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A complete audio solution for Godot 3.3.x, making procedural sound and adaptive/procedural music possible with a few nodes and a couple lines of code.
Godot Mixing Desk 2.13.3
The Mixing Desk is a complete audio solution for the Godot Engine. Godot already ships with some awesome audio capabilities - namely the bus system which is so intuitive for audio. Generally speaking, this makes it easy to implement audio in Godot. But for some more advanced features, a bit of coding is required.
That's where Mixing Desk comes in. A modular plugin, allowing for procedural audio and adaptive music in games, with just a couple of nodes and a line of code for each implementation.
Mixing Desk: Music
The MDM was designed to make adaptive, interactive music easier to design within Godot. You contain songs within song
nodes, each with their own individual properties and with any number of modular components. You can do anything between looping a single audio track, to creating a procedurally generated soundtrack completely dictated by the actions of your game, and with random elements spawned by chance.
NOTE: Ensure that your audio files, whether they are intended to loop or not, are imported with
loop
disabled. MDM handles looping in its own way, and auto-looping tracks will mess things up!
Setting up MDM
Core Tracks
Create a MixingDeskMusic, and place Song nodes for each of your songs, similar to in the image above. As you can see, the main song files are placed under a "CoreContainer", which plays all the audio nodes under it by default. As for the other nodes, they are overlays, and the blue-outlined nodes are AutoContainers, which we will come to shortly.
You must fill in the properties in the song node!
If you don't know the tempo of the music you're using, ask the composer. If you don't know the composer, check the website where you downloaded the music, or the readme in the sample pack you downloaded. If in doubt, try out BPM detection software such as here: https://www.conversion-tool.com/bpmdetector/?lang=en Similar process for bars and beats in bar - but beats in bar will, most of the time, be 4, sometimes 3. Transition beats is how long the fadeout should be when changing song or stopping. And auto-transition is useful for a codeless approach to adaptive music: point the song at the node which contains the desired signal, name the signal, and the song will be queued for transition when the signal is emitted. Transition type can be either beat or bar. Each song can also be routed to its own bus, if desired. By default, it is set to "Music". Mixing Desk will automatically create the named bus if it does not exist, upon running the game, and route the audio to that bus. If this bus isn't "Music", the bus will be routed to "Music".
TIP: All full-length tracks (I.E. all tracks but Concat and Rollover) may extend over the bar length of the track, allowing reverb/delay/decay tails. This ensures smoother looping with instruments that sound out after the play is finished.
TIP cont'd: Such as the above image - you may export your tracks beyond the actual length, to allow instruments to decay. Mixing Desk copies the tracks and plays, then deletes the copies. No awkward repeat cutoffs!
Overlays (random, sequence, concat and rollover tracks)
Overlays are set up in much the same way as core tracks. Create a RandomContainer, and a random track from that folder will be played on each repeat, with a slight chance of no track playing depending on the value of the RandomContainer's random_chance
- if the random number generated (between 0 and 1) each time song plays is lower than the value of random_chance
, the track plays.
SeqContainers play the audio nodes in order, from top to bottom, and over again. Overlays must be equal length or shorter than the corresponding core tracks.
Use a ConcatContainer for a group of short tracks, particularly percussion, that you wish to play in random order over the top of the song. These tracks will be chosen randomly and each will immediately follow the previous. Good for randomising drums by the measure, or whichever length samples you choose to throw in.
Rollovers are semi-transitions within a loop. Think of a crash roll, or snare rush, or any build-up/wind-down clip that may "roll over" from near the end of your clip, to after the start of the next loop. Place a RolloverContainer and add 1 or more rollover clips beneath it, and edit the crossover beat
with the beat number of the clip that should line up with the first beat after looping. If the clip is 9 beats long, and the apex of its climb, or timing of its impact, is on beat 5 - the number is 5. Remember, count from 0, otherwise it will be thrown off.
Loading and hitting play
Once your nodetree is setup, you're all ready to play your music in Godot.
First, pick a play mode. It's a property of the MDM node.
Play Once: as the name suggests, it plays a song once and then stops
Loop One: loop the currently playing song until you decide to stop or transition to another, which will then loop
Shuffle: play a song, silence for a moment, then play another
Endless Shuffle: seamlessly shuffle between all songs in the MDM instance
Endless Loop: Loop the whole playlist without gaps in between
note: all vertical/horizontal adaptive features are available in all play modes!
To have a song play first thing, you can easily set the autoplay
export variable in MDM. Choose which song you'd like to autoplay, and you're ready to go. Otherwise, you can easily call it in code at the appropriate moment for your song to begin. To do this, simply call init_song(song)
to load the track ready to play.
Then, call play(song)
- track in both cases being either the name of the song node you wish to play, or its index, counting from 0. Either will work, though names are easier for us humans to remember, while index numbers are easier to do maths on - it's your call. To quickly initialise and play in one, call quickplay(song)
.
Adapting the music
Based on implementations of interactive music in FMOD and Wwise, the MDM neatly covers the two major branches of adaptive music outlined by Michael Sweet.
Vertical Remixing/Layering
MDM can fade individual tracks in and out using the fade_in(track)
or fade_out(track)
functions. It can also fade multiple tracks in/out at once with the mute_below_layer(track)
and mute_above_layer(track)
functions. Fading and muting both have toggles, too - toggle_fade(song, track)
and toggle_mute(song, track)
. To begin a track with a base layer only, the start_alone(track, layer)
function can be used.
To control an track's (or group of tracks') volume constantly based on a parameter, however, is only slightly more tricky. An AutoFadeContainer will automatically change the volume of its child audio tracks to match the state of a selected variable. This can be done quite simply by dropping in the aforementioned container, and editing the properties to suit. Use All
play style if you want all the tracks to play, random
if you want a randomly selected single track to play. Check toggle
if it is a simple true/false value for toggling the track on. target_node
is the node that contains the desired value, and target_property
is the variable you wish to use for volume modulation. Min/max range is self-explanatory - the range of values to use for modulation. Check invert if it is a value that should increase the volume as the value decreases - distance, for instance. Lastly, the track_speed
is the number by which to increment volume to match the property value. Higher values mean quicker tracking.
The AutoLayerContainer works in a similar way, though treats its contained layers as a an arrangement in series of intensity. Use this container to fade in tracks according to an integer value, depending on the play mode you choose. With additive
, you can fade in all tracks below a certain number, and fade them out above. With single
, you can choose to fade in only a single one of the tracks. With pad
, you can fade in tracks around the chosen number, by the pad number specified. That can either be done automatically, similarly to the AutoFadeContainer, by choosing a node and naming its property, and denoting the range of values to be expected, or manually through code, by changing the values of layer_min
and layer_max
.
Horizontal Resequencing
MDM consistently keeps track of beats and bars, and output signals accordingly. Aligning with this functionality is the ability to switch between songs on the fly, either on the beat or on the bar. A code-less approach is achieved using the auto-transition properties in the Song node itself. You can bind a song to an in-game signal. Just enable auto-transiiton, point the song to the right node in your scene, enter the name of the signal, and finally choose a transition type - beat or bar. When the signal is emitted, MDM will transition to the song at the specified musical demarcation. In the screenshot below, the song will play on the next bar when the level node emits the combat_begin
signal.
In your game's code, however, it is rather simple to queue a transition more specifically. Wherever you need to queue a transition in code, you can easily do this using the queue_beat_transition(song)
or queue_bar_transition(song)
functions. Just as in play()
, the song
argument is the name o r index of the song to transition to.
You can also insert a clip in between the source and destination songs by calling queue_sequence(sequence, type, on_end)
. The sequence
variable is an array of two songnames; the first being the intervening clip, and the second being the destination song. type
is a string, either "beat" or "bar", and denotes which signal to wait for before transitioning. Lastly, on_end
is the play_mode of the final track, and can be either "play_once", "loop", or "shuffle".
Video example of both horizontal and vertical techniques in action
Integrating the music and game
MDM outputs beat and bar signals which can easily be connected to any other node in the scene. This way, you can time events in the game to the music. For example, a yield(mdm, 'bar')
can delay actions until they're in sync with the next bar. MDM also outputs signals when a song ends, when the song is changed, and upon shuffling in a playlist. Here is a run-down of the signals and their connected variables:
bar(bar : int)
beat(beat : int)
end(song_num : int)
shuffle(old_song_num : int, new_song_num : int)
song_changed(old_song_num : int, new_song_num : int)
Mixing Desk: Sound
The MDS is a fully-featured sound-playing plugin, allowing procedural playback of multiple layered and combined sounds through the use of handy containers that each treat their nested sounds in a different way. But there's no need to remember any special functions - just like AudioStreamPlayers, all MDS sound contianers can be started and stopped using play()
and stop()
. They can, of course, also be autostarted using the export variable autoplay
.
Each SoundContainer has similar properties, but they behave in different ways. For example, all containers have the option to randomise pitch and volume, and will all play instanced (to alleviate sound-replay fatigue which is so common when repeating the same sound effect over and over). They also all have the option to spawn under a different node, using the spawn-node
export. Their behaviour is, as noted, the key difference. Their functions are detailed below.
Setting up MDS
MDS is slightly different to MDM - there are still container nodes, but no parent Mixing Desk. There are five kinds of MDS container:
PolySoundContainer
plays all sounds nested within.RandomSoundContainer
plays 1 or more sounds nested within, chosen at random, the number of which is specified in theplay(num)
call, or in the sound number export variable.ScatterSoundContainer
will 'scatter' multiple sounds at random times, by use of 1 or more timers. More on scattering below.ConcatSoundContainer
plays a random sequence of nested sounds, the number of which is specified in the call, or in the export variable.MultiSoundContainer
can contain any of the other containers, or AudioStreamPlayers, and will play all nodes nested within.
And, similar to the AudioStreamPlayers found natively in Godot, there is a Node (no position), 2D, and 3D type for each container.
To play a container, simply call play()
!
Also note that each container has four export variables - autoplay, volume and pitch ranges, and sound number (which we will come to in a moment). Autoplay, as the name suggests, plays the sound the moment it is added to the scene. This is useful for bullets and other items that should make a sound on appearance. The volume and pitch ranges are the randomisation ranges of those respective properties, and is relative to the volume and pitch of the nested sounds.
For instance, an audioplayer set to -10db at a pitch scale of 1, under a container with volume range set to 2 and pitch range set to 0.3, will range between the volumes of -12 and -8 db, and the pitch scales of -0.7 and 1.3.
The sound number is only relevant for random containers and concat containers. This is the number of random sounds to play in the play()
call.
Sound scattering
Scattering sounds is great for ambience. Load up all the sounds you can imagine randomly occuring in a place - animal calls in a forest, shouting and cars in a city - and let MDS do the rest.
An example of sound scattering in Hell Hal
Achieved by calling the scatter function once in _ready()!
To scatter a group of sounds, arrange them nested in a container like usual.
If you want the sounds to begin scattering as soon as the scene is loaded, check Autoplay
in the scatter sound container, and edit the properties in the inspector to how you'd like it.
If you'd prefer to begin scattering at a different time, simply call play(), like any other sound container!
Either method will generate 'voices' number of timers, the timeouts of each being determined randomly between the floats 'min_time' and 'max_time'.
At each timer's timeout, it will randomly play a nested sound and begin again, its timeout once more randomised.
This will continue indefinitely, randomised timers calling randomised sounds, until you call stop()
. This will delete all the timers.
Timeout
is the number of seconds after which to end scattering. Set to 0 if you want scattering to continue indefinitely.
Feel free to contact me here on Github with any questions, or on Discord at irmoz#8586.
A complete audio solution for Godot 3.3.x, making procedural sound and adaptive/procedural music possible with a few nodes and a couple lines of code.
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Quick Information
A complete audio solution for Godot 3.3.x, making procedural sound and adaptive/procedural music possible with a few nodes and a couple lines of code.