4 #include "shared/context.h"
6 #include "shared/ffmpeg_raii.h"
8 #include "frame_on_disk.h"
9 #include "shared/httpd.h"
10 #include "jpeg_frame_view.h"
11 #include "shared/metrics.h"
12 #include "shared/mux.h"
13 #include "shared/timebase.h"
14 #include "video_stream.h"
18 #include <condition_variable>
19 #include <movit/util.h>
26 using namespace std::chrono;
28 extern HTTPD *global_httpd;
30 void Player::thread_func(AVFormatContext *file_avctx)
32 pthread_setname_np(pthread_self(), "Player");
34 QSurface *surface = create_surface();
35 QOpenGLContext *context = create_context(surface);
36 if (!make_current(context, surface)) {
43 // Create the VideoStream object, now that we have an OpenGL context.
44 if (stream_output != NO_STREAM_OUTPUT) {
45 video_stream.reset(new VideoStream(file_avctx));
46 video_stream->start();
51 while (!should_quit) {
56 void Player::play_playlist_once()
58 vector<Clip> clip_list;
60 steady_clock::time_point before_sleep = steady_clock::now();
62 // Wait until we're supposed to play something.
64 unique_lock<mutex> lock(queue_state_mu);
66 clip_ready = new_clip_changed.wait_for(lock, milliseconds(100), [this] {
67 return should_quit || new_clip_ready;
73 new_clip_ready = false;
75 clip_list = move(queued_clip_list);
76 queued_clip_list.clear();
77 assert(!clip_list.empty());
81 steady_clock::duration time_slept = steady_clock::now() - before_sleep;
82 pts += duration_cast<duration<size_t, TimebaseRatio>>(time_slept).count();
85 if (video_stream != nullptr) {
86 ++metric_refresh_frame;
87 video_stream->schedule_refresh_frame(steady_clock::now(), pts, /*display_func=*/nullptr, QueueSpotHolder());
92 steady_clock::time_point origin = steady_clock::now(); // TODO: Add a 100 ms buffer for ramp-up?
93 int64_t in_pts_origin = clip_list[0].pts_in;
94 for (size_t clip_idx = 0; clip_idx < clip_list.size(); ++clip_idx) {
95 const Clip &clip = clip_list[clip_idx];
96 const Clip *next_clip = (clip_idx + 1 < clip_list.size()) ? &clip_list[clip_idx + 1] : nullptr;
97 int64_t out_pts_origin = pts;
99 double next_clip_fade_time = -1.0;
100 if (next_clip != nullptr) {
101 double duration_this_clip = double(clip.pts_out - in_pts_origin) / TIMEBASE / clip.speed;
102 double duration_next_clip = double(next_clip->pts_out - next_clip->pts_in) / TIMEBASE / clip.speed;
103 next_clip_fade_time = min(min(duration_this_clip, duration_next_clip), clip.fade_time_seconds);
106 int stream_idx = clip.stream_idx;
108 // Start playing exactly at a frame.
109 // TODO: Snap secondary (fade-to) clips in the same fashion
110 // so that we don't get jank here).
112 lock_guard<mutex> lock(frame_mu);
114 // Find the first frame such that frame.pts <= in_pts.
115 auto it = find_last_frame_before(frames[stream_idx], in_pts_origin);
116 if (it != frames[stream_idx].end()) {
117 in_pts_origin = it->pts;
121 steady_clock::time_point next_frame_start;
122 for (int frameno = 0; !should_quit; ++frameno) { // Ends when the clip ends.
123 double out_pts = out_pts_origin + TIMEBASE * frameno / global_flags.output_framerate;
125 origin + microseconds(lrint((out_pts - out_pts_origin) * 1e6 / TIMEBASE));
126 int64_t in_pts = lrint(in_pts_origin + TIMEBASE * frameno * clip.speed / global_flags.output_framerate);
127 pts = lrint(out_pts);
129 if (in_pts >= clip.pts_out) {
133 steady_clock::duration time_behind = steady_clock::now() - next_frame_start;
134 if (stream_output != FILE_STREAM_OUTPUT && time_behind >= milliseconds(200)) {
135 fprintf(stderr, "WARNING: %ld ms behind, dropping a frame (no matter the type).\n",
136 lrint(1e3 * duration<double>(time_behind).count()));
137 ++metric_dropped_unconditional_frame;
142 // pts not affected by the swapping below.
143 int64_t in_pts_for_progress = in_pts, in_pts_secondary_for_progress = -1;
145 int primary_stream_idx = stream_idx;
146 FrameOnDisk secondary_frame;
147 int secondary_stream_idx = -1;
148 float fade_alpha = 0.0f;
149 double time_left_this_clip = double(clip.pts_out - in_pts) / TIMEBASE / clip.speed;
150 if (next_clip != nullptr && time_left_this_clip <= next_clip_fade_time) {
151 // We're in a fade to the next clip.
152 secondary_stream_idx = next_clip->stream_idx;
153 int64_t in_pts_secondary = lrint(next_clip->pts_in + (next_clip_fade_time - time_left_this_clip) * TIMEBASE * clip.speed);
154 in_pts_secondary_for_progress = in_pts_secondary;
155 fade_alpha = 1.0f - time_left_this_clip / next_clip_fade_time;
157 // If more than half-way through the fade, interpolate the next clip
158 // instead of the current one, since it's more visible.
159 if (fade_alpha >= 0.5f) {
160 swap(primary_stream_idx, secondary_stream_idx);
161 swap(in_pts, in_pts_secondary);
162 fade_alpha = 1.0f - fade_alpha;
165 FrameOnDisk frame_lower, frame_upper;
166 bool ok = find_surrounding_frames(in_pts_secondary, secondary_stream_idx, &frame_lower, &frame_upper);
168 secondary_frame = frame_lower;
172 if (progress_callback != nullptr) {
173 // NOTE: None of this will take into account any snapping done below.
174 double played_this_clip = double(in_pts_for_progress - clip.pts_in) / TIMEBASE / clip.speed;
175 double total_length = double(clip.pts_out - clip.pts_in) / TIMEBASE / clip.speed;
176 map<size_t, double> progress{{ clip_idx, played_this_clip / total_length }};
178 if (next_clip != nullptr && time_left_this_clip <= next_clip_fade_time) {
179 double played_next_clip = double(in_pts_secondary_for_progress - next_clip->pts_in) / TIMEBASE / next_clip->speed;
180 double total_next_length = double(next_clip->pts_out - next_clip->pts_in) / TIMEBASE / next_clip->speed;
181 progress[clip_idx + 1] = played_next_clip / total_next_length;
183 progress_callback(progress);
186 FrameOnDisk frame_lower, frame_upper;
187 bool ok = find_surrounding_frames(in_pts, primary_stream_idx, &frame_lower, &frame_upper);
192 // Wait until we should, or (given buffering) can, output the frame.
194 unique_lock<mutex> lock(queue_state_mu);
195 if (video_stream == nullptr) {
196 // No queue, just wait until the right time and then show the frame.
197 new_clip_changed.wait_until(lock, next_frame_start, [this]{
198 return should_quit || new_clip_ready || override_stream_idx != -1;
204 // If the queue is full (which is really the state we'd like to be in),
205 // wait until there's room for one more frame (ie., one was output from
206 // VideoStream), or until or until there's a new clip we're supposed to play.
208 // In this case, we don't sleep until next_frame_start; the displaying is
209 // done by the queue.
210 new_clip_changed.wait(lock, [this]{
211 if (num_queued_frames < max_queued_frames) {
214 return should_quit || new_clip_ready || override_stream_idx != -1;
220 if (new_clip_ready) {
221 if (video_stream != nullptr) {
222 lock.unlock(); // Urg.
223 video_stream->clear_queue();
228 // Honor if we got an override request for the camera.
229 if (override_stream_idx != -1) {
230 stream_idx = override_stream_idx;
231 override_stream_idx = -1;
236 // If there's nothing to interpolate between, or if interpolation is turned off,
237 // or we're a preview, then just display the frame.
238 if (frame_lower.pts == frame_upper.pts || global_flags.interpolation_quality == 0 || video_stream == nullptr) {
239 display_single_frame(primary_stream_idx, frame_lower, secondary_stream_idx,
240 secondary_frame, fade_alpha, next_frame_start, /*snapped=*/false);
244 // Snap to input frame: If we can do so with less than 1% jitter
245 // (ie., move less than 1% of an _output_ frame), do so.
246 // TODO: Snap secondary (fade-to) clips in the same fashion.
247 double pts_snap_tolerance = 0.01 * double(TIMEBASE) / global_flags.output_framerate;
248 bool snapped = false;
249 for (FrameOnDisk snap_frame : { frame_lower, frame_upper }) {
250 if (fabs(snap_frame.pts - in_pts) < pts_snap_tolerance) {
251 display_single_frame(primary_stream_idx, snap_frame, secondary_stream_idx,
252 secondary_frame, fade_alpha, next_frame_start, /*snapped=*/true);
253 in_pts_origin += snap_frame.pts - in_pts;
262 // The snapping above makes us lock to the input framerate, even in the presence
263 // of pts drift, for most typical cases where it's needed, like converting 60 → 2x60
264 // or 60 → 2x59.94. However, there are some corner cases like 25 → 2x59.94, where we'd
265 // get a snap very rarely (in the given case, once every 24 output frames), and by
266 // that time, we'd have drifted out. We could have solved this by changing the overall
267 // speed ever so slightly, but it requires that we know the actual frame rate (which
268 // is difficult in the presence of jitter and missed frames), or at least do some kind
269 // of matching/clustering. Instead, we take the opportunity to lock to in-between rational
270 // points if we can. E.g., if we are converting 60 → 2x60, we would not only snap to
271 // an original frame every other frame; we would also snap to exactly alpha=0.5 every
272 // in-between frame. Of course, we will still need to interpolate, but we get a lot
273 // closer when we actually get close to an original frame. In other words: Snap more
274 // often, but snap less each time. Unless the input and output frame rates are completely
275 // decorrelated with no common factor, of course (e.g. 12.345 → 34.567, which we should
276 // really never see in practice).
277 for (double fraction : { 1.0 / 2.0, 1.0 / 3.0, 2.0 / 3.0, 1.0 / 4.0, 3.0 / 4.0,
278 1.0 / 5.0, 2.0 / 5.0, 3.0 / 5.0, 4.0 / 5.0 }) {
279 double subsnap_pts = frame_lower.pts + fraction * (frame_upper.pts - frame_lower.pts);
280 if (fabs(subsnap_pts - in_pts) < pts_snap_tolerance) {
281 in_pts_origin += lrint(subsnap_pts) - in_pts;
282 in_pts = lrint(subsnap_pts);
287 if (stream_output != FILE_STREAM_OUTPUT && time_behind >= milliseconds(100)) {
288 fprintf(stderr, "WARNING: %ld ms behind, dropping an interpolated frame.\n",
289 lrint(1e3 * duration<double>(time_behind).count()));
290 ++metric_dropped_interpolated_frame;
294 double alpha = double(in_pts - frame_lower.pts) / (frame_upper.pts - frame_lower.pts);
295 auto display_func = [this](shared_ptr<Frame> frame) {
296 if (destination != nullptr) {
297 destination->setFrame(frame);
300 if (secondary_stream_idx == -1) {
301 ++metric_interpolated_frame;
303 ++metric_interpolated_faded_frame;
305 video_stream->schedule_interpolated_frame(
306 next_frame_start, pts, display_func, QueueSpotHolder(this),
307 frame_lower, frame_upper, alpha,
308 secondary_frame, fade_alpha);
309 last_pts_played = in_pts; // Not really needed; only previews use last_pts_played.
316 if (done_callback != nullptr) {
320 // Start the next clip from the point where the fade went out.
321 if (next_clip != nullptr) {
322 origin = next_frame_start;
323 in_pts_origin = next_clip->pts_in + lrint(next_clip_fade_time * TIMEBASE * clip.speed);
327 if (done_callback != nullptr) {
332 void Player::display_single_frame(int primary_stream_idx, const FrameOnDisk &primary_frame, int secondary_stream_idx, const FrameOnDisk &secondary_frame, double fade_alpha, steady_clock::time_point frame_start, bool snapped)
334 auto display_func = [this, primary_stream_idx, primary_frame, secondary_frame, fade_alpha]{
335 if (destination != nullptr) {
336 destination->setFrame(primary_stream_idx, primary_frame, secondary_frame, fade_alpha);
339 if (video_stream == nullptr) {
342 if (secondary_stream_idx == -1) {
343 // NOTE: We could be increasing unused metrics for previews, but that's harmless.
345 ++metric_original_snapped_frame;
347 ++metric_original_frame;
349 video_stream->schedule_original_frame(
350 frame_start, pts, display_func, QueueSpotHolder(this),
353 assert(secondary_frame.pts != -1);
354 // NOTE: We could be increasing unused metrics for previews, but that's harmless.
356 ++metric_faded_snapped_frame;
358 ++metric_faded_frame;
360 video_stream->schedule_faded_frame(frame_start, pts, display_func,
361 QueueSpotHolder(this), primary_frame,
362 secondary_frame, fade_alpha);
365 last_pts_played = primary_frame.pts;
368 // Find the frame immediately before and after this point.
369 bool Player::find_surrounding_frames(int64_t pts, int stream_idx, FrameOnDisk *frame_lower, FrameOnDisk *frame_upper)
371 lock_guard<mutex> lock(frame_mu);
373 // Find the first frame such that frame.pts >= pts.
374 auto it = find_last_frame_before(frames[stream_idx], pts);
375 if (it == frames[stream_idx].end()) {
380 // Find the last frame such that in_pts <= frame.pts (if any).
381 if (it == frames[stream_idx].begin()) {
384 *frame_lower = *(it - 1);
386 assert(pts >= frame_lower->pts);
387 assert(pts <= frame_upper->pts);
391 Player::Player(JPEGFrameView *destination, Player::StreamOutput stream_output, AVFormatContext *file_avctx)
392 : destination(destination), stream_output(stream_output)
394 player_thread = thread(&Player::thread_func, this, file_avctx);
396 if (stream_output == HTTPD_STREAM_OUTPUT) {
397 global_metrics.add("http_output_frames", {{ "type", "original" }, { "reason", "edge_frame_or_no_interpolation" }}, &metric_original_frame);
398 global_metrics.add("http_output_frames", {{ "type", "faded" }, { "reason", "edge_frame_or_no_interpolation" }}, &metric_faded_frame);
399 global_metrics.add("http_output_frames", {{ "type", "original" }, { "reason", "snapped" }}, &metric_original_snapped_frame);
400 global_metrics.add("http_output_frames", {{ "type", "faded" }, { "reason", "snapped" }}, &metric_faded_snapped_frame);
401 global_metrics.add("http_output_frames", {{ "type", "interpolated" }}, &metric_interpolated_frame);
402 global_metrics.add("http_output_frames", {{ "type", "interpolated_faded" }}, &metric_interpolated_faded_frame);
403 global_metrics.add("http_output_frames", {{ "type", "refresh" }}, &metric_refresh_frame);
404 global_metrics.add("http_dropped_frames", {{ "type", "interpolated" }}, &metric_dropped_interpolated_frame);
405 global_metrics.add("http_dropped_frames", {{ "type", "unconditional" }}, &metric_dropped_unconditional_frame);
412 if (video_stream != nullptr) {
413 video_stream->stop();
415 new_clip_changed.notify_all();
416 player_thread.join();
419 void Player::play(const vector<Clip> &clips)
421 lock_guard<mutex> lock(queue_state_mu);
422 new_clip_ready = true;
423 queued_clip_list = clips;
424 override_stream_idx = -1;
425 new_clip_changed.notify_all();
428 void Player::override_angle(unsigned stream_idx)
432 // Corner case: If a new clip is waiting to be played, change its stream and then we're done.
434 lock_guard<mutex> lock(queue_state_mu);
435 if (new_clip_ready) {
436 assert(queued_clip_list.size() == 1);
437 queued_clip_list[0].stream_idx = stream_idx;
441 // If we are playing a clip, set override_stream_idx, and the player thread will
442 // pick it up and change its internal index.
444 override_stream_idx = stream_idx;
445 new_clip_changed.notify_all();
449 // OK, so we're standing still, presumably at the end of a clip.
450 // Look at the last frame played (if it exists), and show the closest
452 if (last_pts_played < 0) {
455 last_pts = last_pts_played;
458 lock_guard<mutex> lock(frame_mu);
459 auto it = find_first_frame_at_or_after(frames[stream_idx], last_pts);
460 if (it == frames[stream_idx].end()) {
463 destination->setFrame(stream_idx, *it);
466 void Player::take_queue_spot()
468 lock_guard<mutex> lock(queue_state_mu);
472 void Player::release_queue_spot()
474 lock_guard<mutex> lock(queue_state_mu);
475 assert(num_queued_frames > 0);
477 new_clip_changed.notify_all();
480 double compute_time_left(const vector<Clip> &clips, const map<size_t, double> &progress)
482 // Look at the last clip and then start counting from there.
483 assert(!progress.empty());
484 auto last_it = progress.end();
486 double remaining = 0.0;
487 double last_fade_time_seconds = 0.0;
488 for (size_t row = last_it->first; row < clips.size(); ++row) {
489 const Clip &clip = clips[row];
490 double clip_length = double(clip.pts_out - clip.pts_in) / TIMEBASE / clip.speed;
491 if (row == last_it->first) {
492 // A clip we're playing: Subtract the part we've already played.
493 remaining = clip_length * (1.0 - last_it->second);
495 // A clip we haven't played yet: Subtract the part that's overlapping
496 // with a previous clip (due to fade).
497 remaining += max(clip_length - last_fade_time_seconds, 0.0);
499 last_fade_time_seconds = min(clip_length, clip.fade_time_seconds);