INTRODUCTION
------------

	This document provides a brief tutorial on the use of the mlt++ wrapper 
	and bindings.


Hello World
-----------

	The mlt++ wrapper is a c++ wrapper for the mlt C library. As such, it 
	provides clean C++ access to the underlying library.

	An example of use is as follows:

	#include <mlt++/Mlt.h>
	using namespace Mlt;

	int main( void )
	{
		Factory::init( );
		Producer p( "pango:" );
		p.set( "text", "Hello World" );
		Consumer c( "sdl" );
		Event *e = c.setup_wait_for( "consumer-stopped" );
		c.connect( p );
		c.start( );
		c.wait_for( e );
		delete e;
		return 0;
	}

	This is a fairly typical example of use of mlt++ - create a 'producer' (an
	object which produces 'frames'), create a 'consumer' (an object which consumes
	frames), connect them together, start the consumer and wait until done (here
	we just wait for the user to close the window).

	In this case, we construct a window as a consumer using the 'sdl' consumer
	(SDL is a standard portable library which provides platform independent
	access to accelerated video display and audio) and use the 'pango' 
	producer to generate frames with the words 'Hello World' (pango is a 
	library from the gtk toolkit).

	The main point of this example is to show that mlt uses existing libraries
	to provide its functionality - this keeps the framework itself very small.

	Note that mlt is designed to be housed in GUI or server type applications -
	typically, applications don't wait around for the consumer to be stopped in
	the manner shown.

	So far, we've introduced the Producer and Consumer mlt classes. We'll cover
	each of these in more detail later in the tutorial, but for now, we'll 
	briefly cover the remaining classes.


Playlists
---------

	Another simple class is the Playlist - this is direct extension of Producer
	and it allows you to maintain a list of producer objects.

	As a simple example of the Playlist in action, we'll convert the example
	above into an application which plays multiple video or audio files.

	#include <mlt++/Mlt.h>
	using namespace Mlt;

	int main( int argc, char **argv )
	{
		Factory::init( );
		Playlist list;
		for ( int i = 1; i < argc; i ++ )
		{
			Producer p( argv[i] );
			if ( p.is_valid( ) )
				list.append( p );
		}
		Consumer c( "sdl" );
		c.connect( list );
		Event *e = c.setup_wait_for( "consumer-stopped" );
		c.start( );
		c.wait_for( e );
		delete e;
		return 0;
	}

	Now you can run the program as:

		./player *.avi *.mp3 *.jpg etc

	In this case, we construct a playlist by simply appending producers to it.
	Notice that although the scope of the Producer is limited to the inner 
	for loop, we can safely add it to the playlist - this is due to the fact
	that all mlt objects maintain reference counts and no object is really
	destroyed until all the references are gone. In this case, when the list
	object goes out of scope, all the producers we created will automatically
	be destroyed.


Filters
-------

	So far, we've shown how you can load and play media. We've given a brief
	intro to the Playlist container, now it's time to start manipulating 
	things...

	For the next example, I'll add a 'watermark' to the video - a watermark
	is used by broadcasters to brand the channel and normally consists of a 
	logo of some sort. We'll just use some black text on a partially 
	transparent red background.

	#include <mlt++/Mlt.h>
	using namespace Mlt;

	int main( int argc, char **argv )
	{
		Factory::init( );
		Playlist list;
		for ( int i = 1; i < argc; i ++ )
		{
			Producer p( argv[i] );
			if ( p.is_valid( ) )
				list.append( p );
		}
		Filter f( "watermark", "pango:" );
		f.set( "producer.text", "MLT++" );
		f.set( "producer.fgcolour", "0x000000ff" );
		f.set( "producer.bgcolour", "0xff000080" );
		list.attach( f );
		Consumer c( "sdl" );
		c.connect( list );
		Event *e = c.setup_wait_for( "consumer-stopped" );
		c.start( );
		c.wait_for( e );
		delete e;
		return 0;
	}

	Notice that the watermark filter reuses the 'pango' producer we showed in the
	first example. In fact, you could use any producer here - if you wanted to
	use a graphic or a video, you would just construct the filter with a full path
	to that as the second argument.

	We manipulate the filter using the set method - this method was also shown
	in the first example. 

	Finally, we attach the filter to the playlist. This ensure that all frames 
	that are obtained from the playlist are watermarked. 


Tractor
-------

	A tractor is an object that allows the manipulation of multiple video and audio
	tracks. 

	Stepping away from the player example we've been tinkering with for a minute,
	let's assume we want to do something like dubbing a video with some audio. This
	a very trivial thing to do:

	Tractor *dub( char *video_file, char *audio_file )
	{
		Tractor *tractor = new Tractor( );
		Producer video( video_file );
		Producer audio( audio_file );
		tractor->set_track( video, 0 );
		tractor->set_track( audio, 1 );
		return tractor;
	}

	That's all that needs to be done - you can now connect the returned object to a
	consumer, or add it to a playlist, or even apply it as a track to another tractor.


Transition
----------

	Let's now assume we want to mix the audio between two tracks - to do this, we 
	need to introduce the concept of a transition. A transition in mlt is a service
	which combines frames from two producers to produce a new frame.

	Tractor *mix( char *video_file, char *audio_file )
	{
		Tractor *tractor = new Tractor( );
		Transition mix( "mix" );
		Producer video( video_file );
		Producer audio( audio_file );
		tractor.set_track( video, 0 );
		tractor.set_track( audio, 1 );
		tractor.field.plant_transition( mix, 0, 1 );
		return tractor;
	}

	The tractor returned will now mix the audio from the original video and the audio.


Events
------

	Typically, applications need to be informed when changes occur in an mlt++ object.
	This facilitates application services such as undo/redo management, or project
	rendering in a timeline type widget and many other types of operations which an
	application needs.

	As an example, consider the following:

	class Westley
	{
		private:
			Consumer consumer;
			Tractor &tractor;
		public:
			Westley( MltTractor &tractor ) :
				tractor( tractor ),
				consumer( "westley" )
			{
				consumer.connect( tractor );
				tractor.listen( tractor, "producer-changed", ( mlt_listener )Westley::listener );
			}
			
			static void listener( Properties *tractor, Westley *object )
			{
				object->activate( );
			}

			void activate( )
			{
				consumer.start( );
			}
	};

	

That's All Folks...
-------------------

	And that, believe it or not, is a fairly complete summary of the classes you'll 
	typically be interfacing with in mlt++. Obviously, there's a little more to it 
	than this - a couple of intrisinc classes have been glossed over (notably, the 
	Properties and Service base classes). The next section will cover all of the 
	above, but in much more detail...


DIGGING DEEPER
--------------

	The previous section was designed to give you a whistle stop tour through the major
	framework classes. This section will take you through the scenic route.


Introducing Base Classes
------------------------

	Services in mlt are the collective noun for Producers, Filters, Transitions and 
	Consumer. A Service is also the base class from which all of these classes 
	extend. It provides the basic connectivity which has been shown throughout the
	examples in the previous section.

	Properties are the main way in which we communicate with the Services - 
	essentially, it provides get/set methods for named values. All services extend
	Properties.


Properties
----------

	Properties provide the general mechanism for communicating with Services - 
	through the Properties interface, we are able to manipulate and serialise 
	a services state.

	For example, to dump all the properties to stdout, you can use something 
	like:

	void dump( Properties &properties )
	{
		for ( int i = 0; i < properties.count( ); i ++ )
			cout << Properties.get_name( i ) << " = " << Properties.get( i ) << endl;
	}

	Note that the properties object handles type conversion, so the following
	is acceptable:

	properties.set( "hello", "10.5" );
	int hello_int = properties.get_int( "hello" );
	double hello_double = properties.get_double( "hello" );

	A couple of convenience methods are provide to examine or serialise property
	objects. 

	For example:

	properties.debug( );

	will report all serialisable properties on stderr, in the form:

	Object: [ ref=1, in=0, out=0, track=0, u=75, v=150, _unique_id=15, 
	mlt_type=filter, mlt_service=sepia ]


Services
--------

	Typically, all the services are constructed via the specific classes 
	constructor. Often, you will receive Service objects rather than their
	specific type. In order to access the extended classes interface, 
	you will need to create a reference.

	For example, given an arbitrary Service object, you can determine its
	type by using the type method - this will return a 'service_type' which
	has values of producer_type, filter_type etc. Alternatively, you can
	create a wrapping object and check on its validity.

	bool do_we_have_a_producer( Service &service )
	{
		Producer producer( service );
		return producer.is_valid( );
	}


Events
------