static int
select_dispatch(struct event_base *base, void *arg, struct timeval *tv)
{
int res, i, j;
struct selectop *sop = arg;
check_selectop(sop);
memcpy(sop->event_readset_out, sop->event_readset_in,
sop->event_fdsz);
memcpy(sop->event_writeset_out, sop->event_writeset_in,
sop->event_fdsz);
res = select(sop->event_fds + 1, sop->event_readset_out,
sop->event_writeset_out, NULL, tv);
check_selectop(sop);
if (res == -1) {
if (errno != EINTR) {
event_warn("select");
return (-1);
}
evsignal_process(base);
return (0);
} else if (base->sig.evsignal_caught) {
evsignal_process(base);
}
event_debug(("%s: select reports %d", __func__, res));
check_selectop(sop);
i = arc4random_uniform(sop->event_fds + 1);
for (j = 0; j <= sop->event_fds; ++j) {
struct event *r_ev = NULL, *w_ev = NULL;
if (++i >= sop->event_fds+1)
i = 0;
res = 0;
if (FD_ISSET(i, sop->event_readset_out)) {
r_ev = sop->event_r_by_fd[i];
res |= EV_READ;
}
if (FD_ISSET(i, sop->event_writeset_out)) {
w_ev = sop->event_w_by_fd[i];
res |= EV_WRITE;
}
if (r_ev && (res & r_ev->ev_events)) {
event_active(r_ev, res & r_ev->ev_events, 1);
}
if (w_ev && w_ev != r_ev && (res & w_ev->ev_events)) {
event_active(w_ev, res & w_ev->ev_events, 1);
}
}
check_selectop(sop);
return (0);
}
int
select_dispatch(struct event_base *base, void *arg, struct timeval *tv)
{
int res, i;
struct selectop *sop = arg;
check_selectop(sop);
memcpy(sop->event_readset_out, sop->event_readset_in,
sop->event_fdsz);
memcpy(sop->event_writeset_out, sop->event_writeset_in,
sop->event_fdsz);
res = select(sop->event_fds + 1, sop->event_readset_out,
sop->event_writeset_out, NULL, tv);
check_selectop(sop);
if (res == -1) {
if (errno != EINTR) {
event_warn("select");
return (-1);
}
evsignal_process();
return (0);
} else if (evsignal_caught)
evsignal_process();
event_debug(("%s: select reports %d", __func__, res));
check_selectop(sop);
for (i = 0; i <= sop->event_fds; ++i) {
struct event *r_ev = NULL, *w_ev = NULL;
res = 0;
if (FD_ISSET(i, sop->event_readset_out)) {
r_ev = sop->event_r_by_fd[i];
res |= EV_READ;
}
if (FD_ISSET(i, sop->event_writeset_out)) {
w_ev = sop->event_w_by_fd[i];
res |= EV_WRITE;
}
if (r_ev && (res & r_ev->ev_events)) {
if (!(r_ev->ev_events & EV_PERSIST))
event_del(r_ev);
event_active(r_ev, res & r_ev->ev_events, 1);
}
if (w_ev && w_ev != r_ev && (res & w_ev->ev_events)) {
if (!(w_ev->ev_events & EV_PERSIST))
event_del(w_ev);
event_active(w_ev, res & w_ev->ev_events, 1);
}
}
check_selectop(sop);
return (0);
}
void
evsignal_process(struct event_base *base)
{
struct evsignal_info *sig = &base->sig;
struct event *ev, *next_ev;
sig_atomic_t ncalls;
int i;
base->sig.evsignal_caught = 0;
for (i = 1; i < NSIG; ++i) {
ncalls = sig->evsigcaught[i];
if (ncalls == 0)
continue;
sig->evsigcaught[i] -= ncalls;
for (ev = TAILQ_FIRST(&sig->evsigevents[i]);
ev != NULL; ev = next_ev) {
next_ev = TAILQ_NEXT(ev, ev_signal_next);
if (!(ev->ev_events & EV_PERSIST))
event_del(ev);
event_active(ev, EV_SIGNAL, ncalls);
}
}
}
void run_in_event_loop(
const lambda::function<void(void)>& f,
EventLoopLogicFlow event_loop_logic_flow)
{
if (__in_event_loop__ && event_loop_logic_flow == ALLOW_SHORT_CIRCUIT) {
f();
return;
}
synchronized (functions_mutex) {
functions->push(f);
// Add an event and activate it to interrupt the event loop.
// TODO(jmlvanre): after libevent v 2.1 we can use
// event_self_cbarg instead of re-assigning the event. For now we
// manually re-assign the event to pass in the pointer to the
// event itself as the callback argument.
event* ev = evtimer_new(base, async_function, NULL);
// 'event_assign' is only valid on non-pending AND non-active
// events. This means we have to assign the callback before
// calling 'event_active'.
if (evtimer_assign(ev, base, async_function, ev) < 0) {
LOG(FATAL) << "Failed to assign callback on event";
}
event_active(ev, EV_TIMEOUT, 0);
}
}
void HTTPEvent::trigger(struct timeval* tv)
{
if (tv == NULL)
event_active(ev, 0, 0); // immediately trigger event in main thread
else
evtimer_add(ev, tv); // trigger after timeval passed
}
void async_file::write_cycle()
{
int read_bs = 0;
lock();
read_bs = get_read_bs();
unlock();
while(!error && (read_bs > 0)) {
int bytes = write_to_file(get_read_ptr(),read_bs);
if(bytes < 0) {
error = true;
ERROR("Error detected: stopped writing");
break;
}
lock();
skip(bytes);
read_bs = get_read_bs();
unlock();
}
lock();
if(closed) {
if(error || !fifo_buffer::get_buffered_bytes())
on_flushed();
else
event_active(ev_write, 0, 0);
}
unlock();
}
void start_new_job(curl_handler* _curl_handler)
{
if (_curl_handler->keep_working_)
{
event_active(_curl_handler->start_task_event_, 0, 0);
}
}
static void
t1func(evutil_socket_t fd, short what, void *arg)
{
struct event *t1 = (struct event*)arg;
struct event *t2;
fprintf(stderr, "CAUGHT EVENT\n");
fflush(stderr);
event_del(t1);
free(t1);
loops++;
if (loops < 10) {
t2 = (struct event*)malloc(sizeof(struct event));
if (event_assign(t2, base, -1, EV_WRITE, t1func, t2) < 0) {
die("event_assign_term");
}
if (event_priority_set(t2, TERMPRI) < 0) {
die("event_priority_set_term");
}
fprintf(stderr, "EVENT %d DEFINED\n", loops);
fflush(stderr);
event_active(t2, EV_WRITE, 1);
fprintf(stderr, "EVENT %d ACTIVATED\n", loops);
fflush(stderr);
}
}
tr_watchdir_backend *
tr_watchdir_kqueue_new (tr_watchdir_t handle)
{
const char * const path = tr_watchdir_get_path (handle);
struct kevent ke;
tr_watchdir_kqueue * backend;
backend = tr_new0 (tr_watchdir_kqueue, 1);
backend->base.free_func = &tr_watchdir_kqueue_free;
backend->kq = -1;
backend->dirfd = -1;
if ((backend->kq = kqueue ()) == -1)
{
log_error ("Failed to start kqueue");
goto fail;
}
/* Open fd for watching */
if ((backend->dirfd = open (path, O_RDONLY | O_EVTONLY)) == -1)
{
log_error ("Failed to passively watch directory \"%s\": %s", path,
tr_strerror (errno));
goto fail;
}
/* Register kevent filter with kqueue descriptor */
EV_SET (&ke, backend->dirfd, EVFILT_VNODE, EV_ADD | EV_ENABLE | EV_CLEAR,
KQUEUE_WATCH_MASK, 0, NULL);
if (kevent (backend->kq, &ke, 1, NULL, 0, NULL) == -1)
{
log_error ("Failed to set directory event filter with fd %d: %s", backend->kq,
tr_strerror (errno));
goto fail;
}
/* Create libevent task for event descriptor */
if ((backend->event = event_new (tr_watchdir_get_event_base (handle), backend->kq,
EV_READ | EV_ET | EV_PERSIST,
&tr_watchdir_kqueue_on_event, handle)) == NULL)
{
log_error ("Failed to create event: %s", tr_strerror (errno));
goto fail;
}
if (event_add (backend->event, NULL) == -1)
{
log_error ("Failed to add event: %s", tr_strerror (errno));
goto fail;
}
/* Trigger one event for the initial scan */
event_active (backend->event, EV_READ, 0);
return BACKEND_DOWNCAST (backend);
fail:
tr_watchdir_kqueue_free (BACKEND_DOWNCAST (backend));
return NULL;
}
void
levent_send_now(struct lldpd *cfg)
{
struct lldpd_hardware *hardware;
TAILQ_FOREACH(hardware, &cfg->g_hardware, h_entries)
event_active(hardware->h_timer, EV_TIMEOUT, 1);
}
//
// Action handler that shutdown the server gracefullly
//
static void shutdown_action(struct owl_state* state) {
TRACE("Asked to shutdown...\n");
state->state = OWL_STATE_SHUTTING_DOWN;
event_del(state->sigint);
event_active(state->sigint, 0, 1);
}
void
http_engine_stop()
{
int i;
if (!g_http_engine) {
return;
}
zlog_info(log_get_cat_http(), "Stopping HTTP engine");
/* Stop all the workers */
pthread_mutex_lock(&g_http_engine->lock);
if (g_http_engine->workers_running) {
for (i = 0; i < g_http_engine->total_workers; i++) {
if(g_http_engine->workers[i].worker &&
g_http_engine->workers[i].user_event) {
event_active(g_http_engine->workers[i].user_event,
EV_READ|EV_WRITE, 1);
}
}
}
pthread_mutex_unlock(&g_http_engine->lock);
/* Wait here for the threads to stop */
http_engine_wait_for_completion();
/* Save the test results */
http_engine_save_test_results();
}
/* Loop evbase */
int evepoll_loop(EVBASE *evbase, int loop_flags, struct timeval *tv)
{
int i = 0, n = 0, timeout = -1, flags = 0, ev_flags = 0, fd = 0, event = 0;
struct epoll_event *evp = NULL;
EVENT *ev = NULL;
if(evbase)
{
if(tv)
{
timeout = tv->tv_sec * 1000 + (tv->tv_usec + 999) / 1000;
}
//memset(evbase->evs, 0, sizeof(struct epoll_event) * evbase->allowed);
n = epoll_wait(evbase->efd, (struct epoll_event *)(evbase->evs), evbase->allowed, timeout);
//n = epoll_wait(evbase->efd, (struct epoll_event *)evbase->evs, evbase->maxfd+1, timeout);
if(n <= 0)
{
if(n < 0){fprintf(stderr, "epoll_wait(%d, %p, %d, %d) failed, %s\n", evbase->efd, evbase->evs, evbase->maxfd, timeout, strerror(errno));}
return n;
}
//WARN_LOG("loop()=> %d", n);
for(i = 0; i < n; i++)
{
evp = &(((struct epoll_event *)evbase->evs)[i]);
ev = (EVENT *)evp->data.ptr;
if(ev == NULL) continue;
fd = ev->ev_fd;
flags = evp->events;
//fd = evp->data.fd;
if(fd >= 0 && fd < evbase->allowed && evbase->evlist[fd] && ev == evbase->evlist[fd])
{
ev_flags = 0;
if(flags & (EPOLLHUP|EPOLLERR))
{
ev_flags = E_READ|E_WRITE;
}
else
{
if(flags & EPOLLIN) ev_flags |= E_READ;
if(flags & EPOLLOUT) ev_flags |= E_WRITE;
}
//event = (ev_flags & ev->ev_flags);
//if((ev_flags &= ev->ev_flags))
if(ev_flags)
{
event_active(ev, ev_flags);
}
else
{
WARN_LOGGER(evbase->logger, "ev:%p fd:%d evflags:%d event:%d", ev, fd, ev->ev_flags, ev_flags);
//evepoll_update(evbase, ev);
}
}
}
//WARN_LOG("over_loop()=> %d", n);
}
return n;
}
static int
kq_dispatch(struct event_base *base, void *arg, struct timeval *tv)
{
struct kqop *kqop = arg;
struct kevent *changes = kqop->changes;
struct kevent *events = kqop->events;
struct event *ev;
struct timespec ts, *ts_p = NULL;
int i, res;
if (tv != NULL) {
TIMEVAL_TO_TIMESPEC(tv, &ts);
ts_p = &ts;
}
res = kevent(kqop->kq, changes, kqop->nchanges,
events, kqop->nevents, ts_p);
kqop->nchanges = 0;
if (res == -1) {
if (errno != EINTR) {
event_warn("kevent");
return (-1);
}
return (0);
}
event_debug(("%s: kevent reports %d", __func__, res));
for (i = 0; i < res; i++) {
int which = 0;
if (events[i].flags & EV_ERROR) {
if (events[i].data == EBADF ||
events[i].data == EINVAL ||
events[i].data == ENOENT)
continue;
errno = events[i].data;
return (-1);
}
if (events[i].filter == EVFILT_READ) {
which |= EV_READ;
} else if (events[i].filter == EVFILT_WRITE) {
which |= EV_WRITE;
} else if (events[i].filter == EVFILT_SIGNAL) {
which |= EV_SIGNAL;
}
if (!which)
continue;
if (events[i].filter == EVFILT_SIGNAL) {
struct event_list *head =
(struct event_list *)events[i].udata;
TAILQ_FOREACH(ev, head, ev_signal_next) {
event_active(ev, which, events[i].data);
}
} else {
GithubWebhooks::~GithubWebhooks()
{
if (_breakLoop)
event_active(_breakLoop, EV_READ, 0);
_httpServer.join();
if (_evhttp)
evhttp_free(_evhttp);
}
static void
levent_init(struct lldpd *cfg)
{
/* Setup libevent */
log_debug("event", "initialize libevent");
event_set_log_callback(levent_log_cb);
if (!(cfg->g_base = event_base_new()))
fatalx("unable to create a new libevent base");
log_info("event", "libevent %s initialized with %s method",
event_get_version(),
event_base_get_method(cfg->g_base));
/* Setup SNMP */
#ifdef USE_SNMP
if (cfg->g_snmp) {
agent_init(cfg, cfg->g_snmp_agentx);
cfg->g_snmp_timeout = evtimer_new(cfg->g_base,
levent_snmp_timeout,
cfg);
if (!cfg->g_snmp_timeout)
fatalx("unable to setup timeout function for SNMP");
if ((cfg->g_snmp_fds =
malloc(sizeof(struct ev_l))) == NULL)
fatalx("unable to allocate memory for SNMP events");
TAILQ_INIT(levent_snmp_fds(cfg));
}
#endif
/* Setup loop that will run every X seconds. */
log_debug("event", "register loop timer");
if (!(cfg->g_main_loop = event_new(cfg->g_base, -1, 0,
levent_update_and_send,
cfg)))
fatalx("unable to setup main timer");
event_active(cfg->g_main_loop, EV_TIMEOUT, 1);
/* Setup unix socket */
log_debug("event", "register Unix socket");
TAILQ_INIT(&lldpd_clients);
evutil_make_socket_nonblocking(cfg->g_ctl);
if ((cfg->g_ctl_event = event_new(cfg->g_base, cfg->g_ctl,
EV_READ|EV_PERSIST, levent_ctl_accept, cfg)) == NULL)
fatalx("unable to setup control socket event");
event_add(cfg->g_ctl_event, NULL);
/* Signals */
log_debug("event", "register signals");
signal(SIGHUP, SIG_IGN);
evsignal_add(evsignal_new(cfg->g_base, SIGUSR1,
levent_dump, cfg->g_base),
NULL);
evsignal_add(evsignal_new(cfg->g_base, SIGINT,
levent_stop, cfg->g_base),
NULL);
evsignal_add(evsignal_new(cfg->g_base, SIGTERM,
levent_stop, cfg->g_base),
NULL);
}
static THREAD_FN
register_events_subthread(void *arg)
{
struct timeval tv = {0,0};
SLEEP_MS(100);
event_active(&time_events[0], EV_TIMEOUT, 1);
SLEEP_MS(100);
event_active(&time_events[1], EV_TIMEOUT, 1);
SLEEP_MS(100);
tv.tv_usec = 100*1000;
event_add(&time_events[2], &tv);
tv.tv_usec = 150*1000;
event_add(&time_events[3], &tv);
SLEEP_MS(200);
event_active(&time_events[4], EV_TIMEOUT, 1);
THREAD_RETURN();
}
void core::curl_handler::add_task(priority_t _priority, milliseconds_t _timeout, CURL* _handle, const completion_handler_t& _completion_handler)
{
{
boost::lock_guard<boost::mutex> lock(jobs_mutex_);
pending_jobs_.emplace(_priority, _timeout, _handle, _completion_handler);
}
event_active(start_task_event_, 0, 0);
}
int main(int argc, char **argv) {
base = event_base_new();
//ev = event_new(base, -1, EV_PERSIST|EV_READ, cb, NULL);
ev = event_new(base, -1, EV_PERSIST|EV_READ, cb, NULL);
ev2= event_new(base, -1, EV_PERSIST|EV_READ, cb2, NULL);
event_add(ev, NULL);
event_add(ev2, NULL);
//event_active(ev, EV_WRITE, 0);
event_active(ev, 0, 0);
event_base_dispatch(base);
return 0;
}
static int msgpack_write(void *data, const char *buf, unsigned int len)
{
struct tmate_encoder *encoder = data;
evbuffer_add(encoder->buffer, buf, len);
if ((encoder->ev_readable.ev_flags & EVLIST_INSERTED) &&
!(encoder->ev_readable.ev_flags & EVLIST_ACTIVE)) {
event_active(&encoder->ev_readable, EV_READ, 0);
}
return 0;
}
static void
test_fin_within_cb(void *arg)
{
struct basic_test_data *data = arg;
struct event_base *base = data->base;
struct event_and_count evc1, evc2;
evc1.count = evc2.count = 0;
evc2.ev2 = evc1.ev = evtimer_new(base, timer_callback_2, &evc1);
evc1.ev2 = evc2.ev = evtimer_new(base, timer_callback_2, &evc2);
/* Activate both. The first one will have its callback run, which
* will finalize both of them, preventing the second one's callback
* from running. */
event_active(evc1.ev, EV_TIMEOUT, 1);
event_active(evc2.ev, EV_TIMEOUT, 1);
event_base_dispatch(base);
tt_int_op(evc1.count, ==, 101);
tt_int_op(evc2.count, ==, 100);
event_base_assert_ok_(base);
/* Now try with EV_PERSIST events. */
evc1.count = evc2.count = 0;
evc2.ev2 = evc1.ev = event_new(base, -1, EV_PERSIST, timer_callback_2, &evc1);
evc1.ev2 = evc2.ev = event_new(base, -1, EV_PERSIST, timer_callback_2, &evc2);
event_active(evc1.ev, EV_TIMEOUT, 1);
event_active(evc2.ev, EV_TIMEOUT, 1);
event_base_dispatch(base);
tt_int_op(evc1.count, ==, 101);
tt_int_op(evc2.count, ==, 100);
event_base_assert_ok_(base);
end:
;
}
void
read_cb(evutil_socket_t fd, short evtype, void *arg) {
printf("read_cb\n");
char buf[1024];
int ret = read(fd, buf, 1024);
buf[ret] = '\0';
printf("read == %s\n", buf);
/* test event_active and event_pending function. */
if(event_pending(evw, EV_WRITE, NULL) == 0) {
printf("evw being pending, make it active now.\n");
event_active(evw, EV_WRITE, 1); /* no matter the event is pending nor non-pending. */
}
}
static int on_encoder_write(void *userdata, const char *buf, size_t len)
{
struct tmate_encoder *encoder = userdata;
if (evbuffer_add(encoder->buffer, buf, len) < 0)
tmate_fatal("Cannot buffer encoded data");
if (!encoder->ev_active) {
event_active(&encoder->ev_buffer, EV_READ, 0);
encoder->ev_active = true;
}
return 0;
}
static int s1_fencenb(opal_list_t *procs, int collect_data,
opal_pmix_op_cbfunc_t cbfunc, void *cbdata)
{
pmi_opcaddy_t *op;
/* thread-shift this so we don't block in SLURM's barrier */
op = OBJ_NEW(pmi_opcaddy_t);
op->opcbfunc = cbfunc;
op->cbdata = cbdata;
event_assign(&op->ev, opal_pmix_base.evbase, -1,
EV_WRITE, fencenb, op);
event_active(&op->ev, EV_WRITE, 1);
return OPAL_SUCCESS;
}
/* Loop evbase */
int evselect_loop(EVBASE *evbase, short loop_flag, struct timeval *tv)
{
int i = 0, n = 0;
short ev_flags = 0;
fd_set rd_fd_set, wr_fd_set ;
EVENT *ev = NULL;
struct timeval timeout = {0};
//if(evbase && evbase->nfd > 0)
if(evbase)
{
FD_ZERO(&rd_fd_set);
memcpy(&rd_fd_set, evbase->ev_read_fds, sizeof(fd_set));
FD_ZERO(&wr_fd_set);
memcpy(&wr_fd_set, evbase->ev_write_fds, sizeof(fd_set));
if(tv == NULL)
{
timeout.tv_sec = 0;
timeout.tv_usec = 1000;
tv = &timeout;
}
n = select(evbase->allowed, &rd_fd_set, &wr_fd_set, NULL, tv);
//fprintf(stdout, "%s::%d n:%d\n", __FILE__, __LINE__, n);
if(n <= 0) return n;
DEBUG_LOGGER(evbase->logger, "Actived %d event in %d", n, evbase->allowed);
for(i = 0; i < evbase->allowed; ++i)
{
if((ev = evbase->evlist[i]))
{
ev_flags = 0;
if(FD_ISSET(i, &rd_fd_set))
{
ev_flags |= E_READ;
}
if(FD_ISSET(i, &wr_fd_set))
{
ev_flags |= E_WRITE;
}
if(ev_flags == 0) continue;
if((ev_flags &= ev->ev_flags))
{
event_active(ev, ev_flags);
}
}
}
}
return n;
}
// retrieve file buffer from local storage
// if success == TRUE then "buf" contains "size" bytes of data
void cache_mng_retrieve_file_buf (CacheMng *cmng, fuse_ino_t ino, size_t size, off_t off,
cache_mng_on_retrieve_file_buf_cb on_retrieve_file_buf_cb, void *ctx)
{
struct _CacheContext *context;
struct _CacheEntry *entry;
context = cache_context_create (size, ctx);
context->cb.retrieve_cb = on_retrieve_file_buf_cb;
entry = g_hash_table_lookup (cmng->h_entries, GUINT_TO_POINTER (ino));
if (entry && range_contain (entry->avail_range, off, off + size)) {
int fd;
ssize_t res;
char path[PATH_MAX];
if (ino != entry->ino) {
LOG_err (CMNG_LOG, "Requested inode doesn't match hashed key!");
if (context->cb.retrieve_cb)
context->cb.retrieve_cb (NULL, 0, FALSE, context->user_ctx);
cache_context_destroy (context);
return;
}
cache_mng_file_name (cmng, path, sizeof (path), ino);
fd = open (path, O_RDONLY);
context->buf = g_malloc (size);
res = pread (fd, context->buf, size, off);
close (fd);
context->success = (res == (ssize_t) size);
if (!context->success) {
g_free (context->buf);
context->buf = NULL;
}
// move entry to the front of q_lru
g_queue_unlink (cmng->q_lru, entry->ll_lru);
g_queue_push_head_link (cmng->q_lru, entry->ll_lru);
} else {
LOG_debug (CMNG_LOG, "Entry isn't found or doesn't contain requested range: %"INO_FMT, INO ino);
}
context->ev = event_new (application_get_evbase (cmng->app), -1, 0,
cache_read_cb, context);
// fire this event at once
event_active (context->ev, 0, 0);
event_add (context->ev, NULL);
}
int async_file::writev(const struct iovec *iov, int iovcnt)
{
AmLock _l(*this);
if(closed) return Closed;
if(error) return Error;
int ret = fifo_buffer::writev(iov,iovcnt);
if(fifo_buffer::get_buffered_bytes() >= write_thresh) {
event_active(ev_write, 0, 0);
}
if(ret < 0) return BufferFull;
return ret;
}
int async_file::write(const void* buf, unsigned int len)
{
AmLock _l(*this);
if(closed) return Closed;
if(error) return Error;
int ret = fifo_buffer::write(buf,len);
if(fifo_buffer::get_buffered_bytes() >= write_thresh) {
event_active(ev_write, 0, 0);
}
if(ret < 0) return BufferFull;
return ret;
}
int
main(int argc, char **argv)
{
struct event ev;
struct event *t1;
event_enable_debug_mode();
fprintf(stderr, "Libevent %s\n", event_get_version());
fflush(stderr);
if (!(base = event_base_new()))
die("event_base_new");
if (event_base_priority_init(base, 8) < 0)
die("event_base_priority_init");
if (event_assign(&ev, base, SIGTERM, EV_SIGNAL|EV_PERSIST, cbfunc, NULL)<0)
die("event_assign");
if (event_priority_set(&ev, SIGPRI) < 0)
die("event_priority_set");
if (event_add(&ev, NULL) < 0)
die("event_add");
fprintf(stderr, "SIGNAL EVENT DEFINED\n");
fflush(stderr);
t1 = (struct event*)malloc(sizeof(struct event));
if (event_assign(t1, base, -1, EV_WRITE, t1func, t1) < 0) {
die("event_assign_term");
}
if (event_priority_set(t1, TERMPRI) < 0) {
die("event_priority_set_term");
}
event_active(t1, EV_WRITE, 1);
fprintf(stderr, "FIRST TERMINATION EVENT DEFINED\n");
fflush(stderr);
/* event_dispatch(base); */
while (run) {
event_base_loop(base, EVLOOP_ONCE);
}
fprintf(stderr, "EXITED LOOP - FREEING BASE\n");
fflush(stderr);
event_base_free(base);
return 0;
}
static void chassis_event_thread_update_conn_status(chassis_event_thread_t *thread)
{
network_mysqld_con *conn = NULL;
GList *gl_conn = NULL;
network_mysqld_con_lua_t *st = NULL;
g_assert(thread != NULL);
gl_conn = thread->connection_list;
while (gl_conn) {
conn = gl_conn->data;
st = conn->plugin_con_state;
if (chassis_is_shutdown_normal() &&
g_atomic_int_get(&conn->conn_status.exit_phase) != CON_EXIT_TX) {
g_atomic_int_set(&conn->conn_status.exit_begin_time, time(NULL));
g_atomic_int_set(&conn->conn_status.exit_phase, CON_EXIT_TX);
}
if (g_atomic_int_get(&conn->conn_status.exit_phase) == CON_EXIT_KILL ||
g_atomic_int_get(&conn->conn_status.exit_phase) == CON_EXIT_TX) {
/*|| (st != NULL && st->backend != NULL && IS_BACKEND_WAITING_EXIT(st->backend)))*/
struct event *ev = NULL;
gchar *event_msg = NULL;
int pending = event_pending(&conn->client->event, EV_READ|EV_WRITE|EV_TIMEOUT, NULL);
if (pending) {
ev = &conn->client->event;
event_msg = "client";
} else {
pending = event_pending(&conn->server->event, EV_READ|EV_WRITE|EV_TIMEOUT, NULL);
ev = &conn->server->event;
event_msg = "server";
}
if (pending != 0) {
/*
* 1 stands for the times of calling callback function after manual active event,
* this parameter has been obsoleted at libevent-2.0.
*/
g_log_dbproxy(g_debug, "pending %s's %d event", event_msg, pending);
event_active(ev, pending, 1);
}
}
gl_conn = g_list_next(gl_conn);
}
}
