doc/a1-encapsulation-ogg.tex - platform/external/libvorbis - Git at Google

 % -*- mode: latex; TeX-master: "Vorbis_I_spec"; -*-
 %!TEX root = Vorbis_I_spec.tex
 % $Id$
 \section{Embedding Vorbis into an Ogg stream} \label{vorbis:over:ogg}

 \subsection{Overview}

 This document describes using Ogg logical and physical transport
 streams to encapsulate Vorbis compressed audio packet data into file
 form.

 The \xref{vorbis:spec:intro} provides an overview of the construction
 of Vorbis audio packets.

 The \href{oggstream.html}{Ogg
 bitstream overview} and \href{framing.html}{Ogg logical
 bitstream and framing spec} provide detailed descriptions of Ogg
 transport streams. This specification document assumes a working
 knowledge of the concepts covered in these named backround
 documents.  Please read them first.

 \subsubsection{Restrictions}

 The Ogg/Vorbis I specification currently dictates that Ogg/Vorbis
 streams use Ogg transport streams in degenerate, unmultiplexed
 form only. That is:

 \begin{itemize}
  \item
   A meta-headerless Ogg file encapsulates the Vorbis I packets

  \item
   The Ogg stream may be chained, i.e., contain multiple, contigous logical streams (links).

  \item
   The Ogg stream must be unmultiplexed (only one stream, a Vorbis audio stream, per link)

 \end{itemize}


 This is not to say that it is not currently possible to multiplex
 Vorbis with other media types into a multi-stream Ogg file.  At the
 time this document was written, Ogg was becoming a popular container
 for low-bitrate movies consisting of DivX video and Vorbis audio.
 However, a 'Vorbis I audio file' is taken to imply Vorbis audio
 existing alone within a degenerate Ogg stream.  A compliant 'Vorbis
 audio player' is not required to implement Ogg support beyond the
 specific support of Vorbis within a degenrate Ogg stream (naturally,
 application authors are encouraged to support full multiplexed Ogg
 handling).


 \subsubsection{MIME type}

 The MIME type of Ogg files depend on the context.  Specifically, complex
 multimedia and applications should use \literal{application/ogg},
 while visual media should use \literal{video/ogg}, and audio
 \literal{audio/ogg}.  Vorbis data encapsulated in Ogg may appear
 in any of those types.  RTP encapsulated Vorbis should use
 \literal{audio/vorbis} + \literal{audio/vorbis-config}.


 \subsection{Encapsulation}

 Ogg encapsulation of a Vorbis packet stream is straightforward.

 \begin{itemize}

 \item
   The first Vorbis packet (the identification header), which
   uniquely identifies a stream as Vorbis audio, is placed alone in the
   first page of the logical Ogg stream.  This results in a first Ogg
   page of exactly 58 bytes at the very beginning of the logical stream.


 \item
   This first page is marked 'beginning of stream' in the page flags.


 \item
   The second and third vorbis packets (comment and setup
   headers) may span one or more pages beginning on the second page of
   the logical stream.  However many pages they span, the third header
   packet finishes the page on which it ends.  The next (first audio) packet
   must begin on a fresh page.


 \item
   The granule position of these first pages containing only headers is zero.


 \item
   The first audio packet of the logical stream begins a fresh Ogg page.


 \item
   Packets are placed into ogg pages in order until the end of stream.


 \item
   The last page is marked 'end of stream' in the page flags.


 \item
   Vorbis packets may span page boundaries.


 \item
   The granule position of pages containing Vorbis audio is in units
   of PCM audio samples (per channel; a stereo stream's granule position
   does not increment at twice the speed of a mono stream).


 \item
   The granule position of a page represents the end PCM sample
   position of the last packet \emph{completed} on that
   page.  The 'last PCM sample' is the last complete sample returned by
   decode, not an internal sample awaiting lapping with a
   subsequent block.  A page that is entirely spanned by a single
   packet (that completes on a subsequent page) has no granule
   position, and the granule position is set to '-1'.


   Note that the last decoded (fully lapped) PCM sample from a packet
   is not necessarily the middle sample from that block. If, eg, the
   current Vorbis packet encodes a "long block" and the next Vorbis
   packet encodes a "short block", the last decodable sample from the
   current packet be at position (3*long\_block\_length/4) -
   (short\_block\_length/4).


 \item
     The granule (PCM) position of the first page need not indicate
     that the stream started at position zero.  Although the granule
     position belongs to the last completed packet on the page and a
     valid granule position must be positive, by
     inference it may indicate that the PCM position of the beginning
     of audio is positive or negative.


   \begin{itemize}
     \item
         A positive starting value simply indicates that this stream begins at
         some positive time offset, potentially within a larger
         program. This is a common case when connecting to the middle
         of broadcast stream.

     \item
         A negative value indicates that
         output samples preceeding time zero should be discarded during
         decoding; this technique is used to allow sample-granularity
         editing of the stream start time of already-encoded Vorbis
         streams.  The number of samples to be discarded must not exceed
         the overlap-add span of the first two audio packets.

   \end{itemize}


     In both of these cases in which the initial audio PCM starting
     offset is nonzero, the second finished audio packet must flush the
     page on which it appears and the third packet begin a fresh page.
     This allows the decoder to always be able to perform PCM position
     adjustments before needing to return any PCM data from synthesis,
     resulting in correct positioning information without any aditional
     seeking logic.


   \begin{note}
     Failure to do so should, at worst, cause a
     decoder implementation to return incorrect positioning information
     for seeking operations at the very beginning of the stream.
   \end{note}


 \item
   A granule position on the final page in a stream that indicates
   less audio data than the final packet would normally return is used to
   end the stream on other than even frame boundaries.  The difference
   between the actual available data returned and the declared amount
   indicates how many trailing samples to discard from the decoding
   process.

 \end{itemize}
	% -- mode: latex; TeX-master: "Vorbis_I_spec"; --
	%!TEX root = Vorbis_I_spec.tex
	% $Id$
	\section{Embedding Vorbis into an Ogg stream} \label{vorbis:over:ogg}

	\subsection{Overview}

	This document describes using Ogg logical and physical transport
	streams to encapsulate Vorbis compressed audio packet data into file
	form.

	The \xref{vorbis:spec:intro} provides an overview of the construction
	of Vorbis audio packets.

	The \href{oggstream.html}{Ogg
	bitstream overview} and \href{framing.html}{Ogg logical
	bitstream and framing spec} provide detailed descriptions of Ogg
	transport streams. This specification document assumes a working
	knowledge of the concepts covered in these named backround
	documents. Please read them first.

	\subsubsection{Restrictions}

	The Ogg/Vorbis I specification currently dictates that Ogg/Vorbis
	streams use Ogg transport streams in degenerate, unmultiplexed
	form only. That is:

	\begin{itemize}
	\item
	A meta-headerless Ogg file encapsulates the Vorbis I packets

	\item
	The Ogg stream may be chained, i.e., contain multiple, contigous logical streams (links).

	\item
	The Ogg stream must be unmultiplexed (only one stream, a Vorbis audio stream, per link)

	\end{itemize}


	This is not to say that it is not currently possible to multiplex
	Vorbis with other media types into a multi-stream Ogg file. At the
	time this document was written, Ogg was becoming a popular container
	for low-bitrate movies consisting of DivX video and Vorbis audio.
	However, a 'Vorbis I audio file' is taken to imply Vorbis audio
	existing alone within a degenerate Ogg stream. A compliant 'Vorbis
	audio player' is not required to implement Ogg support beyond the
	specific support of Vorbis within a degenrate Ogg stream (naturally,
	application authors are encouraged to support full multiplexed Ogg
	handling).




	\subsubsection{MIME type}

	The MIME type of Ogg files depend on the context. Specifically, complex
	multimedia and applications should use \literal{application/ogg},
	while visual media should use \literal{video/ogg}, and audio
	\literal{audio/ogg}. Vorbis data encapsulated in Ogg may appear
	in any of those types. RTP encapsulated Vorbis should use
	\literal{audio/vorbis} + \literal{audio/vorbis-config}.


	\subsection{Encapsulation}

	Ogg encapsulation of a Vorbis packet stream is straightforward.

	\begin{itemize}

	\item
	The first Vorbis packet (the identification header), which
	uniquely identifies a stream as Vorbis audio, is placed alone in the
	first page of the logical Ogg stream. This results in a first Ogg
	page of exactly 58 bytes at the very beginning of the logical stream.


	\item
	This first page is marked 'beginning of stream' in the page flags.


	\item
	The second and third vorbis packets (comment and setup
	headers) may span one or more pages beginning on the second page of
	the logical stream. However many pages they span, the third header
	packet finishes the page on which it ends. The next (first audio) packet
	must begin on a fresh page.


	\item
	The granule position of these first pages containing only headers is zero.


	\item
	The first audio packet of the logical stream begins a fresh Ogg page.


	\item
	Packets are placed into ogg pages in order until the end of stream.


	\item
	The last page is marked 'end of stream' in the page flags.


	\item
	Vorbis packets may span page boundaries.


	\item
	The granule position of pages containing Vorbis audio is in units
	of PCM audio samples (per channel; a stereo stream's granule position
	does not increment at twice the speed of a mono stream).


	\item
	The granule position of a page represents the end PCM sample
	position of the last packet \emph{completed} on that
	page. The 'last PCM sample' is the last complete sample returned by
	decode, not an internal sample awaiting lapping with a
	subsequent block. A page that is entirely spanned by a single
	packet (that completes on a subsequent page) has no granule
	position, and the granule position is set to '-1'.


	Note that the last decoded (fully lapped) PCM sample from a packet
	is not necessarily the middle sample from that block. If, eg, the
	current Vorbis packet encodes a "long block" and the next Vorbis
	packet encodes a "short block", the last decodable sample from the
	current packet be at position (3*long\_block\_length/4) -
	(short\_block\_length/4).


	\item
	The granule (PCM) position of the first page need not indicate
	that the stream started at position zero. Although the granule
	position belongs to the last completed packet on the page and a
	valid granule position must be positive, by
	inference it may indicate that the PCM position of the beginning
	of audio is positive or negative.


	\begin{itemize}
	\item
	A positive starting value simply indicates that this stream begins at
	some positive time offset, potentially within a larger
	program. This is a common case when connecting to the middle
	of broadcast stream.

	\item
	A negative value indicates that
	output samples preceeding time zero should be discarded during
	decoding; this technique is used to allow sample-granularity
	editing of the stream start time of already-encoded Vorbis
	streams. The number of samples to be discarded must not exceed
	the overlap-add span of the first two audio packets.

	\end{itemize}


	In both of these cases in which the initial audio PCM starting
	offset is nonzero, the second finished audio packet must flush the
	page on which it appears and the third packet begin a fresh page.
	This allows the decoder to always be able to perform PCM position
	adjustments before needing to return any PCM data from synthesis,
	resulting in correct positioning information without any aditional
	seeking logic.


	\begin{note}
	Failure to do so should, at worst, cause a
	decoder implementation to return incorrect positioning information
	for seeking operations at the very beginning of the stream.
	\end{note}


	\item
	A granule position on the final page in a stream that indicates
	less audio data than the final packet would normally return is used to
	end the stream on other than even frame boundaries. The difference
	between the actual available data returned and the declared amount
	indicates how many trailing samples to discard from the decoding
	process.

	\end{itemize}