# WirePlumber Configuration WirePlumber is a heavily modular daemon. By itself, it doesn't do anything except load the configured modules. All the rest of the logic is implemented inside those modules. Modular design ensures that it is possible to swap the implementation of specific functionality without having to re-implement the rest of it, allowing flexibility on target-sensitive parts, such as policy management and making use of non-standard hardware. ## `wireplumber.conf` This is WirePlumber's main configuration file. It is read at startup, before connecting to the PipeWire daemon. Its purpose is to list all the modules that need to be loaded by WirePlumber. The format of this file is custom and resembles a script with commands: ``` # comment command parameter1 parameter2 ... ``` Lines are executed in the order they appear and each of them executes an action defined by the command. Lines starting with `#` are treated as comments and ignored. Possible commands are: * `add-spa-lib` Associates SPA plugin names with the names of the SPA modules that they can be loaded from. This takes 2 parameters: a name pattern and a library name. This actually does not load the SPA plugin, it only calls `pw_core_add_spa_lib` with the 2 paramteres given as arguments. As a consequence, it is safe to call this even if the SPA module is not actually installed on the system. Example: ``` add-spa-lib api.alsa.* alsa/libspa-alsa ``` In this example, we let `libpipewire` know that any SPA plugin whose name starts with `api.alsa.` can be loaded from the SPA module `alsa/libspa-alsa.so` (relative to the standard SPA modules directory). * `load-pipewire-module` Loads a `libpipewire` module. This is similar to the `load-module` commands that would appear on `pipewire.conf`, the configuration file of the PipeWire daemon. This takes at least 1 parameter, the module name, and optionally any module arguments, in the format that they would be given in `pipewire.conf` Format: ``` load-pipewire-module module-name some-argument some-property=value ``` Example: ``` load-pipewire-module libpipewire-module-client-device ``` This command does not affect the PipeWire daemon by any means. It exists simply to allow loading `libpipewire` modules in the pipewire core that runs inside WirePlumber. This is usually useful to load pipewire protocol extensions, so that you can export custom objects to PipeWire and other clients. * `load-module` Loads a WirePlumber module. This takes 2 arguments and an optional parameter block. Format: ``` load-module ABI module-name { "parameter": <"value"> } ``` The `ABI` parameter specifies the binary interface that WirePlumber shall use to load this module. Currently, the only supported ABI is `C`. It exists to allow future expansion, writing modules in other languages. The `module-name` should be the name of the `.so` file without the `.so` extension. Optionally, if the `load-module` line ends with a `{`, the next lines up to and including the next matching `}` are treated as a parameter block. This block essentially is a [GVariant](https://developer.gnome.org/glib/stable/glib-GVariant.html) of type [`a{sv}`](https://developer.gnome.org/glib/stable/gvariant-format-strings.html) in the [GVariant Text Format](https://developer.gnome.org/glib/stable/gvariant-text.html). As a rule of thumb, parameter names in this block must always be strings enclosed in double quotes, the separation between names and values is done with the `:` character and values, regardless of their inner type, must always be enclosed in `<` `>`. Note that starting the parameter block on the next line is an error. The starting brace (`{`) must always be on the `load-module` line. Example: ``` load-module C libwireplumber-module-monitor { "factory": <"api.alsa.enum.udev">, "flags": <["use-adapter", "activate-devices"]> } ``` Parameters are module-dependent. They are passed as a GVariant in the module's initialization function and it is up to the module to interpret their meaning. WirePlumber does not have any reserved parameters. ## Location of configuration files WirePlumber's default location of its configuration files is determined at compile time by the build system. Typically, it ends up being `/etc/wireplumber`. In more detail, this is controlled by the `--sysconfdir` meson option. When this is set to an absolute path, such as `/etc`, the location of the configuration files is set to be `$sysconfdir/wireplumber`. When this is set to a relative path, such as `etc`, then the installation prefix (`--prefix`) is prepended to the path: `$prefix/$sysconfdir/wireplumber` WirePlumber expects its `wireplumber.conf` to reside in that directory. It is possible to override that at runtime by setting the `WIREPLUMBER_CONFIG_FILE` environment variable: ``` WIREPLUMBER_CONFIG_FILE=src/config/wireplumber.conf wireplumber ``` It is also possible to override the whole configuration directory, so that all other configuration files are being read from a different location as well, by setting the `WIREPLUMBER_CONFIG_DIR` environment variable: ``` WIREPLUMBER_CONFIG_DIR=src/config wireplumber ``` ## Location of modules ### WirePlumber modules Like with configuration files, WirePlumber's default location of its modules is determined at compile time by the build system. Typically, it ends up being `/usr/lib/wireplumber-0.1` (or `/usr/lib//wireplumber-0.1` on multiarch systems) In more detail, this is controlled by the `--libdir` meson option. When this is set to an absolute path, such as `/lib`, the location of the modules is set to be `$libdir/wireplumber-$abi_version`. When this is set to a relative path, such as `lib`, then the installation prefix (`--prefix`) is prepended to the path: `$prefix/$libdir/wireplumber-$abi_version`. It is possible to override this directory at runtime by setting the `WIREPLUMBER_MODULE_DIR` environment variable: ``` WIREPLUMBER_MODULE_DIR=build/modules wireplumber ``` ### PipeWire and SPA modules PipeWire and SPA modules are not loaded from the same location as WirePlumber's modules. They are loaded from the location that PipeWire loads them. It is also possible to override these locations by using environment variables: `SPA_PLUGIN_DIR` and `PIPEWIRE_MODULE_DIR`. For more details, refer to PipeWire's documentation. # module-monitor This module internally loads a SPA "device" object which enumerates all the devices of a certain subsystem. Then it listens for "node" objects that are being created by this device and exports them to PipeWire, after adjusting their properties to provide enough context. `module-monitor` does not read any configuration files, however, it supports configuration through parameters defined in the main `wireplumber.conf`. Possible parameters are: * `factory` A string that specifies the name of the SPA factory that loads the intial "device" object. Well-known factories are: * "api.alsa.enum.udev" - Discovers ALSA devices via udev * "api.v4l2.enum.udev" - Discovers V4L2 devices via udev * "api.bluez5.enum.dbus" - Discovers bluetooth devices by calling bluez5 API via D-Bus * `flags` An array of strings that enable specific functionality in the monitor. Possible flags include: * "use-adapter" Instructs the monitor to wrap all the created nodes in an "adapter" SPA node, which provides automatic port splitting/merging and format/rate conversion. This should be always enabled for audio device nodes. * "local-nodes" Instructs the monitor to run all the created nodes locally in in the WirePlumber process, instead of the default behavior which is to create the nodes in the PipeWire process. This is useful for bluetooth nodes, which should run outside of the main PipeWire process for performance reasons. * "activate-devices" Instructs the monitor to automatically set the device profile to "On", so that the nodes are created. If not specified, the profile must be set externally by the user before any nodes appear. # module-config-endpoint This module creates endpoints when WirePlumber detects new nodes in the pipewire graph. Nodes themselves can be created in two ways: Device modes are being created by "monitors" that watch a specific subsystem (udev, bluez, etc...) for devices. Client nodes are being created by client applications that try to stream to/from pipewire. As soon as a node is created, the `module-config-endpoint` iterates through all the `.endpoint` configuration files, in the order that is determined by the `match-node.priority` field, and tries to match the node to the node description in the `[match-node]` table. Upon a successful match, a new endpoint that follows the description in the `[endpoint]` table is created. ## `*.endpoint` configuration files These files are TOML v0.5 files. At the top-level, they must contain exactly 2 tables: `[match-node]` and `[endpoint]` The `[match-node]` table contains properties that match a pipewire node that exists on the graph. Possible fields of this table are: * `priority` Specifies the order in which the `.endpoint` files are being searched for a match with a node. If a node matches the description of more than one `.endpoint` file, the one with the highest priority wins. The type of this field is unsigned integer. Bigger numbers mean higher priority. * `properties` This is a TOML array of tables, where each table must contain two fields: `name` and `value`, both being strings. Each table describes a match against one of the pipewire properties of the node. For a successful node match, all the described properties must match with the node. The value of the `name` field must match exactly the name of the pipewire property, while the value of the `value` field can contain '*' (wildcard) and '?' (joker), adhering to the rules of the [GLib g_pattern_match() function](https://developer.gnome.org/glib/stable/glib-Glob-style-pattern-matching.html). When writing `.endpoint` files, a useful utility that you can use to list device node properties is: ``` $ wireplumber-cli device-node-props ``` Another way to figure out some of these properties *for ALSA nodes* is by parsing the aplay/arecord output. For example, this line from `aplay -l` is interpreted as follows: ``` card 0: PCH [HDA Intel PCH], device 2: ALC3246 [ALC3246 Analog] ``` ``` { name = "api.alsa.path", value = "hw:0,2" }, { name = "api.alsa.card", value = "0" }, { name = "api.alsa.card.id", value = "PCH" }, { name = "api.alsa.card.name", value = "HDA Intel PCH" }, { name = "api.alsa.pcm.device", value = "2" }, { name = "api.alsa.pcm.id", value = "ALC3246" }, { name = "api.alsa.pcm.name", value = "ALC3246 Analog" }, ``` The `[endpoint]` table contains a description of the endpoint to be created. Possible fields of this table are: * `type` Required. Specifies the factory to be used for construction. The only well-known factory at the moment of writing is: `pw-audio-softdsp-endpoint` * `direction` Required. Can be set to either `"sink"` or `"source"`. Specifies the direction of the media flow of this endpoint. A `source` is an endpoint that produces data (i.e. an audio capture device or a playback application) and a `sink` is an endpoint that consumes data (audio playback device or capture application). * `name` Optional. The name of the newly created endpoint. If not specified, the endpoint is named after the node (from the `node.name` property of the node). * `media_class` Optional. A string that specifies an override for the `media.class` property of the node. It can be used in special circumstances to declare that an endpoint is dealing with a different type of data. This is only useful in combination with a policy implementation that is aware of this media class. * `priority` Optional. An unsigned integer that specifies the order in which endpoints are chosen to be the default of a specific device group. Possible device groups are (determined by the endpoint's `media.class`): * Audio/Sink * Audio/Source * Video/Source Every time a new device endpoint is created, wireplumber picks the "default" of the group that it belongs to, based on this priority number: the endpoint with the biggest priority number wins. If not specified, the default priority of an endpoint is equal to zero (i.e. the lowest priority). * `streams` Optional. Specifies the name of a `.streams` file that contains the descriptions of the streams to create for this endpoint. This currently specific to the implementation of the `pw-audio-softdsp-endpoint` and might change in the future. ## `*.streams` configuration files These files contain lists of streams with their names and priorities. They are TOML v0.5 files. Each `.streams` file must contain exactly one top-level array of tables, called `streams`. Every table must contain exactly two fields: `name` and `priority`. The `name` of each stream is used to create the streams on new endpoints. The `priority` of each stream is being interpreted by the policy module to apply restrictions on which app can use the stream at a given time. # module-config-policy This module implements demo-quality policy management that is partly driven by configuration files. The configuration files that this module reads are described below: ## `*.endpoint-link` These files contain rules to link endpoints with each other. They are TOML v0.5 files. Endpoints are normally created by another module, such as `module-config-endpoint` which is described above. As soon as an endpoint is created, the `module-config-policy` uses the information gathered from the `.endpoint-link` files in order to create a link to another endpoint. `.endpoint-link` files can contain 3 top-level tables: * `[match-endpoint]`, required * `[target-endpoint]`, optional * `[endpoint-link]`, required The `[match-endpoint]` table contains properties that match an endpoint that exists on the graph. Possible fields of this table are: * `priority` Specifies the order in which the `.endpoint-link` files are being searched for a match with an endpoint. If an endpoint matches the description of more than one `.endpoint-link` file, the one with the highest priority wins. The type of this field is unsigned integer. Bigger numbers mean higher priority. * `direction` Required. Can be set to either `"sink"` or `"source"`. Specifies the direction of the media flow of this endpoint. A `source` is an endpoint that produces data (i.e. an audio capture device or a playback application) and a `sink` is an endpoint that consumes data (audio playback device or capture application). * `name` Optional. The name of the endpoint. It is possible to use wildcards here to match only parts of the name. * `media_class` Optional. A string that specifies the `media.class` that the endpoint must have in order to match. * `properties` This is a TOML array of tables, where each table must contain two fields: `name` and `value`, both being strings. Each table describes a match against one of the pipewire properties of the endpoint. For a successful endpoint match, all the described properties must match with the endpoint. The `[target-endpoint]` table contains properties that match an endpoint that exists on the graph. The purpose of this table is to match a second endpoint that the original matching endpoint from `[match-endpoint]` will be linked to. If not specified, `module-config-policy` will look for the session "default" endpoint for the type of media that the matching endpoint produces or consumes and will use that as a target. Possible fields of this table are: * `direction`, `name`, `media_class`, `properties` All these fields are permitted and behave exactly as described above for the `[match-endpoint]` table. * `stream` This field specifies a stream name that the link will use on the target endpoint. If it is not specified, the stream name is acquired from the `media.role` property of the matching endpoint. If specified, the value of this field overrides the `media.role`. The `[endpoint-link]` table specifies properties of the link. Possible fields of this table are: * `keep` A boolean field. If set to true, the link is always kept active and ignores policy rules regarding corking or stream priority. This link will also not affect the rules for other links. For example, if a keep=true link is activating a high priority stream, lower priority streams can still work on the same target endpoint for links with keep=false.