mirror of
https://github.com/owncast/owncast.git
synced 2024-11-23 05:14:20 +03:00
489 lines
16 KiB
JavaScript
489 lines
16 KiB
JavaScript
/*
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The Owncast Latency Compensator.
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It will try to slowly adjust the playback rate to enable the player to get
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further into the future, with the goal of being as close to the live edge as
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possible, without causing any buffering events.
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How does latency occur?
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Two pieces are at play. The first being the server. The larger each segment is
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that is being generated by Owncast, the larger gap you are going to be from
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live when you begin playback.
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Second is your media player.
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The player tries to play every segment as it comes in.
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However, your computer is not always 100% in playing things in real time, and
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there are natural stutters in playback. So if one frame is delayed in playback
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you may not see it visually, but now you're one frame behind. Eventually this
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can compound and you can be many seconds behind.
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How to help with this? The Owncast Latency Compensator will:
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- Determine the start (max) and end (min) latency values.
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- Keep an eye on download speed and stop compensating if it drops too low.
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- Limit the playback speedup rate so it doesn't sound weird by jumping speeds.
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- Force a large jump to into the future once compensation begins.
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- Dynamically calculate the speedup rate based on network speed.
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- Pause the compensation if buffering events occur.
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- Completely give up on all compensation if too many buffering events occur.
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*/
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const REBUFFER_EVENT_LIMIT = 4; // Max number of buffering events before we stop compensating for latency.
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const MIN_BUFFER_DURATION = 200; // Min duration a buffer event must last to be counted.
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const MAX_SPEEDUP_RATE = 1.08; // The playback rate when compensating for latency.
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const MAX_SPEEDUP_RAMP = 0.02; // The max amount we will increase the playback rate at once.
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const TIMEOUT_DURATION = 30 * 1000; // The amount of time we stop handling latency after certain events.
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const CHECK_TIMER_INTERVAL = 3 * 1000; // How often we check if we should be compensating for latency.
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const BUFFERING_AMNESTY_DURATION = 3 * 1000 * 60; // How often until a buffering event expires.
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const REQUIRED_BANDWIDTH_RATIO = 1.8; // The player:bitrate ratio required to enable compensating for latency.
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const HIGHEST_LATENCY_SEGMENT_LENGTH_MULTIPLIER = 2.6; // Segment length * this value is when we start compensating.
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const LOWEST_LATENCY_SEGMENT_LENGTH_MULTIPLIER = 1.8; // Segment length * this value is when we stop compensating.
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const MIN_LATENCY = 4 * 1000; // The absolute lowest we'll continue compensation to be running at.
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const MAX_LATENCY = 15 * 1000; // The absolute highest we'll allow a target latency to be before we start compensating.
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const MAX_JUMP_LATENCY = 5 * 1000; // How much behind the max latency we need to be behind before we allow a jump.
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const MAX_JUMP_FREQUENCY = 20 * 1000; // How often we'll allow a time jump.
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const MAX_ACTIONABLE_LATENCY = 80 * 1000; // If latency is seen to be greater than this then something is wrong.
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const STARTUP_WAIT_TIME = 10 * 1000; // The amount of time after we start up that we'll allow monitoring to occur.
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function getCurrentlyPlayingSegment(tech) {
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const targetMedia = tech.vhs.playlists.media();
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const snapshotTime = tech.currentTime();
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let segment;
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// Iterate trough available segments and get first within which snapshot_time is
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// eslint-disable-next-line no-plusplus
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for (let i = 0, l = targetMedia.segments.length; i < l; i++) {
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// Note: segment.end may be undefined or is not properly set
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if (snapshotTime < targetMedia.segments[i].end) {
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segment = targetMedia.segments[i];
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break;
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}
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}
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if (!segment) {
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[segment] = targetMedia.segments;
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}
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return segment;
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}
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class LatencyCompensator {
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constructor(player) {
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this.player = player;
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this.playing = false;
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this.enabled = false;
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this.running = false;
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this.inTimeout = false;
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this.jumpingToLiveIgnoreBuffer = false;
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this.timeoutTimer = 0;
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this.checkTimer = 0;
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this.bufferingCounter = 0;
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this.bufferingTimer = 0;
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this.playbackRate = 1.0;
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this.lastJumpOccurred = null;
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this.startupTime = new Date();
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this.clockSkewMs = 0;
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this.currentLatency = null;
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// Keep track of all the latencies we encountered buffering events
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// in order to determine a new minimum latency.
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this.bufferedAtLatency = [];
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this.player.on('playing', this.handlePlaying.bind(this));
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this.player.on('pause', this.handlePause.bind(this));
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this.player.on('error', this.handleError.bind(this));
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this.player.on('waiting', this.handleBuffering.bind(this));
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this.player.on('stalled', this.handleBuffering.bind(this));
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this.player.on('ended', this.handleEnded.bind(this));
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this.player.on('canplaythrough', this.handlePlaying.bind(this));
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this.player.on('canplay', this.handlePlaying.bind(this));
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this.check = this.check.bind(this);
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this.start = this.start.bind(this);
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this.enable = this.enable.bind(this);
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this.countBufferingEvent = this.countBufferingEvent.bind(this);
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}
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// To keep our client clock in sync with the server clock to determine
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// accurate latency the clock skew should be set here to be used in
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// the calculation. Otherwise if somebody's client clock is significantly
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// off it will have a very incorrect latency determination and make bad
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// decisions.
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setClockSkew(skewMs) {
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this.clockSkewMs = skewMs;
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}
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// This is run on a timer to check if we should be compensating for latency.
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check() {
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// We have an arbitrary delay at startup to allow the player to run
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// normally and hopefully get a bit of a buffer of segments before we
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// start messing with it.
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if (new Date().getTime() - this.startupTime.getTime() < STARTUP_WAIT_TIME) {
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return;
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}
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// If we're paused then do nothing.
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if (this.player.paused()) {
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return;
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}
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if (this.player.seeking()) {
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return;
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}
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if (this.inTimeout) {
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return;
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}
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if (!this.enabled) {
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return;
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}
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const tech = this.player.tech({ IWillNotUseThisInPlugins: true });
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// We need access to the internal tech of VHS to move forward.
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// If running under an Apple browser that uses CoreMedia (Safari)
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// we do not have access to this as the tech is internal to the OS.
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if (!tech || !tech.vhs) {
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return;
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}
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// Network state 2 means we're actively using the network.
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// We only want to attempt latency compensation if we're continuing to
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// download new segments.
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const networkState = this.player.networkState();
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if (networkState !== 2) {
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return;
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}
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let totalBuffered = 0;
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try {
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// Check the player buffers to make sure there's enough playable content
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// that we can safely play.
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if (tech.vhs.stats.buffered.length === 0) {
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this.timeout();
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return;
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}
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tech.vhs.stats.buffered.forEach(buffer => {
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totalBuffered += buffer.end - buffer.start;
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});
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} catch (e) {
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console.error(e);
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}
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// Determine how much of the current playlist's bandwidth requirements
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// we're utilizing. If it's too high then we can't afford to push
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// further into the future because we're downloading too slowly.
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const currentPlaylist = tech.vhs.playlists.media();
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const currentPlaylistBandwidth = currentPlaylist.attributes.BANDWIDTH;
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const playerBandwidth = tech.vhs.systemBandwidth;
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const bandwidthRatio = playerBandwidth / currentPlaylistBandwidth;
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try {
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const segment = getCurrentlyPlayingSegment(tech);
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if (!segment) {
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return;
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}
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// If we're downloading media fast enough or we feel like we have a large
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// enough buffer then continue. Otherwise timeout for a bit.
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if (bandwidthRatio < REQUIRED_BANDWIDTH_RATIO && totalBuffered < segment.duration * 6) {
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this.timeout();
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return;
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}
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// How far away from live edge do we stop the compensator.
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const computedMinLatencyThreshold = Math.max(
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MIN_LATENCY,
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segment.duration * 1000 * LOWEST_LATENCY_SEGMENT_LENGTH_MULTIPLIER,
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);
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// Create an array of all the buffering events in the past along with
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// the computed min latency above.
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const targetLatencies = this.bufferedAtLatency.concat([computedMinLatencyThreshold]);
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// Determine if we need to reduce the minimum latency we computed
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// above based on buffering events that have taken place in the past by
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// creating an array of all the buffering events and the above computed
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// minimum latency target and averaging all those values.
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const minLatencyThreshold =
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targetLatencies.reduce((sum, current) => sum + current, 0) / targetLatencies.length;
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// How far away from live edge do we start the compensator.
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let maxLatencyThreshold = Math.max(
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minLatencyThreshold * 1.4,
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Math.min(segment.duration * 1000 * HIGHEST_LATENCY_SEGMENT_LENGTH_MULTIPLIER, MAX_LATENCY),
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);
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// If this newly adjusted minimum latency ends up being greater than
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// the previously computed maximum latency then reset the maximum
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// value using the minimum + an offset.
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if (minLatencyThreshold >= maxLatencyThreshold) {
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maxLatencyThreshold = minLatencyThreshold + 3000;
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}
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const segmentTime = segment.dateTimeObject.getTime();
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const now = new Date().getTime() + this.clockSkewMs;
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const latency = now - segmentTime;
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this.currentLatency = latency;
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// Since the calculation of latency is based on clock times, it's possible
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// things can be reported incorrectly. So we use a sanity check here to
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// simply bail if the latency is reported to so high we think the whole
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// thing is wrong. We can't make decisions based on bad data, so give up.
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// This can also occur if somebody pauses for a long time and hits play
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// again but it's not really possible to know the difference between
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// the two scenarios.
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if (Math.abs(latency) > MAX_ACTIONABLE_LATENCY) {
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this.timeout();
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return;
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}
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if (latency > maxLatencyThreshold) {
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// If the current latency exceeds the max jump amount then
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// force jump into the future, skipping all the video in between.
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if (this.shouldJumpToLive() && latency > maxLatencyThreshold + MAX_JUMP_LATENCY) {
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const jumpAmount = latency / 1000 - segment.duration * 3;
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const seekPosition = this.player.currentTime() + jumpAmount;
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console.info(
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'latency',
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latency / 1000,
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'jumping',
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jumpAmount,
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'to live from ',
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this.player.currentTime(),
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' to ',
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seekPosition,
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);
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// Verify we have the seek position buffered before jumping.
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const availableBufferedTimeEnd = tech.vhs.stats.buffered[0].end;
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const availableBufferedTimeStart = tech.vhs.stats.buffered[0].start;
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if (seekPosition > availableBufferedTimeStart < availableBufferedTimeEnd) {
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this.jump(seekPosition);
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return;
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}
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}
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// Using our bandwidth ratio determine a wide guess at how fast we can play.
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let proposedPlaybackRate = bandwidthRatio * 0.33;
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// But limit the playback rate to a max value.
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proposedPlaybackRate = Math.max(Math.min(proposedPlaybackRate, MAX_SPEEDUP_RATE), 1.0);
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if (proposedPlaybackRate > this.playbackRate + MAX_SPEEDUP_RAMP) {
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// If this proposed speed is substantially faster than the current rate,
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// then allow us to ramp up by using a slower value for now.
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proposedPlaybackRate = this.playbackRate + MAX_SPEEDUP_RAMP;
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}
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// Limit to 3 decimal places of precision.
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proposedPlaybackRate = Math.round(proposedPlaybackRate * 10 ** 3) / 10 ** 3;
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// Otherwise start the playback rate adjustment.
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this.start(proposedPlaybackRate);
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} else if (latency <= minLatencyThreshold) {
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this.stop();
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}
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console.info(
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'latency',
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latency / 1000,
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'min',
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minLatencyThreshold / 1000,
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'max',
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maxLatencyThreshold / 1000,
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'playback rate',
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this.playbackRate,
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'enabled:',
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this.enabled,
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'running: ',
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this.running,
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'skew: ',
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this.clockSkewMs,
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'rebuffer events: ',
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this.bufferingCounter,
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);
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} catch (err) {
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// console.error(err);
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}
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}
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shouldJumpToLive() {
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// If we've been rebuffering some recently then don't make it worse by
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// jumping more into the future.
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if (this.bufferingCounter > 1) {
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return false;
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}
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const now = new Date().getTime();
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const delta = now - this.lastJumpOccurred;
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return delta > MAX_JUMP_FREQUENCY;
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}
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jump(seekPosition) {
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this.jumpingToLiveIgnoreBuffer = true;
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this.performedInitialLiveJump = true;
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this.lastJumpOccurred = new Date();
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console.info('current time', this.player.currentTime(), 'seeking to', seekPosition);
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this.player.currentTime(seekPosition);
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setTimeout(() => {
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this.jumpingToLiveIgnoreBuffer = false;
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}, 5000);
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}
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setPlaybackRate(rate) {
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this.playbackRate = rate;
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this.player.playbackRate(rate);
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}
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start(rate = 1.0) {
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if (this.inTimeout || !this.enabled || rate === this.playbackRate) {
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return;
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}
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this.running = true;
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this.setPlaybackRate(rate);
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}
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stop() {
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if (this.running) {
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console.log('stopping latency compensator...');
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}
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this.running = false;
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this.setPlaybackRate(1.0);
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}
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enable() {
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this.enabled = true;
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clearInterval(this.checkTimer);
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clearTimeout(this.bufferingTimer);
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this.checkTimer = setInterval(() => {
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this.check();
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}, CHECK_TIMER_INTERVAL);
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}
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// Disable means we're done for good and should no longer compensate for latency.
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disable() {
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clearInterval(this.checkTimer);
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clearTimeout(this.timeoutTimer);
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this.stop();
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this.enabled = false;
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}
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timeout() {
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if (this.jumpingToLiveIgnoreBuffer) {
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return;
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}
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this.inTimeout = true;
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this.stop();
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clearTimeout(this.timeoutTimer);
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this.timeoutTimer = setTimeout(() => {
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this.endTimeout();
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}, TIMEOUT_DURATION);
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}
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endTimeout() {
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clearTimeout(this.timeoutTimer);
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this.inTimeout = false;
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}
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handlePlaying() {
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const wasPreviouslyPlaying = this.playing;
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this.playing = true;
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clearTimeout(this.bufferingTimer);
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if (!this.enabled) {
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return;
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}
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if (!this.shouldJumpToLive()) {
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return;
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}
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// If we were not previously playing (was paused, or this is a cold start)
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// seek to live immediately on starting playback to handle any long-pause
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// scenarios or somebody starting far back from the live edge.
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// If we were playing previously then that means we're probably coming back
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// from a rebuffering event, meaning we should not be adding more seeking
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// to the mix, just let it play.
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if (!wasPreviouslyPlaying) {
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this.jumpingToLiveIgnoreBuffer = true;
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this.player.liveTracker.seekToLiveEdge();
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this.lastJumpOccurred = new Date();
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}
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}
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handlePause() {
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this.playing = false;
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}
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handleEnded() {
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if (!this.enabled) {
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return;
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}
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this.disable();
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}
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handleError() {
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if (!this.enabled) {
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return;
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}
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this.timeout();
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}
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countBufferingEvent() {
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this.bufferingCounter += 1;
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if (this.bufferingCounter > REBUFFER_EVENT_LIMIT) {
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this.disable();
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return;
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}
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this.bufferedAtLatency.push(this.currentLatency);
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console.log(
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'latency compensation timeout due to buffering:',
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this.bufferingCounter,
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'buffering events of',
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REBUFFER_EVENT_LIMIT,
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);
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// Allow us to forget about old buffering events if enough time goes by.
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setTimeout(() => {
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if (this.bufferingCounter > 0) {
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this.bufferingCounter -= 1;
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}
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}, BUFFERING_AMNESTY_DURATION);
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}
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handleBuffering() {
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if (!this.enabled || this.inTimeout) {
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return;
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}
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if (this.jumpingToLiveIgnoreBuffer) {
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this.jumpingToLiveIgnoreBuffer = false;
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return;
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}
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this.timeout();
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clearTimeout(this.bufferingTimer);
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this.bufferingTimer = setTimeout(() => {
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this.countBufferingEvent();
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}, MIN_BUFFER_DURATION);
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}
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}
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export default LatencyCompensator;
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