Specifying the pads
As explained before, pads are the port through which data goes in and out
of your element, and that makes them a very important item in the process
of element creation. In the boilerplate code, we have seen how static pad
templates take care of registering pad templates with the element class.
Here, we will see how to create actual elements, use _link ()
and _getcaps () functions to let other elements know
their capabilities and how to register functions to let data flow through
the element.
In the element _init () function, you create the pad
from the pad template that has been registered with the element class in
the _base_init () function. After creating the pad,
you have to set a _link () function pointer and a
_getcaps () function pointer. Optionally, you can
set a _chain () function pointer (on sink pads in
filter and sink elements) through which data will come in to the element,
or (on source pads in source elements) a _get ()
function pointer through which data will be pulled from the element. After
that, you have to register the pad with the element. This happens like
this:
static GstPadLinkReturn gst_my_filter_link (GstPad *pad,
const GstCaps *caps);
static GstCaps * gst_my_filter_getcaps (GstPad *pad);
static void gst_my_filter_chain (GstPad *pad,
GstData *data);
static void
gst_my_filter_init (GstMyFilter *filter)
{
GstElementClass *klass = GST_ELEMENT_GET_CLASS (filter);
/* pad through which data comes in to the element */
filter->sinkpad = gst_pad_new_from_template (
gst_element_class_get_pad_template (klass, "sink"), "sink");
gst_pad_set_link_function (filter->sinkpad, gst_my_filter_link);
gst_pad_set_getcaps_function (filter->sinkpad, gst_my_filter_getcaps);
gst_pad_set_chain_function (filter->sinkpad, gst_my_filter_chain);
gst_element_add_pad (GST_ELEMENT (filter), filter->sinkpad);
/* pad through which data goes out of the element */
filter->srcpad = gst_pad_new_from_template (
gst_element_class_get_pad_template (klass, "src"), "src");
gst_pad_set_link_function (filter->srcpad, gst_my_filter_link);
gst_pad_set_getcaps_function (filter->srcpad, gst_my_filter_getcaps);
gst_element_add_pad (GST_ELEMENT (filter), filter->srcpad);
[..]
}
The link function
The _link () is called during caps negotiation. This
is the process where the linked pads decide on the streamtype that will
transfer between them. A full list of type-definitions can be found in
. A _link ()
receives a pointer to a GstCaps
struct that defines the proposed streamtype, and can respond with
either yes
(GST_PAD_LINK_OK),
no
(GST_PAD_LINK_REFUSED) or
don't know yet
(GST_PAD_LINK_DELAYED).
If the element responds positively towards the streamtype, that type
will be used on the pad. An example:
static GstPadLinkReturn
gst_my_filter_link (GstPad *pad,
const GstCaps *caps)
{
GstStructure *structure = gst_caps_get_structure (caps, 0);
GstMyFilter *filter = GST_MY_FILTER (gst_pad_get_parent (pad));
GstPad *otherpad = (pad == filter->srcpad) ? filter->sinkpad :
filter->srcpad;
GstPadLinkReturn ret;
const gchar *mime;
/* Since we're an audio filter, we want to handle raw audio
* and from that audio type, we need to get the samplerate and
* number of channels. */
mime = gst_structure_get_name (structure);
if (strcmp (mime, "audio/x-raw-int") != 0) {
GST_WARNING ("Wrong mimetype %s provided, we only support %s",
mime, "audio/x-raw-int");
return GST_PAD_LINK_REFUSED;
}
/* we're a filter and don't touch the properties of the data.
* That means we can set the given caps unmodified on the next
* element, and use that negotiation return value as ours. */
ret = gst_pad_try_set_caps (otherpad, gst_caps_copy (caps));
if (GST_PAD_LINK_FAILED (ret))
return ret;
/* Capsnego succeeded, get the stream properties for internal
* usage and return success. */
gst_structure_get_int (structure, "rate", &filter->samplerate);
gst_structure_get_int (structure, "channels", &filter->channels);
g_print ("Caps negotiation succeeded with %d Hz @ %d channels\n",
filter->samplerate, filter->channels);
return ret;
}
In here, we check the mimetype of the provided caps. Normally, you don't
need to do that in your own plugin/element, because the core does that
for you. We simply use it to show how to retrieve the mimetype from a
provided set of caps. Types are stored in GstStructure
internally. A GstCaps
is nothing more than a small
wrapper for 0 or more structures/types. From the structure, you can also
retrieve properties, as is shown above with the function
gst_structure_get_int ().
If your _link () function does not need to perform
any specific operation (i.e. it will only forward caps), you can set it
to gst_pad_proxy_link. This is a link forwarding
function implementation provided by the core. It is useful for elements
such as identity.
The getcaps function
The _getcaps () function is used to request the list
of supported formats and properties from the element. In some cases, this
will be equal to the formats provided by the pad template, in which case
this function can be omitted. In some cases, too, it will not depend on
anything inside this element, but it will rather depend on the input from
another element linked to this element's sink or source pads. In that case,
you can use gst_pad_proxy_getcaps as implementation,
it provides getcaps forwarding in the core. However, in many cases, the
format supported by this element cannot be defined externally, but is
more specific than those provided by the pad template. In this case, you
should use a _getcaps () function. In the case as
specified below, we assume that our filter is able to resample sound, so
it would be able to provide any samplerate (indifferent from the samplerate
specified on the other pad) on both pads. It explains how a
_getcaps () can be used to do this.
static GstCaps *
gst_my_filter_getcaps (GstPad *pad)
{
GstMyFilter *filter = GST_MY_FILTER (gst_pad_get_parent (pad));
GstPad *otherpad = (pad == filter->srcpad) ? filter->sinkpad :
filter->srcpad;
GstCaps *othercaps = gst_pad_get_allowed_caps (otherpad), *caps;
gint n;
if (gst_caps_is_empty (othercaps))
return othercaps;
/* We support *any* samplerate, indifferent from the samplerate
* supported by the linked elements on both sides. */
for (i = 0; i < gst_caps_get_size (othercaps); i++) {
GstStructure *structure = gst_caps_get_structure (othercaps, i);
gst_structure_remove_field (structure, "rate");
}
caps = gst_caps_intersect (othercaps, gst_pad_get_pad_template_caps (pad));
gst_caps_free (othercaps);
return caps;
}
Explicit caps
Obviously, many elements will not need the complex mechanism described in
the previous sections, because they are much simpler than that.
Such elements only support one format, or their format
is fixed but the contents of the format depend on the stream or something
else. In those cases, explicit caps are an easy way
of handling caps. Explicit caps are an easy way of specifying one, fixed,
supported format on a pad. Pads using explicit caps do not implement their
own _getcaps () or _link ()
functions. When the exact format is known, an elements uses
gst_pad_set_explicit_caps () to specify the exact
format. This is very useful for demuxers, for example.
static void
gst_my_filter_init (GstMyFilter *filter)
{
GstElementClass *klass = GST_ELEMENT_GET_CLASS (filter);
[..]
filter->srcpad = gst_pad_new_from_template (
gst_element_class_get_pad_template (klass, "src"), "src");
gst_pad_use_explicit_caps (filter->srcpad);
[..]
}
static void
gst_my_filter_somefunction (GstMyFilter *filter)
{
GstCaps *caps = ..;
[..]
gst_pad_set_explicit_caps (filter->srcpad, caps);
[..]
}