X-Git-Url: http://research.m1stereo.tv/gitweb?a=blobdiff_plain;f=docs%2Fframework.txt;h=1c2bafb0ab03d37ab5c1bf938e4a71853197bc40;hb=f4963a6aa07644399b273b5d2b1f9299c9047414;hp=4ffff1f5e595408e4f23fd66555d8353b4330ac3;hpb=52c1bb26fcbb895824cd9237c228ea4834ce1433;p=melted diff --git a/docs/framework.txt b/docs/framework.txt index 4ffff1f..1c2bafb 100644 --- a/docs/framework.txt +++ b/docs/framework.txt @@ -2,7 +2,7 @@ Framework Documentation Copyright (C) 2004 Ushodaya Enterprises Limited Author: Charles Yates -Last Revision: 2004-03-20 +Last Revision: 2004-10-08 MLT FRAMEWORK @@ -323,8 +323,8 @@ Playlists: // Add it to the playlist mlt_playlist_append( playlist, producer ); - // Close the producer (see below) - mlt_producer_close( producer ); + // Close the producer (see below) + mlt_producer_close( producer ); } // Return the playlist as a producer @@ -389,6 +389,193 @@ Filters: section, even multiple tracks have a single track output. +Attached Filters: + + All services can have attached filters. + + Consider the following example: + + // Create a producer + mlt_producer producer = mlt_factory_producer( NULL, clip ); + + // Get the service object of the producer + mlt_producer service = mlt_producer_service( producer ); + + // Create a filter + mlt_filter filter = mlt_factory_filter( "greyscale" ); + + // Create a playlist + mlt_playlist playlist = mlt_playlist_init( ); + + // Attach the filter to the producer + mlt_service_attach( producer, filter ); + + // Construct a playlist with various cuts from the producer + mlt_playlist_append_io( producer, 0, 99 ); + mlt_playlist_append_io( producer, 450, 499 ); + mlt_playlist_append_io( producer, 200, 399 ); + + // We can close the producer and filter now + mlt_producer_close( producer ); + mlt_filter_close( filter ); + + When this is played out, the greyscale filter will be executed for each frame + in the playlist which comes from that producer. + + Further, each cut can have their own filters attached which are executed after + the producer's filters. As an example: + + // Create a new filter + filter = mlt_factory_filter( "invert", NULL ); + + // Get the second 'clip' in the playlist + producer = mlt_playlist_get_clip( 1 ); + + // Get the service object of the clip + service = mlt_producer_service( producer ); + + // Attach the filter + mlt_service_attach( producer, filter ); + + // Close the filter + mlt_filter_close( filter ); + + Even the playlist itself can have an attached filter: + + // Create a new filter + filter = mlt_factory_filter( "watermark", "+Hello.txt" ); + + // Get the service object of the playlist + service = mlt_playlist_service( playlist ); + + // Attach the filter + mlt_service_attach( service, filter ); + + // Close the filter + mlt_filter_close( filter ); + + And, of course, the playlist, being a producer, can be cut up and placed on + another playlist, and filters can be attached to those cuts or on the new + playlist itself and so on ad nauseum. + + The main advantage of attached filters is that they remain attached and don't + suffer from the maintenance problems associated with items being inserted and + displacing calculated in/out points - this being a major issue if you + exclusively use the connect or insert detached filters in a multitrack field + (described below). + + +Introducing the Mix: + + The mix is the simplest way to introduce transitions between adjacent clips + on a playlist. + + Consider the following playlist: + + +-+----------------------+----------------------------+-+ + |X|A |B |X| + +-+----------------------+----------------------------+-+ + + Let's assume that the 'X' is a 'black clip' of 50 frames long. + + When you play this out, you'll get a 50 frames of black, abrupt cut into + A, followed by an abrupt cut into B, and finally into black again. + + The intention is to convert this playlist into something like: + + +-+---------------------+-+------------------------+-+ + |X|A |A|B |B| + |A| |B| |X| + +-+---------------------+-+------------------------+-+ + + Where the clips which refer to 2 clips represent a transition. Notice that + the representation of the second playlist is shorter than the first - this is + to be expected - a single transition of 50 frames between two clips will + reduce the playtime of the result by 50 frames. + + This is done via the use of the mlt_playlist_mix method. So, assuming you get + a playlist as shown in the original diagram, to do the first mix, you could do + something like: + + // Create a transition + mlt_transition transition = mlt_factor_transition( "luma", NULL ); + + // Mix the first and second clips for 50 + mlt_playlist_mix( playlist, 0, 50, transition ); + + // Close the transition + mlt_transition_close( transition ); + + This would give you the first transition, subsequently, you would apply a similar + technique to mix clips 1 and 2. Note that this would create a new clip on the + playlist, so the next mix would be between 3 and 4. + + As a general hint, to simplify the requirement to know the next clip index, + you might find the following simpler: + + // Get the number of clips on the playlist + int i = mlt_playlist_count( ); + + // Iterate through them in reverse order + while ( i -- ) + { + // Create a transition + mlt_transition transition = mlt_factor_transition( "luma", NULL ); + + // Mix the first and second clips for 50 + mlt_playlist_mix( playlist, i, 50, transition ); + + // Close the transition + mlt_transition_close( transition ); + } + + There are other techniques, like using the mlt_playlist_join between the + current clip and the newly created one (you can determine if a new clip was + created by comparing the playlist length before and after the mix call). + + Internally, the mlt_playlist_mix call generates a tractor and multitrack as + described below. Like the attached filters, the mix makes life very simple + when you're inserting items into the playlist. + + Also note that it allows a simpler user interface - instead of enforcing the + use of a complex multitrack object, you can do many operations on a single + track. Thus, additional tracks can be used to introduce audio dubs, mixes + or composites which are independently positioned and aren't affected by + manipulations on other tracks. But hey, if you want a bombastic, confusing + and ultimately frustrating traditional NLE experience, that functionality + is provided too ;-). + + +Practicalities and Optimisations: + + In the previous two sections I've introduced some powerful functionality + designed to simplify MLT usage. However, a general issue comes into this - + what happens when you introduce a transition between two cuts from the same + bit of video footage? + + Anyone who is familiar with video compression will be aware that seeking + isn't always without consequence from a performance point of view. So if + you happen to require two frames from the same clip for a transition, the + processing is going to be excessive and the result will undoubtedly be very + unpleasant, especially if you're rendering in realtime... + + So how do we get round this? + + Actually, it's very simple - you invoke mlt_producer_optimise on the top + level object after a modification and MLT will determine how to handle it. + Internally, it determines the maximum number of overlapping instances + throughout the object and creates clones and assigns clone indexes as + required. + + In the mix example above, you can simply call: + + // Optimise the playlist + mlt_producer_optimise( mlt_playlist_producer( playlist ) ); + + after the mix calls have be done. Note that this is automatically applied + to deserialised westleys. + + Multiple Tracks and Transitions: MLT's approach to multiple tracks is governed by two requirements: @@ -478,13 +665,11 @@ Multiple Tracks and Transitions: | +------+ | +-------------+ +-------+ +----------+ - In reality, we create a field first, and from that we obtain a multitrack - and a tractor. We can then populate the multitrack, field and finally, - connect the tractor to the consumer. - - The reasoning behind this is possibly flawed - it might have made more - sense to produce the tractor and have it encapsulate the field and the - multitrack as that is how it looks to a connected consumer: + So, we need to create the tractor first, and from that we obtain the + multitrack and field objects. We can populate these and finally + connect the tractor to a consumer. + + In essence, this is how it looks to the consumer: +-----------------------------------------------+ |tractor +--------------------------+ | @@ -514,16 +699,16 @@ Multiple Tracks and Transitions: mlt_producer create_tracks( int argc, char **argv ) { - // Create the field - mlt_field field = mlt_field_init( ); + // Create the tractor + mlt_tractor tractor = mlt_tractor_new( ); + + // Obtain the field + mlt_field field = mlt_tractor_field( tractor ); // Obtain the multitrack - mlt_multitrack multitrack = mlt_field_multitrack( field ); - - // Obtain the tractor - mlt_tractor tractor = mlt_field_tractor( field ); + mlt_multitrack multitrack = mlt_tractor_multitrack( tractor ); - // Obtain a composite transition + // Create a composite transition mlt_transition transition = mlt_factory_transition( "composite", "10%,10%:15%x15%" ); // Create track 0 @@ -555,15 +740,12 @@ Multiple Tracks and Transitions: // Now plant the transition mlt_field_plant_transition( field, transition, 0, 1 ); - - // Now set the properties on the tractor - properties = mlt_tractor_properties( tractor ); - mlt_properties_set_data( properties, "multitrack", multitrack, 0, ( mlt_destructor )mlt_multitrack_close, NULL ); - mlt_properties_set_data( properties, "field", field, 0, ( mlt_destructor )mlt_field_close, NULL ); - mlt_properties_set_data( properties, "track0", track0, 0, ( mlt_destructor )mlt_producer_close, NULL ); - mlt_properties_set_data( properties, "track1", track1, 0, ( mlt_destructor )mlt_producer_close, NULL ); - mlt_properties_set_data( properties, "transition", transition, 0, ( mlt_destructor )mlt_transition_close, NULL ); - + + // Close our references + mlt_producer_close( track0 ); + mlt_producer_close( track1 ); + mlt_transition_close( transition ); + // Return the tractor return mlt_tractor_producer( tractor ); }