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f48e7920da
Remove bufferlist part, it's merged with part-buffer.txt
210 lines
7.2 KiB
Text
210 lines
7.2 KiB
Text
Synchronisation
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---------------
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This document outlines the techniques used for doing synchronised playback of
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multiple streams.
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Synchronisation in a GstPipeline is achieved using the following 3 components:
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- a GstClock, which is global for all elements in a GstPipeline.
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- Timestamps on a GstBuffer.
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- the SEGMENT event preceding the buffers.
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A GstClock
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~~~~~~~~~~
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This object provides a counter that represents the current time in nanoseconds.
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This value is called the absolute_time.
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Different sources exist for this counter:
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- the system time (with g_get_current_time() and with microsecond accuracy)
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- an audio device (based on number of samples played)
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- a network source based on packets received + timestamps in those packets (a
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typical example is an RTP source)
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- ...
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In GStreamer any element can provide a GstClock object that can be used in the
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pipeline. The GstPipeline object will select a clock from all the providers and
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will distribute it to all other elements (see part-gstpipeline.txt).
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A GstClock always counts time upwards and does not necessarily start at 0.
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Running time
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~~~~~~~~~~~~
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After a pipeline selected a clock it will maintain the running_time based on the
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selected clock. This running_time represents the total time spent in the PLAYING
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state and is calculated as follows:
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- If the pipeline is NULL/READY, the running_time is undefined.
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- In PAUSED, the running_time remains at the time when it was last
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PAUSED. When the stream is PAUSED for the first time, the running_time
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is 0.
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- In PLAYING, the running_time is the delta between the absolute_time
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and the base time. The base time is defined as the absolute_time minus
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the running_time at the time when the pipeline is set to PLAYING.
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- after a flushing seek, the running_time is set to 0 (see part-seeking.txt).
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This is accomplished by redistributing a new base_time to the elements that
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got flushed.
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This algorithm captures the running_time when the pipeline is set from PLAYING
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to PAUSED and restores this time based on the current absolute_time when going
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back to PLAYING. This allows for both clocks that progress when in the PAUSED
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state (systemclock) and clocks that don't (audioclock).
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The clock and pipeline now provide a running_time to all elements that want to
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perform synchronisation. Indeed, the running time can be observed in each
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element (during the PLAYING state) as:
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C.running_time = absolute_time - base_time
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We note C.running_time as the running_time obtained by looking at the clock.
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This value is monotonically increasing at the rate of the clock.
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Timestamps
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~~~~~~~~~~
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The GstBuffer timestamps and the preceeding SEGMENT event (See
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part-streams.txt) define a transformation of the buffer timestamps to
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running_time as follows:
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The following notation is used:
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B: GstBuffer
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- B.timestamp = buffer timestamp (GST_BUFFER_TIMESTAMP)
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NS: SEGMENT event preceeding the buffers.
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- NS.start: start field in the SEGMENT event
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- NS.stop: stop field in the SEGMENT event
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- NS.rate: rate field of SEGMENT event
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- NS.abs_rate: absolute value of rate field of SEGMENT event
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- NS.time: time field in the SEGMENT event
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- NS.accum: total accumulated time of all previous SEGMENT events. This
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field is kept in the GstSegment structure.
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Valid buffers for synchronisation are those with B.timestamp between NS.start
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and NS.stop. All other buffers outside this range should be dropped or clipped
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to these boundaries (see also part-segments.txt).
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The following transformation to running_time exist:
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if (NS.rate > 0.0)
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B.running_time = (B.timestamp - NS.start) / NS.abs_rate + NS.accum
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else
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B.running_time = (NS.stop - B.timestamp) / NS.abs_rate + NS.accum
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We write B.running_time as the running_time obtained from the SEGMENT event
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and the buffers of that segment.
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The first displayable buffer will yield a value of 0 (since B.timestamp ==
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NS.start and NS.accum == 0).
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For NS.rate > 1.0, the timestamps will be scaled down to increase the playback
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rate. Likewise, a rate between 0.0 and 1.0 will slow down playback.
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For negative rates, timestamps are received stop NS.stop to NS.start so that the
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first buffer received will be transformed into B.running_time of 0 (B.timestamp ==
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NS.stop and NS.accum == 0).
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Synchronisation
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~~~~~~~~~~~~~~~
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As we have seen, we can get a running_time:
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- using the clock and the element's base_time with:
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C.running_time = absolute_time - base_time
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- using the buffer timestamp and the preceeding SEGMENT event as (assuming
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positive playback rate):
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B.running_time = (B.timestamp - NS.start) / NS.abs_rate + NS.accum
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We prefix C. and B. before the two running times to note how they were
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calculated.
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The task of synchronized playback is to make sure that we play a buffer with
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B.running_time at the moment when the clock reaches the same C.running_time.
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Thus the following must hold:
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B.running_time = C.running_time
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expaning:
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B.running_time = absolute_time - base_time
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or:
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absolute_time = B.running_time + base_time
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The absolute_time when a buffer with B.running_time should be played is noted
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with B.sync_time. Thus:
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B.sync_time = B.running_time + base_time
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One then waits for the clock to reach B.sync_time before rendering the buffer in
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the sink (See also part-clocks.txt).
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For multiple streams this means that buffers with the same running_time are to
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be displayed at the same time.
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A demuxer must make sure that the SEGMENT it emits on its output pads yield
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the same running_time for buffers that should be played synchronized. This
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usually means sending the same SEGMENT on all pads and making sure that the
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synchronized buffers have the same timestamps.
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Stream time
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~~~~~~~~~~~
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The stream time is also known as the position in the stream and is a value
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between 0 and the total duration of the media file.
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It is the stream time that is used for:
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- report the POSITION query in the pipeline
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- the position used in seek events/queries
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- the position used to synchronize controller values
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Stream time is calculated using the buffer times and the preceeding SEGMENT
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event as follows:
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stream_time = (B.timestamp - NS.start) * NS.abs_applied_rate + NS.time
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For negative rates, B.timestamp will go backwards from NS.stop to NS.start,
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making the stream time go backwards.
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In the PLAYING state, it is also possible to use the pipeline clock to derive
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the current stream_time.
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Give the two formulas above to match the clock times with buffer timestamps
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allows us to rewrite the above formula for stream_time (and for positive rates).
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C.running_time = absolute_time - base_time
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B.running_time = (B.timestamp - NS.start) / NS.abs_rate + NS.accum
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=>
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(B.timestamp - NS.start) / NS.abs_rate + NS.accum = absolute_time - base_time;
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=>
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(B.timestamp - NS.start) / NS.abs_rate = absolute_time - base_time - NS.accum;
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=>
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(B.timestamp - NS.start) = (absolute_time - base_time - NS.accum) * NS.abs_rate
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filling (B.timestamp - NS.start) in the above formule for stream time
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=>
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stream_time = (absolute_time - base_time - NS.accum) * NS.abs_rate * NS.abs_applied_rate + NS.time
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This last formula is typically used in sinks to report the current position in
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an accurate and efficient way.
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Note that the stream time is never used for synchronisation against the clock.
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