OggKate: Difference between revisions

From XiphWiki
Jump to navigation Jump to search
(add karaoke and text file format sections, plus other minor updates to reflect recent work)
Line 10: Line 10:
karaoke data), etc, but doesn't have to be. A possible use of a lone Kate stream would
karaoke data), etc, but doesn't have to be. A possible use of a lone Kate stream would
be an e-book.
be an e-book.
Moreover, the motion feature gives Kate a powrful means to describe arbitrary curves, so
Moreover, the motion feature gives Kate a powerful means to describe arbitrary curves, so
hand drawing of shapes can be achieved. This was originally meant for karaoke use, but
hand drawing of shapes can be achieved. This was originally meant for karaoke use, but
can be used for any purpose. Motions can be attached to various semantics, like position,
can be used for any purpose. Motions can be attached to various semantics, like position,
Line 46: Line 46:
*Style definitions header: a list of predefined styles to be referred to by data packets
*Style definitions header: a list of predefined styles to be referred to by data packets
*Region definitions header: a list of predefined regions to be referred to by data packets
*Region definitions header: a list of predefined regions to be referred to by data packets
*Curves definitions header: a list of predefined curves to be referred to by data packets
*Motion definitions header: a list of predefined motions to be referred to by data packets
*Motion definitions header: a list of predefined motions to be referred to by data packets


Other header packets are ignored, and left for future expansion. In particular, there will
Other header packets are ignored, and left for future expansion.
likely be a motions definition header, where motions which are to be used repeatedly will
be stored for reference in text packets.


Data packets:
Data packets:
Line 61: Line 60:
*Kate is a discontinuous codec, as defined in ogg-multiplex.html in the Ogg documentation, which means it's timed by start granule, not end granule (as Theora and Vorbis). Also, all data packets are on their own page, for two reasons:
*Kate is a discontinuous codec, as defined in ogg-multiplex.html in the Ogg documentation, which means it's timed by start granule, not end granule (as Theora and Vorbis). Also, all data packets are on their own page, for two reasons:
**Ogg keeps track of granules at the page level, not the packet level
**Ogg keeps track of granules at the page level, not the packet level
**if no text event happens for a while after a particular text event, we don't want to delay it so a fuller page can be issued
**if no text event happens for a while after a particular text event, we don't want to delay it so a larger page can be issued


See also [[#Seeking and memory|Problems to solve: Seeking and memory]].
See also [[#Seeking and memory|Problems to solve: Seeking and memory]].
Line 91: Line 90:
== Motion ==
== Motion ==


The Kate bitstream format includes motion definition, primarily for karaoke purposes, but
The Kate bitstream format includes motion definition, originally for karaoke purposes, but
which can be used for more general purpose, such as line based drawing, or animation of
which can be used for more general purpose, such as line based drawing, or animation of
the text (position, color, etc)
the text (position, color, etc)


Motions are defined by the means of a series of curves (for now, segments and splines). A
Motions are defined by the means of a series of curves (static points, segments and splines).
2D point can be obtained from a motion for any timestamp during the lifetime of a text.
A 2D point can be obtained from a motion for any timestamp during the lifetime of a text.
This can be used for moving a marker in 2D above the text for karaoke, or to use the x
This can be used for moving a marker in 2D above the text for karaoke, or to use the x
coordinate to color text when the motion position passes each letter or word, etc.
coordinate to color text when the motion position passes each letter or word, etc.
Line 106: Line 105:
the main object of an event, it is even possible to have an empty text, and use the motion
the main object of an event, it is even possible to have an empty text, and use the motion
as a virtual pencil to draw arbitrary shapes. Even on-the-fly handwriting subtitles could
as a virtual pencil to draw arbitrary shapes. Even on-the-fly handwriting subtitles could
be done this way, though this would require a lot of control points.
be done this way, though this would require a lot of control points, and would not be able
to be used with text-to-speech.


It is also possible for motions to be discontinuous - simply insert a curve of 'none' type.
It is also possible for motions to be discontinuous - simply insert a curve of 'none' type.
Line 126: Line 126:
needed, Kate predefines the semantics text_color_rg and text_color_ba, so a 4D point can be
needed, Kate predefines the semantics text_color_rg and text_color_ba, so a 4D point can be
obtained using two different motions.
obtained using two different motions.
There are higher level constructs, such as morphing between two styles, or predefined
karaoke effects.


See also [[#Trackers|Trackers]].
See also [[#Trackers|Trackers]].
Line 137: Line 140:
Once initialized with a text and a set of motions, the client code can give the tracker a new
Once initialized with a text and a set of motions, the client code can give the tracker a new
timestamp, and get back the current text position, text color, etc.
timestamp, and get back the current text position, text color, etc.
Using a tracker is not necessary, if one wants to use the motions directly, or just ignore them,
but it makes life easier.
== The Kate file format
Though this is not a feature of the bitstream format, I have created a text file format to
describe a series of events to be turned into a Kate bitstream.
At its minimum, the following is a valid input to the encoder:
: kate {
::  event { 00:00:05 --> 00:00:10    "This is a text" }
: }
This will create a simple stream with "This is a text" emitted at an offset of 5 seconds into
the track, lasting 5 seconds to an offset of 10 seconds.
Motions, regions, styles can be declared in a definitions block to be reused by events, or can
be defined inline. Defining those in the definitions block places them in a header so they can
be reused later, saving space. However, they can also be defined in each event, so they will be
sent with the event. This allows them to be generated on the fly (eg, if the bitstream is being
streamed from a realtime input).
For convenience, the Kate file format also allows C style macros, though without parameters.
Please note that the Kate file format is fully separate from the Kate bitstream format. The
difference between the two is similar to the difference between a C source file and the resulting
object file, when compiled.
== Karaoke
Karaoke effects rely on motions, and there will be predefined higher level ways of specifying
timings and effects, two of which are already done. As an example, this is a valid Karaoke script:
:kate {
::  simple_timed_glyph_style_morph {
:::  from style "start_style" to style "end_style"
:::  "Let "    at 1.0
:::  "us "    at 1.2
:::  "sing "  at 1.4
:::  "to"      at 2.0
:::  "ge"      at 2.5
:::  "ther"    at 3.0
::  }
:}
The syllables will change from a style to another as time passes. The definition of the start_style
and end_style styles is omitted for brevity.




Line 161: Line 214:
=== Text encoding ===
=== Text encoding ===


A header field declares the text encoding used in the stream (this can be overridden in a
A header field declares the text encoding used in the stream. At the moment, only UTF-8 is
data packet, but this is not relevant to this point). At the moment, only UTF-8 is supported,
supported, for simplicity.
for simplicity, and I have not yet decided whether or not the Kate specification will allow
for other encodings, such as UTF-16 of UTF-32. The reason for this is that, if these were to
be supported, either:
*users of the decoder would have to be ready to face text in any one of these encodings
*the decoder would have to convert encodings to one selected by the user of the decoder
 
The first option may be asking a lot of users, while the second one brings complexity to the
decoder, and kind of defeats the purpose of supporting the encoding in the first place.


Note that strings included in the header (language, category, etc) are not affected by that
Note that strings included in the header (language, category, etc) are not affected by that
language encoding (rather obviously for language itself). These are ASCII.
language encoding (rather obviously for language itself). These are ASCII.


At the moment, I am leaning strongly towards limiting the encoding to UTF-8.
The actual text in events may include simple HTML markup (eg, <br>, <em>, etc).
 
It is also possible to ask libkate to remove this markup if the client prefers to receive
The actual text may include simple HTML markup (eg, <br>, <em>, etc).
plain text without the markup.
It is also possible to ask libkate to remove this markup if the client doesn't want it.


=== Language encoding ===
=== Language encoding ===
Line 204: Line 248:
=== Bitstream format for floating point values ===
=== Bitstream format for floating point values ===


At the moment, floating point values (for splines) are stored as their textual representation, and converted back and forth using snprintf and sscanf. We could quantize them and store as
Floating point values are be turned to a 16.16 fixed point format, then stored in a bitpacked
integers, since precision isn't that important here.
format, storing the number of zero bits at the head and tail of the floating point values once
-> If precision doesn't suffer, floating point values will be turned to a 16.16 fixed point format, then
per stream, and the remainder bits for all values in the stream. This seems to yield good results
    stored in a bitpacked format, storing the number of zero bits at the head and tail of the floating point
(typically a 50% reduction over 32 bits raw writes, and 70% over the snprintf based storage), and
    values once per stream, and the remainder bits for all values in the stream. This seems to yield good
has the big advantage of being portable (eg, independant of any IEEE format).
    results (typically a 50% reduction over 32 bits raw writes, and 70% over the snprintf based storage),
However, this means reduced precision due to the quantization to 16.16. I may add support for
    and has the big advantage of being portable (eg, independant of any IEEE format).
variable precision (eg, 8.24 fixed point formats) to alleviate this. This would however mean less
space savings, though these are likely to be insignificant when Kate streams are interleaved with
a video.


*Though this is not a Kate issue per se, the motion feature is very difficult to use without a curve editor. While tools may be coded to create a Kate bitstream for various existing subtitle formats, it is not certain it will be easy to find a good authoring tool for a series of curves. That said, it's not exactly difficult to do if you know a widget set.
*Though this is not a Kate issue per se, the motion feature is very difficult to use without a curve editor. While tools may be coded to create a Kate bitstream for various existing subtitle formats, it is not certain it will be easy to find a good authoring tool for a series of curves. That said, it's not exactly difficult to do if you know a widget set.


*Since motions may be repeated, I may add predefined motions in an extra header packet, to be referenced as styles and regions are. This would depend on whether motions are likely to be exactly repeated often, and I don't know if this will likely be the case. Complex motion definitions can take a lot of space, especially with the current floating point value encoding. After some thought, I will almost certainly place predefined curves in a header, and allow motions to refer to them. Fully defined curves will also be able to be placed in data packets, as it's likely some curves will be used only once, and it would constrain future uses to allow them only in headers (eg, if one were to stream handwriting using Kate).
-> There is now a separate curves/motions definition header, especially as I now use motions for more than simply moving a point in 2D.
    Motions use a lot of floating point values, so the above compression is welcome.
    Motions will still be able to be stored in data packets, however, so they can be generated in real time if streaming from a live source.


== Text to speech ==
== Text to speech ==
Line 269: Line 311:
A encoder and a decoder are included in the tools directory. Note that they are very rough
A encoder and a decoder are included in the tools directory. Note that they are very rough
and do not perform much error checking at all. The encoder pulls its input from a custom
and do not perform much error checking at all. The encoder pulls its input from a custom
text based file format, which is by no means meant to be part of the Kate specification,
text based file format, which is by no means meant to be part of the Kate bitstream specification,
or from an SubRip format file (the most common subtitle format I found, and a very basic one).
or from an SubRip format file (the most common subtitle format I found, and a very basic one).
The custom format It is just used as a quick way to define data to create a Kate bitstream.
Tools might be created to create a Kate bitstream from various data formats, such as existing
subtitle formats (SSA, etc). I currently have a patch to mplayer that can create Kate streams
from any of the subtitle formats it supports, so creating Kate streams is easy.


The Kate bitstreams encoded and decoded by those tools, however, are (supposed to be)
The Kate bitstreams encoded and decoded by those tools, however, are (supposed to be)
correct for this specification, provided their input is correct.
correct for this specification, provided their input is correct.

Revision as of 11:43, 30 January 2008

Disclaimer

This is not a Xiph codec, but I was asked to post information about Ogg/Kate on this wiki. As such, please do not assume that Xiph has anything to do with this, much less responsibility.

What is Kate?

Kate is a codec for karaoke and text encapsulation for Ogg. Most of the time, this would be multiplexed with audio/video to carry subtitles, song lyrics (with or without karaoke data), etc, but doesn't have to be. A possible use of a lone Kate stream would be an e-book. Moreover, the motion feature gives Kate a powerful means to describe arbitrary curves, so hand drawing of shapes can be achieved. This was originally meant for karaoke use, but can be used for any purpose. Motions can be attached to various semantics, like position, color, etc, so scrolling or fading text can be defined.

Why a new codec?

As I was adding support for Theora, Speex and FLAC to some software of mine, I found myself wanting to have song lyrics accompanying Vorbis audio. Since Vorbis comments are limited to the headers, one can't add them in the stream as they are sung, so another multiplexed stream would be needed to carry them.

The three possible bases usable for such a codec I found were Writ, CMML, and OGM/SRT.

  • Writ is an unmaintained start at an implementation of a very basic design, though I did find an encoder/decoder in py-pgg2 later on - I'd been quicker to write Kate from scratch anyway.
  • CMML is more geared towards encapsulating metadata about an accompanying stream, rather than being a data stream itself, and seems complex for a simple use - I don't really want *full* HTML/XML with links, etc - besides, it seems designed for Annodex (which I haven't had a look at), though it does seems relatively generic for use outwith Annodex
  • OGM/SRT, which I only found when I added Kate support to MPlayer, is shoehorning various data formats into an Ogg stream, and just dumps the SRT subtitle format as is, AFAICS (though I haven't looked at this one in detail, since I'd already had a working Kate implementation by that time)

I then decided to roll my own, not least because it's a fun thing to do.

I found other formats, such as USF (designed for inclusion in Matroska) and various subtitle formats, but none were designed for embedding inside an Ogg container.

Overview of the Kate bitstream format

I've taken much inspiration from Vorbis and Theora here. Headers and packets (as well as the API design) follow the design of these two codecs.

A rough overview (detailed description is available below (no, it's not, it will be available later when the format has settled down a bit more)) is:

Headers packets:

  • ID header [BOS]: magic, version, granule fraction, encoding, language, etc
  • Comment header: Vorbis comments, as per Vorbis/Theora streams
  • Style definitions header: a list of predefined styles to be referred to by data packets
  • Region definitions header: a list of predefined regions to be referred to by data packets
  • Curves definitions header: a list of predefined curves to be referred to by data packets
  • Motion definitions header: a list of predefined motions to be referred to by data packets

Other header packets are ignored, and left for future expansion.

Data packets:

  • text data: text and optional motions, accompanied by optional overrides for style, region, language, etc
  • end data [EOS]: marks the end of the stream, it doesn't have any payload

Other data packets are ignored, and left for future expansion.

Things of note:

  • Kate is a discontinuous codec, as defined in ogg-multiplex.html in the Ogg documentation, which means it's timed by start granule, not end granule (as Theora and Vorbis). Also, all data packets are on their own page, for two reasons:
    • Ogg keeps track of granules at the page level, not the packet level
    • if no text event happens for a while after a particular text event, we don't want to delay it so a larger page can be issued

See also Problems to solve: Seeking and memory.

  • The granule encoding is not a direct time/granule correspondance, see the granule encoding section.
  • The EOS packet should have a granule pos higher than the end time of all events.
  • User code doesn't have to know the number of headers to expect, this is moved inside the library code.

Support

I have patches for the following with Kate support:

  • oggmerge (it also adds Theora support)
  • file(1)
  • MPlayer (for multiplexed per-language subtitles - all region/style info is ignored)
  • xine (text, and work-in-progress style/regions/motions support)

None of those are released yet, since the Kate bitstream format is still a work in progress.

Granule encoding

At the moment, the granules are split in two: the high bits represent a time (scaled by a fractional speed defined in the ID header), and the low bits are an increasing counter used when several events happen at the same time. At the moment, 5 bits are taken for that counter. This is totally arbitrary and subject to change. The granule shift of a stream is included in the ID header. See also the problems to solve section, about seeking, for a possible three-way split, where the high bits would be further split.

Motion

The Kate bitstream format includes motion definition, originally for karaoke purposes, but which can be used for more general purpose, such as line based drawing, or animation of the text (position, color, etc)

Motions are defined by the means of a series of curves (static points, segments and splines). A 2D point can be obtained from a motion for any timestamp during the lifetime of a text. This can be used for moving a marker in 2D above the text for karaoke, or to use the x coordinate to color text when the motion position passes each letter or word, etc. Motions have an attached semantics so the client code knows how to use a particular motion. Predefined semantics include text color, text position, etc).

Since a motion can be composed of an arbitrary number of curves, each of which may have an arbitrary number of control points, complex motions can be achieved. If the motion is the main object of an event, it is even possible to have an empty text, and use the motion as a virtual pencil to draw arbitrary shapes. Even on-the-fly handwriting subtitles could be done this way, though this would require a lot of control points, and would not be able to be used with text-to-speech.

It is also possible for motions to be discontinuous - simply insert a curve of 'none' type. While the timestamp lies within such a curve, no 2D point will be generated. This can be used to temporarily hide a marker, for instance.

It is worth mentionning that pauses in the motion can be trivially included by inserting at the right time and for the right duration a simple linear interpolation curve with only two equal points, equal to the position the motion is supposed to pause at.

Kate defines a set of predefined mappings so that each decoder user interprets a motion in the same way. A mapping is coded on 8 bits in the bitstream, and the first 128 are reserved for Kate, leaving 128 for application specific mappings, to avoid constraining creative uses of that feature. Predefined mappings include frame (eg, 0-1 points are mapped to the size of the current video frame), or region, to scale 0-1 to the current region. This allows curves to be defined without knowing in advance the pixel size of the area it should cover.

For uses which require more than two coordinates (eg, text color, where 4 (RGBA) values are needed, Kate predefines the semantics text_color_rg and text_color_ba, so a 4D point can be obtained using two different motions.

There are higher level constructs, such as morphing between two styles, or predefined karaoke effects.

See also Trackers.


Trackers

Since attaching motions to text position, etc, makes it hard for the client to keep track of everything, doing interpolation, etc, the library supplies a tracker object, which handles the interpolation of the relevant properties. Once initialized with a text and a set of motions, the client code can give the tracker a new timestamp, and get back the current text position, text color, etc.

Using a tracker is not necessary, if one wants to use the motions directly, or just ignore them, but it makes life easier.


== The Kate file format

Though this is not a feature of the bitstream format, I have created a text file format to describe a series of events to be turned into a Kate bitstream. At its minimum, the following is a valid input to the encoder:

kate {
event { 00:00:05 --> 00:00:10 "This is a text" }
}

This will create a simple stream with "This is a text" emitted at an offset of 5 seconds into the track, lasting 5 seconds to an offset of 10 seconds.

Motions, regions, styles can be declared in a definitions block to be reused by events, or can be defined inline. Defining those in the definitions block places them in a header so they can be reused later, saving space. However, they can also be defined in each event, so they will be sent with the event. This allows them to be generated on the fly (eg, if the bitstream is being streamed from a realtime input).

For convenience, the Kate file format also allows C style macros, though without parameters.

Please note that the Kate file format is fully separate from the Kate bitstream format. The difference between the two is similar to the difference between a C source file and the resulting object file, when compiled.


== Karaoke

Karaoke effects rely on motions, and there will be predefined higher level ways of specifying timings and effects, two of which are already done. As an example, this is a valid Karaoke script:

kate {
simple_timed_glyph_style_morph {
from style "start_style" to style "end_style"
"Let " at 1.0
"us " at 1.2
"sing " at 1.4
"to" at 2.0
"ge" at 2.5
"ther" at 3.0
}
}

The syllables will change from a style to another as time passes. The definition of the start_style and end_style styles is omitted for brevity.


Problems to solve

There are a few things to solve before the Kate bitstream format can be considered good enough to be frozen:

Seeking and memory

When seeking to a particular time in a movie with subtitles, we may end up at a place when a subtitle has been started, but is not removed yet. Pure streaming doesn't have this problem as it remembers the subtitle being issued (as opposed to, say, Vorbis, for which all data valid now is decoded from the last packet). With Kate, a text string valid now may have been issued long ago.

I see three possible ways to solve this:

  • each data packet includes the granule of the earliest still active packet (if none, this will be the granule of this very packet)
    • this means seeks are two phased: first seek, find the next Kate packet, and seek again if the granule of the earlier still active packet is less than the original seeked granule. This implies support code on players to do the double seek.
  • use "reference frames", a bit like Theora does, where the granule position is split in several fields: the higher bits represent a position for the reference frame, and the lowest bits a delta time to the current position. When seeking to a granule position, the lower bits are cleared off, yielding the granule position of the previous reference frame, so the seek ends up at the reference frame. The reference frame is a sync point where any active strings are issued again. This is a variant of the method described in the Writ wiki page, but the granule splitting avoids any "downtime".
    • this requires reissuing packets, and it doesn't feel right (and wastes space).
    • it also requires "dummy" decoding of Kate data from the reference frame to the actual seek point to fully refresh the state "memory".
  • A variant of the two-granules-in-one system used by libcmml, where the "back link" points to the earliest still active string, rather than the previous one (this allows a two phase seek, rather than a multiphase seek, hopping back from event to event, with no real way to know if there is or not a previous event which is still active - I suppose CMML has no need to know this, if their "clips" do not overlap - mine can do).
    • Such a system considerably shortens the usable granule space, though it can do a one phase seek, if I understand the system correctly, which I am not certain.

Text encoding

A header field declares the text encoding used in the stream. At the moment, only UTF-8 is supported, for simplicity.

Note that strings included in the header (language, category, etc) are not affected by that language encoding (rather obviously for language itself). These are ASCII.

The actual text in events may include simple HTML markup (eg, <br>, <em>, etc). It is also possible to ask libkate to remove this markup if the client prefers to receive plain text without the markup.

Language encoding

A header field defines the language (if any) used in the stream (this can be overridden in a data packet, but this is not relevant to this point). At the moment, my test code uses ISO 639-1 two letter codes, but I originally thought to use RFC 3066 tags. However, matching a language to a user selection may be simpler for user code if the language encoding is kept simple. At the moment, I tend to favor allowing both two letter tags (eg, "en") and secondary tags (like "en_EN"), as RFC 3066 tags can be quite complex, but I welcome comments on this.

Alternatively, I might use only RFC 1766 tags, which are essentially the subset I considered above, but this RFC has been deprecated by RFC 3066, and I'm not sure of the wisdom of basing a new format on a deprecated RFC.

Also, it might be possible for the language field to be a list of such encodings, for streams that contain several languages (though the usual way to present several languages is to have several bitstreams multiplexed with one another (as opposed to Writ, which has all languages included in a single bitstream)).

A disadvantage of having multiple languages is that text-to-speech typically needs to know the current language to function properly, and that having, say, two current languages, would make it more difficult to deal with such a stream.

Bitstream format for floating point values

Floating point values are be turned to a 16.16 fixed point format, then stored in a bitpacked format, storing the number of zero bits at the head and tail of the floating point values once per stream, and the remainder bits for all values in the stream. This seems to yield good results (typically a 50% reduction over 32 bits raw writes, and 70% over the snprintf based storage), and has the big advantage of being portable (eg, independant of any IEEE format). However, this means reduced precision due to the quantization to 16.16. I may add support for variable precision (eg, 8.24 fixed point formats) to alleviate this. This would however mean less space savings, though these are likely to be insignificant when Kate streams are interleaved with a video.

  • Though this is not a Kate issue per se, the motion feature is very difficult to use without a curve editor. While tools may be coded to create a Kate bitstream for various existing subtitle formats, it is not certain it will be easy to find a good authoring tool for a series of curves. That said, it's not exactly difficult to do if you know a widget set.


Text to speech

One of the goals of the Kate bitstream format is that text data can be easily parsed by the user of the decoder, so any additional information, such as style, placement, karaoke data, etc, should be able to be stripped to leave only the bare text. This is in view of allowing text-to-speech software to use Kate bitstreams as a bandwith-cheap way of conveying speech data, and could also allow things like e-books which can be either read or listened to from the same bitstream (I have seen no reference to this being used anywhere, but I see no reason why the granule progression should be temporal, and not user controlled, such as by using a "next" button which would bump a granule postion by a preset amount, simulating turning a page (this would be close to necessary for text-to-speech, as the wall time duration of the spoken speech is not known in advance to the Kate encoder, and can't be mapped to a time based granule progression)). All text strings triggered consecutively between the two granule positions would then be read in order.

Possible additions

Embedded binary data

Various types of binary data could be embedded within a Kate stream:

Fonts

Font selection is the first thing that came to mind, due to the discrepancy of font naming in platforms (eg, the *-*-* X system, and the... hmm, not sure, filename ? in Windows). A potential problem, however, is that there might be several multiplexed Kate streams in an Ogg bitstream, so a custom font might be included several times in the container stream. On the other hand, it would allow for per-language fonts.

Images

Though this could interfere with ability to render as text-to-speech, images could be mixed with text. The same caveat as for fonts applies with regard to data duplication. This might however be best left to a multiplexed OggSpots stream, unless the images mesh with the text (eg, graphical exclamation points, etc).

A possible solution to the duplication issue is to have another stream in the container stream, which would hold the shared data (eg, fonts), which the user program could load, and which could then be used by any Kate (and other) stream. Typically, this type of stream would be a degenerate stream with only header packets (so it is fully processed before any other stream presents data packets that might make use of that shared data), and all payload such as fonts being contained within the headers. Thinking about it, it has parallels with the way Vorbis stores its codebooks within a header packet, or even the way Kate stores the list of styles within a header packet.

Reference encoder/decoder

A encoder and a decoder are included in the tools directory. Note that they are very rough and do not perform much error checking at all. The encoder pulls its input from a custom text based file format, which is by no means meant to be part of the Kate bitstream specification, or from an SubRip format file (the most common subtitle format I found, and a very basic one).

The Kate bitstreams encoded and decoded by those tools, however, are (supposed to be) correct for this specification, provided their input is correct.