/* * Clutter. * * An OpenGL based 'interactive canvas' library. * * Authored By: Emmanuele Bassi * * Copyright (C) 2009 Intel Corporation. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library. If not, see . */ /* * SECTION:clutter-master-clock-default * @short_description: The default master clock for all animations * * The #ClutterMasterClockDefault class is the default implementation * of #ClutterMasterClock. */ #include "clutter-build-config.h" #include #include "clutter-master-clock.h" #include "clutter-master-clock-default.h" #include "clutter-debug.h" #include "clutter-private.h" #include "clutter-stage-manager-private.h" #include "clutter-stage-private.h" #ifdef CLUTTER_ENABLE_DEBUG #define clutter_warn_if_over_budget(master_clock,start_time,section) G_STMT_START { \ gint64 __delta = g_get_monotonic_time () - start_time; \ gint64 __budget = master_clock->remaining_budget; \ if (__budget > 0 && __delta >= __budget) { \ _clutter_diagnostic_message ("%s took %" G_GINT64_FORMAT " microseconds " \ "more than the remaining budget of %" G_GINT64_FORMAT \ " microseconds", \ section, __delta - __budget, __budget); \ } } G_STMT_END #else #define clutter_warn_if_over_budget(master_clock,start_time,section) #endif typedef struct _ClutterClockSource ClutterClockSource; struct _ClutterMasterClockDefault { GObject parent_instance; /* the list of timelines handled by the clock */ GSList *timelines; /* the current state of the clock, in usecs */ gint64 cur_tick; #ifdef CLUTTER_ENABLE_DEBUG gint64 frame_budget; gint64 remaining_budget; #endif /* an idle source, used by the Master Clock to queue * a redraw on the stage and drive the animations */ GSource *source; guint ensure_next_iteration : 1; guint paused : 1; }; struct _ClutterClockSource { GSource source; ClutterMasterClockDefault *master_clock; }; static gboolean clutter_clock_prepare (GSource *source, gint *timeout); static gboolean clutter_clock_check (GSource *source); static gboolean clutter_clock_dispatch (GSource *source, GSourceFunc callback, gpointer user_data); static GSourceFuncs clock_funcs = { clutter_clock_prepare, clutter_clock_check, clutter_clock_dispatch, NULL }; static void clutter_master_clock_iface_init (ClutterMasterClockInterface *iface); #define clutter_master_clock_default_get_type _clutter_master_clock_default_get_type G_DEFINE_TYPE_WITH_CODE (ClutterMasterClockDefault, clutter_master_clock_default, G_TYPE_OBJECT, G_IMPLEMENT_INTERFACE (CLUTTER_TYPE_MASTER_CLOCK, clutter_master_clock_iface_init)); /* * master_clock_is_running: * @master_clock: a #ClutterMasterClock * * Checks if we should currently be advancing timelines or redrawing * stages. * * Return value: %TRUE if the #ClutterMasterClock has at least * one running timeline */ static gboolean master_clock_is_running (ClutterMasterClockDefault *master_clock) { ClutterStageManager *stage_manager = clutter_stage_manager_get_default (); const GSList *stages, *l; stages = clutter_stage_manager_peek_stages (stage_manager); if (master_clock->paused) return FALSE; if (master_clock->timelines) return TRUE; for (l = stages; l; l = l->next) { if (clutter_actor_is_mapped (l->data) && (_clutter_stage_has_queued_events (l->data) || _clutter_stage_needs_update (l->data))) return TRUE; } if (master_clock->ensure_next_iteration) { master_clock->ensure_next_iteration = FALSE; return TRUE; } return FALSE; } static gint master_clock_get_swap_wait_time (ClutterMasterClockDefault *master_clock) { ClutterStageManager *stage_manager = clutter_stage_manager_get_default (); const GSList *stages, *l; gint64 min_update_time = -1; stages = clutter_stage_manager_peek_stages (stage_manager); for (l = stages; l != NULL; l = l->next) { gint64 update_time = _clutter_stage_get_update_time (l->data); if (min_update_time == -1 || (update_time != -1 && update_time < min_update_time)) min_update_time = update_time; } if (min_update_time == -1) { return -1; } else { gint64 now = g_source_get_time (master_clock->source); if (min_update_time < now) { return 0; } else { gint64 delay_us = min_update_time - now; return (delay_us + 999) / 1000; } } } static int64_t master_clock_get_next_presentation_time (ClutterMasterClockDefault *master_clock) { ClutterStageManager *stage_manager = clutter_stage_manager_get_default (); const GSList *stages, *l; int64_t earliest = -1; stages = clutter_stage_manager_peek_stages (stage_manager); for (l = stages; l != NULL; l = l->next) { gint64 t = _clutter_stage_get_next_presentation_time (l->data); if (earliest == -1 || (t != -1 && t < earliest)) earliest = t; } return earliest; } static void master_clock_schedule_stage_updates (ClutterMasterClockDefault *master_clock) { ClutterStageManager *stage_manager = clutter_stage_manager_get_default (); const GSList *stages, *l; stages = clutter_stage_manager_peek_stages (stage_manager); for (l = stages; l != NULL; l = l->next) _clutter_stage_schedule_update (l->data); } static GSList * master_clock_list_ready_stages (ClutterMasterClockDefault *master_clock) { ClutterStageManager *stage_manager = clutter_stage_manager_get_default (); const GSList *stages, *l; GSList *result; stages = clutter_stage_manager_peek_stages (stage_manager); result = NULL; for (l = stages; l != NULL; l = l->next) { gint64 update_time = _clutter_stage_get_update_time (l->data); /* We carefully avoid to update stages that aren't mapped, because * they have nothing to render and this could cause a deadlock with * some of the SwapBuffers implementations (in particular * GLX_INTEL_swap_event is not emitted if nothing was rendered). * * Also, if a stage has a swap-buffers pending we don't want to draw * to it in case the driver may block the CPU while it waits for the * next backbuffer to become available. * * TODO: We should be able to identify if we are running triple or N * buffered and in these cases we can still draw if there is 1 swap * pending so we can hopefully always be ready to swap for the next * vblank and really match the vsync frequency. */ if (clutter_actor_is_mapped (l->data) && update_time != -1 && update_time <= master_clock->cur_tick) result = g_slist_prepend (result, g_object_ref (l->data)); } return g_slist_reverse (result); } static void master_clock_reschedule_stage_updates (ClutterMasterClockDefault *master_clock, GSList *stages) { const GSList *l; for (l = stages; l != NULL; l = l->next) { /* Clear the old update time */ _clutter_stage_clear_update_time (l->data); /* And if there is still work to be done, schedule a new one */ if (master_clock->timelines || _clutter_stage_has_queued_events (l->data) || _clutter_stage_needs_update (l->data)) _clutter_stage_schedule_update (l->data); } } /* * master_clock_next_frame_delay: * @master_clock: a #ClutterMasterClock * * Computes the number of delay before we need to draw the next frame. * * Return value: -1 if there is no next frame pending, otherwise the * number of millseconds before the we need to draw the next frame */ static gint master_clock_next_frame_delay (ClutterMasterClockDefault *master_clock) { if (!master_clock_is_running (master_clock)) return -1; /* If all of the stages are busy waiting for a swap-buffers to complete * then we wait for one to be ready.. */ return master_clock_get_swap_wait_time (master_clock); } static void master_clock_process_events (ClutterMasterClockDefault *master_clock, GSList *stages) { GSList *l; #ifdef CLUTTER_ENABLE_DEBUG gint64 start = g_get_monotonic_time (); #endif /* Process queued events */ for (l = stages; l != NULL; l = l->next) _clutter_stage_process_queued_events (l->data); #ifdef CLUTTER_ENABLE_DEBUG if (_clutter_diagnostic_enabled ()) clutter_warn_if_over_budget (master_clock, start, "Event processing"); master_clock->remaining_budget -= (g_get_monotonic_time () - start); #endif } /* * master_clock_advance_timelines: * @master_clock: a #ClutterMasterClock * * Advances all the timelines held by the master clock. This function * should be called before calling _clutter_stage_do_update() to * make sure that all the timelines are advanced and the scene is updated. */ static void master_clock_advance_timelines (ClutterMasterClockDefault *master_clock) { GSList *timelines, *l; #ifdef CLUTTER_ENABLE_DEBUG gint64 start = g_get_monotonic_time (); #endif /* we protect ourselves from timelines being removed during * the advancement by other timelines by copying the list of * timelines, taking a reference on them, iterating over the * copied list and then releasing the reference. * * we cannot simply take a reference on the timelines and still * use the list held by the master clock because the do_tick() * might result in the creation of a new timeline, which gets * added at the end of the list with no reference increase and * thus gets disposed at the end of the iteration. * * this implies that a newly added timeline will not be advanced * by this clock iteration, which is perfectly fine since we're * in its first cycle. * * we also cannot steal the master clock timelines list because * a timeline might be removed as the direct result of do_tick() * and remove_timeline() would not find the timeline, failing * and leaving a dangling pointer behind. */ timelines = g_slist_copy (master_clock->timelines); g_slist_foreach (timelines, (GFunc) g_object_ref, NULL); for (l = timelines; l != NULL; l = l->next) _clutter_timeline_do_tick (l->data, master_clock->cur_tick / 1000); g_slist_free_full (timelines, g_object_unref); #ifdef CLUTTER_ENABLE_DEBUG if (_clutter_diagnostic_enabled ()) clutter_warn_if_over_budget (master_clock, start, "Animations"); master_clock->remaining_budget -= (g_get_monotonic_time () - start); #endif } static gboolean master_clock_update_stages (ClutterMasterClockDefault *master_clock, GSList *stages) { gboolean stages_updated = FALSE; GSList *l; #ifdef CLUTTER_ENABLE_DEBUG gint64 start = g_get_monotonic_time (); #endif _clutter_run_repaint_functions (CLUTTER_REPAINT_FLAGS_PRE_PAINT); /* Update any stage that needs redraw/relayout after the clock * is advanced. */ for (l = stages; l != NULL; l = l->next) stages_updated |= _clutter_stage_do_update (l->data); _clutter_run_repaint_functions (CLUTTER_REPAINT_FLAGS_POST_PAINT); #ifdef CLUTTER_ENABLE_DEBUG if (_clutter_diagnostic_enabled ()) clutter_warn_if_over_budget (master_clock, start, "Updating the stage"); master_clock->remaining_budget -= (g_get_monotonic_time () - start); #endif return stages_updated; } /* * clutter_clock_source_new: * @master_clock: a #ClutterMasterClock for the source * * The #ClutterClockSource is an idle GSource that will queue a redraw * if @master_clock has at least a running #ClutterTimeline. The redraw * will cause @master_clock to advance all timelines, thus advancing all * animations as well. * * Return value: the newly created #GSource */ static GSource * clutter_clock_source_new (ClutterMasterClockDefault *master_clock) { GSource *source = g_source_new (&clock_funcs, sizeof (ClutterClockSource)); ClutterClockSource *clock_source = (ClutterClockSource *) source; g_source_set_name (source, "Clutter master clock"); g_source_set_priority (source, CLUTTER_PRIORITY_REDRAW); g_source_set_can_recurse (source, FALSE); clock_source->master_clock = master_clock; return source; } static gboolean clutter_clock_prepare (GSource *source, gint *timeout) { ClutterClockSource *clock_source = (ClutterClockSource *) source; ClutterMasterClockDefault *master_clock = clock_source->master_clock; int delay; _clutter_threads_acquire_lock (); if (G_UNLIKELY (clutter_paint_debug_flags & CLUTTER_DEBUG_CONTINUOUS_REDRAW)) { ClutterStageManager *stage_manager = clutter_stage_manager_get_default (); const GSList *stages, *l; stages = clutter_stage_manager_peek_stages (stage_manager); /* Queue a full redraw on all of the stages */ for (l = stages; l != NULL; l = l->next) clutter_actor_queue_redraw (l->data); } delay = master_clock_next_frame_delay (master_clock); _clutter_threads_release_lock (); *timeout = delay; return delay == 0; } static gboolean clutter_clock_check (GSource *source) { ClutterClockSource *clock_source = (ClutterClockSource *) source; ClutterMasterClockDefault *master_clock = clock_source->master_clock; int delay; _clutter_threads_acquire_lock (); delay = master_clock_next_frame_delay (master_clock); _clutter_threads_release_lock (); return delay == 0; } static gboolean clutter_clock_dispatch (GSource *source, GSourceFunc callback, gpointer user_data) { ClutterClockSource *clock_source = (ClutterClockSource *) source; ClutterMasterClockDefault *master_clock = clock_source->master_clock; GSList *stages; CLUTTER_NOTE (SCHEDULER, "Master clock [tick]"); _clutter_threads_acquire_lock (); COGL_TRACE_BEGIN (ClutterMasterClockTick, "Master Clock (tick)"); /* Get the time to use for this frame */ master_clock->cur_tick = master_clock_get_next_presentation_time (master_clock); /* On the first frame the backend might not have an answer */ if (master_clock->cur_tick <= 0) master_clock->cur_tick = g_source_get_time (source); #ifdef CLUTTER_ENABLE_DEBUG master_clock->remaining_budget = master_clock->frame_budget; #endif /* We need to protect ourselves against stages being destroyed during * event handling - master_clock_list_ready_stages() returns a * list of referenced that we'll unref afterwards. */ stages = master_clock_list_ready_stages (master_clock); /* Each frame is split into three separate phases: */ /* 1. process all the events; each stage goes through its events queue * and processes each event according to its type, then emits the * various signals that are associated with the event */ master_clock_process_events (master_clock, stages); /* 2. advance the timelines */ master_clock_advance_timelines (master_clock); /* 3. relayout and redraw the stages */ master_clock_update_stages (master_clock, stages); master_clock_reschedule_stage_updates (master_clock, stages); g_slist_free_full (stages, g_object_unref); COGL_TRACE_END (ClutterMasterClockTick); _clutter_threads_release_lock (); return TRUE; } static void clutter_master_clock_default_finalize (GObject *gobject) { ClutterMasterClockDefault *master_clock = CLUTTER_MASTER_CLOCK_DEFAULT (gobject); g_slist_free (master_clock->timelines); G_OBJECT_CLASS (clutter_master_clock_default_parent_class)->finalize (gobject); } static void clutter_master_clock_default_class_init (ClutterMasterClockDefaultClass *klass) { GObjectClass *gobject_class = G_OBJECT_CLASS (klass); gobject_class->finalize = clutter_master_clock_default_finalize; } static void clutter_master_clock_default_init (ClutterMasterClockDefault *self) { GSource *source; source = clutter_clock_source_new (self); self->source = source; self->ensure_next_iteration = FALSE; self->paused = FALSE; #ifdef CLUTTER_ENABLE_DEBUG self->frame_budget = G_USEC_PER_SEC / 60; #endif g_source_attach (source, NULL); } static void clutter_master_clock_default_add_timeline (ClutterMasterClock *clock, ClutterTimeline *timeline) { ClutterMasterClockDefault *master_clock = (ClutterMasterClockDefault *) clock; gboolean is_first; if (g_slist_find (master_clock->timelines, timeline)) return; is_first = master_clock->timelines == NULL; master_clock->timelines = g_slist_prepend (master_clock->timelines, timeline); if (is_first) { master_clock_schedule_stage_updates (master_clock); _clutter_master_clock_start_running (clock); } } static void clutter_master_clock_default_remove_timeline (ClutterMasterClock *clock, ClutterTimeline *timeline) { ClutterMasterClockDefault *master_clock = (ClutterMasterClockDefault *) clock; master_clock->timelines = g_slist_remove (master_clock->timelines, timeline); } static void clutter_master_clock_default_start_running (ClutterMasterClock *master_clock) { /* If called from a different thread, we need to wake up the * main loop to start running the timelines */ g_main_context_wakeup (NULL); } static void clutter_master_clock_default_ensure_next_iteration (ClutterMasterClock *clock) { ClutterMasterClockDefault *master_clock = (ClutterMasterClockDefault *) clock; master_clock->ensure_next_iteration = TRUE; } static void clutter_master_clock_default_set_paused (ClutterMasterClock *clock, gboolean paused) { ClutterMasterClockDefault *master_clock = (ClutterMasterClockDefault *) clock; if (paused && !master_clock->paused) { g_clear_pointer (&master_clock->source, g_source_destroy); } else if (!paused && master_clock->paused) { master_clock->source = clutter_clock_source_new (master_clock); g_source_attach (master_clock->source, NULL); } master_clock->paused = !!paused; } static void clutter_master_clock_iface_init (ClutterMasterClockInterface *iface) { iface->add_timeline = clutter_master_clock_default_add_timeline; iface->remove_timeline = clutter_master_clock_default_remove_timeline; iface->start_running = clutter_master_clock_default_start_running; iface->ensure_next_iteration = clutter_master_clock_default_ensure_next_iteration; iface->set_paused = clutter_master_clock_default_set_paused; }