Caps negotiation
Caps negotiation is the act of finding a media format (GstCaps) between
elements that they can handle. This process in &GStreamer; can in most
cases find an optimal solution for the complete pipeline. In this section
we explain how this works.
Caps negotiation basics
In &GStreamer;, negotiation of the media format always follows the
following simple rules:
A downstream element suggest a format on its sinkpad and places the
suggestion in the result of the CAPS query performed on the sinkpad.
See also .
An upstream element decides on a format. It sends the selected media
format downstream on its source pad with a CAPS event. Downstream
elements reconfigure themselves to handle the media type in the CAPS
event on the sinkpad.
A downstream element can inform upstream that it would like to
suggest a new format by sending a RECONFIGURE event upstream. The
RECONFIGURE event simply instructs an upstream element to restart
the negotiation phase. Because the element that sent out the
RECONFIGURE event is now suggesting another format, the format
in the pipeline might change.
In addition to the CAPS and RECONFIGURE event and the CAPS query, there
is an ACCEPT_CAPS query to quickly check if a certain caps can
be accepted by an element.
All negotiation follows these simple rules. Let's take a look at some
typical uses cases and how negotiation happens.
Caps negotiation use cases
In what follows we will look at some use cases for push-mode scheduling.
The pull-mode scheduling negotiation phase is discussed in
and is actually similar as we
will see.
Since the sink pads only suggest formats and the source pads need to
decide, the most complicated work is done in the source pads.
We can identify 3 caps negotiation use cases for the source pads:
Fixed negotiation. An element can output one format only.
See .
Transform negotiation. There is a (fixed) transform between the
input and output format of the element, usually based on some
element property. The caps that the element will produce depend
on the upstream caps and the caps that the element can accept
depend on the downstream caps.
See .
Dynamic negotiation. An element can output many formats.
See .
Fixed negotiation
In this case, the source pad can only produce a fixed format. Usually
this format is encoded inside the media. No downstream element can
ask for a different format, the only way that the source pad will
renegotiate is when the element decides to change the caps itself.
Elements that could implement fixed caps (on their source pads) are,
in general, all elements that are not renegotiable. Examples include:
A typefinder, since the type found is part of the actual data stream
and can thus not be re-negotiated. The typefinder will look at the
stream of bytes, figure out the type, send a CAPS event with the
caps and then push buffers of the type.
Pretty much all demuxers, since the contained elementary data
streams are defined in the file headers, and thus not
renegotiable.
Some decoders, where the format is embedded in the data stream
and not part of the peercaps and where the
decoder itself is not reconfigurable, too.
Some sources that produce a fixed format.
gst_pad_use_fixed_caps() is used on the source
pad with fixed caps. As long as the pad is not negotiated, the default
CAPS query will return the caps presented in the padtemplate. As soon
as the pad is negotiated, the CAPS query will return the negotiated
caps (and nothing else). These are the relevant code snippets for fixed
caps source pads.
The fixed caps can then be set on the pad by calling
gst_pad_set_caps ().
,
"channels", G_TYPE_INT, , NULL);
if (!gst_pad_set_caps (pad, caps)) {
GST_ELEMENT_ERROR (element, CORE, NEGOTIATION, (NULL),
("Some debug information here"));
return GST_FLOW_ERROR;
}
[..]
]]>
These types of elements also don't have a relation between the input
format and the output format, the input caps simply don't contain the
information needed to produce the output caps.
All other elements that need to be configured for the format should
implement full caps negotiation, which will be explained in the next
few sections.
Transform negotiation
In this negotiation technique, there is a fixed transform between
the element input caps and the output caps. This transformation
could be parameterized by element properties but not by the
content of the stream (see
for that use-case).
The caps that the element can accept depend on the (fixed
transformation) downstream caps. The caps that the element can
produce depend on the (fixed transformation of) the upstream
caps.
This type of element can usually set caps on its source pad from
the _event() function on the sink pad when
it received the CAPS event. This means that the caps transform
function transforms a fixed caps into another fixed caps.
Examples of elements include:
Videobox. It adds configurable border around a video frame
depending on object properties.
Identity elements. All elements that don't change the format
of the data, only the content. Video and audio effects are an
example. Other examples include elements that inspect the
stream.
Some decoders and encoders, where the output format is defined
by input format, like mulawdec and mulawenc. These decoders
usually have no headers that define the content of the stream.
They are usually more like conversion elements.
Below is an example of a negotiation steps of a typical transform
element. In the sink pad CAPS event handler, we compute the caps
for the source pad and set those.
srcpad, outcaps);
gst_caps_unref (outcaps);
return ret;
}
static gboolean
gst_my_filter_sink_event (GstPad *pad,
GstObject *parent,
GstEvent *event)
{
gboolean ret;
GstMyFilter *filter = GST_MY_FILTER (parent);
switch (GST_EVENT_TYPE (event)) {
case GST_EVENT_CAPS:
{
GstCaps *caps;
gst_event_parse_caps (event, &caps);
ret = gst_my_filter_setcaps (filter, caps);
break;
}
default:
ret = gst_pad_event_default (pad, parent, event);
break;
}
return ret;
}
[...]
]]>
Dynamic negotiation
A last negotiation method is the most complex and powerful dynamic
negotiation.
Like with the transform negotiation in
, dynamic negotiation will
perform a transformation on the downstream/upstream caps. Unlike the
transform negotiation, this transform will convert fixed caps to
unfixed caps. This means that the sink pad input caps can be converted
into unfixed (multiple) formats. The source pad will have to choose a
format from all the possibilities. It would usually like to choose a
format that requires the least amount of effort to produce but it does
not have to be. The selection of the format should also depend on the
caps that can be accepted downstream (see a QUERY_CAPS function in
).
A typical flow goes like this:
Caps are received on the sink pad of the element.
If the element prefers to operate in passthrough mode, check
if downstream accepts the caps with the ACCEPT_CAPS query. If it
does, we can complete negotiation and we can operate in
passthrough mode.
Calculate the possible caps for the source pad.
Query the downstream peer pad for the list of possible
caps.
Select from the downstream list the first caps that you can
transform to and set this as the output caps. You might have to
fixate the caps to some reasonable defaults to construct
fixed caps.
Examples of this type of elements include:
Converter elements such as videoconvert, audioconvert, audioresample,
videoscale, ...
Source elements such as audiotestsrc, videotestsrc, v4l2src,
pulsesrc, ...
Let's look at the example of an element that can convert between
samplerates, so where input and output samplerate don't have to be
the same:
sinkpad, caps)) {
filter->passthrough = TRUE;
} else {
GstCaps *othercaps, *newcaps;
GstStructure *s = gst_caps_get_structure (caps, 0), *others;
/* no passthrough, setup internal conversion */
gst_structure_get_int (s, "channels", &filter->channels);
othercaps = gst_pad_get_allowed_caps (filter->srcpad);
others = gst_caps_get_structure (othercaps, 0);
gst_structure_set (others,
"channels", G_TYPE_INT, filter->channels, NULL);
/* now, the samplerate value can optionally have multiple values, so
* we "fixate" it, which means that one fixed value is chosen */
newcaps = gst_caps_copy_nth (othercaps, 0);
gst_caps_unref (othercaps);
gst_pad_fixate_caps (filter->srcpad, newcaps);
if (!gst_pad_set_caps (filter->srcpad, newcaps))
return FALSE;
/* we are now set up, configure internally */
filter->passthrough = FALSE;
gst_structure_get_int (s, "rate", &filter->from_samplerate);
others = gst_caps_get_structure (newcaps, 0);
gst_structure_get_int (others, "rate", &filter->to_samplerate);
}
return TRUE;
}
static gboolean
gst_my_filter_sink_event (GstPad *pad,
GstObject *parent,
GstEvent *event)
{
gboolean ret;
GstMyFilter *filter = GST_MY_FILTER (parent);
switch (GST_EVENT_TYPE (event)) {
case GST_EVENT_CAPS:
{
GstCaps *caps;
gst_event_parse_caps (event, &caps);
ret = gst_my_filter_setcaps (filter, caps);
break;
}
default:
ret = gst_pad_event_default (pad, parent, event);
break;
}
return ret;
}
static GstFlowReturn
gst_my_filter_chain (GstPad *pad,
GstObject *parent,
GstBuffer *buf)
{
GstMyFilter *filter = GST_MY_FILTER (parent);
GstBuffer *out;
/* push on if in passthrough mode */
if (filter->passthrough)
return gst_pad_push (filter->srcpad, buf);
/* convert, push */
out = gst_my_filter_convert (filter, buf);
gst_buffer_unref (buf);
return gst_pad_push (filter->srcpad, out);
}
]]>
Upstream caps (re)negotiation
Upstream negotiation's primary use is to renegotiate (part of) an
already-negotiated pipeline to a new format. Some practical examples
include to select a different video size because the size of the video
window changed, and the video output itself is not capable of rescaling,
or because the audio channel configuration changed.
Upstream caps renegotiation is requested by sending a GST_EVENT_RECONFIGURE
event upstream. The idea is that it will instruct the upstream element
to reconfigure its caps by doing a new query for the allowed caps and then
choosing a new caps. The element that sends out the RECONFIGURE event
would influence the selection of the new caps by returning the new
prefered caps from its GST_QUERY_CAPS query function. The RECONFIGURE
event will set the GST_PAD_FLAG_NEED_RECONFIGURE on all pads that it
travels over.
It is important to note here that different elements actually have
different responsibilities here:
Elements that want to propose a new format upstream need to first
check if the new caps are acceptable upstream with an ACCEPT_CAPS
query. Then they would send a RECONFIGURE event and be prepared to
answer the CAPS query with the new prefered format. It should be
noted that when there is no upstream element that can (or wants)
to renegotiate, the element needs to deal with the currently
configured format.
Elements that operate in transform negotiation according to
pass the RECONFIGURE
event upstream. Because these elements simply do a fixed transform
based on the upstream caps, they need to send the event upstream
so that it can select a new format.
Elements that operate in fixed negotiation
() drop the RECONFIGURE event.
These elements can't reconfigure and their output caps don't depend
on the upstream caps so the event can be dropped.
Elements that can be reconfigured on the source pad (source pads
implementing dynamic negotiation in
) should check its
NEED_RECONFIGURE flag with
gst_pad_check_reconfigure () and it should
start renegotiation when the function returns TRUE.
Implementing a CAPS query function
A _query ()-function with the GST_QUERY_CAPS query
type is called when a peer element would like to know which formats
this pad supports, and in what order of preference. The return value
should be all formats that this elements supports, taking into account
limitations of peer elements further downstream or upstream, sorted by
order of preference, highest preference first.
srcpad) ? filter->sinkpad :
filter->srcpad;
caps = gst_pad_get_allowed_caps (otherpad);
gst_query_parse_caps (query, &filt);
/* We support *any* samplerate, indifferent from the samplerate
* supported by the linked elements on both sides. */
for (i = 0; i < gst_caps_get_size (caps); i++) {
GstStructure *structure = gst_caps_get_structure (caps, i);
gst_structure_remove_field (structure, "rate");
}
/* make sure we only return results that intersect our
* padtemplate */
tcaps = gst_pad_get_pad_template_caps (pad);
if (tcaps) {
temp = gst_caps_intersect (caps, tcaps);
gst_caps_unref (caps);
gst_caps_unref (tcaps);
caps = temp;
}
/* filter against the query filter when needed */
if (filt) {
temp = gst_caps_intersect (caps, filt);
gst_caps_unref (caps);
caps = temp;
}
gst_query_set_caps_result (query, caps);
gst_caps_unref (caps);
ret = TRUE;
break;
}
default:
ret = gst_pad_query_default (pad, parent, query);
break;
}
return ret;
}
]]>
Pull-mode Caps negotiation
WRITEME, the mechanism of pull-mode negotiation is not yet fully
understood.
Using all the knowledge you've acquired by reading this chapter, you
should be able to write an element that does correct caps negotiation.
If in doubt, look at other elements of the same type in our git
repository to get an idea of how they do what you want to do.