#include #include #include #include #include "nvim/os/event.h" #include "nvim/os/input.h" #include "nvim/os/channel.h" #include "nvim/os/server.h" #include "nvim/os/signal.h" #include "nvim/os/rstream.h" #include "nvim/os/job.h" #include "nvim/vim.h" #include "nvim/memory.h" #include "nvim/misc2.h" #include "nvim/lib/klist.h" // event will be cleaned up after it gets processed #define _destroy_event(x) // do nothing KLIST_INIT(Event, Event, _destroy_event) typedef struct { bool timed_out; int32_t ms; uv_timer_t *timer; } TimerData; #ifdef INCLUDE_GENERATED_DECLARATIONS # include "os/event.c.generated.h" #endif static klist_t(Event) *deferred_events, *immediate_events; void event_init() { // Initialize the event queues deferred_events = kl_init(Event); immediate_events = kl_init(Event); // Initialize input events input_init(); // Timer to wake the event loop if a timeout argument is passed to // `event_poll` // Signals signal_init(); // Jobs job_init(); // Channels channel_init(); // Servers server_init(); } void event_teardown() { channel_teardown(); job_teardown(); server_teardown(); } // Wait for some event bool event_poll(int32_t ms) { uv_run_mode run_mode = UV_RUN_ONCE; static int recursive = 0; if (!(recursive++)) { // Only needs to start the libuv handle the first time we enter here input_start(); } uv_timer_t timer; uv_prepare_t timer_prepare; TimerData timer_data = {.ms = ms, .timed_out = false, .timer = &timer}; if (ms > 0) { uv_timer_init(uv_default_loop(), &timer); // This prepare handle that actually starts the timer uv_prepare_init(uv_default_loop(), &timer_prepare); // Timeout passed as argument to the timer timer.data = &timer_data; // We only start the timer after the loop is running, for that we // use a prepare handle(pass the interval as data to it) timer_prepare.data = &timer_data; uv_prepare_start(&timer_prepare, timer_prepare_cb); } else if (ms == 0) { // For ms == 0, we need to do a non-blocking event poll by // setting the run mode to UV_RUN_NOWAIT. run_mode = UV_RUN_NOWAIT; } bool events_processed; do { // Run one event loop iteration, blocking for events if run_mode is // UV_RUN_ONCE uv_run(uv_default_loop(), run_mode); events_processed = event_process(false); } while ( // Continue running if ... !events_processed && // we didn't process any immediate events !event_has_deferred() && // no events are waiting to be processed run_mode != UV_RUN_NOWAIT && // ms != 0 !timer_data.timed_out); // we didn't get a timeout if (!(--recursive)) { // Again, only stop when we leave the top-level invocation input_stop(); } if (ms > 0) { // Ensure the timer-related handles are closed and run the event loop // once more to let libuv perform it's cleanup uv_close((uv_handle_t *)&timer, NULL); uv_close((uv_handle_t *)&timer_prepare, NULL); uv_run(uv_default_loop(), UV_RUN_NOWAIT); event_process(false); } return !timer_data.timed_out && (events_processed || event_has_deferred()); } bool event_has_deferred() { return !kl_empty(get_queue(true)); } // Push an event to the queue void event_push(Event event, bool deferred) { *kl_pushp(Event, get_queue(deferred)) = event; } // Runs the appropriate action for each queued event bool event_process(bool deferred) { bool processed_events = false; Event event; while (kl_shift(Event, get_queue(deferred), &event) == 0) { processed_events = true; switch (event.type) { case kEventSignal: signal_handle(event); break; case kEventRStreamData: rstream_read_event(event); break; case kEventJobExit: job_exit_event(event); break; default: abort(); } } return processed_events; } // Set a flag in the `event_poll` loop for signaling of a timeout static void timer_cb(uv_timer_t *handle) { TimerData *data = handle->data; data->timed_out = true; } static void timer_prepare_cb(uv_prepare_t *handle) { TimerData *data = handle->data; assert(data->ms > 0); uv_timer_start(data->timer, timer_cb, (uint32_t)data->ms, 0); uv_prepare_stop(handle); } static klist_t(Event) *get_queue(bool deferred) { return deferred ? deferred_events : immediate_events; }