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Original commit message from CVS: * docs/manual/advanced-autoplugging.xml: * docs/manual/advanced-schedulers.xml: * docs/manual/advanced-threads.xml: Rewrites. Remove cothreads, go a bit into opt specifically, document threads and their gotchas, and do some technical stuff on autoplugging plus add some working examples. Fixes #157395. * examples/manual/Makefile.am: Add typefind/autoplugger example (one that actually works). Remove queue example since it's a duplicate of the thread one.
250 lines
9.4 KiB
XML
250 lines
9.4 KiB
XML
<chapter id="chapter-threads">
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<title>Threads</title>
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<para>
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GStreamer has support for multithreading through the use of
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the <ulink type="http"
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url="&URLAPI;GstThread.html"><classname>GstThread</classname></ulink>
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object. This object is in fact a special <ulink type="http"
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url="&URLAPI;GstBin.html"><classname>GstBin</classname></ulink>
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that will start a new thread (using Glib's
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<classname>GThread</classname> system) when started.
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</para>
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<para>
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To create a new thread, you can simply use <function>gst_thread_new
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()</function>. From then on, you can use it similar to how you would
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use a <classname>GstBin</classname>. You can add elements to it,
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change state and so on. The largest difference between a thread and
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other bins is that the thread does not require iteration. Once set to
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the <classname>GST_STATE_PLAYING</classname> state, it will iterate
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its contained children elements automatically.
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</para>
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<para>
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<xref linkend="section-threads-img"/> shows how a thread can be
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visualised.
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</para>
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<figure float="1" id="section-threads-img">
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<title>A thread</title>
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<mediaobject>
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<imageobject>
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<imagedata fileref="images/thread.ℑ" format="&IMAGE;"/>
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</imageobject>
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</mediaobject>
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</figure>
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<sect1 id="section-threads-uses">
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<title>When would you want to use a thread?</title>
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<para>
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There are several reasons to use threads. However, there's also some
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reasons to limit the use of threads as much as possible. We will go
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into the drawbacks of threading in &GStreamer; in the next section.
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Let's first list some situations where threads can be useful:
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</para>
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<itemizedlist>
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<listitem>
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<para>
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Data buffering, for example when dealing with network streams or
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when recording data from a live stream such as a video or audio
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card. Short hickups elsewhere in the pipeline will not cause data
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loss. See <xref linkend="section-queues-img"/> for a visualization
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of this idea.
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</para>
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</listitem>
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<listitem>
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<para>
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Synchronizing output devices, e.g. when playing a stream containing
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both video and audio data. By using threads for both outputs, they
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will run independently and their synchronization will be better.
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</para>
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</listitem>
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<listitem>
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<para>
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Data pre-rolls. You can use threads and queues (thread boundaries)
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to cache a few seconds of data before playing. By using this
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approach, the whole pipeline will already be setup and data will
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already be decoded. When activating the rest of the pipeline, the
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switch from PAUSED to PLAYING will be instant.
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</para>
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</listitem>
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</itemizedlist>
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<figure float="1" id="section-queues-img">
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<title>a two-threaded decoder with a queue</title>
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<mediaobject>
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<imageobject>
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<imagedata fileref="images/queue.ℑ" format="&IMAGE;"/>
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</imageobject>
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</mediaobject>
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</figure>
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<para>
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Above, we've mentioned the <quote>queue</quote> element several times
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now. A queue is a thread boundary element. It does so by using a
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classic provider/receiver model as learned in threading classes at
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universities all around the world. By doing this, it acts both as a
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means to make data throughput between threads threadsafe, and it can
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also act as a buffer. Queues have several <classname>GObject</classname>
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properties to be configured for specific uses. For example, you can set
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lower and upper tresholds for the element. If there's less data than
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the lower treshold (default: disabled), it will block output. If
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there's more data than the upper treshold, it will block input or
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(if configured to do so) drop data.
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</para>
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</sect1>
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<sect1 id="section-threads-constraints">
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<title>Constraints placed on the pipeline by the GstThread</title>
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<para>
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Within the pipeline, everything is the same as in any other bin. The
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difference lies at the thread boundary, at the link between the
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thread and the outside world (containing bin). Since &GStreamer; is
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fundamentally buffer-oriented rather than byte-oriented, the natural
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solution to this problem is an element that can "buffer" the buffers
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between the threads, in a thread-safe fashion. This element is the
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<quote>queue</quote> element. A queue should be placed in between any
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two elements whose pads are linked together while the elements live in
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different threads. It doesn't matter if the queue is placed in the
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containing bin or in the thread itself, but it needs to be present
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on one side or the other to enable inter-thread communication.
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</para>
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<para>
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If you are writing a GUI application, making the top-level bin a
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thread will make your GUI more responsive. If it were a pipeline
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instead, it would have to be iterated by your application's event
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loop, which increases the latency between events (say, keyboard
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presses) and responses from the GUI. In addition, any slight hang
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in the GUI would delay iteration of the pipeline, which (for example)
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could cause pops in the output of the sound card, if it is an audio
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pipeline.
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</para>
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<para>
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A problem with using threads is, however, thread contexts. If you
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connect to a signal that is emitted inside a thread, then the signal
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handler for this thread <emphasis>will be executed in that same
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thread</emphasis>! This is very important to remember, because many
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graphical toolkits can not run multi-threaded. Gtk+, for example,
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only allows threaded access to UI objects if you explicitely use
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mutexes. Not doing so will result in random crashes and X errors.
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A solution many people use is to place an idle handler in the signal
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handler, and have the actual signal emission code be executed in the
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idle handler, which will be executed from the mainloop.
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</para>
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<para>
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Generally, if you use threads, you will encounter some problems. Don't
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hesistate to ask us for help in case of problems.
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</para>
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</sect1>
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<sect1 id="section-threads-example">
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<title>A threaded example application</title>
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<para>
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As an example we show the helloworld program that we coded in
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<xref linkend="chapter-helloworld"/> using a thread. Note that
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the whole application lives in a thread (as opposed to half
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of the application living in a thread and the other half being
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another thread or a pipeline). Therefore, it does not need a
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queue element in this specific case.
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</para>
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<programlisting><!-- example-begin threads.c -->
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#include <gst/gst.h>
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GstElement *thread, *source, *decodebin, *audiosink;
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static gboolean
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idle_eos (gpointer data)
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{
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g_print ("Have idle-func in thread %p\n", g_thread_self ());
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gst_main_quit ();
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/* do this function only once */
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return FALSE;
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}
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/*
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* EOS will be called when the src element has an end of stream.
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* Note that this function will be called in the thread context.
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* We will place an idle handler to the function that really
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* quits the application.
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*/
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static void
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cb_eos (GstElement *thread,
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gpointer data)
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{
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g_print ("Have eos in thread %p\n", g_thread_self ());
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g_idle_add ((GSourceFunc) idle_eos, NULL);
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}
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/*
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* On error, too, you'll want to forward signals to the main
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* thread, especially when using GUI applications.
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*/
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static void
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cb_error (GstElement *thread,
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GstElement *source,
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GError *error,
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gchar *debug,
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gpointer data)
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{
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g_print ("Error in thread %p: %s\n", g_thread_self (), error->message);
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g_idle_add ((GSourceFunc) idle_eos, NULL);
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}
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/*
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* Link new pad from decodebin to audiosink.
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* Contains no further error checking.
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*/
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static void
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cb_newpad (GstElement *decodebin,
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GstPad *pad,
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gboolean last,
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gpointer data)
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{
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gst_pad_link (pad, gst_element_get_pad (audiosink, "sink"));
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gst_bin_add (GST_BIN (thread), audiosink);
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gst_bin_sync_children_state (GST_BIN (thread));
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}
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gint
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main (gint argc,
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gchar *argv[])
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{
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/* init GStreamer */
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gst_init (&argc, &argv);
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/* make sure we have a filename argument */
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if (argc != 2) {
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g_print ("usage: %s <Ogg/Vorbis filename>\n", argv[0]);
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return -1;
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}
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/* create a new thread to hold the elements */
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thread = gst_thread_new ("thread");
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g_signal_connect (thread, "eos", G_CALLBACK (cb_eos), NULL);
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g_signal_connect (thread, "error", G_CALLBACK (cb_error), NULL);
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/* create elements */
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source = gst_element_factory_make ("filesrc", "source");
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g_object_set (G_OBJECT (source), "location", argv[1], NULL);
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decodebin = gst_element_factory_make ("decodebin", "decoder");
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g_signal_connect (decodebin, "new-decoded-pad",
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G_CALLBACK (cb_newpad), NULL);
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audiosink = gst_element_factory_make ("alsasink", "audiosink");
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/* setup */
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gst_bin_add_many (GST_BIN (thread), source, decodebin, NULL);
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gst_element_link (source, decodebin);
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gst_element_set_state (audiosink, GST_STATE_PAUSED);
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gst_element_set_state (thread, GST_STATE_PLAYING);
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/* no need to iterate. We can now use a mainloop */
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gst_main ();
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/* unset */
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gst_element_set_state (thread, GST_STATE_NULL);
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gst_object_unref (GST_OBJECT (thread));
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return 0;
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}
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<!-- example-end threads.c --></programlisting>
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</sect1>
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</chapter>
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