In this chapter you will learn how to construct the bare minimum code for a new plugin. Starting from ground zero, you will see how to get the &GStreamer; template source. Then you will learn how to use a few basic tools to copy and modify a template plugin to create a new plugin. If you follow the examples here, then by the end of this chapter you will have a functional audio filter plugin that you can compile and use in &GStreamer; applications. There are currently two ways to develop a new plugin for &GStreamer;: You can write the entire plugin by hand, or you can copy an existing plugin template and write the plugin code you need. The second method is by far the simpler of the two, so the first method will not even be described here. (Errm, that is, it is left as an exercise to the reader.) The first step is to check out a copy of the gst-template CVS module to get an important tool and the source code template for a basic &GStreamer; plugin. To check out the gst-template module, make sure you are connected to the internet, and type the following commands at a command console: shell $ cd . shell $ cvs -d:pserver:anonymous@cvs.freedesktop.org:/home/cvs/gstreamer login Logging in to :pserver:anonymous@cvs.freedesktop.org:2401/home/cvs/gstreamer CVS password: shell $ cvs -z3 -d:pserver:anonymous@cvs.freedesktop.org:/home/cvs/gstreamer co gst-template U gst-template/README U gst-template/gst-app/AUTHORS U gst-template/gst-app/ChangeLog U gst-template/gst-app/Makefile.am U gst-template/gst-app/NEWS U gst-template/gst-app/README U gst-template/gst-app/autogen.sh U gst-template/gst-app/configure.ac U gst-template/gst-app/src/Makefile.am ... After the first command, you will have to press ENTER to log in to the CVS server. (You might have to log in twice.) The second command will check out a series of files and directories into ./gst-template. The template you will be using is in ./gst-template/gst-plugin/ directory. You should look over the files in that directory to get a general idea of the structure of a source tree for a plugin. The first thing to do when making a new element is to specify some basic details about it: what its name is, who wrote it, what version number it is, etc. We also need to define an object to represent the element and to store the data the element needs. These details are collectively known as the boilerplate. The standard way of defining the boilerplate is simply to write some code, and fill in some structures. As mentioned in the previous section, the easiest way to do this is to copy a template and add functionality according to your needs. To help you do so, there are some tools in the ./gst-template/tools/ directory. One tool, gst-quick-stamp, is a quick command line tool. The other, gst-project-stamp, is a full GNOME druid application that takes you through the steps of creating a new project (either a plugin or an application). To use pluginstamp.sh, first open up a terminal window. Change to the gst-template directory, and then run the pluginstamp.sh command. The arguments to the pluginstamp.sh are: the name of the plugin, and the directory that should hold a new subdirectory for the source tree of the plugin. Note that capitalization is important for the name of the plugin. Under some operating systems, capitalization is also important when specifying directory names. For example, the following commands create the ExampleFilter plugin based on the plugin template and put the output files in a new directory called ~/src/examplefilter/: shell $ cd gst-template shell $ tools/pluginstamp.sh ExampleFilter ~/src First we will examine the code you would be likely to place in a header file (although since the interface to the code is entirely defined by the pluging system, and doesn't depend on reading a header file, this is not crucial.) The code here can be found in examples/pwg/examplefilter/boiler/gstexamplefilter.h. /* Definition of structure storing data for this element. */ typedef struct _GstExample GstExample; struct _GstExample { GstElement element; GstPad *sinkpad, *srcpad; gboolean silent; }; /* Standard definition defining a class for this element. */ typedef struct _GstExampleClass GstExampleClass; struct _GstExampleClass { GstElementClass parent_class; }; /* Standard macros for defining types for this element. */ #define GST_TYPE_EXAMPLE \ (gst_example_get_type()) #define GST_EXAMPLE(obj) \ (GTK_CHECK_CAST((obj),GST_TYPE_EXAMPLE,GstExample)) #define GST_EXAMPLE_CLASS(klass) \ (GTK_CHECK_CLASS_CAST((klass),GST_TYPE_EXAMPLE,GstExample)) #define GST_IS_EXAMPLE(obj) \ (GTK_CHECK_TYPE((obj),GST_TYPE_EXAMPLE)) #define GST_IS_EXAMPLE_CLASS(obj) \ (GTK_CHECK_CLASS_TYPE((klass),GST_TYPE_EXAMPLE)) /* Standard function returning type information. */ GType gst_example_get_type (void); A plan for the future is to create a FilterFactory, to make the process of making a new filter a simple process of specifying a few details, and writing a small amount of code to perform the actual data processing. Ideally, a FilterFactory would perform the tasks of boilerplate creation, code functionality implementation, and filter registration. Unfortunately, this has not yet been implemented. Even when someone eventually does write a FilterFactory, this element will not be able to cover all the possibilities available for filter writing. Thus, some plugins will always need to be manually coded and registered. Here is a rough outline of what is planned: You run the FilterFactory and give the factory a list of appropriate function pointers and data structures to define a filter. With a reasonable measure of preprocessor magic, you just need to provide a name for the filter and definitions of the functions and data structures desired. Then you call a macro from within plugin_init() that registers the new filter. All the fluff that goes into the definition of a filter is thus be hidden from view. The GstElementDetails structure gives a heirarchical type for the element, a human-readable description of the element, as well as author and version data. The entries are: A long, english, name for the element. The type of the element, as a heirarchy. The heirarchy is defined by specifying the top level category, followed by a "/", followed by the next level category, etc. The type should be defined according to the guidelines elsewhere in this document. (FIXME: write the guidelines, and give a better reference to them) A brief description of the purpose of the element. The name of the author of the element, optionally followed by a contact email address in angle brackets. For example: static GstElementDetails example_details = { "An example plugin", "Example/FirstExample", "Shows the basic structure of a plugin", "your name <your.name@your.isp>" }; The element details are registered with the plugin during _base_init (). static void gst_my_filter_base_init (GstMyFilterClass *klass) { static GstElementDetails my_filter_details = { [..] }; GstElementClass *element_class = GST_ELEMENT_CLASS (klass); [..] gst_element_class_set_details (element_class, &my_filter_details); } A GstStaticPadTemplate is a description of a pad that the element will (or might) create and use. It contains: A short name for the pad. Pad direction. Existence property. This indicates whether the pad exists always (an always pad), only in some cases (a sometimes pad) or only if the application requested such a pad (a request pad). Supported types by this element (capabilities). For example: static GstStaticPadTemplate sink_factory = GST_STATIC_PAD_TEMPLATE ( "sink", GST_PAD_SINK, GST_PAD_ALWAYS, GST_STATIC_CAPS ("ANY") ); Those pad templates are registered during the _base_init () function. Pads are created from these templates in the element's _init () function using gst_pad_new_from_template (). The template can be retrieved from the element class using gst_element_class_get_pad_template (). See below for more details on this. static void gst_my_filter_base_init (GstMyFilterClass *klass) { static GstStaticPadTemplate sink_factory = [..] , src_factory = [..] GstElementClass *element_class = GST_ELEMENT_CLASS (klass); gst_element_class_add_pad_template (element_class, gst_static_pad_template_get (&src_factory)); gst_element_class_add_pad_template (element_class, gst_static_pad_template_get (&sink_factory)); [..] } Each element has three functions which are used for construction of an element. These are the _base_init() function which is meant to initialize class and child class properties during each new child class creation; the _class_init() function, which is used to initialise the class only once (specifying what signals, arguments and virtual functions the class has and setting up global state); and the _init() function, which is used to initialise a specific instance of this type. Once we have written code defining all the parts of the plugin, we need to write the plugin_init() function. This is a special function, which is called as soon as the plugin is loaded, and should return TRUE or FALSE depending on whether it loaded initialized any dependencies correctly. Also, in this function, any supported element type in the plugin should be registered. Note that the information returned by the plugin_init() function will be cached in a central registry. For this reason, it is important that the same information is always returned by the function: for example, it must not make element factories available based on runtime conditions. If an element can only work in certain conditions (for example, if the soundcard is not being used by some other process) this must be reflected by the element being unable to enter the READY state if unavailable, rather than the plugin attempting to deny existence of the plugin.