blob: a0248289e8b3a407b6d9d04b18a0ac1f05f8933b [file] [log] [blame]
/*
* File descriptors management functions.
*
* Copyright 2000-2014 Willy Tarreau <w@1wt.eu>
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*
* There is no direct link between the FD and the updates list. There is only a
* bit in the fdtab[] to indicate than a file descriptor is already present in
* the updates list. Once an fd is present in the updates list, it will have to
* be considered even if its changes are reverted in the middle or if the fd is
* replaced.
*
* The event state for an FD, as found in fdtab[].state, is maintained for each
* direction. The state field is built this way, with R bits in the low nibble
* and W bits in the high nibble for ease of access and debugging :
*
* 7 6 5 4 3 2 1 0
* [ 0 | 0 | RW | AW | 0 | 0 | RR | AR ]
*
* A* = active *R = read
* R* = ready *W = write
*
* An FD is marked "active" when there is a desire to use it.
* An FD is marked "ready" when it has not faced a new EAGAIN since last wake-up
* (it is a cache of the last EAGAIN regardless of polling changes). Each poller
* has its own "polled" state for the same fd, as stored in the polled_mask.
*
* We have 4 possible states for each direction based on these 2 flags :
*
* +---+---+----------+---------------------------------------------+
* | R | A | State | Description |
* +---+---+----------+---------------------------------------------+
* | 0 | 0 | DISABLED | No activity desired, not ready. |
* | 0 | 1 | ACTIVE | Activity desired. |
* | 1 | 0 | STOPPED | End of activity. |
* | 1 | 1 | READY | Activity desired and reported. |
* +---+---+----------+---------------------------------------------+
*
* The transitions are pretty simple :
* - fd_want_*() : set flag A
* - fd_stop_*() : clear flag A
* - fd_cant_*() : clear flag R (when facing EAGAIN)
* - fd_may_*() : set flag R (upon return from poll())
*
* Each poller then computes its own polled state :
* if (A) { if (!R) P := 1 } else { P := 0 }
*
* The state transitions look like the diagram below.
*
* may +----------+
* ,----| DISABLED | (READY=0, ACTIVE=0)
* | +----------+
* | want | ^
* | | |
* | v | stop
* | +----------+
* | | ACTIVE | (READY=0, ACTIVE=1)
* | +----------+
* | | ^
* | may | |
* | v | EAGAIN (can't)
* | +--------+
* | | READY | (READY=1, ACTIVE=1)
* | +--------+
* | stop | ^
* | | |
* | v | want
* | +---------+
* `--->| STOPPED | (READY=1, ACTIVE=0)
* +---------+
*/
#include <stdio.h>
#include <string.h>
#include <unistd.h>
#include <fcntl.h>
#include <sys/types.h>
#include <sys/resource.h>
#include <sys/uio.h>
#if defined(USE_POLL)
#include <poll.h>
#include <errno.h>
#endif
#include <haproxy/api.h>
#include <haproxy/activity.h>
#include <haproxy/cfgparse.h>
#include <haproxy/fd.h>
#include <haproxy/global.h>
#include <haproxy/log.h>
#include <haproxy/port_range.h>
#include <haproxy/ticks.h>
#include <haproxy/tools.h>
struct fdtab *fdtab __read_mostly = NULL; /* array of all the file descriptors */
struct polled_mask *polled_mask __read_mostly = NULL; /* Array for the polled_mask of each fd */
struct fdinfo *fdinfo __read_mostly = NULL; /* less-often used infos for file descriptors */
int totalconn; /* total # of terminated sessions */
int actconn; /* # of active sessions */
struct poller pollers[MAX_POLLERS] __read_mostly;
struct poller cur_poller __read_mostly;
int nbpollers = 0;
volatile struct fdlist update_list; // Global update list
THREAD_LOCAL int *fd_updt = NULL; // FD updates list
THREAD_LOCAL int fd_nbupdt = 0; // number of updates in the list
THREAD_LOCAL int poller_rd_pipe = -1; // Pipe to wake the thread
int poller_wr_pipe[MAX_THREADS] __read_mostly; // Pipe to wake the threads
volatile int ha_used_fds = 0; // Number of FD we're currently using
static struct fdtab *fdtab_addr; /* address of the allocated area containing fdtab */
#define _GET_NEXT(fd, off) ((volatile struct fdlist_entry *)(void *)((char *)(&fdtab[fd]) + off))->next
#define _GET_PREV(fd, off) ((volatile struct fdlist_entry *)(void *)((char *)(&fdtab[fd]) + off))->prev
/* adds fd <fd> to fd list <list> if it was not yet in it */
void fd_add_to_fd_list(volatile struct fdlist *list, int fd, int off)
{
int next;
int new;
int old;
int last;
redo_next:
next = _GET_NEXT(fd, off);
/* Check that we're not already in the cache, and if not, lock us. */
if (next > -2)
goto done;
if (next == -2)
goto redo_next;
if (!_HA_ATOMIC_CAS(&_GET_NEXT(fd, off), &next, -2))
goto redo_next;
__ha_barrier_atomic_store();
new = fd;
redo_last:
/* First, insert in the linked list */
last = list->last;
old = -1;
_GET_PREV(fd, off) = -2;
/* Make sure the "prev" store is visible before we update the last entry */
__ha_barrier_store();
if (unlikely(last == -1)) {
/* list is empty, try to add ourselves alone so that list->last=fd */
if (unlikely(!_HA_ATOMIC_CAS(&list->last, &old, new)))
goto redo_last;
/* list->first was necessary -1, we're guaranteed to be alone here */
list->first = fd;
} else {
/* adding ourselves past the last element
* The CAS will only succeed if its next is -1,
* which means it's in the cache, and the last element.
*/
if (unlikely(!_HA_ATOMIC_CAS(&_GET_NEXT(last, off), &old, new)))
goto redo_last;
/* Then, update the last entry */
list->last = fd;
}
__ha_barrier_store();
/* since we're alone at the end of the list and still locked(-2),
* we know no one tried to add past us. Mark the end of list.
*/
_GET_PREV(fd, off) = last;
_GET_NEXT(fd, off) = -1;
__ha_barrier_store();
done:
return;
}
/* removes fd <fd> from fd list <list> */
void fd_rm_from_fd_list(volatile struct fdlist *list, int fd, int off)
{
#if defined(HA_HAVE_CAS_DW) || defined(HA_CAS_IS_8B)
volatile union {
struct fdlist_entry ent;
uint64_t u64;
uint32_t u32[2];
} cur_list, next_list;
#endif
int old;
int new = -2;
int prev;
int next;
int last;
lock_self:
#if (defined(HA_CAS_IS_8B) || defined(HA_HAVE_CAS_DW))
next_list.ent.next = next_list.ent.prev = -2;
cur_list.ent = *(volatile struct fdlist_entry *)(((char *)&fdtab[fd]) + off);
/* First, attempt to lock our own entries */
do {
/* The FD is not in the FD cache, give up */
if (unlikely(cur_list.ent.next <= -3))
return;
if (unlikely(cur_list.ent.prev == -2 || cur_list.ent.next == -2))
goto lock_self;
} while (
#ifdef HA_CAS_IS_8B
unlikely(!_HA_ATOMIC_CAS(((uint64_t *)&_GET_NEXT(fd, off)), (uint64_t *)&cur_list.u64, next_list.u64))
#else
unlikely(!_HA_ATOMIC_DWCAS(((long *)&_GET_NEXT(fd, off)), (uint32_t *)&cur_list.u32, &next_list.u32))
#endif
);
next = cur_list.ent.next;
prev = cur_list.ent.prev;
#else
lock_self_next:
next = _GET_NEXT(fd, off);
if (next == -2)
goto lock_self_next;
if (next <= -3)
goto done;
if (unlikely(!_HA_ATOMIC_CAS(&_GET_NEXT(fd, off), &next, -2)))
goto lock_self_next;
lock_self_prev:
prev = _GET_PREV(fd, off);
if (prev == -2)
goto lock_self_prev;
if (unlikely(!_HA_ATOMIC_CAS(&_GET_PREV(fd, off), &prev, -2)))
goto lock_self_prev;
#endif
__ha_barrier_atomic_store();
/* Now, lock the entries of our neighbours */
if (likely(prev != -1)) {
redo_prev:
old = fd;
if (unlikely(!_HA_ATOMIC_CAS(&_GET_NEXT(prev, off), &old, new))) {
if (unlikely(old == -2)) {
/* Neighbour already locked, give up and
* retry again once he's done
*/
_GET_PREV(fd, off) = prev;
__ha_barrier_store();
_GET_NEXT(fd, off) = next;
__ha_barrier_store();
goto lock_self;
}
goto redo_prev;
}
}
if (likely(next != -1)) {
redo_next:
old = fd;
if (unlikely(!_HA_ATOMIC_CAS(&_GET_PREV(next, off), &old, new))) {
if (unlikely(old == -2)) {
/* Neighbour already locked, give up and
* retry again once he's done
*/
if (prev != -1) {
_GET_NEXT(prev, off) = fd;
__ha_barrier_store();
}
_GET_PREV(fd, off) = prev;
__ha_barrier_store();
_GET_NEXT(fd, off) = next;
__ha_barrier_store();
goto lock_self;
}
goto redo_next;
}
}
if (list->first == fd)
list->first = next;
__ha_barrier_store();
last = list->last;
while (unlikely(last == fd && (!_HA_ATOMIC_CAS(&list->last, &last, prev))))
__ha_compiler_barrier();
/* Make sure we let other threads know we're no longer in cache,
* before releasing our neighbours.
*/
__ha_barrier_store();
if (likely(prev != -1))
_GET_NEXT(prev, off) = next;
__ha_barrier_store();
if (likely(next != -1))
_GET_PREV(next, off) = prev;
__ha_barrier_store();
/* Ok, now we're out of the fd cache */
_GET_NEXT(fd, off) = -(next + 4);
__ha_barrier_store();
done:
return;
}
#undef _GET_NEXT
#undef _GET_PREV
/* deletes the FD once nobody uses it anymore, as detected by the caller by its
* thread_mask being zero and its running mask turning to zero. There is no
* protection against concurrent accesses, it's up to the caller to make sure
* only the last thread will call it. This is only for internal use, please use
* fd_delete() instead.
*/
void _fd_delete_orphan(int fd)
{
uint fd_disown;
fd_disown = fdtab[fd].state & FD_DISOWN;
if (fdtab[fd].state & FD_LINGER_RISK) {
/* this is generally set when connecting to servers */
DISGUISE(setsockopt(fd, SOL_SOCKET, SO_LINGER,
(struct linger *) &nolinger, sizeof(struct linger)));
}
if (cur_poller.clo)
cur_poller.clo(fd);
port_range_release_port(fdinfo[fd].port_range, fdinfo[fd].local_port);
polled_mask[fd].poll_recv = polled_mask[fd].poll_send = 0;
fdtab[fd].state = 0;
#ifdef DEBUG_FD
fdtab[fd].event_count = 0;
#endif
fdinfo[fd].port_range = NULL;
fdtab[fd].owner = NULL;
/* perform the close() call last as it's what unlocks the instant reuse
* of this FD by any other thread.
*/
if (!fd_disown)
close(fd);
_HA_ATOMIC_DEC(&ha_used_fds);
}
/* Deletes an FD from the fdsets. The file descriptor is also closed, possibly
* asynchronously. Only the owning thread may do this.
*/
void fd_delete(int fd)
{
/* This must never happen and would definitely indicate a bug, in
* addition to overwriting some unexpected memory areas.
*/
BUG_ON(fd < 0 || fd >= global.maxsock);
/* we must postpone removal of an FD that may currently be in use
* by another thread. This can happen in the following two situations:
* - after a takeover, the owning thread closes the connection but
* the previous one just woke up from the poller and entered
* the FD handler iocb. That thread holds an entry in running_mask
* and requires removal protection.
* - multiple threads are accepting connections on a listener, and
* one of them (or even an separate one) decides to unbind the
* listener under the listener's lock while other ones still hold
* the running bit.
* In both situations the FD is marked as unused (thread_mask = 0) and
* will not take new bits in its running_mask so we have the guarantee
* that the last thread eliminating running_mask is the one allowed to
* safely delete the FD. Most of the time it will be the current thread.
*/
HA_ATOMIC_OR(&fdtab[fd].running_mask, tid_bit);
HA_ATOMIC_STORE(&fdtab[fd].thread_mask, 0);
if (fd_clr_running(fd) == 0)
_fd_delete_orphan(fd);
}
/* makes the new fd non-blocking and clears all other O_* flags; this is meant
* to be used on new FDs. Returns -1 on failure. The result is disguised at the
* end because some callers need to be able to ignore it regardless of the libc
* attributes.
*/
int fd_set_nonblock(int fd)
{
int ret = fcntl(fd, F_SETFL, O_NONBLOCK);
return DISGUISE(ret);
}
/* sets the close-on-exec flag on fd; returns -1 on failure. The result is
* disguised at the end because some callers need to be able to ignore it
* regardless of the libc attributes.
*/
int fd_set_cloexec(int fd)
{
int flags, ret;
flags = fcntl(fd, F_GETFD);
flags |= FD_CLOEXEC;
ret = fcntl(fd, F_SETFD, flags);
return DISGUISE(ret);
}
/*
* Take over a FD belonging to another thread.
* unexpected_conn is the expected owner of the fd.
* Returns 0 on success, and -1 on failure.
*/
int fd_takeover(int fd, void *expected_owner)
{
unsigned long old;
/* protect ourself against a delete then an insert for the same fd,
* if it happens, then the owner will no longer be the expected
* connection.
*/
if (fdtab[fd].owner != expected_owner)
return -1;
/* we must be alone to work on this idle FD. If not, it means that its
* poller is currently waking up and is about to use it, likely to
* close it on shut/error, but maybe also to process any unexpectedly
* pending data.
*/
old = 0;
if (!HA_ATOMIC_CAS(&fdtab[fd].running_mask, &old, tid_bit))
return -1;
/* success, from now on it's ours */
HA_ATOMIC_STORE(&fdtab[fd].thread_mask, tid_bit);
/* Make sure the FD doesn't have the active bit. It is possible that
* the fd is polled by the thread that used to own it, the new thread
* is supposed to call subscribe() later, to activate polling.
*/
fd_stop_recv(fd);
/* we're done with it */
HA_ATOMIC_AND(&fdtab[fd].running_mask, ~tid_bit);
return 0;
}
void updt_fd_polling(const int fd)
{
if (all_threads_mask == 1UL || (fdtab[fd].thread_mask & all_threads_mask) == tid_bit) {
if (HA_ATOMIC_BTS(&fdtab[fd].update_mask, tid))
return;
fd_updt[fd_nbupdt++] = fd;
} else {
unsigned long update_mask = fdtab[fd].update_mask;
do {
if (update_mask == fdtab[fd].thread_mask)
return;
} while (!_HA_ATOMIC_CAS(&fdtab[fd].update_mask, &update_mask, fdtab[fd].thread_mask));
fd_add_to_fd_list(&update_list, fd, offsetof(struct fdtab, update));
if (fd_active(fd) && !(fdtab[fd].thread_mask & tid_bit)) {
/* we need to wake up another thread to handle it immediately, any will fit,
* so let's pick a random one so that it doesn't always end up on the same.
*/
int thr = one_among_mask(fdtab[fd].thread_mask & all_threads_mask,
statistical_prng_range(MAX_THREADS));
wake_thread(thr);
}
}
}
/* Update events seen for FD <fd> and its state if needed. This should be
* called by the poller, passing FD_EV_*_{R,W,RW} in <evts>. FD_EV_ERR_*
* doesn't need to also pass FD_EV_SHUT_*, it's implied. ERR and SHUT are
* allowed to be reported regardless of R/W readiness. Returns one of
* FD_UPDT_*.
*/
int fd_update_events(int fd, uint evts)
{
unsigned long locked;
uint old, new;
uint new_flags, must_stop;
ulong rmask, tmask;
_HA_ATOMIC_AND(&th_ctx->flags, ~TH_FL_STUCK); // this thread is still running
/* do nothing if the FD was taken over under us */
do {
/* make sure we read a synchronous copy of rmask and tmask
* (tmask is only up to date if it reflects all of rmask's
* bits).
*/
do {
rmask = _HA_ATOMIC_LOAD(&fdtab[fd].running_mask);
tmask = _HA_ATOMIC_LOAD(&fdtab[fd].thread_mask);
} while (rmask & ~tmask);
if (!(tmask & tid_bit)) {
/* a takeover has started */
activity[tid].poll_skip_fd++;
return FD_UPDT_MIGRATED;
}
} while (!HA_ATOMIC_CAS(&fdtab[fd].running_mask, &rmask, rmask | tid_bit));
locked = (tmask != tid_bit);
/* OK now we are guaranteed that our thread_mask was present and
* that we're allowed to update the FD.
*/
new_flags =
((evts & FD_EV_READY_R) ? FD_POLL_IN : 0) |
((evts & FD_EV_READY_W) ? FD_POLL_OUT : 0) |
((evts & FD_EV_SHUT_R) ? FD_POLL_HUP : 0) |
((evts & FD_EV_ERR_RW) ? FD_POLL_ERR : 0);
/* SHUTW reported while FD was active for writes is an error */
if ((fdtab[fd].state & FD_EV_ACTIVE_W) && (evts & FD_EV_SHUT_W))
new_flags |= FD_POLL_ERR;
/* compute the inactive events reported late that must be stopped */
must_stop = 0;
if (unlikely(!fd_active(fd))) {
/* both sides stopped */
must_stop = FD_POLL_IN | FD_POLL_OUT;
}
else if (unlikely(!fd_recv_active(fd) && (evts & (FD_EV_READY_R | FD_EV_SHUT_R | FD_EV_ERR_RW)))) {
/* only send remains */
must_stop = FD_POLL_IN;
}
else if (unlikely(!fd_send_active(fd) && (evts & (FD_EV_READY_W | FD_EV_SHUT_W | FD_EV_ERR_RW)))) {
/* only recv remains */
must_stop = FD_POLL_OUT;
}
if (new_flags & (FD_POLL_IN | FD_POLL_HUP | FD_POLL_ERR))
new_flags |= FD_EV_READY_R;
if (new_flags & (FD_POLL_OUT | FD_POLL_ERR))
new_flags |= FD_EV_READY_W;
old = fdtab[fd].state;
new = (old & ~FD_POLL_UPDT_MASK) | new_flags;
if (unlikely(locked)) {
/* Locked FDs (those with more than 2 threads) are atomically updated */
while (unlikely(new != old && !_HA_ATOMIC_CAS(&fdtab[fd].state, &old, new)))
new = (old & ~FD_POLL_UPDT_MASK) | new_flags;
} else {
if (new != old)
fdtab[fd].state = new;
}
if (fdtab[fd].iocb && fd_active(fd)) {
fdtab[fd].iocb(fd);
}
/* another thread might have attempted to close this FD in the mean
* time (e.g. timeout task) striking on a previous thread and closing.
* This is detected by both thread_mask and running_mask being 0 after
* we remove ourselves last.
*/
if ((fdtab[fd].running_mask & tid_bit) &&
fd_clr_running(fd) == 0 && !fdtab[fd].thread_mask) {
_fd_delete_orphan(fd);
return FD_UPDT_CLOSED;
}
/* we had to stop this FD and it still must be stopped after the I/O
* cb's changes, so let's program an update for this.
*/
if (must_stop && !(fdtab[fd].update_mask & tid_bit)) {
if (((must_stop & FD_POLL_IN) && !fd_recv_active(fd)) ||
((must_stop & FD_POLL_OUT) && !fd_send_active(fd)))
if (!HA_ATOMIC_BTS(&fdtab[fd].update_mask, tid))
fd_updt[fd_nbupdt++] = fd;
}
return FD_UPDT_DONE;
}
/* Tries to send <npfx> parts from <prefix> followed by <nmsg> parts from <msg>
* optionally followed by a newline if <nl> is non-null, to file descriptor
* <fd>. The message is sent atomically using writev(). It may be truncated to
* <maxlen> bytes if <maxlen> is non-null. There is no distinction between the
* two lists, it's just a convenience to help the caller prepend some prefixes
* when necessary. It takes the fd's lock to make sure no other thread will
* write to the same fd in parallel. Returns the number of bytes sent, or <=0
* on failure. A limit to 31 total non-empty segments is enforced. The caller
* is responsible for taking care of making the fd non-blocking.
*/
ssize_t fd_write_frag_line(int fd, size_t maxlen, const struct ist pfx[], size_t npfx, const struct ist msg[], size_t nmsg, int nl)
{
struct iovec iovec[32];
size_t sent = 0;
int vec = 0;
int attempts = 0;
if (!maxlen)
maxlen = ~0;
/* keep one char for a possible trailing '\n' in any case */
maxlen--;
/* make an iovec from the concatenation of all parts of the original
* message. Skip empty fields and truncate the whole message to maxlen,
* leaving one spare iovec for the '\n'.
*/
while (vec < (sizeof(iovec) / sizeof(iovec[0]) - 1)) {
if (!npfx) {
pfx = msg;
npfx = nmsg;
nmsg = 0;
if (!npfx)
break;
}
iovec[vec].iov_base = pfx->ptr;
iovec[vec].iov_len = MIN(maxlen, pfx->len);
maxlen -= iovec[vec].iov_len;
if (iovec[vec].iov_len)
vec++;
pfx++; npfx--;
};
if (nl) {
iovec[vec].iov_base = "\n";
iovec[vec].iov_len = 1;
vec++;
}
/* make sure we never interleave writes and we never block. This means
* we prefer to fail on collision than to block. But we don't want to
* lose too many logs so we just perform a few lock attempts then give
* up.
*/
while (HA_ATOMIC_BTS(&fdtab[fd].state, FD_EXCL_SYSCALL_BIT)) {
if (++attempts >= 200) {
/* so that the caller knows the message couldn't be delivered */
sent = -1;
errno = EAGAIN;
goto leave;
}
ha_thread_relax();
}
if (unlikely(!(fdtab[fd].state & FD_INITIALIZED))) {
HA_ATOMIC_OR(&fdtab[fd].state, FD_INITIALIZED);
if (!isatty(fd))
fd_set_nonblock(fd);
}
sent = writev(fd, iovec, vec);
HA_ATOMIC_BTR(&fdtab[fd].state, FD_EXCL_SYSCALL_BIT);
leave:
/* sent > 0 if the message was delivered */
return sent;
}
#if defined(USE_CLOSEFROM)
void my_closefrom(int start)
{
closefrom(start);
}
#elif defined(USE_POLL)
/* This is a portable implementation of closefrom(). It closes all open file
* descriptors starting at <start> and above. It relies on the fact that poll()
* will return POLLNVAL for each invalid (hence close) file descriptor passed
* in argument in order to skip them. It acts with batches of FDs and will
* typically perform one poll() call per 1024 FDs so the overhead is low in
* case all FDs have to be closed.
*/
void my_closefrom(int start)
{
struct pollfd poll_events[1024];
struct rlimit limit;
int nbfds, fd, ret, idx;
int step, next;
if (getrlimit(RLIMIT_NOFILE, &limit) == 0)
step = nbfds = limit.rlim_cur;
else
step = nbfds = 0;
if (nbfds <= 0) {
/* set safe limit */
nbfds = 1024;
step = 256;
}
if (step > sizeof(poll_events) / sizeof(poll_events[0]))
step = sizeof(poll_events) / sizeof(poll_events[0]);
while (start < nbfds) {
next = (start / step + 1) * step;
for (fd = start; fd < next && fd < nbfds; fd++) {
poll_events[fd - start].fd = fd;
poll_events[fd - start].events = 0;
}
do {
ret = poll(poll_events, fd - start, 0);
if (ret >= 0)
break;
} while (errno == EAGAIN || errno == EWOULDBLOCK || errno == EINTR || errno == ENOMEM);
if (ret)
ret = fd - start;
for (idx = 0; idx < ret; idx++) {
if (poll_events[idx].revents & POLLNVAL)
continue; /* already closed */
fd = poll_events[idx].fd;
close(fd);
}
start = next;
}
}
#else // defined(USE_POLL)
/* This is a portable implementation of closefrom(). It closes all open file
* descriptors starting at <start> and above. This is a naive version for use
* when the operating system provides no alternative.
*/
void my_closefrom(int start)
{
struct rlimit limit;
int nbfds;
if (getrlimit(RLIMIT_NOFILE, &limit) == 0)
nbfds = limit.rlim_cur;
else
nbfds = 0;
if (nbfds <= 0)
nbfds = 1024; /* safe limit */
while (start < nbfds)
close(start++);
}
#endif // defined(USE_POLL)
/* Computes the bounded poll() timeout based on the next expiration timer <next>
* by bounding it to MAX_DELAY_MS. <next> may equal TICK_ETERNITY. The pollers
* just needs to call this function right before polling to get their timeout
* value. Timeouts that are already expired (possibly due to a pending event)
* are accounted for in activity.poll_exp.
*/
int compute_poll_timeout(int next)
{
int wait_time;
if (!tick_isset(next))
wait_time = MAX_DELAY_MS;
else if (tick_is_expired(next, now_ms)) {
activity[tid].poll_exp++;
wait_time = 0;
}
else {
wait_time = TICKS_TO_MS(tick_remain(now_ms, next)) + 1;
if (wait_time > MAX_DELAY_MS)
wait_time = MAX_DELAY_MS;
}
return wait_time;
}
/* Handle the return of the poller, which consists in calculating the idle
* time, saving a few clocks, marking the thread harmful again etc. All that
* is some boring stuff that all pollers have to do anyway.
*/
void fd_leaving_poll(int wait_time, int status)
{
clock_leaving_poll(wait_time, status);
thread_harmless_end();
thread_idle_end();
_HA_ATOMIC_AND(&th_ctx->flags, ~TH_FL_SLEEPING);
}
/* disable the specified poller */
void disable_poller(const char *poller_name)
{
int p;
for (p = 0; p < nbpollers; p++)
if (strcmp(pollers[p].name, poller_name) == 0)
pollers[p].pref = 0;
}
void poller_pipe_io_handler(int fd)
{
char buf[1024];
/* Flush the pipe */
while (read(fd, buf, sizeof(buf)) > 0);
fd_cant_recv(fd);
}
/* allocate the per-thread fd_updt thus needs to be called early after
* thread creation.
*/
static int alloc_pollers_per_thread()
{
fd_updt = calloc(global.maxsock, sizeof(*fd_updt));
return fd_updt != NULL;
}
/* Initialize the pollers per thread.*/
static int init_pollers_per_thread()
{
int mypipe[2];
if (pipe(mypipe) < 0)
return 0;
poller_rd_pipe = mypipe[0];
poller_wr_pipe[tid] = mypipe[1];
fd_set_nonblock(poller_rd_pipe);
fd_insert(poller_rd_pipe, poller_pipe_io_handler, poller_pipe_io_handler, tid_bit);
fd_insert(poller_wr_pipe[tid], poller_pipe_io_handler, poller_pipe_io_handler, tid_bit);
fd_want_recv(poller_rd_pipe);
fd_stop_both(poller_wr_pipe[tid]);
return 1;
}
/* Deinitialize the pollers per thread */
static void deinit_pollers_per_thread()
{
/* rd and wr are init at the same place, but only rd is init to -1, so
we rely to rd to close. */
if (poller_rd_pipe > -1) {
close(poller_rd_pipe);
poller_rd_pipe = -1;
close(poller_wr_pipe[tid]);
poller_wr_pipe[tid] = -1;
}
}
/* Release the pollers per thread, to be called late */
static void free_pollers_per_thread()
{
ha_free(&fd_updt);
}
/*
* Initialize the pollers till the best one is found.
* If none works, returns 0, otherwise 1.
*/
int init_pollers()
{
int p;
struct poller *bp;
if ((fdtab_addr = calloc(global.maxsock, sizeof(*fdtab) + 64)) == NULL) {
ha_alert("Not enough memory to allocate %d entries for fdtab!\n", global.maxsock);
goto fail_tab;
}
/* always provide an aligned fdtab */
fdtab = (struct fdtab*)((((size_t)fdtab_addr) + 63) & -(size_t)64);
if ((polled_mask = calloc(global.maxsock, sizeof(*polled_mask))) == NULL) {
ha_alert("Not enough memory to allocate %d entries for polled_mask!\n", global.maxsock);
goto fail_polledmask;
}
if ((fdinfo = calloc(global.maxsock, sizeof(*fdinfo))) == NULL) {
ha_alert("Not enough memory to allocate %d entries for fdinfo!\n", global.maxsock);
goto fail_info;
}
update_list.first = update_list.last = -1;
for (p = 0; p < global.maxsock; p++) {
/* Mark the fd as out of the fd cache */
fdtab[p].update.next = -3;
}
do {
bp = NULL;
for (p = 0; p < nbpollers; p++)
if (!bp || (pollers[p].pref > bp->pref))
bp = &pollers[p];
if (!bp || bp->pref == 0)
break;
if (bp->init(bp)) {
memcpy(&cur_poller, bp, sizeof(*bp));
return 1;
}
} while (!bp || bp->pref == 0);
free(fdinfo);
fail_info:
free(polled_mask);
fail_polledmask:
free(fdtab_addr);
fail_tab:
return 0;
}
/*
* Deinitialize the pollers.
*/
void deinit_pollers() {
struct poller *bp;
int p;
for (p = 0; p < nbpollers; p++) {
bp = &pollers[p];
if (bp && bp->pref)
bp->term(bp);
}
ha_free(&fdinfo);
ha_free(&fdtab_addr);
ha_free(&polled_mask);
}
/*
* Lists the known pollers on <out>.
* Should be performed only before initialization.
*/
int list_pollers(FILE *out)
{
int p;
int last, next;
int usable;
struct poller *bp;
fprintf(out, "Available polling systems :\n");
usable = 0;
bp = NULL;
last = next = -1;
while (1) {
for (p = 0; p < nbpollers; p++) {
if ((next < 0 || pollers[p].pref > next)
&& (last < 0 || pollers[p].pref < last)) {
next = pollers[p].pref;
if (!bp || (pollers[p].pref > bp->pref))
bp = &pollers[p];
}
}
if (next == -1)
break;
for (p = 0; p < nbpollers; p++) {
if (pollers[p].pref == next) {
fprintf(out, " %10s : ", pollers[p].name);
if (pollers[p].pref == 0)
fprintf(out, "disabled, ");
else
fprintf(out, "pref=%3d, ", pollers[p].pref);
if (pollers[p].test(&pollers[p])) {
fprintf(out, " test result OK");
if (next > 0)
usable++;
} else {
fprintf(out, " test result FAILED");
if (bp == &pollers[p])
bp = NULL;
}
fprintf(out, "\n");
}
}
last = next;
next = -1;
};
fprintf(out, "Total: %d (%d usable), will use %s.\n", nbpollers, usable, bp ? bp->name : "none");
return 0;
}
/*
* Some pollers may lose their connection after a fork(). It may be necessary
* to create initialize part of them again. Returns 0 in case of failure,
* otherwise 1. The fork() function may be NULL if unused. In case of error,
* the the current poller is destroyed and the caller is responsible for trying
* another one by calling init_pollers() again.
*/
int fork_poller()
{
int fd;
for (fd = 0; fd < global.maxsock; fd++) {
if (fdtab[fd].owner) {
HA_ATOMIC_OR(&fdtab[fd].state, FD_CLONED);
}
}
if (cur_poller.fork) {
if (cur_poller.fork(&cur_poller))
return 1;
cur_poller.term(&cur_poller);
return 0;
}
return 1;
}
/* config parser for global "tune.fd.edge-triggered", accepts "on" or "off" */
static int cfg_parse_tune_fd_edge_triggered(char **args, int section_type, struct proxy *curpx,
const struct proxy *defpx, const char *file, int line,
char **err)
{
if (too_many_args(1, args, err, NULL))
return -1;
if (strcmp(args[1], "on") == 0)
global.tune.options |= GTUNE_FD_ET;
else if (strcmp(args[1], "off") == 0)
global.tune.options &= ~GTUNE_FD_ET;
else {
memprintf(err, "'%s' expects either 'on' or 'off' but got '%s'.", args[0], args[1]);
return -1;
}
return 0;
}
/* config keyword parsers */
static struct cfg_kw_list cfg_kws = {ILH, {
{ CFG_GLOBAL, "tune.fd.edge-triggered", cfg_parse_tune_fd_edge_triggered, KWF_EXPERIMENTAL },
{ 0, NULL, NULL }
}};
INITCALL1(STG_REGISTER, cfg_register_keywords, &cfg_kws);
REGISTER_PER_THREAD_ALLOC(alloc_pollers_per_thread);
REGISTER_PER_THREAD_INIT(init_pollers_per_thread);
REGISTER_PER_THREAD_DEINIT(deinit_pollers_per_thread);
REGISTER_PER_THREAD_FREE(free_pollers_per_thread);
/*
* Local variables:
* c-indent-level: 8
* c-basic-offset: 8
* End:
*/