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290 lines
10 KiB
Text
290 lines
10 KiB
Text
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1) The Autoplugger API
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----------------------
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We'll first describe how to use the autoplugger. We will provide
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a use case: autoplug an mpeg1 system stream for audio/video playback.
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a) creating an autoplugger
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--------------------------
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Before any autoplugging can be done, you'll have to create an
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autoplugger object. Autoplugger objects (autopluggers) are
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provided by plugins and are created with gst_autoplugfactor_make().
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GStreamer has provisions for two types of autopluggers:
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- regular autopluggers, which act as a complex element construction
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mechanism. They usually don't create threads and operate solely on
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GstCaps* for the source and destination. The complex elements
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created by regular autopluggers have src and sink pad compatible
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with the requested GstCaps*.
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- renderer autopluggers, which are designed to create a complex
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object that can be used to playback media. Renderer autoplugged
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complex elements have no src pads, only one sink pad.
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We'll create a renderer autoplugger like this:
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!
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! GstAutoplug *autoplug;
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!
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! autoplug = gst_autoplugfactory_make ("staticrender");
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!
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b) finding out the source media type.
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-------------------------------------
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Before we can start the autoplugger, we have to find out the
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source media type. This can be done using the typefind functions
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provided by various plugins.
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We will create a little pipeline to detect the media type by connecting
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a disksrc element to a typefind element. The typefind element will
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repeadedly call all registered typefind functions with the buffer it
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receives on its sink pad. when a typefind function returns a non NULL
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GstCaps*, that caps is set to the sink pad of the typefind element and
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a signal is emitted to notify the app.
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Due to caps negotiation, the disksrc will have the detected GstCaps*
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set on its src pad.
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We typically use a function like below to detect the type of a media stream
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on an element (typically a disksrc). The function accepts a pipeline and the
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element inside the pipeline on which the typefind should be performed (passing
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a GstPad* is probably a better option FIXME).
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!
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! static GstCaps*
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! gst_play_typefind (GstBin *bin, GstElement *element)
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! {
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! GstElement *typefind;
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! GstCaps *caps = NULL;
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!
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! typefind = gst_elementfactory_make ("typefind", "typefind");
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! g_return_val_if_fail (typefind != NULL, FALSE);
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!
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! gst_pad_connect (gst_element_get_pad (element, "src"),
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! gst_element_get_pad (typefind, "sink"));
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!
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! gst_bin_add (bin, typefind);
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!
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! gst_element_set_state (GST_ELEMENT (bin), GST_STATE_PLAYING);
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!
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! // push a buffer... the have_type signal handler will set the found flag
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! gst_bin_iterate (bin);
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!
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! gst_element_set_state (GST_ELEMENT (bin), GST_STATE_NULL);
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!
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! caps = gst_pad_get_caps (gst_element_get_pad (element, "src"));
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!
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! gst_pad_disconnect (gst_element_get_pad (element, "src"),
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! gst_element_get_pad (typefind, "sink"));
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! gst_bin_remove (bin, typefind);
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! gst_object_unref (GST_OBJECT (typefind));
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!
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! return caps;
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! }
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!
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Also note that the disksrc was added to the pipeline before calling this
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typefind function.
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When the function returns a non-NULL pointer, the media type has been
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determined and autoplugging can commence.
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Assume that in our mpeg1 use case the above function returns a GstCaps*
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like:
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!
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! srccaps = GST_CAPS_NEW ("mpeg1system_typefind",
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! "video/mpeg",
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! "mpegversion", GST_PROPS_INT (1),
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! "systemstream", GST_PROPS_BOOLEAN (TRUE)
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! );
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!
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c) Performing the autoplugging
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------------------------------
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Since we use the renderer API, we have to create the output elements
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that are going to be used as the final sink elements.
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!
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! osssink = gst_elementfactory_make("osssink", "play_audio");
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! videosink = gst_elementfactory_make("xvideosink", "play_video");
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!
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We then create a complex element using the following code.
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!
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! new_element = gst_autoplug_to_renderers (autoplug,
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! srccaps,
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! videosink,
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! osssink,
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! NULL);
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!
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! if (!new_element) {
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! g_print ("could not autoplug, no suitable codecs found...\n");
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! exit (-1);
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! }
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!
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2) Autoplugging internals
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-------------------------
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We will now describe the internals of the above gst_autoplug_to_renderers()
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function call. This code is implemented in a plugin found in:
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gst/autoplug/gststaticautoplugrender.c
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a) phase1: create lists of factories.
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---------------------------------------
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The autoplugger will start with executing the following piece of
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code:
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!
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! i = 0;
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!
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! for each sink:
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! {
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! sinkpad = take the first sinkpad of the sink (HACK)
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!
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! list[i] = gst_autoplug_caps (srccaps, sinkpad->caps);
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!
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! i++;
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! }
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!
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gst_autoplug_caps will figure out (based on the padtemplates)
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which elementfactories are needed to connect srccaps to sinkpad->caps
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and will return them in a list.
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The element list is created by using a modified shortest path algorithm
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by Dijkstra (http://www.orie.cornell.edu/~or115/handouts/handout3/handout3.html).
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The nodes of the graph are the elementfactories and the weight of the
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arcs is based on the pad compatibility of the padtemplates of the
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elementfactory. For incompatible elementfactories, we use a weight of
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MAX_COST (999999) and for compatible padtemplates we use 1.
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ex. we have two sinks with following caps:
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!
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! video/raw audio/raw
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! "...." "...."
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!
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gst_autoplug_caps will figure out that for the first sink the following
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elements are needed:
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!
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! mpeg1parse, mp1videoparse, mpeg_play
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!
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for the second sink the following is needed:
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!
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! mpeg1parse, mad
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!
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Note that for the audio connection the element list "mpeg1parse, mp3parse,
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mpg123" would also connect the srccaps to the audiosink caps. Since the
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"mpeg1parse, mad" list is shorter, it it always prefered by the autoplugger.
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We now have two lists of elementfactories.
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b) phase2: collect common elements from the lists and add them to a bin.
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------------------------------------------------------------------------
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The rationale is that from the lists we have created in phase1, there
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must be some element that is a splitter and that it has to come first (HACK)
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We try to find that element by comparing the lists until an element differs.
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We start by creating a toplevel bin that is going to be our complex element.
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In our use-case we find that mpeg1parse is an element common to both lists,
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so we add it to the bin. We then try to find a good ghostpad for the resulting
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complex element. This is done by looping over the sink pads of the first common
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element and taking the pad that is compatible with the srcaps.
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We end up with a bin like this:
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!
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! (----------------------)
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! ! autoplug_bin !
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! ! !
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! ! (------------) !
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! ! ! mpeg1parse ! !
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! ! - sink ! !
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! ! / (------------) !
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! sink !
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! (----------------------)
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!
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c) phase3: add remaining elements
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---------------------------------
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now we loop over all the list and try to add the remaining elements
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(HACK) we always use a new thread for the elements when there is a common
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element found.
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if a new thread is needed (either becuase the previous element is a common
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element or the object flag of the next element is set to GST_SUGGEST_THREAD)
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we add a queue to the bin and we add a new thread. We add the elements to
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the bin and connect them using gst_pipeline_pads_autoplug.
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we finally arrive at the sink element and we're done.
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ex.
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we have just found our mpeg1parse common element, so we start a thread.
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We add a queue to the bin and a new thread, we add the elements
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mp1videoparse and mpeg_play to the thread. We arrive at the videosink, we
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see that the SUGGEST_THREAD flag is set, we add a queue and a thread and
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add the videosink in the thread.
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the same procedure happens for the audio part. We are now left with the
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following pipeline:
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We will also have set a signal "new_pad" on the mpeg1parse element because
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the element mp1videoparse could not be connected to the element just yet.
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(---------------------------------------------------------------------------------------------)
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!autoplug_bin !
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! !
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! (----------------------------------------) (------------) !
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! !thread ! ! thread ! !
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! (-----) ! (-------------) (---------) (-----) ! ! (---------)! !
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! !queue! ! !mp1videoparse! !mpeg_play! !queue! ! ! !videosink!! !
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! sink src-sink src-sink src-sink src-sink !! !
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! (-----------) (-----) ! (-------------) (---------) (-----) ! ! (---------)! !
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! ! mpeg1parse! (----------------------------------------) (------------) !
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! - sink ! !
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! / (-----------) !
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sink (----------------------------------------) (------------) !
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! !thread ! ! thread ! !
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! (-----) ! (-------------) (-----) ! ! (---------)! !
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! !queue! ! !mad ! !queue! ! ! !videosink!! !
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! sink src-sink src ------------ sink src-sink !! !
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! (-----) ! (-------------) (-----) ! ! (---------)! !
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! (----------------------------------------) (------------) !
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(---------------------------------------------------------------------------------------------)
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The autoplugger will return the autoplug_bin. the app will then connect the
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disksrc to the sinkpad of the autoplugged bin.
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Then we play, create_plan happens, data is flowing and the "new_pad" signal is called
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from mpeg1parse, gst_pipeline_pad_autoplug is called and the connection between
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mpeg1parse and the videoqueue is made. same for audio.
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Et voila. same procedure for mp3/vorbis/avi/qt/mpeg2 etc...
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