static void sdlwindow_exit(running_machine &machine)
{
ASSERT_MAIN_THREAD();
mame_printf_verbose("Enter sdlwindow_exit\n");
// free all the windows
while (sdl_window_list != NULL)
{
sdl_window_info *temp = sdl_window_list;
sdl_window_list = temp->next;
sdlwindow_video_window_destroy(machine, temp);
}
// if we're multithreaded, clean up the window thread
if (multithreading_enabled)
{
sdlwindow_sync();
}
// kill the drawers
(*draw.exit)();
execute_async_wait(&sdlwindow_exit_wt, NULL);
if (multithreading_enabled)
{
osd_work_queue_wait(work_queue, 1000000);
osd_work_queue_free(work_queue);
}
mame_printf_verbose("Leave sdlwindow_exit\n");
}
void osd_work_queue_free(osd_work_queue *queue)
{
/**
* Wait until the work queue is empty. We use a special timeout value,
* that we know means 'wait forever'.
**/
osd_work_queue_wait(queue, 0);
/**
* Destroy the queue
**/
osd_free(queue);
/**
* Now decrement the queue count, and if it has gone to zero, destroy the
* work threads as there are no more work queues that need to be serviced
**/
pthread_mutex_lock(&g_mutex);
if (--g_queues_count == 0)
{
work_queue_destroy_threads_locked();
}
pthread_mutex_unlock(&g_mutex);
}
int osd_work_item_wait(osd_work_item *item, osd_ticks_t timeout)
{
/**
* Just wait on the queue that this item belongs to. This is done because
* MAME actually doesn't really use this method and this is the simplest
* way to implement it. Providing for an implementation that can wait for
* this specific item to be finished is more heavyweight and hurts the
* performance of the rest of the work queue implementation.
**/
return osd_work_queue_wait(item->queue, timeout);
}
static void sdlwindow_sync(void)
{
if (multithreading_enabled)
{
// Fallback
while (!osd_work_queue_wait(work_queue, osd_ticks_per_second()*10))
{
mame_printf_warning("sdlwindow_sync: Sleeping...\n");
osd_sleep(100000);
}
}
}
void laserdisc_device::device_stop()
{
// make sure all async operations have completed
if (m_disc != nullptr)
osd_work_queue_wait(m_work_queue, osd_ticks_per_second() * 10);
// free any textures and palettes
if (m_videotex != nullptr)
machine().render().texture_free(m_videotex);
if (m_videopalette != nullptr)
m_videopalette->deref();
if (m_overtex != nullptr)
machine().render().texture_free(m_overtex);
}
void laserdisc_device::process_track_data()
{
// wait for the async operation to complete
if (m_readresult == CHDERR_OPERATION_PENDING)
osd_work_queue_wait(m_work_queue, osd_ticks_per_second() * 10);
assert(m_readresult != CHDERR_OPERATION_PENDING);
// remove the video if we had an error
if (m_readresult != CHDERR_NONE)
m_avhuff_config.video.reset();
// count the field as read if we are successful
if (m_avhuff_config.video.valid())
{
m_frame[m_videoindex].m_numfields++;
player_overlay(m_avhuff_config.video);
}
// pass the audio to the callback
if (!m_audio_callback.isnull())
m_audio_callback(*this, m_samplerate, m_audiocursamples, m_avhuff_config.audio[0], m_avhuff_config.audio[1]);
// shift audio data if we read it into the beginning of the buffer
if (m_audiocursamples != 0 && m_audiobufin != 0)
for (int chnum = 0; chnum < 2; chnum++)
if (m_avhuff_config.audio[chnum] == &m_audiobuffer[chnum][0])
{
// move data to the end
int samplesleft = m_audiobufsize - m_audiobufin;
samplesleft = MIN(samplesleft, m_audiocursamples);
memmove(&m_audiobuffer[chnum][m_audiobufin], &m_audiobuffer[chnum][0], samplesleft * 2);
// shift data at the beginning
if (samplesleft < m_audiocursamples)
memmove(&m_audiobuffer[chnum][0], &m_audiobuffer[chnum][samplesleft], (m_audiocursamples - samplesleft) * 2);
}
// update the input buffer pointer
m_audiobufin = (m_audiobufin + m_audiocursamples) % m_audiobufsize;
}
void sdl_osd_interface::window_exit()
{
worker_param wp_dummy;
ASSERT_MAIN_THREAD();
osd_printf_verbose("Enter sdlwindow_exit\n");
// free all the windows
while (sdl_window_list != NULL)
{
sdl_window_info *temp = sdl_window_list;
sdl_window_list = temp->m_next;
temp->destroy();
// free the window itself
global_free(temp);
}
// if we're multithreaded, clean up the window thread
if (multithreading_enabled)
{
sdlwindow_sync();
}
// kill the drawers
(*draw.exit)();
execute_async_wait(&sdlwindow_exit_wt, wp_dummy);
if (multithreading_enabled)
{
osd_work_queue_wait(work_queue, 1000000);
osd_work_queue_free(work_queue);
}
osd_printf_verbose("Leave sdlwindow_exit\n");
}
void poly_wait(poly_manager *poly, const char *debug_reason)
{
osd_ticks_t time;
/* remember the start time if we're logging */
if (LOG_WAITS)
time = get_profile_ticks();
/* wait for all pending work items to complete */
if (poly->queue != NULL)
osd_work_queue_wait(poly->queue, osd_ticks_per_second() * 100);
/* if we don't have a queue, just run the whole list now */
else
{
int unitnum;
for (unitnum = 0; unitnum < poly->unit_next; unitnum++)
poly_item_callback(poly->unit[unitnum], 0);
}
/* log any long waits */
if (LOG_WAITS)
{
time = get_profile_ticks() - time;
if (time > LOG_WAIT_THRESHOLD)
logerror("Poly:Waited %d cycles for %s\n", (int)time, debug_reason);
}
/* reset the state */
poly->polygon_next = poly->unit_next = 0;
memset(poly->unit_bucket, 0xff, sizeof(poly->unit_bucket));
/* we need to preserve the last extra data that was supplied */
if (poly->extra_next > 1)
memcpy(poly->extra[0], poly->extra[poly->extra_next - 1], poly->extra_size);
poly->extra_next = 1;
}
