mingw/glib2/glib/tests/timeout.c - kiwivm - Git at Google

 #include <glib.h>
 #ifdef G_OS_UNIX
 #include <unistd.h>
 #endif

 static GMainLoop *loop;

 static gboolean
 stop_waiting (gpointer data)
 {
   g_main_loop_quit (loop);

   return G_SOURCE_REMOVE;
 }

 static gboolean
 unreachable_callback (gpointer data)
 {
   g_assert_not_reached ();

   return G_SOURCE_REMOVE;
 }

 static void
 test_seconds (void)
 {
   guint id;

   /* Bug 642052 mentions that g_timeout_add_seconds(21475) schedules a
    * job that runs once per second.
    *
    * Test that that isn't true anymore by scheduling two jobs:
    *   - one, as above
    *   - another that runs in 2100ms
    *
    * If everything is working properly, the 2100ms one should run first
    * (and exit the mainloop).  If we ever see the 21475 second job run
    * then we have trouble (since it ran in less than 2 seconds).
    *
    * We need a timeout of at least 2 seconds because
    * g_timeout_add_seconds() can add as much as an additional second of
    * latency.
    */
   g_test_bug ("https://bugzilla.gnome.org/show_bug.cgi?id=642052");
   loop = g_main_loop_new (NULL, FALSE);

   g_timeout_add (2100, stop_waiting, NULL);
   id = g_timeout_add_seconds (21475, unreachable_callback, NULL);

   g_main_loop_run (loop);
   g_main_loop_unref (loop);

   g_source_remove (id);
 }

 static void
 test_weeks_overflow (void)
 {
   guint id;
   guint interval_seconds;

   /* Internally, the guint interval (in seconds) was converted to milliseconds
    * then stored in a guint variable. This meant that any interval larger than
    * G_MAXUINT / 1000 would overflow.
    *
    * On a system with 32-bit guint, the interval (G_MAXUINT / 1000) + 1 seconds
    * (49.7 days) would end wrapping to 704 milliseconds.
    *
    * Test that that isn't true anymore by scheduling two jobs:
    *   - one, as above
    *   - another that runs in 2100ms
    *
    * If everything is working properly, the 2100ms one should run first
    * (and exit the mainloop).  If we ever see the other job run
    * then we have trouble (since it ran in less than 2 seconds).
    *
    * We need a timeout of at least 2 seconds because
    * g_timeout_add_seconds() can add as much as an additional second of
    * latency.
    */
   g_test_bug ("https://gitlab.gnome.org/GNOME/glib/issues/1600");
   loop = g_main_loop_new (NULL, FALSE);

   g_timeout_add (2100, stop_waiting, NULL);
   interval_seconds = 1 + G_MAXUINT / 1000;
   id = g_timeout_add_seconds (interval_seconds, unreachable_callback, NULL);

   g_main_loop_run (loop);
   g_main_loop_unref (loop);

   g_source_remove (id);
 }

 /* The ready_time for a GSource is stored as a gint64, as an absolute monotonic
  * time in microseconds. To call poll(), this must be converted to a relative
  * timeout, in milliseconds, as a gint. If the ready_time is sufficiently far
  * in the future, the timeout will not fit. Previously, it would be narrowed in
  * an implementation-defined way; if this gave a negative result, poll() would
  * block forever.
  *
  * This test creates a GSource with the largest possible ready_time (a little
  * over 292 millennia, assuming g_get_monotonic_time() starts from near 0 when
  * the system boots), adds it to a GMainContext, queries it for the parameters
  * to pass to poll() -- essentially the first half of
  * g_main_context_iteration() -- and checks that the timeout is a large
  * positive number.
  */
 static void
 test_far_future_ready_time (void)
 {
   GSourceFuncs source_funcs = { 0 };
   GMainContext *context = g_main_context_new ();
   GSource *source = g_source_new (&source_funcs, sizeof (GSource));
   gboolean acquired, ready;
   gint priority, timeout_, n_fds;

   g_source_set_ready_time (source, G_MAXINT64);
   g_source_attach (source, context);

   acquired = g_main_context_acquire (context);
   g_assert_true (acquired);

   ready = g_main_context_prepare (context, &priority);
   g_assert_false (ready);

   n_fds = 0;
   n_fds = g_main_context_query (context, priority, &timeout_, NULL, n_fds);

   g_assert_cmpint (n_fds, >=, 0);

   /* The true timeout in milliseconds doesn't fit into a gint. We definitely
    * don't want poll() to block forever:
    */
   g_assert_cmpint (timeout_, >=, 0);
   /* Instead, we want it to block for as long as possible: */
   g_assert_cmpint (timeout_, ==, G_MAXINT);

   g_main_context_release (context);
   g_main_context_unref (context);
   g_source_unref (source);
 }

 static gint64 last_time;
 static gint count;

 static gboolean
 test_func (gpointer data)
 {
   gint64 current_time;

   current_time = g_get_monotonic_time ();

   /* We accept 2 on the first iteration because _add_seconds() can
    * have an initial latency of 1 second, see its documentation.
    *
    * Allow up to 500ms leeway for rounding and scheduling.
    */
   if (count == 0)
     g_assert_cmpint (current_time / 1000 - last_time / 1000, <=, 2500);
   else
     g_assert_cmpint (current_time / 1000 - last_time / 1000, <=, 1500);

   last_time = current_time;
   count++;

   /* Make the timeout take up to 0.1 seconds.
    * We should still get scheduled for the next second.
    */
   g_usleep (count * 10000);

   if (count < 10)
     return TRUE;

   g_main_loop_quit (loop);

   return FALSE;
 }

 static void
 test_rounding (void)
 {
   loop = g_main_loop_new (NULL, FALSE);

   last_time = g_get_monotonic_time ();
   g_timeout_add_seconds (1, test_func, NULL);

   g_main_loop_run (loop);
   g_main_loop_unref (loop);
 }

 int
 main (int argc, char *argv[])
 {
   g_test_init (&argc, &argv, NULL);

   g_test_add_func ("/timeout/seconds", test_seconds);
   g_test_add_func ("/timeout/weeks-overflow", test_weeks_overflow);
   g_test_add_func ("/timeout/far-future-ready-time", test_far_future_ready_time);
   g_test_add_func ("/timeout/rounding", test_rounding);

   return g_test_run ();
 }
	#include <glib.h>
	#ifdef G_OS_UNIX
	#include <unistd.h>
	#endif

	static GMainLoop *loop;

	static gboolean
	stop_waiting (gpointer data)
	{
	g_main_loop_quit (loop);

	return G_SOURCE_REMOVE;
	}

	static gboolean
	unreachable_callback (gpointer data)
	{
	g_assert_not_reached ();

	return G_SOURCE_REMOVE;
	}

	static void
	test_seconds (void)
	{
	guint id;

	/* Bug 642052 mentions that g_timeout_add_seconds(21475) schedules a
	* job that runs once per second.
	*
	* Test that that isn't true anymore by scheduling two jobs:
	* - one, as above
	* - another that runs in 2100ms
	*
	* If everything is working properly, the 2100ms one should run first
	* (and exit the mainloop). If we ever see the 21475 second job run
	* then we have trouble (since it ran in less than 2 seconds).
	*
	* We need a timeout of at least 2 seconds because
	* g_timeout_add_seconds() can add as much as an additional second of
	* latency.
	*/
	g_test_bug ("https://bugzilla.gnome.org/show_bug.cgi?id=642052");
	loop = g_main_loop_new (NULL, FALSE);

	g_timeout_add (2100, stop_waiting, NULL);
	id = g_timeout_add_seconds (21475, unreachable_callback, NULL);

	g_main_loop_run (loop);
	g_main_loop_unref (loop);

	g_source_remove (id);
	}

	static void
	test_weeks_overflow (void)
	{
	guint id;
	guint interval_seconds;

	/* Internally, the guint interval (in seconds) was converted to milliseconds
	* then stored in a guint variable. This meant that any interval larger than
	* G_MAXUINT / 1000 would overflow.
	*
	* On a system with 32-bit guint, the interval (G_MAXUINT / 1000) + 1 seconds
	* (49.7 days) would end wrapping to 704 milliseconds.
	*
	* Test that that isn't true anymore by scheduling two jobs:
	* - one, as above
	* - another that runs in 2100ms
	*
	* If everything is working properly, the 2100ms one should run first
	* (and exit the mainloop). If we ever see the other job run
	* then we have trouble (since it ran in less than 2 seconds).
	*
	* We need a timeout of at least 2 seconds because
	* g_timeout_add_seconds() can add as much as an additional second of
	* latency.
	*/
	g_test_bug ("https://gitlab.gnome.org/GNOME/glib/issues/1600");
	loop = g_main_loop_new (NULL, FALSE);

	g_timeout_add (2100, stop_waiting, NULL);
	interval_seconds = 1 + G_MAXUINT / 1000;
	id = g_timeout_add_seconds (interval_seconds, unreachable_callback, NULL);

	g_main_loop_run (loop);
	g_main_loop_unref (loop);

	g_source_remove (id);
	}

	/* The ready_time for a GSource is stored as a gint64, as an absolute monotonic
	* time in microseconds. To call poll(), this must be converted to a relative
	* timeout, in milliseconds, as a gint. If the ready_time is sufficiently far
	* in the future, the timeout will not fit. Previously, it would be narrowed in
	* an implementation-defined way; if this gave a negative result, poll() would
	* block forever.
	*
	* This test creates a GSource with the largest possible ready_time (a little
	* over 292 millennia, assuming g_get_monotonic_time() starts from near 0 when
	* the system boots), adds it to a GMainContext, queries it for the parameters
	* to pass to poll() -- essentially the first half of
	* g_main_context_iteration() -- and checks that the timeout is a large
	* positive number.
	*/
	static void
	test_far_future_ready_time (void)
	{
	GSourceFuncs source_funcs = { 0 };
	GMainContext *context = g_main_context_new ();
	GSource *source = g_source_new (&source_funcs, sizeof (GSource));
	gboolean acquired, ready;
	gint priority, timeout_, n_fds;

	g_source_set_ready_time (source, G_MAXINT64);
	g_source_attach (source, context);

	acquired = g_main_context_acquire (context);
	g_assert_true (acquired);

	ready = g_main_context_prepare (context, &priority);
	g_assert_false (ready);

	n_fds = 0;
	n_fds = g_main_context_query (context, priority, &timeout_, NULL, n_fds);

	g_assert_cmpint (n_fds, >=, 0);

	/* The true timeout in milliseconds doesn't fit into a gint. We definitely
	* don't want poll() to block forever:
	*/
	g_assert_cmpint (timeout_, >=, 0);
	/* Instead, we want it to block for as long as possible: */
	g_assert_cmpint (timeout_, ==, G_MAXINT);

	g_main_context_release (context);
	g_main_context_unref (context);
	g_source_unref (source);
	}

	static gint64 last_time;
	static gint count;

	static gboolean
	test_func (gpointer data)
	{
	gint64 current_time;

	current_time = g_get_monotonic_time ();

	/* We accept 2 on the first iteration because _add_seconds() can
	* have an initial latency of 1 second, see its documentation.
	*
	* Allow up to 500ms leeway for rounding and scheduling.
	*/
	if (count == 0)
	g_assert_cmpint (current_time / 1000 - last_time / 1000, <=, 2500);
	else
	g_assert_cmpint (current_time / 1000 - last_time / 1000, <=, 1500);

	last_time = current_time;
	count++;

	/* Make the timeout take up to 0.1 seconds.
	* We should still get scheduled for the next second.
	*/
	g_usleep (count * 10000);

	if (count < 10)
	return TRUE;

	g_main_loop_quit (loop);

	return FALSE;
	}

	static void
	test_rounding (void)
	{
	loop = g_main_loop_new (NULL, FALSE);

	last_time = g_get_monotonic_time ();
	g_timeout_add_seconds (1, test_func, NULL);

	g_main_loop_run (loop);
	g_main_loop_unref (loop);
	}

	int
	main (int argc, char *argv[])
	{
	g_test_init (&argc, &argv, NULL);

	g_test_add_func ("/timeout/seconds", test_seconds);
	g_test_add_func ("/timeout/weeks-overflow", test_weeks_overflow);
	g_test_add_func ("/timeout/far-future-ready-time", test_far_future_ready_time);
	g_test_add_func ("/timeout/rounding", test_rounding);

	return g_test_run ();
	}