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debug updates
Original commit message from CVS: debug updates
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2 changed files with 239 additions and 106 deletions
335
ext/ogg/README
335
ext/ogg/README
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@ -1,3 +1,93 @@
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This document describes some things to know about the Ogg format, as well
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as implementation details in GStreamer.
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INTRODUCTION
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============
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ogg and the granulepos
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----------------------
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An ogg stream contains pages with a serial number and a granulepos.
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The granulepos is a 64 bit signed integer. It is a value that in some way
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represents a time since the start of the stream.
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The interpretation as such is however both codec-specific and
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stream-specific.
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ogg has no notion of time: it only knows about bytes and granulepos values
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on pages.
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The granule position is just a number; the only guarantee for a valid ogg
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stream is that within a logical stream, this number never decreases.
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While logically a granulepos value can be constructed for every ogg packet,
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the page is marked with only one granulepos value: the granulepos of the
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last packet to end on that page.
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theora and the granulepos
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-------------------------
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The granulepos in theora is an encoding of the frame number of the last
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key frame ("i frame"), and the number of frames since the last key frame
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("p frame"). The granulepos is constructed as the sum of the first number,
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shifted to the left for granuleshift bits, and the second number:
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granulepos = pframe << granuleshift + iframe
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(This means that given a framenumber or a timestamp, one cannot generate
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the one and only granulepos for that page; several granulepos possibilities
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correspond to this frame number. You also need the last keyframe, as well
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as the granuleshift.
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However, given a granulepos, the theora codec can still map that to a
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unique timestamp and frame number for that theora stream)
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Note: currently theora stores the "presentation time" as the granulepos;
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ie. a first data page with one packet contains one video frame and
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will be marked with 0/0. Changing that to be 1/0 (so that it
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represents the number of decodable frames up to that point, like
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for Vorbis) is being discussed.
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vorbis and granulepos
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---------------------
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In Vorbis, the granulepos represents the number of samples that can be
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decoded from all packets up to that point.
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In GStreamer, the vorbisenc elements produces a stream where:
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- OFFSET is the byte offset this buffer is at; ie a running count of the
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number of bytes produced before
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- OFFSET_END is the granulepos of the produced vorbis buffer
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- TIMESTAMP is the timestamp matching the begin of the buffer
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- DURATION is set such that TIMESTAMP + DURATION is the correct
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in a raw vorbis stream we use the granulepos as the offset field.
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Ogg media mapping
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-----------------
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Ogg defines a mapping for each media type that it embeds.
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For Vorbis:
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- 3 header pages, with granulepos 0.
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- 1 page with 1 packet header identification
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- N pages with 2 packets comments and codebooks
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- granulepos is samplenumber of next page
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- one packet can contain a variable number of samples but one frame
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that should be handed to the vorbis decoder.
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For Theora
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- 3 header pages, with granulepos 0.
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- 1 page with 1 packet header identification
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- N pages with 2 packets comments and codebooks
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- granulepos is framenumber of last packet in page, where framenumber
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is a combination of keyframe number and p frames since keyframe.
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- one packet contains 1 frame
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DEMUXING
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========
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ogg demuxer
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-----------
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@ -9,25 +99,25 @@ with great efficiency.
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1) the streaming mode.
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In this mode, the ogg demuxer receives buffers in the _chain() function which
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are then simply submited to the ogg sync layer. Pages are then processed when the
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sync layer detects them, pads are created for new chains and packets are sent to
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the peer elements of the pads.
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In this mode, the ogg demuxer receives buffers in the _chain() function which
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are then simply submited to the ogg sync layer. Pages are then processed when
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the sync layer detects them, pads are created for new chains and packets are
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sent to the peer elements of the pads.
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In this mode, no seeking is possible. This is the typical case when the stream is
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read from a network source.
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In this mode, no seeking is possible. This is the typical case when the
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stream is read from a network source.
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In this mode, no setup is done at startup, the pages are just read and decoded.
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A new logical chain is detected when one of the pages has the BOS flag set. At this
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point the existing pads are removed and new pads are created for all the logical
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streams in this new chain.
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In this mode, no setup is done at startup, the pages are just read and decoded.
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A new logical chain is detected when one of the pages has the BOS flag set. At
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this point the existing pads are removed and new pads are created for all the
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logical streams in this new chain.
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2) the random access mode.
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In this mode, the ogg file is first scanned to detect the position and length of
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all chains. This scanning is performed using a recursive binary search algorithm
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that is explained below.
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In this mode, the ogg file is first scanned to detect the position and length
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of all chains. This scanning is performed using a recursive binary search
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algorithm that is explained below.
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find_chains(start, end)
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{
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@ -97,121 +187,158 @@ testcases
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| 111 | 222 |
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BOS EOS
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What can an ogg demuxer do?
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---------------------------
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An ogg demuxer can read pages and get the granulepos from them.
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It can ask the decoder elements to convert a granulepos to time.
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ogg and the granulepos
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----------------------
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An ogg demuxer can also get the granulepos of the first and the last page of a
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stream to get the start and end timestamp of that stream.
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It can also get the length in bytes of the stream
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(when the peer is seekable, that is).
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an ogg streams contains pages with a serial number and a granule pos. The granulepos
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is a number that is codec specific and denotes the 'position' of the last sample in
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the last packet in that page.
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An ogg demuxer is therefore basically able to seek to any byte position and
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timestamp.
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ogg has therefore no notion about time, it only knows about bytes and granule positions.
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The granule position is just a number, it can contain gaps or can just be any random
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number.
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theora and the granulepos
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-------------------------
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the granulepos in theora consists of the framenumber of the last keyframe shifted some
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amount of bits plus the number of p/b-frames.
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This means that given a framenumber or a timestamp one cannot generate the granulepos
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for that frame. eg frame 10 could have several valid granulepos values depending on if
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the last keyframe was on frame 5 or 0. Given a granulepos we can, however, create a
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unique correct timestamp and a framenumber.
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in a raw theroa stream we use the granulepos as the offset field.
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The granulepos of an ogg page is the framenumber of the last frame in the page.
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vorbis and granulepos
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---------------------
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the granulepos in vorbis happens to be the same as the sample counter. conversion to and
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from granulepos is therefore easy.
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in a raw vorbis stream we use the granulepos as the offset field.
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The granulepos of an ogg page is the sample number of the next page in the ogg stream.
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What can ogg do?
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----------------
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An ogg demuxer can read pages and get the granuleposition from it. It can ask the decoder
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elements to convert a granulepos to time.
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An ogg demuxer can also get the granulepos of the first and the last page of a stream to
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get the start and end timestamp of that stream. It can also get the length in bytes of
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the stream (when the peer is seekable, that is).
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An ogg demuxer is therefore basically able to seek to any byte position and timestamp.
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When asked to seek to a given granulepos, the ogg demuxer should always convert the
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value to a timestamp using the peer decoder element conversion function. It can then
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binary search the file to eventually end up on the page with the given granule pos or
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a granulepos with the same timestamp.
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When asked to seek to a given granulepos, the ogg demuxer should always convert
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the value to a timestamp using the peer decoder element conversion function. It
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can then binary search the file to eventually end up on the page with the given
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granule pos or a granulepos with the same timestamp.
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Seeking in ogg currently
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------------------------
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When seeking in an ogg, the decoders can choose to forward the seek event as a
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When seeking in an ogg, the decoders can choose to forward the seek event as a
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granulepos or a timestamp to the ogg demuxer.
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In the case of a granulepos, the ogg demuxer will seek back to the beginning of
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the stream and skip pages until it finds one with the requested timestamp.
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In the case of a timestamp, the ogg demuxer also seeks back to the beginning of
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the stream. For each page it reads, it asks the decoder element to convert the
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granulepos back to a timestamp. The ogg demuxer keeps on skipping pages until the
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page has a timestamp bigger or equal to the requested one.
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the stream. For each page it reads, it asks the decoder element to convert the
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granulepos back to a timestamp. The ogg demuxer keeps on skipping pages until
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the page has a timestamp bigger or equal to the requested one.
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It is therefore important that the decoder elements in vorbis can convert a granulepos
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into a timestamp or never seek on timestamp on the oggdemuxer.
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It is therefore important that the decoder elements in vorbis can convert a
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granulepos into a timestamp or never seek on timestamp on the oggdemuxer.
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The default format on the oggdemuxer source pads is currently defined as a the
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granulepos of the packets, it is also the value of the OFFSET field in the GstBuffer.
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The default format on the oggdemuxer source pads is currently defined as a the
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granulepos of the packets, it is also the value of the OFFSET field in the
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GstBuffer.
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MUXING
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======
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Oggmux
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------
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The ogg muxer's job is to output complete Ogg pages such that the absolute
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time represented by the valid (ie, not -1) granulepos values on those pages
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never decreases. This has to be true for all logical streams in the group at
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the same time.
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To achieve this, encoders are required to pass along the exact time that the
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granulepos represents for each ogg packet that it pushes to the ogg muxer.
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This is ESSENTIAL: without this exact time representation of the granulepos,
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the muxer can not produce valid streams.
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The ogg muxer has a packet queue per sink pad. From this queue a page can
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be flushed when:
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- total byte size of queued packets exceeds a given value
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- total time duration of queued packets exceeds a given value
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- total byte size of queued packets exceeds maximum Ogg page size
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- eos of the pad
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- encoder sent a command to flush out an ogg page after this new packet
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(in 0.8, through a flush event; in 0.10, with a GstOggBuffer)
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- muxer wants a flush to happen (so it can output pages)
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The ogg muxer also has a page queue per sink pad. This queue collects
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Ogg pages from the corresponding packet queue. Each page is also marked
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with the timestamp that the granulepos in the header represents.
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A page can be flushed from this collection of page queues when:
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- ideally, every page queue has at least one page with a valid granulepos
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-> choose the page, from all queues, with the lowest timestamp value
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- if not, muxer can wait if the following limits aren't reached:
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- total byte size of any page queue exceeds a limit
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- total time duration of any page queue exceeds a limit
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- if this limit is reached, then:
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- request a page flush from packet queue to page queue for each queue
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that does not have pages
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- now take the page from all queues with the lowest timestamp value
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- make sure all later-coming data is marked as old, either to be still
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output (but producing an invalid stream, though it can be fixed later)
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or dropped (which means it's gone forever)
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The oggmuxer uses the offset fields to fill in the granulepos in the pages.
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GStreamer implementation details
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--------------------------------
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As said before, the basic rule is that the ogg muxer needs an exact time
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representation for each granulepos. This needs to be provided by the encoder.
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Potential problems are:
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- initial offsets for a raw stream need to be preserved somehow. Example:
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if the first audio sample has time 0.5, the granulepos in the vorbis encoder
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needs to be adjusted to take this into account.
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- initial offsets may need be on rate boundaries. Example:
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if the framerate is 5 fps, and the first video frame has time 0.1 s, the
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granulepos cannot correctly represent this timestamp.
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This can be handled out-of-band (initial offset in another muxing format,
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skeleton track with initial offsets, ...)
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Given that the basic rule for muxing is that the muxer needs an exact timestamp
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matching the granulepos, we need some way of communicating this time value
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from encoders to the Ogg muxer. So we need a mechanism to communicate
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a granulepos and its time representation for each GstBuffer.
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(This is an instance of a more generic problem - having a way to attach
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more fields to a GstBuffer)
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Possible ways:
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- setting TIMESTAMP to this value: bad - this value represents the end time
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of the buffer, and thus conflicts with GStreamer's idea of what TIMESTAMP
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is. This would cause problems muxing the encoded stream in other muxing
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formats, or for streaming. Note that this is what was done in GStreamer 0.8
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- setting DURATION to GP_TIME - TIMESTAMP: bad - this breaks the concept of
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duration for this frame. Take the video example above; each buffer would
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have a correct timestamp, but always a 0.1 s duration as opposed to the
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correct 0.2 s duration
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- subclassing GstBuffer: clean, but requires a common header used between
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ogg muxer and all encoders that can be muxed into ogg. Also, what if
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a format can be muxed into more than one container, and they each have
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their own "extra" info to communicate ?
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- adding key/value pairs to GstBuffer: clean, but requires changes to
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core. Also, the overhead of allocating e.g. a GstStructure for *each* buffer
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may be expensive.
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- "cheating":
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- abuse OFFSET to store the timestamp matching this granulepos
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- abuse OFFSET_END to store the granulepos value
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The drawback here is that before, it made sense to use OFFSET and OFFSET_END
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to store a byte count. Given that this is not used for anything critical
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(you can't store a raw theora or vorbis stream in a file anyway),
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this is what's being done for now.
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In practice
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-----------
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- all encoders of formats that can be muxed into Ogg produce a stream where:
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- OFFSET is abused to be the granulepos of the encoded theora buffer
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- OFFSET_END is abused to be the timestamp corresponding exactly to the
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granulepos
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- TIMESTAMP is the timestamp matching the begin of the buffer
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- DURATION is the length in time of the buffer
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- initial delays should be handled in the GStreamer encoders by mangling
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the granulepos of the encoded packet to take the delay into account as
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best as possible and store that in OFFSET;
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this then brings TIMESTAMP + DURATION to within less
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than a frame period of the granulepos's time representation
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The ogg muxer will then create new ogg packets with this OFFSET as
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the granulepos. So in effect, the granulepos produced by the encoders
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does not get used directly.
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TODO
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----
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- use the OFFSET field in the GstBuffer to store/read the granulepos as
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opposed to the OFFSET_END field.
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Ogg media mapping
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-----------------
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Ogg defines a mapping for each media type that it embeds.
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For Vorbis:
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- 3 header pages, with granulepos 0.
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- 1 page with 1 packet header identification
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- N pages with 2 packets comments and codebooks
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- granulepos is samplenumber of next page
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- one packet can contain a variable number of samples but one frame
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that should be handed to the vorbis decoder.
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For Theora
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- 3 header pages, with granulepos 0.
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- 1 page with 1 packet header identification
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- N pages with 2 packets comments and codebooks
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- granulepos is framenumber of last packet in page, where framenumber
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is a combination of keyframe number and p frames since keyframe.
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- one packet contains 1 frame
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- decide on a proper mechanism for communicating extra per-buffer fields
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@ -574,7 +574,7 @@ gst_ogg_mux_dequeue_page (GstOggMux * mux, GstFlowReturn * flowret)
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* TODO: it CAN be, but it seems silly to do so? */
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buf = g_queue_peek_head (pad->pagebuffers);
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while (buf && GST_BUFFER_OFFSET_END (buf) == -1) {
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GST_LOG_OBJECT (pad->collect.pad, GST_GP_FORMAT " pushing page", -1);
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GST_LOG_OBJECT (pad->collect.pad, "[gp -1] pushing page");
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g_queue_pop_head (pad->pagebuffers);
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*flowret = gst_ogg_mux_push_buffer (mux, buf);
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buf = g_queue_peek_head (pad->pagebuffers);
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@ -584,11 +584,17 @@ gst_ogg_mux_dequeue_page (GstOggMux * mux, GstFlowReturn * flowret)
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if (buf) {
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/* if no oldest buffer yet, take this one */
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if (oldest == GST_CLOCK_TIME_NONE) {
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GST_LOG_OBJECT (mux, "no oldest yet, taking from pad %"
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GST_PTR_FORMAT " with timestamp %" GST_TIME_FORMAT,
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pad->collect.pad, GST_TIME_ARGS (GST_BUFFER_TIMESTAMP (buf)));
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oldest = GST_BUFFER_END_TIME (buf);
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opad = pad;
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} else {
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/* if we have an oldest, compare with this one */
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if (GST_BUFFER_END_TIME (buf) < oldest) {
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GST_LOG_OBJECT (mux, "older buffer, taking from pad %"
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GST_PTR_FORMAT " with timestamp %" GST_TIME_FORMAT,
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pad->collect.pad, GST_TIME_ARGS (GST_BUFFER_TIMESTAMP (buf)));
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oldest = GST_BUFFER_END_TIME (buf);
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opad = pad;
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}
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if (oldest != GST_CLOCK_TIME_NONE) {
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g_assert (opad);
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buf = g_queue_pop_head (opad->pagebuffers);
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GST_LOG_OBJECT (opad,
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GST_LOG_OBJECT (opad->collect.pad,
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GST_GP_FORMAT " pushing oldest page (end time %" GST_TIME_FORMAT ")",
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GST_BUFFER_OFFSET_END (buf), GST_TIME_ARGS (GST_BUFFER_END_TIME (buf)));
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*flowret = gst_ogg_mux_push_buffer (mux, buf);
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Reference in a new issue