LavaPlayer is an audio player library written in Java which can load audio tracks from various sources and convert them into a stream of Opus frames. It is designed for use with Discord bots, but it can be used anywhere where Opus format output is required.
Note
This is a fork of the original Lavaplayer with some additional features and fixes from Walkyst's fork.
Tip
Please read the FAQ in case of issues.
Note
This fork requires Java 11 or newer. If you need Java 8 support you should update as java 8 was released 10 years ago.
Replace x.y.z
with the latest version
number:
- Repository: mavenCentral
- Artifact: dev.arbjerg:lavaplayer:x.y.z
Snapshots are published to https://maven.lavalink.dev/snapshots & https://s01.oss.sonatype.org/content/repositories/snapshots
Using in Gradle:
repositories {
mavenCentral()
maven { url "https://jitpack.io" } // For com.github.walkyst.JAADec-fork:jaadec-ext-aac & ibxm-fork:com.github.walkyst:ibxm-fork
}
dependencies {
implementation 'dev.arbjerg:lavaplayer:x.y.z'
}
Using in Maven:
<repositories>
<repository>
<id>jitpack</id>
<url>https://jitpack.io</url>
</repository>
</repositories>
<dependencies>
<dependency>
<groupId>dev.arbjerg</groupId>
<artifactId>lavaplayer</artifactId>
<version>x.y.z</version>
</dependency>
</dependencies>
The set of sources where LavaPlayer can load tracks from is easily extensible, but the ones currently included by default are:
YouTubeYouTube support is now provided by youtube-source- SoundCloud
- Bandcamp
- Vimeo
- Twitch streams
- Local files
- HTTP URLs
The file formats that LavaPlayer can currently handle are (relevant for file/url sources):
- MP3
- FLAC
- WAV
- Matroska/WebM (AAC, Opus or Vorbis codecs)
- MP4/M4A (AAC codec)
- OGG streams (Opus, Vorbis and FLAC codecs)
- AAC streams
- Stream playlists (M3U and PLS)
What makes LavaPlayer unique is that it handles everything in the same process. Different sources and container formats are handled in Java, while decoding and encoding of audio are handled by embedded native libraries. This gives it a very fine-grained control over the resources that it uses, which means a low memory footprint as well as the chance to skip decoding and encoding steps altogether when the input format matches the output format. Some key things to remember:
- Memory usage is both predictable and low. The amount of memory used per track when testing with YouTube was at most 350 kilobytes per track plus the off-heap memory for the thread stack, since there is one thread per playing track.
- The most common format used in YouTube is Opus, which matches the exact output format required for Discord. When no volume adjustment is applied, the packets from YouTube are directly passed to output, which saves CPU cycles.
- Resource leaks are unlikely because there are no additional processes launched and only one thread per playing track. When an audio player is not queried for an user-configured amount of time, then the playing track is aborted and the thread cleaned up. This avoids thread leaks even when the audio player is not shut down as it is supposed to.
Seeking is supported on all non-stream formats and sources. When a seek is performed on a playing track, the previously buffered audio samples will be provided until the seek is finished (this is configurable). When a seek is performed on a track which has not yet started, it will start immediately from the chosen position.
Due to media containers supporting seeking at different resolutions, the position that a media player can start reading data from might be several seconds from the location that the user actually wanted to seek to. LavaPlayer handles it by remembering the position where it was requested to seek to, jumping to the highest position which is not after that and then ignoring the audio until the actual position that was requested. This provides a millisecond accuracy on seeking.
When creating an instance of an AudioPlayerManager
, sources where the tracks should be loaded from with it must be
manually registered. When loading tracks, you pass the manager an identifier and a handler which will get asynchronously
called when the result has arrived. The handler has separate methods for receiving resolved tracks, resolved playlists,
exceptions or being notified when nothing was found for the specified identifier.
Since the tracks hold only minimal meta-information (title, author, duration and identifier), loading playlists does not usually require the library to check the page of each individual track for sources such as YouTube or SoundCloud. This makes loading playlists pretty fast.
Any source that implements the AudioSourceManager
interface can be registered to the player manager. These can be
custom sources using either some of the supported containers and codecs or defining a totally new way the tracks are
actually executed, such as delegating it to another process, should the set of formats supported by LavaPlayer by
default not be enough.
First thing you have to do when using the library is to create a DefaultAudioPlayerManager
and then configure it to
use the settings and sources you want. Here is a sample:
AudioPlayerManager playerManager = new DefaultAudioPlayerManager();
AudioSourceManagers.registerRemoteSources(playerManager);
There are various configuration settings that can be modified:
- Opus encoding and resampling quality settings.
- Frame buffer duration: how much of audio is buffered in advance.
- Stuck track threshold: when no data from a playing track comes in the specified time, an event is sent.
- Abandoned player cleanup threshold: when the player is not queried in the specified amount of time, it is stopped.
- Garbage collection monitoring: logs statistics of garbage collection pauses every 2 minutes. If the pauses are long enough to cause a stutter in the audio, it will be logged with a warning level, so you could take action to optimize your GC settings.
If possible, you should use a single instance of a player manager for your whole application. A player manager manages several thread pools which make no sense to duplicate.
Once you have a player manager, you can create players from it. Generally you would want to create a player per every different target you might want to separately stream audio to. It is totally fine to create them even if they are unlikely to be used, as they do not use any resources on their own without an active track.
Creating a player is rather simple:
AudioPlayer player = playerManager.createPlayer();
Once you have an instance of an audio player, you need some way to receive events from it. For that you should register
a listener to it which either extends the AudioEventAdapter
class or implements AudioEventListener
. Since that
listener receives the events for starting and ending tracks, it makes sense to also make it responsible for scheduling
tracks. Assuming TrackScheduler
is a class that implements AudioEventListener
:
TrackScheduler trackScheduler = new TrackScheduler(player);
player.addListener(trackScheduler);
Now you have an audio player capable of playing instances of AudioTrack
. However, what you don't have is audio tracks,
which are the next things you have to obtain.
To load a track, you have to call either the loadItem
or loadItemOrdered
method of
an AudioPlayerManager
. loadItem
takes an identifier parameter and a load handler parameter. The identifier is a
piece of text that should identify the track for some source. For example if it is a YouTube video ID, then YouTube
source manager will load it, if it is a file path then the local file source will load it. The handler parameter is an
instance of AudioLoadResultHandler
, which has separate methods for different results of the loading process. You can
either have a dedicated class for this or you can simply pass it an anonymous class as in the next example:
playerManager.loadItem(identifier, new AudioLoadResultHandler() {
@Override
public void trackLoaded(AudioTrack track) {
trackScheduler.queue(track);
}
@Override
public void playlistLoaded(AudioPlaylist playlist) {
for (AudioTrack track : playlist.getTracks()) {
trackScheduler.queue(track);
}
}
@Override
public void noMatches() {
// Notify the user that we've got nothing
}
@Override
public void loadFailed(FriendlyException throwable) {
// Notify the user that everything exploded
}
}
Most of these methods are rather obvious. In addition to everything exploding, loadFailed
will also be called for
example when a YouTube track is blocked or not available in your area. The FriendlyException
class has a field
called severity
. If the value of this is COMMON
, then it means that the reason is definitely not a bug or a network
issue, but because the track is not available, such as the YouTube blocked video example. These message in this case can
simply be forwarded as is to the user.
The other method for loading tracks, loadItemOrdered
is for cases where you want the tracks to be loaded in order for
example within one player. loadItemOrdered
takes an ordering channel key as the first parameter, which is simply any
object which remains the same for all the requests that should be loaded in the same ordered queue. The most common use
would probably be to just pass it the AudioPlayer
instance that the loaded tracks will be queued for.
In the previous example I did not actually start playing the loaded track yet, but sneakily passed it on to our
fictional TrackScheduler
class instead. Starting the track is however a trivial thing to do:
player.playTrack(track);
Now the track should be playing, which means buffered for whoever needs it to poll its frames. However, you would need to somehow react to events, most notably the track finishing, so you could start the next track.
Events are handled by event handlers added to an AudioPlayer
instance. The simplest way for creating the handler is to
extend the AudioEventAdapter
class. Here is a quick description of each of the methods it has, in the context of using
it for a track scheduler:
public class TrackScheduler extends AudioEventAdapter {
@Override
public void onPlayerPause(AudioPlayer player) {
// Player was paused
}
@Override
public void onPlayerResume(AudioPlayer player) {
// Player was resumed
}
@Override
public void onTrackStart(AudioPlayer player, AudioTrack track) {
// A track started playing
}
@Override
public void onTrackEnd(AudioPlayer player, AudioTrack track, AudioTrackEndReason endReason) {
if (endReason.mayStartNext) {
// Start next track
}
// endReason == FINISHED: A track finished or died by an exception (mayStartNext = true).
// endReason == LOAD_FAILED: Loading of a track failed (mayStartNext = true).
// endReason == STOPPED: The player was stopped.
// endReason == REPLACED: Another track started playing while this had not finished
// endReason == CLEANUP: Player hasn't been queried for a while, if you want you can put a
// clone of this back to your queue
}
@Override
public void onTrackException(AudioPlayer player, AudioTrack track, FriendlyException exception) {
// An already playing track threw an exception (track end event will still be received separately)
}
@Override
public void onTrackStuck(AudioPlayer player, AudioTrack track, long thresholdMs) {
// Audio track has been unable to provide us any audio, might want to just start a new track
}
}
To use it with JDA 4, you would need an instance of AudioSendHandler
. There is only the slight difference of no
separate canProvide
and provide
methods in AudioPlayer
, so the wrapper for this is simple:
public class AudioPlayerSendHandler implements AudioSendHandler {
private final AudioPlayer audioPlayer;
private AudioFrame lastFrame;
public AudioPlayerSendHandler(AudioPlayer audioPlayer) {
this.audioPlayer = audioPlayer;
}
@Override
public boolean canProvide() {
lastFrame = audioPlayer.provide();
return lastFrame != null;
}
@Override
public ByteBuffer provide20MsAudio() {
return ByteBuffer.wrap(lastFrame.getData());
}
@Override
public boolean isOpus() {
return true;
}
}