/* * C eventloop example. * * Timer management is similar to eventloop.js but implemented in C. * In particular, timer insertion is an O(n) operation; in a real world * eventloop based on a heap insertion would be O(log N). */ #include #include #include #include #include #include #include "duktape.h" #define MAX_TIMERS 4096 /* this is quite excessive for embedded use, but good for testing */ #define MIN_DELAY 1.0 #define MIN_WAIT 1.0 #define MAX_WAIT 60000.0 #define MAX_EXPIRYS 10 #define MAX_FDS 256 typedef struct { int64_t id; /* numeric ID (returned from e.g. setTimeout); zero if unused */ double target; /* next target time */ double delay; /* delay/interval */ int oneshot; /* oneshot=1 (setTimeout), repeated=0 (setInterval) */ int removed; /* timer has been requested for removal */ /* The callback associated with the timer is held in the "global stash", * in .eventTimers[String(id)]. The references must be deleted * when a timer struct is deleted. */ } ev_timer; /* Active timers. Dense list, terminates to end of list or first unused timer. * The list is sorted by 'target', with lowest 'target' (earliest expiry) last * in the list. When a timer's callback is being called, the timer is moved * to 'timer_expiring' as it needs special handling should the user callback * delete that particular timer. */ static ev_timer timer_list[MAX_TIMERS]; static ev_timer timer_expiring; static int timer_count; /* last timer at timer_count - 1 */ static int64_t timer_next_id = 1; /* Socket poll state. */ static struct pollfd poll_list[MAX_FDS]; static int poll_count = 0; /* Misc */ static int exit_requested = 0; /* Get Javascript compatible 'now' timestamp (millisecs since 1970). */ static double get_now(void) { struct timeval tv; int rc; rc = gettimeofday(&tv, NULL); if (rc != 0) { /* Should never happen, so return whatever. */ return 0.0; } return ((double) tv.tv_sec) * 1000.0 + ((double) tv.tv_usec) / 1000.0; } static ev_timer *find_nearest_timer(void) { /* Last timer expires first (list is always kept sorted). */ if (timer_count <= 0) { return NULL; } return timer_list + timer_count - 1; } /* Bubble last timer on timer list backwards until it has been moved to * its proper sorted position (based on 'target' time). */ static void bubble_last_timer(void) { int i; int n = timer_count; ev_timer *t; ev_timer tmp; for (i = n - 1; i > 0; i--) { /* Timer to bubble is at index i, timer to compare to is * at i-1 (both guaranteed to exist). */ t = timer_list + i; if (t->target <= (t-1)->target) { /* 't' expires earlier than (or same time as) 't-1', so we're done. */ break; } else { /* 't' expires later than 't-1', so swap them and repeat. */ memcpy((void *) &tmp, (void *) (t - 1), sizeof(ev_timer)); memcpy((void *) (t - 1), (void *) t, sizeof(ev_timer)); memcpy((void *) t, (void *) &tmp, sizeof(ev_timer)); } } } static void expire_timers(duk_context *ctx) { ev_timer *t; int sanity = MAX_EXPIRYS; double now; int rc; /* Because a user callback can mutate the timer list (by adding or deleting * a timer), we expire one timer and then rescan from the end again. There * is a sanity limit on how many times we do this per expiry round. */ duk_push_global_stash(ctx); duk_get_prop_string(ctx, -1, "eventTimers"); /* [ ... stash eventTimers ] */ now = get_now(); while (sanity-- > 0) { /* * If exit has been requested, exit without running further * callbacks. */ if (exit_requested) { #if 0 fprintf(stderr, "exit requested, exiting timer expiry loop\n"); fflush(stderr); #endif break; } /* * Expired timer(s) still exist? */ if (timer_count <= 0) { break; } t = timer_list + timer_count - 1; if (t->target > now) { break; } /* * Move the timer to 'expiring' for the duration of the callback. * Mark a one-shot timer deleted, compute a new target for an interval. */ memcpy((void *) &timer_expiring, (void *) t, sizeof(ev_timer)); memset((void *) t, 0, sizeof(ev_timer)); timer_count--; t = &timer_expiring; if (t->oneshot) { t->removed = 1; } else { t->target = now + t->delay; /* XXX: or t->target + t->delay? */ } /* * Call timer callback. The callback can operate on the timer list: * add new timers, remove timers. The callback can even remove the * expired timer whose callback we're calling. However, because the * timer being expired has been moved to 'timer_expiring', we don't * need to worry about the timer's offset changing on the timer list. */ #if 0 fprintf(stderr, "calling user callback for timer id %d\n", (int) t->id); fflush(stderr); #endif duk_push_number(ctx, (double) t->id); duk_get_prop(ctx, -2); /* -> [ ... stash eventTimers func ] */ rc = duk_pcall(ctx, 0 /*nargs*/); /* -> [ ... stash eventTimers retval ] */ if (rc != 0) { #if 0 fprintf(stderr, "timer callback failed for timer %d: %s\n", (int) t->id, duk_to_string(ctx, -1)); fflush(stderr); #endif } duk_pop(ctx); /* ignore errors for now -> [ ... stash eventTimers ] */ if (t->removed) { /* One-shot timer (always removed) or removed by user callback. */ #if 0 fprintf(stderr, "deleting callback state for timer %d\n", (int) t->id); fflush(stderr); #endif duk_push_number(ctx, (double) t->id); duk_del_prop(ctx, -2); } else { /* Interval timer, not removed by user callback. Queue back to * timer list and bubble to its final sorted position. */ #if 0 fprintf(stderr, "queueing timer %d back into active list\n", (int) t->id); fflush(stderr); #endif if (timer_count >= MAX_TIMERS) { duk_error(ctx, DUK_ERR_RANGE_ERROR, "out of timer slots"); } memcpy((void *) (timer_list + timer_count), (void *) t, sizeof(ev_timer)); timer_count++; bubble_last_timer(); } } memset((void *) &timer_expiring, 0, sizeof(ev_timer)); duk_pop_2(ctx); /* -> [ ... ] */ } static void compact_poll_list(void) { int i, j, n; /* i = input index * j = output index (initially same as i) */ n = poll_count; for (i = 0, j = 0; i < n; i++) { struct pollfd *pfd = poll_list + i; if (pfd->fd == 0) { /* keep output index the same */ #if 0 fprintf(stderr, "remove pollfd (index %d): fd=%d, events=%d, revents=%d\n", i, pfd->fd, pfd->events, pfd->revents), fflush(stderr); #endif continue; } #if 0 fprintf(stderr, "keep pollfd (index %d -> %d): fd=%d, events=%d, revents=%d\n", i, j, pfd->fd, pfd->events, pfd->revents), fflush(stderr); #endif if (i != j) { /* copy only if indices have diverged */ memcpy((void *) (poll_list + j), (void *) (poll_list + i), sizeof(struct pollfd)); } j++; } if (j < poll_count) { /* zeroize unused entries for sanity */ memset((void *) (poll_list + j), 0, (poll_count - j) * sizeof(struct pollfd)); } poll_count = j; } int eventloop_run(duk_context *ctx) { ev_timer *t; double now; double diff; int timeout; int rc; int i, n; int idx_eventloop; int idx_fd_handler; /* The Ecmascript poll handler is passed through EventLoop.fdPollHandler * which c_eventloop.js sets before we come here. */ duk_push_global_object(ctx); duk_get_prop_string(ctx, -1, "EventLoop"); duk_get_prop_string(ctx, -1, "fdPollHandler"); /* -> [ global EventLoop fdPollHandler ] */ idx_fd_handler = duk_get_top_index(ctx); idx_eventloop = idx_fd_handler - 1; for (;;) { /* * Expire timers. */ expire_timers(ctx); /* * If exit requested, bail out as fast as possible. */ if (exit_requested) { #if 0 fprintf(stderr, "exit requested, exiting event loop\n"); fflush(stderr); #endif break; } /* * Compact poll list by removing pollfds with fd == 0. */ compact_poll_list(); /* * Determine poll() timeout (as close to poll() as possible as * the wait is relative). */ now = get_now(); t = find_nearest_timer(); if (t) { diff = t->target - now; if (diff < MIN_WAIT) { diff = MIN_WAIT; } else if (diff > MAX_WAIT) { diff = MAX_WAIT; } timeout = (int) diff; /* clamping ensures that fits */ } else { if (poll_count == 0) { #if 0 fprintf(stderr, "no timers and no sockets to poll, exiting\n"); fflush(stderr); #endif break; } timeout = (int) MAX_WAIT; } /* * Poll for activity or timeout. */ #if 0 fprintf(stderr, "going to poll, timeout %d ms, pollfd count %d\n", timeout, poll_count); fflush(stderr); #endif rc = poll(poll_list, poll_count, timeout); #if 0 fprintf(stderr, "poll rc: %d\n", rc); fflush(stderr); #endif if (rc < 0) { /* error */ } else if (rc == 0) { /* timeout */ } else { /* 'rc' fds active */ } /* * Check socket activity, handle all sockets. Handling is offloaded to * Ecmascript code (fd + revents). * * If FDs are removed from the poll list while we're processing callbacks, * the entries are simply marked unused (fd set to 0) without actually * removing them from the poll list. This ensures indices are not * disturbed. The poll list is compacted before next poll(). */ n = (rc == 0 ? 0 : poll_count); /* if timeout, no need to check pollfd */ for (i = 0; i < n; i++) { struct pollfd *pfd = poll_list + i; if (pfd->fd == 0) { /* deleted, perhaps by previous callback */ continue; } if (pfd->revents) { #if 0 fprintf(stderr, "fd %d has revents: %d\n", (int) pfd->fd, (int) pfd->revents); fflush(stderr); #endif duk_dup(ctx, idx_fd_handler); duk_dup(ctx, idx_eventloop); duk_push_int(ctx, pfd->fd); duk_push_int(ctx, pfd->revents); rc = duk_pcall_method(ctx, 2 /*nargs*/); if (rc) { #if 0 fprintf(stderr, "fd callback failed for fd %d: %s\n", (int) pfd->fd, duk_to_string(ctx, -1)); fflush(stderr); #endif } duk_pop(ctx); pfd->revents = 0; } } } duk_pop_n(ctx, 3); return 0; } static int create_timer(duk_context *ctx) { double delay; int oneshot; int idx; int64_t timer_id; double now; ev_timer *t; now = get_now(); /* indexes: * 0 = function (callback) * 1 = delay * 2 = boolean: oneshot */ delay = duk_require_number(ctx, 1); if (delay < MIN_DELAY) { delay = MIN_DELAY; } oneshot = duk_require_boolean(ctx, 2); if (timer_count >= MAX_TIMERS) { duk_error(ctx, DUK_ERR_RANGE_ERROR, "out of timer slots"); } idx = timer_count++; timer_id = timer_next_id++; t = timer_list + idx; memset((void *) t, 0, sizeof(ev_timer)); t->id = timer_id; t->target = now + delay; t->delay = delay; t->oneshot = oneshot; t->removed = 0; /* Timer is now at the last position; use swaps to "bubble" it to its * correct sorted position. */ bubble_last_timer(); /* Finally, register the callback to the global stash 'eventTimers' object. */ duk_push_global_stash(ctx); duk_get_prop_string(ctx, -1, "eventTimers"); /* -> [ func delay oneshot stash eventTimers ] */ duk_push_number(ctx, (double) timer_id); duk_dup(ctx, 0); duk_put_prop(ctx, -3); /* eventTimers[timer_id] = callback */ /* Return timer id. */ duk_push_number(ctx, (double) timer_id); #if 0 fprintf(stderr, "created timer id: %d\n", (int) timer_id); fflush(stderr); #endif return 1; } static int delete_timer(duk_context *ctx) { int i, n; int64_t timer_id; ev_timer *t; int found = 0; /* indexes: * 0 = timer id */ timer_id = (int64_t) duk_require_number(ctx, 0); /* * Unlike insertion, deletion needs a full scan of the timer list * and an expensive remove. If no match is found, nothing is deleted. * Caller gets a boolean return code indicating match. * * When a timer is being expired and its user callback is running, * the timer has been moved to 'timer_expiring' and its deletion * needs special handling: just mark it to-be-deleted and let the * expiry code remove it. */ t = &timer_expiring; if (t->id == timer_id) { t->removed = 1; duk_push_true(ctx); #if 0 fprintf(stderr, "deleted expiring timer id: %d\n", (int) timer_id); fflush(stderr); #endif return 1; } n = timer_count; for (i = 0; i < n; i++) { t = timer_list + i; if (t->id == timer_id) { found = 1; /* Shift elements downwards to keep the timer list dense * (no need if last element). */ if (i < timer_count - 1) { memmove((void *) t, (void *) (t + 1), (timer_count - i - 1) * sizeof(ev_timer)); } /* Zero last element for clarity. */ memset((void *) (timer_list + n - 1), 0, sizeof(ev_timer)); /* Update timer_count. */ timer_count--; /* The C state is now up-to-date, but we still need to delete * the timer callback state from the global 'stash'. */ duk_push_global_stash(ctx); duk_get_prop_string(ctx, -1, "eventTimers"); /* -> [ timer_id stash eventTimers ] */ duk_push_number(ctx, (double) timer_id); duk_del_prop(ctx, -2); /* delete eventTimers[timer_id] */ #if 0 fprintf(stderr, "deleted timer id: %d\n", (int) timer_id); fflush(stderr); #endif break; } } #if 0 if (!found) { fprintf(stderr, "trying to delete timer id %d, but not found; ignoring\n", (int) timer_id); fflush(stderr); } #endif duk_push_boolean(ctx, found); return 1; } static int listen_fd(duk_context *ctx) { int fd = duk_require_int(ctx, 0); int events = duk_require_int(ctx, 1); int i, n; struct pollfd *pfd; #if 0 fprintf(stderr, "listen_fd: fd=%d, events=%d\n", fd, events); fflush(stderr); #endif /* events == 0 means stop listening to the FD */ n = poll_count; for (i = 0; i < n; i++) { pfd = poll_list + i; if (pfd->fd == fd) { #if 0 fprintf(stderr, "listen_fd: fd found at index %d\n", i); fflush(stderr); #endif if (events == 0) { /* mark to-be-deleted, cleaned up by next poll */ pfd->fd = 0; } else { pfd->events = events; } return 0; } } /* not found, append to list */ #if 0 fprintf(stderr, "listen_fd: fd not found on list, add new entry\n"); fflush(stderr); #endif if (poll_count >= MAX_FDS) { duk_error(ctx, DUK_ERR_ERROR, "out of fd slots"); } pfd = poll_list + poll_count; pfd->fd = fd; pfd->events = events; pfd->revents = 0; poll_count++; return 0; } static int request_exit(duk_context *ctx) { (void) ctx; exit_requested = 1; return 0; } static duk_function_list_entry eventloop_funcs[] = { { "createTimer", create_timer, 3 }, { "deleteTimer", delete_timer, 1 }, { "listenFd", listen_fd, 2 }, { "requestExit", request_exit, 0 }, { NULL, NULL, 0 } }; void eventloop_register(duk_context *ctx) { memset((void *) timer_list, 0, MAX_TIMERS * sizeof(ev_timer)); memset((void *) &timer_expiring, 0, sizeof(ev_timer)); memset((void *) poll_list, 0, MAX_FDS * sizeof(struct pollfd)); /* Set global 'EventLoop'. */ duk_push_global_object(ctx); duk_push_object(ctx); duk_put_function_list(ctx, -1, eventloop_funcs); duk_put_prop_string(ctx, -2, "EventLoop"); duk_pop(ctx); /* Initialize global stash 'eventTimers'. */ duk_push_global_stash(ctx); duk_push_object(ctx); duk_put_prop_string(ctx, -2, "eventTimers"); duk_pop(ctx); }