I don't go into detail of every methods and events (what parameters are available, what are their types, etc) as this has been sufficiently explained bluez documentation, available in their source tarball or online here.
Here, I will only summarise the missing critical information that is necessary for you to build your own application that acts as an A2DP Sink or Source.
This diagram summarises the events and sequences when a remote bluetooth device starts an A2DP protocol connection to start audio streaming.
First, the caveat: the "bluetooth device" <--> "bluez" part of that diagram must be taken with a grain of salt, as it is not accurate. If you want to know the details you need to consult A2DP and GAVPD specifications. I show it there so that you can see the big picture of what is happening.
There are 3 levels of events that happen during the lifetime of the your app. I have marked these as A, B, and C. Level A are the highest level events, these are startup/shutdown events and activities. Level B are events and actions that you must do when a remote bluetooth device is connected or disconnected. Level C are the actions you must do to carry out the actual audio streaming.
A1. Application Startup. Upon starting up, you need to tell bluez that your app will handle A2DP Sink or Sources for it. You do it by calling org.bluez.Media.RegisterEvent with the appropriate parameters, mainly UUID, Codec, and Capabilities.
Bluez documentation doesn't make it clear, but you cannot just plug arbitrary made-up values here. "UUID" must be one of the pre-defined "Service Class identifiers" (from here), you want either AudioSource or AudioSink UUID. "Codec" must be one of the available supported codecs from A2DP specification, and the "Capabilities" must be filled with the particular codec's parameters that you want to support.
If the registration is successful, you'll get an empty reply otherwise you'll get an error.
A2. Application Termination. Assuming you have successfully registered, bluez will notify you that your registration has been cancelled. This usually only happens the the bluetooth daemon itself is about to shutdown. Bluez does it by calling org.bluez.MediaEndpoint.Release method, which you must implement and handle (don't you wish now that bluez documentation differentiates between real "API" calls and "callback" interfaces, like this one? ). At this stage you don't need to de-register or do any other cleanup with bluez, you just need to clean-up your own resources. Reply with a blank message, and after that you are free to terminate your app.
B1. Device Connection Events happen when a remote bluetooth device is connected. Assuming that your registration is successful, bluez will call your app again when an A2DP device is trying to connect to the computer. It does it using org.bluez.MediaEndpoint.SelectConfiguration. You will need to implement this method and interface and handle the call. Through this call, bluez will pass you some "Capabilities" codec parameters from the other end. You are supposed to compare this with your own capabilities and choose the best match that provide the highest quality audio. Your reply to bluez will contain the this chosen configuration.
If everything is all right, bluez will then call your app again, using org.bluez.MediaEndpoint.SetConfiguration. The parameter to this call should contain exactly the same codec parameters you gave back earlier in your reply to "SelectConfiguration". Among other things, the most important thing you must do here is this: you must record the "transport path" given as parameter of this call. It is a unique object path that you need to pass along to org.bluez.MediaTransport.Acquire to get the file descriptor you need to use for the actual streaming. If you don't keep that path, you can't find it again. All being good, you reply with empty message.
B2. Device Disconnection Events happen the remote bluetooth device is disconnected. Bluez will call you on org.bluez.MediaEndpoint.ClearConfiguration method. You are supposed to clear any of your resources you keep for that particular bluetooth device connection (ie, that particular "transport path"). Reply with a blank message.
C1. Start streaming event. To detect this event, you must listen to org.bluez.AudioSource.PropertyChanged signal and keep track of its "State" property. The "start streaming" event happens when the state changes from "connected" to "playing". (There are a few other events too, which may be interesting for other purposes but not for us).
When this happens, you need to call org.bluez.MediaTransport.Acquire. Bluez will give you a file descriptor that you can read from, as well as its read MTU (maximum transfer unit) - which is how big each packet would be. From here onwards, you can read this descriptor to obtain the A2DP packet, decode it, and output it. The Read MTU helps to determine how big a buffer you need to allocate. Note that the read isn't always successful, you must allow for error conditions such as EAGAIN because your CPU will be much faster at reading than what bluetooth (and the remote device) can send.
C2. Stop streaming event. Like "start streaming event", you can't decide this from org.bluez.AudioSource.PropertyChanged signal alone. You need to detect the transition, which is "playing" to "connected". When this happens, you need to call org.bluez.MediaTransport.Release to release the transport back to bluez. In my tests, this is not strictly necessary but it is polite to do so. It is also good for you to detect this event so that you can can tell our "streaming" function to stop its work and rest for a while.
That's it! Easy peasy eh?
The explanation above describes the sequence of events and methods to call when the computer is acting as A2DP sink (or "Source", in bluez' parlance).
What about A2DP Source (the computer to send audio data to bluetooth speakers)? As it turns out, the sequence of events (and methods to call) is exactly the same with very minor change:
I've created a working example that implements all of the above. I use a thread for doing the actual streaming (reading/writing to the file descriptors).
The code implements both Sink and Source. As you can see, the difference in handling is minimal.
Note: The code is only an example. A lot of the error handling have been left out on purpose: it focuses neither on performance nor robustness, but more on the working (and hopefully correct) way of handling A2DP under bluez. That being said, I find that the Sink is good enough, while the Source is a bit unsatisfactory. There is a README inside the tarball that shows how you can setup ALSA asoundrc for use with the A2DP Source so that it can act as a poor man's ALSA PCM plugin.
As usual, the code is released under GNU GPL Version 3 or later unless the bits that I took from PulseAudion and bluez itself (SBC stuff, SBC setup stuff, and actual A2DP packet encoding/decoding) - they are licensed as per their original licenses.
You can get the code from here.
Question: Bluez 4.x is already obsolete by now. What do I have to do to get this example to work with bluez 5?
Answer: A lot of work. I have not investigated bluez 5 version of this fully as I'm quite satisfied with bluez 4 for now. But from what I have gathered, the sequence of events is identical. Sure the DBus interfaces change their names (bluez 5 add "1" to the interface names, e.g. "org.bluez.MediaEndpoint" becomes "org.bluez.MediaEndpoint1"); and the signals change their skins too (AudioSource/AudioSink are gone, replaced by generic org.freedesktop.Properties.PropertyChanged, and you can probably decide whether to start/stop streaming directly from the state instead of having to watch the transitions), but the underlying events are still the same.
Originally posted here: