mirror of
https://github.com/brl/mutter.git
synced 2024-11-23 16:40:41 -05:00
77ec8774a0
Revert all the work that happened on the master branch.
Sadly, this is the only way to merge the current development branch back
into master.
It is now abundantly clear that I merged the 1.99 branch far too soon,
and that Clutter 2.0 won't happen any time soon, if at all.
Since having the development happen on a separate branch throws a lot of
people into confusion, let's undo the clutter-1.99 → master merge, and
move back the development of Clutter to the master branch.
In order to do so, we need to do some surgery to the Git repository.
First, we do a massive revert in a single commit of all that happened
since the switch to 1.99 and the API version bump done with the
89a2862b05
commit. The history is too long
to be reverted commit by commit without being extremely messy.
163 lines
4.0 KiB
C
163 lines
4.0 KiB
C
#include <stdlib.h>
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#include <glib.h>
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#include <clutter/clutter.h>
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#include "test-conform-common.h"
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/* We ask for 1 frame per millisecond.
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* Whenever this rate can't be achieved then the timeline
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* will interpolate the number frames that should have
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* passed between timeouts. */
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#define TEST_TIMELINE_FPS 1000
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#define TEST_TIMELINE_DURATION 5000
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/* We are at the mercy of the system scheduler so this
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* may not be a very reliable tolerance. */
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#define TEST_ERROR_TOLERANCE 20
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typedef struct _TestState
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{
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ClutterTimeline *timeline;
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GTimeVal start_time;
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guint new_frame_counter;
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gint expected_frame;
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gint completion_count;
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gboolean passed;
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} TestState;
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static void
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new_frame_cb (ClutterTimeline *timeline,
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gint frame_num,
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TestState *state)
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{
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GTimeVal current_time;
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gint current_frame;
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glong msec_diff;
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gint loop_overflow = 0;
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static gint step = 1;
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g_get_current_time (¤t_time);
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current_frame = clutter_timeline_get_elapsed_time (state->timeline);
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msec_diff = (current_time.tv_sec - state->start_time.tv_sec) * 1000;
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msec_diff += (current_time.tv_usec - state->start_time.tv_usec)/1000;
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/* If we expect to have interpolated past the end of the timeline
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* we keep track of the overflow so we can determine when
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* the next timeout will happen. We then clip expected_frames
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* to TEST_TIMELINE_DURATION since clutter-timeline
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* semantics guaranty this frame is always signaled before
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* looping */
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if (state->expected_frame > TEST_TIMELINE_DURATION)
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{
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loop_overflow = state->expected_frame - TEST_TIMELINE_DURATION;
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state->expected_frame = TEST_TIMELINE_DURATION;
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}
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if (current_frame >= (state->expected_frame-TEST_ERROR_TOLERANCE)
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&& current_frame <= (state->expected_frame+TEST_ERROR_TOLERANCE))
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{
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g_test_message ("elapsed milliseconds=%-5li "
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"expected frame=%-4i actual frame=%-4i (OK)",
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msec_diff,
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state->expected_frame,
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current_frame);
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}
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else
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{
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g_test_message ("elapsed milliseconds=%-5li "
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"expected frame=%-4i actual frame=%-4i (FAILED)",
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msec_diff,
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state->expected_frame,
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current_frame);
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state->passed = FALSE;
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}
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if (step>0)
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{
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state->expected_frame = current_frame + (TEST_TIMELINE_FPS / 4);
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g_test_message ("Sleeping for 250ms "
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"so next frame should be (%i + %i) = %i",
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current_frame,
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(TEST_TIMELINE_FPS / 4),
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state->expected_frame);
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g_usleep (250000);
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}
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else
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{
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state->expected_frame = current_frame + TEST_TIMELINE_FPS;
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g_test_message ("Sleeping for 1sec "
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"so next frame should be (%i + %i) = %i",
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current_frame,
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TEST_TIMELINE_FPS,
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state->expected_frame);
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g_usleep (1000000);
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}
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if (current_frame >= TEST_TIMELINE_DURATION)
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{
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state->expected_frame += loop_overflow;
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state->expected_frame -= TEST_TIMELINE_DURATION;
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g_test_message ("End of timeline reached: "
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"Wrapping expected frame too %i",
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state->expected_frame);
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}
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state->new_frame_counter++;
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step = -step;
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}
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static void
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completed_cb (ClutterTimeline *timeline,
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TestState *state)
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{
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state->completion_count++;
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if (state->completion_count == 2)
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{
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if (state->passed)
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{
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g_test_message ("Passed\n");
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clutter_main_quit ();
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}
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else
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{
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g_test_message ("Failed\n");
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exit (EXIT_FAILURE);
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}
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}
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}
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void
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timeline_interpolation (void)
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{
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TestState state;
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state.timeline =
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clutter_timeline_new (TEST_TIMELINE_DURATION);
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clutter_timeline_set_loop (state.timeline, TRUE);
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g_signal_connect (G_OBJECT(state.timeline),
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"new-frame",
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G_CALLBACK(new_frame_cb),
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&state);
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g_signal_connect (G_OBJECT(state.timeline),
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"completed",
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G_CALLBACK(completed_cb),
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&state);
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state.completion_count = 0;
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state.new_frame_counter = 0;
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state.passed = TRUE;
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state.expected_frame = 0;
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g_get_current_time (&state.start_time);
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clutter_timeline_start (state.timeline);
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clutter_main();
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g_object_unref (state.timeline);
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}
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