void fs_ml_frame_update_end(int frame) {
//printf("%d\n", frame);
// in timed mode only (non-vsync), the video renderer is waiting for
// a new frame signal
fs_mutex_lock(g_frame_available_mutex);
g_available_frame = frame;
fs_condition_signal(g_frame_available_cond);
fs_mutex_unlock(g_frame_available_mutex);
if (g_fs_ml_video_sync) {
fs_mutex_lock(g_start_new_frame_mutex);
while (!g_start_new_frame) {
fs_condition_wait (g_start_new_frame_cond,
g_start_new_frame_mutex);
}
g_start_new_frame = 0;
fs_mutex_unlock(g_start_new_frame_mutex);
}
else if (g_fs_ml_vblank_sync) {
// emulation running independently on the video renderer
}
else if (g_fs_ml_benchmarking) {
// run as fast as possible
}
else {
// video renderer is waiting for a new frame -signal that a new
// frame is ready
//fs_condition_signal(g_video_cond);
}
}
static void fs_eventlog_new_event(int64_t *event_time, int *event,
uint8_t event_type) {
FS_INIT(module);
if (!g_log_events) {
return;
}
int64_t t;
if (event_time == NULL) {
t = fs_get_monotonic_time();
}
else {
if (*event_time == 0) {
*event_time = fs_get_monotonic_time();
}
t = *event_time;
}
void *data = malloc(13);
*((uint8_t *) data) = event_type;
*((int64_t *) data + 5) = t;
fs_mutex_lock(g_mutex);
int e = ++g_event;
*((int32_t *) data + 1) = e;
g_event_list = g_list_append(g_event_list, data);
g_event_count++;
if (g_event_count > 1000000) {
flush_events();
}
fs_mutex_unlock(g_mutex);
if (event) {
*event = e;
}
}
static void fs_eventlog_update_event(int64_t event_time, int event,
int64_t t1, int64_t t2) {
FS_INIT(module);
if (!g_log_events) {
return;
}
if (t1 == 0) {
t1 = fs_get_monotonic_time();
}
if (t2 == 0) {
t2 = t1;
}
t1 = t1 - event_time;
t2 = t2 - event_time;
void *data = malloc(13);
*((uint8_t *) data) = 255; // event update
*((int32_t *) data + 1) = event;
*((uint32_t *) data + 5) = t1;
*((uint32_t *) data + 9) = t2;
fs_mutex_lock(g_mutex);
g_event_list = g_list_append(g_event_list, data);
g_event_count++;
fs_mutex_unlock(g_mutex);
}
static void unqueue_old_buffers(int stream)
{
audio_stream *s = g_streams[stream];
ALint old_buffers = 0;
fs_mutex_lock(s->mutex);
// locking here because unqueue_old_buffers can be run called from
// both the video thread and the emulation thread (consider changing this,
// perhaps even have a separate thread for periodically unqueuing).
alGetSourcei(s->source, AL_BUFFERS_PROCESSED, &old_buffers);
check_al_error("alGetSourcei (AL_BUFFERS_PROCESSED)");
if (old_buffers > 0) {
ALuint buffers[MAX_BUFFERS];
old_buffers = MIN(old_buffers, MAX_BUFFERS);
alSourceUnqueueBuffers(s->source, old_buffers, buffers);
if (check_al_error("alSourceUnqueueBuffers") != AL_NO_ERROR) {
fs_log("while trying to unqueue %d buffers\n");
}
for (int i = 0; i < old_buffers; i++) {
g_queue_push_tail(s->queue, FS_UINT_TO_POINTER(buffers[i]));
}
s->buffers_queued -= old_buffers;
}
fs_mutex_unlock(s->mutex);
}
static int fs_emu_get_netplay_input_event() {
fs_mutex_lock(g_input_event_mutex);
int input_event = FS_POINTER_TO_INT(g_queue_pop_tail(
g_input_event_queue));
fs_mutex_unlock(g_input_event_mutex);
return input_event;
}
static void fs_emu_queue_netplay_input_event(int input_event) {
if (input_event == 0) {
fs_log("WARNING: tried to queue input event 0\n");
return;
}
fs_mutex_lock(g_input_event_mutex);
g_queue_push_head(g_input_event_queue, FS_INT_TO_POINTER(input_event));
fs_mutex_unlock(g_input_event_mutex);
}
static void post_video_event(int event)
{
if (fse_drivers()) {
// printf("FSE_DRIVERS: ignoring post_video_event\n");
} else {
fs_mutex_lock(g_video_event_mutex);
g_queue_push_head(g_video_event_queue, FS_INT_TO_POINTER(event));
fs_mutex_unlock(g_video_event_mutex);
}
}
static void post_video_event(int event)
{
#ifdef FS_EMU_DRIVERS
// printf("FS_EMU_DRIVERS: ignoring post_video_event\n");
#else
fs_mutex_lock(g_video_event_mutex);
g_queue_push_head(g_video_event_queue, FS_INT_TO_POINTER(event));
fs_mutex_unlock(g_video_event_mutex);
#endif
}
static int check_buffer(int stream, int buffer)
{
unqueue_old_buffers(stream);
audio_stream *s = g_streams[stream];
// not extremely efficient
fs_mutex_lock(s->mutex);
GList *link = g_queue_peek_head_link(s->queue);
while (link) {
if ((unsigned int) buffer == FS_POINTER_TO_UINT(link->data)) {
fs_mutex_unlock(s->mutex);
return 1;
}
link = link->next;
}
fs_mutex_unlock(s->mutex);
return 0;
}
void fs_log_string(const char *str)
{
if (!log.initialized) {
initialize();
}
fs_mutex_lock(log.mutex);
if (log.use_stdout) {
printf("%s", str);
fflush(stdout);
}
if (log.file) {
fprintf(log.file, "%s", str);
}
if (log.flush) {
fflush(log.file);
}
fs_mutex_unlock(log.mutex);
}
void fs_ml_video_screenshot(const char *path) {
fs_mutex_lock(g_fs_ml_video_screenshot_mutex);
if (g_fs_ml_video_screenshot_path) {
g_free(g_fs_ml_video_screenshot_path);
}
g_fs_ml_video_screenshot_path = g_strdup(path);
#if 0
if (g_fs_ml_video_screenshots_dir) {
g_free(g_fs_ml_video_screenshots_dir);
}
if (g_fs_ml_video_screenshots_prefix) {
g_free(g_fs_ml_video_screenshots_prefix);
}
g_fs_ml_video_screenshots_dir = g_strdup(screenshots_dir);
g_fs_ml_video_screenshots_prefix = g_strdup(prefix);
g_fs_ml_video_screenshot = number;
#endif
fs_mutex_unlock(g_fs_ml_video_screenshot_mutex);
}
static void process_video_events() {
fs_mutex_lock(g_video_event_mutex);
int count = g_queue_get_length(g_video_event_queue);
for (int i = 0; i < count; i++) {
int event = FS_POINTER_TO_INT(g_queue_pop_tail(g_video_event_queue));
if (event == FS_ML_VIDEO_EVENT_GRAB_INPUT) {
fs_ml_grab_input(1, 1);
}
else if (event == FS_ML_VIDEO_EVENT_UNGRAB_INPUT) {
fs_ml_grab_input(0, 1);
}
else if (event == FS_ML_VIDEO_EVENT_SHOW_CURSOR) {
fs_ml_show_cursor(1, 1);
}
else if (event == FS_ML_VIDEO_EVENT_HIDE_CURSOR) {
fs_ml_show_cursor(0, 1);
}
}
fs_mutex_unlock(g_video_event_mutex);
}
void fs_config_set_log_file(const char *path)
{
fs_log("switch to log file %s\n", path);
fs_mutex_lock(log.mutex);
if (log.file) {
fclose(log.file);
}
log.file = g_fopen(path, "w");
if (log.file) {
printf("LOG: %s\n", path);
if (log.initial_path) {
FILE *f = g_fopen(log.initial_path, "r");
if (f) {
char *buffer = (char *) g_malloc(1024);
int read = fread(buffer, 1, 1024, f);
while (read > 0) {
fwrite(buffer, 1, read, log.file);
read = fread(buffer, 1, 1024, f);
}
g_free(buffer);
fclose(f);
}
}
}
/* All options should have been read, so we can no check log options */
if (fs_config_get_boolean("flush_log") == 1) {
log.flush = 1;
}
fs_mutex_unlock(log.mutex);
if (log.flush) {
fs_log_string("flush_log: will flush log after each log line\n");
}
}
static void process_video_events(void)
{
fs_mutex_lock(g_video_event_mutex);
int count = g_queue_get_length(g_video_event_queue);
for (int i = 0; i < count; i++) {
int event = FS_POINTER_TO_INT(g_queue_pop_tail(g_video_event_queue));
if (event == FS_ML_VIDEO_EVENT_GRAB_INPUT) {
fs_ml_set_input_grab(true);
} else if (event == FS_ML_VIDEO_EVENT_UNGRAB_INPUT) {
fs_ml_set_input_grab(false);
} else if (event == FS_ML_VIDEO_EVENT_SHOW_CURSOR) {
fs_ml_show_cursor(1, 1);
} else if (event == FS_ML_VIDEO_EVENT_HIDE_CURSOR) {
fs_ml_show_cursor(0, 1);
} else if (event == FS_ML_VIDEO_EVENT_TOGGLE_FULLSCREEN) {
fs_ml_toggle_fullscreen();
} else if (event == FS_ML_VIDEO_EVENT_ENABLE_FULLSCREEN) {
fs_ml_set_fullscreen(true);
} else if (event == FS_ML_VIDEO_EVENT_DISABLE_FULLSCREEN) {
fs_ml_set_fullscreen(false);
}
}
fs_mutex_unlock(g_video_event_mutex);
}
static void render_iteration_vsync() {
if (g_fs_ml_video_sync_low_latency) {
int current_frame_at_start = g_available_frame;
//int64_t t1 = fs_ml_monotonic_time();
int sleep_time = 0;
int time_left = g_estimated_upload_render_duration;
int64_t t = fs_emu_monotonic_time();
if (g_fs_ml_target_frame_time > 0) {
sleep_time = g_estimated_next_vblank_time - t - time_left;
}
if (sleep_time > g_fs_ml_target_frame_time - time_left) {
sleep_time = 0;
}
if (sleep_time > 0) {
fs_ml_usleep(sleep_time);
}
if (g_available_frame > current_frame_at_start) {
//printf("low latency %d\n", g_available_frame);
}
else {
//printf("...\n");
}
}
update_frame();
CHECK_GL_ERROR_MSG("update_frame");
render_frame();
CHECK_GL_ERROR_MSG("render_frame");
//opengl_fence(FENCE_SET);
//glFlush();
//opengl_fence(FENCE_WAIT);
//int64_t upload_render_time = fs_ml_monotonic_time() - t1;
//printf("urt %lld\n", upload_render_time);
opengl_swap_synchronous();
g_measured_vblank_time = fs_ml_monotonic_time();
g_vblank_count++;
fs_mutex_lock(g_vblank_mutex);
g_measured_vblank_times[g_vblank_index] = g_measured_vblank_time;
g_vblank_index = (g_vblank_index + 1) % VBLANK_COUNT;
fs_mutex_unlock(g_vblank_mutex);
// FIXME: adjust g_measured_vblank_time based on historical data (smooth out
// irregularities) and save the result in g_adjusted_vblank_time
g_adjusted_vblank_time = g_measured_vblank_time;
g_sleep_until_vsync_last_time = g_adjusted_vblank_time;
g_estimated_next_vblank_time = g_adjusted_vblank_time + \
g_fs_ml_target_frame_time;
// g_start_new_frame_cond is used to signal that a new frame can be
// generated when the emulation is running in sync - this is not used
// when only display flipping is synced to vblank
fs_mutex_lock(g_start_new_frame_mutex);
g_start_new_frame = 1;
fs_condition_signal(g_start_new_frame_cond);
fs_mutex_unlock(g_start_new_frame_mutex);
}
static int queue_buffer(int stream, int16_t* data, int size)
{
if (g_fs_emu_benchmark_mode) {
/* no audio output while benchmarking */
return 0;
}
if (g_fs_emu_benchmarking) {
/* no audio output while benchmarking */
return 0;
}
//fs_log("fs_emu_queue_audio_buffer stream %d size %d\n", stream, size);
audio_stream *s = g_streams[stream];
ALuint buffer = 0;
fs_mutex_lock(s->mutex);
//while (1) {
buffer = FS_POINTER_TO_UINT(g_queue_pop_head(s->queue));
if (!buffer) {
fs_log("no audio buffer available - dropping data\n");
fs_mutex_unlock(s->mutex);
return 0;
}
s->buffers_queued += 1;
// create a local copy while we have the lock
//int buffers_queued = s->buffers_queued;
fs_mutex_unlock(s->mutex);
#if 0
/* for debugging, clear one of the stereo channels */
int16_t *d = data;
for (int i = 0; i < size / 4; i++) {
d++;
*d = 0;
d++;
}
#endif
alBufferData(buffer, AL_FORMAT_STEREO16, data, size, s->frequency);
check_al_error("alBufferData");
alSourceQueueBuffers(s->source, 1, &buffer);
check_al_error("alSourceQueueBuffers");
ALint state;
alGetSourcei(s->source, AL_SOURCE_STATE, &state);
check_al_error("alGetSourcei (AL_SOURCE_STATE)");
if (state != AL_PLAYING) {
g_fs_emu_audio_buffer_underrun_time = fs_get_monotonic_time();
g_fs_emu_audio_buffer_underruns += 1;
// we have had a buffer underrun - we now wait until we have queued
// some buffers
//if (buffers_queued < s->min_buffers) {
// // want more buffers
//}
//else {
fs_log("restarting audio stream %d (buffer underrun)\n", stream);
alSourcePlay(s->source);
g_fs_emu_audio_stream_playing[stream] = 1;
check_al_error("alSourcePlay");
//}
}
double want_volume = g_fs_emu_audio_want_volume[stream] * 0.9;
if (want_volume != s->source_volume_current) {
s->source_volume_current = want_volume;
alSourcef(s->source, AL_GAIN, want_volume);
}
unqueue_old_buffers(stream);
return buffer;
}
void fs_emu_video_render_mutex_lock() {
if (!g_video_render_mutex) {
return;
}
fs_mutex_lock(g_video_render_mutex);
}
void fs_emu_acquire_gui_lock()
{
fs_mutex_lock(g_gui_mutex);
g_gui_mutex_locked = 1;
}
void fs_ml_render_iteration() {
static int first = 1;
if (first) {
first = 0;
initialize_opengl_sync();
}
if (g_fs_ml_vblank_sync) {
render_iteration_vsync();
}
else if (g_fs_ml_benchmarking) {
update_frame();
render_frame();
swap_opengl_buffers();
}
else {
// when vsync is off, we wait until a new frame is ready and
// then we display it immediately
if (fs_ml_is_quitting()) {
// but when the emulation is quitting, we can't expect any new
// frames so there's no point waiting for them. Instead, we just
// sleep a bit to throttle the frame rate for the quit animation
fs_ml_usleep(10000);
} else {
// wait max 33 ms to allow the user interface to work even if
// the emu hangs
// int64_t dest_time = fs_get_real_time() + 33 * 1000;
int64_t end_time = fs_condition_get_wait_end_time(33 * 1000);
int64_t check_time = 0;
fs_mutex_lock(g_frame_available_mutex);
// fs_log("cond wait until %lld\n", end_time);
while (g_rendered_frame == g_available_frame) {
fs_condition_wait_until(
g_frame_available_cond, g_frame_available_mutex, end_time);
check_time = fs_condition_get_wait_end_time(0);
if (check_time >= end_time) {
// fs_log("timed out at %lld\n", check_time);
break;
} else {
// fs_log("wake-up at %lld (end_time = %lld)\n", check_time, end_time);
}
}
fs_mutex_unlock(g_frame_available_mutex);
}
update_frame();
render_frame();
swap_opengl_buffers();
//gl_finish();
}
if (g_fs_ml_video_screenshot_path) {
fs_mutex_lock(g_fs_ml_video_screenshot_mutex);
if (g_fs_ml_video_screenshot_path) {
save_screenshot_of_opengl_framebuffer(
g_fs_ml_video_screenshot_path);
g_free(g_fs_ml_video_screenshot_path);
g_fs_ml_video_screenshot_path = NULL;
}
fs_mutex_unlock(g_fs_ml_video_screenshot_mutex);
}
if (g_fs_ml_video_post_render_function) {
g_fs_ml_video_post_render_function();
}
}
static void post_video_event(int event) {
fs_mutex_lock(g_video_event_mutex);
g_queue_push_head(g_video_event_queue, FS_INT_TO_POINTER(event));
fs_mutex_unlock(g_video_event_mutex);
}
void fs_init_lock() {
fs_mutex_lock(g_init_mutex);
}
