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git01.mediatek.com / haproxy / 037d2c1f8fd6c505f2b44f56b642f2863c17ed4f / . / src / ev_sepoll.c
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/*
* FD polling functions for Speculative I/O combined with Linux epoll()
*
* Copyright 2000-2012 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.
*
*
* This code implements "speculative I/O" under Linux. The principle is to
* try to perform expected I/O before registering the events in the poller.
* Each time this succeeds, it saves an expensive epoll_ctl(). It generally
* succeeds for all reads after an accept(), and for writes after a connect().
* It also improves performance for streaming connections because even if only
* one side is polled, the other one may react accordingly depending on the
* level of the buffer.
*
* More importantly, it enables I/O operations that are backed by invisible
* buffers. For example, SSL is able to read a whole socket buffer and not
* deliver it to the application buffer because it's full. Unfortunately, it
* won't be reported by epoll() anymore until some new activity happens. The
* only way to call it again thus is to perform speculative I/O as soon as
* reading on the FD is enabled again.
*
* The speculative I/O relies on a double list of expected events and updates.
* Expected events are events that are expected to come and that we must report
* to the application until it asks to stop or to poll. Updates are new requests
* for changing an FD state. Updates are the only way to create new events. This
* is important because it means that the number of speculative events cannot
* increase between updates and will only grow one at a time while processing
* updates. All updates must always be processed, though events might be
* processed by small batches if required. The result is that there is no need
* for preallocating room for spec events, updates evinced from the list always
* release at least as much as necessary.
*
* In order to limit memory usage, events and updates share the same list (an
* array to be exact). The lower part (0..nbevts) is used by events and the
* higher part by updates. This way, an fd may be mapped to any entry (evt or
* update) using a single index. Updates may be simply turned to events. When
* events are deleted, the last event from the list must replace the deleted
* event, and if there were updates past this event, one must be moved to take
* its place. It still means that any file descriptor might be present in the
* event or update list, so the list must be at least as large as the maximum
* number of simultaneous file descriptors.
*
* It is important to understand that as long as all expected events are
* processed, they might starve the polled events, especially because polled
* I/O starvation quickly induces more speculative I/O. One solution to this
* consists in only processing a part of the events at once, but one drawback
* is that unhandled events will still wake epoll_wait() up. Using EPOLL_ET
* will solve this issue though.
*
* A file descriptor has a distinct state for each direction. This state is a
* combination of two bits :
* bit 0 = active Y/N : is set if the FD is active, which means that its
* handler will be called without prior polling ;
* bit 1 = polled Y/N : is set if the FD was subscribed to polling
*
* It is perfectly valid to have both bits set at a time, which generally means
* that the FD was reported by polling, was marked active and not yet unpolled.
* Such a state must not last long to avoid unneeded wakeups.
*
* The state of the FD as of last change is preserved in two other bits. These
* ones are useful to save a significant amount of system calls during state
* changes, because there is no need to call epoll_ctl() until we're about to
* call epoll_wait().
*
* Since we do not want to scan all the FD list to find speculative I/O events,
* we store them in a list consisting in a linear array holding only the FD
* indexes right now. Note that a closed FD cannot exist in the spec list,
* because it is closed by fd_delete() which in turn calls __fd_clo() which
* always removes it from the list.
*
* For efficiency reasons, we will store the Read and Write bits interlaced to
* form a 4-bit field, so that we can simply shift the value right by 0/1 and
* get what we want :
* 3 2 1 0
* Wp Rp Wa Ra
*
* The FD array has to hold a back reference to the speculative list. This
* reference is always valid unless the FD if currently being polled and not
* updated (in which case the reference points to index 0).
*
* We store the FD state in the 4 lower bits of fdtab[fd].spec_e, and save the
* previous state upon changes in the 4 higher bits, so that changes are easy
* to spot.
*/
#include <unistd.h>
#include <sys/time.h>
#include <sys/types.h>
#include <common/compat.h>
#include <common/config.h>
#include <common/debug.h>
#include <common/epoll.h>
#include <common/standard.h>
#include <common/ticks.h>
#include <common/time.h>
#include <common/tools.h>
#include <types/global.h>
#include <proto/fd.h>
#include <proto/signal.h>
#include <proto/task.h>
#define FD_EV_ACTIVE 1U
#define FD_EV_POLLED 4U
#define FD_EV_STATUS (FD_EV_ACTIVE | FD_EV_POLLED)
#define FD_EV_STATUS_R (FD_EV_STATUS)
#define FD_EV_STATUS_W (FD_EV_STATUS << 1)
#define FD_EV_POLLED_R (FD_EV_POLLED)
#define FD_EV_POLLED_W (FD_EV_POLLED << 1)
#define FD_EV_POLLED_RW (FD_EV_POLLED_R | FD_EV_POLLED_W)
#define FD_EV_ACTIVE_R (FD_EV_ACTIVE)
#define FD_EV_ACTIVE_W (FD_EV_ACTIVE << 1)
#define FD_EV_ACTIVE_RW (FD_EV_ACTIVE_R | FD_EV_ACTIVE_W)
#define FD_EV_CURR_MASK 0x0FU
#define FD_EV_PREV_MASK 0xF0U
/* This is the minimum number of events successfully processed in speculative
* mode above which we agree to return without checking epoll() (1/2 times).
*/
#define MIN_RETURN_EVENTS 25
static int nbspec = 0; // number of speculative events in the list
static int nbupdt = 0; // number of updates in the list
static int absmaxevents = 0; // absolute maximum amounts of polled events
static int in_poll_loop = 0; // non-null if polled events are being processed
static unsigned int *spec_list = NULL; // speculative I/O list
static unsigned int *updt_list = NULL; // FD updates list
/* private data */
static struct epoll_event *epoll_events;
static int epoll_fd;
/* This structure may be used for any purpose. Warning! do not use it in
* recursive functions !
*/
static struct epoll_event ev;
/* Mark fd <fd> as updated and allocate an entry in the update list for this if
* it was not already there. This can be done at any time.
*/
REGPRM1 static inline void updt_fd(const int fd)
{
if (fdtab[fd].updated)
/* already scheduled for update */
return;
updt_list[nbupdt++] = fd;
fdtab[fd].updated = 1;
}
/* allocate an entry for a speculative event. This can be done at any time. */
REGPRM1 static inline void alloc_spec_entry(const int fd)
{
if (fdtab[fd].spec_p)
/* FD already in speculative I/O list */
return;
spec_list[nbspec++] = fd;
fdtab[fd].spec_p = nbspec;
}
/* Removes entry used by fd <fd> from the spec list and replaces it with the
* last one. The fdtab.spec is adjusted to match the back reference if needed.
* If the fd has no entry assigned, return immediately.
*/
REGPRM1 static void release_spec_entry(int fd)
{
unsigned int pos;
pos = fdtab[fd].spec_p;
if (!pos)
return;
fdtab[fd].spec_p = 0;
nbspec--;
if (pos <= nbspec) {
/* was not the last entry */
fd = spec_list[nbspec];
spec_list[pos - 1] = fd;
fdtab[fd].spec_p = pos;
}
}
/*
* Returns non-zero if <fd> is already monitored for events in direction <dir>.
*/
REGPRM2 static int __fd_is_set(const int fd, int dir)
{
#if DEBUG_DEV
if (!fdtab[fd].owner) {
fprintf(stderr, "sepoll.fd_isset called on closed fd #%d.\n", fd);
ABORT_NOW();
}
#endif
return ((unsigned)fdtab[fd].spec_e >> dir) & FD_EV_STATUS;
}
/*
* Don't worry about the strange constructs in __fd_set/__fd_clr, they are
* designed like this in order to reduce the number of jumps (verified).
*/
REGPRM2 static void __fd_wai(const int fd, int dir)
{
unsigned int i;
#if DEBUG_DEV
if (!fdtab[fd].owner) {
fprintf(stderr, "sepoll.fd_wai called on closed fd #%d.\n", fd);
ABORT_NOW();
}
#endif
i = ((unsigned)fdtab[fd].spec_e >> dir) & FD_EV_STATUS;
if (i == FD_EV_POLLED)
return; /* already in desired state */
updt_fd(fd); /* need an update entry to change the state */
fdtab[fd].spec_e ^= (i ^ (unsigned int)FD_EV_POLLED) << dir;
}
REGPRM2 static void __fd_set(const int fd, int dir)
{
unsigned int i;
#if DEBUG_DEV
if (!fdtab[fd].owner) {
fprintf(stderr, "sepoll.fd_set called on closed fd #%d.\n", fd);
ABORT_NOW();
}
#endif
i = ((unsigned)fdtab[fd].spec_e >> dir) & FD_EV_STATUS;
/* note that we don't care about disabling the polled state when
* enabling the active state, since it brings no benefit but costs
* some syscalls.
*/
if (i & FD_EV_ACTIVE)
return; /* already in desired state */
updt_fd(fd); /* need an update entry to change the state */
fdtab[fd].spec_e |= ((unsigned int)FD_EV_ACTIVE) << dir;
}
REGPRM2 static void __fd_clr(const int fd, int dir)
{
unsigned int i;
#if DEBUG_DEV
if (!fdtab[fd].owner) {
fprintf(stderr, "sepoll.fd_clr called on closed fd #%d.\n", fd);
ABORT_NOW();
}
#endif
i = ((unsigned)fdtab[fd].spec_e >> dir) & FD_EV_STATUS;
if (i == 0)
return /* already disabled */;
updt_fd(fd); /* need an update entry to change the state */
fdtab[fd].spec_e ^= i << dir;
}
/* normally unused */
REGPRM1 static void __fd_rem(int fd)
{
__fd_clr(fd, DIR_RD);
__fd_clr(fd, DIR_WR);
}
/*
* On valid epoll() implementations, a call to close() automatically removes
* the fds. This means that the FD will appear as previously unset.
*/
REGPRM1 static void __fd_clo(int fd)
{
release_spec_entry(fd);
fdtab[fd].spec_e &= ~(FD_EV_CURR_MASK | FD_EV_PREV_MASK);
}
/*
* speculative epoll() poller
*/
REGPRM2 static void _do_poll(struct poller *p, int exp)
{
int status, eo, en;
int fd, opcode;
int count;
int spec_idx;
int updt_idx;
int wait_time;
/* first, scan the update list to find changes */
for (updt_idx = 0; updt_idx < nbupdt; updt_idx++) {
fd = updt_list[updt_idx];
en = fdtab[fd].spec_e & 15; /* new events */
eo = fdtab[fd].spec_e >> 4; /* previous events */
if (fdtab[fd].owner && (eo ^ en)) {
if ((eo ^ en) & FD_EV_POLLED_RW) {
/* poll status changed */
if ((en & FD_EV_POLLED_RW) == 0) {
/* fd removed from poll list */
opcode = EPOLL_CTL_DEL;
}
else if ((eo & FD_EV_POLLED_RW) == 0) {
/* new fd in the poll list */
opcode = EPOLL_CTL_ADD;
}
else {
/* fd status changed */
opcode = EPOLL_CTL_MOD;
}
/* construct the epoll events based on new state */
ev.events = 0;
if (en & FD_EV_POLLED_R)
ev.events |= EPOLLIN;
if (en & FD_EV_POLLED_W)
ev.events |= EPOLLOUT;
ev.data.fd = fd;
epoll_ctl(epoll_fd, opcode, fd, &ev);
}
fdtab[fd].spec_e = (en << 4) + en; /* save new events */
if (!(en & FD_EV_ACTIVE_RW)) {
/* This fd doesn't use any active entry anymore, we can
* kill its entry.
*/
release_spec_entry(fd);
}
else if ((en & ~eo) & FD_EV_ACTIVE_RW) {
/* we need a new spec entry now */
alloc_spec_entry(fd);
}
}
fdtab[fd].updated = 0;
fdtab[fd].new = 0;
}
nbupdt = 0;
/* compute the epoll_wait() timeout */
if (nbspec || run_queue || signal_queue_len) {
/* Maybe we still have events in the spec list, or there are
* some tasks left pending in the run_queue, so we must not
* wait in epoll() otherwise we would delay their delivery by
* the next timeout.
*/
wait_time = 0;
}
else {
if (!exp)
wait_time = MAX_DELAY_MS;
else if (tick_is_expired(exp, now_ms))
wait_time = 0;
else {
wait_time = TICKS_TO_MS(tick_remain(now_ms, exp)) + 1;
if (wait_time > MAX_DELAY_MS)
wait_time = MAX_DELAY_MS;
}
}
/* now let's wait for polled events */
fd = MIN(maxfd, global.tune.maxpollevents);
gettimeofday(&before_poll, NULL);
status = epoll_wait(epoll_fd, epoll_events, fd, wait_time);
tv_update_date(wait_time, status);
measure_idle();
in_poll_loop = 1;
/* process polled events */
for (count = 0; count < status; count++) {
int e = epoll_events[count].events;
fd = epoll_events[count].data.fd;
if (!fdtab[fd].owner)
continue;
/* it looks complicated but gcc can optimize it away when constants
* have same values.
*/
fdtab[fd].ev &= FD_POLL_STICKY;
fdtab[fd].ev |=
((e & EPOLLIN ) ? FD_POLL_IN : 0) |
((e & EPOLLPRI) ? FD_POLL_PRI : 0) |
((e & EPOLLOUT) ? FD_POLL_OUT : 0) |
((e & EPOLLERR) ? FD_POLL_ERR : 0) |
((e & EPOLLHUP) ? FD_POLL_HUP : 0);
if (fdtab[fd].iocb && fdtab[fd].owner && fdtab[fd].ev) {
int new_updt, old_updt = nbupdt; /* Save number of updates to detect creation of new FDs. */
/* Mark the events as speculative before processing
* them so that if nothing can be done we don't need
* to poll again.
*/
if (fdtab[fd].ev & (FD_POLL_IN|FD_POLL_HUP|FD_POLL_ERR))
__fd_set(fd, DIR_RD);
if (fdtab[fd].ev & (FD_POLL_OUT|FD_POLL_ERR))
__fd_set(fd, DIR_WR);
fdtab[fd].iocb(fd);
/* One or more fd might have been created during the iocb().
* This mainly happens with new incoming connections that have
* just been accepted, so we'd like to process them immediately
* for better efficiency. Second benefit, if at the end the fds
* are disabled again, we can safely destroy their update entry
* to reduce the scope of later scans. This is the reason we
* scan the new entries backwards.
*/
for (new_updt = nbupdt; new_updt > old_updt; new_updt--) {
fd = updt_list[new_updt - 1];
if (!fdtab[fd].new)
continue;
fdtab[fd].new = 0;
fdtab[fd].ev &= FD_POLL_STICKY;
if ((fdtab[fd].spec_e & FD_EV_STATUS_R) == FD_EV_ACTIVE_R)
fdtab[fd].ev |= FD_POLL_IN;
if ((fdtab[fd].spec_e & FD_EV_STATUS_W) == FD_EV_ACTIVE_W)
fdtab[fd].ev |= FD_POLL_OUT;
if (fdtab[fd].ev && fdtab[fd].iocb && fdtab[fd].owner)
fdtab[fd].iocb(fd);
/* we can remove this update entry if it's the last one and is
* unused, otherwise we don't touch anything.
*/
if (new_updt == nbupdt && fdtab[fd].spec_e == 0) {
fdtab[fd].updated = 0;
nbupdt--;
}
}
}
}
/* now process speculative events if any */
for (spec_idx = 0; spec_idx < nbspec; ) {
fd = spec_list[spec_idx];
eo = fdtab[fd].spec_e;
/*
* Process the speculative events.
*
* Principle: events which are marked FD_EV_ACTIVE are processed
* with their usual I/O callback. The callback may remove the
* events from the list or tag them for polling. Changes will be
* applied on next round.
*/
fdtab[fd].ev &= FD_POLL_STICKY;
if ((eo & FD_EV_STATUS_R) == FD_EV_ACTIVE_R)
fdtab[fd].ev |= FD_POLL_IN;
if ((eo & FD_EV_STATUS_W) == FD_EV_ACTIVE_W)
fdtab[fd].ev |= FD_POLL_OUT;
if (fdtab[fd].iocb && fdtab[fd].owner && fdtab[fd].ev)
fdtab[fd].iocb(fd);
/* if the fd was removed from the spec list, it has been
* replaced by the next one that we don't want to skip !
*/
if (spec_idx < nbspec && spec_list[spec_idx] != fd)
continue;
spec_idx++;
}
in_poll_loop = 0;
/* in the end, we have processed status + spec_processed FDs */
}
/*
* Initialization of the speculative epoll() poller.
* Returns 0 in case of failure, non-zero in case of success. If it fails, it
* disables the poller by setting its pref to 0.
*/
REGPRM1 static int _do_init(struct poller *p)
{
__label__ fail_spec, fail_ee, fail_fd;
p->private = NULL;
epoll_fd = epoll_create(global.maxsock + 1);
if (epoll_fd < 0)
goto fail_fd;
/* See comments at the top of the file about this formula. */
absmaxevents = MAX(global.tune.maxpollevents, global.maxsock);
epoll_events = (struct epoll_event*)
calloc(1, sizeof(struct epoll_event) * absmaxevents);
if (epoll_events == NULL)
goto fail_ee;
if ((spec_list = (uint32_t *)calloc(1, sizeof(uint32_t) * global.maxsock)) == NULL)
goto fail_spec;
if ((updt_list = (uint32_t *)calloc(1, sizeof(uint32_t) * global.maxsock)) == NULL)
goto fail_updt;
return 1;
fail_updt:
free(spec_list);
fail_spec:
free(epoll_events);
fail_ee:
close(epoll_fd);
epoll_fd = -1;
fail_fd:
p->pref = 0;
return 0;
}
/*
* Termination of the speculative epoll() poller.
* Memory is released and the poller is marked as unselectable.
*/
REGPRM1 static void _do_term(struct poller *p)
{
free(updt_list);
free(spec_list);
free(epoll_events);
if (epoll_fd >= 0) {
close(epoll_fd);
epoll_fd = -1;
}
updt_list = NULL;
spec_list = NULL;
epoll_events = NULL;
p->private = NULL;
p->pref = 0;
}
/*
* Check that the poller works.
* Returns 1 if OK, otherwise 0.
*/
REGPRM1 static int _do_test(struct poller *p)
{
int fd;
fd = epoll_create(global.maxsock + 1);
if (fd < 0)
return 0;
close(fd);
return 1;
}
/*
* Recreate the epoll file descriptor after a fork(). Returns 1 if OK,
* otherwise 0. It will ensure that all processes will not share their
* epoll_fd. Some side effects were encountered because of this, such
* as epoll_wait() returning an FD which was previously deleted.
*/
REGPRM1 static int _do_fork(struct poller *p)
{
if (epoll_fd >= 0)
close(epoll_fd);
epoll_fd = epoll_create(global.maxsock + 1);
if (epoll_fd < 0)
return 0;
return 1;
}
/*
* It is a constructor, which means that it will automatically be called before
* main(). This is GCC-specific but it works at least since 2.95.
* Special care must be taken so that it does not need any uninitialized data.
*/
__attribute__((constructor))
static void _do_register(void)
{
struct poller *p;
if (nbpollers >= MAX_POLLERS)
return;
epoll_fd = -1;
p = &pollers[nbpollers++];
p->name = "sepoll";
p->pref = 400;
p->private = NULL;
p->test = _do_test;
p->init = _do_init;
p->term = _do_term;
p->poll = _do_poll;
p->fork = _do_fork;
p->is_set = __fd_is_set;
p->set = __fd_set;
p->wai = __fd_wai;
p->clr = __fd_clr;
p->rem = __fd_rem;
p->clo = __fd_clo;
}
/*
* Local variables:
* c-indent-level: 8
* c-basic-offset: 8
* End:
*/