitted by telnet servers.
It handles the tricky problem of having data flow in both directions
simultaneously.
You might think it more efficient to use a
fork(2)
call and devote a thread to each stream.
This becomes more tricky than you might suspect.
Another idea is to set nonblocking I/O using
fcntl(2).
This also has its problems because you end up using
inefficient timeouts.
The program does not handle more than one simultaneous connection at a
time, although it could easily be extended to do this with a linked list
of buffers---one for each connection.
At the moment, new
connections cause the current connection to be dropped.
SEE ALSO
accept(2),
connect(2),
ioctl(2),
poll(2),
read(2),
recv(2),
select(2),
send(2),
sigprocmask(2),
write(2),
sigaddset(3),
sigdelset(3),
sigemptyset(3),
sigfillset(3),
sigismember(3),
epoll(7)
Index
- NAME
-
- SYNOPSIS
-
- DESCRIPTION
-
- Arguments
-
- Combining signal and data events
-
- Practical
-
- Select law
-
- Usleep emulation
-
- RETURN VALUE
-
- NOTES
-
- EXAMPLE
-
- SEE ALSO
-
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Time: 02:54:47 GMT, September 18, 2014