Learning_GTK4_tree/gdk/gdkframeclock.c

/* GDK - The GIMP Drawing Kit
 * Copyright (C) 1995-1997 Peter Mattis, Spencer Kimball and Josh MacDonald
 *
 * 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 <http://www.gnu.org/licenses/>.
 */

/*
 * Modified by the GTK+ Team and others 1997-2010.  See the AUTHORS
 * file for a list of people on the GTK+ Team.  See the ChangeLog
 * files for a list of changes.  These files are distributed with
 * GTK+ at ftp://ftp.gtk.org/pub/gtk/.
 */

#include "config.h"

#include "gdkframeclockprivate.h"

/**
 * GdkFrameClock:
 *
 * A `GdkFrameClock` tells the application when to update and repaint
 * a surface.
 *
 * This may be synced to the vertical refresh rate of the monitor, for example.
 * Even when the frame clock uses a simple timer rather than a hardware-based
 * vertical sync, the frame clock helps because it ensures everything paints at
 * the same time (reducing the total number of frames).
 *
 * The frame clock can also automatically stop painting when it knows the frames
 * will not be visible, or scale back animation framerates.
 *
 * `GdkFrameClock` is designed to be compatible with an OpenGL-based implementation
 * or with mozRequestAnimationFrame in Firefox, for example.
 *
 * A frame clock is idle until someone requests a frame with
 * [method@Gdk.FrameClock.request_phase]. At some later point that makes sense
 * for the synchronization being implemented, the clock will process a frame and
 * emit signals for each phase that has been requested. (See the signals of the
 * `GdkFrameClock` class for documentation of the phases.
 * %GDK_FRAME_CLOCK_PHASE_UPDATE and the [signal@Gdk.FrameClock::update] signal
 * are most interesting for application writers, and are used to update the
 * animations, using the frame time given by [method@Gdk.FrameClock.get_frame_time].
 *
 * The frame time is reported in microseconds and generally in the same
 * timescale as g_get_monotonic_time(), however, it is not the same
 * as g_get_monotonic_time(). The frame time does not advance during
 * the time a frame is being painted, and outside of a frame, an attempt
 * is made so that all calls to [method@Gdk.FrameClock.get_frame_time] that
 * are called at a “similar” time get the same value. This means that
 * if different animations are timed by looking at the difference in
 * time between an initial value from [method@Gdk.FrameClock.get_frame_time]
 * and the value inside the [signal@Gdk.FrameClock::update] signal of the clock,
 * they will stay exactly synchronized.
 */

enum {
  FLUSH_EVENTS,
  BEFORE_PAINT,
  UPDATE,
  LAYOUT,
  PAINT,
  AFTER_PAINT,
  RESUME_EVENTS,
  LAST_SIGNAL
};

static guint signals[LAST_SIGNAL];

static guint fps_counter;

#define FRAME_HISTORY_MAX_LENGTH 128

struct _GdkFrameClockPrivate
{
  gint64 frame_counter;
  int n_timings;
  int current;
  GdkFrameTimings *timings[FRAME_HISTORY_MAX_LENGTH];
  int n_freeze_inhibitors;
};

G_DEFINE_ABSTRACT_TYPE_WITH_PRIVATE (GdkFrameClock, gdk_frame_clock, G_TYPE_OBJECT)

static void
_gdk_frame_clock_freeze (GdkFrameClock *clock);

static void
gdk_frame_clock_finalize (GObject *object)
{
  GdkFrameClockPrivate *priv = GDK_FRAME_CLOCK (object)->priv;
  int i;

  for (i = 0; i < FRAME_HISTORY_MAX_LENGTH; i++)
    if (priv->timings[i] != 0)
      gdk_frame_timings_unref (priv->timings[i]);

  G_OBJECT_CLASS (gdk_frame_clock_parent_class)->finalize (object);
}

static void
gdk_frame_clock_constructed (GObject *object)
{
  G_OBJECT_CLASS (gdk_frame_clock_parent_class)->constructed (object);

  _gdk_frame_clock_freeze (GDK_FRAME_CLOCK (object));
}

static void
gdk_frame_clock_class_init (GdkFrameClockClass *klass)
{
  GObjectClass *gobject_class = (GObjectClass*) klass;

  gobject_class->finalize     = gdk_frame_clock_finalize;
  gobject_class->constructed  = gdk_frame_clock_constructed;

  /**
   * GdkFrameClock::flush-events:
   * @clock: the frame clock emitting the signal
   *
   * Used to flush pending motion events that are being batched up and
   * compressed together.
   *
   * Applications should not handle this signal.
   */
  signals[FLUSH_EVENTS] =
    g_signal_new (g_intern_static_string ("flush-events"),
                  GDK_TYPE_FRAME_CLOCK,
                  G_SIGNAL_RUN_LAST,
                  0,
                  NULL, NULL, NULL,
                  G_TYPE_NONE, 0);

  /**
   * GdkFrameClock::before-paint:
   * @clock: the frame clock emitting the signal
   *
   * Begins processing of the frame.
   *
   * Applications should generally not handle this signal.
   */
  signals[BEFORE_PAINT] =
    g_signal_new (g_intern_static_string ("before-paint"),
                  GDK_TYPE_FRAME_CLOCK,
                  G_SIGNAL_RUN_LAST,
                  0,
                  NULL, NULL, NULL,
                  G_TYPE_NONE, 0);

  /**
   * GdkFrameClock::update:
   * @clock: the frame clock emitting the signal
   *
   * Emitted as the first step of toolkit and application processing
   * of the frame.
   *
   * Animations should be updated using [method@Gdk.FrameClock.get_frame_time].
   * Applications can connect directly to this signal, or use
   * [method@Gtk.Widget.add_tick_callback] as a more convenient interface.
   */
  signals[UPDATE] =
    g_signal_new (g_intern_static_string ("update"),
                  GDK_TYPE_FRAME_CLOCK,
                  G_SIGNAL_RUN_LAST,
                  0,
                  NULL, NULL, NULL,
                  G_TYPE_NONE, 0);

  /**
   * GdkFrameClock::layout:
   * @clock: the frame clock emitting the signal
   *
   * Emitted as the second step of toolkit and application processing
   * of the frame.
   *
   * Any work to update sizes and positions of application elements
   * should be performed. GTK normally handles this internally.
   */
  signals[LAYOUT] =
    g_signal_new (g_intern_static_string ("layout"),
                  GDK_TYPE_FRAME_CLOCK,
                  G_SIGNAL_RUN_LAST,
                  0,
                  NULL, NULL, NULL,
                  G_TYPE_NONE, 0);

  /**
   * GdkFrameClock::paint:
   * @clock: the frame clock emitting the signal
   *
   * Emitted as the third step of toolkit and application processing
   * of the frame.
   *
   * The frame is repainted. GDK normally handles this internally and
   * emits [signal@Gdk.Surface::render] signals which are turned into
   * [signal@Gtk.Widget::snapshot] signals by GTK.
   */
  signals[PAINT] =
    g_signal_new (g_intern_static_string ("paint"),
                  GDK_TYPE_FRAME_CLOCK,
                  G_SIGNAL_RUN_LAST,
                  0,
                  NULL, NULL, NULL,
                  G_TYPE_NONE, 0);

  /**
   * GdkFrameClock::after-paint:
   * @clock: the frame clock emitting the signal
   *
   * This signal ends processing of the frame.
   *
   * Applications should generally not handle this signal.
   */
  signals[AFTER_PAINT] =
    g_signal_new (g_intern_static_string ("after-paint"),
                  GDK_TYPE_FRAME_CLOCK,
                  G_SIGNAL_RUN_LAST,
                  0,
                  NULL, NULL, NULL,
                  G_TYPE_NONE, 0);

  /**
   * GdkFrameClock::resume-events:
   * @clock: the frame clock emitting the signal
   *
   * Emitted after processing of the frame is finished.
   *
   * This signal is handled internally by GTK to resume normal
   * event processing. Applications should not handle this signal.
   */
  signals[RESUME_EVENTS] =
    g_signal_new (g_intern_static_string ("resume-events"),
                  GDK_TYPE_FRAME_CLOCK,
                  G_SIGNAL_RUN_LAST,
                  0,
                  NULL, NULL, NULL,
                  G_TYPE_NONE, 0);
}

static void
gdk_frame_clock_init (GdkFrameClock *clock)
{
  GdkFrameClockPrivate *priv;

  clock->priv = priv = gdk_frame_clock_get_instance_private (clock);

  priv->frame_counter = -1;
  priv->current = FRAME_HISTORY_MAX_LENGTH - 1;

  if (fps_counter == 0)
    fps_counter = gdk_profiler_define_counter ("fps", "Frames per Second");
}

/**
 * gdk_frame_clock_get_frame_time:
 * @frame_clock: a `GdkFrameClock`
 *
 * Gets the time that should currently be used for animations.
 *
 * Inside the processing of a frame, it’s the time used to compute the
 * animation position of everything in a frame. Outside of a frame, it's
 * the time of the conceptual “previous frame,” which may be either
 * the actual previous frame time, or if that’s too old, an updated
 * time.
 *
 * Returns: a timestamp in microseconds, in the timescale of
 *  of g_get_monotonic_time().
 */
gint64
gdk_frame_clock_get_frame_time (GdkFrameClock *frame_clock)
{
  g_return_val_if_fail (GDK_IS_FRAME_CLOCK (frame_clock), 0);

  return GDK_FRAME_CLOCK_GET_CLASS (frame_clock)->get_frame_time (frame_clock);
}

/**
 * gdk_frame_clock_request_phase:
 * @frame_clock: a `GdkFrameClock`
 * @phase: the phase that is requested
 *
 * Asks the frame clock to run a particular phase.
 *
 * The signal corresponding the requested phase will be emitted the next
 * time the frame clock processes. Multiple calls to
 * gdk_frame_clock_request_phase() will be combined together
 * and only one frame processed. If you are displaying animated
 * content and want to continually request the
 * %GDK_FRAME_CLOCK_PHASE_UPDATE phase for a period of time,
 * you should use [method@Gdk.FrameClock.begin_updating] instead,
 * since this allows GTK to adjust system parameters to get maximally
 * smooth animations.
 */
void
gdk_frame_clock_request_phase (GdkFrameClock      *frame_clock,
                               GdkFrameClockPhase  phase)
{
  g_return_if_fail (GDK_IS_FRAME_CLOCK (frame_clock));

  GDK_FRAME_CLOCK_GET_CLASS (frame_clock)->request_phase (frame_clock, phase);
}

/**
 * gdk_frame_clock_begin_updating:
 * @frame_clock: a `GdkFrameClock`
 *
 * Starts updates for an animation.
 *
 * Until a matching call to [method@Gdk.FrameClock.end_updating] is made,
 * the frame clock will continually request a new frame with the
 * %GDK_FRAME_CLOCK_PHASE_UPDATE phase. This function may be called multiple
 * times and frames will be requested until gdk_frame_clock_end_updating()
 * is called the same number of times.
 */
void
gdk_frame_clock_begin_updating (GdkFrameClock *frame_clock)
{
  g_return_if_fail (GDK_IS_FRAME_CLOCK (frame_clock));

  GDK_FRAME_CLOCK_GET_CLASS (frame_clock)->begin_updating (frame_clock);
}

/**
 * gdk_frame_clock_end_updating:
 * @frame_clock: a `GdkFrameClock`
 *
 * Stops updates for an animation.
 *
 * See the documentation for [method@Gdk.FrameClock.begin_updating].
 */
void
gdk_frame_clock_end_updating (GdkFrameClock *frame_clock)
{
  g_return_if_fail (GDK_IS_FRAME_CLOCK (frame_clock));

  GDK_FRAME_CLOCK_GET_CLASS (frame_clock)->end_updating (frame_clock);
}

static inline void
_gdk_frame_clock_freeze (GdkFrameClock *clock)
{
  GDK_FRAME_CLOCK_GET_CLASS (clock)->freeze (clock);
}

static inline void
_gdk_frame_clock_thaw (GdkFrameClock *clock)
{
  GDK_FRAME_CLOCK_GET_CLASS (clock)->thaw (clock);
}

void
_gdk_frame_clock_inhibit_freeze (GdkFrameClock *clock)
{
  GdkFrameClockPrivate *priv;

  g_return_if_fail (GDK_IS_FRAME_CLOCK (clock));

  priv = clock->priv;

  priv->n_freeze_inhibitors++;
  if (priv->n_freeze_inhibitors == 1)
    _gdk_frame_clock_thaw (clock);
}

void
_gdk_frame_clock_uninhibit_freeze (GdkFrameClock *clock)
{
  GdkFrameClockPrivate *priv;

  g_return_if_fail (GDK_IS_FRAME_CLOCK (clock));

  priv = clock->priv;

  priv->n_freeze_inhibitors--;
  if (priv->n_freeze_inhibitors == 0)
    _gdk_frame_clock_freeze (clock);
}

static inline gint64
_gdk_frame_clock_get_frame_counter (GdkFrameClock *frame_clock)
{
  return frame_clock->priv->frame_counter;
}

/**
 * gdk_frame_clock_get_frame_counter:
 * @frame_clock: a `GdkFrameClock`
 *
 * `GdkFrameClock` maintains a 64-bit counter that increments for
 * each frame drawn.
 *
 * Returns: inside frame processing, the value of the frame counter
 *   for the current frame. Outside of frame processing, the frame
 *   counter for the last frame.
 */
gint64
gdk_frame_clock_get_frame_counter (GdkFrameClock *frame_clock)
{
  g_return_val_if_fail (GDK_IS_FRAME_CLOCK (frame_clock), 0);

  return _gdk_frame_clock_get_frame_counter (frame_clock);
}

static inline gint64
_gdk_frame_clock_get_history_start (GdkFrameClock *frame_clock)
{
  return frame_clock->priv->frame_counter + 1 - frame_clock->priv->n_timings;
}

/**
 * gdk_frame_clock_get_history_start:
 * @frame_clock: a `GdkFrameClock`
 *
 * Returns the frame counter for the oldest frame available in history.
 *
 * `GdkFrameClock` internally keeps a history of `GdkFrameTimings`
 * objects for recent frames that can be retrieved with
 * [method@Gdk.FrameClock.get_timings]. The set of stored frames
 * is the set from the counter values given by
 * [method@Gdk.FrameClock.get_history_start] and
 * [method@Gdk.FrameClock.get_frame_counter], inclusive.
 *
 * Returns: the frame counter value for the oldest frame
 *  that is available in the internal frame history of the
 *  `GdkFrameClock`
 */
gint64
gdk_frame_clock_get_history_start (GdkFrameClock *frame_clock)
{
  g_return_val_if_fail (GDK_IS_FRAME_CLOCK (frame_clock), 0);

  return _gdk_frame_clock_get_history_start (frame_clock);
}

void
_gdk_frame_clock_begin_frame (GdkFrameClock *frame_clock)
{
  GdkFrameClockPrivate *priv;

  g_return_if_fail (GDK_IS_FRAME_CLOCK (frame_clock));

  priv = frame_clock->priv;

  priv->frame_counter++;
  priv->current = (priv->current + 1) % FRAME_HISTORY_MAX_LENGTH;

  /* Try to steal the previous frame timing instead of discarding
   * and allocating a new one.
   */
  if G_LIKELY (priv->n_timings == FRAME_HISTORY_MAX_LENGTH &&
               _gdk_frame_timings_steal (priv->timings[priv->current],
                                         priv->frame_counter))
    return;

  if (priv->n_timings < FRAME_HISTORY_MAX_LENGTH)
    priv->n_timings++;
  else
    gdk_frame_timings_unref (priv->timings[priv->current]);

  priv->timings[priv->current] = _gdk_frame_timings_new (priv->frame_counter);
}

static inline GdkFrameTimings *
_gdk_frame_clock_get_timings (GdkFrameClock *frame_clock,
                              gint64         frame_counter)
{
  GdkFrameClockPrivate *priv = frame_clock->priv;
  int pos;

  if (frame_counter > priv->frame_counter)
    return NULL;

  if (frame_counter <= priv->frame_counter - priv->n_timings)
    return NULL;

  pos = (priv->current - (priv->frame_counter - frame_counter) + FRAME_HISTORY_MAX_LENGTH) % FRAME_HISTORY_MAX_LENGTH;

  return priv->timings[pos];
}

/**
 * gdk_frame_clock_get_timings:
 * @frame_clock: a `GdkFrameClock`
 * @frame_counter: the frame counter value identifying the frame to
 *  be received
 *
 * Retrieves a `GdkFrameTimings` object holding timing information
 * for the current frame or a recent frame.
 *
 * The `GdkFrameTimings` object may not yet be complete: see
 * [method@Gdk.FrameTimings.get_complete] and
 * [method@Gdk.FrameClock.get_history_start].
 *
 * Returns: (nullable) (transfer none): the `GdkFrameTimings` object
 *   for the specified frame, or %NULL if it is not available
 */
GdkFrameTimings *
gdk_frame_clock_get_timings (GdkFrameClock *frame_clock,
                             gint64         frame_counter)
{
  g_return_val_if_fail (GDK_IS_FRAME_CLOCK (frame_clock), NULL);

  return _gdk_frame_clock_get_timings (frame_clock, frame_counter);
}

/**
 * gdk_frame_clock_get_current_timings:
 * @frame_clock: a `GdkFrameClock`
 *
 * Gets the frame timings for the current frame.
 *
 * Returns: (nullable) (transfer none): the `GdkFrameTimings` for the
 *   frame currently being processed, or even no frame is being
 *   processed, for the previous frame. Before any frames have been
 *   processed, returns %NULL.
 */
GdkFrameTimings *
gdk_frame_clock_get_current_timings (GdkFrameClock *frame_clock)
{
  GdkFrameClockPrivate *priv;

  g_return_val_if_fail (GDK_IS_FRAME_CLOCK (frame_clock), 0);

  priv = frame_clock->priv;

  return _gdk_frame_clock_get_timings (frame_clock, priv->frame_counter);
}

void
_gdk_frame_clock_debug_print_timings (GdkFrameClock   *clock,
                                      GdkFrameTimings *timings)
{
  GString *str;

  gint64 previous_frame_time = 0;
  gint64 previous_smoothed_frame_time = 0;
  GdkFrameTimings *previous_timings = _gdk_frame_clock_get_timings (clock,
                                                                    timings->frame_counter - 1);

  if (previous_timings != NULL)
    {
      previous_frame_time = previous_timings->frame_time;
      previous_smoothed_frame_time = previous_timings->smoothed_frame_time;
    }

  str = g_string_new ("");

  g_string_append_printf (str, "%5" G_GINT64_FORMAT ":", timings->frame_counter);
  if (previous_frame_time != 0)
    {
      g_string_append_printf (str, " interval=%-4.1f", (timings->frame_time - previous_frame_time) / 1000.);
      g_string_append_printf (str, timings->slept_before ?  " (sleep)" : "        ");
      g_string_append_printf (str, " smoothed=%4.1f / %-4.1f",
                              (timings->smoothed_frame_time - timings->frame_time) / 1000.,
                              (timings->smoothed_frame_time - previous_smoothed_frame_time) / 1000.);
    }
  if (timings->layout_start_time != 0)
    g_string_append_printf (str, " layout_start=%-4.1f", (timings->layout_start_time - timings->frame_time) / 1000.);
  if (timings->paint_start_time != 0)
    g_string_append_printf (str, " paint_start=%-4.1f", (timings->paint_start_time - timings->frame_time) / 1000.);
  if (timings->frame_end_time != 0)
    g_string_append_printf (str, " frame_end=%-4.1f", (timings->frame_end_time - timings->frame_time) / 1000.);
  if (timings->drawn_time != 0)
    g_string_append_printf (str, " drawn=%-4.1f", (timings->drawn_time - timings->frame_time) / 1000.);
  if (timings->presentation_time != 0)
    g_string_append_printf (str, " present=%-4.1f", (timings->presentation_time - timings->frame_time) / 1000.);
  if (timings->predicted_presentation_time != 0)
    g_string_append_printf (str, " predicted=%-4.1f", (timings->predicted_presentation_time - timings->frame_time) / 1000.);
  if (timings->refresh_interval != 0)
    g_string_append_printf (str, " refresh_interval=%-4.1f", timings->refresh_interval / 1000.);

  g_message ("%s", str->str);
  g_string_free (str, TRUE);
}

#define DEFAULT_REFRESH_INTERVAL 16667 /* 16.7ms (1/60th second) */
#define MAX_HISTORY_AGE 150000         /* 150ms */

/**
 * gdk_frame_clock_get_refresh_info:
 * @frame_clock: a `GdkFrameClock`
 * @base_time: base time for determining a presentaton time
 * @refresh_interval_return: (out) (optional): a location to store the
 *   determined refresh interval, or %NULL. A default refresh interval of
 *   1/60th of a second will be stored if no history is present.
 * @presentation_time_return: (out): a location to store the next
 *   candidate presentation time after the given base time.
 *   0 will be will be stored if no history is present.
 *
 * Predicts a presentation time, based on history.
 *
 * Using the frame history stored in the frame clock, finds the last
 * known presentation time and refresh interval, and assuming that
 * presentation times are separated by the refresh interval,
 * predicts a presentation time that is a multiple of the refresh
 * interval after the last presentation time, and later than @base_time.
 */
void
gdk_frame_clock_get_refresh_info (GdkFrameClock *frame_clock,
                                  gint64         base_time,
                                  gint64        *refresh_interval_return,
                                  gint64        *presentation_time_return)
{
  gint64 frame_counter;
  gint64 default_refresh_interval = DEFAULT_REFRESH_INTERVAL;

  g_return_if_fail (GDK_IS_FRAME_CLOCK (frame_clock));

  frame_counter = _gdk_frame_clock_get_frame_counter (frame_clock);

  while (TRUE)
    {
      GdkFrameTimings *timings = _gdk_frame_clock_get_timings (frame_clock, frame_counter);
      gint64 presentation_time;
      gint64 refresh_interval;

      if (timings == NULL)
        break;

      refresh_interval = timings->refresh_interval;
      presentation_time = timings->presentation_time;

      if (refresh_interval == 0)
        refresh_interval = default_refresh_interval;
      else
        default_refresh_interval = refresh_interval;

      if (presentation_time != 0)
        {
          if (presentation_time > base_time - MAX_HISTORY_AGE &&
              presentation_time_return)
            {
              if (refresh_interval_return)
                *refresh_interval_return = refresh_interval;

              while (presentation_time < base_time)
                presentation_time += refresh_interval;

              if (presentation_time_return)
                *presentation_time_return = presentation_time;

              return;
            }

          break;
        }

      frame_counter--;
    }

  if (presentation_time_return)
    *presentation_time_return = 0;
  if (refresh_interval_return)
    *refresh_interval_return = default_refresh_interval;
}

void
_gdk_frame_clock_emit_flush_events (GdkFrameClock *frame_clock)
{
  g_signal_emit (frame_clock, signals[FLUSH_EVENTS], 0);
}

void
_gdk_frame_clock_emit_before_paint (GdkFrameClock *frame_clock)
{
  g_signal_emit (frame_clock, signals[BEFORE_PAINT], 0);
}

void
_gdk_frame_clock_emit_update (GdkFrameClock *frame_clock)
{
  gint64 before G_GNUC_UNUSED;

  before = GDK_PROFILER_CURRENT_TIME;

  g_signal_emit (frame_clock, signals[UPDATE], 0);

  gdk_profiler_end_mark (before, "frameclock update", NULL);
}

void
_gdk_frame_clock_emit_layout (GdkFrameClock *frame_clock)
{
  gint64 before G_GNUC_UNUSED;

  before = GDK_PROFILER_CURRENT_TIME;

  g_signal_emit (frame_clock, signals[LAYOUT], 0);

  gdk_profiler_end_mark (before, "frameclock layout", NULL);
}

void
_gdk_frame_clock_emit_paint (GdkFrameClock *frame_clock)
{
  gint64 before G_GNUC_UNUSED;

  before = GDK_PROFILER_CURRENT_TIME;

  g_signal_emit (frame_clock, signals[PAINT], 0);

  gdk_profiler_end_mark (before, "frameclock paint", NULL);
}

void
_gdk_frame_clock_emit_after_paint (GdkFrameClock *frame_clock)
{
  g_signal_emit (frame_clock, signals[AFTER_PAINT], 0);
}

void
_gdk_frame_clock_emit_resume_events (GdkFrameClock *frame_clock)
{
  g_signal_emit (frame_clock, signals[RESUME_EVENTS], 0);
}

static gint64
guess_refresh_interval (GdkFrameClock *frame_clock)
{
  gint64 interval;
  gint64 i;

  interval = G_MAXINT64;

  for (i = _gdk_frame_clock_get_history_start (frame_clock);
       i < _gdk_frame_clock_get_frame_counter (frame_clock);
       i++)
    {
      GdkFrameTimings *t, *before;
      gint64 ts, before_ts;

      t = _gdk_frame_clock_get_timings (frame_clock, i);
      before = _gdk_frame_clock_get_timings (frame_clock, i - 1);
      if (t == NULL || before == NULL)
        continue;

      ts = gdk_frame_timings_get_frame_time (t);
      before_ts = gdk_frame_timings_get_frame_time (before);
      if (ts == 0 || before_ts == 0)
        continue;

      interval = MIN (interval, ts - before_ts);
    }

  if (interval == G_MAXINT64)
    return 0;

  return interval;
}

/**
 * gdk_frame_clock_get_fps:
 * @frame_clock: a `GdkFrameClock`
 *
 * Calculates the current frames-per-second, based on the
 * frame timings of @frame_clock.
 *
 * Returns: the current fps, as a `double`
 */
double
gdk_frame_clock_get_fps (GdkFrameClock *frame_clock)
{
  GdkFrameTimings *start, *end;
  gint64 start_counter, end_counter;
  gint64 start_timestamp, end_timestamp;
  gint64 interval;

  start_counter = _gdk_frame_clock_get_history_start (frame_clock);
  end_counter = _gdk_frame_clock_get_frame_counter (frame_clock);
  start = _gdk_frame_clock_get_timings (frame_clock, start_counter);
  for (end = _gdk_frame_clock_get_timings (frame_clock, end_counter);
       end_counter > start_counter && end != NULL && !gdk_frame_timings_get_complete (end);
       end = _gdk_frame_clock_get_timings (frame_clock, end_counter))
    end_counter--;
  if (end_counter - start_counter < 4)
    return 0.0;

  start_timestamp = gdk_frame_timings_get_presentation_time (start);
  end_timestamp = gdk_frame_timings_get_presentation_time (end);
  if (start_timestamp == 0 || end_timestamp == 0)
    {
      start_timestamp = gdk_frame_timings_get_frame_time (start);
      end_timestamp = gdk_frame_timings_get_frame_time (end);
    }
  interval = gdk_frame_timings_get_refresh_interval (end);
  if (interval == 0)
    {
      interval = guess_refresh_interval (frame_clock);
      if (interval == 0)
        return 0.0;
    }

  return ((double) end_counter - start_counter) * G_USEC_PER_SEC / (end_timestamp - start_timestamp);
}

void
_gdk_frame_clock_add_timings_to_profiler (GdkFrameClock   *clock,
                                          GdkFrameTimings *timings)
{
  if (timings->drawn_time != 0)
    {
      gdk_profiler_add_mark (1000 * timings->drawn_time, 0, "drawn window", NULL);
    }

  if (timings->presentation_time != 0)
    {
      gdk_profiler_add_mark (1000 * timings->presentation_time, 0, "presented window", NULL);
    }

  gdk_profiler_set_counter (fps_counter, gdk_frame_clock_get_fps (clock));
}