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mutter-performance-source/tests/conform/test-timeline-smoothness.c
Robert Bragg 603f936745 Bug 1162 - Re-works the tests/ to use the glib-2.16 unit testing
framework

	* configure.ac:
	* tests/*:
	The tests have been reorganised into different categories: conformance,
	interactive and micro benchmarks.
	- conformance tests can be run as part of automated tests
	- interactive tests are basically all the existing tests
	- micro benchmarks focus on a single performance metric

	I converted the timeline tests to conformance tests and also added some
	tests from Neil Roberts and Ebassi.

	Note: currently only the conformance tests use the glib test APIs,
	though the micro benchmarks should too.

	The other change is to make the unit tests link into monolithic binaries
	which makes the build time for unit tests considerably faster. To deal
	with the extra complexity this adds to debugging individual tests I
	have added some sugar to the makefiles so all the tests can be run
	directly via a symlink and when an individual test is run this way,
	then a note is printed to the terminal explaining exactly how that test
	may be debugged using GDB.

	There is a convenience make rule: 'make test-report', that will run all
	the conformance tests and hopefully even open the results in your web
	browser. It skips some of the slower timeline tests, but you can run
	those using 'make full-report'
2008-11-07 19:32:28 +00:00

115 lines
2.4 KiB
C

#include <stdlib.h>
#include <glib.h>
#include <clutter/clutter.h>
#include "test-conform-common.h"
#define TEST_TIMELINE_FPS 10
#define TEST_TIMELINE_FRAME_COUNT 20
#define TEST_ERROR_TOLERANCE 5
typedef struct _TestState {
ClutterTimeline *timeline;
GTimeVal start_time;
GTimeVal prev_frame_time;
guint frame;
gint completion_count;
gint passed;
}TestState;
static void
new_frame_cb (ClutterTimeline *timeline,
gint frame_num,
TestState *state)
{
GTimeVal current_time;
glong total_elapsed_ms;
glong frame_elapsed_ms = 0;
gchar *bump = "";
g_get_current_time (&current_time);
total_elapsed_ms = (current_time.tv_sec - state->start_time.tv_sec) * 1000;
total_elapsed_ms += (current_time.tv_usec - state->start_time.tv_usec)/1000;
if (state->frame>0)
{
frame_elapsed_ms =
(current_time.tv_sec - state->prev_frame_time.tv_sec) * 1000;
frame_elapsed_ms +=
(current_time.tv_usec - state->prev_frame_time.tv_usec)/1000;
if (ABS(frame_elapsed_ms - (1000/TEST_TIMELINE_FPS))
> TEST_ERROR_TOLERANCE)
{
state->passed = FALSE;
bump = " (BUMP)";
}
}
g_test_message ("timeline frame=%-2d total elapsed=%-4li(ms) "
"since last frame=%-4li(ms)%s\n",
clutter_timeline_get_current_frame(state->timeline),
total_elapsed_ms,
frame_elapsed_ms,
bump);
state->prev_frame_time = current_time;
state->frame++;
}
static void
completed_cb (ClutterTimeline *timeline,
TestState *state)
{
state->completion_count++;
if (state->completion_count == 2)
{
if (state->passed)
{
g_test_message ("Passed\n");
clutter_main_quit ();
}
else
{
g_test_message ("Failed\n");
exit (EXIT_FAILURE);
}
}
}
void
test_timeline_smoothness (TestConformSimpleFixture *fixture,
gconstpointer data)
{
TestState state;
state.timeline =
clutter_timeline_new (TEST_TIMELINE_FRAME_COUNT,
TEST_TIMELINE_FPS);
clutter_timeline_set_loop (state.timeline, TRUE);
g_signal_connect (G_OBJECT(state.timeline),
"new-frame",
G_CALLBACK(new_frame_cb),
&state);
g_signal_connect (G_OBJECT(state.timeline),
"completed",
G_CALLBACK(completed_cb),
&state);
state.frame = 0;
state.completion_count = 0;
state.passed = TRUE;
g_get_current_time (&state.start_time);
clutter_timeline_start (state.timeline);
clutter_main();
g_object_unref (state.timeline);
}