Starting with version 4.7.213, Ardour supports Lua scripts.
This Documentation is Work in Progress and far from complete. Also the documented API may be subject to change.
There are cases that Ardour cannot reasonably cater to with core functionality alone, either because they're session specific or user specific edge cases.
Examples for these include voice-activate (record-arm specific tracks and roll transport depending on signal levels), rename all regions after a specific timecode, launch an external application when a certain track is soloed, generate automation curves or simply provide a quick shortcut for a custom batch operation.
Cases like this call for means to extend the DAW without actually changing the DAW itself. This is where scripting comes in.
"Scripting" refers to tasks that could alternatively be executed step-by-step by a human operator.
Lua is a tiny and simple language which is easy to learn, yet allows for comprehensive solutions. Lua is also a glue language it allows to tie existing component in Ardour together in unprecedented ways, and most importantly Lua is one of the few scripting-languages which can be safely used in a real-time environment.
A good introduction to Lua is the book Programming in Lua. The first edition is available online, but if you have the means buy a copy of the book, it not only helps to support the Lua project, but provides for a much nicer reading and learning experience.
The core of Ardour is a real-time audio engine that runs and processes audio. One interfaces with an engine by sending it commands. Scripting can be used to interact with or modify the active Ardour session, just like a user uses the Editor/Mixer GUI to modify the state or parameters of the session.
Doing this programmatically requires some knowledge about the objects used internally. Most Ardour C++ objects and their methods are directly exposed to Lua and one can call functions or modify variables:
session->set_transport_speed (1.0);
Session:set_transport_speed (1.0)
You may notice that there is only a small syntactic difference in this case. While C++ requires recompiling the application for every change, Lua script can be loaded, written or modified while the application is running. Lua also abstracts away many of the C++ complexities such as object lifetime, type conversion and null-pointer checks.
Close ties with the underlying C++ components is where the power of scripting comes from. A script can orchestrate interaction of lower-level components which take the bulk of the CPU time of the final program.
At the time of writing Ardour integrates Lua 5.3.5: Lua 5.3 reference manual.
Like Control surfaces and the GUI, Lua Scripts are confined to certain aspects of the program. Ardour provides the framework and runs Lua (not the other way around).
In Ardour's case Lua is available:
Editor Action Scripts | User initiated actions (menu, shortcuts) for batch processing |
---|---|
Editor Hooks/Callbacks | Event triggered actions for the Editor/Mixer GUI |
Session Scripts | Scripts called at the start of every audio cycle (session, real-time) |
DSP Scripts | Audio/Midi processor - plugins with access to the Ardour session (per track/bus, real-time) |
Script Console | Action Script commandline |
There are is also a special mode:
Commandline Tool | Replaces the complete Editor GUI, direct access to libardour (no GUI) from the
commandline. Be aware that the vast majority of complex functionality is provided by the Editor UI. |
---|
Ardour searches for Lua scripts in the scripts
folder in $ARDOUR_DATA_PATH
,
Apart from scripts included directly with Ardour, this includes
GNU/Linux | $HOME/.config/ardour6/scripts |
---|---|
Mac OS X | $HOME/Library/Preferences/Ardour6/scripts |
Windows | %localappdata%\ardour6\scripts |
Files must end with .lua
file extension.
Scripts are managed via the GUI
Editor Action Scripts | Menu → Edit → Scripted Actions → Manage |
---|---|
Editor Hooks/Callbacks | Menu → Edit → Scripted Actions → Manage |
Session Scripts | Menu → Session → Scripting → Add/Remove Script |
DSP Scripts | Mixer-strip → context menu (right click) → New Lua Proc |
Script Console | Menu → Window → Scripting |
ardour
descriptor table. Required fields are "Name" and "Type".dsp_run
function, more on that later.A minimal example script looks like:
ardour {
["type"] = "EditorAction",
name = "Rewind",
}
function factory (unused_params)
return function ()
Session:goto_start() -- rewind the transport
end
end
The common part for all scripts is the "Descriptor". It's a Lua function which returns a table (key/values) with the following keys (the keys are case-sensitive):
type [required] | one of "DSP ", "Session ", "EditorHook ",
"EditorAction " (the type is not case-sensitive) |
---|---|
name [required] | Name/Title of the script |
author | Your Name |
license | The license of the script (e.g. "GPL" or "MIT") |
description | A longer text explaining to the user what the script does |
Scripts that come with Ardour (currently mostly examples) can be found in the Source Tree.
Action scripts are the simplest form. An anonymous Lua function is called whenever the action is triggered. A simple action script is shown above.
There are 10 action script slots available, each of which is a standard GUI action available from the menu and hence can be bound to a keyboard shortcut.
Session scripts similar to Actions Scripts, except the anonymous function is called periodically every process cycle. The function receives a single parameter - the number of audio samples which are processed in the given cycle
ardour {
["type"] = "session",
name = "Example Session Script",
description = [[
An Example Ardour Session Script.
This example stops the transport after rolling for a specific time.]]
}
-- instantiation options, these are passed to the "factory" method below
function sess_params ()
return
{
["print"] = { title = "Debug Print (yes/no)", default = "no", optional = true },
["time"] = { title = "Timeout (sec)", default = "90", optional = false },
}
end
function factory (params)
return function (n_samples)
local p = params["print"] or "no"
local timeout = params["time"] or 90
a = a or 0
if p ~= "no" then print (a, n_samples, Session:frame_rate (), Session:transport_rolling ()) end -- debug output (not rt safe)
if (not Session:transport_rolling()) then
a = 0
return
end
a = a + n_samples
if (a > timeout * Session:frame_rate()) then
Session:request_transport_speed (0.0, true, ARDOUR.TransportRequestSource.TRS_UI)
end
end
end
Action hook scripts must define an additional function which returns a Set of Signal that which trigger the callback (documenting available slots and their parameters remains to be done).
ardour {
["type"] = "EditorHook",
name = "Hook Example",
description = "Rewind On Solo Change, Write a file when regions are moved.",
}
function signals ()
s = LuaSignal.Set()
s:add (
{
[LuaSignal.SoloActive] = true,
[LuaSignal.RegionPropertyChanged] = true
}
)
return s
end
function factory (params)
return function (signal, ref, ...)
-- print (signal, ref, ...)
if (signal == LuaSignal.SoloActive) then
Session:goto_start()
end
if (signal == LuaSignal.RegionPropertyChanged) then
obj,pch = ...
file = io.open ("/tmp/test" ,"a")
io.output (file
io.write (string.format ("Region: '%s' pos-changed: %s, length-changed: %s\n",
obj:name (),
tostring (pch:containsFramePos (ARDOUR.Properties.Start)),
tostring (pch:containsFramePos (ARDOUR.Properties.Length))
))
io.close (file)
end
end
end
See the scripts folder for examples for now.
Some notes for further doc:
dsp_ioconfig ()
: return a list of possible audio I/O configurations - follows Audio
Unit conventions.dsp_dsp_midi_input ()
: return true if the plugin can receive midi inputdsp_params ()
: return a table of possible parameters (automatable)dsp_init (samplerate)
: called when instantiation the plugin with given samplerate.dsp_configure (in, out)
: called after instantiation with configured plugin i/o.dsp_run (ins, outs, n_samples)
OR dsp_runmap (bufs, in_map, out_map, n_samples,
offset)
: DSP process callback. The former is a convenient abstraction that passes mapped buffers (as table). The
latter is a direct pass-through matching Ardour's internal ::connect_and_run()
API, which requires the caller
to map and offset raw buffers.CtrlPorts
.mididata
which is valid during dsp_run
only.
(dsp_runmap requires the script to pass raw data from the buffers according to in_map)
The top most object in Ardour is the ARDOUR::Session
.
Fundamentally, a Session is just a collection of other things:
Routes (tracks, busses), Sources (Audio/Midi), Regions, Playlists, Locations, Tempo map, Undo/Redo history, Ports, Transport
state and controls, etc.
Every Lua interpreter can access it via the global variable Session
.
GUI context interpreters also have an additional object in the global environment: The Ardour Editor
. The Editor
provides access to high level functionality which is otherwise triggered via GUI interaction such as undo/redo, open/close
windows, select objects, drag/move regions. It also holds the current UI state: snap-mode, zoom-range, etc.
The Editor also provides complex operations such as "import audio" which under the hood, creates a new Track, adds a new
Source Objects (for every channel) with optional resampling, creates both playlist and regions and loads the region onto the
Track all the while displaying a progress information to the user.
Documenting the bound C++ methods and class hierarchy is somewhere on the ToDo list. Meanwhile luabindings.cc is the best we can offer.
Ardour is a highly multithreaded application and interaction between the different threads, particularly real-time threads, needs to to be done with care. This part has been abstracted away by providing separate Lua interpreters in different contexts and restricting available interaction:
The available interfaces differ between contexts. For example, it is not possible to create new tracks or import audio from real-time context; while it is not possible to modify audio buffers from the GUI thread.
run()
.Please see the example scripts included with the source-code. All the files that start with a leading underscore are not included with releases, but are intended as example snippets.
The standalone tool luasession
allows one to access an Ardour session directly from the commandline.
It can also be used as #! interpreter for scripted sessions.
Interaction is limited by the fact that most actions in Ardour are provided by the Editor GUI.
luasession
provides only two special functions load_session
and close_session
and
exposes the AudioEngine
instance as global variable.
for i,_ in AudioEngine:available_backends():iter() do print (i.name) end
backend = AudioEngine:set_backend("ALSA", "", "")
print (AudioEngine:current_backend_name())
for i,_ in backend:enumerate_devices():iter() do print (i.name) end
backend:set_device_name("HDA Intel PCH")
backend:set_buffer_size(1024)
print (backend:buffer_size())
print (AudioEngine:get_last_backend_error())
s = load_session ("/home/rgareus/Documents/ArdourSessions/lua2/", "lua2")
assert (s)
s:request_transport_speed (1.0, true, ARDOUR.TransportRequestSource.TRS_UI)
print (s:transport_rolling())
s:goto_start()
ARDOUR.LuaAPI.usleep (10 * 1000000) -- 10 seconds
close_session()