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135 lines
5.1 KiB
Text
135 lines
5.1 KiB
Text
tsdemux/tsparse TODO
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--------------------
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* Performance
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* Bufferlist : Creating/Destroying very small buffers is too
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costly. Switch to pre-/re-allocating outgoing buffers in which we
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copy the data.
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* Adapter : Use gst_adapter_peek()/_flush() instead of constantly
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creating buffers.
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* Latency
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* Calculate the actual latency instead of returning a fixed
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value. The latency (for live streams) is the difference between the
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currently inputted buffer timestamp (can be stored in the
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packetizer) and the buffer we're pushing out.
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This value should be reported/updated (leave a bit of extra margin
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in addition to the calculated value).
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* mpegtsparser
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* SERIOUS room for improvement performance-wise (see callgrind),
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mostly related to performance issues mentioned above.
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* Random-access seeking
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* Do minimal parsing of video headers to detect keyframes and use
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that to compute the keyframe intervals. Use that interval to offset
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the seek position in order to maximize the chance of pushing out the
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requested frames.
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Synchronization, Scheduling and Timestamping
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--------------------------------------------
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A mpeg-ts demuxer can be used in a variety of situations:
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* lives streaming over DVB, UDP, RTP,..
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* play-as-you-download like HTTP Live Streaming or UPNP/DLNA
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* random-access local playback, file, Bluray, ...
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Those use-cases can be categorized in 3 different categories:
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* Push-based scheduling with live sources [0]
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* Push-based scheduling with non-live sources
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* Pull-based scheduling with fast random-access
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Due to the nature of timing within the mpeg-ts format, we need to
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pay extra attention to the outgoing NEWSEGMENT event and buffer
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timestamps in order to guarantee proper playback and synchronization
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of the stream.
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In the following, 'timestamps' correspond to GStreamer
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buffer/segment values. The mpeg-ts PCR/DTS/PTS values are indicated
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with their actual name.
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1) Live push-based scheduling
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The NEWSEGMENT event will be in time format and is forwarded as is,
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and the values are cached locally.
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Since the clock is running when the upstream buffers are captured,
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the outgoing buffer timestamps need to correspond to the incoming
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buffer timestamp values.
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=> mpegtspacketizer keeps track of PCR and input timestamp and
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extrapolates a clock skew using the EPTLA algorithm.
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=> The outgoing buffers will be timestamped with their PTS values
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(overflow corrected) corrected by that calculated clock skew.
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A latency is introduced between the time the buffer containing the
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first bit of a Access Unit is received in the demuxer and the moment
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the demuxer pushed out the buffer corresponding to that Access Unit.
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=> That latency needs to be reported.
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According to the ISO/IEC 13818-1:2007 specifications, D.0.1 Timing
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mode, the "coded audio and video that represent sound and pictures
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that are to be presented simultaneously may be separated in time
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within the coded bit stream by ==>as much as one second<=="
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=> The algorithm to calculate the latency should take that into
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account.
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2) Non-live push-based scheduling
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If the upstream NEWSEGMENT is in time format, the NEWSEGMENT event
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is forwarded as is, and the values are cached locally.
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If upstream does provide a NEWSEGMENT in another format, we need to
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compute one by taking the default values:
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start : 0
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stop : GST_CLOCK_TIME_NONE
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time : 0
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Since no prerolling is happening downstream and the incoming buffers
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do not have capture timestamps, we need to ensure the first buffer
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we push out corresponds to the base segment start running time.
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=> The packetizer keeps track of PCR locations and offsets in
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addition to the clock skew (in the case of upstream buffers
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being timestamped, which is the case for HLS).
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=> The demuxer indicates to the packetizer when he sees the
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'beginning' of the program (i.e. the first valid PAT/PMT
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combination). The packetizer will then use that location as
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"timestamp 0", or "reference position/PCR".
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=> The lowest DTS is passed to the packetizer to be converted to
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timestamp. That value is computed in the same way as live
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streams if upstream buffers have timestamps, or will be
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subtracted from the reference PCR.
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=> The outgoing buffers will be timestamped with their PTS values
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(overflow corrected) adjusted by the packetizer.
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Latency is reported just as with the live use-case.
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3) Random access pull-mode
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We do not get a NEWSEGMENT event from upstream, we therefore need to
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compute the outgoing values.
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=> The outgoing values for the newsegment are calculated like for
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the non-live push-based mode when upstream doesn't provide
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timestamp'ed buffers.
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=> The outgoing buffer timestamps are timestamped with their PTS
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values (overflow corrected) adjusted by the packetizer.
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[0] When talking about live sources, we mean this in the GStreamer
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definition of live sources, which is to say sources where if we miss
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the capture, we will miss the data to be captured. Sources which do
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internal buffering (like TCP connections or file descriptors) are
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*NOT* live sources.
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