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authorGeorge Kiagiadakis <george.kiagiadakis@collabora.com>2021-09-20 19:59:08 +0300
committerJan-Simon Moeller <jsmoeller@linuxfoundation.org>2021-10-12 15:35:44 +0000
commit152dfcf51a160a0969c8bc8c2bf415d18468fe53 (patch)
tree0a8b13247fb27c22580fe20edbb58e8639e1a6ad
parent63c014544afd43443066f88e213da1bdd02405df (diff)
docs: add a design document for the "IC sound manager" setup
Bug-AGL: SPEC-4027 Signed-off-by: George Kiagiadakis <george.kiagiadakis@collabora.com> Change-Id: I3059c81f13c359e7af10089f102e811c94814e99 Reviewed-on: https://gerrit.automotivelinux.org/gerrit/c/AGL/documentation/+/26663 Reviewed-by: Jan-Simon Moeller <jsmoeller@linuxfoundation.org> Tested-by: Jan-Simon Moeller <jsmoeller@linuxfoundation.org>
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+# Instrument Cluster Sound Management
+
+## Introduction
+
+This document describes the design of the software setup which enables the integration
+of AGL’s sound system with applications running in the Instrument Cluster domain.
+This software setup is specific to the case where a single system is used to implement
+both the Instrument Cluster and some other domain of the vehicle, typically the
+In-Vehicle-Infotainment domain, using container technology to separate them.
+
+Applications running in the Instrument Cluster need a way to safely play important
+sounds to alert the driver of conditions that need the driver’s attention. At the same
+time, in a containerized environment that serves multiple vehicle domains, applications
+running in other containers may be using the sound hardware to play less important sounds,
+such as music, which conflicts with the IC’s need to play sound on the same hardware.
+
+The solution developed here, for safety reasons, relies on the operating system and the
+hardware itself to allow the IC applications to stream sounds to the speakers using a
+dedicated device handle, while applications from other domains are all routed through a
+sound server that runs on the host container and operates on a different sound device handle.
+
+However, to achieve good inter-operation, there is need for additional software mechanisms
+that will work in combination with this hardware-based solution. First of all, it is necessary
+to have a mechanism that allows IC applications to pause all sounds that are being routed via
+the sound server while there is an important IC sound playing and resume them afterwards.
+This is so that other domain applications can be informed of this temporary pause and offer
+the appropriate user experience. Secondly, it is desirable to have separation of duties
+between the host and the other domain’s (non-IC) container. It should be the responsibility
+of the other domain’s container to implement the sound system policy, so that the host does
+not need to be aware of the exact applications that are running on this container.
+
+## Requirements
+
+- Single system shared between IC and at least one secondary domain (IVI, other ...)
+
+- The domains are separated using containers
+
+- All the containers, including the host, are running a variant of AGL
+
+- The host OS and the secondary domain container use PipeWire and WirePlumber
+ to implement the sound system
+
+- The sound hardware offers, on the Linux kernel driver side, a separate ALSA
+ device for sounds that belong to the IC and a separate ALSA device for other sounds
+
+## Architectural design
+
+![Architecture overview](images/ic-sound-manager/architecture.png)
+
+The core of the sound system consists of the PipeWire daemon, which is responsible for routing
+audio between the kernel and applications running in the “Other Container”.
+
+The PipeWire session is orchestrated by a secondary daemon, WirePlumber. WirePlumber is
+designed in such a way so that it can have multiple instances, for task separation.
+One instance shall be running in the host container and it shall be responsible for
+managing the devices that PipeWire handles as well as the security isolation between
+different applications and different containers. At least one more instance shall be
+running in the “Other Container” and be responsible for implementing policy mechanisms
+related to the applications that are running in that container.
+
+Further WirePlumber instances are possible to run as well. For instance, it may be desirable
+to have another “policy” instance in a third container that implements another vehicle system
+and shares the main PipeWire daemon from the host. Additionally, the “Other Container” may
+be running a separate WirePlumber instance to manage bluetooth audio devices, which shall be
+the responsibility of that container instead of the host.
+
+To implement communication between the IC and the host, a third daemon is used: pipewire-ic-ipc.
+This daemon listens on a UNIX domain socket for messages from the IC applications and offers
+them the ability to pause or resume sounds that are being routed via PipeWire.
+
+Finally, IC applications are given a library (icipc library) that allows them to send messages
+to pipewire-ic-ipc on the host. This library is minimal and has no external dependencies,
+for safety reasons.
+
+For sound playback, IC applications are expected to use the ALSA API directly and communicate
+with the dedicated ALSA device that is meant for IC sounds. Arbitration of this device between
+different IC applications is out of scope for this document and it is assumed to be a solved
+problem.
+
+### PipeWire-IC-IPC
+
+This component acts as the server-side component for the UNIX socket that is used for
+communication between the IC applications and the host. It is implemented as a pipewire module,
+therefore it needs the `/usr/bin/pipewire` process in order to be launched. Launching happens
+with a special configuration file (`pipewire-ic-ipc.conf`) which instructs this PipeWire process
+to be launched as a client (`core.daemon = false`) and to load only `module-ic-ipc` together
+with `module-protocol-native`. The latter enables communication with the daemon instance of
+PipeWire (`core.daemon = true`), which implements the sound server.
+
+![PipeWire-IC-IPC Processes](images/ic-sound-manager/pipewire-ic-ipc-processes.png)
+
+### icipc library
+
+The IC Application is given a library (‘libicipc’) that implements the client side of
+pipewire-ic-ipc. This library allows sending two commands:
+
+- SUSPEND
+ - Asks WirePlumber (via PipeWire) to cork applications and mute the ALSA device used by PipeWire
+- RESUME
+ - Reverts the effects of SUSPEND
+
+IC Applications are expected to send the SUSPEND command before starting playback of a sound
+to their dedicated ALSA device. The RESUME command should be sent after playback of this IC
+sound has finished.
+
+It should be noted that the RESUME command is also issued automatically when the IC application
+disconnects from the pipewire-ic-ipc UNIX socket.
+
+If multiple IC application issue SUSPEND to the pipewire-ic-ipc server, then only the first
+SUSPEND generates actions for WirePlumber. The rest are counted and the pipewire-ic-ipc
+server expects an equal number of RESUME commands before generating resume actions for
+WirePlumber.
+
+The implementation of the SUSPEND/RESUME mechanism uses PipeWire’s metadata to signal
+WirePlumber. PipeWire-IC-IPC will look for the “default” metadata object in PipeWire’s list
+of objects and will write the “suspend.playback” key with a value of “true” on id 0.
+The metadata change is then notified to all clients. WirePlumber, being a client, gets
+notified of this change and takes actions. All actions are defined in Lua scripts.
+
+![PipeWire-IC-IPC Calls](images/ic-sound-manager/pipewire-ic-ipc-calls.png)
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