PipeWire 1.0.5
Loading...
Searching...
No Matches
Tutorial - Part 2: Enumerating Objects

Tutorial - Part 1: Getting Started | Index | Tutorial - Part 3: Forcing A Roundtrip

In this tutorial we show how to connect to a PipeWire daemon and enumerate the objects that it has.

Let take a look at the following application to start.

static void registry_event_global(void *data, uint32_t id,
uint32_t permissions, const char *type, uint32_t version,
const struct spa_dict *props)
{
printf("object: id:%u type:%s/%d\n", id, type, version);
}
static const struct pw_registry_events registry_events = {
.global = registry_event_global,
};
int main(int argc, char *argv[])
{
struct pw_main_loop *loop;
struct pw_context *context;
struct pw_core *core;
struct pw_registry *registry;
struct spa_hook registry_listener;
pw_init(&argc, &argv);
loop = pw_main_loop_new(NULL /* properties */);
NULL /* properties */,
0 /* user_data size */);
core = pw_context_connect(context,
NULL /* properties */,
0 /* user_data size */);
0 /* user_data size */);
spa_zero(registry_listener);
pw_registry_add_listener(registry, &registry_listener,
&registry_events, NULL);
pw_proxy_destroy((struct pw_proxy*)registry);
return 0;
}

To compile the simple test application, copy it into a tutorial2.c file and use:

gcc -Wall tutorial2.c -o tutorial2 $(pkg-config --cflags --libs libpipewire-0.3)

Let's break this down:

First we need to initialize the PipeWire library with pw_init() as we saw in the previous tutorial. This will load and configure the right modules and setup logging and other tasks.

...
pw_init(&argc, &argv);
...

Next we need to create one of the struct pw_loop wrappers. PipeWire ships with 2 types of mainloop implementations. We will use the struct pw_main_loop implementation, we will see later how we can use the struct pw_thread_loop implementation as well.

The mainloop is an abstraction of a big poll loop, waiting for events to occur and things to do. Most of the PipeWire work will actually be performed in the context of this loop and so we need to make one first.

We then need to make a new context object with the loop. This context object will manage the resources for us and will make it possible for us to connect to a PipeWire daemon:

struct pw_main_loop *loop;
struct pw_context *context;
loop = pw_main_loop_new(NULL /* properties */);
NULL /* properties */,
0 /* user_data size */);
struct pw_context * pw_context_new(struct pw_loop *main_loop, struct pw_properties *props, size_t user_data_size)
Make a new context object for a given main_loop.
Definition context.c:179
struct pw_main_loop * pw_main_loop_new(const struct spa_dict *props)
Create a new main loop.
Definition main-loop.c:61
struct pw_loop * pw_main_loop_get_loop(struct pw_main_loop *loop)
Get the loop implementation.
Definition main-loop.c:94
A main loop object.

It is possible to give extra properties when making the mainloop or context to tweak its features and functionality. It is also possible to add extra data to the allocated objects for your user data. It will stay alive for as long as the object is alive. We will use this feature later.

A real implementation would also need to check if the allocation succeeded and do some error handling, but we leave that out to make the code easier to read.

With the context we can now connect to the PipeWire daemon:

struct pw_core *core;
core = pw_context_connect(context,
NULL /* properties */,
0 /* user_data size */);
struct pw_core * pw_context_connect(struct pw_context *context, struct pw_properties *properties, size_t user_data_size)
Connect to a PipeWire instance.
Definition core.c:394

This creates a socket between the client and the server and makes a proxy object (with ID 0) for the core. Don't forget to check the result here, a NULL value means that the connection failed.

At this point we can send messages to the server and receive events. For now we're not going to handle events on this core proxy but we're going to handle them on the registry object.

struct pw_registry *registry;
struct spa_hook registry_listener;
0 /* user_data size */);
spa_zero(registry_listener);
pw_registry_add_listener(registry, &registry_listener,
&registry_events, NULL);
#define PW_VERSION_REGISTRY
Definition core.h:52
static struct pw_registry * pw_core_get_registry(struct pw_core *core, uint32_t version, size_t user_data_size)
Definition core.h:406
#define pw_registry_add_listener(p,...)
Registry.
Definition core.h:568
#define spa_zero(x)
Definition defs.h:421
A hook, contains the structure with functions and the data passed to the functions.
Definition hook.h:350

From the core we get the registry proxy object and when we use pw_registry_add_listener() to listen for events. We need a small struct spa_hook to keep track of the listener and a reference to the struct pw_registry_events that contains the events we want to listen to.

This is how we define the event handler and the function to handle the events:

static const struct pw_registry_events registry_events = {
.global = registry_event_global,
};
static void registry_event_global(void *data, uint32_t id,
uint32_t permissions, const char *type, uint32_t version,
const struct spa_dict *props)
{
printf("object: id:%u type:%s/%d\n", id, type, version);
}
#define PW_VERSION_REGISTRY_EVENTS
Definition core.h:484
Registry events.
Definition core.h:482
void(* global)(void *data, uint32_t id, uint32_t permissions, const char *type, uint32_t version, const struct spa_dict *props)
Notify of a new global object.
Definition core.h:498
uint32_t version
Definition core.h:485
Definition dict.h:39

Now that everything is set up we can start the mainloop and let the communication between client and server continue:

int pw_main_loop_run(struct pw_main_loop *loop)
Run a main loop.
Definition main-loop.c:120

Since we don't call pw_main_loop_quit() anywhere, this loop will continue forever. In the next tutorial we'll see how we can nicely exit our application after we received all server objects.

Tutorial - Part 1: Getting Started | Index | Tutorial - Part 3: Forcing A Roundtrip