/* * BIRD -- I/O and event loop * * Can be freely distributed and used under the terms of the GNU GPL. */ #include #include #include #include #include #include #include #include #include #include "nest/bird.h" #include "lib/buffer.h" #include "lib/lists.h" #include "lib/locking.h" #include "lib/resource.h" #include "lib/event.h" #include "lib/timer.h" #include "lib/socket.h" #include "lib/io-loop.h" #include "sysdep/unix/io-loop.h" #include "conf/conf.h" #include "nest/cli.h" #define THREAD_STACK_SIZE 65536 /* To be lowered in near future */ static struct birdloop *birdloop_new_no_pickup(pool *pp, uint order, const char *name, ...); /* * Nanosecond time for accounting purposes * * A fixed point on startup is set as zero, all other values are relative to that. * Caution: this overflows after like 500 years or so. If you plan to run * BIRD for such a long time, please implement some means of overflow prevention. */ static struct timespec ns_begin; static void ns_init(void) { if (clock_gettime(CLOCK_MONOTONIC, &ns_begin)) bug("clock_gettime: %m"); } #define NSEC_IN_SEC ((u64) (1000 * 1000 * 1000)) static u64 ns_now(void) { struct timespec ts; if (clock_gettime(CLOCK_MONOTONIC, &ts)) bug("clock_gettime: %m"); return (u64) (ts.tv_sec - ns_begin.tv_sec) * NSEC_IN_SEC + ts.tv_nsec - ns_begin.tv_nsec; } #define NSEC_TO_SEC(x) ((x) / NSEC_IN_SEC) #define CURRENT_SEC NSEC_TO_SEC(ns_now()) static _Thread_local struct spent_time *account_target_spent_time; static _Thread_local u64 *account_target_total; static _Thread_local u64 account_last; static u64 account_finish(void) { /* Get current time */ u64 now = ns_now(); u64 dif = now - account_last; /* Update second by second */ if (account_target_spent_time) { /* Drop old time information if difference is too large */ if (NSEC_TO_SEC(account_last) + TIME_BY_SEC_SIZE - 1 < NSEC_TO_SEC(now)) account_last = (NSEC_TO_SEC(now) - TIME_BY_SEC_SIZE + 1) * NSEC_IN_SEC; /* Zero new records */ if (NSEC_TO_SEC(account_target_spent_time->last_written_ns) + TIME_BY_SEC_SIZE < NSEC_TO_SEC(account_last)) memset(account_target_spent_time->by_sec_ns, 0, sizeof(account_target_spent_time->by_sec_ns)); else for (u64 fclr = NSEC_TO_SEC(account_target_spent_time->last_written_ns) + 1; fclr <= NSEC_TO_SEC(now); fclr++) account_target_spent_time->by_sec_ns[fclr % TIME_BY_SEC_SIZE] = 0; /* Add times second by second */ while (NSEC_TO_SEC(account_last) != NSEC_TO_SEC(now)) { u64 part = (NSEC_TO_SEC(account_last) + 1) * NSEC_IN_SEC - account_last; account_target_spent_time->by_sec_ns[NSEC_TO_SEC(account_last) % TIME_BY_SEC_SIZE] += part; account_last += part; } /* Update the last second */ account_target_spent_time->by_sec_ns[NSEC_TO_SEC(account_last) % TIME_BY_SEC_SIZE] += now - account_last; /* Store the current time */ account_target_spent_time->last_written_ns = now; } /* Update the total */ if (account_target_total) *account_target_total += dif; /* Store current time */ account_last = now; return dif; } static u64 account_to_spent_time(struct spent_time *st) { u64 elapsed = account_finish(); account_target_spent_time = st; account_target_total = &st->total_ns; return elapsed; } static u64 account_to_total(u64 *total) { u64 elapsed = account_finish(); account_target_spent_time = NULL; account_target_total = total; return elapsed; } #define account_to(_arg) _Generic((_arg), \ struct spent_time *: account_to_spent_time, \ u64 *: account_to_total)(_arg) /* * Current thread context */ _Thread_local struct birdloop *birdloop_current; static _Thread_local struct birdloop *birdloop_wakeup_masked; static _Thread_local uint birdloop_wakeup_masked_count; #define LOOP_NAME(loop) domain_name((loop)->time.domain) #define LOOP_TRACE(loop, fmt, args...) do { if (config && config->latency_debug) log(L_TRACE "%s (%p): " fmt, LOOP_NAME(loop), (loop), ##args); } while (0) #define THREAD_TRACE(...) do { if (config && config->latency_debug) log(L_TRACE "Thread: " __VA_ARGS__); } while (0) #define LOOP_WARN(loop, fmt, args...) log(L_TRACE "%s (%p): " fmt, LOOP_NAME(loop), (loop), ##args) event_list * birdloop_event_list(struct birdloop *loop) { return &loop->event_list; } struct timeloop * birdloop_time_loop(struct birdloop *loop) { return &loop->time; } pool * birdloop_pool(struct birdloop *loop) { return loop->pool; } _Bool birdloop_inside(struct birdloop *loop) { for (struct birdloop *c = birdloop_current; c; c = c->prev_loop) if (loop == c) return 1; return 0; } _Bool birdloop_in_this_thread(struct birdloop *loop) { return pthread_equal(pthread_self(), loop->thread->thread_id); } void birdloop_flag(struct birdloop *loop, u32 flag) { atomic_fetch_or_explicit(&loop->flags, flag, memory_order_acq_rel); birdloop_ping(loop); } void birdloop_flag_set_handler(struct birdloop *loop, struct birdloop_flag_handler *fh) { ASSERT_DIE(birdloop_inside(loop)); loop->flag_handler = fh; } static int birdloop_process_flags(struct birdloop *loop) { if (!loop->flag_handler) return 0; u32 flags = atomic_exchange_explicit(&loop->flags, 0, memory_order_acq_rel); if (!flags) return 0; loop->flag_handler->hook(loop->flag_handler, flags); return 1; } /* * Wakeup code for birdloop */ void pipe_new(struct pipe *p) { int rv = pipe(p->fd); if (rv < 0) die("pipe: %m"); if (fcntl(p->fd[0], F_SETFL, O_NONBLOCK) < 0) die("fcntl(O_NONBLOCK): %m"); if (fcntl(p->fd[1], F_SETFL, O_NONBLOCK) < 0) die("fcntl(O_NONBLOCK): %m"); } void pipe_drain(struct pipe *p) { while (1) { char buf[64]; int rv = read(p->fd[0], buf, sizeof(buf)); if ((rv < 0) && (errno == EAGAIN)) return; if (rv == 0) bug("wakeup read eof"); if ((rv < 0) && (errno != EINTR)) bug("wakeup read: %m"); } } int pipe_read_one(struct pipe *p) { while (1) { char v; int rv = read(p->fd[0], &v, sizeof(v)); if (rv == 1) return 1; if ((rv < 0) && (errno == EAGAIN)) return 0; if (rv > 1) bug("wakeup read more bytes than expected: %d", rv); if (rv == 0) bug("wakeup read eof"); if (errno != EINTR) bug("wakeup read: %m"); } } void pipe_kick(struct pipe *p) { char v = 1; int rv; while (1) { rv = write(p->fd[1], &v, sizeof(v)); if ((rv >= 0) || (errno == EAGAIN)) return; if (errno != EINTR) bug("wakeup write: %m"); } } void pipe_pollin(struct pipe *p, struct pfd *pfd) { BUFFER_PUSH(pfd->pfd) = (struct pollfd) { .fd = p->fd[0], .events = POLLIN, }; BUFFER_PUSH(pfd->loop) = NULL; } void pipe_free(struct pipe *p) { close(p->fd[0]); close(p->fd[1]); } static inline void wakeup_init(struct bird_thread *loop) { pipe_new(&loop->wakeup); } static inline void wakeup_drain(struct bird_thread *loop) { pipe_drain(&loop->wakeup); } static inline void wakeup_do_kick(struct bird_thread *loop) { pipe_kick(&loop->wakeup); } static inline void wakeup_free(struct bird_thread *loop) { pipe_free(&loop->wakeup); } static inline _Bool birdloop_try_ping(struct birdloop *loop, u32 ltt) { /* Somebody else is already pinging, be idempotent */ if (ltt & LTT_PING) { LOOP_TRACE(loop, "already being pinged"); return 0; } /* Thread moving is an implicit ping */ if (ltt & LTT_MOVE) { LOOP_TRACE(loop, "ping while moving"); return 1; } /* No more flags allowed */ ASSERT_DIE(!ltt); /* No ping when not picked up */ if (!loop->thread) { LOOP_TRACE(loop, "not picked up yet, can't ping"); return 1; } /* No ping when masked */ if (loop == birdloop_wakeup_masked) { LOOP_TRACE(loop, "wakeup masked, can't ping"); birdloop_wakeup_masked_count++; return 1; } /* Send meta event to ping */ if ((loop != loop->thread->meta) && (loop != &main_birdloop)) { LOOP_TRACE(loop, "Ping by meta event to %p", loop->thread->meta); ev_send_loop(loop->thread->meta, &loop->event); return 1; } /* Do the real ping of Meta or Main */ LOOP_TRACE(loop, "sending pipe ping"); wakeup_do_kick(loop->thread); return 0; } static inline void birdloop_do_ping(struct birdloop *loop) { /* Register our ping effort */ u32 ltt = atomic_fetch_or_explicit(&loop->thread_transition, LTT_PING, memory_order_acq_rel); /* Try to ping in multiple ways */ if (birdloop_try_ping(loop, ltt)) atomic_fetch_and_explicit(&loop->thread_transition, ~LTT_PING, memory_order_acq_rel); } void birdloop_ping(struct birdloop *loop) { if (!birdloop_inside(loop)) { LOOP_TRACE(loop, "ping from outside"); birdloop_do_ping(loop); } else { LOOP_TRACE(loop, "ping from inside, pending=%d", loop->ping_pending); if (!loop->ping_pending) loop->ping_pending++; } } /* * Sockets */ static void sockets_init(struct birdloop *loop) { init_list(&loop->sock_list); loop->sock_num = 0; } void socket_changed(sock *s) { struct birdloop *loop = s->loop; ASSERT_DIE(birdloop_inside(loop)); loop->sock_changed = 1; birdloop_ping(loop); } void birdloop_add_socket(struct birdloop *loop, sock *s) { ASSERT_DIE(birdloop_inside(loop)); ASSERT_DIE(!s->loop); LOOP_TRACE(loop, "adding socket %p (total=%d)", s, loop->sock_num); add_tail(&loop->sock_list, &s->n); loop->sock_num++; s->loop = loop; s->index = -1; socket_changed(s); } extern sock *stored_sock; /* mainloop hack */ void birdloop_remove_socket(struct birdloop *loop, sock *s) { ASSERT_DIE(!enlisted(&s->n) == !s->loop); if (!s->loop) return; ASSERT_DIE(birdloop_inside(loop)); ASSERT_DIE(s->loop == loop); /* Decouple the socket from the loop at all. */ LOOP_TRACE(loop, "removing socket %p (total=%d)", s, loop->sock_num); if (loop->sock_active == s) loop->sock_active = sk_next(s); if ((loop == &main_birdloop) && (s == stored_sock)) stored_sock = sk_next(s); rem_node(&s->n); loop->sock_num--; socket_changed(s); s->loop = NULL; s->index = -1; } void sk_reloop(sock *s, struct birdloop *loop) { ASSERT_DIE(birdloop_inside(loop)); ASSERT_DIE(birdloop_inside(s->loop)); if (loop == s->loop) return; birdloop_remove_socket(s->loop, s); birdloop_add_socket(loop, s); } void sk_pause_rx(struct birdloop *loop, sock *s) { ASSERT_DIE(birdloop_inside(loop)); s->rx_hook = NULL; socket_changed(s); } void sk_resume_rx(struct birdloop *loop, sock *s, int (*hook)(sock *, uint)) { ASSERT_DIE(birdloop_inside(loop)); ASSERT_DIE(hook); s->rx_hook = hook; socket_changed(s); } static inline uint sk_want_events(sock *s) { return (s->rx_hook ? POLLIN : 0) | (sk_tx_pending(s) ? POLLOUT : 0); } void sockets_prepare(struct birdloop *loop, struct pfd *pfd) { node *n; WALK_LIST(n, loop->sock_list) { sock *s = SKIP_BACK(sock, n, n); uint w = sk_want_events(s); if (!w) { s->index = -1; continue; } s->index = pfd->pfd.used; LOOP_TRACE(loop, "socket %p poll index is %d", s, s->index); BUFFER_PUSH(pfd->pfd) = (struct pollfd) { .fd = s->fd, .events = sk_want_events(s), }; BUFFER_PUSH(pfd->loop) = loop; } } int sk_read(sock *s, int revents); int sk_write(sock *s); void sk_err(sock *s, int revents); static int sockets_fire(struct birdloop *loop) { if (EMPTY_LIST(loop->sock_list)) return 0; int repeat = 0; times_update(); struct pollfd *pfd = loop->thread->pfd->pfd.data; loop->sock_active = SKIP_BACK(sock, n, HEAD(loop->sock_list)); while (loop->sock_active) { sock *s = loop->sock_active; int rev; if ((s->index >= 0) && (rev = pfd[s->index].revents) && !(rev & POLLNVAL)) { int e = 1; if (rev & POLLOUT) { /* Write everything. */ while ((s == loop->sock_active) && (e = sk_write(s))) ; if (s != loop->sock_active) continue; if (!sk_tx_pending(s)) loop->thread->sock_changed = 1; } if (rev & POLLIN) /* Read just one packet and request repeat. */ if ((s == loop->sock_active) && s->rx_hook) if (sk_read(s, rev)) repeat++; if (s != loop->sock_active) continue; if (!(rev & (POLLOUT | POLLIN)) && (rev & POLLERR)) sk_err(s, rev); if (s != loop->sock_active) continue; } loop->sock_active = sk_next(s); } return repeat; } /* * Threads */ DEFINE_DOMAIN(attrs); static void bird_thread_start_event(void *_data); struct birdloop_pickup_group { DOMAIN(attrs) domain; list loops; list threads; uint thread_count; uint thread_busy_count; uint loop_count; uint loop_unassigned_count; btime max_latency; event start_threads; } pickup_groups[2] = { { /* all zeroes */ }, { /* FIXME: make this dynamic, now it copies the loop_max_latency value from proto/bfd/config.Y */ .max_latency = 10 MS, .start_threads.hook = bird_thread_start_event, .start_threads.data = &pickup_groups[1], }, }; static _Thread_local struct bird_thread *this_thread; static void birdloop_set_thread(struct birdloop *loop, struct bird_thread *thr, struct birdloop_pickup_group *group) { struct bird_thread *old = loop->thread; ASSERT_DIE(!thr != !old); /* Signal our moving effort */ u32 ltt = atomic_fetch_or_explicit(&loop->thread_transition, LTT_MOVE, memory_order_acq_rel); ASSERT_DIE((ltt & LTT_MOVE) == 0); /* Wait until all previously started pings end */ while (ltt & LTT_PING) { birdloop_yield(); ltt = atomic_load_explicit(&loop->thread_transition, memory_order_acquire); ASSERT_DIE(ltt & LTT_MOVE); } /* Now we are free of running pings */ if (!thr) { /* Unschedule from Meta */ ev_postpone(&loop->event); tm_stop(&loop->timer); /* Request local socket reload */ this_thread->sock_changed = 1; } /* Update the thread value */ loop->thread = thr; /* Allow pings */ atomic_fetch_and_explicit(&loop->thread_transition, ~LTT_MOVE, memory_order_acq_rel); /* Put into appropriate lists */ if (thr) { thr->loop_count++; add_tail(&thr->loops, &loop->n); if (!EMPTY_LIST(loop->sock_list)) thr->sock_changed = 1; ev_send_loop(loop->thread->meta, &loop->event); } else { /* Put into pickup list */ LOCK_DOMAIN(attrs, group->domain); add_tail(&group->loops, &loop->n); group->loop_unassigned_count++; UNLOCK_DOMAIN(attrs, group->domain); } } static void bird_thread_pickup_next(struct birdloop_pickup_group *group) { /* This thread goes to the end of the pickup list */ rem_node(&this_thread->n); add_tail(&group->threads, &this_thread->n); /* If there are more loops to be picked up, wakeup the next thread in order */ if (!EMPTY_LIST(group->loops)) wakeup_do_kick(SKIP_BACK(struct bird_thread, n, HEAD(group->threads))); } static void birdloop_take(struct birdloop_pickup_group *group) { struct birdloop *loop = NULL; LOCK_DOMAIN(attrs, group->domain); int drop = this_thread->busy_active && (group->thread_busy_count < group->thread_count) && (this_thread->loop_count > 1); int take = !EMPTY_LIST(group->loops); if (drop) { UNLOCK_DOMAIN(attrs, group->domain); node *n; WALK_LIST2(loop, n, this_thread->loops, n) { birdloop_enter(loop); if (ev_active(&loop->event)) { LOOP_TRACE(loop, "Moving to another thread"); /* Pass to another thread */ rem_node(&loop->n); this_thread->loop_count--; /* This also unschedules the loop from Meta */ birdloop_set_thread(loop, NULL, group); birdloop_leave(loop); LOCK_DOMAIN(attrs, group->domain); bird_thread_pickup_next(group); UNLOCK_DOMAIN(attrs, group->domain); break; } birdloop_leave(loop); } return; } if (take) { /* Take a proportional amount of loops from the pickup list and unlock */ uint thread_count = group->thread_count + 1; if (group->thread_busy_count < group->thread_count) thread_count -= group->thread_busy_count; uint assign = 1 + group->loop_unassigned_count / thread_count; for (uint i=0; !EMPTY_LIST(group->loops) && iloops)); rem_node(&loop->n); group->loop_unassigned_count--; UNLOCK_DOMAIN(attrs, group->domain); birdloop_enter(loop); birdloop_set_thread(loop, this_thread, group); node *n; WALK_LIST(n, loop->sock_list) SKIP_BACK(sock, n, n)->index = -1; birdloop_leave(loop); LOCK_DOMAIN(attrs, group->domain); } bird_thread_pickup_next(group); } UNLOCK_DOMAIN(attrs, group->domain); } static int poll_timeout(struct birdloop *loop) { timer *t = timers_first(&loop->time); if (!t) return -1; btime remains = tm_remains(t); return remains TO_MS + ((remains TO_MS) MS < remains); } static void bird_thread_busy_set(struct bird_thread *thr, int val) { LOCK_DOMAIN(attrs, thr->group->domain); if (thr->busy_active = val) thr->group->thread_busy_count++; else thr->group->thread_busy_count--; ASSERT_DIE(thr->group->thread_busy_count <= thr->group->thread_count); UNLOCK_DOMAIN(attrs, thr->group->domain); } static void bird_thread_busy_update(struct bird_thread *thr, int timeout_ms) { int idle_force = (timeout_ms < 0); int val = (timeout_ms < 5) && !idle_force; if (val == thr->busy_active) return; if (val && (++thr->busy_counter == 4)) return bird_thread_busy_set(thr, 1); if (!val && (idle_force || (--thr->busy_counter == 0))) { thr->busy_counter = 0; bird_thread_busy_set(thr, 0); } } static void * bird_thread_main(void *arg) { struct bird_thread *thr = this_thread = arg; rcu_thread_start(&thr->rcu); synchronize_rcu(); account_to(&thr->overhead); birdloop_enter(thr->meta); tmp_init(thr->pool, birdloop_domain(thr->meta)); init_list(&thr->loops); thr->sock_changed = 1; struct pfd pfd; BUFFER_INIT(pfd.pfd, thr->pool, 16); BUFFER_INIT(pfd.loop, thr->pool, 16); thr->pfd = &pfd; while (1) { u64 thr_loop_start = ns_now(); int timeout; /* Pickup new loops */ birdloop_take(thr->group); /* Schedule all loops with timed out timers */ timers_fire(&thr->meta->time, 0); /* Compute maximal time per loop */ u64 thr_before_run = ns_now(); if (thr->loop_count > 0) thr->max_loop_time_ns = (thr->max_latency_ns / 2 - (thr_before_run - thr_loop_start)) / (u64) thr->loop_count; /* Run all scheduled loops */ int more_events = ev_run_list(&thr->meta->event_list); if (more_events) { THREAD_TRACE("More events to run"); timeout = 0; } else { timeout = poll_timeout(thr->meta); if (timeout == -1) THREAD_TRACE("No timers, no events"); else THREAD_TRACE("Next timer in %d ms", timeout); } /* Run priority events before sleeping */ ev_run_list(&thr->priority_events); /* Do we have to refresh sockets? */ if (thr->sock_changed) { thr->sock_changed = 0; BUFFER_FLUSH(pfd.pfd); BUFFER_FLUSH(pfd.loop); pipe_pollin(&thr->wakeup, &pfd); node *nn; struct birdloop *loop; WALK_LIST2(loop, nn, thr->loops, n) { birdloop_enter(loop); sockets_prepare(loop, &pfd); birdloop_leave(loop); } ASSERT_DIE(pfd.loop.used == pfd.pfd.used); } /* Nothing to do in at least 5 seconds, flush local hot page cache */ else if ((timeout > 5000) && (timeout < 0)) flush_local_pages(); bird_thread_busy_update(thr, timeout); account_to(&this_thread->idle); poll_retry:; int rv = poll(pfd.pfd.data, pfd.pfd.used, timeout); if (rv < 0) { if (errno == EINTR || errno == EAGAIN) goto poll_retry; bug("poll in %p: %m", thr); } account_to(&this_thread->overhead); /* Drain wakeup fd */ if (pfd.pfd.data[0].revents & POLLIN) { ASSERT_DIE(rv > 0); rv--; wakeup_drain(thr); } /* Unset ping information for Meta */ atomic_fetch_and_explicit(&thr->meta->thread_transition, ~LTT_PING, memory_order_acq_rel); /* Schedule loops with active sockets */ if (rv) for (uint i = 1; i < pfd.pfd.used; i++) if (pfd.pfd.data[i].revents) { LOOP_TRACE(pfd.loop.data[i], "socket id %d got revents=%d", i, pfd.pfd.data[i].revents); ev_send_loop(thr->meta, &pfd.loop.data[i]->event); } } bug("An infinite loop has ended."); } static void bird_thread_cleanup(void *_thr) { struct bird_thread *thr = _thr; struct birdloop *meta = thr->meta; ASSERT_DIE(birdloop_inside(&main_birdloop)); /* Wait until the thread actually finishes */ ASSERT_DIE(meta); birdloop_enter(meta); birdloop_leave(meta); /* No more wakeup */ wakeup_free(thr); /* Thread attributes no longer needed */ pthread_attr_destroy(&thr->thread_attr); /* Free the meta loop */ thr->meta->thread = NULL; thr->meta = NULL; birdloop_free(meta); } static struct bird_thread * bird_thread_start(struct birdloop_pickup_group *group) { ASSERT_DIE(birdloop_inside(&main_birdloop)); struct birdloop *meta = birdloop_new_no_pickup(&root_pool, DOMAIN_ORDER(meta), "Thread Meta"); pool *p = birdloop_pool(meta); birdloop_enter(meta); LOCK_DOMAIN(attrs, group->domain); struct bird_thread *thr = mb_allocz(p, sizeof(*thr)); thr->pool = p; thr->cleanup_event = (event) { .hook = bird_thread_cleanup, .data = thr, }; thr->group = group; thr->max_latency_ns = (group->max_latency ?: 5 S) TO_NS; thr->meta = meta; thr->meta->thread = thr; wakeup_init(thr); ev_init_list(&thr->priority_events, NULL, "Thread direct event list"); add_tail(&group->threads, &thr->n); int e = 0; if (e = pthread_attr_init(&thr->thread_attr)) die("pthread_attr_init() failed: %M", e); /* We don't have to worry about thread stack size so much. if (e = pthread_attr_setstacksize(&thr->thread_attr, THREAD_STACK_SIZE)) die("pthread_attr_setstacksize(%u) failed: %M", THREAD_STACK_SIZE, e); */ if (e = pthread_attr_setdetachstate(&thr->thread_attr, PTHREAD_CREATE_DETACHED)) die("pthread_attr_setdetachstate(PTHREAD_CREATE_DETACHED) failed: %M", e); if (e = pthread_create(&thr->thread_id, &thr->thread_attr, bird_thread_main, thr)) die("pthread_create() failed: %M", e); group->thread_count++; UNLOCK_DOMAIN(attrs, group->domain); birdloop_leave(meta); return thr; } static void bird_thread_start_event(void *_data) { struct birdloop_pickup_group *group = _data; bird_thread_start(group); } static struct birdloop *thread_dropper; static event *thread_dropper_event; static uint thread_dropper_goal; static void bird_thread_dropper_free(void *data) { struct birdloop *tdl_stop = data; birdloop_free(tdl_stop); } static void bird_thread_shutdown(void * _ UNUSED) { struct birdloop_pickup_group *group = this_thread->group; LOCK_DOMAIN(attrs, group->domain); int dif = group->thread_count - thread_dropper_goal; struct birdloop *tdl_stop = NULL; if (dif > 0) ev_send_loop(thread_dropper, thread_dropper_event); else { tdl_stop = thread_dropper; thread_dropper = NULL; } UNLOCK_DOMAIN(attrs, group->domain); DBG("Thread pickup size differs from dropper goal by %d%s\n", dif, tdl_stop ? ", stopping" : ""); if (tdl_stop) { birdloop_stop_self(tdl_stop, bird_thread_dropper_free, tdl_stop); return; } struct bird_thread *thr = this_thread; LOCK_DOMAIN(attrs, group->domain); /* Leave the thread-picker list to get no more loops */ rem_node(&thr->n); group->thread_count--; /* Fix the busy count */ if (thr->busy_active) group->thread_busy_count--; UNLOCK_DOMAIN(attrs, group->domain); /* Leave the thread-dropper loop as we aren't going to return. */ birdloop_leave(thread_dropper); /* Last try to run the priority event list; ruin it then to be extra sure */ ev_run_list(&this_thread->priority_events); memset(&this_thread->priority_events, 0xa5, sizeof(this_thread->priority_events)); /* Drop loops including the thread dropper itself */ while (!EMPTY_LIST(thr->loops)) { struct birdloop *loop = HEAD(thr->loops); /* Remove loop from this thread's list */ this_thread->loop_count--; rem_node(&loop->n); /* Unset loop's thread */ birdloop_set_thread(loop, NULL, group); } /* Let others know about new loops */ LOCK_DOMAIN(attrs, group->domain); if (!EMPTY_LIST(group->loops)) wakeup_do_kick(SKIP_BACK(struct bird_thread, n, HEAD(group->threads))); UNLOCK_DOMAIN(attrs, group->domain); /* Request thread cleanup from main loop */ ev_send_loop(&main_birdloop, &thr->cleanup_event); /* Local pages not needed anymore */ flush_local_pages(); /* Unregister from RCU */ rcu_thread_stop(&thr->rcu); /* Now we can be cleaned up */ birdloop_leave(thr->meta); /* Exit! */ pthread_exit(NULL); } void bird_thread_commit(struct config *new, struct config *old UNUSED) { ASSERT_DIE(birdloop_inside(&main_birdloop)); if (new->shutdown) return; if (!new->thread_count) new->thread_count = 1; while (1) { struct birdloop_pickup_group *group = &pickup_groups[0]; LOCK_DOMAIN(attrs, group->domain); int dif = group->thread_count - (thread_dropper_goal = new->thread_count); _Bool thread_dropper_running = !!thread_dropper; UNLOCK_DOMAIN(attrs, group->domain); if (dif < 0) { bird_thread_start(group); continue; } if ((dif > 0) && !thread_dropper_running) { struct birdloop *tdl = birdloop_new(&root_pool, DOMAIN_ORDER(control), group->max_latency, "Thread dropper"); birdloop_enter(tdl); event *tde = ev_new_init(tdl->pool, bird_thread_shutdown, NULL); LOCK_DOMAIN(attrs, group->domain); thread_dropper = tdl; thread_dropper_event = tde; UNLOCK_DOMAIN(attrs, group->domain); ev_send_loop(thread_dropper, thread_dropper_event); birdloop_leave(tdl); } return; } } /* Cleanup after last thread */ static void bird_thread_sync_finish(void *_sync) { ASSERT_THE_BIRD_LOCKED; struct bird_thread_syncer *sync = _sync; /* Keep necessary pointers locally */ pool *p = sync->pool; DOMAIN(control) lock = sync->lock; LOCK_DOMAIN(control, lock); /* This invalidates the `sync` pointer */ CALL(sync->finish, sync); /* Free pool and domain */ rp_free(p); UNLOCK_DOMAIN(control, lock); DOMAIN_FREE(control, lock); } /* Process regular one thread hook */ static void bird_thread_sync_one(void *_sync) { struct bird_thread_syncer *sync = _sync; LOCK_DOMAIN(control, sync->lock); CALL(sync->hook, sync); sync->done++; if (sync->done == sync->total) ev_send_loop(&main_birdloop, ev_new_init(sync->pool, bird_thread_sync_finish, sync)); UNLOCK_DOMAIN(control, sync->lock); } void bird_thread_sync_all(struct bird_thread_syncer *sync, void (*hook)(struct bird_thread_syncer *), void (*done)(struct bird_thread_syncer *), const char *name) { sync->lock = DOMAIN_NEW(control); LOCK_DOMAIN(control, sync->lock); sync->pool = rp_new(&root_pool, sync->lock.control, name); sync->hook = hook; sync->finish = done; for (int i=0; i<2; i++) { struct birdloop_pickup_group *group = &pickup_groups[i]; LOCK_DOMAIN(attrs, group->domain); struct bird_thread *thr; WALK_LIST(thr, group->threads) { sync->total++; ev_send(&thr->priority_events, ev_new_init(sync->pool, bird_thread_sync_one, sync)); wakeup_do_kick(thr); } UNLOCK_DOMAIN(attrs, group->domain); } UNLOCK_DOMAIN(control, sync->lock); } struct bird_thread_show_data { struct bird_thread_syncer sync; cli *cli; linpool *lp; u8 show_loops; uint line_pos; uint line_max; const char **lines; }; #define tsd_append(...) do { \ if (!tsd->lines) \ tsd->lines = mb_allocz(tsd->sync.pool, sizeof(const char *) * tsd->line_max); \ if (tsd->line_pos >= tsd->line_max) \ tsd->lines = mb_realloc(tsd->lines, sizeof (const char *) * (tsd->line_max *= 2)); \ tsd->lines[tsd->line_pos++] = lp_sprintf(tsd->lp, __VA_ARGS__); \ } while (0) static void bird_thread_show_cli_cont(struct cli *c UNUSED) { /* Explicitly do nothing to prevent CLI from trying to parse another command. */ } static int bird_thread_show_cli_cleanup(struct cli *c UNUSED) { return 1; /* Defer the cleanup until the writeout is finished. */ } static void bird_thread_show_spent_time(struct bird_thread_show_data *tsd, const char *name, struct spent_time *st) { char b[TIME_BY_SEC_SIZE * sizeof("1234567890, ")], *bptr = b, *bend = b + sizeof(b); uint cs = CURRENT_SEC; uint fs = NSEC_TO_SEC(st->last_written_ns); for (uint i = 0; i <= cs && i < TIME_BY_SEC_SIZE; i++) bptr += bsnprintf(bptr, bend - bptr, "% 10lu ", (cs - i > fs) ? 0 : st->by_sec_ns[(cs - i) % TIME_BY_SEC_SIZE]); bptr[-1] = 0; /* Drop the trailing space */ tsd_append(" %s total time: % 9t s; last %d secs [ns]: %s", name, st->total_ns NS, MIN(CURRENT_SEC+1, TIME_BY_SEC_SIZE), b); } static void bird_thread_show_loop(struct bird_thread_show_data *tsd, struct birdloop *loop) { tsd_append(" Loop %s", domain_name(loop->time.domain)); bird_thread_show_spent_time(tsd, "Working ", &loop->working); bird_thread_show_spent_time(tsd, "Locking ", &loop->locking); } static void bird_thread_show(struct bird_thread_syncer *sync) { struct bird_thread_show_data *tsd = SKIP_BACK(struct bird_thread_show_data, sync, sync); if (!tsd->lp) tsd->lp = lp_new(tsd->sync.pool); if (tsd->show_loops) tsd_append("Thread %p%s (busy counter %d)", this_thread, this_thread->busy_active ? " [busy]" : "", this_thread->busy_counter); u64 total_time_ns = 0; struct birdloop *loop; WALK_LIST(loop, this_thread->loops) { if (tsd->show_loops) bird_thread_show_loop(tsd, loop); total_time_ns += loop->working.total_ns + loop->locking.total_ns; } if (tsd->show_loops) { tsd_append(" Total working time: %t", total_time_ns NS); bird_thread_show_spent_time(tsd, "Overhead", &this_thread->overhead); bird_thread_show_spent_time(tsd, "Idle ", &this_thread->idle); } else tsd_append("Thread %p working %t s overhead %t s", this_thread, total_time_ns NS, this_thread->overhead.total_ns NS); } static void cmd_show_threads_done(struct bird_thread_syncer *sync) { struct bird_thread_show_data *tsd = SKIP_BACK(struct bird_thread_show_data, sync, sync); ASSERT_DIE(birdloop_inside(&main_birdloop)); tsd->cli->cont = NULL; tsd->cli->cleanup = NULL; for (int i=0; i<2; i++) { struct birdloop_pickup_group *group = &pickup_groups[i]; LOCK_DOMAIN(attrs, group->domain); uint count = 0; u64 total_time_ns = 0; if (!EMPTY_LIST(group->loops)) { if (tsd->show_loops) tsd_append("Unassigned loops in group %d:", i); struct birdloop *loop; WALK_LIST(loop, group->loops) { if (tsd->show_loops) bird_thread_show_loop(tsd, loop); total_time_ns += loop->working.total_ns + loop->locking.total_ns; count++; } if (tsd->show_loops) tsd_append(" Total working time: %t", total_time_ns NS); else tsd_append("Unassigned %d loops in group %d, total time %t", count, i, total_time_ns NS); } else tsd_append("All loops in group %d are assigned.", i); UNLOCK_DOMAIN(attrs, group->domain); } for (uint i = 0; i < tsd->line_pos - 1; i++) cli_printf(tsd->cli, -1026, "%s", tsd->lines[i]); cli_printf(tsd->cli, 1026, "%s", tsd->lines[tsd->line_pos-1]); cli_write_trigger(tsd->cli); mb_free(tsd); } void cmd_show_threads(int show_loops) { struct bird_thread_show_data *tsd = mb_allocz(&root_pool, sizeof(struct bird_thread_show_data)); tsd->cli = this_cli; tsd->show_loops = show_loops; tsd->line_pos = 0; tsd->line_max = 64; this_cli->cont = bird_thread_show_cli_cont; this_cli->cleanup = bird_thread_show_cli_cleanup; bird_thread_sync_all(&tsd->sync, bird_thread_show, cmd_show_threads_done, "Show Threads"); } /* * Birdloop */ static struct bird_thread main_thread; struct birdloop main_birdloop = { .thread = &main_thread, }; static void birdloop_enter_locked(struct birdloop *loop); void birdloop_init(void) { ns_init(); for (int i=0; i<2; i++) { struct birdloop_pickup_group *group = &pickup_groups[i]; group->domain = DOMAIN_NEW(attrs); DOMAIN_SETUP(attrs, group->domain, "Loop Pickup", NULL); init_list(&group->loops); init_list(&group->threads); } wakeup_init(main_birdloop.thread); main_birdloop.time.domain = the_bird_domain.the_bird; main_birdloop.time.loop = &main_birdloop; times_update(); timers_init(&main_birdloop.time, &root_pool); birdloop_enter_locked(&main_birdloop); } static void birdloop_stop_internal(struct birdloop *loop) { LOOP_TRACE(loop, "Stopping"); /* Block incoming pings */ u32 ltt = atomic_load_explicit(&loop->thread_transition, memory_order_acquire); while (!atomic_compare_exchange_strong_explicit( &loop->thread_transition, <t, LTT_PING, memory_order_acq_rel, memory_order_acquire)) ; /* Flush remaining events */ ASSERT_DIE(!ev_run_list(&loop->event_list)); /* Drop timers */ timer *t; while (t = timers_first(&loop->time)) tm_stop(t); /* Drop sockets */ sock *s; WALK_LIST_FIRST2(s, n, loop->sock_list) birdloop_remove_socket(loop, s); /* Unschedule from Meta */ ev_postpone(&loop->event); tm_stop(&loop->timer); /* Remove from thread loop list */ ASSERT_DIE(loop->thread == this_thread); rem_node(&loop->n); loop->thread = NULL; /* Uncount from thread group */ LOCK_DOMAIN(attrs, this_thread->group->domain); this_thread->group->loop_count--; UNLOCK_DOMAIN(attrs, this_thread->group->domain); /* Leave the loop context without causing any other fuss */ ASSERT_DIE(!ev_active(&loop->event)); loop->ping_pending = 0; account_to(&this_thread->overhead); birdloop_leave(loop); /* Request local socket reload */ this_thread->sock_changed = 1; /* Call the stopped hook from the main loop */ loop->event.hook = loop->stopped; loop->event.data = loop->stop_data; ev_send_loop(&main_birdloop, &loop->event); } static void birdloop_run(void *_loop) { /* Run priority events before the loop is executed */ ev_run_list(&this_thread->priority_events); struct birdloop *loop = _loop; account_to(&loop->locking); birdloop_enter(loop); u64 dif = account_to(&loop->working); if (dif > this_thread->max_loop_time_ns) LOOP_WARN(loop, "locked %lu ns after its scheduled end time", dif); uint repeat, loop_runs = 0; do { repeat = 0; LOOP_TRACE(loop, "Regular run"); loop_runs++; if (loop->stopped) /* Birdloop left inside the helper function */ return birdloop_stop_internal(loop); /* Process sockets */ repeat += sockets_fire(loop); /* Run timers */ timers_fire(&loop->time, 0); /* Run flag handlers */ repeat += birdloop_process_flags(loop); /* Run events */ repeat += ev_run_list(&loop->event_list); /* Check end time */ } while (repeat && (ns_now() < account_last + this_thread->max_loop_time_ns)); /* Request meta timer */ timer *t = timers_first(&loop->time); if (t) tm_start_in(&loop->timer, tm_remains(t), this_thread->meta); else tm_stop(&loop->timer); /* Request re-run if needed */ if (repeat) ev_send_loop(this_thread->meta, &loop->event); /* Collect socket change requests */ this_thread->sock_changed |= loop->sock_changed; loop->sock_changed = 0; account_to(&this_thread->overhead); birdloop_leave(loop); } static void birdloop_run_timer(timer *tm) { struct birdloop *loop = tm->data; LOOP_TRACE(loop, "Timer ready, requesting run"); ev_send_loop(loop->thread->meta, &loop->event); } static struct birdloop * birdloop_vnew_internal(pool *pp, uint order, struct birdloop_pickup_group *group, const char *name, va_list args) { struct domain_generic *dg = domain_new(order); DG_LOCK(dg); pool *p = rp_vnewf(pp, dg, name, args); struct birdloop *loop = mb_allocz(p, sizeof(struct birdloop)); loop->pool = p; loop->time.domain = dg; loop->time.loop = loop; atomic_store_explicit(&loop->thread_transition, 0, memory_order_relaxed); birdloop_enter_locked(loop); ev_init_list(&loop->event_list, loop, name); timers_init(&loop->time, p); sockets_init(loop); loop->event = (event) { .hook = birdloop_run, .data = loop, }; loop->timer = (timer) { .hook = birdloop_run_timer, .data = loop, }; if (group) { LOCK_DOMAIN(attrs, group->domain); group->loop_count++; add_tail(&group->loops, &loop->n); if (EMPTY_LIST(group->threads)) ev_send(&global_event_list, &group->start_threads); else wakeup_do_kick(SKIP_BACK(struct bird_thread, n, HEAD(group->threads))); UNLOCK_DOMAIN(attrs, group->domain); } else loop->n.next = loop->n.prev = &loop->n; birdloop_leave(loop); return loop; } static struct birdloop * birdloop_new_no_pickup(pool *pp, uint order, const char *name, ...) { va_list args; va_start(args, name); struct birdloop *loop = birdloop_vnew_internal(pp, order, NULL, name, args); va_end(args); return loop; } struct birdloop * birdloop_new(pool *pp, uint order, btime max_latency, const char *name, ...) { va_list args; va_start(args, name); struct birdloop *loop = birdloop_vnew_internal(pp, order, max_latency ? &pickup_groups[1] : &pickup_groups[0], name, args); va_end(args); return loop; } static void birdloop_do_stop(struct birdloop *loop, void (*stopped)(void *data), void *data) { LOOP_TRACE(loop, "Stop requested"); loop->stopped = stopped; loop->stop_data = data; birdloop_do_ping(loop); } void birdloop_stop(struct birdloop *loop, void (*stopped)(void *data), void *data) { DG_LOCK(loop->time.domain); birdloop_do_stop(loop, stopped, data); DG_UNLOCK(loop->time.domain); } void birdloop_stop_self(struct birdloop *loop, void (*stopped)(void *data), void *data) { ASSERT_DIE(loop == birdloop_current); ASSERT_DIE(DG_IS_LOCKED(loop->time.domain)); birdloop_do_stop(loop, stopped, data); } void birdloop_free(struct birdloop *loop) { ASSERT_DIE(loop->thread == NULL); struct domain_generic *dg = loop->time.domain; DG_LOCK(dg); rp_free(loop->pool); DG_UNLOCK(dg); domain_free(dg); } static void birdloop_enter_locked(struct birdloop *loop) { ASSERT_DIE(DG_IS_LOCKED(loop->time.domain)); ASSERT_DIE(!birdloop_inside(loop)); /* Store the old context */ loop->prev_loop = birdloop_current; /* Put the new context */ birdloop_current = loop; } void birdloop_enter(struct birdloop *loop) { DG_LOCK(loop->time.domain); return birdloop_enter_locked(loop); } static void birdloop_leave_locked(struct birdloop *loop) { /* Check the current context */ ASSERT_DIE(birdloop_current == loop); /* Send pending pings */ if (loop->ping_pending) { LOOP_TRACE(loop, "sending pings on leave"); loop->ping_pending = 0; birdloop_do_ping(loop); } /* Restore the old context */ birdloop_current = loop->prev_loop; } void birdloop_leave(struct birdloop *loop) { birdloop_leave_locked(loop); DG_UNLOCK(loop->time.domain); } void birdloop_mask_wakeups(struct birdloop *loop) { ASSERT_DIE(birdloop_wakeup_masked == NULL); birdloop_wakeup_masked = loop; } void birdloop_unmask_wakeups(struct birdloop *loop) { ASSERT_DIE(birdloop_wakeup_masked == loop); birdloop_wakeup_masked = NULL; if (birdloop_wakeup_masked_count) wakeup_do_kick(loop->thread); birdloop_wakeup_masked_count = 0; } void birdloop_yield(void) { usleep(100); }